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PhysRevB.87.220401.pdf | RAPID COMMUNICATIONS
PHYSICAL REVIEW B 87, 220401(R) (2013)
Anomalous domain wall velocity and Walker breakdown in hybrid systems
with anisotropic exchange
Henrik Enoksen, Asle Sudbø, and Jacob Linder
Department of Physics, Norwegian University of Science and Technology, N-7491 Trondheim, Norway
(Received 16 April 2013; published 7 June 2013)
It has recently been proposed that spin-transfer torques in magnetic systems with anisotropic exchange can be
strongly enhanced, reducing the characteristic current density with up to four orders of magnitude compared toconventional setups. Motivated by this, we analytically solve the equations of motion in a collective-coordinateframework for this type of anisotropic exchange system, to investigate the domain wall dynamics in detail. Inparticular, we obtain analytical expressions for the maximum attainable domain wall velocity of such a setupand also for the occurrence of Walker breakdown. Surprisingly, we find that, in contrast to the standard casewith domain wall motion driven by the nonadiabatic torque, the maximum velocity obtained via the anisotropicexchange torque is completely independent of the nonadiabaticity parameter β, in spite of the torque itself being
very large for small β. Moreover, the Walker breakdown threshold has an opposite dependence on βin these
two cases; i.e., for the anisotropic exchange torque scenario, the threshold value decreases monotonically withβ. These findings are of importance to any practical application of the proposed giant spin-transfer torque in
anisotropic exchange systems.
DOI: 10.1103/PhysRevB.87.220401 PACS number(s): 75 .78.Fg, 75 .60.Ch, 75 .40.Gb, 75 .70.Cn
Introduction . The concept of spin transport in magnetic
structures has proven to be of much relevance in terms ofboth applications and fundamental physics.
1One particularly
promising topic in the field of spintronics is electrical controlof domain wall motion in textured ferromagnets.
2The essential
idea is that controllable domain wall motion via spin-transfertorque may be used to represent information. This forms thebasis for possible applications such as magnetic random accessmemory, magnetic racetrack technology, and various types ofmagnetic logic gates.
3–6
In order to make controllable domain wall motion a feasible
technology, two key aspects7,8need to be addressed: (i) The
required current density to induce high-speed domain wallmotion must be lowered as much as possible and (ii) thestructural deformation of the domain wall triggered at theWalker breakdown
9must be delayed as much as possible,
allowing for a higher maximum wall velocity. An interestingproposition in the right direction concerning point (i) wasrecently made in Ref. 10. By considering an anisotropic
exchange interaction of a bilayer system consisting of aferromagnetic insulator and a semiconducting quantum well,it was proposed that sending a current through the latter partof the system would induce a torque on the texture M(x,t)
of the ferromagnetic insulator which would be four orders ofmagnitude stronger than in conventional spin-transfer torquesetups. The torque originating with anisotropic exchange wasfound to be proportional to 1 /βwithβbeing the so-called
nonadiabaticity parameter.
11For the typical nonadiabatic
torque term, the corresponding proportionality is β, which
is seen to be much smaller than the torque in the presentsystem with anisotropic exchange, since β/lessmuch1. It should be
noted that although the term “nonadiabatic” for this torqueis standard in the literature, it is somewhat misleading sincethis is a dissipative torque present in the adiabatic limit andnot a nonlocal torque.
12However, we will adhere to the
established convention in what follows and refer to this termas nonadiabatic.The usefulness of this novel anisotropic exchange torque in
applications relies on the resulting domain wall dynamics, inparticular the maximum wall velocity and the occurrence ofWalker breakdown. Here, we address these issues by solvinganalytically the Landau-Lifshitz-Gilbert (LLG) equation in acollective-coordinate framework for the domain wall. The twomain degrees of freedom in this treatment are the velocity ofthe domain wall center ˙Xand the tilt angle φdescribing the
deformation of the domain wall as it propagates. While weconfirm the finding of a considerably lowered characteristiccurrent density proposed in Ref. 10, we find that in contrast
to the conventional case with domain-wall motion drivenby the nonadiabatic spin-transfer torque, the maximum wallvelocity under the influence of an anisotropic exchange torqueis completely independent ofβ.
Deriving analytical expressions both for the maximum
velocity and the Walker breakdown threshold, we demonstratethat the latter also behaves differently from the conventionalnonadiabatic case. For a system with anisotropic exchangeinteraction, the breakdown threshold is proportional to βand
thus decreases as β→0. Finally, we consider the properties
of a new hybrid system where the total spin-transfer torqueacting on the domain wall has a contribution both fromthe conventional dissipative torque and the anisotropic ex-change torque by means of two separate currents. In thiscase, we show that the relative magnitude and direction of thecurrents flowing can be used to tune both the maximum domainwall velocity and the threshold value for Walker breakdown.
Theory . The physical systems under consideration are
shown in Fig. 1. In (a), the textured ferromagnet is electrically
conducting and corresponds to the conventional case ofcurrent-induced domain wall motion. In (b), the ferromagnetis an insulator so that the domain wall motion is inducedexclusively via exchange interaction to the semiconductingquantum well when a current passes through the latter. In (c),the ferromagnet is no longer insulating and separate currentsmay flow in the two layers due to insertion of an electrical
220401-1 1098-0121/2013/87(22)/220401(4) ©2013 American Physical SocietyRAPID COMMUNICATIONS
HENRIK ENOKSEN, ASLE SUDBØ, AND JACOB LINDER PHYSICAL REVIEW B 87, 220401(R) (2013)
(a) (b) (c)
FIG. 1. (Color online) (a) A conducting ferromagnet (FC) with a
N´eel magnetic domain wall. (b) A bilayer consisting of a ferromag-
netic insulator (FI) and a semiconducting quantum well (2DHG). A
N´eel magnetic domain wall makes the ferromagnet textured, and the
magnetic coupling between the two layers is strongly anisotropic.(c) The ferromagnet is again conducting and separated from the
2DHG by an insulating layer (I), allowing for separate currents to flow
in the FC and 2DHG region. Here, 2DHG denotes a two-dimensionalhole gas.
insulator between them. Our starting point is to consider a
N´eel-type domain wall M(x,t) where the easy (hard) axis of
magnetic anisotropy are taken to be along the ˆz(ˆy) direction,13
m(x,t)=[sinθ(x) cosφ(t),sinθ(x)s i nφ(t),σcosθ(x)],
(1)
where σdenotes the topological charge of the domain wall.
Here, we have defined the magnetization unit vector as
m(x,t)=M(x,t)/M 0withM0=|M(x,t)|being the satura-
tion magnetization. The tilt angle φ(t) represents a deformation
mode of the domain wall from its equilibrium configuration,while θ(x) represents the angle between the magnetization
and the easy axis. The domain wall texture in the staticcase is determined by the exchange stiffness and magneticanisotropy axes present in the system. We emphasize that wehave also performed the calculations to be presented for aBloch-type domain wall profile (same easy axis, but hardaxis along the ˆxdirection) and find identical results. This
equivalence between the wall profiles no longer holds in thepresence of spin-orbit interactions.
14–16We do not consider
spin-orbit interactions here, as it is not central to the mainresults. The interactions in our system are taken into accountvia the effective field H
eff:
Heff=2Aex
M0∇2m−H⊥myˆy+Hkmzˆz+Hext. (2)
Here,Aexis the exchange coupling constant, HkandH⊥are
the anisotropy fields for the easy and hard axes, respectively,andH
extis an external magnetic field. The components of
the magnetization vector depend on both space and time
according to cos θ=tanh(x−X(t)
λ),sinθ=sech(x−X(t)
λ).Here,
λ=√2Aex/M 0Hkis the domain wall width and X(t)i st h e
position of the domain wall center. Assuming that the easyaxis anisotropy field H
kis larger than its hard axis equivalent
H⊥, i.e.,|Hk|/greatermuch|H⊥|, the domain wall may be treated as rigid
considering φ(t) as the only relevant deformation mode of the
wall.
To account for the novel anisotropy exchange torque, one
must add an extra term which was derived in Ref. 10to the
LLG equation. The physical setup is as follows: Considerthe exchange interaction between the quantum well and theferromagnetic film in Fig. 1(b). Assuming a p-type hole
gas, the exchange arises from the overlap of wave functionsbetween the holes in the quantum well and the atoms in theferromagnet. The point is now that this exchange interaction
is strongly anisotropic if only the heavy-hole subband is filledand the splitting to the light-hole band exceeds the exchangesplitting J.
17In effect, we are considering an exchange
interaction of the type −JSz(r)mz(r) where Szandmz
are the zcomponents of the spin densities of heavy holes
and the magnetization unit vector, respectively. One finds thatthe full equation which governs the magnetization dynamicsreads
10
∂tm=− ˜γm×Heff+˜αm×∂tm+τQW,
(3)
τQW=vs,QW
βQW(m׈z)(∂xmz).
Here, ˜ γand ˜αare the renormalized gyromagnetic ratio and
Gilbert damping constant, respectively, whereas βQWis the
nonadiabaticity parameter proportional to the spin relaxationtimeτ
−1
QWof itinerant holes in the quantum well. The origin and
value of this parameter is debated in the literature, althoughthere appears to be consensus that spin-relaxation processes(which may be model-dependent) are essential.
12,13,18We have
also introduced the spin velocity vs,QW of the current in the
semiconducting layer, which is proportional to the currentdensity (see below). We will obtain the equations of motion forthe collective coordinates {X,φ}and solve these analytically,
thus obtaining a description of how the domain wall velocityv
DW≡˙Xand the Walker breakdown criterion ˙φ/negationslash=0 depend
on the external parameters of the system, such as the appliedcurrent. The breakdown threshold is the critical current densitywhere the domain wall starts deforming from its original shaperather than simply being translated along the current direction.
The theory up to now has been described with the setup
in Fig. 1(b) in mind. For comparison, we will also consider
the system depicted in Fig. 1(a).
11,19The current flowing
through the textured ferromagnet generates two differenttypes of torque terms compared to the anisotropic exchangemechanism, in the literature often referred to as the adiabaticand nonadiabatic torque. Their combined effect is captured inat e r m τ
FMwhich is added to the right-hand side of Eq. (3):
τFM=vs,FM∂xm−βFMvs,FMm×∂xm. (4)
This torque term is controlled by the spin current vs,FM
flowing in the ferromagnetic conductor, and the nonadiabiticity
parameter βFMis in general different from the one in the
quantum well, βQW. Finally, in Fig. 1(c)we consider a scenario
where both the ferromagnet and quantum well are conductingwith an insulator dividing the two regions and thus permittingtwo separate currents to flow in each layer. In this case, bothτ
QWandτFMshould be considered simultaneously in the LLG
equation.
Results and discussion . For a system where all torque terms
are present, like the one depicted in Fig. 1(c), the equations of
motion for {X,φ}are
σ(1+˜α2)˙˜X=sin 2φ−σ(1+˜αβFM)˜vs,FM+σ˜α˜vs,QW
2βQW,
(5)
(1+˜α2)˙˜φ=− ˜αsin 2φ+σ(˜α−βFM)˜vs,FM+σ˜vs,QW
2βQW.
(6)
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ANOMALOUS DOMAIN WALL VELOCITY AND WALKER ... PHYSICAL REVIEW B 87, 220401(R) (2013)
We will consider the general form for the equations of motion
to begin with, whence we obtain the cases shown in Figs. 1(a)
and 1(b) by setting some parameters equal to zero in the
final result for the domain wall velocity and Walker break-down threshold. Here, we have introduced the dimensionless
parameters˙˜X=∂(X/λ)/∂˜t,˙˜φ=∂φ/∂ ˜t,˜t=(˜γH
⊥/2)t, and
˜v=(2/˜γλH ⊥)v.W eh a v eu s e d vs,FM=(¯h˜γ/2eM 0)Pjwhere
eis the electronic charge, Pis the spin polarization of
the current, and jis the current density. Parameter values
areP=0.7,M0=5×105A/m,Aex=10−11J/m,H⊥=
0.04 T, and Hk=0.4 T. By solving Eq. (6)analytically and
inserting the solution into Eq. (5), we obtain an expression for
the average domain wall velocity:
/angbracketleft˙˜X/angbracketright=−βFM
˜α˜vs,FM+1
2˜αβQW˜vs,QW−sgn( ˜J)
1+˜α2/radicalbig
˜J2−1,
(7)
where ˜J=(1−βFM
˜α)˜vs,FM+1
2˜αβQW˜vs,QW. Details on this pro-
cedure can be found in, e.g., Ref. 20.
As stated above, Walker breakdown occurs when ˙φ/negationslash=0.
From Eq. (6)we obtain, for a constant tilt angle, the result
sin(2φ)=σ/parenleftbigg
1−βFM
˜α/parenrightbigg
˜vs,FM+σ˜vs,QW
2˜αβQW, (8)
which gives the domain wall velocity
/angbracketleft˙˜X/angbracketright=−βFM
˜α˜vs,FM+1
2˜αβQW˜vs,QW. (9)
This is the same as the first two terms in Eq. (7).W es e e
that the domain wall velocity reaches a maximum when thetwo currents flow in opposite directions. However, when theright-hand side of Eq. (8)becomes greater than unity, domain
wall deformation sets in.
Consider first the results for the case shown in Fig. 1(a).
11,19
Setting ˜ vs,QW=0 in the above results, one finds that Walker
breakdown sets in when ˜ vs,FMc=1
1−βFM/˜αand the maximum
domain wall velocity attainable in this setup is /angbracketleft˙˜X/angbracketrightc=
1
|1−˜α/β FM|. We emphasize that both ˜ vs,FMcand/angbracketleft˙˜X/angbracketrightcare
normalized and thus dimensionless quantities, to facilitate
comparison between the different setups in Fig. 1. Importantly,
the normalization constants are independent of ˜ αandβ.T h e
above results show that when ˜ α=βFM, Walker breakdown is
absent and the maximum domain wall velocity has no upperbound; it is simply proportional to the applied current density.In practice, however, these parameters cannot be controlledor tuned in a well-defined manner such that this limit isnot easily obtained. A notable feature is that for large β
FM,
the threshold current is lowered whereas the maximum wallvelocity increases.
With this in mind, we analyze the results for domain
wall dynamics in the anisotropic exchange system Fig. 1(b).
By using Eqs. (7)–(9), we find after some calculations the
following results for Walker breakdown and maximum domainwall velocity:
˜v
s,QWc=2˜αβQW,
(10)
/angbracketleft˙˜X/angbracketrightc=1.We note that, despite the fact that the spin-transfer torque
is increased by as much as four orders of magnitude inthe anisostropic exchange system, due to the coefficient1/β
QW, the maximum domain wall velocity is completely
independent of the value of βQW. This should be compared
to the standard setup in Fig. 1(a), where the wall is driven
by the nonadiabatic spin-transfer torque, yielding a maximumdomain wall velocity strongly dependent on the value of β
FM.
The above result may be understood as a result of competitionbetween the magnitude of the spin-transfer torque and theoccurrence of Walker breakdown. Looking at Eq. (9),i ti s
seen that the domain wall velocity is related to the spin velocity
˜v
s,QWvia a constant of proportionality ∼β−1
QW.A tt h es a m et i m e ,
the critical value of the spin velocity where the domain wallno longer is stable towards deformation is given by ˜ v
s,QWcin
Eq.(10) and is proportional to βQW. As a result, the maximum
domain wall velocity (which occurs right at the critical valuefor ˜v
s,QW) is independent of βQW, since the dependence on
this parameter cancels out when multiplying the domain wallvelocity with the critical spin velocity. Physically, this meansthat although the very large magnitude of the torque givesrise to a rapid increase of wall velocity with current, thesame property of the torque also renders the wall unstabletowards deformation faster than in the conventional case. Thedependence on βfor these two effects is such that they exactly
compensate.
Another qualitatively new aspect of the anisotropic ex-
change case is in the manifestation of Walker break-down. The situation is different from the standard setupin Fig. 1(a). Namely, the critical current where Walker
breakdown takes place now increases withβ
QW. Effectively,
this means that the Walker breakdown threshold decreasesas the spin-transfer torque increases, yet the maximum wallvelocity is unaffected by any change in β
QW.T h i si sa
unique feature of the spin-transfer torque originating withanisotropic exchange. The various domain wall dynamicsis depicted in Fig. 2, comparing the setups in Figs. 1(a)
and1(b).
The domain-wall velocity resulting from τ
QWreaches
appreciable values at much lower current densities comparedto a domain wall driven by τ
FM. At the same time, the
maximum attainable wall velocity is independent of βQW,
while the maximum velocity obtained via τFMcan be very
high for large values of βFM. An intriguing scenario could
be realized if one were to combine these two torques to actsimultaneously on the same domain wall. This can be realizedexperimentally as shown in Fig. 1(c), where two separate
currents flowing in the FM and QW layers control the magni-tude of these torques. Introducing the ratio between the spincurrents in the ferromagnet and the semiconducting quantumwell, i.e., a=v
s,QW/vs,FM, we can express ˜Jfrom Eq. (7)
as
˜J=˜vs,FM/bracketleftbigg/parenleftbigg
1−βFM
˜α/parenrightbigg
b+a
2˜αβQW/bracketrightbigg
, (11)
where bis a parameter which controls the direction of ˜ vs,FM:
b=1(−1) for parallell (antiparallell) flow of the currents.
Note that the currents in the QW and FM region can be set tozero respectively by a=0o rb=0.
220401-3RAPID COMMUNICATIONS
HENRIK ENOKSEN, ASLE SUDBØ, AND JACOB LINDER PHYSICAL REVIEW B 87, 220401(R) (2013)
0 2 4 6 8 10 12
x 10701020304050607080˙X [m/s]
js,FM [A/cm2]
0 0.5 1 1.5 2 2.5
x 10501020304050
js,QW [A/cm2]˙X [m/s]β→0
β=0.01
β=0.02
β=0.04
β=0.1
FIG. 2. (Color online) Average domain wall velocity obtained
for the setups in Fig. 1(a) (corresponding to the top panel) and
(b) (corresponding to the bottom panel), for several choices of β.
We have fixed ˜ α=0.02. Note the difference in order of magnitude
on the xaxes, demonstrating the vastly different current magnitudes
required. For β→0 in the bottom panel, Walker breakdown occurs
almost immediately (not seen) and the increasing domain wallvelocity is above threshold so that the wall is continuously deforming.
The maximum wall velocity prior to Walker breakdown is seen to be
independent of βin the bottom panel [Fig. 1(b)] in contrast to the top
panel [Fig. 1(a)].
Since the Walker breakdown condition is ˜J2>1, we
can now identify the critical spin current velocity and thecorresponding critical domain wall velocity for the setup in
Fig.1(c)where both τQWandτFMare active:
˜vs,FMc=1/parenleftbig
1−βFM
˜α/parenrightbig
b+a
2˜αβQW, (12)
/angbracketleft˙˜X/angbracketrightc=1
1−˜αb
βFMb−a/2βQW. (13)
In this way, one can control both the maximum attainable
domain wall velocity and the occurrence of Walker breakdownby the relative magnitude aand relative sign bof the currents
flowing in the FM and QW layer. It should be kept in mindthat the analysis performed here is for an idealized domain wallsystem without any defects or pinning potentials. Nevertheless,our results demonstrate the qualitatively different role playedby the nonadiabaticity parameter βin the anisotropic exchange
system.
Summary . In summary, we have shown that although the
spin-transfer torque in magnetic systems with anisotropicexchange can be made much larger than the conventionalnonadiabatic torque, due to the former being proportionaltoβ
−1rather than β, the maximum domain wall velocity is
independent ofβin contrast to what one might expect. The
Walker breakdown threshold decreases monotonically withβ, which also differs from the conventional scenario. These
findings are of practical relevance to any application of theproposed giant spin-transfer torque in anisotropic exchangesystems.
Acknowledgments. H.E. acknowledges support from
NTNU. J.L. and A.S. acknowledge support from the ResearchCouncil of Norway through Grants No. 205591/V20 andNo. 216700/F20. A.S. acknowledges useful discussions withF. S. Nogueira.
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220401-4 |
PhysRevB.92.024426.pdf | PHYSICAL REVIEW B 92, 024426 (2015)
Gyrational modes of benzenelike magnetic vortex molecules
Christian F. Adolff,1,*Max H ¨anze,1Matthias Pues,1Markus Weigand,2and Guido Meier1,3,4
1Institut f ¨ur Angewandte Physik und Zentrum f ¨ur Mikrostrukturforschung, Universit ¨at Hamburg, 20355 Hamburg, Germany
2Max-Planck-Institut f ¨ur Intelligente Systeme, Heisenbergstr. 3, 70569 Stuttgart, Germany
3The Hamburg Centre for Ultrafast Imaging, Luruper Chaussee 149, 22761 Hamburg, Germany
4Max Planck Institute for the Structure and Dynamics of Matter, Luruper Chaussee 149, 22761 Hamburg, Germany
(Received 12 February 2015; revised manuscript received 7 July 2015; published 27 July 2015)
With scanning transmission x-ray microscopy we study six magnetostatically coupled vortices arranged in a
ring that resembles a benzene molecule. Each vortex is contained in a ferromagnetic microdisk. When excitingone vortex of the ring molecule with an alternating magnetic high-frequency field, all six vortices performgyrations around the equilibrium center positions in their disks. In a rigid particle model, we derive the dispersionrelation for these modes. In contrast to carbon atoms, magnetic vortices have a core polarization that stronglyinfluences the intervortex coupling. We make use of this state parameter to reprogram the dispersion relation ofthe vortex molecule experimentally by tuning a homogeneous and an alternating polarization pattern. In analogyto the benzene molecule, we observe motions that can be understood in terms of normal modes that are largelydetermined by the symmetry of the system.
DOI: 10.1103/PhysRevB.92.024426 PACS number(s): 75 .70.Kw,02.20.−a,68.37.Yz,75.40.Gb
I. INTRODUCTION
In magnetic nanodisks of suitable geometry, the magne-
tization curls in the plane around the center of the diskand turns out-of-plane in the center. This magnetic ground-state configuration is called magnetic vortex. Dynamically,a gyration of the vortex core around the center of the disk isinherent in magnetic vortices [ 1]. Therefore it can be compared
to a harmonic oscillator [ 2]. The polarization p, i.e., the
out-of-plane direction of the vortex core ( p=±1), determines
the gyration direction. It gyrates anticlockwise for positivepolarization and clockwise for negative polarization. A secondstate parameter, the chirality ( C=±1), describes the sense of
in-plane curling of the magnetization in the disk [ 3,4]. The
gyrotropic mode can be resonantly excited in various ways,using magnetic fields or electric currents [ 5,6]. V ortices in
coupled periodic arrangements feature properties that can bedescribed with common concepts of solid state physics, i.e.,group velocity, density of states, and band structure [ 7–9].
The coupling of vortices strongly depends on their relativepolarizations. Thus arrangements of vortices are expected tofeature a reprogrammable band structure depending on theirpolarization configuration [ 7,10–12]. The molecule benzene
(C
6H6) is a ring of six carbon atoms that each binds a
hydrogen atom. When excited, for example, with infrared light,small vibrations of the atoms with respect to the interatomicdistances emerge. Historically, the comprehension of theso-called normal modes and the relation to their excitationfrequencies was crucial for understanding the infrared andRaman spectra. In this article, we study six magnetostaticallycoupled vortices arranged in a ring that resembles the benzenemolecule. Scanning transmission x-ray microscopy is used todirectly observe the gyrational excitations. We find that inanalogy to the benzene molecule, normal modes explain themeasured dynamics that largely depend on the symmetry of the
*cadolff@physnet.uni-hamburg.desystem. As for the actual benzene molecule, such symmetryconsiderations allow to understand the dynamics in a vividfashion. The normal modes are plane waves with wavelengthsthat are fractions of the circumference of the ring, such asa breathing mode of the molecule. Our approach allows fordeducing the dispersion relation of the vortex molecule in aconvenient way. This will be shown in the last section. Thedispersion relation depends on the tuned polarization states inthe molecule and is measured for two states exemplarily.
II. NORMAL MODES OF VORTEX GYRATION
A convenient and powerful model to describe the motions
of coupled vortices is the Thiele model [ 2,13–15]. It describes
the magnetic vortex as a quasiparticle that is exposed to a
force /vectorF=−/vector∇Ethat acts in the plane of the disk. In our case,
it reads
/parenleftbig
G2
0+D2
0α2
Gilbert/parenrightbig˙/vectorx=G0˜r90/vectorF−D0αGilbert/vectorF. (1)
Here, /vectorxis the two-dimensional position vector of the vortex
core within the disk and ˜r90is a 90◦rotation matrix. Two
components add to the velocity of the vortex core. The firstterm describes the nature of the gyrotropic mode that moves
the vortex perpendicular to the driving force /vectorF. The second
term depends on the dimensionless Gilbert damping parameterα
Gilbert and forces the vortex core back to its equilibrium
position. The constants G0andD0depend on material
parameters [ 2]. It can be challenging to determine the driving
force /vectorFin a coupled system. For a single magnetic vortex, a
harmonic confining potential can be assumed to approximatethe internal forces. A linear energy term is commonly usedto describe the influence of external magnetic fields. Recentapproaches for systems of vortices in coupled arrays employsurface charges that emerge when the vortex is deflected fromthe center of the disk to approximate the coupling mediatedby the stray field [ 11,14–16]. Even when neglecting the
damping, for a number of Ncoupled vortices, the Thiele
equation becomes a 2 N-dimensional system of differential
1098-0121/2015/92(2)/024426(5) 024426-1 ©2015 American Physical SocietyADOLFF, H ¨ANZE, PUES, WEIGAND, AND MEIER PHYSICAL REVIEW B 92, 024426 (2015)
FIG. 1. (Color online) X-ray micrographs of six disks that con-
tain a vortex each. The permalloy disks are 60-nm thick and have
a2 -μm diameter, the minimal distance between the disks is 50 nm.
(a) V ortex molecule with homogeneous core polarizations in all six
disks. The magnetic contrast can be seen in the raw data of one time
frame. The vortex cores appear as black dots. (b) V ortex moleculewith alternating polarizations. The static contrast is subtracted to
emphasize the magnetic contrast even more prominently. Disks and
stripline are colorized. In the captured movie (see Ref. [ 18], movie
1) black vortex cores gyrate clockwise ( p
i=−1) and white cores
counterclockwise ( pi=1).
equations that can only be solved numerically. Following the
ideas of Wigner [ 17], we show that for rings of Ncoupled
magnetic vortices the solution can be deduced exclusivelyby symmetry considerations. Figure 1shows the investigated
vortex molecule consisting of six permalloy (Ni
80Fe20)d i s k s .
A stripline is fabricated on one disk in order to excite
the gyrotropic mode with the unidirectional high-frequencymagnetic field generated by an alternating current sent throughthe stripline. The steady-state motions are directly observed byscanning transmission x-ray microscopy at the MAXYMUSmicroscope of the BESSY II synchrotron in Berlin, Germany.As can be seen in Fig. 1(b), the method provides magnetic
contrast that allows to clearly see the vortex cores as whiteor black dots, corresponding to their polarization. The timeresolution provided by the third generation synchrotron of upto 40 ps allows to trace the vortex trajectories (see Ref. [ 18],
movies 1 and 3). In accordance with our measurements, weassume that the excitation will lead to approximately circularmotions of the N=6 vortices:
/vectorx
i=aiCi/parenleftbigg
cos(ωt+ϕi)
pisin(ωt+ϕi)/parenrightbigg
,i∈{0,1,..., N −1}. (2)
With given chiralities Ciand polarizations piam o t i o no ft h e
molecule is fully determined by the Ngyration amplitudes
aiand phases ϕi. In the experiment, the polarizations and
the chiralities are measured [ 19]. Due to the N-fold rotational
symmetry and the linearity of the system, there has to be a basisofNnormal modes, that fulfill this symmetry. In analogy to
the description of a linear chain of harmonic oscillators withperiodic boundary conditions, we determine these modes tobe plane waves with wavelengths that are fractions of thecircumference of the ring. For a ring of an even number of N
disks, the normal modes /vectorx
i,κare given by
/vectorxi,κ∈{ /vectorxi|ai=aκ,ϕi=ϕi,κ=(κ+pi)iα+φκ}.(3)(a) (b)
FIG. 2. (Color online) (a) Pictograms for the form and the propa-
gation direction of the normal modes of the ring (see Ref. [ 18], movie
2). (b) Experiments with a homogeneous core polarization pattern inthe ring ( p
i=−1). Each graph shows the contribution of a normal
mode to the overall motions in the molecule for different excitation
frequencies. The data points are obtained by a fit to the trajectoriestraced via scanning transmission x-ray microscopy (see Fig. 1and
Ref. [ 18], movie 3). The solid lines are Lorentzian fit curves. The
vertical scale of each graph ranges from 0 to 34 nm /mT.
The integer number κ∈[−N/2,..., N/ 2) indexes the normal
mode and is analogous to the wave number k=2π/λ in a
linear chain of oscillators. The angle α=2π/N corresponds
to the lattice constant in a linear chain. Since a generalvibration of the molecule is given by a linear combinationof the normal modes /vectorx
i=/summationtext
κ/vectorxi,κ, the factor aκdescribes the
contribution of the normal mode /vectorxi,κto the motion. The relative
phases of the normal modes are given by φκ. Figure 2(a)
depicts the form of the normal modes for equal chiralities andpolarizations ( c
i=1,pi=−1) of all vortices. For each point
in time, the vortex cores are located on geometric roulettes,i.e., epitrochoids and hypotrochoids. For wave numbers κwith
|κ|>0, the form of the roulettes stays constant over time and
they rotate around the center of the ring, whilst the vortexcores are always located on the curve (see Ref. [ 18], movie
2). For positive wave numbers κ> 0, the roulettes rotate in
the same direction as the vortices (clockwise). In contrast, fornegative wave numbers, the roulettes rotate anti-clockwise,i.e., against the gyration direction of the vortices. Thus thesign of κdenotes the propagation direction of the waves.
Forκ=0, the normal mode /vectorx
i,0is called the breathing
mode since the vortices lie on a circle that changes its sizeover time. It can be compared to the modes 1 and 2 ofthe actual benzene molecule in the seminal work of Wilson,see Ref. [ 20], when only the vibrations of the carbon atoms
are considered. At the edge of the Brillouin zone κ=±3t h e
024426-2GYRATIONAL MODES OF BENZENELIKE MAGNETIC . . . PHYSICAL REVIEW B 92, 024426 (2015)
waves can be understood as propagating in both directions.
Figure 2(b)shows the experimental results for the investigated
vortex benzene, when the homogeneous polarization patternp
i=−1 is present. The steady-state motions of the vortices
are traced for 24 different frequencies around the resonancefrequency of an isolated disk. The grey line in each of thesix graphs is a Lorentzian fit through the black data pointsthat are proportional to the absolute gyration amplitude |a
κ|
of one normal mode /vectorxi,κ. These data points are obtained by
applying a curve fit with the linear combination of normalmodes given by Eqs. ( 2) and ( 3) to the vortex trajectories of
the six vortices. In order to ensure a linear gyration regime,the amplitude of the excitation is adjusted to small vortextrajectories. The influence of different excitation strengths onthe core velocity is normalized out [ 6,21]. For each frequency,
one global curve fit is performed that comprises the completemotion of the six vortices and thus yields one data point ineach of the six graphs. We point out that each eigenmodehas its maximal contribution at different frequencies that lieon a sinusoidal line (dashed blue). Thus, contrary to the actualbenzene molecule, the propagation of waves in the two possibledirections (sign of κ) is not degenerated. The global rotation
direction of the vortices in the homogeneous polarization casehas no equivalent in the linear vibrations in benzene. Such kindof global gyration direction cannot be defined for an alternatingpolarization pattern since the vortices gyrate in differentdirections according to their polarization p
i. The alternating
polarization pattern is shown in Fig. 1(b) and can be adjusted
when a strong alternating magnetic field with a frequencyof 224 MHz is applied via the stripline and is then reducedadiabatically. Although only one vortex is directly excited, thisprocess of self-organized state-formation [ 16,23,29] allows to
tune the polarizations in the whole molecule. The symmetryof the ring changes due to the alternating polarization patternso that two normal modes /vectorx
i,|κ|=/vectorxi,κ+/vectorxi,−κhave to be
combined in order to get standing waves. The combination ofsuch standing waves is depicted in Fig. 3(a)(see also Ref. [ 18],
movie 4). This time, all modes can be compared to the normalmodes of the actual benzene molecule when only the carbonatoms are regarded. Using the Wilson numbering [ 20], the
normal mode with |κ|=1 corresponds to mode “Y” of the
actual benzene, |κ|=2 corresponds to mode “6a” and |κ|=3
can be compared to normal mode “12.” The arrow pictogramsin Fig. 3(a) are identical to those used by Wilson for the
motions of the actual benzene. This elucidates the strongsimilarity between the actual benzene and vortex benzene.The standing waves are fitted to the trajectories and yield theresults presented in Fig. 3(b) [28].
III. DISPERSION RELATION
Until now, we showed that there are strong similarities
between the very different physical systems of magneticvortices and bound carbon atoms with regard to their motionsduring a harmonic excitation. Both systems feature similarnormal modes that are largely determined by the symmetry ofthe system. In the following, we will show that the symmetryconsiderations can be used to determine the dispersion relationof a ringlike vortex-molecule of arbitrary number of vorticesin a very convenient way.(a) (b)
FIG. 3. (Color online) (a) Pictograms of the composition of the
normal modes to obtain standing waves. (b) Experiments withalternating polarization pattern. Each graph shows the contribution of
a standing wave to the overall motions in the molecule for different
excitation frequencies. The data points are obtained by a fit to thetrajectories traced via scanning transmission x-ray microscopy. The
solid lines correspond to the fit with Eq. ( 10). The vertical scale is
identical to that in Fig. 2.
To calculate the dispersion relation, we temporarily neglect
the damping ( αGilbert=0) in Eq. ( 1). All vortex trajec-
tories are described by the 2 N-dimensional vector /vectoru:=
(/vectorx0,/vectorx1,.../vectorxN−1)Tand each two-dimensional component of it
follows Eq. ( 1). When a normal mode with circular trajectories
/vectoruκ=(/vectorx0,κ,/vectorx1,κ,.../vectorxN−1,κ)Tis inserted, it simplifies to
ωκp/vectoruκ=1
G0(/vectorF0,/vectorF1,...,/vectorFN−1)T. (4)
/vectorFidescribes the sum of all driving forces of vortex i.
Multiplying both sides of the equation with /vectoruκyields
ωκ=1
pG 0/summationtextN−1
i=0/vectorFi/vectorxi,κ/summationtextN−1
i=0/vectorx2
i,κ=1
pG 0/summationtextN−1
i=0/vectorFi/vectorxi,κ
Na2κ.(5)
The driving forces /vectorFiare given by the total energy with respect
to vortex i. We approximate the coupling between two vortices
iandjby the most simple approximation, which is dipolar
stray-field interaction [ 22]:
Edipole ,i,j=μ0
4πr3/parenleftbigg
/vectorμi/vectorμj−3
r2(/vectorμi/vectorr)(/vectorμj/vectorr)/parenrightbigg
. (6)
The dipole moment of a vortex is proportional to the
deflection of the vortex rotated by 90 degrees ( /vectorμi=
˜r90Ci˜aκ/vectorxi,κ|/vectorxi,κ|[26]).
The strength of the dipole moment is denoted as ˜aκsince
it is proportional to the gyration amplitude aκ. For the given
harmonic excitation, the chirality Cihas no influence on the
dipole moment, since the change of sign is compensated by aphase shift of 180
◦in time. The anchor points of the dipoles
are assumed to be fixed at the centers of the disks. Thus, thevector /vectorr, that connects the dipoles, is constant. Separating the
dipolar coupling from all other forces that act on the isolated
024426-3ADOLFF, H ¨ANZE, PUES, WEIGAND, AND MEIER PHYSICAL REVIEW B 92, 024426 (2015)
FIG. 4. (Color online) Experimentally determined dispersion re-
lations for the two polarization patterns and theoretical fit curves
derived from the extended Thiele model. The dashed lines result from
a global curve fit of Eq. ( 10). The data points result from individual
Lorentzian curve fits to the experimental results.
disks yields
ωκ−ω0=−1
pG 01
Na2κN−1/summationdisplay
i=0/summationdisplay
j/negationslash=iEdipole ,i,j. (7)
The resonance frequency ω0applies for noninteracting vortices
in isolated disks. Only considering next-neighbor interactionyields the discrete dispersion relation [ 27]
ω
hom(κ)=ω0−1
2Bhomcos((κ+p)α) (8)
for the homogeneous case. For the alternating polarization
pattern, it is useful to integrate Eq. ( 7) over one period of
gyration to separate ωκ. It then yields
ωalt(κ)=ω0+1
2Baltcos(κα),B alt=3Bhom, (9)
for the alternating polarization pattern. The bandwidth Bhom
is a positive constant given by Bhom=−1
pG 0μ0
4πr3(˜aκ
aκ)2. When
comparing the two analytically calculated dispersion relations
ωaltandωhom, one can see that the factor phas vanished
in the cosine and that the prefactor is multiplied by ( −3).
The different bandwidths are commonly explained by aweaker coupling between vortices of equal polarization thanof vortices with different polarizations [ 24]. For the borderline
case of an infinite linear chain ( N→∞ ), the results are in
concordance with previous results [ 11]. In the following, we
include the effects of damping and the experimental results.For negligible damping, there are sharp resonances when theeigenfrequency of a normal mode is met. In the experiment,the damping allows to excite the system in between thoseresonances. The normal modes mix in the way shown inFig.2(also see Ref. [ 18], movie 3). The contributions a
κ(ωexc)
are fitted to the experimental data with Lorentzian functionsthat are shifted according to the analytically derived discretedispersion relation ω(κ):
a
κ(ωexc)=L/Gamma1(ωexc−ω(κ)),κ∈[−N/2,...,N/2).(10)
This set of equations can be understood as the continuous
dispersion relation of the damped system, where ωexcis
the frequency of the exciting magnetic field and L/Gamma1(ω)t h e
Lorentzian peak function with damping parameter /Gamma1.T h efit yields the three model parameters ω0,Bhom, and/Gamma1.T h e
first two parameters determine the discrete dispersion relationsshown in Fig. 4. The dashed green [blue] curve corresponds
to the dispersion relation ω
alt(κ)[ωhom(κ)] measured for the
alternating [homogeneous] polarization configuration of thevortex molecule. The data points correspond to peaks ofindividual Lorentzian fits as presented in Fig. 2(b).T h e
parameters are determined to be ω
0/2π=(225.5±1.5) MHz
andBalt=(96±6) MHz for the alternating case and ω0/2π=
(227.6±0.8) MHz and Bhom=(31±2) MHz for the homo-
geneous polarization pattern. Those are appropriate valuesfor the bandwidth when considering the low disk interdis-tance [ 30]. In both cases, the damping parameter has a value
of/Gamma1=(29±3) MHz, which is in reasonable accordance
with the relation /Gamma1=2α
Gilbertω≈0.02ωexpected from other
studies [ 32].
IV . CONCLUSION
In conclusion, we have shown that there are strong
similarities between the vibrational modes of benzene and thegyrational modes of a sixfold magnetic-vortex ring molecule.The symmetry of both systems determines the motions ofthe oscillators, i.e., the carbon atoms or the vortices. Thebest accordance in the analogy can be achieved when analternating polarization pattern is tuned to the vortex molecule.In this case, all gyrational modes can be identified withvibrational modes in the actual benzene. The symmetryallows to simplify the derivation of the fundamentally dif-ferent dispersion relations of the vortex molecule for thehomogeneous and alternating core polarization patterns. Incontrast to other models, the presented approach includes theeffect of damping and is characterized by only three modelparameters, each of them determined in the experiments. Bothdispersion relations have been confirmed by x-ray transmissionmicroscopy proving that the magnetic vortex molecule featuresa reprogrammable band structure or dispersion relation.
ACKNOWLEDGMENTS
We thank Ulrich Merkt for fruitful discussions, Benedikt
Schulte for support during the evaluation of the measurements,and Michael V olkmann for superb technical assistance. We ac-knowledge the support of the Max-Planck-Institute for Intelli-gent Systems (formerly MPI for Metals Research), DepartmentSch¨utz and the MAXYMUS team, particularly Michael Bech-
tel and Eberhard Goering. We thank the Helmholtz-ZentrumBerlin (HZB) for the allocation of synchrotron radiationbeamtime. Financial support of the Deutsche Forschungs-gemeinschaft via the Sonderforschungsbereich 668 and theGraduiertenkolleg 1286 is gratefully acknowledged. This workhas been supported by the excellence cluster “The HamburgCentre for Ultrafast Imaging - Structure, Dynamics, andCentre of Matter at the Atomic Scale” of the DeutscheForschungsgemeinschaft.
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024426-5 |
PhysRevB.92.064416.pdf | PHYSICAL REVIEW B 92, 064416 (2015)
Spin-wave dynamics in permalloy/cobalt magnonic crystals in the presence of a nonmagnetic spacer
P. Malag `o,1L. Giovannini,1R. Zivieri,1P. Gruszecki,2and M. Krawczyk2
1Dipartimento di Fisica e Scienze della Terra, Universit `a di Ferrara, Via G. Saragat 1, I-44122 Ferrara, Italy
2Faculty of Physics, Adam Mickiewicz University in Pozna ´n, Umultowska 85, 61-641 Poznan, Poland
(Received 16 April 2015; revised manuscript received 24 July 2015; published 12 August 2015)
In this paper, we theoretically study the influence of a nonmagnetic spacer between ferromagnetic dots and a
ferromagnetic matrix on the frequency dispersion of the spin-wave excitations in two-dimensional bicomponentmagnonic crystals. By means of the dynamical matrix method we investigate structures that are inhomogeneousacross the thickness represented by square arrays of cobalt or permalloy dots in a permalloy matrix. We showthat the introduction of a nonmagnetic spacer significantly modifies the total internal magnetic field, especiallyat the edges of the grooves and dots. This permits the manipulation of the magnonic band structure of spinwaves localized either at the edges of the dots or in matrix material at the edges of the grooves. According to themicromagnetic simulations two types of end modes were found. The corresponding frequencies are significantlyinfluenced by the end modes’ localization region. We also show that, with the use of a single ferromagneticmaterial, it is possible to design a magnonic crystal preserving the properties of bicomponent magnonic crystalsand magnonic antidot lattices. Finally, the influence of the nonmagnetic spacers on the technologically relevantparameters such as group velocity and magnonic bandwidth are discussed.
DOI: 10.1103/PhysRevB.92.064416 PACS number(s): 75 .30.Ds,75.78.−n,75.75.−c
I. INTRODUCTION
Spatial periodicity in a ferromagnetic material modifies the
spin-wave (SW) dispersion relation and results in the formationof magnonic bands and band gaps. Magnetic materials withperiodic modulation are called magnonic crystals (MCs) [ 1–3].
Presently, MCs are getting particular interest due to the possi-bility of tailoring frequency spectra of SWs at the nanoscale;as a consequence, it is possible to understand magnetizationdynamics and (a) to design metamaterial devices [ 4,5], (b) to
transduce and transmit signals [ 6–8], (c) to realize magnonic
transistors [ 9], and (d) to make logic operations [ 10–12].
Among the possible geometries of MCs, the planar MCs
are the most often investigated. This is due to the feasibility offabrication of regular patterns and easy access to characterizemagnetic properties, to measure SW dispersion relation anddynamics in time domain, and to visualize SW excita-tions [ 13,14]. In standard SW transmission measurements
microwave transducers (microstripes or coplanar waveguides)are used. They allow for effective excitation of SWs with longwavelengths. In this limit the magnetostatic interactions areimportant and propagation of SWs in nanostructures is usuallyinvestigated in the direction perpendicular to the externalmagnetic field, i.e., in the Damon-Eshbach (DE) geometry,where even at zero wave number the relatively high groupvelocity is present.
Among planar MCs, the one- and two-dimensional (2D)
MCs, i.e., with periodicity along one and two directions,
respectively, can be distinguished. The three main groups of2D MCs are arrays of dots, antidot lattices, and bicomponentMCs (BMCs). The first consists of regular arrays of thinferromagnetic dots, the second of negative arrays of theformer, i.e., arrays of holes in thin ferromagnetic film.The last group can be regarded as a superposition of both,
i.e., the antidot lattices with holes filled with a different
ferromagnetic material. These three groups present distinctfeatures in the SW propagation. The collective magnetizationdynamics in an array of dots is solely due to dynamic dipolecoupling between resonant excitations of the dots; however,
its properties are also influenced by static demagnetizingeffects [ 15]. In the case of weak coupling (large separation
between dots with respect to their thickness and width), the
magnonic spectra consist of flat bands with frequencies related
to the eigenmode excitations of the isolated dot [ 16]. By
increasing the dynamic dipole coupling, e.g., by decreasingseparation between dots, collective SW excitations with finitebandwidth and preserving properties of the magnetostaticwaves appear. The widening of the bands depends on thedipolar coupling strength and on the stray magnetic field [ 17].
However, the dynamic dipole interaction is effective especially
for eigenmodes having the largest total dynamic magneti-zation (averaged over the whole dot), viz., mainly for thefundamental mode [ 18], but also for end modes or low-order
backwardlike magnetostatic modes [ 19]. In antidot lattices,
the low-frequency part of SW spectra is influenced by theinhomogeneous static demagnetizing field created by the edges
of the holes. The presence of holes leads to the formation of
wells of the total magnetic field where magnetization dynamicsmainly concentrate [ 20,21]. Indeed, in antidot lattices end
modes localized at the edges of the holes and SWs concentratedin channels between holes were found [ 22,23]. These effects
disappeared at sufficiently small lattice constants, wherethe exchange interactions start to prevail over the dipole
interactions. Recently, also, the effect of magnetization pinning
on spin-wave dispersion has been theoretically studied inpermalloy (Py) antidot waveguides by introducing a surfaceanisotropy at the ferromagnetic-air interface [ 24]. Moreover,
it has been shown that structural changes in antidot waveguidesbreaking the mirror symmetry of the waveguide can close bandgaps [ 25].
It is also well known from the literature that the
Dzyaloshinskii-Moriya interaction induces the tilting of themagnetic moments at the edges and leads to the formation ofa noncollinear structure [ 26] acting as a scattering barrier for
spin excitations [ 27] and partly contributes to the formation of
1098-0121/2015/92(6)/064416(10) 064416-1 ©2015 American Physical SocietyP. MALAG `Oet al. PHYSICAL REVIEW B 92, 064416 (2015)
end modes along the barrier. The transition from the quantized
to the propagative regime of SWs (end modes and fundamentalmode) can be controlled, e.g., by the magnetic field orientationor by the separation between holes [ 28–30]. In addition to
the demagnetizing effects, also the shape and size of holesin the antidot lattices influence the SW spectrum. This effectdominates for exchange SWs, i.e., at high frequencies or whenthe lattice constant is small [ 31]. In bicomponent MCs the
inhomogeneous demagnetizing field is still present; however,its amplitude depends on the difference between the magneticproperties of the constituent materials. Thus, its influence onSW dynamics is weaker than in antidot lattices and valuablefor the low-frequency modes only.
Recently, a bicomponent MC composed of Co circular
dots embedded in a Py(Ni
80Fe20) matrix was investigated
theoretically and experimentally [ 14,32–34]. The Brillouin
light scattering (BLS) measurements showed the existenceof two types of SW excitations concentrated in regionsperpendicular to the external magnetic field containing Codots and in Py matrix between the Co dots [ 32]. Theoretical
studies have confirmed that the separation of frequenciesof these SWs is due to a magnetostatic effect [ 33,34] and
the splitting of the magnonic band at the boundary of theBrillouin zone (BZ) is connected to the periodicity of themagnetic system [ 14]. However, the full magnonic band gap
in bicomponent MCs has not yet been investigated in detail.Changes of dot or antidot shape, their rotation with respect tothe crystallographic axes, and imperfections in their shape orat their edges can further modify SW spectra [ 35–37]. Thus,
the large variety of shapes for dots or antidots and of theirarrangements together with magnetic configurations which canbe realized in MCs [ 38–41] makes magnonics an inexhaustible
and intriguing topic of research. More specifically, not enoughattention has been given to the study of collective dynamicsin bicomponent MCs where a nonmagnetic spacer separatesthe two magnetic materials. The aim of this paper is thus totheoretically investigate the effect of a nonmagnetic spacer in2D MCs on the dispersions of the relevant SWs accordingto a micromagnetic approach named the dynamical matrixmethod (DMM). This is done to investigate the importantspin dynamics effects due to the significant spatial variationsexperienced by the total inhomogeneous magnetic field be-cause of the nonmagnetic material at the interface betweenthe two ferromagnetic materials. In this respect, the dynamicsin square lattice 2D MCs with square antidots partially filledwith different magnetic materials are studied, but the obtainedresults can be easily generalized to other geometries. Thisis achieved by putting the nonmagnetic spacer around thedots embedded in antidot lattices. In this study two types ofseparation between dots and Py matrix are considered: (a) withthe nonmagnetic spacer located only below the dot, and (b)with the spacer fully around the dot. It is shown that theseseparations create an inhomogeneous static demagnetizingfield which allows for the formation of end modes in thematrix (characteristic for the antidot lattices) and end modesin the dots (characteristic for the array of dots) which werenot yet found in the previous studies [ 14,34]. Moreover, it is
shown that similar properties can be achieved using a singleferromagnetic material, i.e., in single component 2D MC. Thisstudy focuses on the important part of magnetism devotedto SW phenomena in composite structures, which is almost
unexplored yet in the case of large-scale 2D bicomponentnanopatterned systems. This investigation is also of interest fortechnological applications in the area of magnonics, magneticmemories, and metamaterials.
The paper is organized as follows. In the next section the
structures and the theoretical method used in the investigationsare described. Then, in Sec. III, the results of calculation of
SW spectra showing the influence of nonmagnetic spacers onthe magnonic dispersions are presented. In Sec. IVthe results
obtained are discussed and the influence of the inhomogeneityof the total magnetic field is analyzed. Then, in Sec. V,t h e
effect of the nonmagnetic spacer on the group velocity andmagnonic bandwidth is investigated. Finally, conclusions aredrawn in Sec. IV.
II. STRUCTURE AND METHOD
In order to study the dynamical properties of 2D
MCs connected with the nonmagnetic spacers betweenferromagnetic materials, the dispersion relations of SWs forfive systems have been calculated. The magnetic systems arecomposed of Py, Co, and nonmagnetic material. All geometriesinvestigated here are based on square lattice and squaremagnetic dots, the lattice constant being a=400 nm. MCs
are supposed to be infinite in plane (along xandy). These five
systems are depicted in Fig. 1:( a )System 1 (S1): bicomponent
MC composed of 30-nm-thick Py film with an array of20-nm-deep square grooves of 200 nm size. In the bottom ofthe grooves there is 10 nm of nonmagnetic material and then Codots (20 nm thick) partially immersed into the grooves. The Codots are in direct contact with Py only at the lateral edges of thedot. (b) System 2-Co (S2
Co): bicomponent MC similar to S1 but
with 10-nm-width spacer around the Co dots (200 nm wide).In S2
Co, Co dots and Py matrix are separated by a nonmagnetic
spacer. (c) System 2-Py (S2Py): one-component MC with the
same geometry of S2Cobut with Py dots. (d) MC composed of
square Py dots (10 nm thick and 200 nm wide) surrounded bynonmagnetic spacer and fully immersed in the Py matrix. Thisissystem 3 (S3). (e) An array of squared Co dots (20 nm thick
and 200 nm wide) constitutes system 4 (S4). All parameters
used in the simulations are typical parameters for Py and Comaterials [ 42,43]: saturation magnetization for Py M
S,Py=
750 emu /cm3and for Co, MS,Co=1200 emu /cm3; exchange
constants, APy=1.3×10−6erg/cm and ACo=2.0×
10−6erg/cm; gyromagnetic ratios, γPy/2π=2.96 GHz /kOe
andγCo/2π=3.02 GHz /kOe.
The static and dynamic properties of these magnetic sys-
tems have been investigated by means of two micromagneticcodes: Object Oriented MicroMagnetic Framework (
OOMMF )
code [ 42] and the DMM program [ 34,44]. The ground-state
magnetization was determined by using OOMMF with 2D
periodic boundary conditions; then this magnetic configurationwas used as input to
DMM . The DMM with implemented
boundary conditions, a finite-difference micromagnetic ap-proach first implemented for isolated ferromagnetic elementsand extended to MCs composed by two ferromagnetic mate-rials [ 34], is applied to study the spin dynamic properties in
bicomponent systems where the two ferromagnetic materialsare separated by a nonmagnetic spacer. Since our resultsdo not focus on dissipation properties of collective modes,
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FIG. 1. (Color online) (a) System 1: Top view of the primitive cell and its perpendicular cross section in a bicomponent MC consisting of
Co square dots in square array partially immersed in Py. Nonmagnetic spacer (white area) of 10 nm thickness separates the bottom of Co dots
from Py. (b) System 2-Co: similar to S1 but with full separation of Co dots (200 nm wide) from Py (10 nm of nonmagnetic spacer from the
bottom and lateral sides of Co). (c) System S2-Py: one-component MC with geometry equal to S2Cobut with Py dot. (d) System 3: MC created
by square array of square grooves in Py film partially filled with Py dots. Dots are separated from the matrix by 10-nm-thick nonmagnetic
spacer. (e) System 4: square array of square Co dots. Red dashed lines in the perpendicular cross sections point at the planes ( z=5 and 25 nm)
used in Figs. 2(a)–2(e)to visualize the spatial profiles of SW modes.
the dynamics is studied in the purely conservative regime;
hence no Gilbert damping energy density contribution isincluded in the equations of motion. For our purposes, inthe DMM two indices are used: (1) an index kto label
micromagnetic cells, with k=1,2,..., N , where Nis the
total number of micromagnetic cells in the primitive cell;(2) an index j=Py,Co indicating the ferromagnetic material.
The number of micromagnetic cells assigned to the jth
ferromagnetic material is N
jsuch that NPy+NCo=N.F o r
each micromagnetic cell the magnetization in reduced unitstakes the form m
k=Mk/Ms(k) with Mkthe magnetization in
thekth cell and Ms(k) the saturation magnetization depending
on the ferromagnetic material through the index k.Hence, in a
polar reference frame the magnetization can be written in thefollowing form:
m
k=(sinθkcosφk,sinθksinφk,cosθk), (1)
where φk(θk) is the azimuthal (polar) angle of the magnetiza-
tion; for the sake of simplicity the time dependence is omitted.
The total energy density E=˜E
V—with ˜Ethe energy and V
the volume of the system, respectively—depends on the polarand azimuthal angle in each micromagnetic cell, θ
kandφk.
The total energy ˜Eis the magnetic Hamiltonian and the DMM
was developed to study conservative systems corresponding
to a purely precessional dynamics. In explicit form, for thesystems under study, the energy density reads
E=E
ext+Eexch+Edmg, (2)
withEextthe Zeeman, Eexchthe exchange, and Edmgthe
demagnetizing, respectively. Specifically,
E=−MSH·N/summationdisplay
k=1mk+N/summationdisplay
k=1/summationdisplay
n∈{n.n.}Aexch(k,n)1−mk·mn
a2
kn
+1
2M2
S/summationdisplay
klmk·↔
Nml. (3)The first term of Eq. ( 3) corresponds to the Zeeman
energy density, where Hindicates the external magnetic field.
The second term of Eq. ( 3) is the exchange energy density
expressed by means of two sums: the first sum runs overtheNmicromagnetic cells and is indexed by kwhereas the
second sum indexed by nranges over the nearest-neighbouring
(n.n.) micromagnetic cells of the kth micromagnetic cell that
can belong to a different ferromagnetic material. A
exchis the
exchange stiffness constant and is related to the ferromagneticmaterials through the indices kandn, respectively, while
a
kndenotes the distance between the centers of two adjacent
micromagnetic cells of indices kandn, respectively. When the
kth micromagnetic cell is on one of the edges (vertices) of the
proper primitive cell, the interaction with the micromagneticcells belonging to the correct nearest supercell (primitive cell)must be taken into account. The last term of Eq. ( 3)i st h e
demagnetizing energy density where
↔
Nis the demagnetizing
tensor and expresses the interaction among micromagneticcells within the primitive cell and belonging to differentprimitive cells. Note that, unlike the bicomponent systemstudied [ 34], in S2
Cothe intermaterial exchange contribution
is set equal to zero, because in the primitive cell the Co dot andthe Py matrix are separated. Instead, in the S1, the exchangecontribution at the interface between the two ferromagnetic
materials is set equal to ¯A
Py−Co
exch=(APy+ACo)/2 because Py
matrix and Co dots are in contact. Note that in Eq. ( 2)t h e
thermal contribution related to the thermal field is not included.Indeed, the studied dynamics is purely deterministic and notstochastic. Actually, the equations of motion within the
DMM
correspond to the deterministic Landau-Lifshitz equations andnot to the stochastic Langevin or Fokker-Planck equations [ 45].
The dynamic magnetization δm(r) of each collective mode
fulfills the generalized Bloch theorem depending on the Blochwave vector Kand on the two-dimensional lattice vector of
the periodic system R.For each micromagnetic cell δm(r)
is expressed in polar coordinates depending on the angular
064416-3P. MALAG `Oet al. PHYSICAL REVIEW B 92, 064416 (2015)
deviation from the equilibrium position of the azimuthal
and polar angles δφk,δθk. In a compact form, the complex
generalized Hermitian eigenvalue problem takes the form
Av=λBv, (4)
where the eigenvalue λ=1
ωwithωthe angular frequency of
the given collective mode which is in turn described by theeigenvector v=(δφ
k,δθk). The Hermitian matrix Adepends
on saturation magnetization of the two ferromagnetic materialsand on the corresponding gyromagnetic ratios. The Hessianmatrix B
is expressed in terms of the second derivatives of the
energy density with respect to the azimuthal and polar angulardeviations δφ
kandδθkcalculated at equilibrium. For further
technical details of the DMM applied to several materials see
Ref. [ 34].
The use of the DMM for calculating the spectrum of
collective spin-wave modes is preferred with respect to theFourier analysis of
OOMMF because it has several computa-
tional advantages. Among them, just to mention a few, are(a) the system under study does not need to be excited byany magnetic field pulse; (b) the spin-wave modes frequenciesand eigenvectors of any symmetry are determined by meansa single calculation; (c) the spatial profiles of the spin-wavemodes are directly connected to the calculated eigenvectorsallowing to accurately classify each collective excitation;(d) the spectrum is computed directly in the frequency domain;(e) the mode degeneracy is completely taken into account;(f) the differential scattering cross section associated to eachspin-wave mode can be computed accurately starting from thecorresponding eigenvectors. The size of the micromagneticcells used in the static and dynamic simulations is 5 ×5×
10 nm along x,y, andz, respectively.
In order to investigate the propagation properties of SWs
in MCs, the systems have been studied in the DE geometry,i.e., with the external magnetic field ( H) of magnitude fixed at
2000 Oe parallel to the yaxis and the Bloch wave vector ( k)
parallel to the xaxis.
III. SPIN-WA VE EXCITATIONS IN MCS
In 2D antidot lattices and bicomponent MCs a full
magnonic spectrum is very rich with plenty of SW excita-tions [ 33]. As an example, the differential scattering cross
section computed at the center of the BZ is displayed inFig. 2for S1. It can be seen that there is a large number of
spin-wave modes resulting from the calculation. However, forthe purposes of this study focused on the dispersion behaviorin the first BZ only three modes belonging to the lowest-frequency part of the spectrum, namely, the ones exhibitingan appreciable differential scattering cross section, have beenselected in S1. Nevertheless, note that there are also othercollective modes in the highest-frequency part of the spectrumhaving a non-negligible differential scattering cross section,but in higher BZs. The same conclusions on the differentialscatting cross section can be drawn also for the other systems.The dispersion relations shown in Fig. 3are the ones measured
in a typical BLS experiment [ 32,46].
The dispersion relations of SWs in S1 are shown in
Fig. 3(a). We classify the collective modes by taking into10 12 14 16 18 200.00.10.20.3DE
DEHRIntensity (arb. units)
Frequency (GHz)EM
FIG. 2. Differential scattering cross section calculated for S1 at
the center of the BZ. The arrows label the modes with the highest
scattering cross section in the center of the first BZ investigated in
this paper.
account the region inside the primitive cell where they have
the maximum amplitude. In this respect, we named them(1) end mode of the dot (EM
d) (where the subscript “d”
means dot) mainly localized at the borders of the dots,(2) Damon-Eshbach–like mode in horizontal rows (DE
HR)
where the superscript “HR” means horizontal rows, and(3) Damon-Eshbach-like (DE) mode; they have frequencies9.94, 12.89, and 14.06 GHz, respectively. The modes (2)and (3) are called Damon-Eshbach–like because they exhibitnodal planes parallel to the local static magnetization in thehigher BZs and no nodal planes in the center of the BZ[see Fig. 4(a)]. This is in accordance to the classification of
collective modes given for binary magnonic crystals [ 34]. In
the center of the BZ, the DE
HR, and DE are the resonance
modes called fundamental modes. The DEHRmode is localized
in the horizontal rows containing the square dots (withamplitude concentrated mainly in Py), while the DE modehas the maximum amplitude in Co dots and non-negligibleamplitude in the Py film. We point out that the end mode de-tected here has been previously found only in one-componentMCs [ 47,48].
The appearance of the end mode and the different SW
amplitude distribution between Py and Co of DE and DE
HR
modes marks the difference between the S1 and the Co/Pybicomponent MC investigated in Refs. [ 14,34]. We remark that
these differences with respect to previously studied systemsare mainly due to (a) the 10-nm-thick nonmagnetic spacerbetween Co dots and Py matrix placed at the bottom of thedots, and (b) the dot shape (these effects will be discussedin the next paragraph). Next, we study the effect of a fullseparation of Co dots from Py matrix on magnonic spectra.In Fig. 3(b), the dispersion curves for S2
Coare presented.
By looking at Fig. 3(b) we can see the appearance of two
new modes, i.e., the end mode of Py film (EM f) at 11.9 GHz
(where the subscript “f” means film) localized at the borderof Py film and the backwardlike mode (BA
HR) at 13.86 GHz
mainly concentrated in the horizontal rows. The BAHRmode
has nodal planes perpendicular to the local static magnetization[see Fig. 4(b) for profiles of the modes]. The frequency of the
BA
HRin S2Cois higher than the frequency of DEHR.T h i s
064416-4SPIN-WA VE DYNAMICS IN PERMALLOY/COBALT . . . PHYSICAL REVIEW B 92, 064416 (2015)
0.0 0.5 1.0101214
Wave vector, kx(/a)Frequency (GHz)EM dDEHRDE
0.0 0.5 1.068101214DEHR
EM f
EMdFrequency (GHz)
Wave vector, kx(/a)BAHRDE
0.0 0.5 1.010121416Frequency (GHz)
Wave vector, kx(/a)BAHR
DE
EM dEM fDEHR
0.0 0.5 1.010121416
Wave vector, kx(/a)DEBAHRDEHR
EM fEMdFrequency (GHz)
0.0 0.5 1.048121620Frequency (GHz)
Wave vector, kx(/a)DE
EM(a) S1
(b) S2Co
(c) S2Py
(d) S3
(e) S4
FIG. 3. (Color online) Dispersion relation in the first BZ
along the direction perpendicular to the external magnetic field.(a) Dispersion relation of the most relevant modes in S1: end mode
of the dot (EM
d), Damon-Eshbach–like mode (DE), and DE-like
mode in horizontal rows (DEHR) are shown. (b) Dispersion relation
in S2Co. The additional dispersion relation of the end mode in
Py film (EM f) and backwardlike volume SW (BAHR)a r es h o w n .
(c) Dispersion relation of the most relevant modes in S2Py.
(d) Dispersion relation in S3. (e) Dispersion relation in the array
of Co dots (S4). The black dashed lines in (b)–(d) mark dispersion
relation of DE mode in homogeneous Py film of 10 nm thicknesscalculated according to Ref. [ 49].
EMd
EMfDEHR
BAHR
DE
EMdDEHRDES1
z= 5 nm z= 25 nmS2Co
EMdEMfDEBAHRDEHR
S2Py S3
EMfDE
EMd
BAHR
DEHR
EMDES4
+1.0
0.0
-1.0Amplitude (arb. units)(a) (b)
(c) (d)
(e)z= 5 nm z= 25 nm z= 5 nm z= 25 nmz= 5 nm z= 25 nm
FIG. 4. (Color online) Spatial profiles (real part of the out-of-
plane component of the dynamic magnetization vector) for SWswith large differential scattering cross section in the center of the
Brillouin zone. The spatial profiles of SW modes from the bottom
part of the Py film (in the plane z=5 nm in left column) and in the
plane crossing dots (for z=25 nm in right column) are shown in
3×3 primitive cells, i.e., on the planes marked in Fig. 1with red
dashed lines. (a) Spatial profiles of EM, DE
HR, and DE modes in S1.
(b) Spatial profiles of EM d,E M f,D EHR,B AHR, and DE modes in
S2Co. (c) Spatial profiles of EM d,E M f,D E ,B AHR,a n dD EHRmodes
in S2Py. (d) Spatial profiles of EM f, DE, EM d,B AHR,a n dD EHR
modes in S3. (e) Spatial profiles of EM and DE modes in S4.
might be attributed to the strong localization feature of the
BAHRin the region filled by Co dots having higher values of the
magnetic parameters. By comparing the frequency at the centerof the BZ passing from S1 to S2
Co, we observe a significant
decrease of the EM dfrequency from 9.94 to 5.47 GHz and a
slight increase of the DE (DEHR) frequencies from 14.06 GHz
(12.89 GHz) to 14.67 GHz (13.48 GHz). The presence offive dispersion curves in S2
Cois attributed to the fact that the
differential scattering cross section is comparable for the fiveSW excitations at the BZ center.
In order to study the effect of the Py matrix on the SW
excitation in Co dots, we calculate the dispersion curves of S4[Fig. 1(e)], the array composed of square Co dots. By inspec-
tion of Fig. 3(e)we note that the frequency of the EM
din S4
(3.5 GHz) is about 6 GHz lower than in S1 and 2.5 GHz lower
064416-5P. MALAG `Oet al. PHYSICAL REVIEW B 92, 064416 (2015)
as compared to the corresponding one in S2Co. Instead, the
frequency of the DE mode (18.4 GHz) is 4 GHz higher than theone in S1 and 3.5 GHz higher than the one in S2
Co. Therefore,
the effect of Py matrix is to lower the frequencies of the DEmode and to raise the frequencies of the EM
d. This behavior
can be understood by taking into account the variation of themagnitude of the interdot dipolar dynamic coupling and of thestatic demagnetizing field passing from an array of dots (S4) toMCs (S1 and S2
Co) composed of two ferromagnetic materials.
To study the effect of dot material and thickness in a Py
matrix, we calculate the SW spectra of 2D MCs composed ofPy dots in a Py matrix. It is important to underline that S2
Py
and S3 are neither a bicomponent MC nor antidot lattices, butthese structures preserve properties of both with the use ofa single ferromagnetic material. The kind of mode found inS2
Pyand S3 is similar to the one found in S2Co.I nS 2Py,t h e
EM d(8.92 GHz) is the lowest-frequency mode as in S2Co.I n
S2Pythe EM f(10.46 GHz) has a dispersion curve similar to
that of EM d. The DE mode has a frequency of 12.8 GHz at
the center of the BZ. The frequencies of BAHRmode (13.8
GHz) are lower than the ones of the DEHRmode (14.12 GHz).
We observe that in S2Pythe frequency sequence of DE, DEHR,
and BAHRmodes is different with respect to the one in S1
and S2Co[see Figs. 3(a)and3(b)]. In particular, the DE mode
frequencies are lower than the DEHRmode ones as in the
case of 2D one-component antidot lattices [ 47,48] (for further
discussion see Sec. IV).
In order to understand the effect of the thickness of Py dots
we compute the dispersion curves for S3 shown in Fig. 3(d).I n
S3, the EM f(8.92 GHz) is the lowest-frequency mode of the
spectrum. The EM dfrequency at the center of the BZ (12.84
GHz) is larger than the one of the DE mode (12.36 GHz);however, the corresponding dispersion curves have a similarbehavior. This frequency inversion as compared to S2
Pyis not
surprising because the total magnetic field experienced by the
EM dis higher with respect to the field felt by the DE. The
DEHRand BAHRhave frequencies 14.68 and 14.12 GHz at
the center of the BZ, respectively. Comparing the dispersioncurves in S2
Coand S3, we observe that the order of DE and
DEHRfrequency modes in S3 is interchanged with respect to
the ones in S2Co. Moreover, also the frequency order of the EM f
and the EM dis interchanged with respect to the one in S2Py
and S2Co. This interchange can be attributed to the effect of the
reduction of the dot thickness that induces a lowering of thetotal magnetic field in the Py film where the EM
fis localized.
The intensities of the differential scattering cross section ofthe DE, EM
d,E M f, and BAHRmodes are comparable but are
40% lower than that of DEHR.
In Fig. 4we show the spatial profiles of the real part of the
out-of-plane component of the dynamic magnetization for themain modes at the center of the BZ of the systems studied.The spatial profiles are presented at planes z=5 nm and
z=25 nm, left and right column of each panels, respectively,
along the cross sections indicated in Fig. 1with red dashed
lines. Looking at Fig. 4(a)we can see that the EM
dis strongly
localized at the border of the Co dots and its amplitudedecreases at z=5 nm where only Py is present with respect to
z=25 nm. The presence of the Co dots in S1 induces a strong
DE
HRamplitude decrease inside the region containing the Co
dots: indeed, for z<10 nm the amplitude of the DEHRmodeis uniform in the whole rows, while for 20 nm <z< 30 nm
its amplitude decreases in the Co dots region. By contrast, forthe EM
dthe square Co dots induce an opposite behavior. The
amplitude distribution of the DE mode takes a contributionfrom both Co dots and Py matrix through its whole thickness.The DE is also the mode with largest differential scatteringcross section. Its intensity at k
x=0 is three times larger than
that of the EM dor the DEHRmode (see Fig. 2). Figure 4(b)
displays the spatial profiles of the characteristic SW modesof S2
Co. The presence of the nonmagnetic spacer around
the Co dots induces the appearance of the EM fthat is
strongly localized at the border of the Py matrix close to thenonmagnetic spacer. The amplitude of this mode is almostuniform along the thickness, while that of the EM
ddecreases
by decreasing z.T h eD EHR,B AHR, and DE modes have
uniform amplitude in the region of the Py matrix along thethickness. On the other hand, in the region filled by Co dotstheir amplitude strongly decreases for z>20 nm.
In Fig. 4(c) we show the spatial profiles of the collective
excitations in S2
Py. The amplitude variation of the EM d,D E ,
BAHR, and DEHRmodes as a function of zis the same as that
in S2Co. Moreover, in S2Pythe amplitude of EM fdecreases
by decreasing zfollowing a trend similar to that of the EM d.
The amplitude of SW modes of S3 are illustrated in Fig. 4(d).
Similarly to what occurs in S2Coand S2Py, the SW amplitude
of the DE mode is almost homogeneous across the thicknessof the whole structure and larger in the rows between dots. TheDE
HRand BAHRmodes’ amplitude is almost uniform along
zin the Py matrix but decreases for z>20 nm in the region
filled by Py dots. In Fig. 4(e)are depicted the spatial profiles
of collective modes in S4. In this system there is only Co alongzand the amplitudes of EM and DE mode are uniform along
the thickness.
IV . TOTAL MAGNETIC FIELD ANALYSIS
In order to understand the dispersion curves of the in-
vestigated structures, we calculate the in-plane componentsof the total (effective) magnetic field at different values ofz. The total static magnetic field, which is the sum of the
exchange field, the demagnetizing field, and the Zeeman field,calculated for each micromagnetic cell by the
OOMMF code,
is averaged along the xdirection for different values of z
andy. The behavior of the total magnetic field is strictly
related to the orientation of the static magnetization in themagnetic system. In Fig. 5four regions along the thickness
are taken into account: (a) 0 nm /lessorequalslantz/lessorequalslant10 nm where only Py
is present; (b) 10 nm <z/lessorequalslant20 nm where there are Py and a
nonmagnetic spacer; (c) 20 nm <z/lessorequalslant30 nm where in S1 there
are Py and Co, in S2
Cothere are Py, a nonmagnetic spacer, and
Co, while in S2Pyand S3 there are Py and a nonmagnetic
spacer; (d) 30 nm <z/lessorequalslant40 nm where in S1 and S2Cothere is
Co, and in S2Pythere is Py. In particular, the presence of a
well or a wall in the total magnetic field (see Fig. 5) is due
to the saturation magnetization contrast present at interfacesbetween two different materials. Moreover, in MCs showingmagnetization inhomogeneities across the thickness, the totalmagnetic field at interfaces between two materials, present for10 nm <z< 30 nm, influences also collective excitations in
the homogeneous part of the structure (for 0 nm <z< 10 nm).
064416-6SPIN-WA VE DYNAMICS IN PERMALLOY/COBALT . . . PHYSICAL REVIEW B 92, 064416 (2015)
FIG. 5. (Color online) The ycomponent of the total magnetic
field calculated for (a) S1, (b) S2Co,( c )S 2Py, and (d) S3 along the y
axis and averaged along x, for four different values of z:z=5n m
(in full Py film, black dot-dashed line), z=15 nm (crossing Py and
spacer below the dots, red dashed line), z=25 nm (crossing Py matrix
and middle of dots, green dotted line), and z=35 nm crossing Co
dots (only in S1 and S2Co, blue solid line). The gray vertical rectangles
mark the nonmagnetic spacers which separate the dot from the matrix.
The insets on the top show a sketch of MCs with lines along whichthe total magnetic field is calculated.
The appearance of end modes in MCs is related to the
presence of a strong inhomogeneity of the total field resultingin deep wells close to the border of the dots and the matrix.This feature of the total magnetic field in 2D bicomponentMCs depends on two main factors: the shape of the dotand the contrast between the saturation magnetization of thedifferent materials. In particular, the magnetization saturationcontrast enhanced by the presence of the nonmagnetic spacerleads to the formation of an inhomogeneous demagnetizingfield and, as a consequence, to strong inhomogeneities ofthe total magnetic field at the border between two materials(Co/Py, Co/nonmagnetic spacer, and Py/nonmagnetic spacer).Therefore, the presence of a thin nonmagnetic spacer betweentwo ferromagnetic materials not only influences significantlythe SW spectra but can also be an end mode’s creatingfactor. We underline that this important feature, namely, theappearance of end modes, either as EM
for EM d, does not
depend on the dot shape or on the ferromagnetic materialfor MCs having geometric parameters in the range of theones typical of the recently studied bicomponent systems.Hence, this picture is different from the one occurring inbicomponent systems [ 14,34] where a crucial rule to determine
the appearance of end modes was played by a specificcombination of the magnetization saturation contrast and thedot shape. As an example, in a bicomponent MC composed ofcircular Co (Py) dots in direct contact with a Py (Co) matrix,the end mode is present when |/Delta1M
S|=|MS,Co−MS,Py|>
250 emu /cm3, but disappears when |/Delta1M S|=200 emu /cm3.Instead, if the bicomponent system is composed of square
Co (Py) dots in direct contact with Py (Co) matrix, an endmode is present when |/Delta1M
S|>200 emu /cm3. Therefore,
a thin nonmagnetic spacer between the two ferromagneticcomponents of MCs not only influences significantly the SWspectra but also is an end mode’s creating factor. We underlinethat this important feature, namely, the appearance of endmodes, either as EM
for EM d, does not depend on the dot
shape or on the ferromagnetic material. In the following, wediscuss the shape of the total magnetic field in 2D bicomponentMCs introduced by nonmagnetic spacers around dots and itsrelation to the end modes. Figure 5(a)shows the total magnetic
field calculated for S1 vs yfor different values of z.Two deep
wells are present inside the region of the Co dot above thePy matrix corresponding to z>30 nm. The two wells are
still present for 20 nm <z< 30 nm, although with decreasing
depth. The two wells disappear for z<20 nm; however, the
walls appear in this range. For this reason the EM
dis strongly
localized in the well of the total magnetic field at the border oft h eC od o tf o r z>20 nm and disappears in the homogeneous
part of the system where there is the Py matrix ( z<20 nm)
[see Fig. 4(a)].
In Fig. 5(b) is displayed the total magnetic field calculated
for S2
Coas a function of yfor different values of z.I tc a n
be seen that the positions of the minima of the total magneticfield depend on z. In particular, the total magnetic field has
its minimum value in the Py region for z<20 nm, and in the
Co region for z>20 nm. These two wells close to the border
between Py and the nonmagnetic spacer and the nonmagneticspacer and Co give rise to the two localized modes EM
fand
EM d, respectively. Thus, the presence of these two end modes
is strictly related to the nonmagnetic material that surroundsthe Co dots responsible for the appearance of the two minimain the total magnetic field.
Comparing the profiles of the total field at z=15 nm and
z=25 nm [red dashed and green dotted line in Figs. 5(a)
and5(b)], an increase of the depth of the magnetic wells
can be noted in S2
Cowith respect to the one in S1. This
explains the decrease of the frequency of the EM din S2Co
as compared to the one in S1. Moreover, the wells of the totalfield corresponding to the region filled by the Py matrix close tothe nonmagnetic spacer at z=15 nm, although less deep than
the ones in the Co dot, are deep enough to permit localizationof the EM
f.
By looking at Fig. 5(a)it is also possible to understand that
the variation of the total magnetic field due to the nonmagneticspacer induces a change of DE
HRand DE mode profiles as a
function of z. We observe that the uniform amplitude of DEHR
in the horizontal rows [see Fig. 4(a)] is due to the trend of
the total magnetic field. Indeed, by looking at Fig. 5(a)(black
dot-dashed line), we note that the total magnetic field does notpresent significant inhomogeneities along the ydirection at
z=5 nm. Instead, at z=25 nm the DE
HRmode is localized
only in the Py region [see Fig. 4(a)] and its amplitude vanishes
inside the Co dot. On closer inspection of the correspondingtotal magnetic field [Fig. 5(a), green dotted line] we note the
presence of a high wall at the border between Py and Cothat prevents the spreading of DE
HRinside the Co dot. The
DE mode has higher frequency than DEHRand its amplitude
spreads also in Co dot for z>20 nm. In S2Co, there is an
064416-7P. MALAG `Oet al. PHYSICAL REVIEW B 92, 064416 (2015)
TABLE I. Group velocity vgin the BZ center and bandwidth for EM d,E M f,D E ,a n dD EHRmodes in the MCs investigated in the paper.
The two largest group velocities and bandwidths are emphasized in bold.
S1 S2CoS2PyS3 S4
vg Bandwidth vg Bandwidth vg Bandwidth vg Bandwidth vg Bandwidth
(m/s) (MHz) (m /s) (MHz) (m /s) (MHz) (m /s) (MHz) (m /s) (MHz)
EM d 64 162 48 154 0 21 48 446 40 154
DEHR144 750 368 272 160 1378 160 668 – –
DE 256 355 522 810 256 1097 152 410 68 203
EM f – – 80 226 48 49 48 173 – –
increase of the total magnetic field inhomogeneity as compared
to S1 for each value of z, apart from z>30 nm where there is
a small reduction [see Figs. 5(a) and5(b)]. This results in an
increase of the frequencies of the DE and DEHRmodes.
In Fig. 5(c) we plot the total magnetic field for S2Pyin
order to investigate the effect of the change of the materialfilling the dots. There are two minima of the total magneticfield: The absolute minimum is located in the Py matrix for10 nm <z< 20 nm and the other minimum is placed in the Py
dot for 30 nm <z< 40 nm. In correspondence of the above-
mentioned minima, also in S2
Pythere is the appearance of the
EM dand of the EM f, respectively. By looking at Figs. 5(b)–
5(d), we can note a qualitative similarity of the behavior of
the total magnetic field as a function of yin S2Co,S 2Py, and
S3, respectively. In Fig. 5(d), where the Py dot thickness is 10
nm, the magnetic field well in the dot is less deep than the onein S2
Py, while in the Py matrix it has a significant minimum
(green dotted line, z=25 nm). This explains the interchange
of the frequencies of the EM fand EM dmodes found in S3
with respect to the ones in S2Coand S2Py. Detailed inspection
of the total magnetic field profiles shown in Figs. 5(b)–5(d)
allows us to notice also the relative change of the magneticfield values among S2
Co,S 2Py, and S3 in the channels parallel
to the xaxis containing dots [i.e., area of the DEHRmode,
for 100 nm <y< 300 nm in Fig. 5] and lying between the
dots [i.e., area of the DE mode for 0 nm <y< 90 nm and
310 nm <y< 400 nm]. In the middle part of these areas the
average value of the total magnetic field is almost constantacross the full thickness. In S2
Cothe values of the field are 2.06
and 1.85 kOe in the center of the areas of DE and DEHRmode,
respectively, while in S3 the respective values are 1.82 and2.1 kOe. This behavior of the field can explain the frequencyexchange of the DE and DE
HRmodes between S2Co,S 2Py, and
S3 in Figs. 3(b)–3(d), respectively.
V . FEATURES OF THE DISPERSION RELATION
In order to fully understand the effect of different position
and size of the nonmagnetic spacer on the propagation ofSWs, we compute the group velocity and the bandwidth forthe most relevant modes. The group velocity is important, e.g.,in the transmission measurements with the use of coplanarwaveguide transducers, where SWs with low wave number areusually excited [ 7]. A wide bandwidth is important in order
to accommodate incoming and transmitted signal; moreover,it can be used as an indicator of the interaction strength in the
MC. The group velocity ( v
g) in the DE geometry has been
calculated for selected modes close to the center of the BZ, as
vg=2π/Delta1ν
/Delta1kx, (5)
where /Delta1νis the change of the SW frequency due to the change
of the wave vector along the xaxis,/Delta1kx(in calculations we set
/Delta1kx=0.05π/a). The bandwidth for the selected mode has
been calculated as a change of its frequency between the BZcenter and the BZ border, /Delta1ν
bw=|ν(kx=π/a)−ν(kx=0)|.
The group velocity and the bandwidth of the investigated SWexcitations (EM
d,E M f, DE, and DEHR) are calculated and
collected in Table I.
By looking at Table Iwe can see that for vanishing wave
vector, the DE and DEHRmodes in S2Coexhibit the largest
group velocities. These larger values of vgcan be attributed to
a combination of higher contrast between Co and nonmagneticspacer and Py and nonmagnetic spacer and to a higher Cogyromagnetic ratio. This is an interesting result as S2
Cocan
be regarded as the most disruptive structure with respect toa homogeneous thin film. The DE
HRmodes in S1, S2Py, and
S3 have similar group velocities, while the DE mode of S3has a group velocity smaller than the ones of the DE modesin S1 and S2
Py. The decrease of the group velocity in S3 can
be due to the thickness reduction of the Py dots. These groupvelocities can be compared to that of the DE magnetostaticSW in homogeneous Py film of 10 nm thickness calculatedaccording to Eq. ( 5). In this special case the latter turns out to
be 880 m/s, a value larger than the ones of the systems studiedas expected. The dispersion relation of the DE magnetostaticSW is superimposed in Figs. 3(b)–3(d) with a black dashed
line. We can see that it matches very well with the DE modein S2
Coand the DEHRmodes in S2Pyand S3. This shows that
the DE and DEHRmodes, in S2Co,S 2Py, and S3, respectively,
propagate in a way similar to that of the DE magnetostatic SWin homogeneous Py film and they travel mainly in the lowerpart of the structure where the dots’ influence on the internalfield is smallest; nevertheless, it changes the group velocityand bandwidth.
Comparing the group velocities of DE and DE
HRmodes
of S1, S2Co,S 2Py, S3, and S4 with the one of the DE
magnetostatic SW mode in homogeneous Py film, it can benoted that the presence of two different magnetic materialsand a nonmagnetic spacer reduces the speed of propagation in
064416-8SPIN-WA VE DYNAMICS IN PERMALLOY/COBALT . . . PHYSICAL REVIEW B 92, 064416 (2015)
the BZ center. This is probably due to the presence of different
magnetic material and nonmagnetic spacer that induce the SWconfinement in particular regions of the primitive cell.
The DE and DE
HRmode of S2Pyhave the largest bandwidth.
It is interesting to note that also the end modes with higherfrequency, EM
fand EM din S2Coand S3, have a bandwidth
comparable to that of the propagative DEHRand DE modes.
This means that also the localized modes can propagate inthese kinds of MCs and their properties can be exploited fortransmitting a signal.
VI. CONCLUSIONS
Detailed theoretical investigations of the spin-wave spectra
in two-dimensional bicomponent MCs with the DMM , in order
to identify the influence of a nonmagnetic spacer on the
magnonic band structure, have been performed. Square arrays
of square grooves in thin Py film filled (or partially filled) withCo or Py square dots have been studied. The conclusions drawnfor these kinds of MCs can be generalized to other kinds of 2Dlattices and of different dot shapes in the nanometric range. Thenonmagnetic spacer breaks exchange interactions between themagnetic materials of the matrix and the dot. However, mostimportantly, this nonmagnetic spacer strongly modifies thetotal magnetic field, especially also at the dot edges. Due tothese changes of the magnetic field, two types of end modesappear in the same structure. These are the end mode localizedin the dot and that localized in the matrix. Their frequenciesstrongly depend on the magnetization of the matrix and of thedot material. Moreover, we have shown that, by employinga single material (Py in our case), it is possible to design aMC preserving the main properties of bicomponent MCs andmagnonic antidot lattices.We have also shown that the introduction of a nonmagnetic
spacer and the change of the magnetic dot material allowus to tailor in different ways the SW spectra in MCs. Thisincludes even the interchange of the SW frequency order.This property can be further exploited for modeling themagnonic band structure and magnonic band gaps towardsthe properties desired for practical applications. Moreover, thenonmagnetic spacer breaks the exchange interaction at theborder between the two ferromagnetic materials and allowsthe fabrication of structures where magnetization reversal ofthe dots can take place at magnetic field values differentfrom those causing magnetization reversal in the matrix (dueto different shape or crystalline magnetic anisotropy). Here,there are more possibilities than in one-dimensional (1D)reprogrammable structures [ 50,51], because the anisotropy
axis (and the magnetization) of the dots can be in an obliquedirection with respect to the magnetization of the matrix.
The results of this study are interesting also for the
investigation of the dynamical properties of bicomponent MCscomposed of hard and soft ferromagnetic materials, wherestray magnetic field originating from the dots (made of hardferromagnetic material) influences formation of the domainpattern [ 52] but SW dynamics has not been investigated so far
in such structures.
ACKNOWLEDGMENTS
The research leading to these results has received funding
from Polish National Science Centre Project No. DEC-2-12/07/E/ST3/00538, from the European Union’s Horizon2020 research and innovation programme under the MarieSkłodowska-Curie Grant Agreement No. 644348 (MagIC),and from MIUR-PRIN 2010–11 Project No. 2010ECA8P3“DyNanoMag.”
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064416-10 |
PhysRevB.94.014412.pdf | PHYSICAL REVIEW B 94, 014412 (2016)
Magnon spin transport driven by the magnon chemical potential in a magnetic insulator
L. J. Cornelissen,1,*K. J. H. Peters,2G. E. W. Bauer,3,4R. A. Duine,2,5and B. J. van Wees1
1Physics of Nanodevices, Zernike Institute for Advanced Materials, University of Groningen,
Nijenborgh 4, 9747 AG Groningen, The Netherlands
2Institute for Theoretical Physics and Center for Extreme Matter and Emergent Phenomena, Utrecht University,
Leuvenlaan 4, 3584 CE Utrecht, The Netherlands
3Institute for Materials Research and WPI-AIMR, Tohoku University, Sendai, Japan
4Kavli Institute of NanoScience, Delft University of Technology, Delft, The Netherlands
5Department of Applied Physics, Eindhoven University of Technology, PO Box 513, 5600 MB Eindhoven, The Netherlands
(Received 13 April 2016; published 11 July 2016)
We develop a linear-response transport theory of diffusive spin and heat transport by magnons in magnetic
insulators with metallic contacts. The magnons are described by a position-dependent temperature and chemicalpotential that are governed by diffusion equations with characteristic relaxation lengths. Proceeding from alinearized Boltzmann equation, we derive expressions for length scales and transport coefficients. For yttriumiron garnet (YIG) at room temperature we find that long-range transport is dominated by the magnon chemicalpotential. We compare the model’s results with recent experiments on YIG with Pt contacts [L. J. Cornelissenet al. ,Nat. Phys. 11,1022 (2015 )] and extract a magnon spin conductivity of σ
m=5×105S/m. Our results for
the spin Seebeck coefficient in YIG agree with published experiments. We conclude that the magnon chemicalpotential is an essential ingredient for energy and spin transport in magnetic insulators.
DOI: 10.1103/PhysRevB.94.014412
I. INTRODUCTION
The physics of diffusive magnon transport in magnetic
insulators, first investigated by Sanders and Walton [ 1], has
been a major topic in spin caloritronics since the discoveryof the spin Seebeck effect (SSE) in YIG |Pt bilayers [ 2–4].
This transverse voltage generated in platinum contacts toinsulating ferromagnets under a temperature gradient can beexplained by thermal spin pumping caused by a temperaturedifference between magnons in the ferromagnet and electrons
in the platinum [ 4–7]. The magnons and phonons in the
bulk ferromagnet are considered as two weakly interactingsubsystems, each with their own temperature [ 1]. Hoffman
et al. explained the spin Seebeck effect in terms of the
stochastic Landau-Lifshitz-Gilbert equation with a noise termthat follows the phonon temperature [ 8].
Recently, diffusive magnon spin transport over large dis-
tances has been observed in yttrium iron garnet (YIG) that wasdriven either electrically [ 9,10], thermally [ 9], or optically [ 11].
Notably, our observation of electrically driven magnon spintransport was recently confirmed in a Pt|YIG|Pt trilayergeometry [ 12,13]. Here, we argue that previous theories cannot
explain these observations, and therefore do not capture the
complete physics of magnon transport in magnetic insulators.
We present arguments in favor of a nonequilibrium magnonchemical potential and work out the consequences for theinterpretation of experiments.
Magnons are the elementary excitations of the magnetic
order parameter. Their quantum mechanical creation andannihilation operators fulfill the boson commutation relationsas long as their number is sufficiently small. Just like photonsand phonons, magnons at thermal equilibrium are distributedover energy levels according to Planck’s quantum statistics fora given temperature T. This is a Bose-Einstein distribution
*Corresponding author: l.j.cornelissen@rug.nlwith zero chemical potential because the energy and therefore
magnon number is not conserved. Nevertheless, it is wellestablished that a magnon chemical potential can parametrizea long-living nonequilibrium magnon state. For instance,
parametric excitation of a ferromagnet by microwaves gen-erates high-energy magnons that thermalize much faster bymagnon-conserving exchange interactions than their numberdecays [ 14]. The resulting distribution is very different from a
zero-chemical potential quantum or classical distribution func-tion, but is close to an equilibrium distribution with a certaintemperature and nonzero chemical potential. The breakdownof even such a description is then indicative of the creation ofa Bose (or, in the case of pumping at energies much smallerthan the thermal one, Rayleigh-Jeans [ 15]) condensate. This
new state of matter has indeed been observed [ 16]. Here, we
argue that a magnon chemical potential governs spin and heattransport not only under strong parametric pumping, but also inthe linear response to weak electric or thermal actuation [ 17].
The elementary magnetic electron-hole excitations of nor-
mal metals or spin accumulation have been a very fruitful
concept in spintronics [ 18]. Since electron thermalization is
faster than spin-flip decay, a spin-polarized nonequilibriumstate can be described in terms of two Fermi-Dirac distributionfunctions with different chemical potentials and temperaturesfor the majority and minority spins. We may distinguishthespin (particle) accumulation as the difference between
chemical potentials from the spin heat accumulation as the
difference between the spin temperatures [ 19]. Both are vectors
that are generated by spin injection and governed by diffusionequations with characteristic decay times and lengths. Thespin heat accumulation decays faster than the spin particleaccumulation since both are dissipated by spin-flip scattering,while the latter is inert to energy exchanging electron-electron interactions. Here, we proceed from the premise that
nonequilibrium states of the magnetic order can be described
by a Bose-Einstein distribution function for magnons thatis parametrized by both temperature and chemical potential,
2469-9950/2016/94(1)/014412(16) 014412-1 ©2016 American Physical SocietyCORNELISSEN, PETERS, BAUER, DUINE, AND V AN WEES PHYSICAL REVIEW B 94, 014412 (2016)
where the latter implies magnon number conservation. We
therefore define a magnon heat accumulation δTmas the
difference between the temperature of the magnons and thatof the lattice. The chemical potential μ
mthen represents
themagnon spin accumulation , noting that this definition
differs from that by Zhang and Zhang [ 20], who define a
magnon spin accumulation in terms of the magnon density.The crucial parameters are then the relaxation times governing
the equilibration of δT
mandμm. When the magnon heat accu-
mulation decays faster than the magnon particle accumulation,previous theories for magnonic heat and spin transport shouldbe doubted [ 1,5–7,21]. The relaxation times are governed by
the collision integrals that include inelastic (one-, two-, andthree-magnon scatterings involving phonons) and elastic two-and four-magnon scattering processes. At room temperature,
two-magnon scattering due to disorder is likely to be negligibly
small compared to phonon scattering. Four-magnon scatteringonly redistributes the magnon energies, but does not lead tomomentum or energy loss of the magnon system. Processesthat do not conserve the number of magnons are caused byeither dipole-dipole or spin-orbit interaction with the latticeand should be less important than the magnon-conserving onesfor high-quality magnetic materials such as YIG. At room
temperature, the magnon spin accumulation is then essential
to describe diffusive spin transport in ferromagnets.
Here, we revisit the linear-response transport theory for
magnon spin and heat transport, deriving the spin and heatcurrents in the bulk of the magnetic insulator as well asacross the interface with a normal metal contact. The magnontransport is assumed to be diffusive. Formally we are thenlimited to the regime in which the thermal magnon wavelength/Lambda1and the magnon mean-free path /lscript(the path length over which
magnon momentum is conserved) are smaller than the systemsizeL. The wavelength of magnons in YIG is (in a simple
parabolic band model) a few nanometers at room temperature.Boona et al. [22] find that /lscriptat room temperature is of the
same order. As in electron transport in magnetic multilayers,scattering at rough interfaces is likely to render a diffusivepicture valid even when the formal conditions for diffusive bulktransport are not met. Under the assumptions that magnonsthermalize efficiently and that the mean-free path is dominatedby magnon-conserving scattering by phonons or structural andmagnetic disorder, we find that the magnon chemical potentialis required to harmonize theory and experiments on magnonspin transport [ 9].
This paper is organized as follows: We start with a brief
review of diffusive charge, spin, and heat transport in metalsin Sec. II A. In Sec. II B, we derive the linear-response
expressions for magnon spin and heat currents, starting fromthe Boltzmann equation for the magnon distribution function.We proceed with boundary conditions at the Pt |YIG interface
in Sec. II C. In Sec. II D, we provide estimates for relaxation
lengths and transport coefficients for YIG. The transportequations are analytically solved for a one-dimensional model(longitudinal configuration) in Sec. III A . In Sec. III B ,w e
implement a numerical finite-element model of the experi-mental geometry and we compare results with experiments inSec. III C . We apply our model also to the (longitudinal) spin
Seebeck effect in Sec. III D . A summary and conclusions are
given in Sec. IV.
Generation Absorption
Platinum YIG PlatinumMx yz
jsjsjcinjcoutjm
FIG. 1. Schematic of the 1D geometry [ 13,20]. A charge current
jin
cis sent through the left platinum strip along +y. This generates a
spin current js=jxz=θjin
ctowards the YIG |Pt interface and a spin
accumulation, injecting magnons into the YIG with spin polarizationparallel to the magnetization M. The magnons diffuse towards the
right YIG |Pt interface, where they excite a spin accumulation and
spin current into the contact. Due to the inverse spin Hall effect, thisgenerates a charge current j
out
calong the −ydirection. Note that if M
is aligned along −z, magnons are absorbed at the injector and created
at the detector.
II. THEORY
We first review the diffusion theory for electrical magnon
spin injection and detection as published by one of usin [17,23]. By introducing the magnon chemical potential, this
approach can disentangle spin and heat transport in contrastto earlier treatments based on the magnon density [ 20]o r
magnon temperature [ 1,5–7] only. We initially focus on the
one-dimensional (1D) geometry in Fig. 1with two normal
metal (Pt) contacts to the magnetic insulator YIG. We expressthe spin currents in the bulk of the normal metal contactsand magnetic spacer, and the interface. While Ref. [ 17]
focused on the chemical potential, here we include the magnontemperature as well. At low temperatures, the phonon specificheat has been reported to be an order of magnitude larger thanthe magnon one [ 22]. The room-temperature phonon mean-
free path (that provides an upper bound for the phonon collisiontime) of a few nm [ 22] corresponds to a subpicosecond
transport relaxation time for sound velocities of 10
3–104m/s.
From the outset, we therefore take the phonon heat capacityto be so large and the phonon mean-free path and collisiontimes so short that the phonon distribution is not significantlyaffected by the magnons. The phonon temperature T
pis
assumed to be either a fixed constant or, in the spin Seebeckcase, to have a constant gradient. For simplicity, we alsodisregard the finite thermal (Kapitza) interface heat resistanceof the phonons [ 24].
A. Spin and heat transport in normal metals
There is much evidence that spin transport in metals is
well described by a spin diffusion approximation. Spin-flipdiffusion lengths of the order of nanometers reported in plat-inum betray the existence of large interface contributions [ 25],
but the parametrized theory describes transport well [ 26]. The
charge ( j
c,α), spin ( jαβ), and heat ( jQ,α) current densities in
014412-2MAGNON SPIN TRANSPORT DRIVEN BY THE MAGNON . . . PHYSICAL REVIEW B 94, 014412 (2016)
the normal metals, where the spin polarization is defined in
the coordinate system of Fig. 1,a r eg i v e nb y( s e ee . g .[ 27])
jc,α=σe∂αμe−σeS∂αTe−σSH
2/epsilon1αβγ∂βμγ,
2e
/planckover2pi1jαβ=−σe
2∂αμβ−σSH/epsilon1αβγ∂γμe−σSHSSN/epsilon1αβγ∂γTe,
jQ,α=−κe∂αTe−σeP∂αμe−σSH
2PSN/epsilon1αβγ∂βμγ.(1)
Here, μe,Te, and μαdenote the electrochemical potential,
electron temperature, and spin accumulation, respectively.The subscripts α,β,γ ∈{x,y,z}are Cartesian components
in the coordinate system in Fig. 1,αindicating current
direction and βspin polarization. /epsilon1
αβγ is the Levi-Civita
tensor and the summation convention is assumed throughout.The charge, spin, and heat current densities are measured inunits of A /m
2,J/m2, and W /m2,respectively, while both
the electrochemical potential and the spin accumulation arein volts. The charge and spin Hall conductivities are σ
eand
σSH, both in units of S /m. Thermoelectric effects in metals are
governed by the Seebeck coefficient Sand Peltier coefficient
P=STe. Similarly, we allow for a spin Nernst effect via
the coefficient SSNand the reciprocal spin Ettingshausen
effect governed by PSN=SSNTe. We assume, however, that
spin-orbit coupling is weak enough so that we can ignore spinswapping terms, i.e., terms of the form j
αβ∼∂βμαand their
Onsager reciprocal [ 28]. The spin heat accumulation in the
normal metal and therefore spin polarization of the heat currentare disregarded for simplicity [ 19]./planckover2pi1and−eare Planck’s
constant and the electron charge. The continuity equation∂
tρe+∇·je=0 expresses conservation of the electric charge
density ρe. The electron spin μand heat Qeaccumulations
relax to the lattice at rates /Gamma1sμand/Gamma1QT,respectively:
∂tsβ+1
/planckover2pi1∂αjαβ=− 2/Gamma1sμeμβν, (2)
∂tQe+∇·jQ=−/Gamma1QTCe(Te−Tp), (3)
where the nonequilibrium spin density sβ=2eμβν,Ceis the
electron heat capacity per unit volume, and νthe density of
states at the Fermi level. Inserting Eq. ( 1) leads to the length
scales /lscripts=/radicalbig
σe/(4e2/Gamma1sμν) and/lscriptep=/radicalbig
κe/(/Gamma1QTCe) govern-
ing the decay of the electron spin and heat accumulations,respectively. At room temperature, these are typically /lscript
Pt
s=
1.5n m , /lscriptPt
ep=4.5 nm for platinum [ 21,29], and /lscriptAu
s=35 nm,
/lscriptAu
ep=80 nm for gold [ 21,30].
B. Spin and heat transport in magnetic insulators
Magnonics traditionally focuses on the low-energy, long-
wavelength regime of coherent wave dynamics. In contrast,the basic and yet not-well-tested assumption underlying thepresent theory is diffusive magnon transport, which we believeto be appropriate for elevated temperatures in which short-wavelength magnons dominate. Diffusion should be prevalentwhen the system size is larger than the magnon mean-free pathand magnon thermal wavelength (called magnon coherencelength in [ 5]). Magnons carry angular momentum parallel to
the magnetization ( zaxis). Oscillating transverse components
of the angular momentum can be safely neglected for systemsizes larger than the magnetic exchange length, which is on
the order of 10 nm in YIG at low external magnetic fields [ 8].
Not much is known about the scattering mean-free path, but
extrapolating the results from Ref. [ 22] to room temperature
leads to an estimate of a few nm. Dipolar interactionsaffect mainly the long-wavelength coherent magnons thatdo not contribute significantly at room temperature. Thermalmagnons interact by strong and number-conserving exchangeinteractions. In the Appendix, the magnon-magnon scatteringrate is estimated as ( T/T
c)3kBT//planckover2pi1[31,32] or a scattering time
of 0.1 ps for YIG with Curie temperature Tc∼500 K at room
temperature T=300 K, where T≈Tm≈Tp. According to
the Landau-Lifshitz-Gilbert phenomenology [ 33], the magnon
decay rate is αGkBT//planckover2pi1[32], with Gilbert damping constant
αG≈10−4/lessmuch1 for YIG. Hence, the ratio between the scatter-
ing rates for magnon-nonconserving to -conserving processesisα
G(Tc/T)3/lessmuch1 at room temperature. These numbers justify
the second crucial premise of the present formalism, viz., veryefficient, local equilibration of the magnon system. Since aspin accumulation in general injects angular momentum andheat at different rates, we need at least two parameters for themagnon distribution f, i.e., an effective temperature T
mand
a nonzero chemical potential (or magnon spin accumulation)μ
min the Bose-Einstein distribution function nB:
f(x,/epsilon1)=nB(x,/epsilon1)=/parenleftbig
e/epsilon1−μm(x)
kBTm(x)−1/parenrightbig−1, (4)
where kBis Boltzmann’s constant. Both magnon accumu-
lations Tm−Tpandμmvanish on, in principle, different
length scales during diffusion. Assuming an isotropic (cubic)medium, the magnon spin current ( j
m,i nJ/m2) and heat
current densities ( jQ,m,i nW/m2) in linear response read as
/parenleftBigg2e
/planckover2pi1jm
jQ,m/parenrightBigg
=−/parenleftbigg
σm L/T
/planckover2pi1L/2eκ m/parenrightbigg/parenleftbigg
∇μm
∇Tm/parenrightbigg
, (5)
where μmis measured in volts, σmis the magnon spin
conductivity (in units of S /m),Lis the (bulk) spin Seebeck
coefficient in units of A /m, and κmis the magnonic heat
conductivity in units of Wm−1K−1. Magnon-phonon drag
contributions jm,jQ,m∝∇Tpare assumed to be absorbed in
the transport coefficients since Tm≈Tp. The spin and heat
continuity equations for magnon transport read as
/parenleftBigg∂ρm
∂t+1
/planckover2pi1∇·jm
∂Qm
∂t+∇·jQ,m/parenrightBigg
=−/parenleftbigg
/Gamma1ρμ/Gamma1ρT
/Gamma1Qμ/Gamma1QT/parenrightbigg/parenleftBigg
μm∂ρm
∂μm
Cm(Tm−Tp)/parenrightBigg
,
(6)
in which ρmis the nonequilibrium magnon spin density and
Qmthe magnonic heat accumulation. Cmis the magnon heat
capacity per unit volume. The rates /Gamma1ρμand/Gamma1QTdescribe
relaxation of magnon spin and temperature, respectively. Thecross terms (decay or generation of spins by cooling or heatingof the magnons and vice versa) are governed by the coefficients/Gamma1
ρTand/Gamma1Qμ. Equations ( 5) and ( 6) lead to the diffusion
equations
/parenleftbigg
eα μkB
eαT/kB 1/parenrightbigg/parenleftbigg
∇2μm
∇2Tm/parenrightbigg
=/parenleftBigg
e//lscript2
m kB/(/lscriptρTT2)
e//parenleftbig
kB/lscriptQμμ2
m/parenrightbig
1//lscript2
mp/parenrightBigg/parenleftbigg
μm
Tm−Tp/parenrightbigg
,(7)
014412-3CORNELISSEN, PETERS, BAUER, DUINE, AND V AN WEES PHYSICAL REVIEW B 94, 014412 (2016)
Te
TmTp
μsμmNM FI
lslmleplmp
∆μ∆Tme
jxzM
FIG. 2. Length scales at normal metal |ferromagnetic insulator
(NM|FI) interfaces in Fig. 1. Assuming a constant gradient of the
phonon temperature Tpand disregarding Joule heating, the electron
temperature Teand magnon temperature Tmr e l a xo nl e n g t hs c a l e s /lscriptep
and/lscriptmp. A significant phonon heat (Kapitza) resistance would cause
a step in Tpat the interface. The spin Hall effect in the normal
metal drives a spin current jxztowards the interface, which will
be partially transmitted to the magnon system (causing a nonzeromagnon chemical potential in the FI) and partially reflected back into
the NM (causing a nonzero electron spin accumulation in the NM).
The electron spin accumulation μ
s=μzand the magnon chemical
potential μmrelax on length scales /lscriptsand/lscriptm, respectively.
with four length scales and two dimensionless ratios. Here,
/lscriptm=/radicalBig
σm/(2e/Gamma1ρμ)(∂ρm
∂μm)−1is the magnon spin diffusion
length (or relaxation length of the magnon chemical potential)
and/lscriptmp=/radicalbig
κm/(/Gamma1QTCm) is the magnon-phonon relaxation
length that governs the relaxation of the magnon tempera-ture. The equilibrium values for magnon chemical potentialand magnon temperature are μ
m=0 and Tm=Tp(see
Fig. 2). The length scales /lscriptρT=/radicalbig
kBσm/(2e2/Gamma1ρTCm) and
/lscriptQμ=/radicalBig
eκm/(/planckover2pi1kB/Gamma1Qμ)(∂ρm
∂μm)−1arise from the nondiagonal
cross terms. The dimensionless ratio αμ=eL/(kBσmTp)i s
a measure for the relative ability of chemical-potential andtemperature gradients to drive spin currents. Similarly, α
T=
/planckover2pi1kBL/(2eκm) characterizes the magnon heat current driven
by chemical potential gradients relative to that driven bytemperature gradients.
C. Interfacial spin and heat currents
The electron and magnon diffusion equations are
linked by interface boundary conditions. Spin currents andaccumulations are parallel to the magnetization direction ofthe ferromagnet along the zdirection. We assume that the
exchange coupling dominates the coupling between electronsand magnons across the interface. A perturbative treatmentof the exchange coupling at the interface leads to the spincurrent [ 34,35]
j
int
s=−/planckover2pi1g↑↓
2e2πs/integraldisplay
d/epsilon1D (/epsilon1)(/epsilon1−eμz)
×/bracketleftbigg
nB/parenleftbigg/epsilon1−eμm
kBTm/parenrightbigg
−nB/parenleftbigg/epsilon1−eμz
kBTe/parenrightbigg/bracketrightbigg
, (8)
where g↑↓is the real part of the spin-mixing conductance in
S/m2,s=S/a3the equilibrium spin density of the magnetic
insulator, and S is the total spin in a unit cell with volume a3.
The density of states of magnons D(/epsilon1)=√/epsilon1−/Delta1/(4π2J3/2
s)
for a dispersion /planckover2pi1ωk=Jsk2+/Delta1. The spin-wave gap /Delta1is
governed by the magnetic anisotropy and the applied magneticfield. In soft ferromagnets such as YIG /Delta1∼1 K, which we
disregard in the following since we focus on effects at roomtemperature (see e.g. Ref. [ 8]). The heat current is given by
inserting /epsilon1//planckover2pi1into the integrand of Eq. ( 8).
Linearizing the above equation, we find the spin and heat
currents across the interface [ 17]
/parenleftBigg
j
int
s
jint
Q/parenrightBigg
=3/planckover2pi1g↑↓
4e2πs/Lambda13/parenleftBiggeζ(3/2)5
2kBζ(5/2)
5
2ekBT
/planckover2pi1ζ(5/2)35
4k2
BT
/planckover2pi1ζ(7/2)/parenrightBigg
×/parenleftbigg
μz−μm
Te−Tm/parenrightbigg
. (9)
/Lambda1=√4πJs/(kBT) is the magnon thermal (de Broglie)
wavelength (the factor 4 πis included for convenience).
These expressions agree with those derived from a stochasticmodel [ 5] after correcting numerical factors of the order
of unity. In YIG at room temperature /Lambda1∼1n m .T h et e r m
proportional to μ
zcorresponds to the spin transfer (absorption
of spin current by the fluctuating magnet), while thatproportional to μ
mis the spin pumping contribution (emission
of spin current by the magnet). The prefactor ∼1/(s/Lambda13) can
be understood by noting that s/Lambda13is the effective number of
spins in the magnetic insulator that has to be agitated andappears in the denominator of Eq. ( 9) as a mass term. In the
macrospin approximation, this term would be replaced by thetotal number of spins in the magnet.
From Eq. ( 9) we identify the effective spin conductance
g
sthat governs the transfer of spin across the interface by
the chemical potential difference /Delta1μ=μz−μm. In units of
S/m2,
gs=3ζ/parenleftbig3
2/parenrightbig
2πsg↑↓
/Lambda13. (10)
Using the material parameters for YIG from Table IIand the
expression for the thermal de Broglie wavelength given above,we find g
s=0.06g↑↓at room temperature [ 21,36].gsscales
with temperature like ∼(T/T c)3/2, but it should be kept in mind
that the theory is not valid in the limits T→TcandT→0.
It is nevertheless consistent with the recently reported strongsuppression of g
sat low temperatures [ 10,13].
D. Parameters and length scales
In this section, we present expressions for the transport
parameters derived from the linearized Boltzmann equationfor the magnon distribution function and present numericalestimates based on experimental data.
014412-4MAGNON SPIN TRANSPORT DRIVEN BY THE MAGNON . . . PHYSICAL REVIEW B 94, 014412 (2016)
TABLE I. Transport coefficients and length scales [ 17] as derived in the Appendix.
Symbol Expression
Magnon thermal de Broglie wavelength /Lambda1√4πJs/(kBT)
Magnon spin conductivity σm 4ζ(3/2)2e2Jsτ/(/planckover2pi12/Lambda13)
Magnon heat conductivity κm35
2ζ(7/2)Jsk2
BTτ/(/planckover2pi12/Lambda13)
Bulk spin Seebeck coefficient L 10ζ(5/2)eJskBTτ/(/planckover2pi12/Lambda13)
Magnon thermal velocity vth 2√JskBT//planckover2pi1
Magnon spin diffusion length /lscriptm vth/radicalBig
2
3ττmr
Magnon-phonon relaxation length /lscriptmp vth/radicalBig
2
3τ(1/τmr+1/τmp)−1
Magnon spin-heat relaxation length /lscriptρT /lscriptm/√αμ
Magnon heat-spin relaxation length /lscriptQμ /lscriptm/√αT
αμ5
2ζ(5/2)/ζ(3/2)
αT2
7ζ(5/7)/ζ(7/2)
1. Boltzmann transport theory
Magnon transport as formulated in the previous section
is governed by the transport coefficients σm,L,κm, four
length scales /lscriptm,/lscriptmp,/lscriptρT, and /lscriptQμ, and two dimension-
less numbers αμandαT. In the Appendix, we derive
these parameters using the linearized Boltzmann equationin the relaxation time approximation. We consider fourinteraction events: (i) elastic magnon scattering by bulkimpurities or interface disorder, (ii) magnon dissipation bymagnon-phonon interactions that annihilate or create spinwaves and/or inelastic scattering of magnons by magneticdisorder, (iii) magnon-phonon interactions that conserve thenumber of magnons, and (iv) magnon-magnon scattering bymagnon-conserving exchange scattering processes (see alsoSec. II B).
The magnon energy and momentum-dependent scattering
times for these processes are τ
el,τmr,τmp, andτmm.At elevated
temperatures they should be computed at magnon energyk
BTand momentum /planckover2pi1//Lambda1. Magnon-magnon interactions that
conserve momentum do not directly affect transport currentsin our single magnon band model, so the total relaxation rateis 1/τ=1/τ
el+1/τmr+1/τmp.
The transport coefficients and length scales derived in
the Appendix are summarized in Table I. The Einstein
relation σm=2eDm∂ρm//planckover2pi1∂μmconnects the magnon diffusion
constant Dmdefined by jm=−Dm∇ρmwith the magnon con-
ductivity, where ∂ρm/∂μm=eLi1/2(e−/Delta1/k BT)/(4π/Lambda1J s) and
Lin(z) is the polylogarithmic function of order n.
We observe that the magnon-phonon relaxation length /lscriptmp
is smaller than the magnon spin diffusion length /lscriptmsince the
latter is proportional to τmr, whereas /lscriptmpis limited by both
magnon-conserving and -nonconserving scattering processes.Furthermore, 1 /τ
mrcan be estimated by the Landau-Lifshitz-
Gilbert equation as ∼αGkBT//planckover2pi1[32], where the Gilbert
constant αGat thermal energies is not necessarily the same
as for ferromagnetic resonance.
2. Clean systems
In the limit of a clean system, 1 /τel→0. At sufficiently
low temperatures, the magnon-conserving magnon-phononscattering rate 1 /τ
mp∼T3.5[37] (see also the Appendix)loses against 1 /τmr∼αGkBT//planckover2pi1sinceαGis approximately
temperature independent. Then, all lengths ∼/Lambda1/α G∼10μm
for YIG at room temperature and with αG=10−4from
ferromagnetic resonance (FMR) [ 8]. The agreement with the
observed signal decay [ 9] is likely to be coincidental, however,
since the spin waves at thermal energies have a much shorterlifetime than the Kittel mode for which α
Gis measured. σm
estimated using the FMR Gilbert damping is larger than the
experimental value by several orders of magnitude, which isa strong indication that the clean limit is not appropriate forrealistic devices at room temperature.
3. Estimates for YIG at room temperature
The phonon and magnon inelastic mean-free paths derived
from the experimental heat conductivity appear to be almostidentical at low temperatures up to 20 K [ 22] but could
not be measured at higher temperatures. Both are likelyto be limited by the same scattering mechanism, i.e., themagnon-phonon interaction. We assume here that the magnon-phonon scattering of thermal magnons at room temperatureis dominated by the exchange interaction (which alwaysconserves magnons) rather than the magnetic anisotropy(which may not conserve magnons) [ 38]. Then, τ∼τ
mpand
extrapolating the low-temperature results to room temperatureleads to an /lscript
mpof the order of a nm, in agreement with an
analysis of spin Seebeck [ 6] and Peltier [ 21] experiments. The
associated time scale τmp∼1–0.1 ps is of the same order
asτmmestimated in Sec. II B. On the other hand, τmr∼1n s
fromαG∼10−4and therefore /lscriptm∼vth√τmpτmr∼0.1–1μm.
The observed magnon spin transport signal decays over asomewhat longer length scale ( ∼10μm). Considering that the
estimated τ
mris an upper limit, our crude model apparently
overestimates the scattering. An important conclusion is,nonetheless, that /lscript
m/greatermuch/lscriptmp, which implies that the magnon
chemical potential carries much farther than the magnontemperature.
Withτ∼τ
mp∼0.1–1 ps we can also estimate the magnon
spin conductivity σ∼e2Jsτ//planckover2pi12/Lambda13∼105–106S/m, in rea-
sonable agreement with the value extracted from our experi-ments (see next section).
014412-5CORNELISSEN, PETERS, BAUER, DUINE, AND V AN WEES PHYSICAL REVIEW B 94, 014412 (2016)
III. HETEROSTRUCTURES
Here, we apply the model, introduced and parametrized
in the previous section, to concrete contact geometries andcompare the results with experiments. We start with ananalytical treatment of the one-dimensional geometry, fol-lowed by numerical results for the transverse configurationof top metal contacts on a YIG film with finite thickness.Throughout, we assume, motivated by the estimates presentedin the previous section, that the magnon-phonon relaxationis so efficient that the magnon temperature closely followsthe phonon temperature, i.e., T
m=Tp(only in Sec. III C 3
we study the implications of the opposite case, i.e., Tm/negationslash=Tp
andμm=0). This allows us to focus on the spin diffusion
equation for the chemical potential μm. This approximation
should hold at room temperature, while the opposite regime/lscript
mp/greatermuch/lscriptmmight be relevant at low temperatures or high
magnon densities: when the magnon chemical potential ispinned to the band edge, transport can be described in terms ofthe effective magnon temperature. The intermediate regime/lscript
mp∼/lscriptm, in which both magnon chemical potential and
effective temperature have to be taken into account, is leftfor future study.
A. One-dimensional model
We consider first the one-dimensional geometry shown in
Fig. 1. We focus on strictly linear response and therefore
disregard Joule heating in the metal contacts as well asthermoelectric voltages by the spin Nernst and Ettingshauseneffects. The spin and charge currents in the metal are thengoverned by
/parenleftBigg
j
c
2e
/planckover2pi1js/parenrightBigg
=/parenleftbigg
σe−σSH
−σSH−σe/parenrightbigg/parenleftBigg
∂yμe
1
2∂xμz/parenrightBigg
, (11)
where the charge transport is in the ydirection, spin transport in
thexdirection, and the electron spin accumulation is pointing
in the zdirection. The spin and magnon diffusion equations
reduce to
∂2μs
∂x2=μz
/lscript2s, (12)
∂2μm
∂x2=μm
/lscript2m. (13)
The interface spin currents ( 8) provide the boundary conditions
at the interface to the ferromagnet, while all currents at thevacuum interface vanish. Equations ( 9) and ( 10) lead to the
interface spin current density j
int
s=gs(μint
z−μint
m), where gs
is defined in Eq. ( 10).
1. Current transfer efficiency
The nonlocal resistance Rnlis the voltage over the detector
divided by current in the injector, also referred to as nonlocalspin Hall magnetoresistance (see below). The magnon spininjection and detection can also be expressed in terms ofthe current transfer efficiency η, i.e., the absolute value of
the ratio between the currents in the detector and injectorstrip [ 20] when the detector circuit is shorted. η=R
nl/R0
for identical Pt contacts with resistance R0.I nF i g . 3,w elmlm
FIG. 3. The current transfer efficiency η(nonlocal resistance
normalized by that of the metal contacts) as a function of distance
between the contacts in a Pt |YIG|Pt structure calculated in the 1D
model. Parameters are taken from Table IIand the Pt thickness
t=10 nm. The dashed lines are plots of the functions C1/d(red
dashed line) and C2exp (−d//lscriptm) (blue dashed line) to show the
different modes of signal decay in different regimes: diffusive 1 /d
decay for d</lscript mand exponential decay for d>/lscript m. The constants C1
andC2were chosen to show overlap with ηfor illustrative purposes,
but have no physical meaning.
plot the calculated ηas a function of distance dbetween the
contacts for a Pt thickness t=10 nm and parameters from
Table II.ηdecays algebraically ∝1/dwhend/lessmuch/lscriptm,which
implies diffusion without relaxation, and exponentially ford/greatermuch/lscript
m. The calculated order of magnitude already agrees
with experiments [ 9]. The η/primesi nR e f .[ 20] are three orders
of magnitude larger than ours due to their much weakerrelaxation.
TABLE II. Selected parameters for spin and heat transport in
bilayers with magnetic insulators and metals. a, S, and Jsare adopted
from [ 39],/lscriptsandθfrom [ 21,29], and σeis extracted from electrical
measurements on our devices [ 9]. Note that our values for σeand
/lscriptsare consistent with Elliot-Yafet scattering as the dominant spin
relaxation mechanism in platinum [ 40]. The mixing conductance,
magnon spin diffusion length, and the magnon spin conductivity are
estimated in the main text.
Symbol Value Unit
YIG lattice constant a 12.376 ˚A
Spin quantum number per YIG S 10
unit cell
Spin-wave stiffness constant in YIG Js 8.458×10−40Jm2
YIG magnon spin diffusion length /lscriptm 9.4 μm
YIG spin conductivity σm 5×105S/m
Real part of the spin-mixing g↑↓1.6×1014S/m2
conductance
Platinum conductivity σe 2.0×106S/m
Platinum spin relaxation length /lscripts 1.5n m
Platinum spin Hall angle θ 0.11
014412-6MAGNON SPIN TRANSPORT DRIVEN BY THE MAGNON . . . PHYSICAL REVIEW B 94, 014412 (2016)
FIG. 4. Experimental spin Hall magnetoresistance (SMR) as a
function of platinum strip width. The black squares (left axis) showabsolute resistance changes /Delta1R
SMR divided by the device length
(18μm) in units of /Omega1/m. The red dots (right axis) show the relative
resistivity changes /Delta1ρ/ρ .
The origin of the small ηis the inefficiency of the spin Hall
mediated spin-charge conversion. The ratio between the spin
accumulations in injector and detector ηs=μdet
s/μinj
sis much
larger than ηand discussed in Sec. III C 2 .
2. Spin Hall magnetoresistance
The effective spin conductance gsgoverns the amount of
spin transferred across the interface between the normal metaland the magnetic insulator. While g
scannot be extracted from
measurements directly, it is related to the spin-mixing conduc-tanceg
↑↓via Eq. ( 10). In order to determine g↑↓we measured
the spin Hall magnetoresistance (SMR) [ 41,42] in devices of
Ref. [ 9]. The SMR is defined as the relative resistivity change
in the Pt contact between in-plane magnetization parallel andnormal to the current /Delta1ρ/ρ . The expression for the magnitude
of the SMR reads as [ 43]
/Delta1ρ
ρ=θ2/lscripts
t2/lscriptsg↑↓tanh2t
2/lscripts
σe+2/lscriptsg↑↓cotht
/lscripts, (14)
where t=13.5 nm is the platinum thickness. Figure 4shows
the experimental SMR as a function of platinum strip width.As expected /Delta1ρ/ρ =(2.6±0.09)×10
−4does not depend on
the strip width. Using Eq. ( 14) and the values for /lscripts,θ, and
σeas indicated in Table II, we find g↑↓=(1.6±0.06)×1014
S/m2,which agrees with previous reports [ 29,42,44].
In Chen et al. ’s zero-temperature theory [ 43]t h es p i n
current generated by the spin Hall effect in Pt is perfectlyreflected when spin accumulation and magnetization arecollinear. As discussed above, at finite temperature a fraction ofthe spin current is injected into the ferromagnet in the form ofmagnons. This implies that the SMR should be a monotonouslydecreasing function of temperature. This has been found forhigh temperatures [ 45], but the decrease of the SMR at low
temperatures [ 46] hints at a temperature dependence of other
parameters such as the spin Hall angle.
The current transfer efficiency ηcan be interpreted as a
nonlocal version of the SMR [ 10]. The SMR is caused bythe contrast in spin current absorption of the YIG |Pt interface
when the spin accumulation vector is normal or parallel tothe magnetization M. In the nonlocal geometry, we measure
the voltage in contact 2 that has been induced by a chargecurrent (in the same direction) in contact 1. Since g
s<g↑↓,t h e
relation |/Delta1ρ/ρ|/greaterorequalslantηmust hold even in the absence of losses
in the ferromagnet and detector. This indeed agrees with ourdata.
3. Interface transparency
The analytical expression for ηin the one-dimensional
geometry is lengthy and omitted here, but it can be simplifiedfor special cases. In the limit of a large bulk magnonspin resistance, the interface resistance can be disregarded.The decay of the spin current is then dominated by thebulk spin resistance and relaxation of both materials. Whenσ
m//lscriptm,σe//lscripts/lessmuchgs
η=θ2/lscriptmσeσm
t/bracketleftbig
σ2m+/parenleftbig/lscriptm
/lscripts/parenrightbig2σ2e/bracketrightbigsinh−1d
/lscriptm, (15)
where the Pt thickness is chosen t/greatermuch/lscriptsandθ=σSH/σe
is the spin Hall angle. When d/lessmuch/lscriptmwe are in the purely
diffusive regime with algebraic decay η∝1/d. Exponential
decay with characteristic length /lscriptmtakes over when d/greaterorsimilar/lscriptm.
In our experiments (see Table II)σm∼σeand/lscriptm/greatermuch/lscripts,s o
η=θ2/lscript2
sσm
/lscriptmtσesinh−1d
/lscriptm. (16)
On the other hand, when σm//lscriptm,σe//lscripts/greatermuchgsthe interfaces
dominate and
η=θ2g2
s/lscript2s/lscriptm
tσeσmsinh−1d
/lscriptm, (17)
with identical scaling with respect to d, but a different
prefactor. According to the parameters in Table IIσm//lscriptm/greatermuch
σe//lscripts/greatermuchgs, so spin injection is limited by the interfaces due
to the small spin conductance between YIG and platinum.
B. Two-dimensional geometry
Experiments are carried out for Pt |YIG|Pt with a lateral
(transverse) geometry in which the platinum injector anddetector are deposited on a YIG film. The two-dimensionalmodel sketched in Fig. 5captures this configuration but cannot
be treated analytically. We therefore developed a finite-elementimplementation of our spin diffusion theory by the
COMSOL
MULTIPHYSICS (version 4.3a) software package, extending
the description of spin transport in metallic systems [ 47]t o
magnetic insulators. The finite-element simulations of the spinSeebeck [ 6] and spin Peltier [ 21]e f f e c t si nP t |YIG focused
on heat transport and were based on a magnon temperaturediffusion model. Here, we find that neglecting the magnonchemical potential underestimates spin transport by ordersof magnitude because the magnon temperature equilibratesat a length scale /lscript
mpof a few nanometers and the magnon
heat capacity and heat conductivity are small [ 22]. The
magnon chemical potential and the associated nonequilibriummagnons, on the other hand, diffuse on the much longer lengthscale/lscript
m.
014412-7CORNELISSEN, PETERS, BAUER, DUINE, AND V AN WEES PHYSICAL REVIEW B 94, 014412 (2016)
Detector
YIGInjector
Interface layerμsDetectordrightdleft
tintt
tYIGw w w
xz
y
MInterface layerjzxleftjzxright
Interface layer
FIG. 5. Schematic of the 2D geometry. The relevant dimensions are indicated in the figure. The spin accumulation arising from the charge
current through the injector μsis used as a boundary condition on the YIG |Pt interface. The interface layer is used to account for the effect of
finite spin-mixing conductance between YIG and platinum.
In order to model the experiments in two dimensions, we
assume translational invariance in the third direction, whichis justified by the large aspect ratio of relatively small contactdistances compared with their length. With equal magnon andphonon temperatures everywhere, the magnon transport in twodimensions is governed by
2e
/planckover2pi1jm=−σm∇μm,
∇2μm=μm
/lscript2m, (18)
where ∇=x∂x+z∂z.
The particle spin current js=(jxx,jzx)i nt h em e t a li s
described by
2e
/planckover2pi1js=−σe
2∇μx,
∇2μx=μx
/lscript2s, (19)
where μxis the xcomponent of the electron spin accumu-
lation. The spin-charge coupling via the spin Hall effect isimplemented by the boundary conditions in Sec. III B 2 , while
the inverse spin Hall effect is accounted for in the calculationof the detector voltage (see Sec. III B 5 ). The estimates at the
end of the previous section justify disregarding temperatureeffects.
1. Geometry
In order to accurately model the experiments, we define two
detectors (left and right) and a central injector, introducing thedistances d
leftanddrightas in Fig. 5. We generate a short- (A)
and a long-distance (B) geometry. The injector and detectorsare slightly different as summarized in Table III.T h eY I Gfi l m
thicknesses are 200 nm for (A) and 210 nm for (B). The YIGfilm is chosen to be long compared to the spin diffusion length(w
YIG=150μm) in order to prevent finite-size artifacts.
TABLE III. Properties of geometry sets A and B.
Pt width Pt thickness Distances
w(nm) t(nm) d(μm)
Geometry A 140 13 .50 .2–5
Geometry B 300 7 2–42 .52. Boundary conditions
Sending a charge current density jcin the +ydirection
through the platinum injector strip generates a spin accumula-tionμ
sat the YIG |platinum interface by the spin Hall effect
(shown in Fig. 5). This is captured by Eq. ( 1) that predicts a
spin accumulation at the Pt side of the interface of [ 21]
μs≡μx|interface =2θjc/lscripts
σetanh/parenleftbiggt
2/lscripts/parenrightbigg
, (20)
which is used for the interface boundary condition of the
magnon diffusion equation. Here, we assume that the contactwith the YIG does not significantly affect the spin accumu-lation [ 43], which is allowed for the collinear configuration
since g
s<σe//lscripts. The spin orientation of μspoints along
−x, parallel to the YIG magnetization. A charge current
I=100μA generates spin accumulations in the injector
contact of μA
s=8.7μV and μB
s=7.7μV for geometries
A and B, respectively.
The uncovered YIG surface is subject to a zero current
boundary condition ( ∇·n)μs=0, where nis the surface
normal.
3. YIG |Pt interface
The interface spin conductance gsis modeled by a thin
interface layer, leading to a spin current jint
s=−σint
s∂μx/∂z,
with spin conductivity σint
s=gstint. When the interface thick-
nesstintis small compared to the platinum thickness tPtwe
can accurately model the Pt |YIG interface without having
to change the COMSOL code. Varying the auxiliary interface
layer thickness between 0 .5<t int<2.5 nm, the spin currents
change by only 0 .1%. This is expected because the increased
interface layer thickness is compensated by the reducedresistivity of the interface material such that the resistanceremains constant. In the following, we adopt t
int=1.0n m .
Finally, with Eq. ( 10)gs=0.06g↑↓andg↑↓from
Sec. III A 2 we get gs=9.6×1012S/m2.
4. Magnon chemical potential profile
A representative computed magnon chemical potential map
is shown in Fig. 6(a), while different profiles along the three
indicated cuts are plotted in Figs. 6(b)–6(d). The magnon
chemical potential along xand at z=− 1 nm (i.e., 1 nm
below the surface of the YIG) in Fig. 6(b) is characterized by
the spin injection by the center electrode. Globally, μmdecays
exponentially with distance from the injector on the scale of /lscriptm.
014412-8MAGNON SPIN TRANSPORT DRIVEN BY THE MAGNON . . . PHYSICAL REVIEW B 94, 014412 (2016)
μm (μV)
059
1234678
−15 −10 −5 0 5 10 1502468
x (μm)μm (μV)Linecut along x
−200 −100 00510
z (nm)μm (μV)Injector linecut
−200 −100 00123
z (nm)μm (μV)Left detector linecut(a)
(b)
(d) (c)x (nm)00 04 002- 002 004-z (nm)
-200015213
FIG. 6. (a) Two-dimensional magnon chemical potential distribu-
tion for geometry (A) with dleft=200 nm and dright=300 nm. The
lines numbered 1, 2, 3 indicate the locations of the profiles plotted
in figures (b), (c), (d), respectively. In (b) we observe a maximumμ
mforx=0, i.e., under the injector, followed by a sharp decrease
close to the detectors located at x=− 200 and 300 nm because the Pt
contacts are efficient (but not ideal) spin sinks. On the outer sides ofthe detectors μ
mpartially recovers with distance and finally decays
exponentially on the length scale /lscriptm.
We also observe that the left and right detector contacts at x=
−200 nm and 300 nm, respectively, act as sinks that visibly
suppress but do not quench the magnon accumulation. Thefinite mixing conductance and therefore magnon absorptionare also evident from the profiles along zin Figs. 6(c) and6(d):the magnon chemical potential changes abruptly across the
YIG|Pt interface by the relatively large interface resistance
g
−1
s. The magnon chemical potential is much smaller than the
magnon gap ( ∼1 K). We are therefore far from the threshold
for current-driven instabilities such as magnon condensationand/or self-oscillations of the magnetization [ 32].
5. Detector contact and nonlocal resistance
The spin current density in the detectors is governed by the
spin accumulation according to
/angbracketleftjzx/angbracketright=−σe
2A/integraldisplay
A∂μx
∂zdA/prime, (21)
which is an average over the detector area A=wt.T h e
observable nonlocal resistance Rnl(normalized to device
length) in units of /Omega1/m,
Rnl=θ/angbracketleftjzx/angbracketright
σeI, (22)
is compared with experiments in the next section.
C. Comparison with experiments
1. Two-dimensional model
Figure 7compares the simulations as described in the
previous section with our experiments [ 9]. Figure 7(a) is a
linear plot for closely spaced Pt contacts while Fig. 7(b) shows
the results for all contact distances on a logarithmic scale. Themagnon spin conductivity σ
mand the magnon spin diffusion
length /lscriptmare adjustable parameters; all others are listed in
Table II. We adopted σm=5×105S/m and /lscriptm=9.4μma s
the best fit values that agree with the estimates in Ref. [ 9] and
Sec. II D.
At large contact separations in geometry (B), the signal
is more sensitive to the bulk parameters /lscriptmandσmthan
the interface gs. When contacts are close to each other, the
interfaces become more important and the results dependsensitively on g
sandσmas compared to /lscriptm. For very close
contacts ( d< 500 nm) the total spin resistance of YIG is
dominated by the interface and our model calculations slightly
(b) (a)
FIG. 7. (a) Computed nonlocal first harmonic signal as a function of distance on a linear scale. The red open circles show the results for
sample (A), while black open squares represent sample (B). The blue triangles are the experimental results [ 9]. The red dashed line is a 1 /dfit
of the numerical results for (A). (b) Same as (a) but on a logarithmic scale.
014412-9CORNELISSEN, PETERS, BAUER, DUINE, AND V AN WEES PHYSICAL REVIEW B 94, 014412 (2016)
RintsRintsRYIGs
μsinjμsdet
RPts(a)
(b)10−310−210−110010110210−610−510−410−310−210−1100
Distance ( μm)μsdet / μsinjExperimental data
Fit from Ref. 9
Circuit model
(no relaxation)
RPts
FIG. 8. (a) Experimental and simulated spin transfer efficiency
ηs=μdet
s/μinj
s. The blue solid line is a fit by the 1D spin diffusion
model [ 9]. Since here interfaces are disregarded, μdet
s→μinj
sfor
vanishing contact distances. The red dashed line is obtained fromthe equivalent circuit model in (b) with spin resistances R
s
Xdefined
in the text. This model includes gsbut is valid for d</lscript monly since
spin relaxation is disregarded. The interfaces lead to a saturation ofη
sat short distances.
underestimate the experimental signal and, in contrast to
experiments, deviate from the ∼d−1fit that might indicate
an underestimated gs.However, a larger gswould lead to
deviations at intermediate distances (1 <d< 5μm).
2. Spin transfer efficiency and equivalent circuit model
The spin transfer efficiency ηs=μdet
s/μinj
s, i.e., the ratio
between the spin accumulation in the injector and that inthe detector, can be readily derived from the experiments byEq. ( 20). From the voltage generated in the detector by the
inverse spin Hall effect V
ISHE [48]
μdet
s=2t
θL1+e−2t//lscripts
(1−e−t//lscripts)2VISHE, (23)
where lis the length of the metal contact. The spin transfer
efficiency therefore reads as
ηs=t
/lscriptsθ2Rnl
Rdet(et//lscripts+1)(e2t//lscripts+1)
(et//lscripts−1)3, (24)
where Rnl=VISHE/Iis the observed nonlocal resistance and
Rdetthe detector resistance. Figure 8(a) shows the experimental
data converted to the spin transfer efficiency as a function ofdistance dthat is fitted to a 1D magnon spin diffusion model
that does not include the interfaces [ 9]. When d→0 and
interfaces are disregarded, η
sdiverges. This artifact can be
repaired by the equivalent spin-resistor circuit in Fig. 8(b)according to which
ηs=Rs
Pt
Rs
YIG+2Rs
int+2RPts, (25)
where Rs
Pt=/lscripts/[σeAinttanh(t//lscripts)] is the spin resistance of
the platinum strip [ 48],Rs
int=1/(gsAint) is interface spin
resistance, and Rs
YIG=d/(σmAYIG) is the magnonic spin
resistance of YIG. AYIG=ltYIGis the cross section of the YIG
channel and Aint=wlis the area of the Pt |YIG interfaces. The
parameters in Table IIlead to the red dashed line in Fig. 8(a),
which agrees well with the experimental data for d</lscript m.N o
free parameters were used in this model since we adoptedσ
m=5×105S/m as extracted from our 2D model in the
previous section.
The model predicts that the spin transfer efficiency should
saturate for d/lessorsimilar100 nm for gs=9.6×1012S/m2. A pre-
dicted onset of saturation at 200 nm is not confirmed by theexperiments, which as pointed out already in the previoussection, could imply a larger g
s. Experiments on samples
with even closer contacts are difficult but desirable. Basedon the available data, we predict that the efficiency saturatesatη
s=4×10−3. The charge transfer efficiency (defined in
Sec. III A 1 ) would be maximized at η≈5×10−5, which
is still below the SMR /Delta1ρ/ρ =2.6×10−4, as predicted in
Sec. III A 2 .
3. Magnon temperature model
We can analyze the experiments also in terms of magnon
temperature diffusion [ 1] as applied to the spin Seebeck [ 5,6]
and spin Peltier [ 21] effects. Communication between the
platinum injector and detector is possible via phonon andmagnon heat transport: the spin accumulation at the injectorcan heat or cool the magnon/phonon system by the spin Peltiereffect. The diffusive heat current generates a voltage at thedetector by the spin Seebeck effect. However, pure phononicheat transport does not stroke with the exponential scaling,but decays only logarithmically (see below). The magnontemperature model (which describes the magnons in termsof their temperature only) can give an exponential scaling,but in order to agree with experiments, the magnon-phononrelaxation length must be large such that T
m/negationslash=Tpover large
distances. This is at odds with the analysis by Schreier et al.
and Flipse et al. However, we can test this model by, for the
sake of argument, increasing this length scale by four ordersof magnitude to /lscript
mp=9.4μm and completely disregard the
magnon chemical potential. The spin Peltier heat current Qinj
SPE
is then [ 21]
Qinj
SPE=LsTμinj
s
2Aint, (26)
where Lsis the interface spin Seebeck coefficient, Ls=
2g↑↓γ/planckover2pi1kB/(eMs/Lambda13)[5,6,21], and Ms=μBS/a3is the sat-
uration magnetization of YIG. The equivalent circuit is basedon the spin Peltier heat current and the spin thermal resistancesof the YIG |Pt interfaces and the YIG channel. This allows us
to find T
m−e, the temperature difference between magnons and
electrons at the detector interface, which is the driving forcefor the SSE in this model. The equivalent thermal resistancecircuit is shown in Fig. 9(b). Relaxation is disregarded, so
014412-10MAGNON SPIN TRANSPORT DRIVEN BY THE MAGNON . . . PHYSICAL REVIEW B 94, 014412 (2016)
RintthRintthRYIGth QSPEinj(a)
(b)
Tm-e10−310−210−110010110210−710−610−510−410−310−210−1
Distance ( μm)μsdet / μsinj
Experimental data
κm=1e−2 W/(mK)
κm=1e−1 W/(mK)
κm=1 W/(mK)
FIG. 9. (a) Results of the thermal model for κm=10−2W/(mK)
(red curve), κm=10−1W/(mK) (green curve), and κm=1W/(mK)
(black curve). Plotted on the yaxis is the spin transfer efficiency
resulting from the thermal model ηth=μdet
s/μinjs. The blue squares
represent the experimental data. (b) The equivalent thermal resistance
model. The definitions of the thermal resistances used in the model
are given in the main text. At the thermal grounds in the circuit,the temperature difference between magnons and electrons ( T
m−e)i s
zero.
the model is only valid for d</lscript mp. The interface magnetic
heat resistance is given by Rth
int=1/(κI
sAint), with κI
sequal
to [5,6,21]
κI
s=h
e2kBT
/planckover2pi1μBkBg↑↓
πMs/Lambda13, (27)
and where μBis the Bohr magneton. The YIG heat resistance
Rth
YIG=d/(κmAYIG) and from the thermal circuit model we
find that Tm−e=Qinj
SPE(Rth
int)2/(Rth
int+Rth
YIG), which generates
a spin accumulation in the detector by the spin Seebeck effect
μdet
s=Tm−eg↑↓γ/planckover2pi1kB
πMs/Lambda134π
e/lscripts
σtanh/parenleftbiggt
2/lscripts/parenrightbigg1+e−2t//lscripts
(1−e−t//lscripts)2.(28)
The thus obtained spin transfer efficiency ηthis plotted in
Fig. 9(a) as a function of the magnon spin conductivity
κm.F o rκm∼0.1–1 W /(mK) reasonable agreement with the
experimental data can be achieved. While Schreier et al.
argued that κmshould be in the range 10−2–10−3W/(mK)),
κmfrom Table Iis also of the order of 1 W /(mK) at
room temperature. Hence, the magnon temperature modelcan describe the nonlocal experiments, provided that themagnon-phonon relaxation length /lscript
mpis large. However, from
the expression for /lscriptmpthat we gave in Table Iwe find that
/lscriptmp∼10μm corresponds to τmp≈τmr∼1 ns and κm∼104
W/(mK), which is at least three orders of magnitude larger
than even the total YIG heat conductivity, and is clearlyunrealistic. Thus, requiring /lscriptmp∼10μm while maintaining
κm∼1W/(mK) is inconsistent. Also, an /lscriptmpof the order of
nanometers as reported by Schreier et al. and Flipse et al. is
difficult to reconcile with the observed length scale of the orderof 10μm.
Up to now, we disregarded phononic heat transport. As
argued, the interaction of phonons with magnons in the spinchannel is weak, but the energy transfer can be efficient.The spin Peltier effect at the contact generates a magnonheat current that decays on the length scale /lscript
mp, heating up
the phonons that subsequently diffuse to the detector, wherethey cause a spin Seebeck effect. The magnon system is inequilibrium except at distances from injector and detector onthe scale /lscript
mpthat we argued to be short. In this scenario, there
is no nonlocal magnon transport in the bulk at all, but injectorand detector communicate by pure phonon heat transport.However, this mechanism does not explain the exponentialdecay of the nonlocal signal: the diffusive heat current emittedby a line source, taking into account that the gadoliniumgallium garnet (GGG) substrate has a heat conductivity closeto that of YIG [ 6], decays only logarithmically as a function
of distance.
D. Longitudinal spin Seebeck effect
The spin Seebeck effect is usually measured in the longi-
tudinal configuration, i.e., samples with a YIG film grownon GGG and a Pt top contact. Longitudinal spin Seebeckmeasurements are hence local measurements, as opposed tothe nonlocal experiments we have discussed in the precedingsections. However, in the longitudinal configuration our one-dimensional model [ 17] is still applicable. A recent study
extracted the length scale of the longitudinal spin Seebeckeffect from experiments on samples with various YIG filmthicknesses [ 49]. A length of the order of 1 μm was found.
Similar results were obtained by Kikkawa et al. [50].
We assume a constant gradient ( T
L−TR)/d < 0,where
TL,TRare the temperatures at the interfaces of YIG to GGG,
platinum, respectively, with Tmeverywhere equilibrized to Tp,
and disregard the Kapitza heat resistance [cf. Fig. 10(a) ]. At
the YIG |GGG interface the spin current vanishes. Figure 10
illustrates the magnon chemical potential profile on the YIGthickness das well as the transparency of the Pt |YIG interface
for four limiting cases, i.e., for opaque ( g
s<σm//lscriptm) and
transparent ( gs>σm//lscriptm) interfaces and a thick ( d>/lscript m) and
at h i n( d</lscript m) YIG film, in which analytic results can be
derived.
We define a spin Seebeck coefficient as the normalized
inverse spin Hall voltage VISHE/tyin the platinum film of
length tydivided by the temperature gradient /Delta1T/d, with
/Delta1T=TL−TRand average temperature T0:
σSSE=dVISHE
ty/Delta1T. (29)
Assuming that the Pt spin diffusion length /lscriptsis much shorter
than its film thickness t, we find the analytic expression
σSSE=gs/lscripts/lscriptmLθ/bracketleftbig
coshd
/lscriptm−1/bracketrightbig
tσeT0/bracketleftbig
gs/lscriptmcoshd
/lscriptm+σm/parenleftbig
1+2gs/lscripts
σe/parenrightbig
sinhd
/lscriptm/bracketrightbig.(30)
014412-11CORNELISSEN, PETERS, BAUER, DUINE, AND V AN WEES PHYSICAL REVIEW B 94, 014412 (2016)
d > lm
YIG PtChemical potential μmd < lm
0
GGGYIG Pt
GGG
YIG PtChemical potential μm
0GGGYIG PtGGG0
0Opaque Transparent(b) (a)
(d) (c)TR
TL
FIG. 10. Magnon chemical potential μmunder the spin Seebeck
effect for a linear temperature gradient in YIG, in the limit of (a)an opaque interface and thick YIG, (b) an opaque interface and thin
YIG, (c) a transparent interface and thick YIG, and (d) a transparent
interface and thin YIG. In all four cases, μ
mchanges sign somewhere
in the YIG. For higher interface transparency (larger gs), the zero
crossing shifts closer to the Pt |YIG interface.
In Fig. 11,σSSE is plotted as a function of the relative
thickness d//lscriptmof the magnetic insulator in the transport
direction, Pt thickness of t=10 nm and T0=300 K. We
adopt Lfrom Table Iand a relaxation time τ∼τmp∼0.1
ps and the parameters from Fig. 11. The normalized spin
Seebeck coefficient saturates as a function of don the scale
of the magnon spin diffusion length /lscriptm. While experiments at
T0/lessorequalslant250 K report somewhat smaller length scales than our
/lscriptm,our saturation σSSE∼0.1–1μV/K is of the same order as
the experiments [ 51].
In the limit of an opaque interface, σSSEsaturates to
σSSE(d/greatermuch/lscriptm)=gs/lscripts/lscriptmLθ
tT0σeσm=/parenleftbigggs/lscripts
σe/parenrightbigg/parenleftbigg/lscriptm
t/parenrightbiggαμθkB
e,(31)
in terms of the dimensionless ratio αμfrom Eq. ( 7).
02468 1 00.000.050.100.150.200.250.300.35
dlmΣSSEΜVK
FIG. 11. Normalized spin Seebeck coefficient as a function of the
thickness of the magnetic insulator in the direction of the temperaturegradient. Parameters taken are from Table II, together with a Pt
thickness of t=10 nm and temperature of 300 K. The value for
the bulk spin Seebeck coefficient Lis taken from the expression in
Table Iwithτ=0.1p s .For a transparent interface with /lscriptm/greatermuch/lscriptsandσm∼σe,t h e
result is governed by bulk parameters only:
σSSE(d→∞ )=/lscriptsLθ
tT0σe. (32)
This model for the spin Seebeck effect is oversimplified
by assuming a vanishing magnon-phonon relaxation lengthand disregarding interface heat resistances. The gradient inthe phonon temperature can give rise to a spin Seebeckvoltage [ 52] even when bulk magnon spin transport is frozen
out by a large magnetic field. Nevertheless, it is remarkablethat it gives a reasonable qualitative description for the spinSeebeck effect with input parameters adapted for electricallydriven magnon transport. We conclude that also in thedescription of the spin Seebeck effect the magnon chemicalpotential can play a crucial role.
IV . CONCLUSIONS
We presented a diffusion theory for magnon spin and
heat transport in magnetic insulators actuated by metalliccontacts. In contrast to previous models, we focus on themagnon chemical potential. This is an essential ingredientbecause under ambient conditions /lscript
m>/lscript mp, i.e., the magnon
chemical potential relaxes over much larger length scalesthan the magnon temperature. We compare theoretical resultsfor electrical magnon injection and detection with nonlocaltransport experiments on YIG |Pt structures [ 9], for both a 1D
analytical and a 2D finite-element model.
In the 1D model, we study the relevance of interface versus
bulk-limited transport and find that, for the materials andconditions considered, the interface spin resistance dominates.For the limiting cases of transparent and opaque interfaces,the spin transfer efficiency ηdecays algebraically ∝1/das
a function of injector-detector distance dwhen d</lscript
m, and
exponentially with a characteristic length /lscriptmford>/lscript m.
A 2D finite-element model for the actual sample configura-
tions can be fitted well to the experiments for different contactdistances, leading to a magnon conductivity σ
m=5×105
S/m and diffusion length /lscriptm=9.4μm.
The experiments measure first- and second-order har-
monic signals that are attributed to electrical magnon spininjection/detection and thermal generation of magnons byJoule heating with spin Seebeck effect detection, respectively.Here, we focus on the linear response that we argue tobe dominated by the diffusion of a magnon accumulationgoverned by the chemical potential, rather than the magnontemperature. However, we applied our theory also to thestandard longitudinal (local) spin Seebeck geometry. We findthe same length scale /lscript
mand a (normalized) spin Seebeck
coefficient of σSSE∼0.1–1μV/Kf o r d/greatermuch/lscriptm,which is of
the same order of magnitude as the observations [ 49].
ACKNOWLEDGMENTS
We would like to acknowledge H. M. de Roosz and
J. G. Holstein for technical assistance, and Y . Tserkovnyak,A. Brataas, S. Bender, J. Xiao, and B. Flebus for discussions.This work is part of the research program of the Foundationfor Fundamental Research on Matter (FOM) and supported
014412-12MAGNON SPIN TRANSPORT DRIVEN BY THE MAGNON . . . PHYSICAL REVIEW B 94, 014412 (2016)
by NanoLab NL, EU FP7 ICT Grant No. 612759 InSpin,
Grant-in-Aid for Scientific Research (Grants No. 25247056,No. 25220910, and No. 26103006) and the Zernike Institutefor Advanced Materials. R.D. is a member of the D-ITPconsortium, a program of the Netherlands Organization forScientific Research (NWO) that is funded by the DutchMinistry of Education, Culture, and Science (OCW).
APPENDIX: BOLTZMANN TRANSPORT THEORY
Here, we derive our magnon transport theory from the
linearized Boltzmann equation in the relaxation time ap-proximation, thereby introducing and estimating the differentcollision times.
1. Boltzmann equation
Equations ( 5)–(7) are based on the Boltzmann equation for
the magnon distribution function f(x,k,t):
∂f
∂t+∂f
∂x·∂ωk
∂k=/Gamma1in[f]−/Gamma1out[f], (A1)
where /Gamma1in=/Gamma1in
el+/Gamma1in
mr+/Gamma1in
mp+/Gamma1in
mm and/Gamma1out=/Gamma1out
el+
/Gamma1out
mr+/Gamma1out
mp+/Gamma1out
mmare the total rates of scattering into and
out of a magnon state with wave vector k, respectively.
The subscripts refer to elastic magnon scattering at defects,magnon relaxation by magnon-phonon interactions that do notconserve magnon number, magnon-conserving inelastic andelastic magnon-phonon interactions, and magnon number andenergy-conserving magnon-magnon interactions. We discussthem in the following for an isotropic magnetic insulator andin the limit of small magnon and phonon numbers.
The elastic magnon scattering is given by Fermi’s golden
rule as
/Gamma1
out
el=2π
/planckover2pi1/summationdisplay
k/prime/vextendsingle/vextendsingleVel
kk/prime/vextendsingle/vextendsingle2δ(/planckover2pi1ωk−/planckover2pi1ωk/prime)f(k,t), (A2)
where Vel
kk/primeis the matrix element for scattering by defects
and rough boundaries [ 23,37] of a magnon with momentum
/planckover2pi1kto one with /planckover2pi1k/primeat the same energy. /Gamma1in
elis obtained
from this expression by interchanging kandk/prime.I nt h e
presence of the in-scattering term (vertex correction) /Gamma1in
el,
the Boltzmann equation is an integrodifferential rather thana simple differential equation.
Gilbert damping parametrizes the magnon dissipation into
the phonon bath. According to the linearized Landau-Lifshitz-Gilbert equation [ 32]
/Gamma1
out
mr=2αGωkf(k,t). (A3)
Since the phonons are assumed to be at thermal equilibrium
with temperature Tp,/Gamma1in
mris obtained by substituting f(k,t)→
nB(/planckover2pi1ωk/kBTp)i n/Gamma1out
mr.
Magnon-conserving magnon-phonon interactions with ma-
trix elements Vmp
kk/primeqgenerate the out-scattering rate
/Gamma1out
mp=2π
/planckover2pi1/summationdisplay
k/prime,q/vextendsingle/vextendsingleVmp
kk/primeq/vextendsingle/vextendsingle2δ(/planckover2pi1ωk−/planckover2pi1ωk/prime−/epsilon1q)
×f(k,t)[(1+f(k/prime,t)]/bracketleftbigg
1+nB/parenleftbigg/epsilon1q
kBTp/parenrightbigg/bracketrightbigg
, (A4)where /epsilon1q=/planckover2pi1c|q|is the acoustic phonon dispersion with sound
velocity cand momentum q.The “in” scattering rate
/Gamma1in
mp=2π
/planckover2pi1/summationdisplay
k/prime,q/vextendsingle/vextendsingleVmp
kk/primeq/vextendsingle/vextendsingle2δ(/planckover2pi1ωk−/planckover2pi1ωk/prime−/epsilon1q)
×f(k/prime,t)[(1+f(k,t)]nB/parenleftbigg/epsilon1q
kBTp/parenrightbigg
. (A5)
Finally, the four-magnon interactions (two magnons in, two
magnons out) generate
/Gamma1out
mm=2π
/planckover2pi1/summationdisplay
k/prime,k/prime/prime,k/prime/prime/prime/vextendsingle/vextendsingleVmm
k+k/prime,k−k/prime,k/prime/prime−k/prime/prime/prime/vextendsingle/vextendsingle2
×δ(/planckover2pi1ωk+/planckover2pi1ωk/prime−/planckover2pi1ωk/prime/prime−/planckover2pi1ωk/prime/prime/prime)δ(k+k/prime−k/prime/prime−k/prime/prime/prime)
×f(k,t)f(k/prime,t)[1+f(k/prime/prime,t)][1+f(k/prime/prime/prime,t)], (A6)
while /Gamma1in
mmfollows by exchanging kk/prime/prime, and k/primeandk/prime/prime/prime.
Disregarding umklapp scattering, the magnon-magnon inter-actions conserve linear and angular momentum. V
mmtherefore
depends only on the center-of-mass momentum and the relativemagnon momenta before and after the collision, which impliesthat/Gamma1
mmdoes not affect transport directly (analogous to the
role of electron-electron interactions in electric conduction).
The collision rates govern the energy and
momentum-dependent collision times τa(k,/planckover2pi1ω) (with
a∈{el,mr,mp,mm}). These are defined from the “out” rates
via
1
τa(k,/planckover2pi1ω)=/Gamma1out
a
f(k,t), (A7)
replacing f→nB(/planckover2pi1ωk/kBTp) and /planckover2pi1ωkwith /planckover2pi1ωwhere
phonons are involved. Here, we are interested mainly in
thermal magnons for which the relevant collision times are
evaluated at energy /planckover2pi1ω=kBTand momentum k=/Lambda1−1.
Then, 1 /τmr∼αGkBT//planckover2pi1. Elastic magnon scattering can be
parametrized by a mean-free path /lscriptel=τel(k,/planckover2pi1ω)∂ωk/∂k, and
therefore 1 /τel(k,/planckover2pi1ω)=2/lscript−1
el√Jsω//planckover2pi1orτel=/lscriptel/vm, where
vm=2√Jsω//planckover2pi1is the magnon group velocity. Estimates for
/lscriptelrange from 1 μm[23] under the assumption that /lscriptelis due to
Gilbert damping and disorder only, to 500 μm[37]. Therefore,
τel∼10–105ps. Since we deduce in the main text that at room
temperature τmpis one to two orders of magnitude smaller than
thisτel, we completely disregard elastic two-magnon scattering
in the comparison with experiments.
We adopt the relaxation time approximation in which the
scattering terms read as
/Gamma1[f]=1
τel/bracketleftbigg
f−nB/parenleftbigg/planckover2pi1ωk−μm
kBTm/parenrightbigg/bracketrightbigg
+1
τmr/bracketleftbigg
f−nB/parenleftbigg/planckover2pi1ωk
kBTp/parenrightbigg/bracketrightbigg
+1
τmp/bracketleftbigg
f−nB/parenleftbigg/planckover2pi1ωk−μm
kBTp/parenrightbigg/bracketrightbigg
+1
τmm/bracketleftbigg
f−nB/parenleftbigg/planckover2pi1ωk−μm
kBTm/parenrightbigg/bracketrightbigg
. (A8)
The distribution functions here are chosen such that the
elastic scattering processes stop when fapproaches the Bose-
Einstein distribution with local chemical potential μm/negationslash=0,
014412-13CORNELISSEN, PETERS, BAUER, DUINE, AND V AN WEES PHYSICAL REVIEW B 94, 014412 (2016)
in contrast to the inelastic scattering that causes relaxation to
thermal equilibrium with the lattice and μm=0.Similarly, the
temperatures TpvsTmare chosen to express that the scattering
exchanges energy with the phonons or keeps it in the magnonsystem, respectively.
The Boltzmann equation may be linearized in terms of
the small perturbations, i.e., the gradients of temperature andchemical potential. The local momentum space shift δfof the
magnon distribution function
δf(x,k)=τ∂n
B/parenleftbig/planckover2pi1ωk
kBTp/parenrightbig
∂/planckover2pi1ωk∂ωk
∂k·/parenleftbigg
∇xμm+/planckover2pi1ωk∇xTm
Tp/parenrightbigg
,
(A9)
where 1 /τ=1/τmr+1/τmp. The magnon spin and heat
currents [Eq. ( 5)] are obtained by substituting δfinto
jm=/planckover2pi1/integraldisplaydk
(2π)3δf(k)∂ωk
∂k, (A10)
jQ,m=/integraldisplaydk
(2π)3δf(k)/planckover2pi1ωk∂ωk
∂k. (A11)
The magnon spin and heat diffusion [Eq. ( 6)] are obtained
by a momentum integral of the Boltzmann equation ( A8)a f t e r
multiplying by /planckover2pi1and/planckover2pi1ωk, respectively. The local distribution
function in the collision terms consists of the sum of the“drift” term δfand the Bose-Einstein distribution with local
temperature and chemical potential
f(k,t)=δf+n
B([/planckover2pi1ωk−μm(x)]/[kBTm(x)]). (A12)We reiterate that the relatively efficient magnon conserving τm
limits the energy, but not (directly) the spin diffusion.
2. Magnon-magnon scattering rate
The four-magnon scattering rate is believed to efficiently
thermalize the local magnon distribution to the Bose-Einsteinform [ 31,32]. At room temperature, the leading-order correc-
tion to the exchange interaction in the presence of magnetiza-tion textures reads as
H
xc=−Js
2s/integraldisplay
dxs(x)·∇2s(x), (A13)
where s(x)(s=|s|=S/a3) is the spin density. By the
Holstein-Primakoff transformation, the spin-lowering op-
erator reads as ˆs−=sx−isy=/radicalbig
2s−ˆψ†ˆψˆψ/similarequal√
2sˆψ−
ˆψ†ˆψˆψ/2√
2sin terms of the bosonic creation ( ˆψ†) and
annihilation ( ˆψ) operators. Hxccan be approximated as a
four-particle pointlike interaction term
Hmm≈g/integraldisplay
dxˆψ†ˆψ†ˆψˆψ, (A14)
where g∼kBT/s is the exchange interaction strength at
thermal energies. Using Fermi’s golden rule for this interactionyields collision terms as Eq. ( A6) with V
mm≈g:
1
τmm(k,/planckover2pi1ω)≈g2
/planckover2pi1/summationdisplay
k/prime,k/prime/prime,k/prime/prime/primeδ(/planckover2pi1ωk+/planckover2pi1ωk/prime−/planckover2pi1ωk/prime/prime−/planckover2pi1ωk/prime/prime/prime)δ(k+k/prime−k/prime/prime−k/prime/prime/prime)×nB/parenleftbigg/planckover2pi1ωk/prime
kBTp/parenrightbigg
×/bracketleftbigg
1+nB/parenleftbigg/planckover2pi1ωk/prime/prime
kBTp/parenrightbigg/bracketrightbigg/bracketleftbigg
1+nB/parenleftbigg/planckover2pi1ωk/prime/prime/prime
kBTp/parenrightbigg/bracketrightbigg
. (A15)
The momentum integrals can be estimated for thermal
magnons with k=/Lambda1−1and/planckover2pi1ω=kBTand
1
τmm≈g2
/Lambda16kBT
/planckover2pi1≈/parenleftbiggT
Tc/parenrightbigg3kBT
/planckover2pi1, (A16)
with Curie temperature kBTc≈Jss2/3. With parameters for
YIGJss2/3/kB≈200 K, which is the correct order of
magnitude. The T4scaling of the four-magnon interaction
rate results from the combined effects of the magnon density ofstates (magnon scattering phase space) and energy dependenceof the exchange interactions.
While the magnon-magnon scattering is efficient at thermal
energies, it becomes slow at low energies close to the band edgedue to phase space restrictions and leads to deviations from theBose-Einstein distribution functions that may be disregardedat room temperature.
3. Magnon-conserving magnon-phonon interactions
At thermal energies and large wave numbers, the magnon-
conserving magnon-phonon scattering [ 37] is dominated bythe dependence of the exchange interaction on lattice distor-
tions rather than magnetocrystalline fields. Since we estimateorders of magnitude, we disregard phonon polarization andthe tensor character of the magnetoelastic interaction and startfrom the Hamiltonian
H
mp=−B
s/integraldisplay
dxs(x)·∇2s(x)⎛
⎝/summationdisplay
α∈{x,y,z}∂R
∂xα⎞
⎠, (A17)
where Bis a magnetoelastic constant. The scalar lattice
displacement field Rcan be expressed in the phonon creation
and annihilation operators ˆφ†and ˆφas
R=/radicalBigg
/planckover2pi12
2ρ/epsilon1[ˆφ+ˆφ†], (A18)
where /epsilon1is the phonon energy and ρthe mass density. By the
Holstein-Primakoff transformation introduced in the previous
014412-14MAGNON SPIN TRANSPORT DRIVEN BY THE MAGNON . . . PHYSICAL REVIEW B 94, 014412 (2016)
section, we find to leading order
Hmp≈B/integraldisplay
dx(∇ˆψ†)·(∇ˆψ)/parenleftbigg/planckover2pi12
ρ/epsilon1/parenrightbigg⎛
⎝/summationdisplay
α∈{x,y,z}∂ˆφ
∂xα⎞
⎠+H.c.
(A19)
This Hamiltonian is the scattering potential in the matrix
elements of Eq. ( A5):
/vextendsingle/vextendsingleVmp
kk/primeq/vextendsingle/vextendsingle2≈B2/planckover2pi12q2
ρ/epsilon1q(k·k/prime)2δ(k−k/prime−q) (A20)
which by substitution and in the limit /Lambda1/lessmuch/Lambda1p, where /Lambda1p=
/planckover2pi1c/kBTpis the phonon thermal de Broglie wavelength, leads
to
1
τmp∼B2
/planckover2pi1ρ/parenleftbigg/planckover2pi1
kBT/parenrightbigg21
/Lambda14/Lambda15p. (A21)In the opposite limit /Lambda1/greatermuch/Lambda1p,
1
τmp∼B2
/planckover2pi1ρ/parenleftbigg/planckover2pi1
kBT/parenrightbigg21
/Lambda17/Lambda12p. (A22)
At room temperature /Lambda1≈/Lambda1pand for ρa3=10−24kg both
expressions lead to τmp=10(Js/B)2ns [38]. We could not
find estimates of Bfor YIG in the literature. In iron, exchange
interactions change by a factor of 2 upon small lattice distortion/Delta1a/lessmucha[53]. While the authors of this latter work find that
this does not strongly affect the Curie temperature, it leadsto fast magnon-phonon scattering as we show now. Namely,B∼a∂J
s/∂/Delta1a|/Delta1a=0≈aJs//Delta1a , so that τmp=10(/Delta1a/a )2
ns, which is many orders of magnitude smaller than one ns
(and thus smaller than τmrat room temperature). While no
proof, this argument supports our hypothesis that the magnontemperature relaxation length is much shorter than that of themagnon chemical potential.
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014412-16 |
PhysRevB.87.174417.pdf | Selected for a Viewpoint inPhysics
PHYSICAL REVIEW B 87, 174417 (2013)
Comparative measurements of inverse spin Hall effects and magnetoresistance
in YIG/Pt and YIG/Ta
C. Hahn, G. de Loubens,*O. Klein, and M. Viret
Service de Physique de l’ ´Etat Condens ´e (CNRS URA 2464), CEA Saclay, 91191 Gif-sur-Yvette, France
V. V. N a l e t ov
Service de Physique de l’ ´Etat Condens ´e (CNRS URA 2464), CEA Saclay, 91191 Gif-sur-Yvette, France and
Institute of Physics, Kazan Federal University, Kazan 420008, Russian Federation
J. Ben Youssef
Universit ´e de Bretagne Occidentale, Laboratoire de Magn ´etisme de Bretagne CNRS, 6 Avenue Le Gorgeu, 29285 Brest, France
(Received 18 February 2013; published 13 May 2013)
We report on a comparative study of spin Hall related effects and magnetoresistance in YIG |Pt and YIG |Ta
bilayers. These combined measurements allow to estimate the characteristic transport parameters of both Pt andTa layers juxtaposed to yttrium iron garnet (YIG): the spin mixing conductance G
↑↓at the YIG |normal metal
interface, the spin Hall angle /Theta1SH, and the spin diffusion length λsdin the normal metal. The inverse spin Hall
voltages generated in Pt and Ta by the pure spin current pumped from YIG excited at resonance confirm theopposite signs of spin Hall angles in these two materials. Moreover, from the dependence of the inverse spin Hallvoltage on the Ta thickness, we extract the spin diffusion length in Ta, found to be λ
Ta
sd=1.8±0.7 nm. Both the
YIG|Pt and YIG |Ta systems display a similar variation of resistance upon magnetic field orientation, which can
be explained in the recently developed framework of spin Hall magnetoresistance.
DOI: 10.1103/PhysRevB.87.174417 PACS number(s): 85 .75.−d, 76.50.+g
I. INTRODUCTION
Spintronics aims at designing devices that capitalize on
the interplay between the spin and charge degrees of freedomof the electron. In particular, it is of central interest to study
the interconversion from a spin current, the motion of spin
angular momentum, to a charge current and the transfer ofspin angular momentum between the conduction electrons of anormal metal (NM) and the magnetization of a ferromagneticmaterial (FM). The separation of oppositely spin-polarizedelectrons of a charge current through spin-orbit coupling iscalled spin Hall effect (SHE).
1,2Its inverse process (ISHE)
converts spin currents into charge currents and has recently
sparked an intense research activity.3,4as it allows for an
electrical detection of the dynamical state of a ferromagnet.5,6
Indeed, a precessing magnetization in a ferromagnet generates
a spin current via spin pumping,7which can be converted, at
the interface with an adjacent normal layer, to a dc voltageby ISHE. Moreover, electronic transport can also be affected
by the static magnetization in the FM as electrons spins
separated by SHE can undergo different spin-flip scatteringon the interface with the FM layer. In particular, spin-flippedelectrons are deflected by ISHE in a direction opposite to theinitial current, leading to a reduced total current at constantvoltage. This effect depends on the relative orientation betweenmagnetization and current direction, and has recently been
called spin Hall magnetoresistance (SMR).
8
Experimental studies on spin pumping induced inverse spin
Hall voltages ( VISH)i nF M |NM bilayers were first carried out
with Pt as NM in combination with NiFe as FM5,9–12and
more recently with the insulating ferrimagnet yttrium irongarnet (YIG).
6,13–17Although other strong spin-orbit metals
have been tried in combination with the metallic ferromagnetsNiFe18,19and CoFeB,20,21inverse spin Hall voltage6,17and
magnetoresistance8,22measurements made on YIG |NM have
so far been limited to NM =Pt. Still, it would be very
interesting to compare VISHand SMR measurements on
different YIG |NM systems, including metals having opposite
spin Hall angles, such as Pt versus Ta.20,23Ab initio calculations
indeed predict the spin Hall angle of the resistive βphase
of Ta to be larger and of opposite sign to that of Pt.24The
defining parameters for VISHand SMR are the spin diffusion
length in the normal metal, λsd, the spin Hall angle /Theta1SH, which
quantifies the efficiency of spin to charge current conversion,and the spin mixing conductance ( G
↑↓), which depends on the
scattering matrices for electrons at the FM |NM interface7and
can be seen as the transparency of the interface for transfer ofspin angular momentum.
25The evaluation of the three above
mentioned parameters is a delicate task,26as the measured
VISHvoltages and SMR ratio depend on all of them.
In this paper, we present a comparative study of YIG |Pt and
YIG|Ta bilayers, where we measure both the ISHE and SMR
on each sample. We confirm the opposite signs of spin Hallangles in Pt and Ta and the origin of SMR, which has beenexplained in Ref. 8. Thanks to these combined measurements,
we can evaluate the spin mixing conductances of the YIG |Pt
and YIG |Ta interfaces and the spin Hall angles in Pt and Ta. In
order to get more insight on the previously unexplored YIG |Ta
system, we study the dependence of ISHE on Ta film thickness,which enables us to extract the spin diffusion length in Ta.
The remaining of the manuscript is organized as follows.
Section IIgives details on the samples and experimental setup
used in this study. In Sec. III, the experimental data of V
ISH
and SMR obtained on the YIG |Pt and YIG |Ta systems are
presented and analyzed. In Sec. IV, we discuss the transport
parameters extracted from our measurements. We also
174417-1 1098-0121/2013/87(17)/174417(8) ©2013 American Physical SocietyC. HAHN et al. PHYSICAL REVIEW B 87, 174417 (2013)
FIG. 1. (Color online) (a) Standard in-plane FMR spectrum of a bare YIG 200-nm thin film used in this study. (b) Full FMR linewidth vs
frequency.
comment on the absence of direct effect of a charge current in
Pt on the linewidth of our 200-nm-thick YIG samples. Finally,we emphasize the main results of this work in the conclusion.
II. EXPERIMENTAL DETAILS
A. Samples
1. YIG films
Two single-crystal Y 3Fe5O12(YIG) films of 200-nm thick-
ness were grown by liquid phase epitaxy on (111) Gd 3Ga5O12
(GGG) substrates,27and labeled YIG1 and YIG2. Epitaxial
growth of the YIG was verified by x-ray diffraction and thefilms roughness was determined by atomic force microscopyto be below 5 ˚A. Their magnetic static properties were
investigated by vibrating sample magnetometry. The in-planebehavior of the thin YIG films is isotropic with a coercitivitybelow 0.6 Oe.
27The saturation magnetization, found to be
140 emu /cm3, corresponds to the one of bulk YIG. This value
was verified by performing ferromagnetic resonance (FMR) atdifferent excitation frequencies.
FMR also allows to extract the magnetic dynamic properties
of the 200-nm-thick YIG films. A typical FMR spectrum ofthe YIG1 film obtained at 10 GHz and low microwave power(P=− 20 dBm) is presented in Fig. 1(a). The gyromagnetic
ratio of our YIG films is found to be γ=1.79×10
7rad/s/Oe.
From the dependence of the linewidth on the excitationfrequency, their Gilbert damping α
G=(2.0±0.2)×10−4
can be determined, see Fig. 1(b). This value highlights the
very small magnetic relaxation of these thin films. Still, thereis an inhomogeneous part to the linewidth [ /Delta1H
0=0.4O ei n
Fig. 1(b)]. For one of the two prepared films (YIG2), two to
three closely spaced resonance lines could be observed in somecases, which we attribute to distinct sample regions havingslightly different properties.
2. YIG |Pt and YIG |Ta bilayers
After these standard magnetic characterizations, the
YIG films were cut into slabs with lateral dimensions of1.1 mm ×7 mm in order to perform inverse spin Hall voltage
and magnetoresistance measurements. Platinum and tantalumthin films were then grown by rf sputter deposition, at a powerdensity of 4 W /cm
2. The growth of the resistive βphase
of Ta was achieved by optimizing the Ar pressure duringthe sputtering process. This study was conducted in parallelonto oxidised Si and GGG(111) substrates. The appearanceof the tetragonal crystalline phase in a narrow window around10
−2mbar was verified by the presence of the characteristic
(200)- β-Ta line in the x-ray diffraction spectra.28Theβphase
was also confirmed by the resistivity of the films,20which for
10-nm Ta thickness lies at 200 μ/Omega1cm.
In order to compare ISHE and SMR on YIG |Pt and YIG |Ta
bilayers, a 15-nm-thick Pt and a 3-nm-thick Ta layers weregrown on the YIG1 sample. The conductivities of thesemetallic films are σ
Pt=2.45×106/Omega1−1m−1(in agreement
with the values reported in Refs. 17and18) andσTa=3.05×
105/Omega1−1m−1, respectively. These two samples have been used
to obtain the results presented in Figs. 2and4. The dependence
on Pt thickness of both VISH17and magnetoresistance22,29has
been studied earlier. In this work, we have used the YIG2sample to study the dependence as a function of the Tathickness, which was varied from 1.5 to 15 nm (1.5, 2, 3,5, 10, and 15 nm). The conductivity of these Ta films increasesfrom 0 .8×10
5to 7.5×105/Omega1−1m−1with the film thickness.
This series of samples has been used to obtain the data ofFig. 3. Finally, Pt films with thicknesses 10 and 15 nm were
also grown on YIG2, for the sake of comparison with YIG1.
B. Measurement setup
A 500- μm-wide and 2- μm-thick Au transmission line cell
and electronics providing frequencies up to 20 GHz wereused for microwave measurements. The long axis of thesample was aligned perpendicularly to the microwave line,thus parallel to the excitation field h
rfas indicated in the inset
of Fig. 2.VISHwas measured by a lock-in technique (with
the microwave power turned on and off at a frequency of afew kilohertz) with electrical connections through gold leads
174417-2COMPARATIVE MEASUREMENTS OF INVERSE SPIN HALL ... PHYSICAL REVIEW B 87, 174417 (2013)
FIG. 2. (Color online) Inverse spin Hall voltage measured at 3.5 GHz for YIG |Ta and YIG |Pt. (Inset) Sketch of the experiment.
at equal distance to the area of excitation. Magnetotransport
measurements of the YIG |NM slabs were performed using a
four-point configuration. The samples were placed at the centerof an electromagnet, which can be rotated around its axis inorder to obtain curves of magnetoresistance versus angle. Themeasurement cell was placed in a cryostat, with the possibilityto cool down to 77 K. All the measurements presented in thispaper were performed at room temperature, except for thosereported in Fig. 5.
III. EXPERIMENTAL RESULTS AND ANALYSIS
A. Inverse spin Hall voltage: YIG |Pt versus YIG |Ta
First, we compare in Fig. 2the inverse spin Hall voltages
measured at 3.5 GHz ( P=+ 10 dBm) in the YIG |Pt and
YIG|Ta bilayers. It shows that one can electrically detect the
FMR of YIG in these hybrid systems.6The spin current Js
pumped into the adjacent normal metal by the precessing mag-
netization in YIG is converted into a charge current by ISHE,
Je=2e
¯h/Theta1SHJs, (1)
where eis the electron charge and ¯ hthe reduced Planck
constant. This leads to a transverse voltage VISH(across
the length of the YIG |NM slab), as sketched in the inset of
Fig. 2. Moreover, VISHmust change sign upon reversing the
magnetization of YIG because of the concomitant reversalof the spin pumped current J
s(hence Je). This is observed
in both the YIG |Pt and YIG |Ta systems, where VISHis odd
in applied magnetic field, which shows that the voltagegenerated at resonance is not due to a thermoelectric effect.
The striking feature to be observed here is the opposite
signs of V
ISHin these two samples. This remains true at all
microwave frequencies (from 2 to 8 GHz) and power levels(from −8t o+10 dBm), which were measured, as well asfor the different YIG |Pt and YIG |Ta bilayers made from
YIG1 and YIG2 samples. It thus confirms that the spin Hallangles in Ta and Pt have opposite signs, as predicted by ab
initio calculations
24and inferred from measurements where
the spin current was generated by a metallic ferromagnet.20,23
Moreover, from the electrical circuit that was used in the
measurements (the anode of the voltmeter is on the left inFig. 2, inset), it can be found that /Theta1
Pt
SH>0, while /Theta1Ta
SH<0.
The precise estimation of the spin Hall angles in these twomaterials requires the extra analyses presented in the followingsections. Still, it is interesting to note that the 4 μV amplitude
ofV
ISHmeasured in Fig. 2on our 15-nm-thick Pt is close
to the one reported in Ref. 17(2 to 3 μV) with comparable
experimental conditions.
B. Dependence of inverse spin Hall voltage on Ta thickness
In this work, we have measured the dependence of VISHonly
on Ta thickness. The study as a function of Pt thickness wasalready reported in Ref. 17, using a similar 200-nm-thick YIG
film (fabricated in the same laboratory). In Fig. 3,w eh a v e
plotted using red squares the dependence of V
ISHon the Ta
thickness measured on the series of samples described above.Here,V
ISHis produced by the precession of magnetization in
YIG, resonantly excited at 3.8 GHz by the microwave field(P=+ 10 dBm). V
ISHincreases from less than 2 μVu pt o
70μV as the Ta layer thickness is reduced from 15 to 2 nm
at which the maximal voltage is measured. For the thinnest Talayer ( t
Ta=1.5n m ) , VISHdrops to about 10 μV , a value close
to the one observed at tTa=10 nm. A similar dependence of
VISHon Pt thickness was reported in Ref. 17, where a maximum
of voltage was observed between tPt=1.5 nm and tPt=6n m .
The resistance measured across the length of the YIG |Ta
slab is also plotted with green crosses in Fig. 3as a function
oftTa(see right scale). It is interesting to note that both VISH
174417-3C. HAHN et al. PHYSICAL REVIEW B 87, 174417 (2013)
FIG. 3. (Color online) Dependence of inverse spin Hall voltage
on Ta thickness (red squares, left scale). The microwave frequencyis 3.8 GHz ( P=+ 10 dBm). The lines are theoretical predictions
17
from Eq. (2)for different values of λsd, with the parameters G↑↓=
4.3×1013/Omega1−1m−2and/Theta1SH=− 0.02. The resistance of the samples
is also displayed (green crosses, right scale). The resistance of the
1.5-nm-thin Ta sample (95 k /Omega1) is out of range.
andRfollow a similar dependence on the Ta thickness, if one
excludes the thinnest Ta layer, which might be discontinuous oroxidized, and thus exhibits a very large resistance ( R=95 k/Omega1
is out of range of the graph).
To analyze the thickness dependence of the inverse spin
Hall voltage, we follow the approach derived in Ref. 17.T h e
spin diffusion equation with the appropriate source term andboundary conditions leads to the following expression:
V
ISH=/Theta1SHG↑↓
G↑↓+σ
λsd1−exp (−2tNM/λsd)
1+exp (−2tNM/λsd)
×hLPf sin2(θ)
2etNM[1−exp (−tNM/λsd)]2
1+exp (−2tNM/λsd),(2)
where σis the conductivity of the normal metal, tNMis
its thickness, Lis the length of the YIG |NM slab excited
at frequency fby the microwave field, θis the angle of
precession of YIG, and Pis an ellipticity correction factor.
The latter depends on the excitation frequency18and, in our
case,P/similarequal1.25.
From Eq. (2), one can see that the amplitude ofVISHdepends
on the transport parameters λsd,G↑↓, and /Theta1SH,a sw e l la s
on the resonant precession angle θ. We do not have a direct
measurement of θ, but it can be evaluated from the strength of
the microwave field hrfand the measured linewidth /Delta1H.30By
performing network analyzer measurements and consideringthe geometry of the transmission line, we estimate the strengthof the microwave field h
rf/similarequal0.2O ef o ra P=+ 10 dBm output
power from the synthesizer. For the series of YIG |Ta samples,
it yields a precession angle θ/similarequal3.3◦in YIG at 3.8 GHz.Nevertheless, the measurements presented in Fig. 3are not
sufficient to extract independently G↑↓and/Theta1SH.
Thethickness dependence ofVISHprimarily depends on λsd,
through the argument of the exponential functions in Eq. (2).
The spin diffusion length can thus be adjusted to fit the shapeofV
ISHvs.tTain Fig. 3. The series of lines in Fig. 3displays
the result of calculations based on Eq. (2)for three different
values of λsd, using the thickness dependent conductivity σTa
measured experimentally. A very good overall agreement to
the data is found for a spin diffusion length λTa
sd=1.8n m .W e
explain the discrepancy observed at tTa=1.5 nm at which the
measured voltage is about five times smaller than predicted, bythe fact that the thinnest Ta layer is discontinuous or oxidized,as already pointed out.
C. Magnetoresistance: YIG |Pt versus YIG |Ta
We now turn to the measurements of dc magnetoresistance
in our hybrid YIG |NM bilayers. We have measured the
variation of resistance in the exact same samples as the onesstudied by ISHE in Fig. 2,Y I G|Pt (15 nm) and YIG |Ta (3 nm),
as a function of the angle of the applied field with respect tothe three main axes of the slabs. In these experiments, theapplied field was fixed to H=3 kOe (sufficient to saturate the
YIG), and a dc current of a few mA together with a 6
1/2digits
voltmeter were used to probe the resistance of the NM layersin a four-probe configuration. The results obtained by rotatingthe magnetic field in the plane of the sample (angle α), from
in-plane perpendicular to the charge current J
eto out-of-plane
(angle β) and from in-plane parallel to Jeto out-of-plane
(angle γ) are presented in Figs. 4(a)–4(c), respectively (see
also associated sketches).
In both YIG |Pt and YIG |Ta bilayers, we do observe a weak
magnetoresistance ( /Delta1R max/R0of 5×10−5and 4 ×10−5,
respectively), as it was reported on the YIG |Pt system.22We
checked that this weak variation does not depend on the signor strength of the probing current. In contrast to the inversespin Hall voltage measurements presented in Fig. 2,w ea l s o
note that the sign (or symmetry) of the effect is identical inYIG|Pt and YIG |Ta.
In order to interpret this magnetoresistance, it is important
to understand its dependence on all three different angles,α,β, andγ, shown in Fig. 4. If one would just look at the
in-plane behavior [see Fig. 4(a)], one could conclude that
the NM resistance Rchanges according to some anisotropic
magnetoresistance (AMR) effect, as if the NM would bemagnetized at the interface with YIG due to proximity effect.
22
But with AMR, Rdepends on the angle between the charge
current Jeand the magnetization (applied field H). Hence no
change of Ris expected with the angle β, whereas Rshould
vary with the angle γ, which is exactly opposite to what is
observed in Figs. 4(b) and4(c), respectively. Therefore usual
AMR as the origin of the magnetoresistance in YIG |Pt and
YIG|Ta bilayers has to be excluded.
Instead, the spin Hall magnetoresistance (SMR) mechanism
proposed in Ref. 8is well supported by our magnetoresistance
data. In this scenario, the electrons carried by the chargecurrent in the NM layer are deflected by SHE in oppositedirections depending on their spin. Those whose spin is flippedby scattering at the interface with the FM can oppose the
174417-4COMPARATIVE MEASUREMENTS OF INVERSE SPIN HALL ... PHYSICAL REVIEW B 87, 174417 (2013)
FIG. 4. (Color online) (a)–(c) Magnetoresistance in YIG |Ta and
YIG|Pt as a function of the angle of the applied field ( H=3 kOe)
sketched at the top (the samples are the same as the ones measured in
Fig. 2). Dashed lines are predictions from Eq. (3)of the SMR theory
(see Ref. 8).
initial current by ISHE and lead to an increase of resistance.
Therefore the spin Hall magnetoresistance depends on therelative angle between the magnetization Mof the FM and
the accumulated spins sat the FM |NM interface:
R=R
0+/Delta1R maxsin2(M,s). (3)
The increase of resistance is maximal when Mand sare
perpendicular, because the spin-flip scattering governed byG
↑↓at the interface is the largest. In the geometry depicted in
Fig. 4, the charge current is applied along y, hence the spins
accumulated at the YIG |NM interface due to SHE are oriented
along x. The dashed lines plotted in Figs. 4(a)–4(c) are the
prediction of the SMR theory. As can be seen, Eq. (3)explains
the presence (absence) of resistance variation upon the appliedfield angles αandβ(γ). Due to demagnetizing effects, the
magnetization of YIG is not always aligned with the appliedfield. This is the reason why the measured curves in Figs. 4(a)
and4(b) have different shapes, and a simple calculation
30of
the equilibrium position of Min combination with Eq. (3)
reproduces them quite well.
The SMR ratio was also calculated in Ref. 8:
SMR=/Delta1R max
R0=/Theta12
SH2λ2
sd
σtNMG↑↓tanh2/parenleftbigtNM
2λsd/parenrightbig
1+2λsd
σG↑↓coth/parenleftbigtNM
λsd/parenrightbig.(4)
As for the inverse spin Hall voltage VISH[see Eq. (2)], the
SMR depends on all the transport parameters G↑↓,/Theta1SH, andλsd, which therefore cannot be extracted individually from a
single measurement. In Sec. IV A , we will take advantage of
the combined measurements of VISH(see Figs. 2and 3) and
SMR (see Fig. 4) to do so. For now, it is interesting to point
out that because both SHE and ISHE are at play in spin Hallmagnetoresistance, the SMR depends on the square of the spin
Hall angle. This explains the positive SMR for both YIG |Pt
and YIG |Ta, even though the spin Hall angles of Pt and Ta are
opposite.
Finally, it would have been interesting to measure the
dependence of SMR on Ta thickness (the dependence on Ptthickness was studied in Refs. 22and29). Unfortunately, it was
difficult to realize low noise four-point contacts to investigatethe faint magnetoresistance on the series of Ta samplesprepared to study V
ISHversus tTa. From our attempts, we found
that the SMR of YIG |Ta (10 nm) is less than 2 ×10−5.T h i s
is consistent with the decrease predicted by Eq. (4)(assuming
λTa
sd=1.8 nm) with respect to the SMR /similarequal4×10−5measured
for YIG |Ta (3 nm).
IV . DISCUSSION
A. Transport parameters
As already discussed, both VISHand SMR depend on the set
of transport parameters ( G↑↓,/Theta1SH,λsd). By studying VISHas a
function of the NM thickness, the spin diffusion length can bedetermined, and we found that in Ta, λ
Ta
sd=1.8±0.7n m ,s e e
Fig. 3. We mention here that from a similar study on YIG |Pt,
λPt
sd=3.0±0.5 nm could be inferred.17This value lies in the
range of spin diffusion lengths reported on Pt, which span overalmost an order of magnitude,
26from slightly more than 1 nm
up to 10 nm.
We note that the spin diffusion length extracted from the
YIG|Ta data of Fig. 3is somewhat shorter than the 2.7 nm
inferred from nonlocal spin-valve measurements.23The value
found for the spin diffusion length in Ta is short, but reasonableas it represents several times the electronic mean free paths,which are of the order of 0.4 nm. We note here that indeedTa is very resistive but still in the metallic-like regime withsheet resistances below 4 k /Omega1. However, the extraction of
physical spin diffusion lengths in these measurements is at theheart of a present controversy.
26It seems indeed that nonlocal
measurements give systematically larger values than thoseextracted from ISHE measurements of FMR spin pumping. Inthis respect, we would like to point out that perhaps the modelof Eq. (2)is too simple for the present problem as charge
current (for resistivity measurements) and spin currents are intwo different directions: the former is in-plane while the latteris perpendicular to the plane. Hence the spin current has tocross one interface and interacts with the free surface of themetallic layer. It is not clear to us that the relevant quantity inthe problem is really the bulk λ
sd. It is not impossible that the
relevant spin diffusion length also depends on layer thickness,but this refinement is beyond the reach of the present paper.
There is a direct way to get the spin mixing conductance
of a FM |NM interface, by determining the increase of
damping in the FM layer associated to spin pumping inthe adjacent NM layer.
7Due to its interfacial nature, this
effect is inversely proportional to the thickness of the FM
174417-5C. HAHN et al. PHYSICAL REVIEW B 87, 174417 (2013)
TABLE I. Transport parameters obtained from the analysis of
inverse spin Hall voltage [Figs. 2and 3+Eq.(2)] and spin Hall
magnetoresistance [Fig. 4+Eq.(4)] performed on YIG |Ta (1.5–
15 nm) and YIG |Pt (15 nm).
YIG|Ta (1.5–15 nm) YIG |Pt (15 nm)
σ(106/Omega1−1m−1)0 .08–0.75 2 .45±0.10
λsd(10−9m) 1 .8±0.7n /a [from 1.5 to 10]26
G↑↓(1013/Omega1−1m−2)4 .3±11
2 6.2±14
4
/Theta1SH −0.02±0.008
0.015 0.03±0.04
0.015
and can be measured only on ultrathin films. This was
recently achieved in nanometer-thick YIG films grown bypulsed laser deposition,
31,32where spin mixing conductances
G↑↓=(0.7−3.5)×1014/Omega1−1m−2have been reported for the
YIG|Au interface.
Even for 200-nm-thick YIG films as ours, it is possible
to obtain the full set of transport parameters thanks to ourcombined measurements of V
ISHand SMR on YIG |NM hybrid
structures. In fact, from Eqs. (2)and(4), the ratio V2
ISH/SMR
does not depend on /Theta1SH, which allows to determine G↑↓.
Then, the last unknown /Theta1SHcan be found from the VISHor
SMR signal. This is how we proceed to determine the transportparameters, which are collected in Table I. The drawback
of this method is that it critically relies on (i) λ
sd, which
enters in the argument of exponential functions in Eqs. (2)
and(4)and (ii) the angle of precession θin the inverse spin
Hall experiment, since V2
ISH/SMR∝θ4. Our estimation of θ
being within ±25%, the value extracted for G↑↓from the ratio
V2
ISH/SMR can vary by a factor up to 8 due to this uncertainty.
The spin Hall angle /Theta1SHis less sensitive to other parameters,
still it can vary by a factor up to 3. This explains the ratherlarge error bars in Table I. In this study, we did not determine
the spin diffusion length in Pt, hence we used the range ofvalues reported in the literature.
26
The spin mixing conductances determined from our com-
bined VISHand SMR measurements on YIG |Ta and YIG |Pt
bilayers lie in the same window as the ones determined frominterfacial increase of damping in YIG |Au,
31from inverse
spin Hall voltage in BiY 2Fe5O12|Au and Pt,33and from
first-principles calculations in YIG |Ag.25We would like to
point out that despite the large uncertainty, G↑↓for YIG |Ta is
likely less than for YIG |Pt. We note that the smaller damping
measured in CoFeB |Ta compared to CoFeB |Pt was tentatively
attributed to a smaller spin mixing conductance.20
The spin Hall angles that we report for Pt and Ta are both
of a few percents. In particular, /Theta1Ta
SH/similarequal− 0.02 lies in between
the values determined from nonlocal spin-valve measurements(/similarequal−0.004)
23and from spin-torque switching using the SHE
(/similarequal−0.12).20
The main conclusion, which arises from the summary pre-
sented in Table I, is that the sets of transport parameters deter-
mined for the hybrid YIG |Ta and YIG |Pt systems are quite sim-
ilar. Apart from the opposite sign of /Theta1SHin Ta and Pt, the main
difference concerns the conductivity: σβ−Tais roughly one
order of magnitude smaller than σPt. This explains the large
inverse spin Hall voltages that can be detected in our YIG |Ta
bilayers (up to 70 μVa tP=+ 10 dBm), since from Eq. (2)
VISH∝1/σ, which could be a useful feature of the Ta layer.B. Influence of a dc current on FMR linewidth
Onsager reciprocal relations imply that if there is an ISHE
voltage produced by the precession of YIG, there must also bea transfer of spin angular momentum from the NM conductionelectrons to the magnetization of YIG, through the finite spinmixing conductance at the YIG |NM interface.
25Therefore
one would expect to be able to control the relaxation of theinsulating YIG by injecting a dc current in an adjacent strongspin-orbit metal, as it was shown on YIG |Pt in the pioneering
work of Kajiwara et al.
6Although this direct effect is well
established when the ferromagnetic layer is ultra-thin andmetallic,
34–37only a few works report on conclusive effects on
micron-thick YIG6,38,39or provide a theoretical interpretation
to the phenomenon.40
The 200-nm-thick YIG films that have been grown for this
study are about six times thinner than the one used in Ref. 6,
with an intrinsic relaxation close to bulk YIG. Because the spintransfer torque is an interfacial effect and sizable spin mixingconductances have been measured in our YIG |Ta and YIG |Pt
bilayers, our samples must be good candidates to observethe direct effect of a dc current on the relaxation of YIG.Due to their large resistance, β-Ta films are not convenient
to pass the large current densities required to observe such aneffect (large Joule heating). Therefore we have conducted theseexperiments only on the YIG |Pt films prepared in this work.
The inverse spin Hall voltage measurements presented in
Fig. 2have therefore been repeated in the presence of a dc
current flowing through the Pt layer. This type of experiment,where a ferromagnetic layer is excited by a small amplitudesignal and a spin polarized current can influence the linewidthof the resonance, has already been reported on spin-valve spin-torque oscillators
41,42and NiFe |Pt bilayers.35,43The results
obtained on our YIG (200 nm) |Pt (15 nm) at 77 K when the
dc current is varied from −40 to +40 mA are displayed in
Fig. 5.
Let us now comment on these experiments. We first
emphasize that the current injected in Pt is truly dc (not pulsed).A sizable Joule heating is thus induced, as reflected by theincrease of Pt resistance. As a consequence, the main effect ofdc current injection at room temperature is the displacementof the resonance towards larger field, due to the decrease ofthe YIG saturation magnetization M
s. To avoid this trivial
effect, we have performed these experiments directly in liquidnitrogen. In that case, the increase of Pt resistance is verylimited ( +0.2% at ±40 mA). We note that when cooled from
300 K down to 77 K, the peak of the inverse spin Hall voltagemeasured in the YIG |Pt bilayer is displaced towards lower field
due to the increase of M
sof YIG (from 140 to 200 emu /cm3),
and its amplitude slightly decreases.
The main conclusion that can be drawn from Fig. 5is that
there is basically no effect of the dc current injected in Pt onthe YIG resonance. We stress that the maximal current densityreached in Pt in these experiments is J
e=2.4×109Am−2,
i.e., twice larger than the one at which YIG magnetizationoscillations were reported in Ref. 6. In our experiments, we
are not looking for auto-oscillations of YIG, which requiresthat the damping is fully compensated by spin transfer torque,but only for some variation of the linewidth. The fact that wedo not see any change in the shape of the resonant peak of
174417-6COMPARATIVE MEASUREMENTS OF INVERSE SPIN HALL ... PHYSICAL REVIEW B 87, 174417 (2013)
FIG. 5. (Color online) Inverse spin Hall voltage measured at 2.95 GHz ( P=+ 10 dBm) for YIG |Pt as a function of the dc current flowing
in the Pt layer. A small current dependent offset ( <0.2μV) has been subtracted to the data.
our 200-nm-thin YIG film is thus in contradiction with the
observation of bulk auto-oscillations in thicker films.6
We have also performed similar experiments on the other
YIG(200 nm) |Pt samples, which were prepared using the two
different YIG films grown for this study. Although the currentdensity was increased up to 6 ×10
9Am−2, we were never able
to detect any sizable variation of the linewidth of YIG. Instead,we have measured that the dc current can affect the inverse spinHall voltage in different ways. First, when a charge current isinjected into Pt, a non-zero offset of the lock-in signal can bedetected (it was subtracted in Fig. 5). This is due to the increase
of Pt resistance induced by the microwave power, as it wasverified by monitoring this offset while varying the modulationfrequency of the microwave. Secondly, the amplitude of theV
ISHpeaks can be affected by the dc current (but again, not
the linewidth). This effect can at first be confused with someinfluence on the relaxation of YIG, because it displays theappropriate symmetries versus field and current. But instead,we have found that this is a bolometric effect:
44when the
YIG is excited at resonance, it heats up, thereby heating theadjacent Pt whose resistance gets slightly larger. Hence anadditional voltage to V
ISHis picked up on the lock-in due to
the nonzero dc current flowing in Pt. Therefore, one shouldbe very careful in interpreting changes in inverse spin Hallvoltage as the indication of damping variation in YIG. Finally,we observed that at very large current density, the resonancepeak slightly shifts towards larger field due to Joule heating,even at 77 K.
V . CONCLUSION
In this paper, we have presented and analyzed a com-
parative set of data of inverse spin Hall voltage VISHandmagnetoresistance obtained on YIG |Pt and YIG |Ta bilayers.
We have detected the voltages generated by spin pumping atthe YIG |Pt interface (already well established)
6and at the
YIG|Ta interface. Their opposite signs are assigned to the
opposite spin Hall angles in Pt and Ta.24From the thickness
dependence of VISH, we have been able to obtain the spin
diffusion length in Ta, λTa
sd=1.8±0.7 nm, in reasonable
agreement with the value extracted from nonlocal spin valvemeasurements.
23From symmetry arguments, we have shown
that the weak magnetoresistance measured on our hybridYIG|NM layers cannot be attributed to usual AMR, but is
instead well understood in the framework of the recentlyintroduced spin Hall magnetoresistance (SMR).
8By taking
advantage of the combined measurements of VISHand SMR
performed on the same samples, we have been able to extractthe spin Hall angles in Pt and Ta, as well as the spin mixingconductances at the YIG |Pt and YIG |Ta interfaces.
These transport parameters have all been found to be of
the same order of magnitude as those already measured
20,31or
predicted.25We believe that at least part of the discrepancies
between the parameters evaluated in different works26depend
on the details of the YIG |NM interface32and on the quality of
the NM.18,19,23
Finally, we could not detect any change of linewidth in our
YIG|Pt samples by passing large current densities through the
Pt layer. One might argue that our high-quality 200-nm YIGthin films are still too thick to observe any appreciable effectof spin transfer torque, which is an interfacial mechanism, orthat the spin-waves which can auto-oscillate under the actionof spin transfer at the interface with Pt are different fromthe uniform mode that we excite with the microwave fieldin our experiments.
6,40If one would estimate the threshold
current required to fully compensate the damping of all the
174417-7C. HAHN et al. PHYSICAL REVIEW B 87, 174417 (2013)
magnetic moments contained in our YIG films,20,40Jth/similarequal
2eαωM stYIG/(/Theta1SHγ¯h), one would get current densities of
about 1011Am−2. This is 20 times larger than the largest
current density which we have tried. Thus the lack of avisible effect in our Fig. 5is not a real surprise in itself, but
it is inconsistent with the results reported in Ref. 6. Future
experiments on ultrathin YIG |NM hybrid films, in which thespin mixing conductance can be directly determined from the
interfacial increase of damping,
31might give a definite answer
to this point.
ACKNOWLEDGMENT
This research was supported by the French ANR Grant
Trinidad (ASTRID 2012 program).
*Corresponding author: gregoire.deloubens@cea.fr
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174417-8 |
PhysRevLett.99.227207.pdf | Microwave Assisted Switching of Single Domain Ni80Fe20Elements
Georg Woltersdorf and Christian H. Back
Universita ¨t Regensburg, Universita ¨tsstraße 31, 93040 Regensburg, Germany
(Received 16 July 2007; published 30 November 2007; publisher error corrected 3 December 2007)
We study the switching behavior of thin single domain magnetic elements in the presence of microwave
excitation. The application of a microwave field strongly reduces the coercivity of the elements. We showthat this effect is most profound at the ferromagnetic resonance frequency of the elements. Observations
using time-resolved magneto-optic Kerr microscopy in combination with pulsed microwave excitation
further support that the microwave assisted switching process is indeed based on the coherent motion ofthe magnetization.
DOI: 10.1103/PhysRevLett.99.227207 PACS numbers: 75.60.Jk, 75.30.Ds, 75.75.+a, 78.47.+p
In magnetic recording the increasing data rates require
fast magnetization reversal in small magnetic elements.
Thin magnetic elements in the deep submicron range ofsizes favor a single domain state and often show a switch-ing behavior as expected by the Stoner-Wohlfarth theory.However, due to the absence of magnetization reversal
processes based on domain wall motion or buckling, this
implies that for coherent Stoner-Wohlfarth magneticswitching a field larger than the magnetic anisotropy fieldneeds to be applied along the magnetic easy axis for a
duration of several nanoseconds. This long wait time is
required since applying a magnetic field opposing themagnetization does not exert a torque on the magnetizationand only thermal fluctuation or a small initial misalignmentof the magnetic field can cause large angle precession of
the magnetization. Finally the magnetization precesses
into the direction parallel to the applied field due to re-laxation processes. This slow and—if based on thermalfluctuations—to a large extent unpredictable process canbe avoided in two ways. (i) Precessional or ballistic switch-
ing; in this case the magnetic field is applied perpendicular
to the magnetization and the torque term of the equation ofmotion is used [ 1–3] to drive the magnetization reversal.
This type of switching, however, requires a careful timing
of pulse length /.0028and magnetic field amplitude Bsince a
deviation from the product of /.0028/.0001Bcan lead to multiple
switching and a loss of control of the final state [ 4]. (ii) An
alternative route is to use an rf field perpendicular to themagnetization in order to assist the magnetic switching.
The feasibility of this method was shown in magnetic
nanoparticles by superconducting quantum interferencemagnetometry [ 5] and recently by magnetic force micros-
copy [ 6]. In this Letter time-resolved Kerr microscopy is
employed to show that this mechanism is also present in
micrometer-sized thin film elements. The static magneti-zation is probed by a time-resolved method based on themagneto-optic Kerr effect.
For a single spin the magnetization dynamics can be
described by the Landau-Lifshitz-Gilbert equation of mo-
tion [ 7]: d~M
dt/.0136/.0255/.0013/.00220/.0137~M/.0002~Heff/.0138/.0135/.0011
M/.0020
~M/.0002d~M
dt/.0021
; (1)
where~Mis the magnetization vector, ~Heffis the effective
magnetic field, /.0011is the damping parameter, and /.0013/.0136
g/.0022B=@is the absolute value of the gyromagnetic ratio.
The first term on the right-hand side determines the reso-
nance frequency and the second term represents dampingand leads to relaxation. For the measurements, we use atime and spatially resolved ferromagnetic resonance(FMR) technique based on the time-resolved magneto-optical Kerr (TRMOKE) effect combined with continuouswave (cw) excitation [ 8]. The spatial resolution of our Kerr
setup is roughly 300 nm. Details concerning this technique
can be found in [ 9]. The magnetic sample is excited by
means of a cw rf field which is phase-locked to the laserpulses. By measuring the TRMOKE signal as a function ofthe time delay between microwave signal and optical probeone obtains amplitude and phase of the magneticprecession.
The layer structure of the samples is prepared by sputter
deposition in UHV of 5 nm Al=2n mN i
80Fe20=200 nm
Au=5n m Ti onto GaAs. A coplanar waveguide with a
signal linewidth of 10/.0022mis subsequently defined by
optical lithography and dry etching. The magnetic ele-ments are structured in a second e-beam lithography and
dry etching step. Two different element sizes were inves-tigated:0:7/.00021:4/.0022m
2hexagons and 1:5/.00023:0/.0022m2hex-
agons. The Ni80Fe20structures have a 1:2aspect ratio and a
45/.0014taper. The thickness of the magnetic elements is only
2 nm to ensure that the single domain state is the magnetic
ground state [ 10]. A schematic outline of the sample
structure with the relative orientations of the dc and rfmagnetic fields is shown in Fig. 1. In addition, an optical
microscope image of a typical sample is shown in the upperinset of Fig. 2. An unpatterned region on top of the signal
line (not shown) was used to characterize the 2 nm thickNi
80Fe20film.
From the Kittel plot shown in Fig. 2, magnetic anisot-
ropy,gfactor, and effective magnetization are extracted:PRL 99,227207 (2007)PHYSICAL REVIEW LETTERSweek ending
30 NOVEMBER 2007
0031-9007 =07=99(22)=227207(4) 227207-1 ©2007 The American Physical SocietyHA/.01360:1m T ,g/.01362:2,/.00220Meff/.01360:93 T . The damping
parameter is determined from the frequency scan in abias field of 5 mT and amounts to /.0011/.01360:0085 . The reduced
M
effis expected and a consequence of the perpendicular
interface anisotropy present in such thin Ni80Fe20films
[11]. The zero-field resonance scan of the two hexagonal
structures and the unpatterned films are compared in the
lower inset of Fig. 2. The elongated hexagonal shape of the
structures leads to a uniaxial shape anisotropy field alongthe long axis of the magnetic elements of about /.0022
0HA/.0136
0:5m T for the larger and /.00220HA/.01361:0m T for the smallerhexagon. This additional internal field in comparison with
the extended film is evident in the 250 MHz and 700 MHzoffsets of the zero-field resonance frequency, as can be
seen in the lower inset of Fig. 2. As a consequence of the
shape anisotropy, the two possible magnetic states of theelements (along the long axis of the elements pointing tothe right or to the left) are thermally stable at room tem-
perature. The energy barrier between the two states can be
estimated from the uniaxial anisotropy field and leads—for example for the smaller element—to an energy barrier
of 1 eV , which is far above k
BTat 300 K. In the TRMOKE
experiments indeed a stable single domain state is observedin zero field; see Fig. 3. This is important since we want to
study the influence of a rf magnetic field on the switching
behavior of magnetic elements immersed in an opposing
magnetic field. The switching is studied by measuringhysteresis loops of an individual element. Figure 3shows
a typical example. The loops are acquired by using the off-
resonance dynamic response to the synchronized micro-
wave excitation measured by time-resolved Kerr micros-copy. In the particular case shown in Fig. 3we measure at a
fixed frequency of 2 GHz. However, the resonance field of
the element is at about 5 mT when it is excited at 2 GHz;see the inset of Fig. 2. This means that a field sweep from
/.02551m T to/.01351m T is always far away from resonance and
the induced precessional motion of the magnetization is
small. Nevertheless, the technique applied here allows oneto measure static hysteresis loops on individual magnetic
FIG. 2 (color). The main graph shows the Kittel plot for the
Ni80Fe20film. The resonance frequencies were determined by
measuring the amplitude of the precession as a function offrequency at a low microwave power of 0 dBm. The inset on
the top shows an optical microscope image of the microstruc-
tures. In the inset on the bottom resonance scans are shown. Thered curve corresponds to the unpatterned Ni
80Fe20film. Blue and
olive curves correspond to 1:5/.00023:0/.0022m2and0:7/.00021:4/.0022m2
hexagons, respectively. The microstructures have a built-in shape
anisotropy of 0.5 mT and 1 mT leading to zero-field frequencyoffsets 250 and 700 MHz compared to the continuous film,
respectively. The black dashed curve shows a resonance scan
for the1:5/.00023/.0022m
2hexagon measured in a field of 5 mT.FIG. 1 (color online). Experimental configuration. A coplanar
waveguide is used to excite the magnetic microstructures. The
magnetic easy axis and the applied magnetic field are parallel to
the coplanar waveguide.
FIG. 3 (color online). Series of hysteresis loops measured for
the1:5/.00023/.0022m2hexagon as a function of microwave power at a
fixed frequency of 2 GHz. The microwave frequency is 2 GHzwith a power of (a) 8 dBm, (b) 15 dBm, (c) 16 dBm, and
(d) 18 dBm. As the magnetization reverses, the sign of the
magnetic response is inverted; see image scans in (a). The slightincrease of the signal with increasing field is due to the fact thatthe amplitude of the magnetic precession increases with field
since the resonance of the element at 2 GHz occurs at about
5m T .PRL 99,227207 (2007)PHYSICAL REVIEW LETTERSweek ending
30 NOVEMBER 2007
227207-2elements with an extremely high sensitivity: in the experi-
ment the synchronized microwaves are chopped and lock-in detection is used. If the microwave field is applied in-
plane and perpendicular to the magnetic easy axis of the
elements, as illustrated in Fig. 1the phase of the out-of-
plane magnetic response to the microwaves changes by180
/.0014(and hence the signal changes its sign) when the
magnetization switches; see Fig. 3. Monitoring the polar
Kerr signal as a function of the applied magnetic fieldtherefore allows one to measure the magnetic hysteresisfor individual elements as small as a few hundred nm.
When hysteresis loops are measured as a function of
microwave power at a fixed frequency one observes agradually decreasing coercive field with increasing micro-wave power while the square shape of the hysteresis loop
remains; Figs. 3and4show the coercive field as a function
of microwave power measured at a fixed frequency of2 GHz. At a microwave power below 5 dBm the coercivityis independent of the power for both hexagonal element
sizes. At a certain threshold power the coercivity is rapidly
reduced to zero. The larger threshold power for the smallerhexagon can be expected due to its larger shape anisotropy.
In a further experiment this collapse of the hysteresis was
measured for applied microwave frequencies between 0.08and 2.0 GHz. The result is shown in Fig. 5in a 2D plot. One
can clearly see that for a fixed microwave power the
reduction of the coercivity is strongest at the 500 MHz
resonance frequency of the 1:5/.00023:0/.0022m
2hexagon;
cf. Fig. 2. This can be expected if the reduced coercivity
is indeed caused by coherent motion of the magnetization
dynamics, allowing the magnetization to spiral out of its
local energy minimum when an opposing magnetic field isapplied. Nembach et al. also recently observed a micro-
wave induced reduction of the coercivity for much larger
multidomain elliptical Ni
80Fe20elements ( 160/.0022m/.000280/.0022m2)[12]. This reduction was explained by an en-
hanced domain wall nucleation in a microwave field [ 13]
and preferential entropy-driven domain growth in a trans-verse microwave field [ 14]. In this Letter we show that for
micron-sized single domain magnetic elements the micro-
wave assisted switching is actually based on a coherentmotion of the magnetization.
It is important to exclude the possibility that the reduc-
tion of the coercive fields is due to thermal heating effects.
The large thickness of the Au waveguide underneath the
2 nm thick Ni
80Fe20film provides an efficient heat sink and
the applied microwave power is small. The maximumapplied power of 20 dBm corresponds to an in-plane rf-
field amplitude of h
rf/.00244m T atf/.01362 GHz for the
10/.0022mwide signal line. One can estimate the power
absorbed at FMR using PFMR/.0136/.0025f/.003100h2
rfAtFM[15], where
/.003100/.002450is the imaginary part of the susceptibility at FMR
andAtFMis the volume of the ferromagnetic sample. An
upper limit for the expected heating /.0001Tat resonance can
be estimated from steady state heating by the thermal
conductivity of the substrate using the following relation:
/.0001T/.0136tPFMR
/.0021, where /.0021/.013655 W=mK for GaAs and t/.0136
200/.0022mis the thickness of the GaAs substrate. These
pessimistic considerations only lead to a temperature in-
crease of less than 0.2 K at FMR, in line with recent resultsreported in Ref. [ 16]. In addition to the magnetic dissipa-
tion there are also electrical losses in the 200 nm thick Au
waveguide. Here the temperature increase can be estimatedin the following way: in the frequency range of interest the
waveguide has a transmission of more than T/.013690%. The
10/.0022mwide signal line section has a length of 1 mm. If
one assumes that the losses are uniformly distributed along
this length a dissipation of 10% of P/.013620 dBm would
lead to a temperature increase of only /.0001T/.0136
t/.01331/.0255T/.0134P
/.0021/.00244K.
From these simple estimates one can see that heating
FIG. 4 (color online). Coercive field of the of the 0:7/.0002
1:4/.0022m2(diamonds) and 1:5/.00023:0/.0022m2(circles) hexagons as
a function of microwave power at a frequency of 2 GHz.
FIG. 5 (color). Coercive fields as a function of microwavepower and frequency measured for the 1:5/.00023:0/.0022m
2hexagon.
The zero-field resonance occurs at about 500 MHz (see lowerinset in Fig. 2). The coercivity is color-coded and ranges be-
tween 0 and 0.4 mT. In addition to the power scale also a scale
with the corresponding rf magnetic field is shown.PRL 99,227207 (2007)PHYSICAL REVIEW LETTERSweek ending
30 NOVEMBER 2007
227207-3cannot play a significant role in the reduction of the
coercivity.
In order to further support the notion that the microwave
assisted switching is related to a coherent motion of themagnetization, microwave bursts are used to study theswitching behavior. Using a microwave mixer and a pulse
generator short bursts with a carrier frequency of 2 GHz are
produced from a 2 GHz cw signal. The rise and fall timesof the pulses are about 200 ps and pulse lengths between0.4 and 2.5 ns are studied. Typical microwave bursts gen-erated by this method are shown in the inset of Fig. 6.I n
these measurements again the static magnetization isprobed by the sign of the magnetic response to the micro-wave burst excitation. Figure 6shows the coercive field as
a function of the microwave pulse width at a constant
microwave power of 18 dBm. The coercivity as a functionof microwave burst duration is reduced in an oscillatingmanner. Dips of the coercive field are evidenced when thepulse period corresponds to a multiple of the period of the2 GHz carrier frequency of the microwave burst (0.5 ns,1.0 ns, and 1.5 ns). As the pulse length grows the preces-sional amplitude grows and it becomes more and more
likely that the energy barrier may be overcome. This
behavior is consistent with the picture that a coherentspin precession is the leading mechanism of the reducedcoercivity. It is worthwhile to point out that although theduty cycle in the pulsed experiment is reduced by morethan a factor of 6 compared to the experiments with cwexcitation the peak amplitude required to cause a reducedcoercivity remains nearly unchanged.
When the peak amplitude of the burst was reduced such
that even for longer bursts (several ns) a finite coercivitycan still be observed, a reduction of the coercivity is only
observed for pulse lengths below approximately 2 ns. Forlonger pulses the coercivity is not reduced any further.
This can be expected by considering the decay time of
magnetic excitations. The decay time is determined fromthe damping parameter obtained from the frequency widthof resonance scans at high fields (not shown): /.0028/.0136
2=/.0137/.0011/.0013/.0022
0/.0133Meff/.01352Heff/.0134/.0138 /.01361:4n s [17]. This implies that
it is not possible to pump more energy into the magneticsystem after 2 ns. The presence of this behavior also showsthat thermal effects can be excluded since heating would
simply lead to a continuous decrease of the coercivity as a
function of pulse length.
In conclusion, it was shown that the coercive fields in
micron-sized uniaxial magnetic elements can be signifi-cantly reduced in the presence of a rf magnetic fieldapplied in-plane and perpendicular to the magnetization.This effect was shown to be a threshold effect. In addition,the reduction of the coercivity is strongest at the zero-field
resonance frequency of the magnetic element itself.
Measurements with short microwave pulses as a functionof pulse length clearly show that the reduction of thecoercive field is a consequence of coherent motion of themagnetization. The method which was used to measure thehysteresis loops by using the sign of the dynamic responseas introduced in this Letter is new and provides an unpre-cedented signal-to-noise ratio allowing one to study mag-
netic switching behavior of individual submicron magnetic
elements by magnetic Kerr effect microscopy.
Financial support from the DFG Priority Program
No. 1133 and Sonderforschungsbereich No. 689 is grate-fully acknowledged.
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30 NOVEMBER 2007
227207-4 |
PhysRevLett.97.077205.pdf | Theoretical Limit of the Minimal Magnetization Switching Field
and the Optimal Field Pulse for Stoner Particles
Z. Z. Sun and X. R. Wang
Physics Department, The Hong Kong University of Science and Technology, Clear Water Bay, Hong Kong SAR, China
(Received 7 May 2006; published 18 August 2006)
The theoretical limit of the minimal magnetization switching field and the optimal field pulse design for
uniaxial Stoner particles are investigated. Two results are obtained. One is the existence of a theoreticallimit of the smallest magnetic field out of all possible designs. It is shown that the limit is proportional to
the damping constant in the weak damping regime and approaches the Stoner-Wohlfarth (SW) limit at
large damping. For a realistic damping constant, this limit is more than 10 times smaller than that of so-called precessional magnetization reversal under a noncollinear static field. The other is on the optimal
field pulse design: if the magnitude of a magnetic field does not change, but its direction can vary during a
reversal process, there is an optimal design that gives the shortest switching time. The switching timedepends on the field magnitude, damping constant, and magnetic anisotropy.
DOI: 10.1103/PhysRevLett.97.077205 PACS numbers: 75.60.Jk, 75.75.+a, 85.70.Ay
Fabrication [ 1,2] and manipulation [ 3] of magnetic
single-domain nanoparticles (also called the Stoner parti-cles) are of great current interests in nanotechnology and
nanosciences because of their importance in spintronics.
Magnetization reversal, which is about how to switch amagnetization from one state to another, is an elementaryoperation. One important issue is how to switch a magne-tization fast by using a small switching field. The switchingfield can be a laser light [ 4], or a spin-polarized electric
current [ 5,6], or a magnetic field [ 7,8]. Many reversal
schemes [ 9,10] have been proposed and examined.
However, the issue of theoretical limits of the smallest
switching field and the shortest switching time under allpossible schemes are not known yet. Here we report twotheorems on the magnetic-field induced magnetizationreversal for uniaxial Stoner particles. One is about thetheoretical limit of the smallest possible switching field.The other is about the optimal field pulse for the shortestswitching time when the field magnitude is given.
Magnetization ~M/.0136~mM of a Stoner particle can be
conveniently described by a polar angle /.0018and an azimuthal
angle/.0030, shown in Fig. 1(a), because its magnitude Mdoes
not change with time. The dynamics of magnetization unit
direction ~mis governed by the dimensionless Landau-
Lifshitz-Gilbert (LLG) equation [ 3,8],
/.01331/.0135/.00112/.0134d~m
dt/.0136/.0255~m/.0002~ht/.0255/.0011~m/.0002/.0133~m/.0002~ht/.0134;(1)
where/.0011is a phenomenological damping constant whose
typical value ranges from 0.01 to 0.22 for Co films [ 11].
The total field ~ht/.0136~h/.0135~hicomes from an applied field ~h
and an internal field ~hi/.0136/.0255 r ~mw/.0133~m/.0134due to the magnetic
anisotropic energy density w/.0133~m/.0134. Different particle is char-
acterized by different w/.0133~m/.0134. In our analysis, we assume it
uniaxial with the easy axis along the zdirection, w/.0136
w/.0133cos/.0018/.0134and~hi/.0136/.0255@w/.0133cos/.0018/.0134
@/.0133cos/.0018/.0134^z/.0017f/.0133cos/.0018/.0134^z.According to Eq. ( 1), each field generates two motions, a
precession motion around the field and a damping motiontoward the field as shown in Fig. 1(a). In terms of /.0018and/.0030,
Eq. ( 1) can be rewritten as [ 3]
/.01331/.0135/.00112/.0134_/.0018/.0136h/.0030/.0135/.0011h/.0018/.0255/.0011f/.0133cos/.0018/.0134sin/.0018;
/.01331/.0135/.00112/.0134sin/.0018_/.0030/.0136/.0011h/.0030/.0255h/.0018/.0135f/.0133cos/.0018/.0134sin/.0018:(2)
Hereh/.0018andh/.0030are the field components along ^e/.0018/.0255and
^e/.0030/.0255directions of ~m, respectively.
The switching problem is as follows: in the absence of
an external field, the particle has two stable states, ~m0
(pointA) and/.0255~m0(pointB) along its easy axis as shown
in Fig. 1(b). Initially, the magnetization is ~m0, and the goal
is to reverse it to /.0255~m0by applying an external field. In our
analysis, Gilbert damping constant /.0011and the anisotropy
f/.0133cos/.0018/.0134are the fixed specifications of the problem, and
only applied field variations are investigated. This is incontrast with earlier studies [ 12] where completely differ-
ent analysis was performed. There are an infinite number
of paths that connect the initial and the target state. L1 and
h
m−m h−m (m h )
θ(a)
y
x xyL1
L2Az z
Bφ(b)
FIG. 1. (a) Two motions of magnetization ~munder field ~h:
/.0255~m/.0002~hand/.0255~m/.0002/.0133~m/.0002~h/.0134describe the precession and dis-
sipation motions, respectively. (b) Points AandBrepresent the
initial and the target states, respectively. The solid curve L1 anddashed curve L2 illustrate two possible reversal routes.PRL 97,077205 (2006)PHYSICAL REVIEW LETTERSweek ending
18 AUGUST 2006
0031-9007 =06=97(7)=077205(4) 077205-1 ©2006 The American Physical SocietyL2 in Fig. 1(b) are two examples. Each of these paths can
be used as a magnetization reversal route (path). Let ~hL;s/.0133t/.0134
be the magnetic field pulse of design salong magnetization
reversal route L. To proceed, a few quantities must first be
introduced.
Definition of switching field HL;s.—The switching field
HL;sof design salong route Lis defined to be the largest
magnitude of ~hL;s/.0133t/.0134for allt,HL;s/.0136maxfj~hL;s/.0133t/.0134j;8tg.
Definition of minimal switching field HLon reversal
routeL.—The minimal switching field along route Lis
defined to be the smallest value of HL;sfor all possible
designssthat will force the magnetization to move along
L, i.e.,HL/.0136minfHL;s;8sg.
Definition of theoretical limit of minimal switching field
Hc.—The switching field limit Hcis defined as the smallest
value of HLout of all possible routes, i.e., Hc/.0136
minfHL;8Lg.
If the applied field is restricted to be static, reversal of a
magnetization from AtoBcan only go through so-called
‘‘ringing motion’’ [ 7,8]. The corresponding switching field
forms so-called modified Stoner-Wohlfarth (SW) astroid
[7]. Strictly speaking, these switching fields are not HLthat
exists only for those ballistic reversal paths [ 8]. With the
above remark about a static field, we come back to the firstissue about H
c.
Theorem 1.— For a given uniaxial magnetic anisotropy
specified by f/.0133cos/.0018/.0134/.0136/.0255@w/.0133cos/.0018/.0134
@/.0133cos/.0018/.0134, the theoretical limit of
the minimal switching field is given by Hc/.0136/.0011/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
1/.0135/.00112pQ,
whereQ/.0136maxff/.0133cos/.0018/.0134sin/.0018g,/.00182/.01370;/.0025/.0138.
Proof.— To find the lowest possible switching field, it
should be noticed that field along the radius direction hrof
an external field does not appear in Eq. ( 2). Thus one can
lower the switching field by always putting hr/.01360, and the
magnitude of the external field is h/.0136/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
h2
/.0018/.0135h2
/.0030q
.
According to Eq. ( 2),_/.0018and _/.0030are fully determined by h/.0018
andh/.0030and vice versa. It can be shown that h2can be
expressed in terms of /.0018,/.0030,_/.0018, and _/.0030
g/.0017h2
/.0136/.01331/.0135/.00112/.0134_/.00182/.01352/.0011f/.0133cos/.0018/.0134sin/.0018_/.0018/.0135/.0133/.0011sin/.0018_/.0030/.01342
/.0135sin2/.0018/.0137_/.0030/.0255f/.0133cos/.0018/.0134/.01382: (3)
Hereg/.0133_/.0018;/.0018; _/.0030/.0134does not depend explicitly on /.0030for a
uniaxial model.
In order to find the minimum of g, it can be shown that /.0030
must obey the following equation:
_/.0030/.0136f/.0133cos/.0018/.0134=/.01331/.0135/.00112/.0134; (4)
which is from@g
@_/.0030j/.0133_/.0018;/.0018/.0134/.01360and@2g
@_/.00302j/.0133_/.0018;/.0018/.0134>0.
Equation ( 4) is a necessary condition for the smallest
minimal switching field. This can be understood as fol-
lows. Assume Hcis the minimal switching field along
reversal path Ldescribed by /.0018/.0133t/.0134/.0136/.00181/.0133t/.0134and/.0030/.0133t/.0134/.0136
/.00301/.0133t/.0134[i.e.,Hcis the maximum magnitude of the externalfield that generates the motion of /.00181/.0133t/.0134and/.00301/.0133t/.0134]. If/.00301/.0133t/.0134
does not satisfy Eq. ( 4), then one can construct another
reversal path L/.0003specified by /.0018/.0133t/.0134/.0136/.00181/.0133t/.0134and/.0030/.0133t/.0134/.0136
/.00302/.0133t/.0134, where/.00302/.0133t/.0134satisfies Eq. ( 4). Because /.0018/.0133t/.0134and _/.0018
are exactly the same on both paths LandL/.0003at an arbitrary
timet, the values of g/.0133t/.0134shall be smaller on L/.0003than those
onLat anyt. Thus, the maximum g/.0003/.0136/.0133H/.0003c/.01342ofgonL/.0003
will be also smaller than that ( H2c)o nL, i.e.,H/.0003c<Hc. But
this is in contradiction with the assumption that Hcis the
theoretical limit of the minimal switching field. Hence,/.0030/.0133t/.0134must obey Eq. ( 4) on the optimal path that generates
the smallest switching field, H
c.
Substituting Eq. ( 4) into Eq. ( 3), we have
h2/.0136/.0137/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
1/.0135/.00112p_/.0018/.0135/.0011f/.0133cos/.0018/.0134sin/.0018=/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
1/.0135/.00112p
/.01382:(5)
In order to complete a magnetization reversal, the tra-
jectory must pass through all values of 0/.0020/.0018/.0020/.0025.I n
particular, it must pass through whatever value of /.0018in
that range maximizes f/.0133cos/.0018/.0134sin/.0018on that range. At
that maximizing value of /.0018, the trajectory must be such
that/.0018is nondecreasing, that is _/.0018/.00210, so that the trajec-
tory is proceeding in the correct direction. Substitutingthese constraints into Eq. ( 5), we see that at that point
in the trajectory, hmust be at least
/.0011Q/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
1/.0135/.00112p , where
Q/.0017maxff/.0133cos/.0018/.0134sin/.0018g.—QED.
To have a better picture about what this theoretical limit
Hcis, we consider a well-studied uniaxial model, w/.0133~m/.0134/.0136
/.0255km2z=2,o rf/.0136kcos/.0018. It is easy to show that the largest h
is at/.0018/.0136/.0025=4so thatQ/.0136k=2, and
Hc/.0136/.0011/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
1/.0135/.00112pk
2: (6)
At small damping, Hcis proportional to the damping
constant. The result in the limit of /.0011!0coincides with
the switching field in Ref. [ 9] where the time-dependent
field always follows the motion of magnetization. At thelarge damping, H
capproaches the SW field [ 8] when a
noncollinear static switching field is 135/.0014from the easy
axis. The solid curve in Fig. 2isHcversus/.0011. For com-
parison, the minimal switching fields from other reversalschemes are also plotted. The dotted line is the minimal
switching field when the applied field is always parallel to
FIG. 2. The switching field hcvs damping constant /.0011under
different reversal schemes.PRL 97,077205 (2006)PHYSICAL REVIEW LETTERSweek ending
18 AUGUST 2006
077205-2the motion of the magnetization [ 9]. The curve in square
symbols is the minimal switching field when a circularlypolarized microwave at optimal frequencies is applied [ 9].
The dashed line is minimal switching field under a non-
collinear static field of 135
/.0014to the easy axis. It saturates to
the SW field beyond /.0011c[7,8].
Although the theoretical limit of the switching field is
academically important because it provides a low bound tothe switching field so that one can use the theorem toevaluate the quality of one particular strategy, a designusing a field at the theoretical limit would not be interesting
from a practical point of view because the switching time
would be infinitely long. Thus, it is more important todesign a reversal path and a field pulse such that thereversal time is the shortest when the field magnitude H
(H>H
c) is given. An exact result is given by the follow-
ing theorem.
Theorem 2.— Suppose a field magnitude Hdoes not
depend on time and H>H c. The optimal reversal path
(connects /.0018/.01360and/.0018/.0136/.0025) that gives the shortest switch-
ing time is the magnetization trajectory generated by the
following field pulse ~h/.0133t/.0134,
hr/.0133t/.0134/.01360;h /.0018/.0133t/.0134/.0136/.0011H=/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
1/.0135/.00112p
;
h/.0030/.0133t/.0134/.0136H=/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
1/.0135/.00112p
/.0136h/.0018=/.0011:(7)
Proof.— The reversal time from AtoB[Fig. 1(b)]i sT/.0017R/.0025
0d/.0018= _/.0018. According to Eq. ( 2), one needs /.0133h/.0030/.0135/.0011h/.0018/.0134to
be as large as possible in order to make _/.0018maximal at an
arbitrary/.0018. SinceH2/.0136h2r/.0135h2
/.0018/.0135h2
/.0030, one has the follow-
ing identity:
/.01331/.0135/.00112/.0134H2/.0136/.01331/.0135/.00112/.0134h2r/.0135/.0133h/.0030/.0135/.0011h/.0018/.01342/.0135/.0133h/.0018
/.0255/.0011h/.0030/.01342: (8)
Thus, (h/.0030/.0135/.0011h/.0018) reaches the maximum of/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
1/.0135/.00112p
H
whenhr/.01360andh/.0018/.0136/.0011h/.0030, which lead to Eq. ( 7), are
satisfied.—QED
The optimal shape of field pulse ( 7) appears to depend
only on the Gilbert damping constant /.0011and not on f/.0133cos/.0018/.0134.
However, those expressions provide the components offield magnitude in a coordinate system relative to the
time-varying direction of ~m. The magnetic anisotropy
f/.0133cos/.0018/.0134in part determines the trajectory of ~mwhich in
turn determines the optimal pulse shape when combinedwith the expressions of Eq. ( 7). It should be pointed out
that if they were to change f/.0133cos/.0018/.0134and nothing else, the
time-dependent field pulse would be different.
Under the optimal design of ( 7),/.0030/.0133t/.0134and/.0018/.0133t/.0134satisfy,
respectively, Eq. ( 4) and
_/.0018/.0136H=/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
1/.0135/.00112p
/.0255/.0011f/.0133cos/.0018/.0134sin/.0018=/.01331/.0135/.00112/.0134:(9)
For uniaxial magnetic anisotropy w/.0133~m/.0134/.0136/.0255km2z=2,i ti s
straightforward to integrate Eq. ( 9), and to find the reversal
timeTfromAtoB[Fig. 1(b)], T/.01362
k/.0133/.00112/.01351/.0134/.0025/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
4/.0133/.00112/.01351/.0134H2=k2/.0255/.00112p : (10)
In the weak damping limit /.0011!0,T/.0025/.0025=H while in the
large damping limit /.0011!1 ,T/.0025/.0011/.0025/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
H2/.0255k2=4p !1 . For the
large field H!1 ,T/.0025/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
/.00112/.01351p
/.0025
H, inversely proportional to
the field strength. Thus, it is better to make /.0011as small as
possible. Then the critical field is low, and the speed is fast(T/.0024/.0025=H ). Figure 3shows the field dependence of the
switching time for /.0011/.01360:1, whereTandHare in the units
of2=kandk=2, respectively.
How much could the so-called ballistic (precessional)
reversal strategy [ 7,13] be improved? To answer the ques-
tion, let us compare the switching field and time in theballistic reversal with those of theoretical limits for uniax-ial magnetic anisotropy w/.0133~m/.0134/.0136/.0255km
2z=2and/.0011/.01360:1.
According to Ref. [ 8], the smallest switching field (in
unit ofk=2) for the ballistic connection is H/.01361:02ap-
plied in 97.7/.0014to the easy zaxis, and the corresponding
ballistic reversal time (in unit of 2=k)i sT/.01365:87. On the
other hand, the theoretical limit for the minimal switching
field isHc/.00250:1from Eq. ( 6), about one tenth of the
minimal switching field in the ballistic reversal [ 8]. For
realistic value of /.0011of order of 0.01, the difference between
experimentally achieved low switching field and the theo-retical limit is of the order of hundred times. Thus there is avery large room for an improvement. It is also possible toswitch a magnetization faster than that of the conventional
ballistic reversal by using a smaller field. For example, to
achieve a reversal time of T/.01365:87along the optimal
route, the field magnitude can be as lower as H/.01360:547
(instead of H/.01361:02) according to Fig. 3. To illustrate
what scale of theoretical reversal is being demonstratedhere, let us consider bulk fcc Co parameters of anisotropyconstantK/.01362:7/.000210
6erg=cm3and saturation magneti-
zationMs/.01361445 emu =cm3[14]. Thus the dimensionless
reversal time of T/.01365:87and switching field H/.01360:547
correspond to 178psand0:1T, respectively.
The field pulse given in Eq. ( 7) requires a constant
adjustment of field direction during the magnetization
FIG. 3. The field dependence of Tunder the optimal field pulse
Eq. ( 7) for/.0011/.01360:1. The field is in the unit of k=2and the unit for
time is 2=k.PRL 97,077205 (2006)PHYSICAL REVIEW LETTERSweek ending
18 AUGUST 2006
077205-3reversal. To have a better idea about the type of fields
required, we plot in Fig. 4(a) the time dependence of x,
y, andzcomponent of the field while its magnitude is kept
atH/.01360:547. The time dependence of /.0018and/.0030is also
plotted in Fig. 4(b) and4(c).
Although the Stoner-Wohlfarth problem of magnetiza-
tion reversal for a uniaxial model is of great relevance to
the magnetic nanoparticles, it is interesting to generalize
the results to the nonuniaxial cases. So far, our results areon the magnetic-field induced magnetization reversal; itwill be extremely important to generalize the results to the
spin-torque induced magnetization reversal. It should also
be pointed out that it is an experimental challenge to createa time-dependent field pulse given by Eq. ( 7) in order to
implement the optimal design reported here. This chal-
lenge could be met if a device sensitive to the motion ofa magnetization can be found because a coil can be at-tached to the device to generate the required field. In
principle, one may also use three mutually perpendicular
coils to generate a given time-dependent field. This can beaccomplished by controlling time-dependent electric cur-rents through the coils.
In conclusion, the theoretical limit of the magnetization
switching field for uniaxial Stoner particles is obtained.
The limit is proportional to the damping constant at weakdamping and approaches the SW field at large damping.When the field magnitude is kept to a constant, and the
field direction is allowed to vary, the optimal field pulse
and reversal time are obtained.
This work is supported by UGC, Hong Kong, through
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Phys. Rev. Lett. 90, 017201 (2003); H. W. Schumacher,
C. Chappert, R. C. Sousa, P. P. Freitas, and J. Miltat, Phys.Rev. Lett. 90, 017204 (2003).
[14] J. P. Chen, C. M. Sorensen, K. J. Klabunde, and G. C.
Hadjipanayis, Phys. Rev. B 51, 11 527 (1995).FIG. 4. Time dependence of different field components, /.0018and
/.0030,o f~mfor uniaxial magnetic anisotropy w/.0133~m/.0134/.0136/.0255km2z=2with
/.0011/.01360:1andH/.01360:547when the reversal path is optimal. The
reversal time is T/.01365:87. (a)x,y, andzcomponents of magnetic
field. (b) /.0018/.0133t/.0134. (c)/.0030/.0133t/.0134.PRL 97,077205 (2006)PHYSICAL REVIEW LETTERSweek ending
18 AUGUST 2006
077205-4 |
PhysRevApplied.7.034004.pdf | Gilbert Damping Parameter in MgO-Based Magnetic Tunnel Junctions from First Principles
Hui-Min Tang1and Ke Xia1,2,*
1The Center for Advanced Quantum Studies and Department of Physics,
Beijing Normal University, Beijing 100875, China
2Synergetic Innovation Center for Quantum Effects and Applications (SICQEA),
Hunan Normal University, Changsha 410081, China
(Received 26 November 2016; revised manuscript received 14 February 2017; published 6 March 2017)
We perform a first-principles study of the Gilbert damping parameter ( α) in normal-metal/MgO-cap/
ferromagnet/MgO-barrier/ferromagnetic magnetic tunnel junctions. The damping is enhanced by interface
spin pumping, which can be parametrized by the spin-mixing conductance ( G↑↓). The calculated
dependence of Gilbert damping on the thickness of the MgO capping layer is consistent with experimentand indicates that the decreases in αwith increasing thickness of the MgO capping layer is caused by
suppression of spin pumping. Smaller αcan be achieved by using a clean interface and alloys. For a thick
MgO capping layer, the imaginary part of the spin-mixing conductance nearly equals the real part, and thelarge imaginary mixing conductance implies that the change in the frequency of ferromagnetic resonance
can be observed experimentally. The normal-metal cap significantly affects the Gilbert damping.
DOI: 10.1103/PhysRevApplied.7.034004
I. INTRODUCTION
Magnetic tunnel junctions (MTJs) with an epitaxial (001)-
oriented MgO barrier exhibit a large tunnel magnetoresistance
ratio (TMR) at room temperature, which makes them a goodcandidate for applications in magnetic devices [1–6].A p a r t
from this large TMR ratio, perpendicular magnetic anisotropy
(PMA) and magnetic damping ( α)i nC o F e B =MgO=CoFeB
MTJs have been investigated in detailed studies [7–10].T h e
MTJ is a promising candidate as memory cells in spin-
transfer-torque magnetic random-access memory (STT
MRAM) because of their high thermal stability, low STTswitching current, and high magnetoresistance (MR). To
produce STT MRAM with long retention time [11]as well
as spin-torque oscillators and diodes with stable precession[12–14],al a r g e rP M Ai sn e c e s s a r y .I na d d i t i o n ,t h es w i t c h i n g
current in STT-based devices is proportional to α[15–20],s oa
small αis desired.
Recent experiments show that using a MgO capping layer
on CoFeB =MgO=CoFeB (or FeB) MTJs can increase the
PMA and decrease α[21–24].T h o u g ht h i c k e n i n gt h eM g O
capping layer decreases αand increases the PMA, it also
decreases the TMR [25], so a moderately thick MgO capping
layer is preferable. Tsunegi et al. [22]found α∼0.0054 and
PMA∼3.3erg=cm
2in a MgO-barrier/FeB/MgO-cap struc-
ture with a 0.6-nm MgO capping layer using the spin-torquediode effect. The decreases in αappear to come from
suppression of spin pumping [26,27] at the ferromagnet –
normal-metal (FM/NM) interface [21].H o w e v e r ,M o r i y a m a
et al. [28]measured a large voltage signal in MTJs with an
Al
2O3tunnel barrier, a behavior which cannot be explainedby the spin-pumping mechanism. It is not clear whether spin-
pumping theory is applicable to MgO-based tunnel junctions.
Here, we use first-principles calculations to analyze the
relation between αand spin pumping in NM/MgO/FM MTJs.
Our calculated αestimated from G↑↓agrees well with the
experiment [13], and the imaginary part of G↑↓(G↑↓
i) almost
equals the real part ( G↑↓
r), especially with a thick MgO
capping layer. These results indicate that the decrease in α
comes from the suppression of spin pumping, and the large
G↑↓
iimplies that the change in frequency of the ferromagnetic
resonance can be observed experimentally. A clean interface
and an alloy electrode promote small α. Moreover, we find
that the capping normal metal greatly affects α.
This article is organized as follows. In Sec. II,w e
introduce scattering theory in order to estimate αby the
parameter G↑↓. In Sec. III, we present our results of αin
NM/MgO/FM MTJs. Section IVis our summary.
II. SPIN PUMPING AND GILBERT
DAMPING PARAMETER
For a FM/NM interface, the magnetization in the FM layer
can be simplified as a macrospin M¼MsVm, where mis
the unit vector, Msis the saturation magnetization, and Vis
the total FM volume. When the magnetization precesses, a
spin current Ipump
sis pumped out of the ferromagnet [26]:
Ipump
sðtÞ¼ℏ
4π½G↑↓
rmðtÞ×_mþG↑↓
i_mðtÞ/C138; ð1Þ
where G↑↓¼ðe2=hÞTrðI−r†
↑r↓Þis the spin-mixing con-
ductance, and Iandrσare the unit matrix and the matrix of
interface reflection coefficients for spin σspanned by the
scattering channels at the Fermi energy [29].*kexia@bnu.edu.cnPHYSICAL REVIEW APPLIED 7,034004 (2017)
2331-7019 =17=7(3)=034004(7) 034004-1 © 2017 American Physical SocietyAn immediate consequence of the spin pump is
enhanced Gilbert damping of the magnetization dynamics
[26]. When the NM is an ideal spin sink, the spin backflow
can be disregarded, and by the conservation of the spinangular momentum, enhanced Gilbert damping can be
obtained [30]
α¼γℏ
4πMsVZ
dE/C18
−df
dE/C19
G↑↓
rðEÞ; ð2Þ
where γis the gyromagnetic ratio. At finite temperature, the
volume Vis replaced by the magnetic coherent volume Va
[31,32] . The temperature effects contain two factors: one is the
Fermi-Dirac distribution function f¼expf½ðE−EfÞ=KBT/C138þ
1g−1, and the other is the magnetic coherent volume
Va¼f2=½3ξð5=2Þ/C138g½ð4πDÞ=ðkBTÞ/C1383=2, where ξis the
Riemann ζfunction, Tis the ambient temperature, and D
is the spin stiffness constant. At 0 K, Vaequals Vand
−∂f=∂Ei sr e d u c e dt ot h e δfunction δðE−EfÞat the Fermi
level Ef. In general, the total Gilbert damping contains the
bulk part α0and the interface enhancement part α. In Konoto
et al.’s[21] experiment, α0accounts for 40% of the total
Gilbert damping; however, the decreases in Gilbert dampingwith increasing thickness of the MgO capping layer comes
from the interfacial effect, so we focus on the interface-
enhancement part.
III. GILBERT DAMPING IN
Ag=MgO -CAP =FeMTJS
We consider an Ag =MgO ðxnmÞ=Fe MTJ, as shown in
Fig.1, where the MgO-barrier thickness xranges from 0 to
1.4 nm. In our calculation, we choose bcc Fe as one lead
with the lattice constant a
Fe¼2.866Å, and the crystal
MgO is reduced 4% and rotated 45 to match the bcc Fe. The
lattice constant of fcc Ag is aAg¼4.053Å, and Ag is
matched with MgO. The interlayer spacing between the Ag
monolayer and the MgO surface layer is 2.52 Å for Ag
above the O site [33], For the clean junction, we use a
400×400k-point mesh in the full two-dimensional
Brillouin zone (BZ) to ensure numerical convergence.
For the disordered interface case, we use a 40×40k-point
mesh in the full two-dimensional BZ for a 4×4lateral
supercell, and 12 configurations are used to ensureconfiguration convergence. The scattering matrix is
obtained using a first-principles wave-function methodwith tight-binding linearized muffin-tin orbitals [34].
First, we check how the MgO capping layer and MgO
barrier affect G
↑↓. We study Ag =MgO-cap ðnMLÞ=
Feð18MLÞ=MgO-barrier ðmMLÞ=Fe MTJs, where the
MgO capping layer is nML and the MgO barrier is m
ML. Table Ishows the dependences of G↑↓and TMR on
the thickness of the MgO capping layer and MgO barrier.
When considering the dependence of G↑↓and TMR on n
(m), we fix m(n) equal to 3. The TMR is defined in terms
of the conductance of the magnetization between thetwo Fe layers parallel ( P) and antiparallel (AP): TMR ¼
½ðG
P−GAPÞ=GAP/C138×100% .
Table Ishows that G↑↓decreases with increasing thickness
of the MgO capping layer and does not change significantlywith an increasing thickness of the MgO barrier. Gilbert
damping is estimated from G
↑↓. As we show in Fig. 2,t h e
experimental measurement of G↑↓is dominated by the MgO
capping layer. Thus, we can choose the Ag =MgO-cap =Fe
structure to study how the MgO capping layer affects theGilbert damping of Ag =MgO-cap =Fe=MgO-barrier =
Fe MTJs.
The MgO capping layer and MgO barrier have a different
effect on the TMR. The TMR decreases with increasingthickness of the MgO capping layer and increases with anincreasing thickness of the MgO barrier, which agrees withprevious experiments [25].
Based on scattering theory, αis proportional to G
↑↓
r,
which is related to the in-plane part of the spin current. Weestimate αfrom Eq. (2). Figure 2shows the αdependences
of the MgO capping layer thickness of Ag =MgO ðxnmÞ=Fe
MTJs with 6.25% OVs at all Fe =MgO and Ag =MgO
interfaces, with the thickness of the MgO capping layer
ranging from 0 to 1.4 nm. αdecays exponentially (inset
of Fig. 2) with the thickness of the MgO capping layer.
FIG. 1. Schematic Ag =MgO-cap ð001Þ=Fe MTJs with five
MgO monolayers. The red and green atoms in the scatteringregion (MgO) denote O and Mg, the gray atoms on the left leadsdenote Ag, and the blue atoms denote Fe. There are some oxygenvacancies (OVs, yellow) at the two interfaces.TABLE I. Dependences of the spin-mixing conductance ( G↑↓)
(in units of 1013Ω−1m−2) and the TMR on the thickness of the
MgO capping layer with a 3-ML MgO barrier and on thethickness of the MgO barrier with a 3-ML MgO capping layerin Ag =MgO-cap ðnMLÞ=Feð18MLÞ=MgO-barrier ðmMLÞ=Fe
MTJs with a clean interface and an interface with 6.25% OVs(in brackets). nis the number of MgO layers.
n(m¼3) G
↑↓
r G↑↓
iTMR (%)
2 1.991(4.252) 0.772(1.174) 1027.5(97.1)
3 0.119(0.315) 0.119(0.289) 449.5(29.1)4 0.009(0.056) 0.016(0.051) 321.0(31.5)5 0.002(0.011) 0.003(0.014) 209.1(2.88)m(n¼3)
2 0.158(0.380) 0.145(0.298) 245.2(1.10)3 0.119(0.315) 0.119(0.289) 449.5(29.1)4 0.099(0.314) 0.105(0.297) 918.9(91.2)5 0.091(0.314) 0.101(0.233) 1288.3(97.4)HUI-MIN TANG and KE XIA PHYS. REV. APPLIED 7,034004 (2017)
034004-2Δα¼0.0029 atT¼0K and Δα¼0.01atT¼300K,
the second result of which is comparable to earlier
experimental results [21]Δα¼0.007at room temperature
in Ta =MgO ð0–1.9nmÞ=Fe80B20=MgO ð1nmÞ=Ta MTJs.
As shown in Fig. 2,αdecreases as the MgO capping
layer thickens, which agrees well with the experiment. The
good agreement between our calculations and experimentalresults indicates that the decreases in αare related to the
suppression of the spin-pumping effects through the FM/
NM interface, with inserting MgO layers.
To understand why αdecreases as the MgO capping
layer thickens, we compare the spin-dependent conduct-
ance G
↑,G↓[G↑ð↓Þ¼ðe2=hÞTrðt†
↑ð↓Þt↑ð↓Þ)] and G↑↓
rfor
various thicknesses of the MgO capping layer, as shown in
Fig.3.G↑,G↓, and G↑↓
rof the sample with the thinnest
MgO layer are much larger than those of the thickersample, showing an exponential decay as a function of
MgO thickness (inset of Fig. 3).αis estimated from G↑↓
r,
and these results indicate that the decrease in αis related to
the decrease in spin-dependent conductance.
We plot the k∥-resolved transmission and G↑↓
rat the
Fermi energy for the epitaxial Ag =MgO ð3MLÞ=Fe MTJs
with a clean interface, as shown in Figs. 4(a)–4(c). The
logarithm function is applied to the transmission coeffi-cient, and the red (blue) color represents a high- (low-)
transmission probability. We find that the majority-spin
channel mainly comes from k
∥points near the Γpoint andthat the minority-spin channel comes from bright k∥points
near the boundary of the BZ. The G↑↓
rchannel contains
features of both the majority and minority spins, indicating
thatG↑↓
ris related to spin-dependent conductance. The G↑↓
r
channel in some kpoints is larger than 1, such as G↑↓
r¼
1.99atkxa0¼0.7645 andkya0¼2.8926 , as shown with
red circles in Fig. 4(c), where a0¼0.286nm is the lattice
constant of Fe. These large G↑↓
rchannels are caused by the
resonant states at those kpoints.
To understand how the interface roughness affects α,w e
study G↑,G↓, and G↑↓
rwith clean 4% OVs and 6.25% OVs
at the Fe =MgO and Ag =MgO interfaces, as shown in Fig. 3.
G↑,G↓, and G↑↓
rare larger for the Fe =MgO and Ag =MgO
interfaces with OVs than for the clean interfaces. Thevalues increase at a higher concentration of OVs. Thisresult agrees with previous studies of FeCo =MgO =FeCo
MTJs [35].
As shown in Fig. 5, the origin of the increment of G
↑and
G↓for Fe =MgO and Ag =MgO interfaces with OVs that the
transmission channels spread much wider into the BZ dueto the diffusive scattering with interface roughness. Thus,FIG. 2. Gilbert damping parameter in Ag =MgO ð0–1.4nmÞ=Fe
MTJs as a function of MgO thickness in the presence of 6.25%OVs at the Fe =MgO and Ag =MgO interfaces at T¼0and 300 K.
L
MgO ¼0nm is calculated from the Ag =Fe interface. For the case
at 0 K, we assume 16-ML Fe (about 2 nm). Δα¼αðxÞ-αðx¼∞Þ.
αis estimated from Eq. (2), and the temperature effect is
considered including both the Fermi-Dirac distribution and themagnetic coherent volume effect. The blue stars are the exper-imental values [21] of the Ta =MgO ð0–1.9nmÞ=Fe
80B20=
MgO ð1nmÞ=Ta MTJs. The inset picture is the logarithmic
coordinates for the yaxis.FIG. 3. Spin-dependent conductance G↑,G↓(in units of
1013Ω−1m−2) and G↑↓
r(in units of 1013Ω−1m−2)i n
Ag=MgO ð0–1.4nmÞ=Fe MTJs as a function of MgO thickness
in the presence of a clean interface, 4% OVs, and 6.25% OVs at
the Fe =MgO and Ag =MgO interfaces. G↑,G↓, and G↑↓
rdecrease
with thickening of the MgO capping layer, and the results at therough interface are larger than at the clean interface. αis
estimated from G↑↓
r.GILBERT DAMPING PARAMETER IN MGO-BASED … PHYS. REV. APPLIED 7,034004 (2017)
034004-3theG↑andG↑after integrating over the entire BZ is larger
for the rough interface than for the clean interface. G↑↓
ris
determined by the coupling between the incoming states(arriving to interface) and magnetizations. The diffusion
scattering enhances the conductance electrons, which also
enhances the G↑↓
randαfor interfaces with OVs, so the
clean interface is better for decreasing smaller α.
The ferromagnetic alloys FeCo and FeCoB are mostly
used as spin sources in MgO-based multilayer structures
because of their perpendicular magnetic anisotropy.Table IIlists the parameters G
↑,G↓,G↑↓
r, and αfor
FeCo =MgO MTJs. We consider two kinds of structures:
crystalline and alloy FeCo structures. The crystalline FeCostructure consists of alternating Fe and Co atomic layers
along bcc (001), which can form a Fe- (Co-) terminated
interface with MgO referred to as the “Fe (Co) term. ”For
the alloy structure, Fe and Co in every layer (including theinterface layer) are randomly distributed, and we consider
three different compositions of Fe
xCo1−x, where xis the
concentration of Fe.
The magnetization of Co is smaller than that of Fe, so the
total magnetization MsVis different between Fe and FeCo.
The total magnetizations are 2.36, 2.31, 2.18, 1.98, 2.27,
and2.22μBin Fe, Fe 0.75Co0.25,F e 0.5Co0.5,F e 0.25Co0.75,F e
term, and Co term, respectively, for 1-ML ferromagnetic
layers, where μBis the Bohr magneton.
Table IIshows that the spin-dependent conductance and
G↑↓
rare larger in junctions with Fe as the lead. Both
crystalline and alloy FeCo decrease the value of αto lower
than that with a Fe lead at T¼300K. When Fe and Co
atoms form an alloy, the interfacial resonant states aresuppressed by the random distribution of atoms at the
interface, reducing α. The value of αfor Co term is smaller
than for all the other structures. For example, for 2LMgO
layers, α¼0.346in the Co-term crystalline FeCo structure,
which is about 47% smaller than that for the Fe lead. These
FIG. 4. k∥-resolved electron transmission probability for
(a)–(c) Ag =MgO ð3MLÞ=Fe with a clean interface, (d) –(f)
Ir=MgO ð3MLÞ=Fe with a clean interface, and (g) –(i)
Pt=MgO ð3MLÞ=Fe with a clean interface at the Fermi energy:
(a),(d),(g) for majority-spin ( G↑) channels, (b),(e),(h) for minor-
ity-spin channels ( G↓), and (c),(f),(i) for G↑↓
rchannels. Resonant
tunnel reflection features are shown with red circles.
FIG. 5. k∥-resolved electron transmission probability for
Ag=MgO ð3MLÞ=Fe with 6.25% OVs at both the Fe =MgO
and Ag =MgO interfaces: (a) majority-spin ( G↑) channels,
(b) minority-spin ( G↓) channels. This calculation for electron
transmission probability is based on the Keldysh nonequilibriumGreen ’s function [35,36] .TABLE II. Spin-dependent conductances G↑,G↓,G↑↓
r(in units
of1013Ω−1m−2) and α(T¼300K) in Ag =MgO ðnMLÞ=FM
MTJs with clean interfaces. FM indicates Fe, crystalline, andalloy FeCo structures. Fe term (Co term) indicates that MgO isattached to both Fe (Co) layers of the crystalline FeCo. nis the
number of MgO layers, and n¼3is about 0.61 nm.
n FM G
↑G↓G↑↓
r αð10−3Þ
2 Fe 2.37 0.74 2.67 0.652
Fe0.25Co0.75 2.32 0.50 1.61 0.455
Fe0.5Co0.5 2.37 0.65 1.64 0.460
Fe0.75Co0.25 2.40 0.96 1.89 0.527
Fe term 2.63 0.31 1.80 0.532
Co term 2.07 0.04 1.22 0.346
3 Fe 0.49 0.07 0.31 0.086
Fe0.25Co0.75 0.47 0.05 0.27 0.077
Fe0.5Co0.5 0.48 0.05 0.27 0.081
Fe0.75Co0.25 0.51 0.06 0.29 0.083
Fe term 0.52 0.03 0.29 0.085
Co term 0.41 0.003 0.22 0.063
TABLE III. G↑↓
r,G↑↓
i(in units of 1013Ω−1m−2) dependence
on MgO thickness in Fe =MgO =Ag MTJs with a clean interface
and with 6.25% OVs at both the Fe =MgO and Ag =MgO
interfaces (in brackets). nis the number of MgO layers and
LMgOis the corresponding distance in nanometers. The last row
Fe=Ag is n¼0.
nL MgO (nm) G↑↓
r G↑↓
i
2 0.41 2.6731(4.9641) 0.6191(0.7751)
3 0.61 0.3144(0.4907) 0.1977(0.2373)4 0.81 0.0474(0.0750) 0.0378(0.0553)5 1.01 0.0096(0.0162) 0.0088(0.0142)6 1.22 0.0021(0.0040) 0.0020(0.0040)7 1.42 0.0005(0.0011) 0.0005(0.0011)Fe=Ag 0 45.81 −0.11HUI-MIN TANG and KE XIA PHYS. REV. APPLIED 7,034004 (2017)
034004-4results indicate that the FeCo lead is better for reducing α,
especially for the Co-term crystalline FeCo structure.
From Eq. (1),G↑↓
iis related to the out-of-plane part of
the spin current. The out-of-plane spin current can be
ignored at the NM/FM interface because G↑↓
iis 2 orders of
magnitude smaller than G↑↓
r(the value for the Fe =Ag
interface in Table III). Our results indicate that the out-of-
plane part of the spin current cannot be neglected compared
with the in-plane part in the MgO-based MTJs, especially
with a thick MgO capping layer (see Table III).
G↑↓
imodifies the gyromagnetic ratio and the frequency
of ferromagnetic resonance [37]:ð1=γeffÞ¼ð 1=γÞ×
f1−½ðℏγG↑↓
iÞ=ð4πMsVÞ/C138g, the frequency ω¼γHeff,
the change of the frequency is Δω¼½1=ð1−ℏγG↑↓
i=
4πMsVÞ−1/C138ω. In our calculations, G↑↓
i¼0.78×
1013Ω−1m−2for 2-ML MgO with 6.25% OVs rough-
ness at both interfaces, the frequency of the resonances inthe MgO-based MTJ is about ω¼2–14GHz [38], which
modifies the frequency by Δω¼0.46–3.22MHz at room
temperature and should be able to be observedexperimentally.
To understand the effects of capping NMs, we study
various NMs on the MgO =Fe interface. Table IVlists the
calculated G
↑,G↓, and G↑↓
rin NM =MgO ðnMLÞ=Fe MTJs
with a clean interface. We consider Ir, Pt, and Ag as NMsfor 2- and 3-ML MgO layers. We choose fcc Pt (Ir) with the
lattice constant a
Pt¼3.9242 Å(aIr¼3.839Å). The in-
plane lattice constant of the NM is matched with MgO, andthe interlayer spacing between the NM monolayer and theMgO surface layer is 2.364 (2.305) Å for Pt (Ir) above theO site to ensure the space fulfilling.
We find that both spin-dependent conductance and G
↑↓
r
in Ir=MgO =Fe structures are higher than in Pt =MgO =Fe
and Ag =MgO=Fe. To understand the difference, we plot the
k∥-resolved transmission and G↑↓
rfor Ir =MgO ð3MLÞ=Fe
and Pt =MgO ð3MLÞ=Fe MTJs at the Fermi energy, as
shown in Figs. 4(d)–4(i).G↑↓
ris dominated by the area near
theΓpoint of the 3-ML MgO barrier, and the transmission
probability and area are larger in Ir than in Pt and Ag as aNM. The band structures along the fcc (001) of Ag, Ir, andPt are analyzed in the following to further understand theirdifference, as shown in Fig. 6. The main contribution to
the transmission channel is the Δ
1state of MgO-based
MTJs [3]. The kinetic energy in the Ir junction is larger than
in Pt and Ag at the Fermi energy, so G↑↓
ris larger in
Ir=MgO =Fe MTJs.
Table IVshows that G↑↓
ris larger than the spin-dependent
conductance of Ir =MgO ð2MLÞ=Fe junctions. The relative
spin-mixing conductance [39] η¼2G↑↓
r=ðG↑þG↓Þ¼2.5.
The large ηimplies a large skewness of the angular-
dependent STT of Fe =MgO =Ir structures, which makes this
material promising for applications in high-frequency gen-
erators [40].
IV. SUMMARY
We estimate G↑↓in Ag =MgO ðnMLÞ=Fe MTJs. At
room temperature, our calculated αis consistent with the
experimental results. The decrease in αis related to the
suppression of spin-pumping effects in the Fe =Ag interface
caused by inserted MgO layers. Our calculations show that
both the interface roughness and site disorder in the
ferromagnetic layer affect α, while a clean interface and
alloy electrode are better for obtaining smaller α:G↑↓
iis
nearly equal to G↑↓
rin the MgO-based MTJs, and the
capping NM material affects α.
ACKNOWLEDGMENTS
We gratefully acknowledge financial support from the
National Natural Science Foundation of China (Grants
No. 61376105 and No. 21421003).
[1] S. S. Parkin, C. Kaiser, A. Panchula, P. M. Rice, B. Hughes,
M. Samant, and S.-H. Yang, Giant tunnelling magneto-resistance at room temperature with MgO (100) tunnelbarriers, Nat. Mater. 3, 862 (2004) .TABLE IV. The calculated G↑,G↓, and G↑↓
r(in units of
1013Ω−1m−2)i nN M =MgO ðnMLÞ=Fe MTJs with a clean
interface. NM is Ir, Pt, and Ag; nis the number of MgO layers.
n NM G↑G↓G↑↓
r
2 Ir 5.01 2.55 9.33
Pt 3.67 0.78 3.71
Ag 2.37 0.74 2.67
3 Ir 1.24 0.09 0.88
Pt 0.86 0.04 0.52
Ag 0.49 0.07 0.31
FIG. 6. Band structures of Ag, Ir, and Pt along (001), with theFermi level fixed at 0 eV (indicated by the dotted line).GILBERT DAMPING PARAMETER IN MGO-BASED … PHYS. REV. APPLIED 7,034004 (2017)
034004-5[2] S. Yuasa, T. Nagahama, A. Fukushima, Y. Suzuki, and K.
Ando, Giant room-temperature magnetoresistance in single-crystal Fe =MgO =Fe magnetic tunnel junctions, Nat. Mater.
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034004-7 |
PhysRevB.95.174407.pdf | PHYSICAL REVIEW B 95, 174407 (2017)
Ultrafast optical excitation of coherent magnons in antiferromagnetic NiO
Christian Tzschaschel,1,*Kensuke Otani,2Ryugo Iida,2Tsutomu Shimura,2Hiroaki Ueda,3
Stefan Günther,1Manfred Fiebig,1and Takuya Satoh1,2,4
1Department of Materials, ETH Zurich, 8093 Zurich, Switzerland
2Institute of Industrial Science, The University of Tokyo, Tokyo 153-5805, Japan
3Department of Chemistry, Kyoto University, Kyoto 606-8502, Japan
4Department of Physics, Kyushu University, Fukuoka 819-0395, Japan
(Received 30 January 2017; revised manuscript received 3 April 2017; published 5 May 2017)
In experiment and theory, we resolve the mechanism of ultrafast optical magnon excitation in antiferromagnetic
NiO. We employ time-resolved optical two-color pump-probe measurements to study the coherent nonthermalspin dynamics. Optical pumping and probing with linearly and circularly polarized light along the optic axisof the NiO crystal scrutinizes the mechanism behind the ultrafast magnon excitation. A phenomenologicalsymmetry-based theory links these experimental results to expressions for the optically induced magnetizationvia the inverse Faraday effect and the inverse Cotton-Mouton effect. We obtain striking agreement betweenexperiment and theory that, furthermore, allows us to extract information about the spin domain distribution. Wealso find that in NiO the energy transfer into the magnon mode via the inverse Cotton-Mouton effect is aboutthree orders of magnitude more efficient than via the inverse Faraday effect.
DOI: 10.1103/PhysRevB.95.174407
I. INTRODUCTION
Antiferromagnetism is rapidly gaining importance as a cru-
cial ingredient of spintronics applications [ 1,2]. Because of the
absence of a net magnetization in the ground state, it is robustagainst externally applied fields and the formation of domainsis not obstructed by magnetic stray fields. Accordingly, thetechnologies envisaged are mainly based on the application ofspin currents instead of magnetic fields [ 3–9]. In addition, the
intimate coupling of the sublattice magnetizations in antifer-romagnets in combination with a strong exchange interactionbetween neighboring spins implies magnetization-dynamicaltimescales, which are typically orders of magnitude faster thanthose of ferro- or ferrimagnetic materials [ 10]. Naturally, ultra-
short laser pulses come to mind when accessing the dynamicalproperties of the antiferromagnetic order. In contrast to thermalapproaches, which are based on local heating of the electronicand magnetic systems [ 11], nonthermal excitations would pro-
vide a quasi-instantaneous access to the antiferromagnetic spinsystem via spin-orbit coupling. Thus they can fully exploit thefaster timescales inherent to antiferromagnets. The two mostprominent nonthermal magneto-optical effects are the inverseFaraday effect (IFE) [ 12] and the inverse Cotton-Mouton
effect (ICME) [ 13]. In a qualitative picture, they represent
impulsive stimulated Raman scattering processes, where theIFE is described by an antisymmetric tensor and the ICME by asymmetric tensor [ 14–16]. Consequently, the magneto-optical
coupling effectively exerts a torque onto the spin system.
The IFE and ICME have been applied to a variety of mate-
rial systems [ 17–24], but a clean discrimination in experiment
and theory between the two effects for a pure antiferromagnetis still due. A particularly obvious candidate for such ananalysis is antiferromagnetic NiO because of its high orderingtemperature, its simple crystallographic structure, and its well-researched physical properties [ 25–34]. In addition, it may be
*christian.tzschaschel@mat.ethz.chan excellent candidate for a clear and insightful experimental
and theoretical discrimination between IFE and ICME becauseit has been speculated that in NiO the symmetric part issignificantly larger than the antisymmetric part of the Ramanscattering tensor [ 31]. Consequently, the ICME would be more
pronounced than the IFE, even though the ICME is a second-order effect in the magnetic order parameter. Unfortunately,the pronounced magnetic birefringence of NiO [ 28] leads to
an inseparable mixture of the polarization-dependent Ramancontributions. Hence the spin oscillations observed in NiOare to date generally induced by such mixture of IFE andICME. Consequently, the mechanism behind the nonthermalexcitation of coherent magnons in NiO has not been identified,let alone quantified [ 35–40].
In this paper, we present a comprehensive experimental
and theoretical analysis of IFE and ICME in antiferromagneticNiO. We separate the two effects in a nonthermal polarization-dependent two-color pump-probe measurement. The birefrin-gence resulting from the optical anisotropy is avoided byapplying our measurements to a specific single-domain state.The combination with a symmetry-based phenomenologicaltheory that we develop for quantifying IFE and ICME allowsus to distinguish between the two effects and clarify the drivingforce exciting the magnon oscillations in NiO. Moreover, wecompare the magnon generation efficiencies of the two effects.
The paper is organized as follows: the crystallographic
and magnetic lattices of NiO are reviewed in Sec. IAwith
a special focus on the domain structure. We describe themagneto-optical properties in Sec. II A. Subsequently, based
on that description, we develop a theory for the inversemagneto-optical effects in NiO in Sec. II B. In Sec. III A ,t h e
optical pump-probe setup is described, and the results of thetheory sections are converted into experimental configurationsthat enable IFE and ICME to be measured and distinguished.Sections III B andIII C present the experimental results ob-
tained by linear and circular pump polarizations, respectively.They are discussed in detail in Sec. IV, where we show
that magnon excitation via the ICME in NiO is significantly
2469-9950/2017/95(17)/174407(11) 174407-1 ©2017 American Physical SocietyCHRISTIAN TZSCHASCHEL et al. PHYSICAL REVIEW B 95, 174407 (2017)
FIG. 1. (a) Crystallographic and magnetic structure of NiO in
the defined coordinate system. (b) Graphical representation of the
spin dynamics for the in-plane mode and (c) out-of-plane mode. (d)Schematic of the experimental geometry. θdenotes the azimuth angle
of the pump polarization relative to the easy axis of the spins, whereas
ψparameterizes the setting of the Wollaston prism. The probe pulse
is always circularly polarized.
more efficient than via the IFE. In Sec. V, conclusions are
presented.
A. NiO structure
NiO is a type-II antiferromagnet with a Néel temperature
TNof 523 K [ 27]. In the paramagnetic phase, the crystal
has the NaCl-type structure (point group m¯3m). Below TN,
spins are coupled ferromagnetically within the {111}planes
with neighboring planes being coupled antiferromagnetically[Fig. 1(a)][26]. Furthermore, in the antiferromagnetic phase,
there is a rhombohedral distortion along the /angbracketleft111/angbracketrightdirection
arising from exchange striction. This distortion correspondsto a reduction of the crystallographic point symmetry to
¯3mand induces a significant uniaxial optical anisotropy of
/Delta1n=0.003 [ 28]. The optic axis forms along the direction of
the distortion. Because the four independent /angbracketleft111/angbracketrightdirections
([111] ,[11¯1],[1¯11],[¯111]) are energetically degenerate in the
paramagnetic phase, the rhombohedral distortion can occuralong any of those directions leading to four twin-domainstates commonly referred to as T-domain states ( T
0−T3).
The four T-domain states can be distinguished by their linear
birefringence [ 41].
Within each T-domain state, spins point in one of three
independent /angbracketleft11¯2/angbracketrightdirections that are perpendicular to the
direction of the rhombohedral distortion [ 30]. This creates the
formation of three spin domain states, commonly referred to asS-domain states, S
1−S3, leading to a total of twelve possible
orientation domain states in NiO [ 34]. The formation of the
Sdomains leads to another small magnetostrictive distortion,corresponding to a reduced crystallographic point symmetry
2/m, which is also the point symmetry of the magnetic lattice
[32,42]. This distortion, as well as the resulting linear bire-
fringence, are approximately two orders of magnitude smallerthan that associated with the Tdomains [ 29] so that they have
negligible influence on the polarization of the propagatingpump and probe light. For the symmetry-based polarizationanalysis, however, the full magnetic 2 /msymmetry needs
to be considered, as we shall see later. Antiferromagneticordering along the [11 ¯2] direction breaks the threefold
rotational symmetry; for the resulting 2 /msymmetry the
twofold axis is perpendicular to both the rhombohedraldistortion and the easy axis of the spins, i.e., along [1 ¯10].
With the two sublattice magnetizations M
1(t) and M2(t),
we define the ferromagnetic vector M(t)=M1(t)+M2(t) and
the antiferromagnetic vector L(t)=M1(t)−M2(t). To study
dynamics, it is convenient to split both quantities into a time-independent ground state and describe the excitation by a time-dependent contribution:
M(t)=M
0+m(t)=m(t), (1a)
L(t)=L0+l(t). (1b)
The dynamic contribution may be a superposition of the two
eigenmodes of the two sublattice antiferromagnetic system,both of which are optically excitable in NiO [ 35]. For the
in-plane mode (IPM), also termed B
gmode, the modulation of
the antiferromagnetic vector l(t)i sa l o n gt h e[ 1 ¯10] direction,
i.e., it occurs within the sheets of ferromagnetically coupledspins. The oscillating magnetization m(t), in contrast, is
along the [111] out-of-plane direction. The frequency of thismode is /Omega1
IPM/2π/similarequal0.14 THz at 77 K [ 33,35]. The opposite
behavior occurs for the out-of-plane mode (OPM), also termedA
gmode. The antiferromagnetic vector is modulated along
the [111] direction, whereas the magnetization oscillatesalong [1 ¯10]. The eigenfrequency of the out-of-plane mode
is/Omega1
OPM/2π/similarequal1.0 7T H za t7 7K[ 27,31,35–40,43,44].
In contrast to previous publications [ 35], we specifically
consider a T0domain on a (111)-cut NiO sample, where the
rhombohedral distortion is along the surface normal. There-fore, the optic axis coincides with the propagation direction oflight at normal incidence and optical anisotropy, especially lin-ear birefringence, can be avoided. For this situation, we define areference system: we choose the xaxis to be along the surface
normal, i.e., the [111] direction, the zaxis to be along the
magnetic easy axis, i.e., the [11 ¯2] direction, and the yaxis per-
pendicular to both to form a right-handed coordinate system,i.e., along [1 ¯10]. The orientation is shown in Fig. 1together
with a schematic representation of the spin motion for the in-plane mode [Fig. 1(b)] and the out-of-plane mode [Fig. 1(c)].
Using this notation, Eqs. ( 1a) and ( 1b) can be expressed as
M(t)=⎛
⎝m
x(t)
my(t)
0⎞
⎠, (2a)
L(t)=⎛
⎝0
0
Lz⎞
⎠+⎛
⎝lx(t)
ly(t)
0⎞
⎠. (2b)
174407-2ULTRAFAST OPTICAL EXCITATION OF COHERENT . . . PHYSICAL REVIEW B 95, 174407 (2017)
Here, mxandlyare contributions purely from the in-plane
mode, whereas myandlxoriginate from the out-of-plane
mode.
II. PHENOMENOLOGICAL THEORY
OF MAGNETO-OPTICAL AND INVERSE
MAGNETO-OPTICAL EFFECTS IN NiO
We briefly review the phenomenological theory of the Fara-
day effect as well as the Cotton-Mouton effect, both of whichare used to detect magnon oscillations in NiO. Furthermore,a phenomenological theory of the inverse magneto-opticaleffects, i.e., the IFE and the ICME, is presented, whichenables the different magnon excitation mechanisms to bedistinguished. These discussions are accompanied by a specialconsideration of the point-group symmetry of NiO.
Light-matter interaction is typically described by an inter-
action Hamiltonian which, in cgs units, reads [ 45]
H
int=−/epsilon1ij(M,L)
16πEi(t)E∗
j(t). (3)
Here, /epsilon1ij(M,L) is the dielectric tensor, which is in general
a complex function of MandL, and Eiis the electric field
amplitude with Ei(t)=/Rfractur[Ei(t)eiωt][18,46]. We assume light
propagating in xdirection. Thus E=(0,Ey(t),Ez(t)).
Expanding the dielectric tensor into a power series in M
andL, we obtain with magneto-optical coupling constants kijk
andgijkl[47,48]:
/epsilon1ij=/epsilon1(0)
ij+ikM
ijkMk+ikL
ijkLk
+gMM
ijklMkMl+gLL
ijklLkLl+gML
ijklMkLl. (4)
As|M|/lessmuch| L|, the term quadratic in Mcan be neglected.
For symmetry reasons, only even orders in Lcan give
nonvanishing contributions to the dielectric tensor. This leadsto the simplified equation
/epsilon1
ij=/epsilon1(0)
ij+ikM
ijkMk+gLL
ijklLkLl. (5)
Note that because of the ac character of Mk(/Omega1) andLk(/Omega1)t h e
magneto-optical coupling constants kM
ijkandgLL
ijklwill depend
on the frequency /Omega1. For simplicity, we will henceforth omit
the superscripts M and LL as well as the argument /Omega1.
Considering the complex dielectric tensor /epsilon1ij(M,L) and the
Onsager principle, the absence of absorption leads to
/epsilon1ij(M,L)=/epsilon1∗
ji(M,L)=/epsilon1∗
ij(−M,L)=/epsilon1∗
ij(M,−L).(6)
Here, /epsilon1∗
ijdenotes the complex conjugate of /epsilon1ij. Equation ( 6)
indicates that the diagonal components /epsilon1iiare purely real,
whereas the off-diagonal components are in general complex./Rfractur[/epsilon1
ij] is a symmetric tensor, whereas /Ifractur[/epsilon1ij] is antisymmetric.
Consequently, the nonzero coefficients in Eq. ( 5) are real-
valued and satisfy kijk=−kjikandgijkl=gjikl=gijlk=
gjilk. As the birefringence caused by the magnetostriction is
neglected in our symmetry analysis [ 29], we set /epsilon1(0)
yy=/epsilon1(0)
zz≡
/epsilon1(0)and/epsilon1(0)
yz=/epsilon1(0)
zy≡0. Considering an electromagnetic wave
propagating in xdirection, we neglect all xcomponents of
the dielectric tensor and assume the following ansatz for theremaining tensor components:
/parenleftbigg
/epsilon1yy/epsilon1yz
/epsilon1zy/epsilon1zz/parenrightbigg
=/parenleftbigg
/epsilon1(0)+/tildewideαyβ+iξ
β−iξ /epsilon1(0)+/tildewideαz/parenrightbigg
. (7)
With Eq. ( 5) we identify
/tildewideαy=gyyzzLzLz+gyyzxLzlx, (8a)
/tildewideαz=gzzzzLzLz+gzzzxLzlx, (8b)
β=gyzzyLzly, (8c)
ξ=kyzxmx. (8d)
All other possible contributions to gijklandkijkvanish in
compliance with the 2 /msymmetry of the antiferromagnetic
order [ 42,48]. As the static magnetic linear birefringence
expressed by Eqs. ( 8a) and ( 8b) was not resolved, we assume
gyyzz≈gzzzzand redefine:
/epsilon1(0)+/tildewideαy=/epsilon1/prime+αy, (9a)
/epsilon1(0)+/tildewideαz=/epsilon1/prime+αz, (9b)
with
αy=gyyzxLzlx, (10a)
αz=gzzzxLzlx. (10b)
A. Magneto-optical effects
We now discuss the eigenvalues and eigenpolarizations of
Eq. ( 7) in the simplified case, where only one of the quantities
α,β orξis nonzero. The square roots of these eigenvalues are
the refractive indices corresponding to the eigenpolarizations.We show that ξleads to the Faraday effect, i.e., circular
birefringence, whereas αandβinduce a linear birefringence
thus leading to the Cotton-Mouton effect.
1.ξ/negationslash=0andα=β=0
The refractive indices N±and corresponding eigenpolar-
izations E±are
N±=/radicalbig
/epsilon1/prime±ξ (11a)
E±=E0√
2exp/bracketleftbigg
iω/parenleftbigg
t−N±
cx/parenrightbigg/bracketrightbigg
(ˆy∓iˆz). (11b)
Here, ˆyand ˆzcorrespond to unit vectors along the yand
zdirections, ωis the angular frequency of the light, and
cis the speed of light. Thus the eigenpolarizations E±
describe circularly polarized waves ( σ±), which are subject to
different refractive indices N±. Typically, with /epsilon1/prime/greatermuch|kyzxmx|,
the circular birefringence /Delta1N=N+−N−≈kyzxmx/√
/epsilon1/primeis
linear in mxand results in a rotation of the plane of polarization
of linearly polarized light by
φF=−ωdkyzxmx
c√
/epsilon1/prime∝mx, (12)
where dis the sample thickness. Therefore the magnetization
component mxcan be studied by analyzing the Faraday
rotation of linearly polarized light.
174407-3CHRISTIAN TZSCHASCHEL et al. PHYSICAL REVIEW B 95, 174407 (2017)
2.β/negationslash=0andα=ξ=0
The eigenvalues N±45◦and the corresponding eigenpolar-
izations E±45◦are
N±45◦=/radicalbig
/epsilon1/prime±β, (13a)
E±45◦=E0√
2exp/bracketleftbigg
iω/parenleftbigg
t−N±45◦
cx/parenrightbigg/bracketrightbigg
(ˆy±ˆz).(13b)
The eigenpolarizations are linearly polarized with angle ±45◦
relative to the ydirection. Over a propagation distance d,t h i s
linear birefringence induces a phase difference of
φ45◦≈ωdgyzzyLzly
c√
/epsilon1/prime∝ly. (14)
Incident circularly polarized light thus becomes elliptically
polarized with principal axes along the yandzdirections.
3.α/negationslash=0andβ=ξ=0
The refractive indices Ny,zand eigenpolarizations Ey,zare
Ny,z=/radicalbig
/epsilon1/prime+αy,z, (15a)
Ey=E0exp/bracketleftbigg
iω/parenleftbigg
t−Ny
cx/parenrightbigg/bracketrightbigg
ˆy,
Ez=E0exp/bracketleftbigg
iω/parenleftbigg
t−Nz
cx/parenrightbigg/bracketrightbigg
ˆz. (15b)
Hence the eigenpolarizations are linearly polarized along the
yandzdirections with different refractive indices Ny,z.O v e r
a propagation distance d, this linear birefringence induces a
phase difference of
φyz≈ωd(gyyzx−gzzzx)Lzlx
2c√
/epsilon1/prime∝lx. (16)
Consequently, circularly polarized light becomes ellipti-
cally polarized with principal axes aligned at ±45◦.T h e
magnetically induced linear birefringence observed in cases2 and 3 are also known collectively as the Cotton-Moutoneffect.
To summarize, because each component of the dielectric
tensor has a specific dynamical modification, the polarizationof light propagating through the material is altered in a highlyselective way. This selectivity enables the different physicalmechanisms that are responsible for a certain modulationof the magnetization to be distinguished experimentally. Inparticular, only the in-plane magnon mode causes oscillationsinm
xandlyand can thus be observed via the Faraday effect
(case 1) or the Cotton-Mouton effect (case 2). The out-of-planemagnon mode causes oscillations of l
xandmyand is therefore
only observable via the Cotton-Mouton effect (case 3).
B. Inverse magneto-optical effects
The Hamiltonian in Eq. ( 3) with the dielectric tensor defined
in Eq. ( 7) can also be used to describe the inverse magneto-
optical effects. In accordance with the previous notion, kijkand
gijklthen mediate the IFE and the ICME, respectively, with
direct and inverse effects parameterized by the same couplingtensors. This assumption should be valid in the region of opticaltransparency [ 49] to which our investigation is restricted. Yet,since the tensor components are dependent on the frequency of
both the laser and the magnetization, the actual values for thedirect and inverse effects can still be different, as suggested inRef. [ 50]. However, this has no influence on the results of the
ensuing investigation as we focus our discussions exclusivelyon the coupling parameters for the inverse effects.
We define the effective magnetic fields H
effandheffform
andlas the partial derivative of the interaction Hamiltonian
with respect to mandl:
Heff=−∂Hint
∂m,heff=−∂Hint
∂l. (17)
When an ultrashort light pulse irradiates a sample, these
effective magnetic fields become the driving force of thenonthermal magnetization dynamics.
The Landau-Lifshitz-Gilbert equations for mandlare [45]
∂m
∂t=−γ{M×Heff+L×heff}+Rm, (18a)
∂l
∂t=−γ{M×heff+L×Heff}+Rl, (18b)
where γis the gyromagnetic ratio. Anisotropy terms leading
to the elliptical precession of mandl, and damping terms are
subsumed into Rm,l. Combining these with Eq. ( 17) and the
initial conditions M(t=0)=0 and L(t=0)=(0,0,Lz), we
obtain
∂m
∂t=γ
16πL2
z[gyzzy{Ey(t)E∗
z(t)+Ez(t)E∗
y(t)}ˆx
−{gyyxzEy(t)E∗
y(t)+gzzxzEz(t)E∗
z(t)}ˆy]+Rm,
(19a)
∂l
∂t=−iγ
16πLzkyzx{Ey(t)E∗
z(t)−Ez(t)E∗
y(t)}ˆy+Rl.
(19b)
If the magnetization dynamics are induced by an ultrafast
laser pulse of pulse duration τ, which is short compared to the
spin oscillation period, i.e., E(t)E∗(t)≈EE∗τδ(t)=I0/cδ(t),
the terms RmandRlcan be neglected and Eqs. ( 19a) and ( 19b)
can be integrated around t=0:
/Delta1m=γτ
16πL2
z[gyzzy{EyE∗
z+EzE∗
y}ˆx
−{gyyxzEyE∗
y+gzzxzEzE∗
z}ˆy], (20a)
/Delta1l=−iγτ
16πLzkyzx{EyE∗
z−E∗
yEz}ˆy. (20b)
These optically induced changes occur instantaneously during
the excitation.
1. Excitation by linearly polarized light
With linearly polarized light specified by ( Ey(t),Ez(t))=
E(t)(sinθ,cosθ), where θdenotes the angle between the
direction of polarization and the zaxis (cf. Fig. 1), Eqs. ( 20a)
174407-4ULTRAFAST OPTICAL EXCITATION OF COHERENT . . . PHYSICAL REVIEW B 95, 174407 (2017)
and ( 20b) lead to
/Delta1mlin=γ
16πcL2
zI0[gyzzysin(2θ)ˆx−(g1−g2cos(2θ))ˆy],
(21a)
/Delta1llin=0. (21b)
Here,g1=(gyyxz+gzzxz)/2 and g2=(gyyxz−gzzxz)/2. Af-
ter the quasi-instantaneous generation of mxandmy,t h e
spins start to precess around their easy axis orientation witha strong ellipticity that reflects the pronounced magneticanisotropy perpendicular to this axis. The short axis of theellipse is along /Delta1m, whereas the long axis is along /Delta1l[41,51].
The precession can be separated into in-plane and out-of-plane contributions, where for the in-plane mode m
xandly
oscillate with a π/2 phase difference at frequency /Omega1IPMand
for the out-of-plane mode myandlxoscillate at frequency
/Omega1OPM. The magnetization dynamics lead to
mlin
x(t)=γ
16πcL2
zI0gyzzysin 2θcos/Omega1IPMt, (22a)
llin
y(t)=−γ
16πcAIPML2
zI0gyzzysin 2θsin/Omega1IPMt, (22b)
mlin
y(t)=−γ
16πcL2
zI0(g1−g2cos 2θ)cos/Omega1OPMt,
(22c)
llin
x(t)=−γ
16πcAOPML2
zI0(g1−g2cos 2θ)sin/Omega1OPMt.
(22d)
Here, we introduced the anisotropy factors AIPMandAOPM,
which account for the magnetic anisotropy and parametrize theellipticity of the spin precession [ 18]. The coupling between
the light field and the magnetization is purely described byparameters based on the tensor g
ijkl, and therefore based
on magnetic linear birefringence. Therefore both modes areexcited by the ICME.
2. Excitation by circularly polarized light
With circularly polarized light, σ±=(Ey(t),Ez(t))=
E(t)(1,∓i)/√
2, analogous considerations as for linearly
polarized light lead to
/Delta1mσ±=−γ
16πcL2
zI0g1ˆy, (23a)
/Delta1lσ±=∓γ
16πcLzI0kyzxˆy. (23b)
This induces oscillations of mandlaccording to
mσ±
x(t)=∓γ
16πc1
AIPMLzI0kyzxsin/Omega1IPMt, (24a)
lσ±
y(t)=∓γ
16πcLzI0kyzxcos/Omega1IPMt, (24b)
mσ±
y(t)=−γ
16πcL2
zI0g1cos/Omega1OPMt (24c)
lσ±
x(t)=−γ
16πcAOPML2
zI0g1sin/Omega1OPMt. (24d)Thus, the in-plane mode is linearly dependent on Lz,
obtains a 180◦phase change upon changing the pump helicity,
and couples via kyzx, which is related to magnetic circular
birefringence. Accordingly, it is excited by the IFE, whichcreates an effective magnetic field that exerts a torque on thespin system and contributes the term /Delta1l. Meanwhile, even
though induced by circularly polarized light, the out-of-planemode is excited via the ICME.
III. EXPERIMENTAL RESULTS
A. Optical setup
We study the magnon dynamics in NiO by performing
impulsive stimulated Raman scattering experiments in thetime domain, which was realized by a pump-probe setup.We optically excite the sample using a 0.98-eV 90-fs laserpulse and probe the transient optical properties of the materialwith a 1.55-eV 50-fs pulse [ 35]. The absorption coefficient of
NiO for the pump pulse is approximately 20 cm
−1at 77 K
[25]. By pumping and probing the sample in the highly
transparent regime, we are able to excite and measure theentire volume of our 260- μm-thick NiO slice. Furthermore, we
avoid heating effects, which allows us to study the nonthermalmagnetization dynamics. The polarization of both pulsescan be tuned such that any linear or circular polarizationcan be realized for the pump and for the probe pulse. Thetransmitted part of the probe pulse is split into orthogonalcontributions by a Wollaston prism and measured as intensitiesI
1andI2on a balanced pair of photodiodes. The theory
presented in the previous section allows to predict the resultingimbalance
/Delta1η=/bracketleftbiggI
1−I2
I1+I2/bracketrightbigg
pumpon−/bracketleftbiggI1−I2
I1+I2/bracketrightbigg
pumpoff(25)
between the photodiodes as a function of the orientation of the
Wollaston prism, which is parameterized by the angle ψ[cf.
Fig. 1(c)], as well as by the pump and probe polarizations.
We focus on the Cotton-Mouton effect by probing withcircularly polarized light and measuring the ellipticity of thetransmitted light. This enables both in-plane and out-of-planemodes to be observed. The sample is kept at 77 K for allmeasurements.
Eliminating l
yby combining Eqs. ( 14) and ( 22b), we find
for the in-plane mode excited by linearly polarized light thefollowing dependence of the ellipticity on the pump and probeconditions:
/Delta1η
lin
IPM=CAIPML3
zI0gpu
yzzygpr
yzzysin 2θcos 2ψsin/Omega1IPMt.(26)
Here, we defined C=−γωd/ (16πc2√
/epsilon1/prime). Furthermore, the
magneto-optical coupling constants are in general frequencydependent and can therefore be different for the pump and theprobe pulse. This is taken into account by introducing g
pu
yzzy
andgpr
yzzy.
Analogously, combining Eqs. ( 14) and ( 24b) yields the
following dependence for the observation of the in-planemode, when excited by circularly polarized light:
/Delta1η
σ±
IPM=±CL2
zI0kpu
yzxgpr
yzzycos 2ψcos/Omega1IPMt. (27)
174407-5CHRISTIAN TZSCHASCHEL et al. PHYSICAL REVIEW B 95, 174407 (2017)
Similar considerations based on Eqs. ( 16) and ( 22d)a sw e l la s
(24d) yield for the out-of-plane mode:
/Delta1ηlin
OPM=CAOPML3
zI0
×/parenleftbig
gpu
1−gpu
2cos 2θ/parenrightbig
gpr
2sin 2ψsin/Omega1OPMt,(28)
/Delta1ησ±
OPM=CAOPML3
zI0gpu
1gpr
2sin 2ψsin/Omega1OPMt.(29)
Thus the present model clearly predicts the measurable signal
of the magnon dynamics as a function of pump and probepolarizations. In reverse, it allows the determination of themechanisms leading to magnon excitation. Experimentallyverifying the predictions, which are ultimately summarized inEqs. ( 26)t o( 29), is the core part of the following section. We
shall first consider excitations using linearly polarized pump
pulses and subsequently circularly polarized light.
B. Excitation by linearly polarized light
To verify the predictions regarding linearly polarized pump
pulses, i.e., Eqs. ( 26) and ( 28), we performed time-resolved
measurements for three different settings: (i) the detectionangle ψis fixed at 0
◦and the pump polarization angle θis
varied; (ii) the pump polarization angle θis fixed at 45◦and
the detection angle ψis varied; (iii) the detection angle ψis
fixed at 45◦and the pump polarization angle θis varied.
Figure 2(a) shows time-resolved ellipticity measurements
for setting (i). Here and in all following time-dependentmeasurements the pump pulse triggers an instantaneousstep-like change of /Delta1η. This step occurs independent of
polarization which suggests a thermal origin [ 22] rather
than displacive mechanisms like photoinduced magneticanisotropy effects, which are mostly restricted to systemswith dopants or impurities [ 52,53]. Figure 2(a) reveals a
single oscillation with a periodicity of approximately 8 ps.The solid lines are fits according to the equation /Delta1η
IPM=
η0−Aexp (−t/τ)s i n(/Omega1t+B). [Note that Acorresponds to
CAIPML3
zI0gpu
yzzygpr
yzzysin 2θcos 2ψin Eq. ( 26).] Fitting yields
an oscillation frequency /Omega1/2πof 0.13 THz, which is in
agreement with the expected value of 0.14 THz for the in-planemode [ 35]. The slight deviation may be temperature related.
The initial phase Bturns out to be close to zero, confirming
the sinelike time-dependence of Eq. ( 26). The red curve in
Fig. 2(b) shows the behavior of the signed amplitude A.I t
resembles the predicted sin 2 θfunction, but a fit proportional
to sin 2( θ−ζ) reveals a small shift ζ=−6.9
◦±0.7◦, and
thus a deviation from the predicted behavior. As we shall seein Sec. IV A , this phase shift originates from the S-domain
substructure of our single Tdomain. Distinct from the red
curve, the blue curve in Fig. 2(b) shows the signed amplitude
Aof the magnon oscillation for setting (ii). It confirms the
expected cos 2 ψdependence of the in-plane mode amplitude
in both Eqs. ( 26) and ( 27). To verify the linear dependence
on the pump intensity, the pump fluence was reduced from80 mJ cm
−2for setting (i) to 40 mJ cm−2for setting (ii). The
observed maximum amplitudes of the two curves in Fig. 2(b)
differ by a factor of about 2, confirming the predicted behavior.
Figure 3(a) shows time-resolved measurements of the
magnetically induced linear birefringence for setting (iii).According to our model, this allows for the most efficientFIG. 2. (a) Observation of the in-plane mode from measurements
of the Cotton-Mouton effect in setting (i), i.e., ψ=0◦,θvaried.
Curves are vertically displaced for clarity. (b) Signed amplitude Aof
optically induced magnon oscillation in setting (i) (red) and setting
(ii) (blue). A(θ)∝sin 2(θ+ζ).A(ψ)∝cos 2ψ. The difference in
the modulation amplitude reflects the difference in pump power as
mentioned in the text.
observation of the out-of-plane mode. Measurements were
performed on the same spot as for Fig. 2(a). A high-frequency
modulation of the underlying in-plane mode is clearlyvisible. The solid curves are fits according to /Delta1η=η
0+
A0exp (−t/τ0)−Aexp (−t/τ)s i n(/Omega1t+B)−A/primeexp (−t/τ/prime)
sin (/Omega1/primet+B/prime). The exponential terms ( ∼τ0,τ,τ/prime) and the
phase shifts ( ∼B,B/prime) are phenomenological additions
parameterizing the magnetic damping and the aforementionedS-domain substructure of our single Tdomain, respectively.
The fit reveals /Omega1/2π=0.13 THz and /Omega1
/prime/2π=1.07 THz
confirming the origin of the observed oscillations as a magnonexcitation. A magnified representation of the region aroundt=0 is given in Fig. 3(b). The sinelike behavior of the
out-of-plane mode is in agreement with Eq. ( 28). Figure 3(c)
shows the dependence of the signed oscillation amplitudeof the out-of-plane mode A
/primeon the pump polarization angle
θ. As expected from Eq. ( 28), we observe a cos 2( θ−ζ)
dependence with an isotropic, i.e., polarization-independentbackground. This contribution is allowed in materials withmagnetic point groups permitting g
yyxz/negationslash=−gzzxzsuch as NiO
with its magnetic symmetry 2 /m[48]. This phenomenological
description captures all features of the measurements. Thus,
174407-6ULTRAFAST OPTICAL EXCITATION OF COHERENT . . . PHYSICAL REVIEW B 95, 174407 (2017)
FIG. 3. (a) Observation of the out-of-plane mode by measurement
of the Cotton-Mouton effect in setting (iii), i.e., ψ=45◦,θvaried.
Curves are vertically displaced for clarity. (b) Magnification of region
between −1a n d+4 ps. The out-of-plane mode is sinelike. Data points
around 0 are out of scale. (c) Dependence of the signed amplitude
A/primeof the out-of-plane mode on the linear pump polarization angle θ.
The solid red line is a fit using A/prime=X1−X2cos 2(θ−ζ).
in NiO, with its collinear spin structure, the excitation
mechanism relies on a magneto-optical coupling that issymmetry-allowed in the magnetic point group. Note thatin principle, the noncollinearity of the spins in the domainwalls can lead to an additional isotropic contribution viathe inverse magneto-refractive effect [ 54,55]. However, with
150 nm the width of a NiO domain wall is about an order ofmagnitude smaller than the lateral extension of the domain[56], so that any isotropic contribution from the walls would
be of the order of a few percent only. This value is expected todiminish further by compensation effects among the varietyof wall types that are possible between the several domainstates within a T
0domain of NiO. We therefore neglect the
influence of the inverse magneto-refractive effect and restrictour description to the simplest possible model required toexplain our results.
The red line in Fig. 3(c) plots the fitting function X
1−
X2cos 2(θ−ζ) with X1=(9±1)×10−5,X2=−(1.6±
0.1)×10−4, and ζ=3.7◦±2.2◦. The phase shift of 3 .7◦
and the presence of the in-plane mode are again caused by
the admixture of additional Sdomains to the anticipated
single-domain state, which are discussed in detail in Sec. IV A .
Summarizing, we are able to observe both magnon
modes of NiO by studying the magnetically induced linearFIG. 4. Magnon oscillations induced by circularly polarized light.
Curves have been displaced by ±0.1m r a df o rc l a r i t y .( a )O n l yt h e
in-plane mode is observed; the signal displays a 180◦phase shift
following a change in the pump helicity, indicating excitation via the
IFE. (b) The out-of-plane mode has no pump-helicity dependence,
indicating excitation via the ICME.
birefringence, which can be efficiently probed by circularly
polarized light. Furthermore, based on the striking agreementbetween measurement and theory, we can identify the ICMEas the driving mechanism for the optical magnon excitation bylinearly polarized light in NiO.
C. Excitation by circularly polarized light
After confirming our model theory for the generation of
magnons by linearly polarized light, we now consider magnonexcitations driven by circularly polarized optical pulses.Similar to the previous section, two cases can be distinguished,where the detection angle of the Wollaston prism is fixed toeitherψ=0
◦orψ=45◦. Furthermore, the helicity σ±of the
circularly polarized pump pulse can be altered. Four individualmeasurements are obtained (see Fig. 4).
Forψ=0
◦[Fig. 4(a)], only the in-plane mode is observed
in agreement with the theory. The cosinelike behavior ofthe probed birefringence accords also with the prediction.Moreover, the in-plane mode obtains a 180
◦phase shift when
the pump helicity is changed. This is a distinct signature of theIFE as the driving mechanism of this oscillation. Qualitatively,the IFE creates an effective magnetic field pulse in xdirection,
which acts as a torque on L
z, effectively rotating Laround
thexaxis. This causes a finite contribution in ly, which can
be consequently probed by the induced birefringence via theCotton-Mouton effect.
The out-of-plane mode cannot be probed in this geometry
because of the sin 2 ψdependence [Eqs. ( 28) and ( 29)]. To
clarify its excitation mechanism, we also took measurements atψ=45
◦, which allows for the observation of the out-of-plane
mode. The obtained time-traces [Fig. 4(b)] show the expected
sinelike time dependence. Remarkably, the out-of-plane modedoes not obtain a 180
◦phase shift after a change in the pump
174407-7CHRISTIAN TZSCHASCHEL et al. PHYSICAL REVIEW B 95, 174407 (2017)
helicity, just as predicted by Eq. ( 29). Consequently, based on
the excellent agreement between theory and all measurementspresented here, we can identify the Cotton-Mouton effect asthe driving mechanism of the out-of-plane mode, even thoughit was excited by circularly polarized light. Note that the weakunderlying signature of the in-plane mode in Fig. 4(b) does
not obtain a 180
◦phase shift, when the pump helicity is
changed. Furthermore, it exhibits a sine-like time-dependenceas opposed to the cosinelike time dependence of the in-planemode in Fig. 4(a). Thus it is not excited by the IFE acting on
the underlying S-domain substructure, but rather by the ICME
[Eq. ( 26)] due to a slight inevitable ellipticity of the circularly
polarized pump pulse.
IV . DISCUSSION
A. Influence of S2and S3domains
The coordinate system in Fig. 1was chosen such that the
easy axis of the S1-domain state lies along the zaxis. The
probed single- T-domain area, however, may also include S2
andS3domains. Their easy axes are rotated around the x
axis by 120◦and 240◦, respectively. As we will see in the
following, measurements on different spots on the sampleindeed yielded varying compositions of Sdomains. For a more
detailed analysis of our data, we therefore have to expand /Delta1η
by terms representing the contributions from these domainstates. For pumping with linearly polarized light , probing with
circularly polarized light leads to
/Delta1η
lin
IPM=CAIPML3
zI0gpu
yzzygpr
yzzysin/Omega1IPMt
×[A1cos(2ψ)sin(2θ)
+A2cos(2ψ−120◦)sin(2θ−120◦)
+A3cos(2ψ−240◦)sin(2θ−240◦)] (30)
for the in-plane mode, where A1,2,3represent the area fractions
covered by the domain states S1,2,3of the single Tdomain.
Thus we impose the boundary condition A1+A2+A3=1.
Note that for A1=A2=A3=1/3, the isotropic ¯3msymme-
try is recovered as an average across the Tdomain. In this
case, Eq. ( 30) simplifies to
/Delta1η=1
2CAIPML3
zI0gpu
yzzygpr
yzzysin(2θ−2ψ)sin/Omega1IPMt,(31)
indicating that the observed amplitude depends solely on the
difference between pump and detection angle. This behaviorhas been observed for instance in FeBO
3[18].
For parameterizing the degree of S-domain mixing within
aN i O Tdomain, it is convenient to consider the setting ψ=0
for which Eq. ( 30) can be rewritten as
/Delta1ηlin
IPM=CAIPML3
zI0gpu
yzzygpr
yzzysin/Omega1IPMt
×Alin
effsin(2θ−δlin) (32)
with
δlin=arctan/parenleftbigg√
3(A2−A3)
4A1+A2+A3/parenrightbigg
(33)
and
Alin
eff=4A1+A2+A3
4 cosδlin. (34)FIG. 5. Amplitude of the in-plane mode as a function of pump
polarization angle θforψ=−45◦and 0◦. The dependence can be
explained by contributions from different S-domain states.
Let us now analyze the distribution of the domains probed.
For a single S1domain, the amplitude for ψ=±45◦would
be zero for all pump angles. However, the amplitude of thein-plane-mode as a function of pump polarization for differentdetection angles (Fig. 5) immediately reveals the presence of a
multi-S-domain composition of the sample. A fit of Eqs. ( 30)
yields
A
1=0.651±0.004,
A2=0.064±0.007, (35)
A3=0.285±0.012,
In combination with Eqs. ( 33) and ( 34), we find
δlin=−7.4◦±0.7◦, (36)
Alin
eff=0.744±0.002. (37)
As anticipated, the combination of S1,S2, and S3domains
leads to a phase shift δlinin the polarization dependence.
A similar analysis of the S-domain composition can be
applied for the excitation of the in-plane mode with circularly
polarized light , that is, via the IFE. In analogy to Eq. ( 30), we
obtain
/Delta1ησ±
IPM=CL2
zI0kpu
yzxgpr
yzzycos/Omega1IPMt
×[A1cos(2ψ)
+A2cos(2ψ−120◦)
+A3cos(2ψ−240◦)], (38)
which can be expressed as
/Delta1ησ±
IPM=CL2
zI0kpu
yzxgpr
yzzycos/Omega1IPMt
×Aσ±
effcos(2ψ−δσ±) (39)
with
δσ±=arctan/parenleftbigg√
3(A2−A3)
2A1−A2−A3/parenrightbigg
(40)
and
Aσ±
eff=2A1−A2−A3
2 cosδσ±. (41)
174407-8ULTRAFAST OPTICAL EXCITATION OF COHERENT . . . PHYSICAL REVIEW B 95, 174407 (2017)
In revisiting Fig. 4, the dominance of the in-plane
mode for ψ=0 and its small amplitude of approximately
0.05 mrad for ψ=45◦are striking. They point to the
pronounced prevalence of the S1domain state so that, even
without an explicit fit of Eq. ( 38), we can conclude that δσ±≈0
andAσ±
eff≈1.0 in the probed area. A refinement of our analysis
by taking S-domain distributions into account as described in
this section enables, in the following, quantitative statementsabout the strength of the magneto-optical coupling constantsin NiO to be made.
B. Magneto-optical coupling constants
This section focuses on the quantitative analysis of the
magneto-optical coupling tensors kijkandgijkl.D u r i n g
the analysis of the out-of-plane mode given in Sec. III B,t h e
fitting parameters X1andX2were extracted, which are directly
related to the magneto-optical coupling constants gyyxz and
gzzxz. The extracted values yield gzzxz/gyyxz≈−3.6. This
is a significant deviation from the isotropic case with ¯3m
symmetry, where the ratio would be −1[42,48]. This is strong
confirmation that, although the deviation from the crystallo-
graphic point symmetry ¯3mtoward 2 /mby magnetostriction
from the Sdomains is small, the magneto-optical properties
of NiO have to be discussed in the framework of the magnetic
point symmetry 2 /m.
Furthermore, by comparing the oscillation amplitude of
the in-plane mode in Figs. 2and4, the magnon generation
efficiency via IFE and ICME can be compared. The pumpfluences were 80 mJ cm
−2in both cases. In Fig. 2,t h e
magnon was excited by the ICME with a maximum oscillationamplitude l
ICME
y of approximately 4.7 mrad. In contrast, for
generation via the IFE [Fig. 4(a)], the observed oscillation had
an amplitude lIFE
yof 0.13 mrad. In both cases, the dynamics
were probed via the contribution of lyto the Cotton-Mouton
effect. The quantitative evaluation of the two excitation pathsis hindered, however, by the multi- S-domain distribution. With
the analysis of the previous section, we can now renormalizethe measured amplitudes for single- S-domain samples.
From Eq. ( 32) and ( 39), we see that the ratio of the spin
precession amplitudes is determined by
l
ICME
y
lIFEy=AIPMAlin
eff
Aσ±
effLzgpu
yzzy
kpu
yzx. (42)
The anisotropy factor AIPMcan be derived from the exchange
field [ 35]HE=2π×27.4T H z /γand the angular frequency
of the mode /Omega1IPM=2π×0.14 THz according to [ 18]
AIPM=2γHE
/Omega1IPM≈400. (43)
The second factor in Eq. ( 42) is geometric and accounts
for the distribution of Sdomains within the probed area.
With our previously determined values for Alin
effandAσ±
eff,
we conclude that the ratio of the induced magnetizationsisL
zgpu
yzzy/kpu
yzx≈0.1. Consequently, the ICME induces a
magnetization, which is about an order of magnitude smallerthan that of the IFE in NiO. Even though NiO is structurallydifferent, this value is in line with the values obtained by Ra-man scattering in rutile structure antiferromagnets [ 57]. Nev-
ertheless, in NiO, this is overcompensated by the pronouncedmagnetic anisotropy so that in total the amplitude ratio of
the induced magnon oscillation on a single Sdomain equals
A
IPMLzgyzzy/kyzx≈50.
Moreover, we can consider the magnetic anisotropy energy,
which applies to the in-plane mode:
Haniso=a
2m2
x+b
2l2
y. (44)
This anisotropy leads to an elliptical spin motion. Con-
sequently, mx=0, when lyis maximized and vice versa.
Therefore the ratio of the energies pumped into the magneticsystem by the ICME and the IFE scales with the square of theratio of the l
yamplitudes, which is about 502, or 2500.
As the IFE and ICME are described by antisymmetric
and symmetric tensors kijkandgijkl, respectively, we can
now revisit the apparent contradictions in earlier Ramanscattering experiments [ 31]. There, it had been argued that the
commonly accepted antisymmetric Raman scattering tensoris not sufficient to explain their results, but a symmetrictensor would. Moreover, they estimated that the symmetriccontribution would be dominant. This is now confirmed,explained, and quantified by our measurements.
V . CONCLUSIONS
We performed time-resolved pump-probe measurements of
two magnon modes in antiferromagnetic NiO. Measurementswere performed on T
0domains on the (111) surface of the
sample. Thus, pump and probe pulses were propagating alongthe optic axis of the crystal, which avoids loss of the initial lightpolarization due to birefringence. This allowed us to study thedependence of the amplitude and phase of the induced magnonoscillations on pump polarization in detail. Comparing themeasurements to an analytical model under consideration ofthe full magnetic 2 /mpoint symmetry, we clarified the driving
force of the individual magnon modes. Our model predictsclear selection rules for the dependence of the optical responseon the probe conditions, which were verified in experiments.
The ICME constitutes the excitation mechanism for
both the in-plane and the out-of-plane magnon modes bylinearly polarized light. Its analysis even provides highlysensitive quantitative access to the distribution of the elusiveS-domain substructure of the otherwise dominating T-domain
distribution.
When circularly polarized pump pulses are used,
the general behavior of the in-plane mode is qualitativelydifferent from the out-of-plane mode. Such pulses propagatingalong the xaxis excite the out-of-plane mode via the ICME;
the IFE becomes the driving mechanism of the in-plane mode.Comparison of the amplitudes of the magnon oscillationsresulting from ICME and IFE revealed that the energy transferinto the magnetic system via the ICME is about three ordersof magnitude more efficient than via the IFE. Whereas themagneto-optical coefficients parameterizing the ICME areabout an order of magnitude smaller than those of the IFE,the dynamics induced by the ICME are significantly morepronounced due to the strong magnetic anisotropy. Thisresolves the long-standing question about the proclaimeddominance of the second-order ICME over the first-order IFEderived from Raman scattering experiments.
174407-9CHRISTIAN TZSCHASCHEL et al. PHYSICAL REVIEW B 95, 174407 (2017)
ACKNOWLEDGMENTS
T.S. was supported by KAKENHI (Grants No. 15H05454
and No. 26103004), JST-PRESTO, JSPS Core-to-Core Pro-gram, A. Advanced Research Networks, and thanks ETHZurich for hosting him on a guest Professorship. C.T. and M.F.
acknowledge support from the SNSF project 200021/147080and by FAST, a division of the SNSF NCCR MUST.
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174407-11 |
PhysRevB.87.180403.pdf | RAPID COMMUNICATIONS
PHYSICAL REVIEW B 87, 180403(R) (2013)
Phase-resolved x-ray ferromagnetic resonance measurements of spin pumping
in spin valve structures
M. K. Marcham,1L. R. Shelford,2S. A. Cavill,2P. S. Keatley,1W. Yu,1P. Shafer,3A. Neudert,4J. R. Childress,5J. A. Katine,5
E. Arenholz,3N. D. Telling,6G. van der Laan,2and R. J. Hicken1,*
1School of Physics and Astronomy, University of Exeter, Stocker Road, Exeter, Devon, EX4 4QL, United Kingdom
2Diamond Light Source, Harwell Science and Innovation Campus, Didcot, Oxfordshire, OX11 0DE, United Kingdom
3Advanced Light Source, Lawrence Berkeley National Laboratory, Berkeley, California 94720, USA
4Helmholtz-Zentrum Dresden-Rossendorf e. V., Institute of Ion Beam Physics and Materials Research, P .O. Box 51 01 09,
01314 Dresden, Germany
5San Jose Research Center, HGST, 3403 Yerba Buena Rd., San Jose, California 95135, USA
6Keele University, Institute for Science and Technology in Medicine, Guy Hilton Research Centre, Thornburrow Drive, Hartshill,
Stoke-on-Trent, ST4 7QB, United Kingdom
(Received 6 December 2012; revised manuscript received 6 March 2013; published 21 May 2013)
Element-specific phase-resolved x-ray ferromagnetic resonance (FMR) was used to study spin pumping within
Co50Fe50(3)/Cu(6)/Ni80Fe20(5) (thicknesses in nanometers) spin valve structures with large areas, so that edge
effects typical of nanopillars used in standard magnetotransport experiments could be neglected. The phase ofprecession of the Co
50Fe50fixed layer was recorded as FMR was induced in the Ni 80Fe20free layer. The field
dependence of the fixed layer phase contains a clear signature of spin transfer torque (STT) coupling due to spinpumping. Fitting the phase delay yields the spin-mixing conductance, the quantity that controls all spin transferphenomena. The STT coupling is destroyed by insertion of Ta into the middle of the Cu layer.
DOI: 10.1103/PhysRevB.87.180403 PACS number(s): 76 .50.+g, 72.25.−b, 75.70.Cn, 75 .76.+j
The ability of a spin-polarized electric current to exert
spin transfer torque (STT) upon a nanoscale ferromagneticelement has led to a revolution in electronics. Electricallyaddressed magnetic random access memory, agile microwavefrequency spin transfer oscillators, and low power spintroniclogic devices are being realized in metal-based structures,fueling research into spin-polarized transport in other classesof material. By also exploiting the spin Hall, spin Seebeck,and precessional spin-pumping effects, there are furtheropportunities to observe new physical effects and constructdevices based upon the flow of pure spin currents. Whilemicroscopic theory for the generation, transfer, and absorptionof spin current has been developed, it now needs to be testedin materials of practical interest. However, the fabrication ofnanostructured devices for spin-polarized current injection andlateral transport of spin current continues to be a formidablechallenge. Although multilayered thin-film stacks can be de-posited with atomic scale precision, additional patterning andion milling processes are required to form nanopillars andlateral spin valves. Processing may modify the structuraland magnetic properties, particularly at edges, in a mannerthat is difficult to characterize and control. Hence there isan urgent need to study spin transfer effects in large-areafilms of the highest structural quality, in which the effectsof nanoscale patterning are absent or negligible. In this waythe intrinsic interfacial and interlayer STT effects can be bettercharacterized.
In the spin-pumping effect, magnetization precession
within a ferromagnetic (FM) “source” layer pumps pure spincurrent into an adjacent nonmagnetic (NM) layer.
1A nonlocal
damping may result from spin scattering in the NM layer.However, if a second FM “sink” layer is added to forma spin valve structure, then the transverse component ofthe spin current may be absorbed by the sink, generatinga STT that acts upon the sink, and further modifying the
damping of the source. The STTs generated, by injection ofeither a spin-polarized charge current or a pure spin current,depend upon the spin-mixing conductance g
↑↓. Studies of spin
pumping in large-area multilayered films can therefore be usedto predict the performance of nanostructured STT devices.
Spin pumping was first observed as an increased damp-
ing of the source layer in ferromagnetic resonance (FMR)experiments.
2By varying the thickness of the sink layer,
the transverse spin relaxation length within the sink layerhas recently been inferred.
3However, spin current can be
destroyed by spin-flip scattering at interfaces and within thespacer layer. Therefore it is essential to also directly observethe response of the sink if the flow of spin current is tobe fully understood. The dynamics of the sink have beendetected in just a few time-resolved magneto-optical Kerreffect (TRMOKE) studies
4–6of epitaxial structures with Ag
and Au spacer layers. In this Rapid Communication we presentx-ray ferromagnetic resonance (XFMR) measurements of spinpumping within spin valve structures with polycrystallineCu spacer layers. Element-specific x-ray magnetic circulardichroism (XMCD) allows the magnetization dynamics of thesource and sink layers to be studied independently. It willbe shown that the field-dependent phase of precession of thesink layer provides a clear signature of STT coupling fromwhich the value of g
↑↓may be determined. The present study
hence shows how phase-resolved measurements made uponeach oscillator within an ensemble can provide informationabout their mutual interactions. This method has immediateextensions within acoustics,
7plasmonics,8and the interaction
of spins in quantum dots coupled by tunneling.9
A spin valve stack consisting of underlayers/
Ta(3)/Ru(2)/Ir80Mn 20(6)/Co50Fe50(3)/Cu(6)/Ni80Fe20(5)/
Ru(7) (thicknesses in nm) was deposited by magnetron
180403-1 1098-0121/2013/87(18)/180403(4) ©2013 American Physical SocietyRAPID COMMUNICATIONS
M. K. MARCHAM et al. PHYSICAL REVIEW B 87, 180403(R) (2013)
FIG. 1. (Color online) Schematic of the experimental geometry
for XFMR measurements. Precession of the magnetization Mabout
the bias field His induced by an in-plane rf magnetic field h(t). The
x-ray beam is incident at grazing angle θ.
sputtering onto an insulating sapphire substrate of 500 μm
thickness. Field annealing was used to set the exchange biasfield of the antiferromagnetic IrMn layer. The thickness ofthe Cu spacer layer is small compared to the spin diffusionlength (350 nm).
10However, a second reference stack was
deposited with a Cu(2.5) /Ta(1)/Cu(2.5) spacer layer, in
which strong spin scattering at the Ta is expected to quenchthe spin accumulation within the NM layer and suppressSTT-induced dynamics of the sink. A combination ofelectron-beam lithography and ion-beam milling was used topattern the magnetic layers of the stack into elements withlateral dimensions of 190 ×400μm
2. Photolithography and
further milling were then used to define a 50 /Omega1coplanar
waveguide (CPW) within the now exposed nonmagneticTa(5)/[Cu(25) /Ta(3)]
×3/Cu(25) /Ta(5)/Ru(10) underlayers.
The elements are sufficiently large that inhomogeneitiesassociated with edges make negligible contribution to thespatially averaged behavior of the element. A 5- μm border
was left between the edges of the element and the centraltrack of the CPW to avoid any significant out-of-plane fieldexcitation.
Phase-resolved XFMR measurements were made in fluo-
rescence yield.
11A continuous wave microwave magnetic field
was phase locked to the x-ray pulse train generated by thesynchrotron and used to excite the sample magnetization intoa state of steady precession about an in-plane bias magneticfield. The sample was positioned close to the shorted end ofthe CPW, as shown in Fig. 1, so as to be close to an antinode of
the microwave field. The exchange bias field and the appliedfield lay parallel to the length of the CPW in the experiment,of which further details are given elsewhere.
11
Previous TRMOKE studies of the STT-induced dynamics
of the sink layer used a spacer of sufficient thickness that theMOKE signal from the source layer was negligible.
5Other
studies used a rotatable compensator to suppress the signalfrom the source layer.
4,6In this XFMR study the response of
the source and sink layers is distinguished by tuning the x-rayenergy to the Ni L
3edge and Co L3edge, respectively.
Theory12predicts that the FMR linewidth of the source will
be broadened as it “leaks” spin angular momentum into theadjacent NM layer. The pure spin current pumped into the NMlayer generates a spin accumulation that may be described as aspin splitting of the chemical potential when diffuse scatteringat the interfaces randomizes the electron momentum withinthe NM layer.
13Spin currents driven by diffusion within the
FIG. 2. (Color online) Longitudinal MOKE loops acquired from
the patterned structures with (a) the Cu spacer and (b) the Cu /Ta/Cu
spacer.
NM layer flow both in to the sink and back to the source.
The back flow partially (fully) compensates the spin currentfrom the source when its magnetization is precessing (inequilibrium). It is assumed that spin current injected into a3dtransition-metal FM layer is completely absorbed near the
interface. The absorption of the component of spin angularmomentum transverse to the sink magnetization generatesa STT. The equations of motion take the form of coupledLandau-Lifshitz-Gilbert equations modified to include STTdue to spin pumping,
2
∂mi
∂t=− |γi|mi×Heff,i+α(0)
imi×∂mi
∂t
+αSP
i/bracketleftbigg
mi×∂mi
∂t−mj×∂mj
∂t/bracketrightbigg
, (1)
where miandmjare unit vectors parallel to the magnetization
vectors of layers iandj, respectively. The first term on the
right-hand side represents the torque term due to the localeffective field H
eff,i, while the second represents the damping
within the ith layer due to intrinsic spin-orbit effects and two
magnon scattering. The third term describes the enhanceddamping of the ith layer due to spin pumping, while the fourth
term represents the STT induced by absorption of spin currentfrom the jth layer.
Let us consider the case that the resonance field of the fixed
layer ( i=2) lies below that of the free layer ( j=1), and
is heavily damped so that the fixed and free layer resonancesoverlap. The direction of the STT acting upon the fixed layerchanges abruptly as the field passes through the free layerresonance value. Above (below) the free layer resonance thedifference in phase between the precession of the fixed layerand the oscillation of the driving field decreases (increases)as the STT partially assists (opposes) the torque term dueto the static applied field. The magnitude of the STT scaleswith the amplitude of the free layer precession, and so, to afirst approximation, the STT generates a bipolar feature in thefield-dependent fixed layer phase that has a width comparableto the FWHM of the free layer resonance. Outside this fieldrange the fixed layer phase returns to the background valueresulting from excitation of the fixed layer by the rf field.
The longitudinal MOKE hysteresis loops acquired from
the patterned samples are shown in Fig. 2. All dynamic
measurements were performed for positive bias field, wherethe free and fixed layer magnetizations are parallel. The freelayer resonance condition was identified by sweeping the biasfield with the delay between the x rays and microwaves set
180403-2RAPID COMMUNICATIONS
PHASE-RESOLVED X-RAY FERROMAGNETIC RESONANCE ... PHYSICAL REVIEW B 87, 180403(R) (2013)
FIG. 3. (Color online) (a) The imaginary component of the
magnetic susceptibility component χyyof the free layer for (a) the Cu
spacer at 7 GHz and (b) the Cu /Ta/Cu spacer at 5 GHz. Lorentzian
fits to the experimental data (open symbols) are shown as solid red
curves.
so as to obtain the imaginary component of the magnetic
susceptibility component χyyas shown in Fig. 3.
The linewidth extracted by Lorentzian fitting was found
to be equal to 50 Oe for both samples within experimentalerror. At 7 GHz [Fig. 3(a)] this requires the sum of the
damping constants α(0)
1andαSP
1for the free layer to be
equal to 0.0105. Due to imperfect impedance matching themicrowave amplitude at the sample had a different frequencydependence for each sample. Excitation frequencies of 7 and5 GHz were used in Figs. 3(a) and3(b), respectively, for which
the microwave amplitude was a maximum in each case. InFig. 3(b) a linewidth of 50 Oe at 5 GHz implies that the sum
of the damping parameters is equal to 0.0150. Although noattempt is made to separate the contributions to the damping,the damping of the free layer in the absence of spin pumpingis expected to be similar at 5 and 7 GHz. This suggests that thevalue of α
SP
1is larger for the Cu /Ta/Cu spacer, as expected
if the Ta strongly scatters spins within the spacer layer. Thespin-pumping contribution to the Gilbert damping coefficienthas the form
14
αSP
i=gμBRe(g↑↓)
8πMidi, (2)
where Miis the saturation magnetization, diis the layer
thickness, gis the spectroscopic splitting factor, and Re( g↑↓)
is the real part of the spin-mixing conductance, which has notbeen corrected to account for the Sharvin conductance.
12
The fixed layer resonance was not observable in field
sweep measurements performed on either sample due to alarge damping resulting from direct contact with the IrMn.However, the precession of the fixed layer could be observedin time delay scans performed at different applied fields asshown in Fig. 4. The phase of the x-ray pulses relative to
the microwave field was varied by passing the microwavesthrough an electromechanical delay generator. The delay scansobtained from the Cu and Cu /Ta/Cu samples are shown in
Figs. 4(a) and 4(b), respectively. A sine curve with period
equal to that of the microwaves was fitted to each scan. Abackground of constant phase and amplitude, arising frominductive pickup, was subtracted from the fitted curves. Thefitted amplitudes are plotted against the applied field inFigs. 4(c) and 4(d). The phase of each fitted curve relative
to the microwave field is plotted in Figs. 4(e) and4(f).F r e e
layer delay scans (not shown) were also fitted and the phase
FIG. 4. (Color online) Fixed (sink) layer delay scans for (a) the
Cu spacer at 7 GHz and (b) the Cu /Ta/Cu spacer at 5 GHz. The sine
curves (red) are fits to the data (open dots). (c), (d) Fitted amplitudes
are plotted as open dots. (e), (f) The phase relative to the driving
field of both fixed (open circles) and free (open squares) layers is
plotted. The red (fixed layer) and blue (free layer) curves assume (e)
αSP
1=0.0050 and αSP
2=0.0034; (f) αSP
1=0.010 and αSP
2=0.0068.
values are plotted for comparison. No background subtraction
was performed for the much larger free layer signals. Thefree layer phase curve has the sigmoidal shape expected for asimple harmonic oscillator.
For the Cu spacer, a clear peak at the free layer resonance
(530 Oe) is observed in Fig. 4(c) on top of a broad Lorentzian
background due to the FMR of the fixed layer. No clearpeak is seen for the control sample [Fig. 4(d)]. For the
Cu spacer, a clear bipolar variation in the phase due toSTT coupling is observed at the free layer resonance field.For the control sample there is perhaps a small dip in thefixed layer phase at the free layer resonance. A unipolarphase variation is characteristic of dipolar coupling, resultingfrom interfacial roughness, or interlayer exchange coupling,although the latter is expected to be negligible for a 6 nm Cuthickness.
The amplitude and phase data in Fig. 4were modeled with
a linearized macrospin solution of Eq. (1). The saturation mag-
netization of the free and fixed layers was assumed to be 815and 2017 emu cm
−3, as determined by vibrating sample mag-
netometry measurements made on coupon samples, while theexchange bias field was taken from the loops in Fig. 2. Dipolar
coupling between fixed and free layers was neglected. The
180403-3RAPID COMMUNICATIONS
M. K. MARCHAM et al. PHYSICAL REVIEW B 87, 180403(R) (2013)
fixed layer damping constant α(0)
2was varied so as to reproduce
the background for the fixed layer response, yielding values of0.45 and 0.35 for Cu and Cu /Ta/Cu, respectively. These values
are large but reasonable. A previous study
15showed that the
damping constant of a Ni 81Fe19/Fe50Mn 50sample increased
from 0.008 to 0.05 as the exchange bias field increased from0 to 120 Oe. Extrapolating to the exchange bias values ofFig. 2yields values for the damping constant comparable to
those obtained here.
The linewidths observed in Fig. 3constrain the total free
layer damping constant ( α
(0)
1+αSP
1) to values of 0.0105 and
0.0150 for the Cu and Cu /Ta/Cu samples, respectively. The
values of αSP
1andα(0)
1were varied subject to this constraint to
give the best simultaneous agreement with the free and fixedlayer responses in Fig. 4. The best agreement for the Cu sample
was obtained when α(0)
1=0.0055 and αSP
1=0.0050. From
Eq.(2)this implies that αSP
2=0.0034. The intrinsic Gilbert
damping of α(0)
1=0.0055 for permalloy is in agreement with
the range of values reported in the literature.16We note that
the values for αSP
1andαSP
2are also comparable to those
found in previous spin-pumping studies (3 – 5 ×10−3).4
The curves in Fig. 4(f) were obtained with α(0)
1=0.005 and
αSP
1=0.010. This then implies that αSP
2=0.0068. However,
since no evidence of STT was observed in the Cu /Ta/Cu
sample, the fourth term on the right-hand side of Eq. (1)was
set to zero for both layers. The implication is that strong spinscattering in the Ta layer prevents spin current passing fromone layer to the other.
Inserting the fitted α
SP
1into Eq. (2)yields Re( g↑↓)=2.64×
1015cm−2. The value of Re( g↑↓) is related to the number of
conducting channels per spin and is a measure of the spin-pumping efficiency.17Approximate expressions of Re( g↑↓)
≈1.2n2/3and 0.75 n2/3have been assumed previously14,18
where nis the number of electrons per spin in the spacer
layer. Assuming n=4.25×1022cm−3for Cu (Ref. 19)
leads to Re( g↑↓)=1.46 and 0.91 ×1015cm−2, respectively.
Improved agreement can be expected following correctionfor the Sharvin conductance
14but this requires input from
ab initio electronic structure calculations that lie beyond the
scope of the present study. Strictly speaking a separate valueofg
↑↓should be introduced to describe each interface at
which spin scattering can be expected to occur. Thereforethe values deduced here should be regarded as effective valuesthat describe the two dissimilar interfaces and any internalstructure of the spacer layer.
In summary, phase-resolved XFMR measurements of
the spin-pumping effect have been demonstrated for spinvalve structures with polycrystalline Cu spacers. The field-dependent phase of precession of the fixed layer at the freelayer resonance provides a clear signature of STT couplingdue to spin pumping. The phase variation is reproduced by amacrospin model that allows the real part of the spin-mixingconductance to be determined. By quantifying the flow of spinangular momentum from the source layer and into the sinklayer, XFMR is a powerful new tool for the study of spintransfer in material systems of practical interest. The presentwork illustrates the more general principle of how measuringthe phase of individual oscillators within an ensemble canprovide unique insight into their mutual interaction.
The authors gratefully acknowledge the financial support
of EPSRC Grant No. EP/F021755/1. Part of this work wascarried out on beamline I06 at Diamond Light Source.
*R.J.Hicken@exeter.ac.uk
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180403-4 |
PhysRevLett.99.267201.pdf | Driven Dynamic Mode Splitting of the Magnetic Vortex Translational Resonance
K. S. Buchanan,1,*M. Grimsditch,2F. Y . Fradin,2S. D. Bader,1,2and V . Novosad2
1Center for Nanoscale Materials, Argonne National Laboratory, Argonne, Illinois 60439, USA
2Materials Science Division, Argonne National Laboratory, Argonne, Illinois 60439, USA
(Received 10 April 2007; revised manuscript received 16 August 2007; published 27 December 2007)
A magnetic vortex in a restricted geometry possesses a nondegenerate translational excitation that
corresponds to circular motion of its core at a characteristic frequency. For 40-nm thick, micron-sized
permalloy elements, we find that the translational-mode microwave absorption peak splits into two peaks
that differ in frequency by up to 25% as the driving field is increased. An analysis of micromagneticequations shows that for large driving fields two stable solutions emerge.
DOI: 10.1103/PhysRevLett.99.267201 PACS numbers: 75.40.Gb, 75.30.Ds, 75.75.+a
Nonlinear phenomena are ubiquitous in nature, existing
in systems ranging from leaky faucets to atmosphericcirculation to optics [ 1–3]. Magnetic systems can be mod-
els for improving our understanding of nonlinear phe-nomena since they are experimentally accessible and theequations of motion are generally tractable. In magnetism,
nonlinear effects were first observed in high-power ferro-
magnetic resonance experiments in the 1950s [ 4,5] where
the premature saturation of the main absorption peak andthe emergence of subsidiary peaks were attributed to spin-wave generation [ 6]. These initial nonlinear dynamic stud-
ies focused on a saturated magnetic state. More recently,magnetic systems have been shown to exhibit a wealth ofother interesting phenomena, such as spin-wave self-
focusing [ 7], symmetry breaking spin-wave Mo ¨bius soli-
tons [ 8], and foldover and bistability effects [ 9].
The spin vortex state, an in-plane flux-closure magneti-
zation distribution with a small central core, is often ob-served in magnetically soft microstructures [ 10–12]. Spin-
polarized scanning tunneling microscopy shows that thecore radius is /.002410 nm , comparable to the material’s ex-
change length [ 13]. Because of the Magnus-type force
(gyroforce) that acts on the core, magnetic vortices exhibit
unique dynamic excitations, including the translational orgyrotropic mode that is characterized by sub-GHz, spiral-like core motion [ 14–20], distinct from the higher fre-
quency (GHz range) quantized spin waves observed inrestricted geometries [ 21–23]. The core polarization p/.0136
/.00061determines the handedness of the spiral motion, as
demonstrated by time-resolved magneto-optical Kerr
[24–26] and x-ray experiments [ 27]; the restoring force
is provided mainly by the magnetostatic energy [ 16,28].
Here we explore frequency- and amplitude-dependent
dynamics of magnetic vortices in circular and ellipticalmicrodisks excited by a radio frequency (rf) driving field.We find that as the magnitude of the rf field h
acis in-
creased, the resonance peak corresponding to the vortextranslational mode splits into two well-defined peaks
whose separation increases with h
ac. The appearance of
mode splitting is unusual since for a single dot this is anondegenerate mode. (There is a degeneracy in the sense
that the ensemble contains random chiralities and polari-ties with the same eigenfrequency but we find no indicationin simulations that their high-field response should differ.)
However, comparing the results with micromagnetic cal-
culations and a phenomenological analytical model revealsthat this system is similar to a driven anharmonic oscillatorwhere a nonlinear energy potential can lead to two reso-nance states, thereby resolving the apparent contradictionof a split, nondegenerate mode. Nevertheless, the prevail-
ing theory for magnetic vortex dynamics does not fully
explain our observations.
We use a microwave reflection technique to investigate
the excitations of vortices in magnetic microstructures[29]. Elliptical and circular permalloy ( Fe
20Ni80alloy)
microdisks were patterned on the central strip of coplanar
waveguides (CPW), /.00242000 per waveguide separated by
>1/.0022mto minimize dipolar interactions, using e-beam
lithography and liftoff. A rf current in the waveguidegenerates an in-plane rf magnetic field that is preferentiallyabsorbed when the frequency coincides with a resonance.The derivatives of the CPW impedance are recorded with
respect to a small modulation field applied parallel to the
static, in-plane magnetic field H, andh
acis calculated from
the current in the CPW. We examine three samples: 2:2/.0002
1:1/.0022mellipses, 3:1/.00021:7/.0022mellipses, and circles of
diameter 2:2/.0022m, all 40-nm thick, referred to as samples
A,B, andC, respectively. All are in the single-vortex
ground state with a mixture of chiralities and polarities.
Figure 1(a) shows microwave impedance spectra as a
function of hacfor sample AwithH/.013660 Oe along the
ellipse minor axis, orthogonal to hac. Magneto-optical Kerr
effect measurements (not shown) indicate that this is below
the vortex annihilation field of 2.5 kOe along the minor
(hard) axis. A single, symmetric peak is found at
/.0024130 MHz for lowhac.A shacis increased, it broadens
and develops a shoulder ( hac/.002411 Oe ) and then splits in
two, where one branch increases in frequency and the other
decreases, reaching a separation of 40 MHz for hac/.0024
24 Oe . Figure 1(b) shows how the microwave spectraPRL 99,267201 (2007)PHYSICAL REVIEW LETTERSweek ending
31 DECEMBER 2007
0031-9007 =07=99(26)=267201(4) 267201-1 ©2007 The American Physical Societychange as a function of H. Spectra at H/.01360O e , obtained
using background subtraction (not shown), are similar tothose obtained at H/.013620 Oe . The increase in resonance
frequency with His related to the increasing curvature of
the energy profile, as described in [ 28]. Both the critical h
ac
and the splitting magnitudes, however, are relatively in-
sensitive to H. The frequencies below the critical hacvary
little for small Hbut take on a negative slope for larger H,
which may be related to the asymmetry of the energy
profile of the shifted vortex [ 28].
The data for sample B(not shown) are similar except the
frequencies are lower ( /.002480 MHz forH/.013620 Oe ) due to
the smaller aspect ratio [ 11]. Splitting begins at hac/.00247O e
along the major axis, reaches 21 MHz at hac/.002410 Oe , and
changes little with H. The critical hacis slightly higher
when directed along the ellipse minor axis. For circulardots (sample C), splitting effects were detected at h
acof
only 3.6 Oe and the splitting reaches 17 MHz at hac/.0024
5:5O e . The vortex translational-mode splitting is thus
observed at large hac(nonlinear regime ) for all measured
samples and is relatively insensitive to H.
Since the vortex translational mode is nondegener-
ate, the key question is, Why is mode splitting observed?To explore this further, we use micromagnetic theory
and computation, both of which are in excellent agree-
ment with experiments for small hac(linear regime )
[18,21,24,26,27,30]. We include additional terms in
Thiele’s equation [ 14] to describe the nonlinear demagne-
tization and Zeeman energy profiles expected at higher hac
and we use micromagnetic simulations to model the effect
of increasing hac. In spite of incomplete agreement with
experiment, both approaches show evidence for the emer-
gence of two allowed modes at high hac, only one of which
is accessed at a given time.
Thiele’s equation /.0255G/.0002dX
dt/.0255DdX
dt/.0135@W/.0133X/.0134
@X/.01360de-
scribes the motion of the vortex core position X/.0136/.0133X;Y/.0134
in a phenomenological energy well W/.0133X/.0134, wheretis time
andDis a damping parameter [ 30]. The gyrovector G/.0136
/.0255Gp^zinduces the spiral motion of the core, where G/.0136
2/.0025LMs=/.0013,/.0013is the gyromagnetic ratio, and Msis the
saturation magnetization [ 24–26].W/.0133X/.0134provides the re-
storing force. The dipolar portion of W,Wdem, is quadratic
for small amplitudes, leading to harmonic-oscillator-like
equations of motion. For large displacements, higher orderterms must be included [ 28], leading to equations of mo-
tion similar to those describing an anharmonic oscillator.
Considering contributions up to 4th order in X,W
dem/.0133X/.0134/.0136
/.0133/.0020=2/.0134X2/.0135/.0133/.0012=4/.0134X4for a circular disk. The Zeeman en-
ergy isWZ/.0136/.0255M/.0001h, where h/.0136hacsin/.0133!t/.0134^iis the driv-
ing magnetic field at frequency !. For small X,Mx/Y,
but the general form is Mx/.0136C1Y/.0135C2Y/.0133Y2/.0135X2/.0134, where
C1, andC2are adjustable parameters. For /.0012/.0136C2/.01360, the
eigenfrequency is !0/.0136G/.02551/.0129/.0129/.0129 /.0129/.0020p[16]. Damping effects
may also contribute [ 31], but should primarily affect the
amplitude and width of the resonance line.
Figure 2shows numerical solutions calculated using the
parameters of sample C[32] assuming a solution of the
form X/.0136Axcos/.0133!t/.0135/.0030/.0134^i/.0135Aysin/.0133!t/.0135/.0030/.0134^j, whereAx
andAyrepresent the amplitudes of the core motion along x
andyand/.0030is the phase lag between hacand the vortex
response. /.0012was chosen to provide a small narrowing of
a) b)
100 150 200 25005001000 A (nm)x5 Oe
1.5 Oe
0.5 Oe
100 150 200 2500200400600
ω/2π(MHz) ω/2π(MHz)
FIG. 2 (color online). (a) Calculated vortex core motion am-
plitude as a function of !for a circular disk with /.0012> 0shows a
foldover effect when hac(values in legend) is increased. Arrows
indicate the hysteretic path and the dashed line shows the /.0012/.01360
result for hac/.01361:5O e . (b)Axvs!=2/.0025using a large C2value
shows a crossover effect for hac/.01365O e .
FIG. 1 (color online). (a) Microwave spectra (real part, scaled)
for sample A,H/.013660 Oe , as a function of hac. (b) Spectra
showing dynamic splitting as a function of excitation power
forH/.013620–140 Oe applied along the ellipse minor axis.PRL 99,267201 (2007)PHYSICAL REVIEW LETTERSweek ending
31 DECEMBER 2007
267201-2Wdem/.0133X/.0134, andC1/.0024MsV=R, whereVis the volume, esti-
mated by assuming that the vortex annihilation approxi-mately corresponds to saturation. We also considered 3rdharmonics but found they are suppressed by several orders
of magnitude. As the driving field is increased a foldover of
the solution is observed, as reported previously for non-linear oscillators [ 33], high-power ferromagnetic resona-
tors [ 34], and in nonlinear optics [ 2]. The solution changes
little for small C
2(C2/.0136C3/.0136/.0255 0:1C1=R2, considered
reasonable based on fits to MvsXfrom micromagnetic
simulations), but for larger C2/.0136/.0255 2:5C1=R2crossover
behavior is found [Fig. 2(b)]. Both solutions lead to two
peaks, as indicated by arrows in Fig. 2. Figure 2(a) shows
both frequencies increasing as hacis increased, whereas
Fig. 2(b) is qualitatively closer to the experimental trends
as it allows for one peak to increase with hacwhile the other
decreases. Note, however, that the value of C2used in
Fig. 2(b) is larger than can be justified based on
simulations.
Micromagnetic modeling was conducted based on the
Landau-Lifshitz-Gilbert equation [ 35]. To achieve trac-
table computational times ( /.00243 days on a workstation), a
scaled-down ellipse with dimensions 300/.0002150 nm , 20-
nm thick, of permalloy [ 32] was used with 3/.00023n m2cells.
A sinusoidal driving magnetic field h/.0133t/.0134/.0136hacsin/.0133!t/.0134was
applied parallel to the ellipse major axis ( x) and!was
swept slowly to maintain steady-state motion.
Micromagnetic modeling results for hac/.01360:1, 10, and
20 Oe are shown in Fig. 3. The amplitude Mxbuilds and
then declines as the frequency is swept through resonance[Fig. 3(a)] and/.0030is zero for low !,/.0025at high, and passes
through/.0025=2at resonance. Since the absorption measured
experimentally is proportional to M
xsin/.0133/.0030/.0134, this effec-
tively decreases the peak widths in Fig. 3so that they
more closely resemble Fig. 1. The forward and reverse
sweeps coincide when hacis 0.1 Oe ( <1 MHz difference
is due to sweeping). At hac/.013610 Oe ,Mxbuilds more
slowly and the response is hysteretic, falling off at
637 MHz on the forward sweep and building at 628 MHz
on the reverse. At hac/.013620 Oe the effect is more pro-
nounced (builds at 670 and falls at 643 MHz).Simulations at constant !/.0136632 MHz andh
ac/.013610 Oe
show that varying the initial phase of the driving fieldallows two steady-state resonances to be accessed(M
x=Ms/.01360:127,/.0030/.01362:60;Mx=Ms/.01360:216,/.0030/.0136
2:07), confirming that the bistability in Fig. 3is a steady-
state phenomenon. There is no indication from theory orsimulations that vortices with different chirality or polarity,other than their direction of core circulation, should behavedifferently. In the experiment, the frequency is increased in
discrete steps and the foldover dependence on sweep di-
rection cannot be detected. Since we are averaging severalspectra for many dots we expect that the signal shouldreflect both bistable states. The magnitude of h
acand the
separation of the frequency resonance edges in Fig. 3arequalitatively similar to the experiment and they display a
foldover effect similar to Fig. 2(a). Assuming comparable
representation of the bistable resonances, the expected line
shape resembles a peak with a shoulder, as shown for hac/.0024
11–15 Oe in Fig. 1(a) and not the well-separated peaks
observed for larger hac.
For higher hac/.013650 Oe , the simulations show that the
core becomes unstable and will undergo repeated polariza-
tion reversal events. For !above and below resonance,
steady-state solutions are obtained; however, for a range of!near resonance the amplitude repeatedly builds, declines
after the core reversal, and rebuilds, which would lead to a
region of decreased absorption in our experiment.Experimental evidence of core flipping by an in-plane rf
field has been shown recently [ 36], which may occur in our
samples for the largest h
ac; however, micromagnetic mod-
eling and theory indicate that the onset of nonlinear be-
havior should occur at lower hac.
In summary, using a microwave reflection technique we
find that driven magnetic vortices exhibit a nonlinear re-
a)
0.0000.003
-0.003
0.2
0.0
-0.2
580 600 620 640b)M /Mxs
M /MxsM /Mxs
(MHz)(MHz)hac= 0.1 Oe
hac= 10 Oe600 680 640-0.40.00.4hac = 20 Oe
ω/2π
ω/2π
FIG. 3 (color online). Micromagnetic simulations for a 300/.0002
150 nm ellipse, 20-nm thick, for hacof (a) 0.1 Oe, (b) 10 Oe, and
inset of (b) 20 Oe. The frequency was increased [dark (blue)] or
decreased [light (green)] at 31:8 kHz=ns, and the xaxis con-
verted from time to !=2/.0025.PRL 99,267201 (2007)PHYSICAL REVIEW LETTERSweek ending
31 DECEMBER 2007
267201-3sponse at the vortex translational-mode resonance. For
large driving fields we detect a splitting of the translationalmode that is surprising since this mode is nondegenerate.
Theory and micromagnetic modeling indicate that a
foldover-type effect plays a role in defining this behaviorand suggest that the two peaks in the absorption spectracorrespond to two steady-state solutions that differ in theirphase lag relative to the driving field.
We thank K. Yu. Guslienko, A. Slavin, and P. Roy for
stimulating discussions. Work at Argonne, including use ofthe Center for Nanoscale Materials, was supported by the
U.S. Department of Energy, Basic Energy Sciences, under
Contract No. DE-AC02-06CH11357.
*Corresponding author.
buchanan@anl.gov
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267201-4 |
PhysRevB.100.054426.pdf | PHYSICAL REVIEW B 100, 054426 (2019)
Hydrodynamics of three-dimensional skyrmions in frustrated magnets
Ricardo Zarzuela, Héctor Ochoa,*and Yaroslav Tserkovnyak
Department of Physics and Astronomy, University of California, Los Angeles, California 90095, USA
(Received 7 January 2019; revised manuscript received 31 July 2019; published 20 August 2019)
We study the nucleation and collective dynamics of Shankar skyrmions [Shankar, J. Phys. 38,1405 (1977 )]
in the class of frustrated magnetic systems described by a SO(3) order parameter, including multilatticeantiferromagnets and amorphous magnets. We infer the expression for the spin-transfer torque that injectsskyrmion charge into the system and the Onsager-reciprocal pumping force that enables its detection by electricalmeans. The thermally assisted flow of topological charge gives rise to an algebraically decaying drag signal innonlocal transport measurements. We contrast our findings to analogous effects mediated by spin supercurrents.
DOI: 10.1103/PhysRevB.100.054426
I. INTRODUCTION
Recent years have witnessed a growing interest in the
transport properties of frustrated (quantum) magnets [ 1–9]
since they provide a powerful knob to explore unconventionalspin excitations in phases characterized by a highly degenerateground state. Spin glasses [ 10,11], spin ices [ 12], and spin
liquids [ 13], to mention a few examples, belong to this broad
family. In the exchange-dominated limit for magnetic inter-actions [ 14], long-wavelength excitations around a local free-
energy basin are generically described by the O(4) nonlinearσmodel [ 15,16], whose action reads
S=1
4/integraldisplay
d3/vectorrd t(χTr[∂tˆRT∂tˆR]−ATr[∂kˆRT∂kˆR]).(1)
The order parameter ˆR(/vectorr,t) represents smooth and slowly
varying proper rotations of the initial noncoplanar spin config-uration [ 17,18];χandAdenote the spin susceptibility and the
order-parameter stiffness of the system, respectively. Phase-coherent precessional states sustain spin supercurrents [ 7],
manifested as a long-range spin signal decaying algebraicallywith the propagation distance. This form of spin superfluidity[19] gives rise to a low-dissipation channel for spin transport
that could be probed via nonlocal magnetotransport measure-ments [ 20].
The SO(3) order parameter can also host stable three-
dimensional solitons akin to skyrmions in chiral models ofmesons [ 21]. In condensed-matter physics, these textures
are known as Shankar skyrmions and appear, e.g., in the A
phase of superfluid
3He [22,23] and in atomic Bose-Einstein
condensates with ferromagnetic order [ 24–26]. These objects
are characterized by a different topological number than otherthree-dimensional textures arising in materials characterizedby vectorial order parameters [ 27–29]. Like chiral domain
walls in one dimension [ 30] and baby skyrmions in two-
dimensional magnets [ 31], suitable spin-transfer torques at
the interface bias the injection of Shankar skyrmions into
*Present address: Department of Physics, Columbia University,
New York, 10027.the frustrated magnet, which diffuse over the bulk as stable
magnetic textures carrying quanta of topological charge. Ro-bustness against structural distortions and moderate externalperturbations along with their particlelike behaviors makeskyrmions attractive from the technological standpoint dueto their potential use as building blocks for information andenergy storage [ 32,33]. Frustrated magnets offer a possible
realization of these objects, which were originally proposed inlow-energy chiral effective descriptions of QCD [ 21,34] and
appear in cosmology [ 35] and string theory [ 36].
In this paper, we construct a hydrodynamic theory for
skyrmions in the (electrically insulating) bulk, complementedwith spin-transfer physics at the interfaces with adjacentheavy-metal contacts. Figure 1depicts the device (open)
geometry with lateral terminals usually utilized in nonlocaltransport measurements. For suitable reduced symmetries(Rashba-like systems), magnetic torques can pump skyrmioncharge into the frustrated magnet, whose diffusion over thebulk and subsequent flow across the right interface sustains apumping electromotive force in the second terminal. The re-sultant drag of spin current is positive and thermally activated,in sharp contrast to the case of spin superfluid transport. Thestructure of the paper is as follows. In Sec. II, we introduce the
winding number describing SO(3) skyrmions and constructa continuity equation for the associated topological current.Appendix Acontains some useful mathematical identities.
The expression of the spin-transfer torque favoring skyrmionnucleation and its reciprocal electromotive force are deducedin Sec. III. We obtain the expression for the spin-drag resis-
tivity of a proptotypical device in Sec. IV. Some details of the
derivation are saved for Appendix B. Finally, we compare the
spin-drag signals mediated by skyrmions and spin supercur-rents in Sec. V.
II. TOPOLOGICAL CHARGE AND
CONTINUITY EQUATION
The order-parameter manifold SO(3) is topologically
equivalent to the four-dimensional unit hypersphere with an-tipodal points identified. Unit-norm quaternions (so-calledversors) q=(w,v) provide a convenient parametrization of
2469-9950/2019/100(5)/054426(7) 054426-1 ©2019 American Physical SocietyZARZUELA, OCHOA, AND TSERKOVNYAK PHYSICAL REVIEW B 100, 054426 (2019)
1.0
0.8
0.6
0.4
0.2
0
I
zy
x
V
FIG. 1. Two-terminal geometry for the electrical injection and
detection of skyrmions in frustrated magnets. The inset: Imaginarycomponent of the versor parametrization of the rigid hard cutoff
ansatz for skyrmions q={cos[f(˜r)/2],sin[f(˜r)/2]ˆe
r}(see the main
text for details). Length and color of the arrows correspond to themagnitude of the vector field.
rotation matrices: The three-dimensional vector vlies along
the rotation axis, whereas the first component wparametrizes
the rotation angle, see Appendix A. Skyrmions are topological
objects associated with the nontrivial classes of the homo-topy group π
3[SO(3)] =Z, which are labeled by an integer
index referred to as the skyrmion charge. The latter is themultidimensional analog of a winding number and admits thefollowing simple expression in terms of versors:
Q=/integraldisplay
d
3/vectorrj0,j0=/epsilon1klm
12π2det[q,∂kq,∂lq,∂mq],(2)
where k,l,m∈{x,y,z}are spatial indices, /epsilon1αβ···μis the Levi-
Civita symbol, and det[ ·,·,·,·] denotes the determinant of a
4×4 matrix formed by versors arranged as column vectors.
Our choice of prefactor ensures the normalization to unity ofthe skyrmion charge when the mapping q:S
3→S3wraps the
target space once.
Formulation of a hydrodynamic theory for skyrmions re-
quires the stability of these textures, which, in turn, yields thelocal conservation of their charge. In this regard, additionalquartic terms (in the derivatives of the order parameter) inthe effective action given by Eq. ( 1), which may have a
dipolar /exchange origin in real systems, preclude the collapse
of skyrmions into atomic-size defects [ 21]. We will assume
this scenario in what follows and utilize the rigid hard cutoffansatz for stable skyrmions as a simple solution that sufficesto estimate the transport coefficients of our theory [ 37]:
ˆR(/vectorr)=exp[−if(˜r)ˆe
˜r·ˆL], (3)
where [ ˆLα]βγ=−i/epsilon1αβγrepresent the generators of SO(3),
˜r=|/vectorr−/vectorR|, and ˆe˜r=(/vectorr−/vectorR)/˜ris the unit radial vectorfrom the center /vectorRof the skyrmion. Here, f(˜r)=2π(1−
˜r/R⋆)/Theta1(R⋆−˜r),/Theta1(x) denotes the Heaviside θfunction, and
the skyrmion radius reads R⋆=ξ(A/A4)1/2, where ξis a
dimensionless prefactor and A4is the strength of the fourth-
order term [ 38]. Note that this ansatz corresponds to the
rotation around ˆe˜rby the angle fat each point of space.
Figure 1also depicts the vector field v(/vectorr)=sin[f(˜r)/2]ˆer
associated with the versor parametrization of the rotation
matrix ( 3), whose skyrmion charge is Q=−1.
Topological invariance (i.e., global conservation) of the
skyrmion charge translates into a local conservation law em-
bodied in a continuity equation. More specifically, we cancast the skyrmion charge density as the time component ofa topological four-current defined per
j
μ=1
12π2/epsilon1μμ 1μ2μ3det[q,∂μ1q,∂μ2q,∂μ3q], (4)
which satisfies the continuity equation ∂μjμ=0. Here,
μ,μ 1–3∈{t,x,y,z}denote spatiotemporal indices. The com-
ponents of the associated topological flux read
jk=1
32π2/epsilon1klmω·(/Omega1l×/Omega1m), (5)
in terms of the angular velocity of the order parameter ω≡
iTr[ˆRTˆL∂tˆR]/2, and the (spin) vectors /Omega1l≡iTr[ˆRTˆL∂lˆR]/2
describing the spatial variations of the collective spin rotationthat defines the instantaneous state of the magnet [ 7]. Note
that both scalar and cross products (highlighted in boldcharacters) take place in spin space and that, in the versorparametrization, these quantities can be recast as the Hamiltonproduct 2 ∂
μq∧q∗of the derivatives of the quaternion and its
adjoint q∗, see Appendix A. Similarly, the skyrmion charge
density takes the form
j0=1
16π2/Omega1z·(/Omega1x×/Omega1y). (6)
It is worth noting here that, contrary to the case of baby
skyrmions, the topological charge is even under time-reversalsymmetry, see Appendix A. Furthermore, the skyrmion flux /vectorj
is a pseudovector in real space.
III. SPIN-TRANSFER TORQUES AND
ELECTROMOTIVE FORCES
In the device geometry considered in Fig. 1, the magnet
is subject to spin-exchange and spin-orbit coupling with ad-jacent heavy-metal contacts. In what follows, we invoke aminimal symmetry reduction in the bulk, which allows theexistence of magnetic torques τthat couple to the skyrmion
flux in Eq. ( 5), and assume that they also operate at the
interface. Thus, for our purposes, interfaces serve merely asa medium for the charge current to flow. These torques areonly effective in a volume of width λ(along x) in contact
with the metal where this distance characterizes the spatialextension of the proximity effect between the metal contactand the insulating magnet.
In order to inject a skyrmion flux /vectorjby a transverse charge
current density /vectorJ, we wish to establish the following work
(per unit of volume and time) by the magnetic torque:
P≡τ·ω=¯h
2e/vectorj·(/vectorJ×/vectorζ), (7)
054426-2HYDRODYNAMICS OF THREE-DIMENSIONAL SKYRMIONS … PHYSICAL REVIEW B 100, 054426 (2019)
where /vectorζis a special vector (with units of length) and the scalar
and cross products on the right-hand side of the equation (innormal characters) take place in real space. Note that mirror
reflection symmetry must be broken along /vectorζforPto be
a scalar, i.e., we restrict ourselves hereafter to Rashba-type
magnets with /vectorζbeing the corresponding principal axis. The
latter should ideally be oriented parallel to the interface. Letus consider the situation depicted in Fig. 1where the principal
axis lies along the perpendicular to the basal plane ( /vectorζ=ζˆe
z).
As can be inferred from Eq. ( 7), we are interested in the
magnetic torques that produce work in favor of the skyrmionmotion along the longitudinal direction ( xaxis) when they
are induced by a charge current density flowing along thetransverse direction ( yaxis). With account of Eq. ( 5), we
obtain from Eq. ( 7) that the spin-transfer torque providing
such a work is given by
τ=¯h
32eπ2(/vectorJ·/vector/Omega1)×(/vectorζ·/vector/Omega1). (8)
This torque involves two spatial derivatives of the order
parameter and is dissipative, implying that the injectionof skyrmion charge requires a strong spin-orbit interaction.Heavy-metal contacts, such as platinum contain this basicmicroscopic ingredient, and the effect is likely to be enhanced
by the application of a perpendicular electric field ( /vectorE∝/vectorζ)
just due to the conventional Bychkov-Rashba effect [ 39]. Spin
torques of the form ∝/vectorJ·/vector/Omega1do not couple to the topological
flux/vectorjand will, thus, be disregarded along with other torques
at the same order of expansion, e.g., τ∝/vectorJ·(/vector∇×/vector/Omega1) that are
irrelevant to the skyrmion-injection physics.
Skyrmion diffusion over the magnet yields a pumping
electromotive force in the second terminal, whose expressioncan be obtained by invoking Onsager reciprocity. Currents andthermodynamic forces are related by the following matrix oflinear-response coefficients:
⎛
⎝∂
tˆR
∂tm
/vectorJ⎞
⎠=⎛
⎝·⋆·· ⋆·· ⋆·
·⋆·γχB× ˆLsq
·⋆· ˆLqsˆϑ⎞
⎠⎛
⎝ˆfˆR
fm
/vectorE⎞
⎠, (9)
where ˆfˆR≡−δF/δˆRandfm≡−δF/δm=−m/χ+γB=
−ωare the thermodynamic forces conjugate to the order pa-
rameter and the nonequilibrium spin density, respectively, and
/vectorErepresents the electromotive force. For our construction, we
only need to focus on the charge and spin sectors, which arerelated by ˆL
sq,ˆLqs(other linear-response coefficients, denoted
by·⋆·, are inconsequential for our discussion); Bis an
external magnetic field, γis the gyromagnetic ratio, and ˆϑis
the conductivity tensor that we assume symmetric (i.e., purelydissipative). Note that it is not obvious whether Onsager re-ciprocal relations can be applied to the order-parameter sectorbecause the SO(3) matrices ˆRare defined with respect to the
initial (mutual equilibrium) spin configuration defining a free-energy basin, and microscopic time-reversal symmetry relatesdifferent (and possibly disconnected) basins. However, thenonequilibrium spin-density mdoes not depend on the initial
configuration and, therefore, the situation for the spin-chargesectors is analogous to that of bipartite antiferromagnets [ 40].For the torque in Eq. ( 8), we have
[ˆL
sq]αi=¯h
32π2e/epsilon1αβγϑijζk/Omega1jβ/Omega1kγ, (10)
and since the off-diagonal blocks are related by the reciprocal
relation ˆLqs=− ˆLT
sq, the pumping electromotive force /vectorE=
ˆϑ−1ˆLqsfmgenerated in the right terminal becomes
/vectorE=¯h
32π2eω·[/vector/Omega1×(/vectorζ·/vector/Omega1)]=¯h
2e/vectorζ×/vectorj. (11)
IV . SKYRMION DIFFUSION AND SPIN DRAG
Dynamics of the soft modes (center of mass) describing
stable skyrmions obey the Thiele equation,
M¨/vectorR+/Gamma1˙/vectorR=/vectorf, (12)
where M=16π
9(π2+3)χR⋆is the skyrmion inertia and /vectorf=
−δF/δ/vectorRrepresents the thermodynamic force conjugate to
the skyrmion center, see Appendix B. The friction coeffi-
cient/Gamma1=αsM/χis proportional to the Gilbert damping
constant αparametrizing losses due to dissipative processes
in the bulk [ 41] where s≈¯hS/a3,Sis the length of the
microscopic spin operators and adenotes the lattice spacing.
Local (quasi)equilibrium within a free-energy basin alongwith translational invariance in the bulk yields Fick’s law forthe topological flux,
/vectorj=−D/vector∇j
0, (13)
where the diffusion coefficient is related to the friction coef-
ficient via the Einstein-Smoluchowski relation D=kBT//Gamma1.
Hereafter, we assume that the current is injected into thefrustrated magnet from the left contact in the two-terminalgeometry depicted in Fig. 1. We also assume translational
invariance along the transverse directions (i.e., the yzplane).
The latter, combined with the continuity equation for thetopological four-current, yields the conservation of the lon-gitudinal bulk skyrmion current in the steady state. It reads
j
x
bulk=D(j0
L−j0
R)/Ltwith j0
L/RandLtbeing the skyrmion
charge density at the left /right terminals and the distance
between them, respectively.
The topological current at the boundaries of the magnet can
be cast as
jx
L=γL(T)¯hζλJL
ekBT−¯γL(T)j0
L, (14a)
jx
R=¯γR(T)j0
R, (14b)
where γL(T)=ν(T)e−Esky/kBTis the equilibrium-nucleation
rate of skyrmions at the left interface, ν(T) and Eskydenotes
the attempt frequency and the skyrmion energy, respectively[42], and ¯ γ
L,R(T) represents the skyrmion annihilation rates
per unit density [ 43]. The electrical bias in the left terminal
favors the nucleation of skyrmions with positive topologicalcharge by lowering the energy barrier in an amount equal tothe work carried out by the magnetic torque in Eq. ( 8); the
expression in Eq. ( 14a) corresponds to the leading order in
the external bias [ 31]. Continuity of the topological flux sets
the steady state, characterized, in linear response, by the drag
054426-3ZARZUELA, OCHOA, AND TSERKOVNYAK PHYSICAL REVIEW B 100, 054426 (2019)
resistivity,
/rho1drag=λR2
Q
Rbulk+RL+RR(15)
defined per the ratio of the detected voltage per unit length
to the injected charge current density. Here, RQ=h/2e2/similarequal
12.9k/Omega1is the quantum of resistance and Rbulk,RL/Rdenote
the drag resistances of the bulk and interfaces of the frustratedmagnet, respectively,
R
bulk=2π2/Gamma1Lt
e2ζ2j0eq,RL/R=2π2kBT
e2ζ2γL/R(T), (16)
where j0
eq=γL,R(T)/¯γL,R(T)=ρ0e−Esky/kBTis the skyrmion
density at equilibrium.
V . DISCUSSION
The channel for spin transport rooted in the diffusion of
skyrmion charge becomes suppressed in the low-temperatureregime as the proliferation of skyrmions in the bulk of themagnet dies out with probability ∝e
−Esky/kBT. The frustrated
magnet, however, sustains stable spin supercurrents in thepresence of additional easy-plane anisotropies, the latter pre-cluding the relaxation of the phase-coherent precessional stateinto the uniform state. This coherent transport of spin maybe driven by nonequilibrium spin accumulations at the leftinterface, which are induced by the charge current flowingwithin the first terminal via the spin Hall effect [ 7]. Fur-
thermore, in the absence of topological singularities in theSO(3) order parameter (namely, Z
2vortices) degradation of
the spin superflow only occurs via thermally activated phaseslips in the form of 4 π-vortex lines [ 7]. These events are
exponentially suppressed at low temperatures (compared tothe easy-plane anisotropy gap). On the other hand, we canshow through the analog of the Mermin-Ho relation [ 44]
derived in Appendix A,
/vector∇×/vectorJ
α=−(A/2)/epsilon1αβγ/vector/Omega1β×/vector/Omega1γ, (17)
that skyrmions crossing streamlines in a planar section of the
magnet do not contribute to the generation of phase slips in
the superfluid [ 45]. Here, /vectorJα=−A/vector/Omega1αdenotes the αcom-
ponent of the spin supercurrent. Therefore, in magneticallyfrustrated systems with weak easy-plane anisotropies, weexpect to observe a smooth crossover from a spin superfluidto a skyrmion conductor driven by temperature as depicted
in Fig. 2. For a large separation between terminals, L
t/greatermuch
1//Gamma1γ L,R,¯hgL,R/4παs(gL,R’s are the effective interfacial con-
ductances), the drag coefficients for both transport channelsreduce to
/rho1sky
drag=/parenleftbigg¯h
e/parenrightbigg2ζ2λj0
eq
2/Gamma1Lt,/rho1SF
drag=−/parenleftbigg¯h
2e/parenrightbigg2ϑ2
sH
αstdLt,(18)
where ϑsHandtddenote the spin Hall angle in the metal con-
tacts and the thickness of the detector strip, respectively. Note
the algebraical decay /rho1sky,SF
drag∝1/Ltand the opposite sign of
the drag resistivities in these two spin-transport channels. Thelatter can be intuitively understood as the manifestation ofthe different symmetries under time reversal of the flavorsencoding the information and dragging of the electrical signal:
FIG. 2. Sketch of the thermal dependence of the total drag re-
sistivity /rho1drag=/rho1SF
drag+/rho1sky
dragfor frustrated magnets with weak easy-
plane anisotropies.
Whereas, in the case of the superfluid, this is just the spin flow
ascribed to coherent precession, in the case of the skyrmionconductor, the signal is mediated by the flux of the associ-ated topological charge, which is even under time reversal.We note in passing that, remarkably, skyrmions do generatehopfions through the fibration S
3→S2described by a given
element of the internal spin frame [ 46]. Finally, experimental
platforms well suited to host Shankar skyrmions and observethe aforementioned crossover are amorphous magnets, inparticular, amorphous yttrium iron garnet in which nonlocalspin-transport measurements have been recently reported [ 5].
In conclusion, we have established the hydrodynamic
equations governing the diffusion of skyrmion charge withinthe bulk of frustrated magnetic insulators. Interfacial spin-transfer torques inject topological charge into the system,whose steady flow sustains a spin drag signal between themetallic terminals. The algebraic decay of the drag coefficientover long distances manifests the topological robustness ofShankar skyrmions in the SO(3) order parameter. We alsoremark that S
2hopfions could be pumped into the frustrated
magnet by suitable spin-transfer torques, therefore, givingrise to a third channel for low-dissipation spin transport.The program developed in this paper can, in principle, beextended to S
2hopfions with the caveat that the Hopf charge
density is nonlocal in the order parameter [ 47] and that it is
unclear whether these topological excitations are stable withinSkyrme-like models [ 48].
ACKNOWLEDGMENTS
This work has been supported by NSF under Grant No.
DMR-1742928.
R.Z. and H.O. contributed equally to this work.
APPENDIX A: VERSOR PARAMETRIZATION
In this Appendix, we show that versors (i.e., unit-norm
quaternions) provide a convenient parametrization of rotationmatrices. To begin with note that SU(2) is the universal(double) covering of SO(3) and is isomorphic to the unit
054426-4HYDRODYNAMICS OF THREE-DIMENSIONAL SKYRMIONS … PHYSICAL REVIEW B 100, 054426 (2019)
hypersphere in R4. The latter means that we can represent a
generic SU(2) matrix ˆUby means of a four-component (real)
vector q=(w,v),
ˆU=wˆ1−iv·σ≡wˆ1−ivxˆσx−ivyˆσy−ivzˆσz, (A1)
where σ=(ˆσx,ˆσy,ˆσz) is the vector of Pauli matrices and v=
(vx,vy,vz) denotes the vector part of the quaternion q.N o t e
that the normalization condition w2+v2=1 arises from the
unitary character of SU(2) matrices. The SO(3) matrix ˆR
associated with ˆU∈SU(2) reads
ˆRαβ=(1−2|v|2)δαβ+2vαvβ−2εαβγwvγ. (A2)
Since qand−qparametrize the same rotation ˆR, we conclude
that SO(3) ∼=RP3, namely, the group of proper rotations
corresponds to the hypersphere S3with antipodal points being
identified. In this parametrization of rotations, vlies along
the rotation axis, and the first component wparametrizes the
rotation angle.
The set {ˆ1,−iˆσx,−iˆσy,−iˆσz}defines the basis of quater-
nions as a real vector space where addition and multiplicationby scalars is as in R
4. The algebra of Pauli matrices defines a
multiplicative group structure, the Hamilton product,
q1∧q2≡(w1w2−v1·v2,w1v2+w2v1+v1×v2).(A3)
The adjoint of q=(w,v)i sq∗=(w,−v) so that the norm√q∗∧q(=1 in the case of versors) is a real number. Note that
the Hamilton product provides a convenient representation ofthe usual matrix product in SO(3) since q
∗corresponds to ˆRT
and ˆR1·ˆR2corresponds to q1∧q2.
Finally, the O(4) nonlinear σmodel takes the following
simple form:
L=2/integraldisplay
d3/vectorr(χ∂tq∗∧∂tq−A∂iq∗∧∂iq), (A4)
in terms of versors. A simple spin-wave analysis of this
Lagrangian yields, akin to Néel antiferromagnets, three inde-pendent linear dispersion relations characterized by the soundvelocity c=√
A/χ.
1. Spin currents in versor parametrization
We first introduce the fields /Omega1μ=iTr[ˆRTˆL∂μˆR]/2, which
describe time ( μ=t) and spatial ( μ=x,y,z) variations of
the collective spin rotation defining the instantaneous state ofthe magnet,
i∂
μˆU(t,/vectorr)=[/Omega1μ(t,/vectorr)·ˆS]ˆU(t,/vectorr). (A5)
Here, [ ˆLα]βγ=−i/epsilon1αβγare the generators of SO(3), and /epsilon1αβγ
is the Levi-Civita symbol. In particular, /Omega1t=ωis the angular
velocity of the order parameter ˆR. The spin current is given
by/vectorJ=−A/vector/Omega1as inferred from the Euler-Lagrange equations,
where /vector/Omega1≡/Omega1xˆex+/Omega1yˆey+/Omega1zˆez[7]. With account of the
versor parametrization Eq. ( A2), we obtain the identity,
/Omega1μ=2w∂μv−2v∂μw+2v×∂μv, (A6)
which is just /Omega1μ=2∂μq∧q∗as deduced from the definition
of the Hamilton product Eq. ( A3). Note that the scalar part of
∂μq∧q∗is identically zero w∂μw+vα∂μvα=0.The following identity holds in the absence of singularities
in the order parameter:
∂μ1/Omega1μ2−∂μ2/Omega1μ1=/Omega1μ1×/Omega1μ2.μ 1,μ2∈{t,x,y,z}.
(A7)
In terms of the αcomponent of the spin current /vectorJα=−A/vector/Omega1α,
the above equation for spatial subindices can be recast as
/vector∇×/vectorJα=−A
2/epsilon1αβγ/vector/Omega1β×/vector/Omega1γ, (A8)
which is analogous to the Mermin-Ho relation in3He-A[44].
Equation ( A7) can be easily proved in versor notation since
∂μ1/Omega1μ2−∂μ2/Omega1μ1=2∂μ2q∧∂μ1q∗−2∂μ1q∧∂μ2q∗
=/Omega1μ1×/Omega1μ2, (A9)
so long as the order parameter is single valued and, therefore,
∂μ1∂μ2q=∂μ2∂μ1q.
The internal spin frame of reference is defined locally by
the tetrad of vectors ˆeα=ˆR·ˆα,α=x,y,z. By projecting
Eq. ( A7) onto these director vectors, we obtain
ˆeα·(/Omega1i×/Omega1j)=ˆeα·(∂iˆeα×∂jˆeα). (A10)
Furthermore, the projection of the spin current onto the vec-
tors{ˆeα}αdefines the components of the internal spin current ,
namely, the spin current measured in the internal spin frameof the texture,
/vectorJ
(α)=ˆeα·/vectorJ=[ˆRT·/vectorJ]α. (A11)
Equation ( A7) can be recast as
[/vector∇×/vectorJ(α)]k=−A
2/epsilon1ijkˆeα·(∂iˆeα×∂jˆeα), (A12)
which implies that the circulation of the αcomponent of the
internal spin current along a closed loop is proportional tothe solid angle subtended by the surface defined by ˆe
αon the
planar section enclosed by the loop. Therefore, in the absenceof singularities in the order parameter, the spin current canonly decay in multiples of 4 πAbecause the solid angle is
quantized in units of 4 π(provided that ˆe
αpoints towards the
same direction far away from the phase-slip event).
2. Versors under parity and time-reversal symmetries
The order-parameter manifold of magnetic systems with
frustrated interactions dominated by exchange is genericallybuilt upon applying SO(3) rotations to a given ground-stateG, which corresponds to a classical solution (a minimum) of
the free-energy landscape [ 7,17,18]. These rotations connect
physically distinguishable spin configurations with the sameenergy. Nonequilibrium deviations within the free-energybasin are described by smoothly varying (in space and time)elements of SO(3) in this approach.
LetˆPand ˆTbe the operators (in spin space) corresponding
to the representations of parity and time-reversal symmetryoperations, respectively. Note that the action of these sym-metries on the ground-state |G/angbracketrightleads to isoenergetic states
|G
/prime/angbracketrightthat belong, in general, to other energy basins. The
spin-rotation operator ˆUacting on the whole set of spins is
the direct sum of irreducible representations of SU(2) actingon individual spins S
i(ilabels here the spatial position).
054426-5ZARZUELA, OCHOA, AND TSERKOVNYAK PHYSICAL REVIEW B 100, 054426 (2019)
The identities |G/prime/angbracketright≡ˆTˆU|G/angbracketright= ˆUˆT|G/angbracketrightand|G/prime/prime/angbracketright≡ ˆPˆU|G/angbracketright=
ˆUˆP|G/angbracketrightfollow from
ˆTSiˆT−1=−Si, (A13a)
ˆPSiˆP−1=Si, (A13b)
so that ˆPˆUˆP−1=ˆUand ˆTˆUˆT−1=ˆU. With account of
Eq. ( A1), we have the identities,
•ˆPˆUˆP−1=ˆPwˆP−1−iˆPvˆP−1·ˆPσˆP−1
=w−iv·σ=ˆU/equal1⇒ qˆP/mapsto→q,(A14)
•ˆTˆUˆT−1=ˆTwˆT−1+iˆTvˆT−1·ˆTσˆT−1
=w−iv·σ=ˆU/equal1⇒ qˆT/mapsto→q,(A15)
Thus, the quaternions that parametrize SO(3) rotations
(with respect to the new basin) remain invariant under theinversion operations.
APPENDIX B: COLLECTIVE-VARIABLE
APPROACH FOR SKYRMIONS
Time dependence of the SO(3)-order parameter for the
hard cutoff ansatz is encoded in the soft modes of theskyrmion texture, namely, its center of mass: ˆR(t,/vectorr)≡ˆR[/vectorr−
/vectorR(t)]. At the same time, the canonical momentum /vector/Pi1conju-
gate to /vectorRreads
/vector/Pi1=−/integraldisplay
d
3/vectorrm·/vector/Omega1. (B1)With account of the equation of motion m=χωand of ∂tˆR≈
−(˙/vectorR·/vector∇/vectorr)ˆRfor rigid skyrmions, we can write the canonical
momentum as /Pi1i=Mij˙Rj, where the inertia tensor takes the
form
Mij=χ/integraldisplay
d3/vectorr/Omega1i·/Omega1j
=4χ/integraldisplay
d3/vectorr(∂iw∂jw+∂iv·∂jv)=Mδij,(B2)
withM=16π
9(π2+3)χR⋆. For the final result, we have used
the ansatz given in the main text.
We model dissipation by means of the Gilbert-Rayleigh
function [ 7],
R[ˆR]=αs
2/integraldisplay
d3/vectorrω2=αs
4/integraldisplay
d3/vectorrTr[∂tˆRT∂tˆR], (B3)
which provides the dominant term in the low-frequency (com-
pared to the microscopic exchange J) regime. Within the
collective-variable approach, it becomes
R[ˆR]=1
2˙/vectorR·[/Gamma1]·˙/vectorR,/Gamma1 ij=Mij
T, (B4)
where T=χ/sαrepresents a relaxation time. Therefore, the
Euler-Lagrange equations for the skyrmion center (the so-called Thiele equation) turn out to be as follows:
M¨/vectorR+M
T˙/vectorR=/vectorf, (B5)
where /vectorf≡−δ/vectorRFis the conservative force.
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054426-7 |
PhysRevB.62.570.pdf | Spin-current interaction with a monodomain magnetic body: A model study
J. Z. Sun
IBM T. J. Watson Research Center, P.O. Box 218, Yorktown Heights, New York 10598
~Received 3 February 2000 !
I examined the consequence of a spin-current-induced angular momentum deposition in a monodomain
Stoner-Wohlfarth magnetic body. The magnetic dynamics of the particle are modeled using the Landau-Lifshitz-Gilbert equation with a phenomenological damping coefficient
a. Two magnetic potential landscapes
are studied in detail: One uniaxial, the other uniaxial in combination with an easy-plane potential term thatcould be used to model a thin-film geometry with demagnetization. Quantitative predictions are obtained forcomparison with experiments.
I. INTRODUCTION
Recently it has been shown, both theoretically1–5and
experimentally6–9that a spin-polarized current, when passing
through a small magnetic conductor, will deposit its spin-angular momentum into the magnetic system. It causes themagnetic moment to precess or even switch direction. Thenature of this interaction between the spin current and theferromagnetic moment brings about a new set of precessiondynamics, the details of which remain unexplored. In thispaper, a model system is presented of a monodomain ferro-magnetic body with its dynamics determined by the Landau-Lifshitz-Gilbert ~LLG!equation. The spin-current-induced
magnetic precession dynamics are examined, and the resultsobtained compared to controlled thin-film experiments. Thisstudy also brings quantitative insights to the potential use ofspin-current injection as a method for magnetic writing.
Centimeter-gram-seconds units are used for this work.
Variables are grouped in simple forms where the only rel-evant unit is the energy product. Therefore results should bereadily translatable to meter-kilogram-seconds or any otherengineering units. For numerical simulation a set of dimen-sionless variables are introduced to simplify discussion andto elucidate the basic physics. Table I gives a summary ofthese reduced variables.
II. MODEL DEFINITION
The ferromagnet is represented by a Stoner-Wohlfarth
monodomain magnetic body with magnetization M, situated
at the origin, as shown in Fig. 1. For volume calculation
only, the body is assumed to have a size of lmalong the ex
directions, and ain botheyandezdirections, thus with avolume of a2lm. Assume the shape of the body is close to
isotropic, and the energy landscape experienced by Mis de-
scribed by three terms ~independent of its geometric param-
etersaandlm): an applied field H, a uniaxial anisotropy
energyUKwith easy axis along the ezdirection, and an
easy-plane anisotropy Upin theey2ezplane, with exbeing
its normal direction. The magnetization Mis assumed to be
constant in magnitude, its motion represented by a unit di-
rection vector nm5M/uMu, which at any instant of time,
makes an angle uwith theezaxis, while the plane of Mand
ezmakes an angle wwithex. Coordinates ( u,w) completely
describe the motion of Min time. A spin-polarized current J
enters the magnetic body in the 2exdirection, with spin-
polarization factor h, and the spin direction in the ey2ez
plane, making an angle fwithezaxis. The current exits in
the same direction, but with its average spin direction
aligned to that of M. The self-induced magnetic field of the
current is ignored here—this is reasonable as long as themagnetic body is small with dimension abelow about 1000
Å , where the spin-current effect is expected to becomedominant over the current-induced magnetic field.
The potential energy for MisU5U
K1Up1UH, where
UK5Ksin2uis the uniaxial anisotropy, with K
5(1/2)MHk, whereHkis the Stoner-Wohlfarth switching
field. The easy-plane anisotropy is written as Up
5Kp(sin2ucos2w-1). The magnetic field is applied in the
easy plane of ey2ez, making an angle of cwith the easy
axisez. Thus UH52M"H52MH(sinusinwsinc
1cosucosc). Define h5H/(2K/M) andhp5Kp/K,
U~u,w!5K@sin2u1hpsin2ucos2w22h~sinusinwsinc
1cosucosc!#. ~1!
TABLE I. Summary for dimensionless units.
Dimensionless variable Conversion relation Normalization quantity
Magnetization m5M/Ms Saturation magetization Ms
Magnetic field h5H/Hk Uniaxial-anisotropy field Hk
Easy-plane anisotropy field hp5Kp/K54pMs/Hk Uniaxial-anisotropy field Hk.
Effective spin current hs5(\/2e)hJ/lmMsHk Uniaxial-anisotropy energy MsHk/2
Natural time unit t5Vkt/(11a2) Ferromagnetic resonance frequency Vk5gHkPHYSICAL REVIEW B 1 JULY 2000-I VOLUME 62, NUMBER 1
PRB 62 0163-1829/2000/62 ~1!/570~9!/$15.00 570 ©2000 The American Physical SocietyIf one takes the usual thin-film situation of shape anisotropy
and lets the easy-plane anisotropy energy be Kp52pMs2
thenhp54pMs/Hk. The torque Mexperiences within unit
volumelm3(unit area) under potential well Eq. ~1!can be
written as
GU
lm52nm3U~u,w! ~2!
with „U(u,w)5(]U/]u)eu1(1/sin u)(]U/]w)ew, whereeu
andeware unit vectors for uandwrotation, respectively.
The three terms in potential energy Ulead to three terms
in torque GU. First the uniaxial anisotropy term:
G1
lmK5~2 sin ucosu!@~sinw!ex2~cosw!ey#. ~3!
Second the easy-plane anisotropy term:
G2
lmK522hp@~cosusinucosw!ey2~coswsinwsin2u!ez#.
~4!
Third, the applied field term:
G3
lmK52h@~sinwcoscsinu2cosusinc!ex
2~coswcoscsinu!ey1~sinucoswsinc!ez#.
~5!
Spin current also brings a torque to M. We assume that
the magnetic body absorbs the angular-momentum from the
spin current only in the direction perpendicular to M.10This
causes a net torque on M, which can be expressed in vector
form as:
G45snm3~ns3nm!52lmKhsnm3~ns3nm!, ~6!
wheres5(\/2e)hJis the spin-angular momentum deposi-
tion per unit time. h5(J"2J#)/(J"1J#) is the spin-
polarization factor of the incident current J. The spin direc-
tion of the incident current is in the ey2ezplane, and makesan angle fwith theezaxis.nsis a unit vector whose direc-
tion is that of the initial spin direction of the current. Also we
define
hs5s
2lmK5S\
2eDhJ
2lmK5S\
2eDhI
2lma2K~7!
as the spin-current amplitude in dimensionless units. In com-
ponent form Eq. ~6!becomes
G4
lmK52hs$2~sinucosw!~sinusinwsinf1cosucosf!ex
1@~cosu!~sinfcosu2cosfsinusinw!
1sin2ucos2wsinf#ey1@~sinu!~sinucosf
2sinwsinfcosu!#ez%. ~8!
The dynamics of Munder the influence of torque
G5(
i514
Gi
can be described using the Landau-Lifshitz-Gilbert equation
as
dnm
dt1aSnm3dnm
dtD51
2VK(
i514SGi
lmKD, ~9!
where ais the LLG damping coefficient and g5gmB/\is
the gyromagnetic ratio. In our case, g52. Here we intro-
duced a characteristic frequency unit VK5gHk. Equation
~9!can be written in component form using a natural time
unitt5VKt/(11a2):
Fu8
w8G5(
i514Fui8
wi8G ~10!
with
Fu18
w18G52Fasinucosu
cosuG,
Fu28
w28G52hpF~sinw1acosucosw!sinucosw
~coswcosu2asinw!coswG,
Fu38
w38G52hFcoswsinc
1a~sinucosc2cosusinwsinc!
[~sinucosc2cosusinwsinc!
2acoswsinc]/sin uG,
Fu48
w48G5hsFacoswsinf
1sinwsinfcosu2cosfsinu
(coswsinf
2asinwsinfcosu)/sin u
1acosfG,
FIG. 1. Model geometry definition and related mathematical
symbols.PRB 62 571 SPIN-CURRENT INTERACTION WITH A MONODOMAI N...where () 85d/dt(). Equation ~10!can be numerically evalu-
ated. It is the basis for all numerical studies discussed below.
III. ANALYTICAL RESULTS
In this section we discuss the analytical solutions to Eq.
~10!. For simplicity we only consider the on-axis geometry
where both applied field hand the spin direction nsare along
the easy-axis ez. Further, we assume a small cone-angle
limit uuu!1. In this case Eq. ~10!becomes
du
dt52u@a~11h!1hp~sinw1acosw!cosw1hs#
dw
dt5212hp~cosw2asinw!cosw2h1hsa.
~11!
A coordinate transformation of u15ucoswandu25usinw
could further simplify this equation set for small cone-angle
motion. However, we decide to keep using the polar coordi-nate system here, as it allows easy comparison with numeri-cal results that involve large cone-angle motions.
A. Unperturbed equation of motion
In this case, c50,hs50, and a50. For finite hp, Eq.
~11!can be solved to give
w~t!5arctanFS«11
«D1/2
cotvptG
u~t!5u0F~2«11!1cos2vpt
2~«11!G1/2
~12!
and in implicit form simply from energy considerations:
u25«u02
~«1cos2w!, ~13!
where «5(11h)/hpandvp5hpA«(11«). An initial con-
dition of u5u0!1 and w5p/2 is assumed.
This derivation is valid only for «.0, that is for h.
21. Similar small uorbits can be obtained for «!21 with
«(11«).0. We will restrict our discussion to these two
regions. When «(11«),0, the trajectory changes shape to
include large oscillations in u, violating the small uassump-
tion. This corresponds to an unperturbed orbit crossing the
equator with periodic oscillations of Mfromezto2ezdi-
rection.
B. Average system energy
Use the constant-energy motion trajectory @Eqs.~12!and
~13!#as a starting point, and treating the damping and spin
current as a perturbation, the average rate of energy change
^dU/dt&is obtained using Eq. ~1!, with Eq. ~11!foru8and
w8. The average energy variation rate thus obtained is1
KKdU
dtL52~2hp«u02!hs2~2hp«u02!ahpF2«~11«!A
1~112«!1hs
hp2BG ~14!
with
A[K1
«1cos2wL52«11
2«~11«!
B[Kcoswsinw
«1cos2wL50 ~15!
as long as «(«11).0. Therefore,
1
KKdU
dtL522~11h!FS11h11
2hpDa1hsGu02.~16!
C. Low-field switching threshold
Foruhu,1, Eq. ~16!gives the on-axis stability threshold
for spin-current-driven motion at the small cone-angle limit.
For spin current, instability occurs when the magnitude of hs
exceeds a critical value. In this case,
hs,hsc52~11h11
2hp!a. ~17!
Placing real-life units back in, we have for the magnitude of
the critical spin-injection current:
Ic51
hS2e
\Da
ucosfu~a2lmHkMs!S112pMs
Hk1H
HkD,
~18!
which was the same as shown in Ref. 7 but now also in-
cludes an easy-plane anisotropy 2 pMs/Hk. This relation is
also consistent with the results obtained by Katine et al.9
It is curious to notice that the easy-plane anisotropy hp
does not affect the magnetic switching threshold of uhu51,
yet it does affect the threshold for spin-current-induced
switch. For large easy-plane anisotropy uhscu’ahp/2. This is
because a magnetic-field-driven switch can occur with M
practically rotating only in the easy plane, whereas a spin-current-induced switch has to involve significant amount ofout-of-plane precession.
It is also important to mention that Eq. ~17!only gives a
threshold for an instability towards an increasing cone angle
insmall
ulimit.Itdoesnotguaranteethattheconeanglewill
increase indefinitely and a switching event will follow. For
largehpsystems the actual switching requires a spin current
with larger magnitude than dictated by Eq. ~17!, as will be
discussed later using a numerical example.
D. High-field switching threshold
Foruhu@hp11, and with a large spin-current hspushing
the moment in the opposite direction as hdoes, one obtains
another threshold, either for current or for applied field, for
the high-field forced alignment of Mwith respect to applied
field. This relates to the stable small cone-angle ( u0!1)
solution for the unperturbed ( a50,hs50) orbit in the limit572 PRB 62 J. Z. SUNof«(«11).0 but «,21. In this case, because Mandhare
in opposite directions along the easy axis, a small u0stability
corresponds to an energy maximum . Using Eq. ~16!and
keeping track of the signs with regard to the relative align-
ment of Mandh, one gets the threshold fields for field-
induced switching under a large spin current hs:
uhac(6)u5uhsu
a6S111
2hpD, ~19!
wherehac(1)is the threshold field for Mto switch from anti-
parallel to parallel to an hincreasing in magnitude, while
hac(2)is the threshold field for switching of Mback from a
parallel to antiparallel state with respect to has the value of
his reduced. In real-life units, if one assumes a zero-field
threshold current Ic}2pMs, then Eq. ~19!can be rewritten
as
Hac(6)52pMsSIbias
Ic61D, ~20!
whereIbiasis the bias current of the junction. Equations ~19!
and~20!are related to the intermediate magnetoresistance
states observed in Fig. 3 ~d!of Ref. 9, as will be discussed
below using a numerical example.
IV. NUMERICAL STUDIES
Numerical studies of Eq. ~10!are organized as follows.
First we discuss the time evolution of the magnetization M.
This is followed by a study on the effect of spin current on
the magnetic switching, both in terms of sweeping field H
and sweeping current hs. We then discuss the speed of
switching under spin-current drive as it compares to the morefamiliar field-driven reversal process. In the end we brieflydiscuss the device and material implications of this mecha-nism.
We use the reduced units introduced in previous sections
for our simulation. A summary of the units and their refer-ence values are given in Table I. In most simulation results
discussed below we set the LLG damping coefficient
a
50.01, unless differently specified for individual cases.
A. Time evolution of M under the influence of a spin-current
First consider the simple uniaxial anisotropy case with
hp50. The time evolution of Munder the influence of a
uniaxial anisotropy field is one of a spiral motion traced by
the tip of M. The damping action causes a decrease of the
cone angle, and the moment eventually comes to rest in the
direction parallel to the easy-axis ez. This is well known.
Under the influence of a spin-current hs,Mwill pick up an
additional precession corresponding to the spin-angular mo-mentum deposition. The balance between the damping term
and that of h
sdetermines the final resting direction of M,a s
described by
du
dt52u@a~11h!1hs#
dw
dt52~11h!1hsa ~21!that has a solution of
u~t!5u0exp~2t/t1!
t151/@a~11h!1hs# ~22!
with a threshold spin current of
hsc52a~11h!. ~23!
Given an initial state such that Mis stationary and slightly
tilted away from the uniaxial direction ezatt50, the time-
dependent evolution of M(t) is illustrated in Fig. 2 for dif-
ferent values of spin current hs. A characteristic of a spin-
current-induced switch of M(t) is the reversal of its
precession direction when it crosses the equatorial position.This comes from the sign change in the spin-current-inducedtorque term in Eq. ~6!. A purely magnetic-field-driven switch
ofM(
t) does not have this precession reversal.
For finite values of hp, as one may expect, the precession
in general follows an elliptically distorted trajectory, with thecone angle more spread out in the easy plane, while becom-ing confined normal to the easy plane. An example of thissituation is shown in Fig. 3. Later we will show that a large
h
p(@1) does not only compress the precession cone angle
into the easy plane, it can also introduces a steady-state pre-cession for spin currents with a magnitude slightly above the
low-cone-angle stability threshold h
scfrom Eq. ~17!.
B. Spin-current induced switching
As shown above, in the case of pure uniaxial anisotropy
with the spin polarization aligned to that of the easy axis,
whenhsexceedshsc,Mswitches its orientation to become
aligned with the spin-polarization. This can be traced out as
an hysteresis loop in M(hs), as shown in Fig. 4. A system-
atic dependence of the switching field hscon applied field h
is found, following Eq. ~23!.
Forh50,M(hs) is always symmetric against origin.
That does not necessarily mean M(I) is symmetric. This is
because the amount of net torque deposition depends sensi-
FIG. 2. The precession of magnetization under the influence of a
spin current. Uniaxial anisotropy alone. ~a!Time dependence of
Mz.~b!Time dependence of Mx.~c!A 3D portrait of the spiral
motion of the tip of M. North pole is ezdirection.PRB 62 573 SPIN-CURRENT INTERACTION WITH A MONODOMAI N...tively on the condition of the interface responsible for spin-
current injection. This situation can be phenomenologicallyhandled by introducing an effective spin polarization con-
taining a sign dependence on I, i.e.,
h!h6in Eqs. ~7!and
~18!.
C. The effect of a strong easy-plane anisotropy
The hysteresis loop M(hs) changes its shape upon the
introduction of a large easy-plane anisotropy. This is illus-
trated in Fig. 5. For hp.5, before a complete reversal of M,
a sloped M(hs) region is seen to develop when uhsufirst
exceeds uhscuas defined by Eq. ~17!. This region corresponds
to a steady-state precession with an oblong-shaped trajec-
tory. This can be seen in the time dependence of Mz(t), as
shown in Fig. 6.
This large angle steady-state precession is a result of an
increase in effective damping for large cone-angle dynamics.As one increases the easy-plane anisotropy, the precessionbecomes increasingly nonlinear and complex, which chan-nels more energy into the higher frequency modes that give
more dissipation to M(
t) per unit time. A balance can al-
ways be established between increased energy injection from
increasing hsand the increased damping from increasing
cone angle, as long as the maximum cone angle does notcross the equator. This is the region where a steady-stateprecession is formed. Once the precession crosses the equa-tor, however, due to the sign change of the torque term @Eq.
~6!#, the precession accelerates, and a switching of M(
t)
results.
Figure 5 also shows the dependence of M(hs) hysteresis
on applied field h. While Eq. ~17!does dictate the onset of M
reversal ~see bottom inset, Fig. 5 !, the threshold current po-
sition corresponding to the completion of Mreversal ~de-
fined ashsc1,2shown in Fig. 5 !does not follow from that of
Eq.~17!, but rather has a stronger dependence in h, as shown
in Fig. 5. Furthermore, the dependence of hsc1,2on appliedfieldhis asymmetric. When the direction of his to decrease
hsc2, the magnitude of hscdecreases asymptotically towards
hsc52a(11h11
2hp) from Eq. ~17!. It does not decrease
belowhschowever until h,21. Then a sudden switch oc-
curs and hsc2drops to zero. This is reasonable, since h,
21 is the condition for a magnetic-field induced moment
reversal without the assistance of spin current, naturally hsc2
becomes zero. On the other hand, if his to increase the
magnitude of hsc1, as occurred on the left-side transition
shown in Fig. 5, hsc1’s change is not bounded by hsc, hence
larger field dependence in the ~broadened !switching field is
observed there.
D. High-field switching threshold
An example of the simulated high-field switching thresh-
old behavior is shown in Fig. 7. Here a large spin current
hs56.0 is applied with its polarization along the 2ezdirec-
tion. Also included is an easy-plane anisotropy of hp5190.
The applied field is swept from 2800 to 800 along the ez
axis. This is a situation very similar in quantitative terms to
the experiment shown in Fig. 3 ~d!of Katine et al.’s paper.9
TheM(h) behavior consists of four regions.
~1!Forh,0 in Fig. 7, the effect of both applied field and
the spin current is to force Mto point to 21, henceMpoints
to2ez.
~2!Between h50 andh5hp: This region corresponds to
an unperturbed orbit involving large cone angles where «
,0 and «(11«),0. In the present situation, the competi-
tion between applied field hwhich now favors a 11 direc-
tion forM, and that of the spin current ~still pointing towards
2ez) causes a strong steady-state precession when 1 ,h
!hp.A sh!hpa stable resting position develops for Mthat
points out of the easy plane and making an angle with the
2ezdirection, results in an Mzvalue between 0 and 21.As
hincreases in value, Mincreasingly tilts back towards
2ez, away from h, causing Mzto approach 21. It is at first
counterintuitive that Mzin this region should become closer
to21 as the applied field is being increased. But this is
actually not surprising once one realizes that in this region
FIG. 3. The precession of magnetization under the influence of a
spin current. Uniaxial anisotropy plus an easy-plane anisotropy ofh
p55. The uniaxial-anisotropy-alone trace of a50.01 is included
for comparison. The elliptical precession is apparent here, with thecone-angle being compressed in the direction normal to the easyplane. Panels have the same definition as in Fig. 2.
FIG. 4. Spin-current-driven reversal of magnetization. Uniaxial
anisotropy only, no easy-plane anisotropy is added. The switchingcurrenth
scshows linear dependence on applied easy-axis field has
predicted by Eq. ~23!.574 PRB 62 J. Z. SUNthe behavior of Munder the influence of hsis to seek a
resting position with energy maximum .
~3!Between h5hpandh5hac(1)5uhsu/a1(11hp/2), fol-
lowing Eq. ~19!. In this region Mzis completely forced to
21.~4!Whenh.hac(1), where finally the effect of applied
field takes over, and Mswitches direction to rest along the
direction of applied field, and Mz511.
OnceMswitches direction to align with h, the stability
criteria for small cone angle, Eq. ~16!changes sign, hence on
its way back, hac(2)5uhsu/a2(11hp/2).
The monodomain threshold hac(6)can only give a rough
estimate to the high-field threshold observed in Katine
et al.’s experiment. For a real thin-film sample such as the
one used by Katine et al.,the magnetic dynamics between
h50 andh5hac(6)is not even approximately monodomain in
nature. This is because in this region large cone-angle mo-
tion as well as resting positions with significant out-of-the-
plane component of Mis involved, which would favor spin-
wave excitation or domain formation. The fact that thesystem in this parameter region seeks out an energy maxi-mum rather than a minimum, further increases the likelihoodfor the film to break into complex domains or to excite spinwaves. This may account for the wide plateau observed inRef. 9. A proper treatment of these is however beyond thescope of this paper.
E. Effect of spin current on the M Hswitching characteristics:
Spin-current-induced distortion to astroids
Here we study the switching behavior of M(H) as a func-
tion of spin current hs. We focus on on-axis geometries,
where the relative angle fbetweennsandezis either zero or
p.
Without the presence of a spin current, the M(H) switch-
ing characteristic for simultaneous easy- and hard-axis fieldpresence is an analytically solvable energy minimumproblem.
11The resulting switching boundary forms an as-
troid shape, with the boundary curves defined by
FIG. 5. Spin-current induced magnetic switching hysteresis loop
M(hs), with a strong easy-plane anisotropy hp5190~chosen to
emulate a cobalt thin-film’s demagnetization field 4 pMs). The on-
set position in hsforMswitching follows the estimate given in Eq.
~17!. It is not very sensitive to the change of hf r o m0t o1 ,a s
expected ~sinceh!hpin this range of h). However, the beginning
portion of the switching curve is much more gently sloped. This isdue to the presence of a steady-state precession as discussed in thetext and in Fig. 6.
FIG. 6. The evolution of steady-state precession and the
completion of M(hs) switch as the precessing moment crosses
equator upon increasing hs. Initial u5p20.01. Small deviation
from pis added to shorten the initial build-up time for precession
amplitudes. Curves ~b!–~e!are progressively offset in vertical di-
rection. A crossover from steady-state precession and completeswitching occurs within 1.2127497 ,h
s,1.2127498.
FIG. 7. Numerical result for the high-current, high-field behav-
ior. Field his applied along ez. Spin-current polarization is along
2ez. From origin to h5hp, the competition between applied field
and the spin-current causes a deflected final resting angle for the
moment. Between h5hpand point A with hA5hac15(hs/a)1(1
1hp/2) according to Eq. ~19!, spin-current effect causes the mo-
ment to seek out the energy maximum for its resting direction,hencem
z521. At point A, the energy term from applied field
finally takes over, and a switching of magnetic moment from 21t o
1 occurs. This switching is hysteretic—upon reversing the sweepdirection of applied field, the moment does not switch back to -1
until point Cwhereh
C5hac25(hs/a)2(111
2hp). The net hyster-
esis opening between points AandCisdh5hp12;hp.PRB 62 575 SPIN-CURRENT INTERACTION WITH A MONODOMAI N...heasy2/31hhard2/351. ~24!
The effect of a spin current on the shape of the astroid is
shown in Fig. 8, for a monodomain magnetic moment withonly a uniaxial anisotropy term. Notice that the amount ofspin current required to significantly change the shape of theastroid is within a factor of 2 of the zero-field critical current
h
sc. The increase in magnitude of the switching field on the
left side of the astroid is interesting to observe, as this is aregion where the spin-momentum deposition completelychanged the magnetic system’s trajectory of motion, distort-ing significantly the astroid boundary. While without thepresence of the spin current a large cone-angle precessionwill develop, the spin current stabilizes the small cone-angleprecession, and hence this region is now treatable as a per-turbation to the constant-energy trajectory.
The introduction of an easy-plane anisotropy h
pdoes not
affect the zero-spin-current switching astroid @Eq.~24!#.
However, it does alter the effect the spin current has on theshape of the astroid. The evolution of the switching charac-
teristics for h
p5190 is shown in Fig. 9. The amount of spin
current required to affect the shape of the astroid again is
around the zero-field critical current hsc, as determined by
Eq.~17!. The presence of a strong easy-plane anisotropy
completely suppresses the increase of switching field magni-tude on the left side of the astroid.
V. SWITCHING SPEED
The reversal of Munder a spin-current-driven situation is
different from that of a magnetic-field-driven case.
For field-driven reversal, in small damping limit ( a!1),
the reversal time for magnetization Malong its easy axis
depends primarily on the initial dynamics of the moment.
For a system with «5(11h)/hp&0, the unperturbed orbit
for small ucan be used to estimate the amount of time for
the cone angle to evolve from its initial value u0tou.I nt h e
limit ofhp@1, to the leading order of «,i ti s
t~u!51
hpA2«lnu1Au22u02
u0. ~25!
Therefore the asymptotic behavior of the initial reversal-
related switching time is ~setting u;1):t0’1
hpA2«ln11A12u02
u0}Hu12hu21/2~h!11!
2lnu0 ~u0!01!.
~26!
This relation is verified by numerical simulation for a spe-
cific set of conditions: hp5190 and a50.01 and 0.001, re-
spectively, as shown in Fig. 10.
For current-driven reversal the process is somewhat dif-
ferent. Since current-driven reversal is determined by thebalance of damping-related dissipation and the spin-currentinduced energy gain, damping plays a much more critical
role—it determines the value of threshold h
sc. For the
uniaxial anisotropy-only situation, Eq. ~22!gives
t~u!’uhs2hscu21ln~u/u0!. ~27!
A similar scaling behavior is found numerically in the large
hplimit, as shown in Fig. 11.
To compare the situation between a field-driven reversal
and a spin-driven switch, one examines the behavior of t(u)
for the same amount of relative overdrive amplitude infield and in spin current. Following Eq. ~17!, for a given
amount of overdrive amplitude
uhsu5(11d)uhscu,t
}(adhp)21ln(u/u0), whereas for the same amount of over-
drive in field uhu511d,t}(dhp)21/2ln(2u/u0). Thus for a
spin-current switch with a fixed percentage of overdrive, the
speed is directly proportional to its threshold current ahp,
and hence to a, whereas for magnetic-field-driven switch, a
doesn’t matter as long as a!1.
Another limit for a spin-current switch is when the current
is well-above the threshold. In this case, t0}uhsu21ln(u/u0).
Thus in a large current limit, the switching time for a spin-
injection process is independent of a, and is determined by
the amount of spin current injected. Thus, in a large spin-current limit, the total amount of spins needed for a reversalevent is independent of the magnitude of the spin current.
To get some feelings for real materials, consider a pat-
terned cobalt film. Assume a uniaxial anisotropy field of
H
k5100 Oe from the film’s in-plane shape. In the direction
perpendicular to the film, a demagnetization field of 4 pMs
’1.83104Oe’180Hkis present, thus hp’180, similar to
FIG. 8. Uniaxial anisotropy only: effect of spin-current injection
on the shape of M(H). The zero-current switching characteristics
reproduces the well-known ‘‘astroid’’ shape. For this simulation
a50.01, thus hsc50.01.
FIG. 9. Uniaxial anisotropy plus a strong in-plane anisotropy of
hp5190. The effect of spin-current injection on the shape of M(H)
is quite different from those shown in Fig. 8 with only uniaxialanisotropy. In this case, h
sc50.96 as calculated from Eq. ~17!.576 PRB 62 J. Z. SUNthehp5190 used in the simulation for Figs. 10 and 11. The
time conversion is t’Vk21t50.568(ns) twith Vk
5(2mB/\)Hk’1.763109s21. When driven at twice the
threshold value, for on-axis-only a magnetic-field-driven
switch, and at an initial angle of u051023, the initial-
reversal part of the switching time is about t0’0.34 ns, ac-
cording to data shown in Fig. 10. With the same amount of
overdrive ( hs52hsc), and the same u051023, the spin-
current driven process will involve a t0’3.98 ns.
VI. MATERIALS-RELATED DEVICE CONSIDERATIONS
Equation ~18!has important implications for device appli-
cations. First of all, there is a fundamental limit on howsmall the critical current can be if it were to be used forswitching a memory element. The limit is set by the memorybit size required for thermal stability. This was briefly dis-cussed in Ref. 7 where the numerical estimates were basedon a definition of super-paramagnetic transition temperatures
that allows a magnetic lifetime of 1 s. Here we discuss thiswith a more realistic magnetic stability requirement of 100
yr. The thermal transition lifetime
tLof the magnetic body
can be expressed as tL5tAexp(E0/kBT) with the thermal
activation barrier E0for moment reversal set by the uniaxial
anisotropy barrier height: E051
2a2lmMsHk.tAis associated
with the basic magnetic attempt frequency with 1/ tA
’109Hz. If one sets the magnetic lifetime tL.100 yr
53.153109s as criterion for super-paramagnetic transition,
this gives a super-paramagnetic transition temperature TS
such that E0/kBTS;ln(tL/t0);42.60. Thus E0542.60kBTS
anda2lmMsHk585.19kBTS. From Eq. ~18!, this means the
threshold current for a 100 yr stability against thermal rever-sal has to be larger than
I
c>1
hS2e
\Da~85.19kBTS!. ~28!
Taking h50.1 and a50.01 as a conservative estimate of a
typical magnetic metal such as cobalt, and setting operating
FIG. 10. Initial reversal-related switching time t0for magnetic
field-driven reversal. hp5190. Here we define t0as the amount of
time it takes for Mto evolve from u0tou’p/2.~a!t0is largely
determined by the unperturbed motion of M. Adding damping
changes the ringing characteristic after the initial reversal, but itdoes not significantly alter the initial switching time. As shown inthe text, an asymptotic relation
t;2logu0is held for zero ~or a
small !a.~b!t0scales essentially as uh21u21/2. Again the result is
fairly robust against adding a small a. The top inset shows time
dependencies of Mzand the definition of t0in our numerical
procedure.
FIG. 11. The reversal process for a spin-current-driven process.
~a!Initial reversal-time dependence on starting angle u0. A scaling
oft0}2t1lnu0is demonstrated, as discussed in the text. ~b!The
scaling of t0ashsapproaches hsc. It is described by t0}uhs
2hscu21, withhscas described by Eq. ~17!. Upper inset shows the
time-dependent evolution of Mz(t) and the definition of the initial
reversal time t0.PRB 62 577 SPIN-CURRENT INTERACTION WITH A MONODOMAI N...temperature TS5130°C 5400 K, we have the minimum
threshold current for technologically interesting applications
ofIc;140mA.
For thin-film devices in current-perpendicular geometry,
we can estimate the amount of current density required formagnetic switching. Assume that there are ways to neutralizethe demagnetizing field of the film, the threshold currentdensity can then be expressed as
J
c5a
hS2e
\D~lmHkMs!S11H
HkD, ~29!
wherelmcan be viewed as the thickness of the magnetic
switching layer. The critical current density is then directly
proportional to the film thickness lm. Again, taking cobalt as
an example where we assume a uniaxial anisotropy term of
Hk5100 Oe, and a saturation magnetization Ms.1.5
3103e m u/c m3, in zero-applied field, one has Jc54.6
3104lm(A/c m2), where lmis in angstroms. An all-metal
current-perpendicular pillar can probably take around 107to
108A/c m2of current density without short-term damage.
This gives a reasonable working film thickness of at least100 Å . For magnetic tunneling junctions, however, the prac-
ticalJ
cfrom materials and electrical integrity point of view
is limited to about 106A/c m2. This means to directly inject
spin current across a tunneling barrier into the magneticbody, the magnetic body would prefer to have softer anisot-
ropy energy product H
kMsto give a reasonable working film
thickness of well-above 1 0 Å . This can perhaps be done by
a careful selection of electrode material and its shape—alow-aspect ratio Permalloy magnetic dot perhaps will work.
Combining the requirements of thermal stability @Eq.
~28!#and current-density limit @Eq.~29!#, the lateral dimen-
sion of the magnetic body can be determined as well. To
have aT
S5400 K, again use the parameters for cobalt as we
did before, and set lm515 Å , one has a;1500 Å . Thesenumbers give a rough estimate to the relevant device dimen-
sions, although they should not be taken literally. For onething at such high aspect ratios it is questionable whether thefilm will remain single domained for its dynamic processes.
VII. SUMMARY
A preliminary study is presented here for the basic dy-
namic properties of a magnetic moment under the influenceof a spin current. The magnetic moment is found to precessunder the torque associated with spin-current-induced angu-lar momentum deposition. The competition between thespin-current-related energy gain and the LLG damping-related energy dissipation determines the precession process.Under appropriate conditions, the precession will lead to areversal of the resting direction of the magnetic moment,causing a magnetic switch. Quantitative predictions are madefor the threshold spin current for such a switch, as well as thegeneral dependence of the switching process on the magneticenvironment experienced by the moment. The switchingspeed under spin-current injection is predicted to be compa-rable to present-day field-driven switching processes, al-though the two processes are intrinsically different and theyfollow different asymptotic scaling behaviors with regard tothe initial and drive conditions. The spin current is also pre-dicted to affect the magnetic switching characteristics of themoment, causing a distortion to the astroid-shaped switchingcharacteristics.
ACKNOWLEDGMENTS
I wish to thank John Slonczewski and Roger Koch at IBM
Research and Professor Dan Ralph at Cornell University forfruitful discussions. I would also like to thank Roger Kochfor help setting up the computing environment for part ofthis simulation work.
1J. C. Slonczewski, J. Magn. Magn. Mater. 159,L 1~1996!.
2J. C. Slonczewski, J. Magn. Magn. Mater. 195, L261 ~1999!.
3L. Berger, Phys. Rev. B 54, 9353 ~1996!.
4L. Berger, J. Appl. Phys. 49, 2156 ~1978!.
5Y. B. Bazaliy, B. A. Jones, and S.-C. Zhang, Phys. Rev. B 57,
R3213 ~1998!.
6M. Tsoi, A. G. M. Jansen, J. Bass, W.-C. Chiang, M. Seck, V.
Tsoi, and P. Wyder, Phys. Rev. Lett. 80, 4281 ~1998!.
7J. Z. Sun, J. Magn. Magn. Mater. 202, 157 ~1999!.
8E. B. Myers, D. C. Ralph, J. A. Katine, R. N. Louie, and R. A.
Buhrman, Science 285, 867 ~1999!.
9J. A. Katine, J. F. Albert, R. A. Buhrman, E. B. Meyers, and D. C.
Ralph, Phys. Rev. Lett. 84, 3149 ~2000!.
10This is a phenomenological assumption that simplifies the mathwhile still keeping the essence of the physics. Details of the spin
angular momentum transfer process is significantly more com-plex, and is certainly interface dependent. Experimental quanti-fication remains to be obtained. A theoretical derivation basedon microscopic quantum mechanics for a specific five-layer ge-ometry was given by Slonczewski in Ref. 1, which gave Eq. ~6!
an additional factor of (1/
h)g(nsnm)5(1/h)@241(1
1h)3(31nsnm)/4h3/2#21. The angular dependence of this fac-
tor is not significant for small h.
11J. C. Slonczewski, IBM Research Memorandum No. 003.111.224
~1956!. Also see L. D. Landau and E. M. Lifshitz, Electrody-
namics of Continuous Media ~Pergamon, New York, 1960 !, Sec.
37, pp. 150–151.578 PRB 62 J. Z. SUN |
PhysRevB.77.134424.pdf | Electron magnetic resonance study of transition-metal magnetic nanoclusters embedded
in metal oxides
Vincent Castel and Christian Brosseau *
Laboratoire d’Electronique et Systèmes de Télécommunications, Université de Bretagne Occidentale, CS 93837, 6 Avenue Le Gorgeu,
29238 Brest Cedex 3, France
/H20849Received 25 October 2007; revised manuscript received 28 February 2008; published 10 April 2008 /H20850
Here, we report on the results of an electron magnetic resonance /H20849EMR /H20850study of a series of Ni /ZnO and
Ni //H9253-Fe2O3nanocomposites /H20849NCs /H20850to probe the resonance features of ferromagnetic /H20849FM/H20850Ni nanoclusters
embedded in metal oxides. Interest in these NCs stems from the fact that they are promising for implementingthe nonreciprocal functionality employed in many microwave devices, e.g., circulators. We observe that theEMR spectrum is strongly affected by the metallic FM content and its environment in the NC sample. Wereport the existence of broad and asymmetric features in the EMR spectra of these NCs. Our temperaturedependent EMR data revealed larger linewidth and effective gfactor, in the range of 2.1–3.7 /H20849larger than the
free electron value of /H110152/H20850, for all samples as temperature is decreased from room temperature to 150 K. The
line broadening and asymmetry of the EMR features are not intrinsic properties of the metallic nanophase butreflect the local /H20849nonmagnetic or magnetic /H20850environment in which they are embedded. Furthermore, the results
of a systematic dependence of the room temperature EMR linewidth and resonant field on the Ni content andthe corresponding effective microwave losses measured in previous works show a remarkable correlation. Thiscorrelation has been attributed to the dipolar coupling between magnetic nanoparticles in the NCs.
DOI: 10.1103/PhysRevB.77.134424 PACS number /H20849s/H20850: 75.50.Tt, 75.75. /H11001a, 76.30.Fc, 76.50. /H11001g
I. INTRODUCTION
Interest in the polarization and magnetization mechanisms
in nanocomposites /H20849NCs /H20850is on the rise. From the fundamen-
tal point of view, the main scientific drivers are the multi-plicity of new and interesting effects, e.g., product propertysuch as magnetoelectricity,
1–4and the observation that many
of the ideas central to the understanding of two-dimensionalelectromagnetism and magnetism indicate the need for newtheoretical and experimental approaches. Respective systemsmight be realized in granular mixtures, layered compounds,thin films, or artificial multilayers. Another reason to givesome attention to magnetic NCs is the current increase ininterest in biological physics and in the development of newpharmaceutical products.
5–9The particular interest among
the biophysical and chemical sciences is triggered by the factthat plasmonic NCs can provide promising platforms for thedevelopment of multimodal imaging and therapyapproaches.
10,11From the practical side, such studies are im-
portant for developing techniques that are able to producenanostructures in a controlled manner. However, expecta-tions for integrated nanoelectronic devices exhibiting newfunctionalities will become more realistic when there is com-plete understanding of the microscopic mechanisms that con-trol changes in electronic structure that scale with the clusterdimensions.
While much attention has focused on exploring the micro-
structure of materials by using conventional methods of char-acterization, recent work has recognized the value of conven-tional electron magnetic resonance /H20849EMR /H20850techniques /H20849see,
e.g., Refs. 12–14/H20850which can reveal both the average mag-
netic behavior and its microscopic inhomogeneity. Thesetechniques have proven to provide reliable approaches to thestability of nanoparticle dispersions which can be affected byaggregation and agglomeration due to their high surface en-ergy, secondary crystallization, and Ostwald ripening, just to
name a few indicative ones.
12,15–19At this length scale, con-
duction and magnetic properties considerably deviate frombulk, e.g., by showing a significant enhanced magnetic mo-ment for sizes up to a few hundred atoms.
4,9Within this
context, a powerful attribute of the EMR is its ability toexperimentally probe local scale.
As yet, few experimental approaches for the EMR analy-
sis of magnetic NCs have been discussed. Only a few se-lected magnetic nanoparticle systems, including
/H9253-Fe 2O3
/H20849Refs. 12,15, and 16/H20850and ferrites,20–23were investigated by
the EMR methods. So far, hardly any data exist on the EMRcharacterization of magnetic metal and/or metal oxide NCs.It is also worth emphasizing that several analytical
24and
numerical25,26approaches have been put forward to analyze
the resonance spectra of magnetic submicron particles. De-spite this motivation to develop a full understanding of fer-romagnetic /H20849FM/H20850metallic nanoclusters dispersed into a vari-
ety of /H20849magnetic or not /H20850hosts from EMR, several basic
features in the gigahertz EMR modes remain unclear. In par-ticular, there is no simple theory which allows the measuredspectrum to be related to the underlying microstructure. An-other basic issue is to determine whether the linewidth is anintrinsic feature of metallic clusters or arises as a conse-quence of surface interactions or other perturbations.
Our original intent for the present work was to investigate
Ni /ZnO and Ni /
/H9253-Fe 2O3NCs. A series of recent microwave
frequency-domain spectroscopy /H20849gigahertz /H20850studies of the
quasistatic effective permittivity and magnetic permeabilityposed fundamental questions concerning polarization andmagnetization mechanisms in these NCs.
27–32Here, these
materials were chosen because our group has previously pub-lished detailed accounts of experimental and modeling ap-proaches on the static magnetic and microwave response ofthe samples under study.
33–38This analysis allowed us toPHYSICAL REVIEW B 77, 134424 /H208492008 /H20850
1098-0121/2008/77 /H2084913/H20850/134424 /H208499/H20850 ©2008 The American Physical Society 134424-1simulate magnetization dynamics on solving the Landau–
Lifshitz–Gilbert equation coupled to the Bruggeman effec-tive medium approach. Traditionally, particle and aggregatesize information are considered irrelevant to the wave trans-port since rapid oscillations of the electromagnetic wave onlength scales larger than any scale
/H9264of the medium inhomo-
geneities are integrated out in the conventional effective me-dium analysis, where it is specifically assumed that
/H9264/H11270/H9261
with/H9261the wavelength of the probing wave, and thereby the
NC can be treated as a structureless continuummedium.
30,31,34–36,39,40Some very recent work has demon-
strated that ferromagnetic resonance /H20849FMR /H20850measurements of
these NCs,37,38or of hot isostatic pressed /H20849hipped /H20850polycrys-
talline yttrium iron garnet41are very sensitive to details of
the spatial magnetic inhomogeneities. Although these studieshave advanced the understanding of wave transport phenom-ena in granular NCs, striking discrepancies remain betweenexperiments and corresponding results obtained from exist-
ing phenomenological models and numerical simulations. Animportant question of broad fundamental interest is why theeffective permittivity and magnetic permeability appear to bevery sensitive to the details of the nanoparticle cluster struc-ture, thus suggesting a breakdown of the continuum-levelmodeling and bringing NC physics concepts to light. Theanswer to this question constitutes the key for understandingthe response of magnetic clusters to electromagnetic probes.
In the present study, we report on a detailed EMR study of
magnetic metal and/or metal oxide NCs. This paper providestwo main results. By varying the Ni volume fraction in thesamples, we observed that the EMR signal reflects the prop-erties of the metallic FM nanophases as well as the localnonmagnetic or magnetic environment in which they are em-bedded. Our data also indicated an empirical correlation be-tween the systematic dependence of EMR linewidth andTABLE I. Selected physical properties of the powders investigated in this study.
Powder ZnO /H9253-Fe2O3 Ni
Average particle sizea–d49 nm 23 nm 35 nm
Powder color White Brown BlackSpecific surface area BET
a/H20849m2g−1/H20850 22 51 15.6
MorphologycElongated Nearly
spherical,
facetedSpherical
Crystal phasea,dWurtzite Maghemite
/H20849Cubic spinel /H20850Fm3m/H20849225/H20850
ccp
Densitya/H20849gc m−3/H20850 5.6 5.2 8.9
aFrom manufacturer product literature.
bDetermined from specific surface area.
cChecked by TEM images.
dDetermined by XRD. In the XRD analysis, the possible influence of strain on the online broadening was
neglected. This may result in an underestimate of the particle size.
TABLE II. Overview of NCs compositions: ƒ xdenotes the volume fraction of the X species, ƒ pis the
porosity of the samples and ƒ resinis the volume fraction of resin. The uncertainty on ƒ xis typically of the
order of 5%.
Material designation ƒ Ni ƒZnO ƒp ƒresin ƒ/H9253-Fe2O3
nNiZ1 0.49 0.08 0.28 0.15
nNiZ2 0.42 0.17 0.27 0.14nNiZ3 0.38 0.21 0.26 0.15nNiZ4 0.33 0.26 0.25 0.15nNiZ5 0.29 0.30 0.26 0.15nNiZ6 0.25 0.35 0.25 0.15nNiZ7 0.18 0.44 0.23 0.14nNiZ8 0.09 0.54 0.22 0.15nNiZ9 0 0.63 0.21 0.16
1–nNiF 0.08 0.26 0.13 0.532–nNiF 0.17 0.25 0.14 0.443–nNiF 0.29 0.27 0.12 0.32
4–nNiF 0.50 0.26 0.15 0.09
5–nNiF 0.04 0.26 0.25 0.55VINCENT CASTEL AND CHRISTIAN BROSSEAU PHYSICAL REVIEW B 77, 134424 /H208492008 /H20850
134424-2resonant field on the Ni content and the corresponding mi-
crowave loss features.
The rest of the paper is organized as follows. Section II
gives some background on the samples we have investigatedand discusses technical details on the EMR characterization.This is followed in Sec. III by a presentation of an experi-mental analysis of the effects of varying the Ni content in theNCs on the EMR spectra. A comparison with previous FMRlinewidth data and effective microwave losses is given inSec. IV . Next, Sec. V presents the main conclusions of thisstudy and we make some comments regarding possible im-plications of these results.
II. EXPERIMENT
The same samples were used as in a previous study.33
Room temperature-pressed NC compacts were made underthe application of a uniaxial pressure of 64 MPa for 2 min.The morphology and size of the starting powders /H20849Table I/H20850
were determined by transmission electron microscopy/H20849TEM /H20850by using a 200 kV Phillips apparatus. Bright field
TEM images indicate that
/H9253-Fe 2O3and Ni particles are ho-
mogeneous with nearly spherical shape, whereas thewurtzite-type ZnO particles are rod shaped with an aspectratio of about 3:1. The phase purity was checked by x-raypowder diffraction /H20849XRD /H20850by using Cu K
/H92511radiation, and
the crystallite sizes were determined from the full width athalf maximum of the strongest reflection by using theWilliamson-Hall method after applying the standard correc-tion for instrumental broadening. The average crystallinesizes of the samples were also determined from analysis ofbright field that cross-sectional TEM images were found tobe consistent with the ones obtained from XRDmeasurements.
30–34The XRD analysis of spherelike clusters
suggests that Ni existed in the form of metal. These clusters,composed of Ni nanoparticles, are randomly and uniformlydistributed in the matrix and are isolated from each other bythe metal oxide and epoxy phases. The Ni cluster size in-creases with the Ni content. The metallic nanoparticle tendsto be oxidized, arising from the large surface-area-to-volumeratio and the high electronegativity of metallic nickel. Al-though not studied in detail, the presence of secondaryphases, e.g., NiO, was estimated to be less than 0.3 vol %from XRD. In addition, Ni nanoparticles can be protectedfrom oxidation by encapsulation in the epoxy phase.
The EMR experiments were performed in two sets of
samples /H20849see Table II/H20850. The first series /H20849Ni /ZnO /H20850comprising
nominal Ni volume fractions in the range of 0%–49% con-sisted of mixtures of Ni and ZnO nanoparticles and epoxyresin /H2084915 vol % /H20850. The second series /H20849Ni /
/H9253-Fe 2O3/H20850had nomi-
nal Ni volume fractions in the range of 4%–50% and /H9253-Fe 2O
fractions were chosen to maintain the total content of themagnetic phase constant /H1101560 vol %. For the two sets of
NCs, the residual porosities were estimated to be between 21and 28 vol %.
For the present EMR measurements, samples were cut to
pieces of about 1 /H110031/H110031m m
3. EMR signals were recorded
on a heterodyne spectrometer in a continuous wave modeX-mode microwave /H20849F=9.4 GHz /H20850with a 500 mW Varianklystron, a Bruker resonance TE
102cavity, a Varian electro-
magnet with maximum field amplitudes of 800 mT, and anitrogen flux cryosystem /H20849Oxford Instruments /H20850for low-
temperature measurements in the range from 150 K to roomtemperature /H20849RT/H20850. For g-factor calibration, the 1,1-diphenyl-
2-picrylhydrazyl standard has been used /H20849g=2.0037 /H20850. The
EMR signals recorded were the first derivatives of the powerabsorption, dP /dH, as a function of the applied magnetic
field Hby using 100 kHz modulation amplitude and lock-in
technique /H20849EG&G Princeton /H20850for calculations of gfactors,
peak-to-peak linewidths /H20849/H9004H
pp/H20850, and resonance field /H20849Hres/H20850.
For the g-factor measurements, the cavity frequency /H9263was
measured at each temperature and Hresis determined by the
location of the zero of the absorption derivative. Then, g
=0.714 48 /H1100310−6/H9263/Hres, where /H9263is in gigahertz and Hresin
kilo-oersted. The EMR measurement was performed on cool-ing the sample.
EMR signals were also obtained for neat nanoparticles by
using either powders placed in an EMR tube, and pumped to/H1102110
−3Pa in order to eliminate the moisture and oxygen ef-
fect, or in loose packed form with 15 vol % epoxy. For bothsamples, the EMR line cannot be accurately fitted to a singleLorentzian line shape /H20849not shown /H20850. Figures 1and2show that
H
res/H20849/H9004Hpp/H20850, for both neat and compacted powders of Ni and
/H9253-Fe 2O3, appreciably increases /H20849decreases /H20850with TforTsin
the range of 150–300 K. The broadening of the EMR featureis sharply decreased by upshifting the resonance field. Sys-tematic EMR characteristics follow the same monotonictrends; however, the data reveal that the dilution of nanopar-ticle powder in the epoxy host matrix and compaction havefor effect to downshift the EMR line and to decrease its peakwidth compared to the neat powder EMR features. The EMRlinewidth is affected by inhomogeneities and is quite large,i.e., 0.85–2.6 kOe. The difference between powder andloose packed form with epoxy can be attributed to someaspects of the microstructure, such as porosity, grain bound-aries and other extended defects, the presence of localstrains, or anisotropy in the randomly oriented magneticclusters. Figure 3illustrates that grapidly decreases with
increasing Tfor the neat Ni powder, whereas for
/H9253-Fe 2O3
powder, gshows little Tdependence and does not signifi-
cantly deviate from g/H110152.1–2.2. A similar behavior has been
reported in ferrite nanoparticles.12For ease of comparison,
data are plotted as g/H20849T/H20850/g/H20849RT/H20850. Part of the gshift with low-
ering Tcan be attributed to the increase in the demagnetizing
field. We would like also to emphasize that no measurableEMR signal for ZnO nanoparticle powder was detected.
For our low conductivity NCs and considering the mea-
sured values of the effective electromagnetic parameters ofthese NCs,
31,37,38we find that the skin depth is in the
102–103mm size range in the gigahertz frequency range,
i.e., much larger than the sample thickness. Thus, one cansafely assume a full and homogeneous penetration of themicrowaves into our samples. In composites with uniformdispersions of magnetic nanoparticles, the conductivity ofthe NC is mainly determined by the interparticle distance andeddy currents, produced within the particle is extremelysmall at high frequency, which are limited to individual par-ticles or aggregates. We note that Ramprasad et al.
27have
shown, in their phenomenological modeling of the propertiesELECTRON MAGNETIC RESONANCE STUDY OF … PHYSICAL REVIEW B 77, 134424 /H208492008 /H20850
134424-3of magnetic nanoparticle composites, that in the 0.1–10 GHz
frequency range, particles with radii smaller than 100 nm areexpected to encounter negligible eddy current losses. Thiswas found true even at high particle volume fraction, whenclustering of particles could result in aggregates much largerthan the actual particles. Furthermore, no signature for per-colation threshold is apparent for the data collected; thus, weinfer from the Ni content dependence of
/H9268dcthat the Ni nano-
aggregates should be separated in the ZnO matrix. It hasbeen recognized by now that in ferromagnetic NCs, theshielding and dissipation due to eddy currents rapidly dimin-ish with decreasing the particle size. This has for effect toreduce the dielectric losses in metallic nanoparticles.
III. ELECTRON MAGNETIC RESONANCE LINEWIDTH
PARAMETERS
We now present the data underlying our conclusions sum-
marized above. Full sets of absorption versus field derivativeprofiles, shown in arbitrary units, which correspond to rep-resentative EMR spectra of Ni /ZnO and Ni /
/H9253-Fe 2O3NCs,were obtained in the restricted temperature range from
300 to 150 K. Typical spectra are displayed in Figs. 4/H20849a/H20850and
4/H20849b/H20850at six different temperatures for Ni /ZnO /H20849Ni content of
17.5 vol % /H20850and Ni //H9253-Fe 2O3/H20849Ni content of 50.3 vol % /H20850
NCs, respectively. Note first that the EMR spectra display aseverely distorted line shape suggestive of inhomogeneousbroadening, which is typical of superparamagnetic resonancespectra.
25Unfortunately, the spectra cannot be meaningfully
deconvoluted. Possible explanations range from size andshape distributions to magnetic anisotropy /H20849see, for example,
Refs. 25and26/H20850. A consensus on the cause of these has yet
to be established partly because it is difficult to make quan-titative evaluations of the EMR line in composites of finemagnetic particles and also because there may not be a singlecause.
To analyze the temperature dependence of the EMR spec-
tra,/H9004H
ppandHresare shown in Fig. 5/H20849Fig. 6/H20850as a function
of temperature for the Ni /ZnO NCs /H20849Ni //H9253-Fe 2O3NCs /H20850. The
inset of Fig. 1indicates how /H9004Hppand Hreswere actually
measured. The data of the lower panels of Figs. 5and6serve
to make four important points. First, although different indetail, the Tdependence of /H9004H
ppin Figs. 5and6has impor-
tant features in common, namely, as Tis increased, /H9004Hpp
monotonically decreases. Also, the line shape becomes quite
asymmetrical at the lower temperatures. For the three lowestNi volume fractions in Ni /
/H9253-Fe 2O3NCs, a very weak de-150 180 210 240 270 3001.01.21.41.61.82.02.22.42.62.02.22.42.62.83.03.2
Ni powder compacted
with epoxy (15 vol% )
Ni neat powder
T(K)/CID39Hpp(kOe)
(b)H(kOe)dP/dH (a.u)/CID39Hpp
Hres
(a)Ni powder compacted
with epoxy (15 vol% )
Ni neat powderHres(kOe)
FIG. 1. /H20849a/H20850The line position, Hres, as a function of temperature
for neat Ni powder and a Ni /H2084956 vol % /H20850powder compact with
15 vol % epoxy /H20849see text for details /H20850. The inset shows that the reso-
nant field Hresis determined by the location of the zero of the
absorption derivative. The dotted and dashed lines serve as guidesfor the eye. /H20849b/H20850S a m ea si n /H20849a/H20850for the peak-to-peak linewidth /H9004H
pp
corresponding to the peak-to-peak separation in the absorption de-
rivative /H20851inset of /H20849a/H20850/H20852.120 150 180 210 240 270 3000.81.01.21.43.123.163.20
(b)/CID74Fe2O3powder compacted
with epoxy (15 vol% ))
/CID74Fe2O3neat powder
/CID39Hpp(kOe)
T(K)(a)/CID74Fe2O3powder compacted
with epoxy (15 vol% )
/CID74Fe2O3neat powderHres(kOe)
FIG. 2. /H20849a/H20850The line position, Hres, as a function of temperature
for neat /H9253-Fe2O3powder and a /H9253-Fe2O3/H2084956 vol % /H20850compact with
15 vol % epoxy. The dotted and dashed lines serve as guides for theeyes. /H20849b/H20850S a m ea si n /H20849a/H20850for the peak-to-peak linewidth /H9004H
pp.VINCENT CASTEL AND CHRISTIAN BROSSEAU PHYSICAL REVIEW B 77, 134424 /H208492008 /H20850
134424-4cline around 1.1 kOe is observed. At low temperatures, the
spin-spin interactions cause spin dynamics to freeze out, andspins essentially behave as static spins. At higher tempera-tures, when the time scale of the dynamics of the spins isfast, it might be expected that the conduction electron spin-lattice relaxation time in metals, T
1, is the characteristic time
for the return to thermal equilibrium of a spin system drivenout of equilibrium by the microwave field at resonance. It iswell established that in pure metals, T
1is limited by the
scattering of conduction electrons by the random spin-orbitpotential of nonmagnetic impurities or phonons.
14These
changes in /H9004Hpp/H20849T/H20850and g/H20849T/H20850are reflected in the motional
narrowing of the EMR line.15,25Second, when these values
are compared to the experimental data of neat and compactedpowder with epoxy, i.e., Figs. 1and 2, it is seen that the
dependence of /H9004H
pponTmatches rather well that for neat
powder, except for the Ni //H9253-Fe 2O3NCs containing the two
largest Ni volume fractions. We also notice that for theNi /
/H9253-Fe 2O3sample with 50 vol % Ni, one recovers very
similar values of /H9004Hppthan for those displayed in Fig. 5for
Ni /ZnO samples. Thus, the line broadening is not an intrin-
sic feature of Ni but arises as a consequence of surface in-teractions, reflecting the fact that interaggregate interactionsinduce collective behavior between the magneticnanophases. It seems likely that the interfaces play a key rolein determining the ultimate performance of magnetic nano-structures: the surface anisotropy and magnetization signifi-cantly modify the static states and dynamic properties.
42Fur-
ther, the broadening of the EMR features is sharply increasedfor a large Ni content in Ni /
/H9253-Fe 2O3NCs. That the Hres
versus Tdependences do not map the Hresof powderedsamples is also a noticeable fact. A natural question is why
we observe a substantial downshift of the EMR line of themagnetically diluted samples in comparison with neat pow-ders. It is rather likely that this downshift is a manifestationof powder compaction during sample fabrication. Indeed, weobserved /H20849not shown /H20850an apparent correlation between the
residual porosity and the effective density of the NCsamples, e.g., we simultaneously measured a 30% drop ofthe porosity with a 10% increase in the density as the appliedpressure during the compact fabrication process is changedfrom 33 to 230 MPa. Third, it is worth noting that /H9004H
ppfor
Ni /ZnO NCs is larger than the corresponding value of /H9004Hpp
for Ni //H9253-Fe 2O3NCs for a given Ni concentration. Interest-
ingly, there is also a clear trend toward lower Hresfor smaller
temperature, as displayed in Fig. 5. Fourth, the EMR lines
continuously shift to high fields as the temperature is in-creased. For the Ni /ZnO NCs, the temperature variation
H
res/H20849T/H20850resembles /H20851see Fig. 5/H20849a/H20850/H20852that observed for neat or
compacted powder, in stark contrast to what is observed forNi /
/H9253-Fe 2O3NCs, i.e., Fig. 6/H20849a/H20850.
Figure 3summarizes the dependence of the lowering of
the effective gfactor on temperature for the two kinds of
NCs. The inset shows the actual values of g/H20849RT/H20850. For
Ni /ZnO NCs, these values rapidly fall to the gfactor corre-150 180 210 240 270 3001.01.11.21.3
0 1 02 03 04 05 06 07 08 09 0 1 0 02.02.22.42.62.83.03.23.43.63.8Ni/ZnO
Ni//CID74-Fe2O3
NP:
PCE:
Ni content (vol%)g( R T )powder: Ni /CID74Fe2O3g(T)/g(RT)
T(K)Ni/ZnO: 9 vol% 18 29 33 42
Ni//CID74Fe2O3: 4v o l % 8 17 29 50
FIG. 3. Effective gfactor, normalized to the RT value g/H20849RT/H20850,o f
Ni /ZnO /H20849open symbols /H20850, and Ni //H9253-Fe2O3/H20849filled symbols /H20850NC
samples as a function of temperature. The corresponding values forthe neat powders of Ni /H20849open stars /H20850and
/H9253-Fe2O3/H20849filled stars /H20850have
been shown for comparison. The inset shows g/H20849RT/H20850versus the Ni
content in the Ni /ZnO /H20849open circles /H20850and Ni //H9253-Fe2O3/H20849filled tri-
angles /H20850NC samples, Ni powder compact /H20849open square /H20850with
15 vol % epoxy and /H9253-Fe2O3powder compact /H20849filled square /H20850with
15 vol % epoxy /H20851phosphorus-containing /H20849PCE /H20850/H20852, and neat Ni /H20849open
star/H20850and/H9253-Fe2O3/H20849filled star /H20850powder /H20849NP/H20850samples. The solid lines
serve as guides for the eyes. 02468 1 0 1 2(a)
H(kOe)151 K180 K209 K240 K270 KdP/dH (a.u.)Ni/ZnO 17 vol%
294 K
(b) 148 K180 K210 K240 K270 KNi//CID74Fe2O350 vol%dP/dH (a.u.)294 K
FIG. 4. /H20849a/H20850X-band EMR spectra /H20849absorption derivative /H20850for a
representative Ni /ZnO NC sample /H20849Ni content of 17.5 vol % /H20850and
different temperature values. /H20849b/H20850X-band EMR spectra /H20849absorption
derivative /H20850for a representative Ni //H9253-Fe2O3sample /H20849Ni content of
50.3 vol % /H20850and different temperature values.ELECTRON MAGNETIC RESONANCE STUDY OF … PHYSICAL REVIEW B 77, 134424 /H208492008 /H20850
134424-5sponding to neat powder /H20851g/H20849RT/H20850/H110152.2/H20852. By contrast, g/H20849RT/H20850is
practically constant for Ni //H9253-Fe 2O3NCs. The clear and sys-
tematic decrease in the gfactor can be found up to the high-
est accessible temperature of 300 K. The experimental be-havior could arise from several sources. First, there ismotional narrowing. Another possible mechanism is the in-terplay of demagnetizing field effects and of the presence ofshort-range magnetic ferrimagnetic ordering due to the
/H9253-Fe 2O3nanoparticles.
Figure 7/H20849Fig. 8/H20850illustrates how /H9004Hppand Hresat RT
change as a function of the metallic FM nanophase contentfor the Ni /ZnO NCs /H20849Ni /
/H9253-Fe 2O3NCs /H20850. For Ni /ZnO NCs,
/H9004Hppsignificantly increases as Ni volume fraction is in-
creased followed by a sharp drop at Ni content of/H1101530 vol %, while in the same Ni fraction range, /H9004H
pp
monotonically increases for the Ni //H9253-Fe 2O3specimens.
These data serve to make two further points. First, the broad-ening of the EMR line for Ni /
/H9253-Fe 2O3samples is sharply
increased by increasing the Ni volume fraction. We interpretthe broadening of the EMR features in these samples as aris-ing from the strong collective magnetostatic intergranular in-teractions of the nanosized FM clusters with the surroundingferrimagnetic matrix. Second, it is interesting to relate themaximum of /H9004H
ppto the electrical transport properties of the
Ni /ZnO NCs characterized by the four-point probe
technique.37In Ref. 37, we discussed a set of electrical trans-
port data of these materials and observed that the RT dcconductivity
/H9268dcversus Ni content data for Ni /ZnO NCs
collected at low field exhibit an S-shaped curve /H20849notperco-
lativelike process /H20850with an exponential increase between 10
and 30 vol % Ni and a change of slope at about 30 vol % Ni.
Generally, in the solid state, we classify EMR lines into
those that are homogenously broadened and those that areinhomogeneously broadened.
13,14The main contributions to
homogeneous broadening are the magnetic dipolar coupling,spin-lattice interaction, interaction with radiation field, andmotionally narrowing fluctuations of local fields.
13,14For the
inhomogeneous case, the line broadening mechanism distrib-utes the resonance frequencies over an unresolved band, e.g.,inhomogeneous external magnetic field, anisotropic interac-tions in the randomly oriented set of spins, unresolved hy-perfine structure, and strain distribution. Thus, the distribu-tion in local fields will make the spins in various parts of thesample feel different field strengths. Here, in the analysis ofour FMR spectra of the NCs under study here,
37we found
that inhomogeneity based line broadening mechanisms, dueto the damping of surface and/or interface effects and inter-particle interaction, affect the FMR effective linewidth.These remarks suggest that the /H9004H
ppversus Tand Ni content
is most likely associated with two contributions to the ob-served EMR linewidth: on the one hand, there is the homo-2.02.22.42.62.83.0
150 200 250 3001.41.61.82.02.22.42.62.842%
18
9
(a)Ni/ZnOHres(kOe)neat
compacted
neat
(b)42%
18
9
/CID39Hpp(kOe)
T(K)
FIG. 5. /H20849a/H20850The line position, Hres, as a function of temperature
for Ni /ZnO NC samples. The number indicates the Ni volume frac-
tion. For the purpose of comparison, we have represented the valuesofH
resfor neat Ni powder and a Ni /H2084956 vol % /H20850powder compact
with 15 vol % epoxy as dashed and dotted lines, respectively. /H20849b/H20850
S a m ea si n /H20849a/H20850for the peak-to-peak linewidth /H9004Hpp. For the purpose
of comparison, we have represented the values of Hresfor neat Ni
powder and a Ni /H2084956 vol % /H20850powder compact with 15 vol % epoxy
as dashed and dotted lines, respectively.2.82.93.03.13.2
150 200 250 300 3500.81.21.62.02.42.8neat
(a)50%
29
17
8
4Hres(kOe)
neat
(b)Ni//CID74-Fe2O3
50%
29
17
8
4
T(K)/CID39Hpp(kOe)
FIG. 6. Same as in Fig. 5for Ni //H9253-Fe2O3samples. For the
purpose of comparison, we have represented the values of Hresfor
neat Ni powder and a Ni /H2084956 vol % /H20850powder compact with
15 vol % epoxy as dashed and dotted lines, respectively.VINCENT CASTEL AND CHRISTIAN BROSSEAU PHYSICAL REVIEW B 77, 134424 /H208492008 /H20850
134424-6geneous line broadening mechanism involving dipolar inter-
action and spin-lattice relaxation, which is stronglytemperature dependent /H20849motional narrowing /H20850. On the other
hand, the unsymmetrical line shape, especially at low tem-peratures, is an indication that the EMR is broadened in aninhomogeneous manner and the EMR linewidth is expectedto increase as a function of magnetic field.
37
IV. COMPARISON WITH FERROMAGNETIC
RESONANCE SPECTRA AND MICROWAVE LOSSES
It may be meaningful to compare our EMR parameters to
values of the linewidths measured over the 9–10 GHz fre-quency range recently reported in FMR experiments, inves-tigating the surface anisotropy contribution to the anisotropyof Ni and
/H9253-Fe 2O3nanoparticles,37and to effective micro-
wave losses measured in order to probe the evolution oflarge-wave-vector spin wave modes in these NCs.
38The
FMR response of magnetic nanostructures is a rich area in itsown right, and several models,
43,44e.g., two-magnon scatter-
ing theory, have been applied to the problem of magneticheterogeneities in coarse-grained heterostructures. Fromthese FMR measurements,
37it was pointed out that the char-
acteristic intrinsic damping dependent on the selected mate-rial and the damping due to surface and/or interface effectsand interparticle interaction were estimated. Inhomogeneousdamping due to surface and/or interface effects increases
with diminishing particle size, whereas damping due to in-teractions increases with increasing volume fraction of mag-netic particles /H20849i.e., reducing the separation between neigh-
boring magnetic phases /H20850in the composite.
Figures 7and8summarize the main findings of this work.
The upper and lower panels in Figs. 7and8provide a direct
comparison of /H9004H
ppandHresas a function of Ni content and
at RT between, on the one hand, the EMR /H208499.40 GHz /H20850fea-
tures and the nominal /H208499 and 10 GHz /H20850uniform FMR mode,
and on the other hand, the nominal /H208499.40 GHz /H20850microwave
losses. A number of interesting features are worth remarking.First, all of the curves show nonmonotonic variations. Sec-ond, as can be realized from these graphs, the striking mainfeature is the qualitative similarity in the three types of mea-surements. Third, as seen in Figs. 7and 8, substituting a
nonmagnetic by a magnetic host matrix not only shifts theposition of the resonance but also sensitively affects its line-width. This is caused by locally changing the interactionsbetween magnetic nanoparticles. It has been recognized thata shortening of T
1can result from weak dipole interactions,
whereas strong interactions may result in slowing down ofthe relaxation.
45The analysis of the FMR spectra was inter-
preted in Ref. 37as arising from aggregates of magnetic
nanoparticles, each of which resonates in an effective mag-netic field composed of the applied field, the average /H20849mag-
netostatic /H20850dipolar field, and the randomly oriented magnetic
anisotropy field. The importance of the Ni concentration has2.42.62.83.03.23.4
10 20 30 40 501.41.61.82.02.22.42.6
123456(a)Ni/ZnOHres(kOe)FMR: 9G H z
10 GHz from [39]
EMR 9.40 GHz
FMR: 9G H z 10 GHz from [39]
EMR 9.40 GHz
(b)/CID39Hpp(kOe)
Ni content (vol.%)Losses 9.40 GHz from [40]Losses L (dB)
FIG. 7. EMR line peak-to-peak width /H9004Hp.p.and position, Hres,
/H208499.40 GHz /H20850plotted as a function of the Ni content in the Ni /ZnO
NC samples at RT. Comparison with FMR data /H208499 and 10 GHz /H20850
from Ref. 39and microwave loss data /H208499.40 GHz /H20850from Ref. 40.2.93.03.13.23.33.43.53.63.7
0 1 02 03 04 05 01.21.62.02.42.8
04812FMR: 9G H z
10 GHz from [39]
EMR 9.40 GHzNi//CID74-Fe2O3
(a)Hres(kOe)
FMR: 9G H z 10 GHz from [39]
EMR 9.40 GHz
(b)/CID39Hpp(kOe)Losses L (dB)
Ni content (vol.% )Losses 9.40 GHz from [40]
FIG. 8. Same as in Fig. 7for Ni //H9253-Fe2O3samples.ELECTRON MAGNETIC RESONANCE STUDY OF … PHYSICAL REVIEW B 77, 134424 /H208492008 /H20850
134424-7also been discussed in relation to measurements of the spin
wave group velocity induced by the samples.38The presence
of nonmagnetic phases of specific type and volume fractionoffers the possibility of controlling the magnetic and micro-wave properties of NCs.
V. CONCLUDING REMARKS
In summary, a systematic EMR study in Ni /ZnO and
Ni //H9253-Fe 2O3NCs, for temperatures ranging from 150 up to
RT, has been presented. Two compounds with different prop-erties /H20849diamagnetic ZnO and ferrimagnetic
/H9253-Fe 2O3/H20850and
structural disorder were chosen in order to vary the magneticinteractions between the nanoparticles in these heterostruc-tures. There are general reasons to expect that the EMR linebroadening and position are not intrinsic features of the me-tallic FM content, but arise as a consequence of the interac-tion between aggregates and other interface perturbations.The motional narrowing offers an explanation for the widevariation in the degree of broadening of the EMR line as afunction of temperature. The strength of the coupling, asmanifested by the EMR linewidth, can be significantly modi-fied by the metallic FM content. One very interesting findingis that there is a clear correlation between EMR linewidth,the corresponding FMR features, and the effective micro-wave losses measured in these heterostructures. The correla-tion found here is far from trivial and we regard it as moti-vation for the development of models underlying the processof resonance in granular heterostructures in which all thedetails take place. More specifically, although a large numberof theoretical calculations have been performed to under-stand the phenomenon of resonance in nanostructures, nofirst-principles theoretical calculation has been reported tounderstand the role of the nonmagnetic phase in tuning theFM of nanoclusters which can be a useful reference for ex-perimentalists.
This study is part of a larger effort to identify essential
factors governing magnetoelectricity in dense nanostructuredcompacts and to explore control possibilities due to their rich
behaviors under magnetic and electric perturbations.
46There
are/H20849at least /H20850three directions in which the present work could
be extended. First, one wishes to know if our experimentalfindings do extend to functional multiferroic NCs motivatedby the desire to be able to simultaneously manipulate differ-ent combinations of microwave properties by the applicationof external fields. Second, the question begs to be asked:what is the impact of having extremely dense nanocompacts,e.g., by using hot isostatic pressing in order to have a nearlycomplete elimination of porosity, on EMR linewidths. Third,numerous experimental challenges exist when consideringmagnetic NCs because they offer a promising avenue towardnanoelectronics and spintronics. EMR can give important in-sights complementing information from direct studies of themorphological structure of magnetic nanoclusters. Investiga-tions at these length scales are in their infancy, and muchroom exists for improvement. There remains significant workahead in continuing to understand the growth modes of nano-particle aggregates, e.g., for Ni clusters containing up to 800atoms, regularly spaced peaks in the mass spectra of a certainmagic cluster sizes have been interpreted as icosahedralgrowth patterns.
47The applicability of metals in nanoelec-
tronic and spintronic devices in which information is pro-cessed by using electron spins will depend on a sufficientlylong spin lifetime, i.e., long T
1or narrow EMR linewidth.48
We hope to discuss the magnetism of Ni clusters and the
resulting microwave frequency-domain spectroscopy in fu-ture work.
ACKNOWLEDGMENTS
One of the authors /H20849V .C. /H20850gratefully acknowledges finan-
cial support from the Conseil Régional de Bretagne. We wishto thank J. Ben Youssef for helpful conversations. We alsowish to thank N. Kervarec for her assistance in EMR experi-ments.
*Also at Département de Physique, Université de Bretagne Occi-
dentale. brosseau@univ-brest.fr
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134424-9 |
PhysRevB.92.024403.pdf | PHYSICAL REVIEW B 92, 024403 (2015)
Propagating spin waves excited by spin-transfer torque: A combined electrical and optical study
M. Madami,1E. Iacocca,2,3S. Sani,4G. Gubbiotti,5S. Tacchi,5R. K. Dumas,2J.˚Akerman,2,4and G. Carlotti1
1Physics Department, University of Perugia, Perugia, Italy
2Physics Department, University of Gothenburg, Gothenburg, Sweden
3Department of Applied Physics, Division for Condensed Matter Theory, Chalmers University of Technology, Gothenburg, Sweden
4Materials Physics, School of Information and Communications Technology, Royal Institute of Technology (KTH), Kista, Sweden
5Istituto Officina dei Materiali del Consiglio Nazionale delle Ricerche (IOM-CNR),
Unit `a di Perugia c/o Dipartimento di Fisica, Perugia, Italy
(Received 13 April 2015; revised manuscript received 9 June 2015; published 2 July 2015)
Nanocontact spin-torque oscillators are devices in which the generation of propagating spin waves can be
sustained by spin transfer torque. In the present paper, we perform combined electrical and optical measurementsin a single experimental setup to systematically investigate the excitation of spin waves by a nanocontactspin-torque oscillator and their propagation in a Ni
80Fe20extended layer. By using microfocused Brillouin
light scattering we observe an anisotropic emission of spin waves, due to the broken symmetry imposed bythe inhomogeneous Oersted field generated by the injected current. In particular, spin waves propagate on theside of the nanocontact where the Oersted field and the in-plane component of the applied magnetic field areantiparallel, while propagation is inhibited on the opposite side. Moreover, propagating spin waves are efficientlyexcited only in a limited frequency range corresponding to wavevectors inversely proportional to the size of thenanocontact. This frequency range obeys the dispersion relation for exchange-dominated spin waves in the farfield, as confirmed by micromagnetic simulations of similar devices. The present results have direct consequencesfor spin wave based applications, such as synchronization, computation, and magnonics.
DOI: 10.1103/PhysRevB.92.024403 PACS number(s): 85 .75.−d,75.30.Ds,81.07.Lk,78.35.+c
I. INTRODUCTION
Nanocontact (NC)-based spin-torque oscillators (STOs) [ 1]
have been extensively studied in recent years due to theirpotential applications in a variety of fields, including spin-tronics, magnonics [ 2], and data storage [ 3]. Nanocontact-
based spin-torque oscillators typically consist of an extendedpseudo-spin-valve where two magnetic layers are separatedby a nonmagnetic spacer. One of the magnetic layers is a hard
magnet that acts as a spin polarizer and a reference layer, and it
is referred to as the “fixed” layer. The second “free,” magneticlayer is softer and thinner, making it susceptible to spin-transfer torque (STT) induced dynamics [ 4,5]. Depending on
the material used for the free layer, unique magnetodynamicalmodes can be generated in NC-STOs. On the one hand, byusing Co/Ni multilayers exhibiting perpendicular magneticanisotropy, NC-STOs have been shown to support steadymagnetization dynamics at low external fields [ 6] and even the
excitation of localized modes known as magnetic dissipativedroplets [ 7–10]. On the other hand, using soft magnets such as
NiFe, the existence of propagating [ 11,12], localized [ 12–15],
and vortex [ 16,17] modes has been demonstrated, depending
on both the strength and the direction of the external magnetic
field.
The propagating mode was predicted theoretically by
Slonczewski [ 18] for a perpendicularly magnetized NC-STO,
i.e., by applying an external magnetic field perpendicular tothe device plane strong enough to saturate the free layer. Thismode has been shown to consist of exchange-dominated spinwaves (SWs) propagating radially away from the NC regionat frequencies above the ferromagnetic resonance (FMR)frequency with a wavenumber inversely proportional to theNC diameter. The propagating nature of this mode lends itselfto coupling NC-STOs to achieve better spectral features bysynchronization [ 19–23], to perform computation [ 24,25], or
to propagate information in magnonic devices [ 26,27].
The existence of the propagating mode was demonstrated
only recently by employing either electrical measurements
[28,29], to study SW-mediated synchronization, or micro-
focused Brillouin light scattering ( μ-BLS) [ 11], to directly
detect the emitted SWs. Although these experiments pro-vided unambiguous proof of the propagating character ofthis mode, micromagnetic simulations including the Oerstedfield generated by the bias current [ 13,30] predicted that
the propagation is generally anisotropic, especially if the
applied field is tilted away from the device normal. This
has tremendous consequences for the design and applicationof devices utilizing STT-driven SWs. However, to the bestof our knowledge, no direct experimental evidence of such
asymmetric emission has been provided to date for out-of-plane magnetized NC-STOs with well-defined propagatingspin waves. Evidence of asymmetric emission has been
experimentally demonstrated only for in-plane magnetized
NC-STOs by the studies of Demidov et al. [15,31] to date.
In the present paper, we combine electrical characterization
andμ-BLS in a single experimental setup to systematically
investigate both the electrical properties of the STT-induceddynamics and the characteristics of the propagating SWsexcited in an out-of-plane magnetized NC-STO. Evidence isprovided for anisotropic SW propagation in these devices, asreproduced by micromagnetic simulations. More importantly,the STT-generated SWs are found to propagate within awavevector range dictated by both the SW dispersion in the farfield and the diameter of the NC. In fact, micromagnetic sim-ulations reveal that nonlinear dynamics are strongly dampedclose to the NC (near-field region), while only wavevectorsobeying the SW dispersion relation are able to propagatein the far-field region, i.e., at distances larger than the NC
1098-0121/2015/92(2)/024403(7) 024403-1 ©2015 American Physical SocietyM. MADAMI et al. PHYSICAL REVIEW B 92, 024403 (2015)
dimensions. These results are relevant for the development of
SW-based devices, including the synchronization of NC-STOarrays, computation, and magnonics.
A. Experimental details
Samples were fabricated on a SiO 2(1μm) covered
silicon wafer through the following processing steps: apseudo-spin-valve stack of Pd (8 nm)/Cu (15 nm)/Co (8 nm)/Cu (8 nm)/Ni
80Fe20(4.5n m ) / C u( 3n m ) / P d( 3n m ) w a s d e -
posited by magnetron sputtering; then, making use ofphotolithography, rectangular 8 ×16-μm
2mesas were
defined. A 30 nm thick SiO 2layer was deposited on top of the
mesas to realize electric insulation of the devices. Defined inthis insulation layer above each mesa were 2 ×4μm
2ground
electrodes and circular NCs with 100-nm diameter. Finally,contact pads with ground-signal-ground (GSG) geometry, asdepicted in Fig. 1(c), were fabricated with sputter deposition
of 1μmC u/20 nm Au in a photolithography prepared lift-off
pattern. The final device allows for μ-BLS optical access on
one side of the NC only, as shown in Fig. 1(c).
Measurements in the frequency domain were performed
using a broadband spectrum analyzer (SA). A dc was injectedinto the NC while the device impedance was continuouslymonitored in order to avoid damage due to Joule heating.The direction of the injected dc is negative (i.e., electronsdrift from the free to the fixed layer) as required to obtain anSTT-induced enhancement of the magnetization dynamics inthe free layer [ 11]. Notably, this approach is only sensitive to
the magnetodynamics generated very near the NC, along thepath of the dc.
Microfocused Brillouin light scattering measurements were
performed applying an external magnetic field Hat an
angle of about 15
◦from the sample normal by means of
a customized projected field electromagnet. As has alreadybeen demonstrated in a previous paper [ 11], the out-of-plane
magnetized NC geometry favors the emission of propagatingSWs in the extended portion of the NiFe free layer. At the sametime, the slight tilt of the external field allows us to define thedirection of the in-plane component of the field, H
IP,a ss h o w n
in Fig. 1. This choice is crucial in defining the direction of the
propagating SWs, as we will demonstrate below. The emittedSWs were experimentally detected at room temperature bymeans of a μ-BLS setup described in detail elsewhere [ 32].
We measured the Stokes side of each spectrum only, in orderto halve the total acquisition time. This approach is justifiedby the symmetry of the Stokes and anti-Stokes sides of thespectrum in a measurement performed at normal incidence ina thin magnetic film [ 33].
To summarize, our setup allows us to electrically investigate
the generated dynamics of the NC-STO while simultaneouslycharacterizing the emitted SWs by μ-BLS.
B. Micromagnetic simulations
Micromagnetic simulations were performed using the
graphic processing unit (GPU) accelerated software Mumax3[34]. The extended free layer was modeled by a disk with a di-
ameter of 2 .2μm and absorbing boundary conditions (ABCs)
to prevent spurious generation and reflection of SWs. TheABCs were implemented by linearly increasing the Gilbert
damping coefficient over 200 nm towards the disk edge, sothat the active area of the model was a 1 .8μm diameter disk.
We considered the device nominal free layer thickness to be4.5 nm and the magnetic parameters as follows: saturation
magnetization μ
oMS=0.69 T, Gilbert damping α=0.01,
exchange stiffness A=11 pJ/m, and no magnetocrystalline
anisotropy. These parameters define the cell discretization to4.3×4.3×4.5n m
3, below the exchange length λex≈6n m ,
resulting in a 512 ×512 mesh. Spin-transfer torque was con-
sidered only in a cylindrical region defined by the NC ofdiameter d=100 nm positioned in the geometrical center of
the disk. We assumed a polarization consistent with a Co layer,P=0.3, and a symmetric torque λ=1, as has previously been
shown to model similar devices with high accuracy [ 13,14].
The direction of the fixed layer was calculated numericallyby solving the magnetostatic boundary conditions for a Cothin film with saturation magnetization μ
oMP=1.5T . B o t h
the external applied field and the current-generated Oerstedfield were included in the simulations. Unless specified, thesimulations were performed with a fixed time step of 10 fs atroom temperature.
The spectral characteristics of the generated dynamics can
be estimated from 10 ns long simulations sampled at 10 ps,returning a frequency resolution of ≈97 MHz. Field-dependent
simulations indicate that high field magnitudes are required toexcite well-defined SWs. This can be understood from thefact that demagnetizing fields arise at the boundaries of thesimulated disk, favoring a vortex ground state. Applied fields ofmagnitude μ
oH> 650 mT are numerically found to preclude
the formation of a vortex and to allow the excitation of STT-induced propagating SWs.
II. RESULTS AND DISCUSSION
A. Anisotropic spin-wave emission and decay length
The first step of our experiment was to investigate the effect
of varying the direction of the in-plane component of theexternal magnetic field ( H
IP) on the spatial distribution of SWs
emitted below the NC area. To perform such an experimentthe external field intensity was set to μ
oH=+ 700 mT and
the field direction was tilted so that its in-plane componentwas antiparallel to the Oersted field on the side of the NCwhich is accessible to μ-BLS, as shown in Fig. 1(a).B y
injecting a dc of I=30 mA into the NC, we were able to
obtain steady-state oscillations at a frequency of 15 .5 GHz
with an intensity of about +9 dB over noise, as measured by
the SA. In order to map the intensity of the emitted SWs,we then performed a two-dimensional μ-BLS scan over an
area of about 2 ×1μm
2with a step size of 250 nm on the
optically accessible NC side at a distance of about 1 μmf r o m
the NC itself. The measured two-dimensional map, shownin Fig. 1(a), was obtained by integrating the measured SW
intensity in a frequency range of 0 .5 GHz around the central
value of 15 .5 GHz. This μ-BLS map clearly shows emission
from the NC area, confined in a relatively narrow beam whichpropagates in the direction perpendicular to both the directionof the Oersted field and H
IP. If the external field polarity is
reversed ( μoH=− 700 mT), the Oersted field and HIPbecome
024403-2PROPAGATING SPIN W A VES EXCITED BY SPIN- . . . PHYSICAL REVIEW B 92, 024403 (2015)
(a) (b)
(c)
FIG. 1. (Color online) (a, b) SW intensity maps measured by μ-BLS in the green area of panel (c) for two different directions of the
in-plane component ( HIP) of the external field, H=700 mT and I=30 mA. (c) Scanning electron microscope (SEM) image of the device
with the GSG pads, NC position and the direction of the Oersted (Oe) field generated by the current ( I) flowing into the NC.
parallel on the optically accessible NC side [ 29] but no SWs are
detected in this case, as shown by the μ-BLS map in Fig. 1(b)
[35]. This clearly demonstrates anisotropic SW emission,
confirming previous numerical predictions indicating that thelargest SW intensity is emitted on the side of the NC where
1 . 01 . 21 . 41 . 61 . 82 . 02 . 2200300400500600 µ-BLS intensity
best-fit curve intensity (arb. units)
distance from the NC ( µm)
FIG. 2. (Color online) SW intensity (circles) measured by
μ-BLS as a function of the distance ( X−X0) from the NC position.
Best-fit curve (line) obtained using Eq. ( 1).the Oersted and the HIPfields are antiparallel [ 13,30]. As the
second step of this investigation, we measured the decay of theemitted SW intensity ( i) as a function of the distance from
the NC position ( X−X
0), by scanning the laser probe along
theXdirection. The results of these measurements are shown
in Fig. 2(black dots) together with the result of a best fit
analysis obtained using the following analytical expression:
i(X)=i0+A
X−X0·e−X−X0
l (1)
where i0is the baseline, X0is the NC position (fixed at
X0=0), and lis the decay length of SW intensity; Aand
lare the free parameters in the fit routine, which returns
a value of l=500±50 nm. This is in very good agree-
ment with the expected value obtained from the expressionl=v
g/2αω=500 nm, where vg=1.0μm/ns is the SW
group velocity extracted from the simulated dispersion curveof the free layer (see Fig. 5),α=0.01 is the conventional
value of damping in NiFe, and ω=2πfis the SW angular
frequency ( f=15.5 GHz).
B. Dependence of the spin-wave emission on the injected
current and applied field intensity
Next, we turn our attention to the characteristics of
the emitted SWs by simultaneously measuring the spectra
024403-3M. MADAMI et al. PHYSICAL REVIEW B 92, 024403 (2015)
-20 -18 -16 -14 -12 -10 -8 -6
frequency (GHz)(a)
(b) (d)
-20 -18 -16 -14 -12 -10
frequency (GHz)µ0H=550 mT
µ0H=800 mTµ0H=550 mT
µ0H=800 mT
(e)(c)
FIG. 3. (Color online) (a) μ-BLS and (b) SA spectra measured as a function of the intensity of the external field Hf o rafi x e dv a l u eo ft h e
injected dc I=30 mA. (c, b) Color plots of the sequence of spectra in panels (a) and (b). (e) Results of micromagnetic simulations obtained
under the same conditions.
obtained electrically and optically when varying either the
intensity of the external magnetic field Hor the direct current
I. The results reported in Fig. 3were obtained by injecting a
constant current I=30 mA and applying an external magnetic
field of variable intensity (in the range H=550−800 mT)
with its in-plane component ( HIP) directed as in Fig. 1(a),t o
favor the emission of SWs on the optically accessible side ofthe device. The first two panels show the μ-BLS spectra of
SW intensity measured at a fixed position of about 1 .0μm
away from the NC [Fig. 3(a)] and the sequence of spectra
acquired with the SA [Fig. 3(b)]a saf u n c t i o no f H.T h e
same data are reported in Figs. 3(c) and 3(d) on color scale
bidimensional plots. The data obtained from μ-BLS features
two well-defined peaks. The lowest frequency peak, which isnot observed on the SA spectra [Fig. 3(d)], exhibits a constant
intensity and can be measured even for I=0 [cf. red spectrum
in Fig. 4(a)]. It corresponds to the thermally activated FMR
mode of the NiFe layer, consistent with Kittel’s equation asaf u n c t i o no f H. The highest frequency peak of Fig. 3(c) is
instead observed in the SA spectra at the same frequency forall the measured fields and corresponds to the SWs emittedby the STT-driven precession of the magnetization under theNC. The blue-shift of this peak with respect to the FMRfrequency is a signature of the propagating character of theSWs emitted away from the NC, which is further confirmedby the fact that its signal is measurable up to about 2 .2μm
away from the NC itself, as was shown in Fig. 2. The positive
field tunability of this mode is estimated to be 24 MHz /mT.
A comparison of the above experimental results with thoseobtained from micromagnetic simulations [Fig. 3(e)] accounts
for a very good quantitative agreement over the entire rangeof fields we investigated. Careful inspection of the measuredspectra reveals the presence of a mode transition for a fieldvalue of H=675 mT, denoted by two resonant frequencies in
both the μ-BLS and SA spectra. Corresponding to this mode
transition, the SA spectrum is strongly modified, exhibiting asharper and more intense peak. The occurrence of such modetransitions is very common in this kind of NC-STO devices[28,29] and reflects the complicated nonlinear dynamics that
can also be affected by unique and local features of the realNC. As a matter of fact, nominally identical devices presentone or more mode transitions at different field/current values,or even no transitions at all.
A direct comparison of the measured peaks corresponding
to the FMR and STT modes in the μ-BLS spectra [Fig. 3(a)]
suggests that the two modes have comparable intensities. Thisresult may seem surprising at first, since a much larger intensityshould be expected for STT-driven SWs than for thermallyexcited SWs. The reason for this apparent inconsistencylies in the wavevector content of the two modes and howit is efficiently collected by the optics of our experimentalsetup. By combining the effect of the finite collection angle[θ=48.6
◦,NA=sin(θ)=0.75] of our microscope objective
with the effect of the uncertainty in the in-plane componentof the wavevector of the scattered photons, resulting fromthe limited spatial extent of the laser spot on the sample(≈300 nm), it is possible to demonstrate that the efficiency
of our apparatus in detecting SWs with small wavelengths
024403-4PROPAGATING SPIN W A VES EXCITED BY SPIN- . . . PHYSICAL REVIEW B 92, 024403 (2015)
-20 -18 -16 -14 -12 -10
frequency (GHz)-20 -18 -16 -14 -12 -10 -8 -6
frequenc y shift (GHz)FMR
I=23 mA
I=38 mAI=0 mA
FMRI=23 mA
I=38 mA
(a)
(b) (d)(c)
FIG. 4. (Color online) (a) μ-BLS and (b) SA spectra measured as a function of the intensity of the injected dc ( I) for a fixed value of the
external field H=680 mT. (c, b) Color plots of the sequence of spectra in panels (a) and (b).
decreases very rapidly as the wavelength is reduced below
300 nm [ 11]. Since the diameter of the NC under investigation
is only 100 nm, we expect the wavelength of propagating SWsto be smaller than 200 nm [ 18], which means we can detect
them with relatively low efficiency in our apparatus.
Figure 4shows the results of a second set of simultaneous
μ-BLS and SA characterizations obtained by setting the
external field intensity to a fixed value of H=680 mT and
varying the intensity of the injected dc ( I) over the range
between 23.0 and 38 .0m A . T h e fi r s t μ-BLS spectrum (red
line) in Fig. 4(a) was measured at I=0m A , s h o w i n g t h e
thermal FMR mode. In the following sequence of μ-BLS
spectra [Fig. 4(a)], the FMR signal was no longer acquired, in
order to reduce the acquisition time and because its frequencydoes not vary with current, so the only visible peak inthe spectra is the one corresponding to the STT-driven SWexcitation. Figure 4(b) shows the corresponding sequence of
SA spectra, while Figs. 4(c) and4(d) report the same μ-BLS
and SA measurements in bidimensional color scale plots.Similarly, as in the case of the field characterization (Fig. 3),
we observed a blue-shift of the STT-driven SW frequencieswith respect to the FMR, as well as a positive currenttunability that we estimate to be 250 MHz /mA. On increasing
I, a mode transition is observed for the value I=29.0m A ;this is characterized by a relatively large frequency jump of
about 2 GHz, clearly visible in the SA sequence of spectra,and accompanied by a dramatic reduction in linewidth andan increase in maximum intensity. It is interesting to notehow the signal coming from propagating SWs, as measuredbyμ-BLS, is easily detectable only over a finite range of
currents, I=29.0−35.0 mA, after the mode transition. Before
the mode transition ( I< 29.0 mA) the SW signal is hardly
detectable, probably because of the very low STT efficiency, asis confirmed by the electric measurements. More interesting isthe existence of an upper bound ( I=35.0 mA), above which
the intensity of the emitted SWs rapidly decreases. This isdiscussed in greater detail in the following paragraphs.
The existence of a well-defined dc range (and a
corresponding frequency range), in which propagatingSWs are experimentally detected, is a reproducible featurethat we observed in several NC-STO devices with slightlydifferent NC diameters, in the range 80 −120 nm, obtaining
results which are in good qualitative agreement with thosepresented in this paper. In order to shed more light onthis effect, we calculated the dispersion curve for SWs inthe out-of-plane magnetized NiFe layer ( H=680 mT).
The resulting frequency vs 1 /λplot is shown in Fig. 5(b),
where it is compared with the frequency vs I
plot of
024403-5M. MADAMI et al. PHYSICAL REVIEW B 92, 024403 (2015)
I=29 mA I=36 mA
FMR
= 150 115 nm(b) (a)
FIG. 5. (Color online) (a) μ-BLS spectra measured as a function
of the intensity of the injected dc ( I) for a fixed value of the external
fieldH=680 mT. (b) Simulated SW dispersion curve of the NiFe
free layer.
Fig. 5(a). We can see good quantitative agreement between
the frequency of the FMR mode, as measured by μ-BLS,
and the simulated frequency at 1 /λ=0(k=2π/λ=0).
From a direct comparison between the two panels in Fig. 5,i t
is clear that the finite frequency range detected experimentallycorresponds to a finite wavelength range of λ=115−150 nm.
This is the central result of the present paper, as it suggeststhat propagating SWs emitted by an out-of-plane magnetizedNC-STO have a limited range of accessible wavelengths,which is ultimately associated with the NC diameter andthe exchange-dominated dispersion relation of SWs [ 36]. In
other words, a NC-STO cannot efficiently excite exchange-dominated SWs with a wavelength much shorter (or longer)than its own NC diameter. This has tremendous implicationsfor the synchronization of NC-STOs, since the wavelengthunambiguously determines the phase difference between thedevices and ultimately the phase-locking condition.
The above observations can be further tested using micro-
magnetic simulations. Due to the finite size of the simulateddisk, much stronger fields are required to obtain a coherentSW emission. Consequently, we set a field of magnitudeH=800 mT tilted 15
◦from the plane normal in the following
simulations. To characterize the allowed propagating SWs,we performed simulations at T=0 K and determined their
wavelength as a function of distance via smoothed pseudo-Wigner-Ville (SPWV) transform. By this method, it is possibleto tune the real and reciprocal space resolution by makinguse of smoothing windows. The wavelength content of thegenerated SW is determined by performing a SPWV transformon a simulation snapshot along the Xdirection, where we
used a Gaussian window of 4 .3 nm for the real space and a
Hann window of 1 .9μm
−1for the reciprocal space. We then
averaged 100 SPWV transforms, each one calculated fromdifferent snapshots of the same time-dependent simulation,to further improve the accuracy of the method. The resultsfor NC-STO driven at 34 and 25 mA are shown as colorplots in Figs. 6(a) and 6(b), respectively, where the vertical
black lines indicate the boundaries of the NC and the colorrepresents the normalized SW magnitude in logarithmic scale.The choice of the values for Iwas made in order to have one
value below the SW emission threshold (25 mA) and the otherone right in the middle of that range (34 mA), as confirmedby Fig. 5(a). We remind the reader that this figure must be
understood as the wavelength content ( yaxis) as a function
of distance for the SW propagating along X. Whether the
I = 34 mA
I = 25 mA
FIG. 6. (Color online) SPWV transform of simulated SWs along
Xfor (a) I=34 mA and (b) I=25 mA and an external field of
H=800 mT. The vertical black lines indicate the boundaries of the
NC while the white dashed lines indicate wavelength obtained fromthe SW dispersion relation at each frequency, namely (a) 19 .2 GHz
and (b) 17 .1 GHz. The color contrast indicates the normalized
magnitude in logarithmic scale of the SW associated with eachwavelength ( yaxis) as a function of X.
NC-STO is driven at 34 mA [Fig. 6(a)]o r2 5 m A[ F i g . 6(b)],
most of the wavelength content is rapidly damped within about0.2μm from the NC center (near-field region). This strong
wavelength content describes the nonlinear forced dynamicsof the system due to the presence of strong/local effects inthe NC area such as the STT effect and the Oersted field.However, when the NC is driven at 34 mA [Fig. 6(a)], a band
of wavelengths is observed to prevail up to the simulationboundary, and only in the +Xdirection. This wavelength
band is in good quantitative agreement with the wavelengthanalytically obtained from the SW dispersion relation for NiFeat the driven NC-STO frequency (white dashed line) andsimilar to the NC diameter. In contrast, when the NC-STOis driven at 25 mA [Fig. 6(b)], this wavelength band, although
present, is rapidly damped within about 0 .6μm, corresponding
to a scenario in which the Oersted field strongly distortsthe magnetic landscape. It is worth mentioning that theseresults indicate that SW do propagate in the −Xdirection
as well, as expected from exchange coupling, but their energyis negligible for distances greater than 0 .5μm from the NC. An
additional interesting feature of Fig. 6is that the wavelengths
close to the NC boundary are lower (higher) in the +X(−X)
direction corresponding to the decrease (increase) of the localfield magnitude induced by the Oersted field.
III. CONCLUSIONS
The properties of propagating SWs emitted by an out-of-
plane magnetized NC-STO were investigated by means ofa combined radio frequency (RF) and μ-BLS experimen-
tal setup. We experimentally demonstrated the anisotropicemission of SWs, which is concentrated on the side of theNC where the Oersted field and the in-plane component ofthe external field are antiparallel. The analysis of both thefield and the current tunability of the device showed a clearblue-shift of the STT-excited SW frequency with respect tothat of the FMR, as well as the presence of abrupt modetransitions. More importantly, it was found that propagatingSWs are only efficiently excited over a limited interval ofwavelengths comparable with the NC diameter. Given thedispersion relation in the far field, this corresponds to a range
024403-6PROPAGATING SPIN W A VES EXCITED BY SPIN- . . . PHYSICAL REVIEW B 92, 024403 (2015)
of frequencies of a few gigahertz. We believe these results will
be of the utmost importance for further progress in NC-STOsynchronization, computation, and magnonic applications viaemitted SWs.
ACKNOWLEDGMENTS
Support from the European Community’s Seventh Frame-
work Programme (FP7/2007-2013) under Grant No. 318287“LANDAUER” and by the Ministero Italiano dell’Universit `a
e della Ricerca (MIUR) under the PRIN2010 project (No.2010ECA8P3) is gratefully acknowledged. Support from theSwedish Research council (VR), the Swedish Foundation forStrategic Research (SSF), and the Knut and Alice WallenbergFoundation is gratefully acknowledged. E. Iacocca acknowl-edges support from the Swedish Research Council, Reg. No.637-2014-6863.
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024403-7 |
PhysRevApplied.15.024017.pdf | PHYSICAL REVIEW APPLIED 15,024017 (2021)
Giant Perpendicular Magnetic Anisotropy Enhancement in MgO-Based Magnetic
Tunnel Junction by Using Co /Fe Composite Layer
Libor Vojá ˇcek ,1,2,*Fatima Ibrahim ,1Ali Hallal ,1Bernard Dieny ,1and Mairbek Chshiev1,3,†
1Univ. Grenoble Alpes, CNRS, CEA, Spintec, 38000 Grenoble, France
2CEITEC BUT, Brno University of Technology, Purkynova 123, 612 00 Brno, Czech Republic
3Institut Universitaire de France (IUF), 75231 Paris Cedex 5, France
(Received 17 August 2020; revised 8 December 2020; accepted 8 December 2020; published 8 February 2021)
Magnetic tunnel junctions with perpendicular anisotropy form the basis of the spin-transfer torque
magnetic random-access memory (STT MRAM), which is nonvolatile, fast, dense, and has quasi-infinite
write endurance and low power consumption. Based on density-functional-theory (DFT) calculations, wepropose an alternative design of magnetic tunnel junctions comprising Fe (n)Co(m)Fe(n)|MgO storage
layers [ nand mdenote the number of monolayers (ML)] with greatly enhanced perpendicular magnetic
anisotropy (PMA) up to several mJ/m
2, leveraging the interfacial perpendicular anisotropy of Fe |MgO
along with a strain-induced bulk PMA discovered within bcc Co. This giant enhancement dominates
the demagnetizing energy when increasing the film thickness. The tunneling magnetoresistance (TMR)
estimated from the Julliere model is comparable with that of the pure Fe |MgO case. We discuss the advan-
tages and pitfalls of a real-life fabrication of the structure and propose the Fe (3ML)Co(4ML)Fe(3ML)as
a storage layer for MgO-based STT MRAM cells. The large PMA in strained bcc Co is explained in the
framework of second-order perturbation theory by the MgO-imposed strain and consequent changes in theenergies of d
yzand dz2minority-spin bands.
DOI: 10.1103/PhysRevApplied.15.024017
I. INTRODUCTION
MgO-based magnetic tunnel junctions (MTJs) are used
in today’s hard-disk-drive read heads and a variety of
magnetic field sensors for their supremely high tun-
neling magnetoresistance (TMR) effect [ 1]. Hard-disk
drives, however, are approaching their scaling limits
[2]. Besides, spin-transfer torque magnetic random-access
memory (STT MRAM), also based on MTJs comprising
an MgO tunnel barrier, is entering into volume production
for eFLASH replacement and SRAM type of applications.
They are nonvolatile, fast (5–50 ns cycle time), can be
made relatively dense (Gbit), with low power consumption
(100 fJ/write event), and exhibit very good write endurance
[3–5].
The building block of STT MRAM is a cell with (1)
high TMR for good readability, (2) high spin-transfer
torque efficiency for good writability, and (3) high mag-
netic anisotropy for good thermal stability and therefore
memory retention [ 6,7]. All of these requirements must
be satisfied together, which is the case in perpendicu-
larly magnetized Co-Fe-B |MgO MTJs as long as the cell
diameter remains larger than approximately 30 nm [ 8].
*libor.vojacek@vutbr.cz
†mair.chshiev@cea.frBelow this diameter, the perpendicular anisotropy pro-
vided by the Co-Fe-B |MgO interface becomes too weak
in regards to thermal fluctuations so that the memory reten-
tion reduces excessively. In this work, we focus on improv-
ing the third requirement—the perpendicular magnetic
anisotropy (PMA)—of the MgO-based MTJ, therefore
allowing improved downsize scalability of out-of-plane
magnetized MRAM.
Although heavy metals like Pt or Pd can enhance PMA
[9,10], they do so by increasing the spin-orbit coupling
(SOC) parameter ξ. This is, however, associated with the
undesirable side effect of increasing the Gilbert damp-
ing [ 11], thus increasing the spin-transfer torque switch-
ing current [ 12,13]. To avoid this problem, recipes based
on purely 3 dmetallic elements were developed [ 14,15].
However, these recipes are based on Fe /Ni or Co /Ni alter-
nating atomic layers, yielding structures that are intrin-
sically complex to fabricate or may require excessively
high deposition or annealing temperature. They can also
get deteriorated upon the annealing necessary to obtain
good crystallization of the MgO barrier and surrounding
magnetic electrodes.
In this work, we propose a different approach based on
introducing a bulk Co interlayer into a simple Fe |MgO
MTJ. The latter exhibits comparable or stronger PMA than
the aforementioned Fe /Ni or Co /Ni alternating atomic
2331-7019/21/15(2)/024017(8) 024017-1 © 2021 American Physical SocietyLIBOR VOJÁ ˇCEK et al. PHYS. REV. APPLIED 15,024017 (2021)
layers. In addition, the PMA characterized by the mag-
netocrystalline anisotropy energy EMCA increases with the
film thickness at a comparable or higher rate. Lastly, the Co
Curie temperature (1404 K) is significantly higher than that
of Fe (1043 K) and twice higher than that of Ni (631 K),
which provides higher temperature stability [ 16].
The paper is organized as follows. In Sec. II, based
on DFT calculations, we propose a MTJ with enhanced
PMA and high TMR and discuss the aspects useful for a
real-life fabrication of the structure. In Sec. III, the sys-
tematic calculations supporting our proposal are presented.
In Sec. IV, the large bulk Co |MgO PMA, crucial to the
enhancement, is explained by the electronic structure and
the second-order perturbation theory.
II. MTJ WITH GREATLY ENHANCED PMA
The DFT calculations are performed using the Vienna
ab initio simulation package (VASP) [17,18]. Besides the
electronic structure, the primary output of the calcula-
tions is the magnetocrystalline anisotropy energy EMCA
and its atomic site-resolved contributions. Positive (neg-
ative) value of EMCA indicates PMA (in-plane anisotropy),
respectively. See the Supplemental Material [ 19] for calcu-
lation details [ 20–22].
A. PMA enhancement
In this study, we find that a significant contribution to
PMA originates from the bulk of epitaxial bcc Co on top
of MgO. Its origin is presented in detail in Secs. IIIandIV.
We exploit this finding and propose to enhance the PMA
of conventional Fe |MgO MTJ by replacing the bulk Fe
layers with Co. The effect can be further enhanced by sand-
wiching the magnetic layer between two MgO barriers.
The proposed improved MTJ storage layer thus takes the
form MgO |Fe(n)Co(m)Fe(n)|MgO with n≥2a n d m≥3,
as shown in Fig. 1(c). It is required to have at least two Fe
atoms at the MgO interface and three successive Co atoms
in the bulk to obtain the PMA enhancement (see Fig. S1
within the Supplemental Material [ 19] for details).
Structures with different nand mare systematically
investigated. The thickness of MgO in all the calcula-
tions is chosen to be 5 (6) monolayers for an odd (even)
number of metal layers, respectively. Figure 1(a) shows
the effective PMA, which is a sum of the magnetocrys-
talline anisotropy energy EMCAand dipole-dipole–induced
demagnetization energy EDDas a function of n,m. One can
see that the effective PMA does not vanish with increasing
thickness, but interestingly, it grows steadily. This con-
trasts with the pure Fe |MgO case (gray line), where the
demagnetizing energy EDDdrives the magnetization in
plane for thicknesses above 11 monolayers. The variation
ofEMCA and EDDas a function of mfor n=2 is shown in
Fig.1(b).
(a) (c)
(b)
FIG. 1. (a) Effective PMA ( EMCA+EDD)i n
MgO|Fe(n)Co(m)Fe(n)|MgO as a function of number of
monolayers n,m. There is no perpendicular to in-plane magnetic
anisotropy switching compared to pure MgO |Fe|MgO (gray
diamonds; its thickness is m+4 ML, the same as the overall
thickness for n=2). (b) EMCA,EDD, and the effective PMA
(EMCA+EDD)f o r n=2. The effective PMA increases with the
Co thickness. (c) Supercell of the MgO |Fe(2)Co(3)Fe(2)|MgO
with periodic boundary conditions applied in all directions.Produced by
VESTA [23].
The dipole-dipole energy EDDis obtained by summing
over all the dipole-dipole interactions [ 24,25] (see the
Supplemental Material [ 19] for calculation details). EDD
acts mainly as demagnetizing energy [ 24], favoring an
in-plane magnetization orientation. EDDis proportional
to the product of the magnetic moments of the inter-
acting atoms ( μ1·μ2). Thus, replacing the bulk Fe with
Co decreases its magnitude knowing that in the bulk of
the layer μFe≈2.5μBwhile μCo≈1.8μB, where μBis
the Bohr magneton. The effect of the bulk Co is there-
fore twofold: it increases the positive EMCA (discussed in
detail in Secs. IIIand IV) and diminishes the negative
demagnetizing dipole-dipole contribution.
Replacing the MgO on one side of the metal film with
vacuum, as tested on the n=4,m=6 structure, decreases
the EMCA by 16% (see the Supplemental Material [ 19]).
This is predominantly due to the drop in EMCA of the two
interfacial Fe atoms [ 26]. (The effect of replacing the MgO
by vacuum in pure bcc Fe (Co, Ni )|MgO can also be seen in
Fig. S3 within the Supplemental Material [ 19].) However,
at reduced thicknesses ( n=2,m=3), this drop is much
more dramatic, namely 36%, or even 86%, when both
interfaces are in contact with vacuum. This explains why
024017-2GIANT PMA ENHANCEMENT IN MgO-BASED MTJ. . . PHYS. REV. APPLIED 15,024017 (2021)
Hotta et al.[14] observed no enhancement of anisotropy
in Fe(2)Co(3)Fe(2)|MgO. They mimicked the presence of
MgO by setting the lattice parameter equal to that of bulk
MgO while, in reality, having vacuum at the interfaces.
Note that changing the MgO thickness from 3 ML to
7 ML has a negligible effect on the EMCA in the order of
0.01 mJ/m2, as tested on the Fe (2)Co(3)Fe(2).
B. Tunneling magnetoresistance
Since we are interested in implementing this proposed
storage layer in a full MTJ stack, we investigate its
expected TMR amplitude. A large TMR of 410% at room
temperature has been observed previously in pure bcc
Co|MgO|Co MTJs [ 27]. In addition, Co in combination
with Fe is often used for its record-holding TMR values.
Therefore, we expect the high TMR to be present also
in the proposed Fe |MgO MTJs with the inserted Co bulk
layer. We estimate the TMR of the structures from the
Julliere formula [ 28] with the spin polarization calculated
from the local density of states with /Delta11symmetry of the
interfacial oxygen at the Fermi level. The values are very
high, around 300%. Note that the PMA does not originate
solely from the interface in the proposed structure, but also
from the bulk, in contrast to pure Fe |MgO [ 26]. This sug-
gests that we might be able to separately tune the PMA (by
the bulk Co) and the TMR (by the Fe |MgO interface).
As mentioned in the introduction, the proposed MTJ
is conceptually much simpler and more robust against
annealing than the alternating layer-based MTJ [ 14,15]
with similar properties. However, there are two main issues
that we address regarding the fabrication of our structure,
namely the stability of the bcc Co phase and the robustness
against the Fe-Co interface not being atomically sharp.
C. Fabrication of the metastable bcc Co
Although the natural form of Co is hcp, the metastable
bcc Co phase can be grown at room temperature [ 29–31].
It has been successfully grown on top of Fe with thick-
ness up to 15 ML [ 32], with well-defined interfaces and no
visible interdiffusion. The observed strain of 10% in bcc
Co|MgO is considerable but still within the limit of what
is experimentally realizable [ 33]. Indeed, Yuasa et al.[27]
fabricated bcc Co (4ML)|MgO(10ML )|Co(4ML)MTJ and
measured a record-holding TMR of 410% at room temper-
ature. From our structural relaxation simulations, it follows
that the bcc Co is preserved on top of MgO while it trans-
forms into the fcc phase when surrounded by vacuum.Therefore, the bcc phase will probably be most stable if
the device is used as a double-barrier MTJ. This also pro-
vides higher PMA from the interfacial Fe, compared to
single-barrier MTJ.
FIG. 2. The effect of interdiffusion on the effective PMA in two
selected structures. For the (minimal) Fe (2)Co(3)Fe(2)struc-
ture, there is a significant PMA decrease of 73% at 0.5-ML
atomic intermixing. For the thicker Fe (3)Co(4)Fe(3),t h eP M A
is reduced only by 22%, demonstrating the robustness against
interfacial roughness. We expect this robustness in the thicker
structures in general.
D. Decrease of PMA with interfacial roughness
The sharpness of the Fe-Co interface is another rele-
vant factor to consider. From the simulations it follows
that any interdiffusion is fatal for the PMA when the
Fe or Co thickness is less than 2 ML or 3 ML, respec-
tively ( n<2o r m<3; see Fig. S1 within the Supplemental
Material [ 19]). Robustness can be achieved at larger Fe
and Co thicknesses. In Fig. 2, one may see the effec-
tive PMA in the Fe (2)Co(3)Fe(2)and Fe (3)Co(4)Fe(3)
structures with 0.5-ML (50%) interdiffusion and when the
interface layers are swapped (1-ML interdiffusion). The
drop in the effective PMA of Fe (3)Co(4)Fe(3)is only
22% at 0.5-ML interdiffusion, compared to a drop of
73% for Fe (2)Co(3)Fe(2). This robustness against surface
roughness is to be expected in the thicker structures in
general.
Larger Co thickness is favorable as it increases the PMA
(Fig. 1), but on the other hand, thicker bcc Co will probably
be harder to fabricate [ 27]. Larger Fe thickness provides
robustness against interdiffusion and might stabilize the
bcc Co, as it is generally easier to grow bcc Co on Fe
than on MgO (Co does not wet well on oxides due to its
high surface tension while Fe does [ 34,35]). On the other
hand, the PMA is decreased with thicker Fe, as shown in
Fig. 1(a) (for layer-resolved behavior, see Fig. S4 within
the Supplemental Material [ 19]).
Looking at Fig. 1(a) and considering all the mentioned
aspects, the MgO |Fe(3ML)Co(4ML)Fe(3ML)|MgO seems
like a promising candidate as a storage layer for
STT MRAM cells with highly improved thermal stability
024017-3LIBOR VOJÁ ˇCEK et al. PHYS. REV. APPLIED 15,024017 (2021)
(a) (b) (c)
FIG. 3. (a) Thickness dependence of EMCA in bcc Fe (Co, Ni )|MgO. Surprisingly, the PMA in Co increases steadily. (b) Layer-
resolved EMCA in the structure with 15 ML of metal. Layer 1 is the interfacial layer. The layer number increases towards the bulk of
the material. The largest contribution for Fe comes from the interface; for Co, it comes from the bulk. (c) EMCA in purely bulk bcc Fe,
Co, and Ni as a function of c/aratio. Dashed lines indicate the typical value of c/ain the bulk of the given metal |MgO (see text for
details). At its typical strain, the EMCA for Co is the same as in the bulk layers in Fig. 3(b).
compared to conventional STT MRAM. Indeed, when the
storage layer is sandwiched between two MgO layers, the
anisotropy per unit area is of the order of 2 mJ/m2from the
interfacial contribution minus approximately 1.2 mJ/m2
from demagnetizing energy (dependent on the chosen stor-age layer thickness) yielding a net effective PMA per
unit area approximately 0.8 mJ/m
2[4]. In comparison,
the net anisotropy per unit area in the proposed structure
is approximately 2.2 mJ/m2being almost 3 times larger.
This means that for the same thermal stability factor, the
cell area could be reduced by a factor of 3 compared to
conventional MRAM [ 7,36].
III. PMA IN BCC Fe(Co, Ni) |MgO THIN FILMS
The idea of the improved MTJ proposed above is driven
by our systematic investigation of the thickness depen-
dence of EMCA in pure bcc (001) Fe, Co, and Ni |MgO
ultrathin films. The EMCA as a function of metallic layer
thickness is presented in Fig. 3(a). While for Fe the EMCA
converges to a constant value [ 26], we observe a steady
increase for Co. The behavior for Ni is more subtle. To elu-
cidate why the trend varies among the three metals, in Fig.
3(b), we show the layer-resolved contributions to the EMCA
(the contributions from each atomic layer separately).
For Fe, the main contribution to EMCA comes from the
first two interfacial layers [ 26,37]. Increasing the thickness
does not affect the electronic properties of the interfacial
layers in a significant way [ 26] (see also Fig. S5 within the
Supplemental Material [ 19]). The bulk layers almost do not
contribute to the PMA. Hence the EMCA does not change.In contrast, all the bulk layers of Co seem to contribute
with a significant positive EMCA value, as evident from
Fig. 3(b). Hence, the EMCA grows almost linearly with
the number of added bulk Co layers [see Fig. 3(a)]. This
observation is the cornerstone of this paper.
For Ni, the influence of the interface manifests itself
as deep as 6 ML, with the two interfacial monolayers
contributing a negative EMCA. This is the reason for the
in-plane anisotropy in the 5-ML structure, as shown in
Fig.3(a). Although the deeper bulk layers contribute posi-
tively, the EMCA does not grow monotonically as expected
because the interfacial contributions in Ni do change upon
thickness increase (see Fig. S5 in the Supplemental Mate-
rial [ 19]). The bcc Ni |MgO is problematic also because of
the large strain of approximately 15%.
The large positive bulk EMCA in Co|MgO is caused by
the strain that is induced within the Co by the MgO. To
confirm this hypothesis, we have calculated EMCA as a
function of the c/aratio in the primitive bcc unit cell for
each of the metals shown in Fig. 3(c).T h e aand blat-
tice parameters were set to the value of the relaxed bulk
bcc Fe, Co, or Ni unit cell, while the clattice parameter
was varied. The typical relaxed c/aratios we found within
the bulk metal layers in Fe, Co, and Ni interfaced with
MgO are 0.94, 0.89, and 0.85, respectively [dashed lines
in Fig. 3(c)].
It clearly follows from Fig. 3(c) that for Fe and Ni,
this bulk strain-induced EMCA is very small at their typ-
ical bulk strains (dashed lines). However, we observe
a large positive contribution of ≈0.5 mJ/m2for Co,
which is the same value expected from Fig. 3(b). Indeed,
artificially setting c/a= 1 in a previously relaxed Co|MgO
024017-4GIANT PMA ENHANCEMENT IN MgO-BASED MTJ. . . PHYS. REV. APPLIED 15,024017 (2021)
(a) (b) (c)
(d) (e) (f)
FIG. 4. (a) Based on the orbital-resolved local density of states, the four contributions to the bcc Co EMCA(c/a) calculated from the
second-order perturbation theory [ 41] are shown separately and in total. The values extracted from the DFT calculation with spin-orbit
coupling included [“DFT”; see Fig. 3(c)] are shown for comparison. The classical Bruno term /Delta1E↓⇒↓ on its own reproduces the DFT
curve for c/a<1 to a certain extent. (b) The Bruno /Delta1E↓⇒↓ term from Fig. 4(a) divided into contributions from individual virtual
excitations. The excitation from dyztodz2states and vice versa ( dyz↔ dz2; red circles) is the one that causes the overall increase for
c/a<1 .( c )S a m ea sF i g . 4(a)but calculated from the orbital-projected band structure, where additional aspects are taken into account
(see text for details). The correspondence with the DFT curve is hence much better. (d) The orbital-resolved DOS for bcc Co with
c/a=1. There is a peak in the dz2and dx2−y2minority states right above the Fermi level. (e) The orbital-resolved DOS for bcc Co
with c/a=0.90. The strain causes the overall spreading of the DOS. Both the dz2and the dx2−y2peaks are pushed further above EF.
(f) The most bulklike Co from the Fe (3)Co(12)Fe(3)structure. Its features are very similar to the bcc Co with c/a=0.90 in Fig. 4(e),
supporting the applicability of the results of Sec. IVto the proposed structures of Sec. II.
eliminates the bulk contribution to EMCA, thus confirming
that strain plays the central role. We note that the calcu-
lated EMCA (c/a) dependence in Fig. 3(c)corresponds well
to previous findings [ 38,39], where the focus was limited
toc/a>1 .
IV . PERTURBATIVE TREATMENT OF
STRAIN-INDUCED ANISOTROPY IN BCC
COBALT
The magnetocrystalline anisotropy is due to the spin-
orbit coupling [ 40]. The magnitude of spin-orbit coupling
constant is several 10 meV, which is much less than thewidth of 3 dbands. Therefore, the E
MCA can be calculated
within the second-order perturbation theory framework
directly from the orbital-resolved (A) density of states or
(B) band structure. Both of these are obtained from a DFTcalculation with the spin-orbit coupling not included. This
treatment allows us to link changes in EMCA directly to
changes in the electronic structure.
A. Density of states
The magnetic anisotropy energy can be calculated from
the local density of states (LDOS) at a particular atom
as [41]
EMCA=/Delta1E↓⇒↓+/Delta1E↑⇒↑−/Delta1E↑⇒↓−/Delta1E↓⇒↑,( 1 )
where [ 42]
/Delta1Eσ⇒σ/prime=ξ2
4/summationdisplay
μμ/primePμμ/prime/integraldisplayEF
−∞dε/integraldisplay∞
EFdε/primeρσ
μ(ε)ρσ/prime
μ/prime(ε/prime)
ε/prime−ε.
(2)
024017-5LIBOR VOJÁ ˇCEK et al. PHYS. REV. APPLIED 15,024017 (2021)
Hereξis the spin-orbit coupling constant, μ( μ/prime)is an
occupied (unoccupied) orbital with spin σ( σ/prime)and density
of states ρσ
μ(ρσ/prime
μ/prime)at energy ε( ε/prime). The constant Pμμ/prime=
|/angbracketleftμ|Lz|μ/prime/angbracketright|2−| /angbracketleftμ|Lx|μ/prime/angbracketright|2, where Lz(Lx)is the orbital
momentum operator in the out-of-plane (in-plane) direc-
tion, respectively. The Pμμ/primematrix for dorbitals is given
in the Supplemental Material [ 19]. We use ξCo=84 meV
[43].
The physical picture encompassed in Eqs. (1)and(2)
is that virtual excitations of electrons from occupied to
unoccupied orbitals give rise to positive, negative, or zero
contribution to EMCA. The sign depends on the Pμμ/primecon-
stant, and hence on the two interacting orbitals μandμ/prime.
The closer the two orbitals are to each other, and hence to
the Fermi level EF, and the larger their density of states
ρ, the larger this contribution. The excitations are divided
into four terms [Eq. (2)] based on the orbitals’ spins. The
two “spin-conservation terms” have a plus sign, while the
two “spin-flip terms” have a minus sign.
In Fig. 4(a), we aim to reproduce the DFT-calculated
results from Fig. 3(c) using the model from Eqs. (1)
and (2). We show the four terms from Eq. (1), their
sum (“ EMCA”), and the Co DFT curve from Fig. 3(c) for
comparison (“DFT”). The EMCA curve does not reproduce
the DFT curve well, so the model from Eq. (2)must be
an oversimplification. Despite this, we can use it to draw
several qualitative conclusions.
(1) The minority-to-minority excitation term /Delta1E↓⇒↓
(the only term that is taken into account in the origi-
nal Bruno approach [ 40]) on its own can reproduce the
increase of EMCA for c/a<1 observed in the DFT curve.
To link this increase directly to changes in the LDOS in
Fig. 4(d), in Fig. 4(b), we show all the excitations con-
tributing to /Delta1E↓⇒↓ separately. We see that the increase
is caused by excitations from dyztodz2minority orbitals
and vice versa ( dyz↔ dz2). This is linked to the strain-
induced changes in the LDOS: for c/a<1 [Fig. 4(e)],
the dz2peak in the unoccupied minority states is shifted
further above the Fermi level, diminishing the negative
dyz→ dz2contribution. This increases the overall EMCA.
The increase is counteracted by a decrease in the posi-
tive dxy↔ dx2−y2excitation contribution. This decrease is
due to the strain-induced shift of the minority unoccupied
dx2−y2peak, located immediately above EFfor c/a=1.
(2) The two contributions that come from excitations
to majority-spin states, /Delta1E↑⇒↑ and−/Delta1E↓⇒↑, are small.
The reason is that there are almost no unoccupied majority-
spin states, especially near the Fermi level, as we see in
Figs. 4(d)–4(f). Moreover, these two contributions tend to
cancel each other. Hence they can often be neglected [ 42].
Note that including the porbitals gives only a minor
correction of approximately 1%.B. Band structure
Next, we calculate the EMCA(c/a) directly from the
(orbital-resolved) band structure [Eqs. (4)–(6) in [ 41]].
This approach intrinsically includes many aspects that are
neglected in the calculation from LDOS in Sec. IV A ,
namely that (1) the projection coefficient of a Bloch state
onto a particular dorbital is a complex number, (2) virtual
excitations also happen in between atoms at different sites,
not only on site, and that (3) a virtual excitation generally
includes four orbitals, not only two (see Fig. 1 in Ref. [ 44]).
All of these have proven to be essential for the model to be
more accurate.
The whole calculation is nicely described by Miura et
al.[41]. In short, setting LORBIT =12 in the VASP calcula-
tion provides the real and imaginary parts of the projection
coefficients c, which we use to calculate the joint local den-
sity of states G(see Ref. [ 41]). Taking its real part and
performing summation over several variables, one may
obtain the four contributions to EMCA from Eq. (1).W e
useξCo=84 meV [ 43].
The calculation results are plotted in Fig. 4(c).T h e
model is much better than the one in Fig. 4(a), while
the main features are retained, namely that the /Delta1E↓⇒↓
term governs the overall trend. The −/Delta1E↑⇒↓ term serves
to refine the shape, but in addition, causes an excessive
overall decrease. The EMCA(c/a=1) is not zero in the
EMCA curve, as it should be by symmetry arguments and
as it is in the DFT curve. Despite that, the difference
EMCA(c/a=0.90)- EMCA(c/a=1) in the EMCA and DFT
curves correspond well to each other.
Analyzing the contributions to /Delta1E↓⇒↓ from individual
excitations, we confirm the results of Sec. IV A , namely
that the main positive change in EMCA for c/a<1 is due
to the dyz→ dz2virtual excitation, and the main negative
change is due to the dx2−y2→ dxyexcitation.
V . CONCLUSIONS
We propose an alternative concept of MTJ with strongly
enhanced perpendicular magnetic anisotropy based on
introducing a Co interlayer into the bulk of conven-
tional Fe |MgO MTJ. DFT calculations confirm that the
PMA enhancement overcomes the negative demagnetiz-
ing energy in these Fe (n)Co(m)Fe(n)|MgO structures. The
TMR shows values similar to the pure Fe |MgO case.
There is a trade-off between the enhancement magnitude
and its robustness against the Fe-Co interfacial diffu-
sion in a prospective real-life fabrication process. The
Fe(3ML)Co(4ML)Fe(3ML)seems of strong potential as
a storage layer for MgO-based STT MRAM cells. The
design is based on the presented systematic study of PMAin bcc Fe (Co, Ni )|MgO, showing clearly that the MgO-
imposed compressive strain induces a significant bulk
PMA in bcc Co. We explain the PMA enhancement in bcc
Co via the second-order perturbation theory approach and
024017-6GIANT PMA ENHANCEMENT IN MgO-BASED MTJ. . . PHYS. REV. APPLIED 15,024017 (2021)
attribute it mainly to the strain-induced changes in ener-
gies of the minority-spin filled dyzand unfilled dz2orbitals
around the Fermi level.
ACKNOWLEDGMENTS
Computational resources are partially supplied by the
project “e-Infrastruktura CZ” (e-INFRA LM2018140) pro-
vided within the program “Projects of Large Research,
Development and Innovations Infrastructures”. B.D.
acknowledges ERC funding via ERC Adv grant No. MAG-
ICAL 669204. Co-funded by the Erasmus +Programme of
the European Union.
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024017-8 |
PhysRevLett.121.097204.pdf | Theory of the Topological Spin Hall Effect in Antiferromagnetic Skyrmions:
Impact on Current-Induced Motion
C. A. Akosa,1,2,*O. A. Tretiakov,3G. Tatara,1,4and A. Manchon2
1RIKEN Center for Emergent Matter Science (CEMS), 2-1 Hirosawa, Wako, Saitama 351-0198, Japan
2King Abdullah University of Science and Technology (KAUST), Physical Science and Engineering (PSE) Division,
Thuwal 23955-6900, Saudi Arabia
3Institute for Materials Research, Tohoku University, Sendai 980-8577, Japan
4RIKEN Cluster for Pioneering Research (CPR), 2-1 Hirosawa, Wako, Saitama, 351-0198 Japan
(Received 5 September 2017; revised manuscript received 11 May 2018; published 30 August 2018)
We demonstrate that the nontrivial magnetic texture of antiferromagnetic Skyrmions (AFM Sks)
promotes a nonvanishing topological spin Hall effect (TSHE) on the flowing electrons. This effect results ina substantial enhancement of the nonadiabatic torque and, hence, improves the Skyrmion mobility. This
nonadiabatic torque increases when decreasing the Skyrmion size, and, therefore, scaling down results in a
much higher torque efficiency. In clean AFM Sks, we find a significant boost of the TSHE close to the vanHove singularity. Interestingly, this effect is enhanced away from the band gap in the presence of
nonmagnetic interstitial defects. Furthermore, unlike their ferromagnetic counterpart, the TSHE in AFM
Sks increases with an increase in the disorder strength, thus opening promising avenues for materialsengineering of this effect.
DOI: 10.1103/PhysRevLett.121.097204
Introduction. —As the spintronics community advances
the search for high-efficiency, high-density, and low-power-
consuming spintronic devices, alternative materials otherthan conventional ferromagnets (FMs) are being continu-
ously introduced and explored. Besides FMs, antiferromag-
nets (AFMs) have recently drawn significant attention [1,2].
The experimental observation of bulk spin-orbit torques(SOTs) in locally inversion asymmetric CuMnAs [3],t h e
demonstration of AFM-assisted zero-field SOT switching
[4,5], and the achievement of large anomalous and spin Hall
effects in noncollinear AFMs [6–8]open promising per-
spectives for the implementation of AFMs into efficient spindevices. The latter effect is particularly intriguing, since itemerges from the coexistence of spin-orbit coupling (SOC)-
driven Berry curvature and noncollinear magnetism. In
addition, it has also been predicted that AFM textures suchas domain walls driven by SOTs can move much faster thantheir FM counterparts due to the absence of Walker break-
down [9,10] . Therefore, the interplay between topological
spin transport and the dynamics of AFM textures is apromising route to explore towards the realization of efficientcurrent-driven control of the AFM order parameter.
Recently, ferromagnetic Skyrmions (FM Sks) have been
proposed as good candidates for technological applicationsdue to their weak sensitivity to defects [11–13], ultralow
critical current density [13–19], enhanced nonadiabatic
torque [20,21] , and substantial TSHE [22,23] . In spite of
these remarkable properties, FM Sks suffer from the so-
called Skyrmion Hall effect [19,24,25] , a motion transverse
to the current flow. This parasitic effect hinders the robustelectrical manipulation of FM Sks. In contrast, both
the analytical theory and micromagnetic simulations
recently showed that, in AFM Sks, the Skyrmion Halleffect vanishes by symmetry [26–30].
In this Letter, we demonstrate that the nontrivial magnetic
texture of AFM Sks promotes a nonvanishing TSHE on the
flowing electrons. This effect results in a substantial enhance-
ment of the nonadiabatic torque and, hence, improves theSkyrmion mobility. This nonadiabatic torque increases as the
Skyrmion size decreases, and, as a result, scaling down results
in a much higher torque efficiency. In clean systems, we find asignificant enhancement of the TSHE close to the van Hove
singularity. Most importantly, unlike FM Sks [23],t h eT S H E
in AFM Sks increases in the presence of nonmagneticinterstitial defects. Moreover, the TSHE is enhanced awayfrom the band gap in the presence of these defects.
Phenomenological model. —Motivated by the prediction
of a metastable single AFM Sk on a square lattice [29–32],
our analysis begins with an isolated G-type (i.e., checker-
board) AFM Sk with equivalent sublattices aandb. The
conduction electrons are coupled to the N´ eel order nðr;tÞ
via an exchange energy J. For a smooth and slowly varying
N´eel order parameter, the emergent electromagnetic fields
of the ηsublattice acting on electrons with spin σare
derived as [33,38 –
40]
Eη;σ
em¼ðσℏ=2eÞPη
σNt;iðrÞei; ð1aÞ
Bη;σ
em¼−ðσℏ=2eÞPη
σNx;yðrÞz; ð1bÞPHYSICAL REVIEW LETTERS 121, 097204 (2018)
0031-9007 =18=121(9) =097204(5) 097204-1 © 2018 American Physical Societywhere Nμ;νðrÞ¼ð∂μn×∂νnÞ·n, with μ;ν∈ðt; x; y Þ,
σ¼þ ð−Þ1for↑ð↓Þspin, Pη
σ¼ð1þσηPkÞ=2, where
Pk¼J=εkis the polarization of the density of state per
sublattice, and εkis the energy dispersion [40,41] . Notice
thatPktakes a value of 1 close to the van Hove singularity
or as the exchange Jgoes to infinity. In these limits, the two
sublattices behave like two independent parallel ferromag-
nets ( Pa
↑¼1,Pa
↓¼0) and ( Pb
↑¼0,Pb
↓¼1). Therefore,
unlike FM Sks, in which electrons feel an emergent
electromagnetic field of opposite sign for different spins,
in real AFM Sks (finite J), the magnitude of this field is
both spin- and sublattice-dependent and strongly dependson the dispersion [42].
Our analysis is based on an AFM Sk with radius r
0,
embedded in a large system of radius R≫r0moving rigidly
with velocity v[i.e.,∂tn¼−ðv·∇Þn]. We chosewithout the
loss of generality the profile given as n¼ðcosΦsinθ;
sinΦsinθ;cosθÞ, where cos θ¼pðr2
0−r2Þ=ðr2
0þr2Þ
andΦ¼qArgðxþiyÞþcπ=2define the polar and azimu-
thal angles, respectively. The constants p,q,a n d c, which
take values of /C61, define the polarization, vorticity, and
chirality, respectively [33]. Under the action of an external
electric field along the xaxis (i.e., E¼Ex), the local charge
and spin current densities per sublattice read [33]
jη
e¼ð1=2Þ½σ0xþησxyðrÞy/C138E
þηðℏ=4Þ¯P0σ0Nx;yðrÞðv×zÞ; ð2aÞ
jη
s¼n⊗ð1=2Þ½ηx−pqβTðrÞy/C138bJ
þðpq=2ÞαTðrÞn⊗ðv×zÞ; ð2bÞ
where σ0ðHÞ=2is the longitudinal (ordinary Hall) conduc-
tivity of sublattice ηand σxyðrÞ¼ðℏ=2eÞ¯PHσHNx;yðrÞ
is the nonlocal steady state transverse conductivity.
bJ¼γℏP0σ0E=2eMsquantifies the adiabatic torque,
while αTðrÞ¼pqλ2
ENx;yðrÞand βTðrÞ¼pqλ2
HNx;yðrÞ
are dimensionless nonlocal contributions to the Gilbert
damping and nonadiabatic torque, respectively. Here Ms
is the saturation magnetization, and the constants
λ2
H¼ℏ˜PHσH=ð2eP0σ0Þand λ2
E¼γℏ2˜P0σ0=ð4e2MsÞare
length scales associated with the emergent magnetic
and electric fields, respectively [21]. In the above
expressions, P0ðHÞ≡Pa
0ðHÞ¼−Pb
0ðHÞis the longitudinal
(ordinary Hall) current polarization, where Pη
0ðHÞ¼
ðση;↑
0ðHÞ−ση;↓
0ðHÞÞ=ðση;↑
0ðHÞþση;↓
0ðHÞÞ.F i n a l l y ,w ea l s on e e dt o
define the effective polarizations ¯P0;H¼ðP0ðHÞþPkÞ=2
and ˜P0ðHÞ¼ð1þP0ðHÞPkÞ=2[33].
Interesting physics of charge and spin transport in AFM
Sks can be inferred from Eq. (2). Indeed, since ηchanges
sign on different sublattices, there is (i) no macroscopictransverse (along y) charge current, i.e., no topological Hall
effect (THE) [29,30] , (ii) no macroscopic longitudinal(along x)spin current, and (iii) a nonzero transverse spin
current, i.e., a finite TSHE [26,42] . The physical origin of
the TSHE as illustrated in Fig. 1stems from the interplay
between the emergent magnetic field, Eq. (1b), and the
dispersion of the underlying system. The emergent mag-netic field deflects flowing electrons with opposite spins to
opposite directions, and the inherent twofold degeneracy
ensures that a continuous transverse pure spin current flows
in the system.
To elucidate the effect of this transverse spin current on
the mobility of Skyrmions, the impact of the topologicalspin current derived in Eq. (2b)on the dynamics of an AFM
Sk is investigated. To achieve this, we calculate thecorresponding total spin torque as τ
T¼−∇·js, where
js¼jasþjbsand, for the sake of completeness, we include
nonadiabatic effects [43] via a constant nonadiabaticity β
and the Gilbert damping torque with damping constant α
such that the total spin torque is given as τ¼αn×∂tn−
βbJn×∂xn−τTto obtain
τ¼αn×∂tn−βbJn×∂xn
þαTðrÞn×∂tn−βTðrÞbJn×∂xn: ð3Þ
It appears clear from Eq. (3)that, just as in FM Sks [20,21] ,
the transverse spin current flowing in AFM Sks directlyenhances the nonadiabatic torque and the damping.Moreover, this nonadiabatic topological torque increaseswhen decreasing the Skyrmion size. As a result, theefficiency of the current-driven motion increases whenthe Skyrmion becomes smaller.
We follow the standard theoretical scheme employed to
study the dynamics of antiferromagnetic textures [44–49]
supplemented by the derived topological torque to obtainthe equation of motion of the N´ eel order parameter as [33]
1
¯a˜γ∂2tnþαeffðrÞ∂tn¼γfnþβeffðrÞbJ∂xn; ð4Þ
where ˜γ¼γ=ð1þα2Þ,αeffðrÞ¼αþαTðrÞ,βeffðrÞ¼
βþβTðrÞ, and fnis the effective field derived from the
FIG. 1. Schematic illustration of the physical origin of the TSHE
in an AFM Sk. (a) For J≫tand close to the van Hove singularity,
two bands are essentially decoupled ( Pη
k¼η), and the emergent
magnetic field (EMF) results to a substantial TSHE. (b) For J∼t
(away from the van Hove singularity), a strong transition betweendegenerate bands results to a substantial reduction of the TSHE.PHYSICAL REVIEW LETTERS 121, 097204 (2018)
097204-2magnetic energy E¼Rdr½ð¯a=2Þm2þA
2ð∇nÞ2/C138asfn¼
−δnE, where ¯aandAare the homogeneous and inhomo-
geneous exchange constants, respectively [46]. The termi-
nal velocity calculated from Eq. (4)is given as
vy¼0and vx¼ðβeff=αeffÞbJ; ð5Þ
where the effective parameters are given as [33]
αeff¼αþ4
3λ2
E
r2
0and βeff¼βþ4
3λ2
H
r2
0: ð6Þ
To provide a qualitative estimate of our predicted effect,
using realistic material parameters Ms¼800KA=m,
α¼0.01,β¼0.02,P0¼0.7,Pk¼0.4,σ0¼14.75=ðμΩmÞ,
σH=σ0¼0.045=T, and je¼5×1011A=m2, we obtain λ2
E¼
0.225nm2andλ2
H¼13.54nm2. These values translate to a
longitudinal velocity of up to 391m=s for a Skyrmion size
of 10 nm, showing that, for small Skyrmions sizes, thetopological torque produces a sizable effect.
Before we proceed, we note that, even though the
topological torque discussed above does not rely onSOC, the latter is expected to be ubiquitous in systemspromoting noncollinear magnetic textures such as AFMSks [38–40]. Indeed, SOC has several effects on spin
transport, depending on its symmetry. In bulk materials, it
contributes to spin relaxation, which results in nonadiabatictorque that gives rise to a Skyrmion mobility that isindependent of r
0[43]. In magnets lacking inversion
symmetry, such as in magnetic multilayers, interfacial(Rashba-like) SOC produces (mostly) a fieldlike torque,while the spin Hall effect arising from an adjacent heavymetal induces a dampinglike torque. The former does notcontribute to AFM Sks mobility, while Velkov et al. [28]
showed that the latter induces a mobility that is proportionaltor
0. Finally, one also needs to consider the spin Hall effect
inside the AFM itself. In the case of ferromagnetic vortices,Manchon and Lee [50]showed that the spin Hall effect acts
in the same way as the nonadiabatic torque, thus inducinga mobility that does not depend on the vortex radius.Therefore, we expect the Skyrmion mobility to be domi-nated by the topological torque discussed above in the limitof small Skyrmions.
Tight-binding model. —Our theoretical predictions in
Eqs. (2)and(6)are verified by means of a tight-binding
model of an isolated AFM Sk on a square lattice describedby the Hamiltonian
H¼X
iϵiˆc†
iˆci−tX
hijiˆc†
iˆcj−JX
iˆc†
imi·ˆσˆci;ð7Þ
where Jis the exchange energy that couples the spin of
electrons ˆσto the local magnetization mi,tis the nearest-
neighbor hopping, and ϵiand ˆc†
i(ˆci) are the on-site energy
and the spinor creation (annihilation) operator of site i,respectively. We consider an AFM Sk of radius 12a0to
ensure that the texture is smooth and slowly varying [21],
for both the strong ( J¼5t) and the intermediate ( J¼2t=3)
exchange limits [22]using the KWANT code [51]. The Hall
transport is investigated via a four-terminal system [23]
with a scattering region of size 102×102a2
0(i.e., 51×51
AFM unit cells) and compared with an equivalent FM Sk.
In a clean system, we find a substantial TSHE in AFM
Sks in both the strong exchange limit and close to thevan Hove singularity [blue line in Figs. 2(a)and2(b)]. In
the intermediate exchange limit, however, the transition
between degenerate bands is strong [40]; this results in an
overall reduction of the TSHE. Furthermore, since theTSHE increases with the Skyrmion density [23], a sub-
stantial spin current capable of inducing magnetizationdynamics and/or switching on an adjacent attached FM
layer can be expected. Moreover, unlike FM Sks, AFM Sks
exhibit no THE due to the cancellation of the charge currentcontributions from both sublattices [29] [green line in
Figs. 2(a) and2(b)]. Our numerical results are consistent
with our analytical predictions in Eq. (2).
To model real materials, we investigated the impact of
nonmagnetic impurities which are omnipresent in experi-
ments. This is done via randomized on-site energies
ϵ
i¼Vi∈½−ðW=2Þ;ðW=2Þ/C138, where Wdefines the strength
of the disorder, and average over 104configurations to
ensure convergence. Two classes of defects are considered:
(i)interstitial defects, which preserve the coherence
between the sublattices within the antiferromagnetic unitcell, referred to as symmetric scattering (SS), and (ii) dis-order that induces decoherence within the unit cell, referred
to as asymmetric scattering (AS) [33]. We find that, in both
the strong and intermediate exchange limits, as shown inFigs. 3(a)and3(b), respectively, the presence of disorder-4 -2 0 2 4
Transport energy (t)-0.10 0.1
Hall angles
FMTH
FMTSH AFM TH AFM TSH-6 -3 0 3 6
Transport energy (t)0 0.1 Hall angles
-1.1 -0.8
Transport energy (t)0 0.040.08
Hall angles
-5.6 -5.2
Transport energy (t)0 0.020.04Hall angles(b) (a)
(c) (d)3/t2 = J t5 = J
J = 5t J = 2t/3
FIG. 2. Computed THE and TSHE for a FM Sk and AFM Sk as
a function of the Fermi energy in the (a) strong and (b) inter-mediate exchange limits. Insets (c) and (d) represent an enlarge-ment around the purple region in (a) and (b), respectively.PHYSICAL REVIEW LETTERS 121, 097204 (2018)
097204-3progressively quenches the TSHE for the FM Sk (black
curve); in contrast, in the case of the AFM Sk, only ASquenches the TSHE (red curve). In fact, SS disorder
enhances the TSHE (blue curve) as long as the coherence
between the two sublattices is preserved (region I) [33,40] .
A further increase in the disorder strength eventually leads
to the onset of decoherence (region II), resulting in the
reduction of the TSHE.
Finally, we numerically verify the scaling law of the
topological torques with respect of the Skyrmion size given
by Eq. (3). To achieve this, we follow the scheme outlined in
Ref.[21], consider a large system size of 302×302a
2
0, and
calculate the local spin transfer torque from the nonequili-
brium spin density induced by a voltage bias of 0.2t.T h e
calculated torque is then projected on ∂xn(adiabatic) or
n×∂xn(nonadiabatic), integrated over space, and normal-
ized accordingly to obtain the scaling law with respect to the
Skyrmion size. From this, we computed the nonadiabatic
torque as βeffbJ¼½Rτ·ðn×∂xnÞd2r/C138=RNx;yðrÞd2r[33].
Our numerical calculations as depicted in Figs. 4(a)and4(b)
show good correspondence with our analytical predictions inEq.(6)in both the strong and intermediate exchange limits.Conclusion. —Micromagnetic simulations originally
predicted that Skyrmions have, in principle, limitedsensitivity to local and edge defects owing to very
weak interactions [11,12] and their finite spatial extension
[15,17,52] . Indeed, the ability of a defect to pin a Skyrmion
increases when the size of the Skyrmion becomes compa-rable to the size of the defect [11]. Hence, scaling down
the Skyrmion towards sub-100-nm size results in low
Skyrmion mobility and large critical depinning currentsin polycrystalline systems [53]. What makes AFM Sks
remarkable in this respect is the fact that the torque
efficiency itself increases when reducing the Skyrmion
size, as discussed above. While this topological torquecontributes only to the transverse motion of FM Sks, it
drives the longitudinal motion of AFM Sks and, therefore,
directly competes with the enhanced pinning potential.This unique property could be a substantial advantage to
compensate the increasing pinning upon size reduction.
Furthermore, our calculations show that the TSHE isenhanced in the presence of moderate disorder that is
omnipresent in real materials, demonstrating the robustness
of the proposed approach for device applications.
This work was supported by Grant-in-Aid for Scientific
Research(B) No. 17H02929, from the Japan Society for the
Promotion of Science and Grant-in-Aid for Scientific
Research on Innovative Areas No. 26103006 from theMinistry of Education, Culture, Sports, Science andTechnology (MEXT) of Japan. O. A. T. acknowledges
support by the Grants-in-Aid for Scientific Research
(No. 25247056, No. 17K05511, and No. 17H05173) fromthe MEXT of Japan, MaHoJeRo (DAAD Spintronics
network, Project No. 57334897), and by JSPS and
RFBR under the Japan-Russia Research CooperativeProgram. A. M. acknowledges support from the King
Abdullah University of Science and Technology (KAUST).
C. A. A. thanks R. Cheng for useful discussions.
*collins.akosa@riken.jp
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10 15 20
Skyrmion radius (a0)00.511.52Normalized torqueAdiabatic torque
Nonadiabatic torque
10 15 20
Skyrmion radius (a0)012345Normalized torqueAdiabatic torque
Nonadiabatic torque51 0 1 5
1/r02 (a0-2)012Normalized torque 51 0 1 5
1/r02 (a0-2)024Normalized torque 10-5 10-8
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(d) (c)
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097204-5 |
PhysRevB.81.054418.pdf | Stochastic properties and Brillouin light scattering response of thermally driven collective
magnonic modes on the arrays of dipole coupled nanostripes
M. P. Kostylev1and A. A. Stashkevich2
1School of Physics–M013, University of Western Australia, 35 Stirling Highway, Crawley, Western Australia 6009, Australia
2LPMTM CNRS (UPR 9001), Université Paris 13, 93430 Villetaneuse, France
/H20849Received 15 October 2009; revised manuscript received 10 January 2010; published 16 February 2010 /H20850
In the present paper, the problem of thermal excitation of collective /H20849magnonic /H20850Bloch magnetostatic modes
on a one-dimensional array of magnetic stripes has been addressed. It has been shown that partially phase-correlated oscillations localized on individual stripes can be regarded as an ensemble of individual harmonicoscillators interpretable in terms of independent degrees of freedom of the magnetic system subject to thelow-energy Rayleigh-Jeans statistics. Numerical simulations of the Brillouin light scattering spectra, based onthis approach, have shown that the nth Bloch mode in strongly coupled stripes contributes mainly to the
scattering in the nth Brillouin zone. Our calculations have also confirmed numerically the noncoherent wide-
angle character of the BLS, demonstrated experimentally earlier.
DOI: 10.1103/PhysRevB.81.054418 PACS number /H20849s/H20850: 75.30.Ds, 78.35. /H11001c
I. INTRODUCTION
From both fundamental and application viewpoints, mag-
netization dynamics in ferromagnetic media has become ofutmost significance today. Rapid advances in spintronics dur-ing the last decade have contributed massively to theprogress in this field. Suffice it to mention such discoveriesas the giant magnetoresistance
1,2and precessional switching
applied to read-write processes in magnetic data storage.3,4
In the case of relatively low-angle precession, magnetic dy-
namics manifests itself through magnetic excitations propa-gating in the bulk of such materials known as spin waves/H20849SW /H20850, which are an object of great interest themselves. His-
torically, there are two different philosophies regarding thisphenomenon from different points of view. It was with theincoherent SW driven by thermal agitation, better known asmagnons, that the research in this domain began, as early asin the 1930s.
5Since then such magnetic excitations, with a
very short wavelength on the scale of the lattice parameterand hence entirely dominated by short-range exchange inter-actions, have become one of the fundamental notions in thesolid-state physics of ferromagnetic media. Another view ofthe problem, seeing it from a completely different angle, isdue to extensive application of ferrite materials to micro-wave components, beginning from the 1950s. In this case,the excitations, better known, as magnetostatic waves/H20849MSW /H20850, are of long-wavelength nature, which is dictated by
the macroscopic characteristic size of the microwave ele-ments themselves. As a result, their behavior is completelydescribed solely by the long-range dipole-dipole interactions/H20849DDI /H20850. Further development of the latter concept in the
1960s was based on the breakthrough in the technology ofsingle-crystal ferrite films, especially those based on yttriumiron garnet, with extremely low losses at microwave frequen-cies, suitable for effective signal processing, typically in de-lay lines in the frequency range from 2 to 20 GHz.
6The
coherent MSWs were excited by an external microwavesource, i.e., by a special MSW antenna. The characteristicsize of the ferrite films employed /H20849their thickness /H20850as well as
that of the microstrip MSW antennas /H20849their width /H20850being in
the micrometric range, the magnetic waves excited were ofcombined dipole-exchange nature.
7Extensive research in SW dynamics over the last few
decades has lead to further merging of the two ideasthus leading to a generic concept of the dipole-exchangeSW, either coherent or incoherent. One of the stepscontributing to the reconciliation of the two points ofview, especially important in the context of this paper, wasdue to the major improvements of the Brillouin lightscattering /H20849BLS /H20850techniques, that took place in the late
1970s and early 1980s. While earlier setups, lacking in sen-sitivity, had to resort to generation of coherent SWs by ex-ternal sources,
8,9in the updated versions10preference was
given to thermal magnons,11i.e., incoherent SWs. In spite of
their low intensity, they ensured, owing to their thermal na-ture, excitation of modes with all possible wave numbers andtemporal frequencies, within the range permitted by the SWspectra. The latter development spawned a series of papersproviding adequate theoretical support for a newly emergedtechnique.
12,13It relied on the modification of the fluctuation-
dissipation theorem /H20849FDT /H20850, developed somewhat earlier, for
a magnetic system /H20849see, for example, Refs. 14and15/H20850. The
latter allows to relate the Fourier transform of the correlationfunction /H20855m
i/H20849x/H11032,r/H6023,t/H20850mj/H20849x,r/H6023=0,t=0/H20850/H20856, determining the inten-
sity of the light scattered at a given angle to the dynamic
susceptibilities gij/H20849x,x/H11032,K/H6023,/H9275/H11006i/H9255/H20850,
/H20885dtd2r/H20855mi/H20849x/H11032,r/H6023,t/H20850mj/H20849x,r/H6023=0 ,t=0 /H20850/H20856exp /H20851i/H20849−K/H6023·r/H6023+/H9275t/H20850/H20852
/H11008/H20851gij/H20849x,x/H11032,K/H6023,/H9275+i/H9255/H20850
−gij/H20849x,x/H11032,K/H6023,/H9275−i/H9255/H20850/H20852,
in the limit /H9255→0.gij/H20849x,x/H11032,K/H6023,/H9275/H11006i/H9255/H20850, being responses to
delta-type excitations hi/H20849x/H20850=/H9254/H20849x−x/H11032/H20850, can be as well re-
garded as magnetic Green’s functions. Optical properties ofthe multilayered ferromagnetic structure are taken into ac-count via the optical Green’s-functions formalism. Typicallyapplied to magneto-optical /H20849MO /H20850interactions in thin metal
ferromagnetic structures, it has proved to be a very powerfultheoretical tool, allowing to extract from the structure of theBLS spectra valuable information on the intrinsic magneticPHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
1098-0121/2010/81 /H208495/H20850/054418 /H2084914/H20850 ©2010 The American Physical Society 054418-1parameters of the investigated sample, unattainable by any
other technique. In more recent papers16some specialized
versions of this general theoretical approach have been re-ported.
In spite of a rapid progress, within a span of the last 5
years, of an innovative micro-Brillouin modification, typi-cally employing externally excited coherent SW localized onindividual nanoelements,
17,18the classic “thermal magnon
BLS” is still indispensable,16,19–21especially for the investi-
gation of collective SW modes existing on the arrays of fer-
romagnetic elements, forming a one-dimensional /H208491D /H20850or
two-dimensional /H208492D /H20850structure.22–24Not surprisingly, it is
largely and successfully used to this end until now.
Although powerful and effective, the FDT implies an
analysis of the magnetic system on the microscopic level,which accentuates the quantum-mechanical aspect of theproblem. An alternative approach, more consistent with apurely microscopic nature of the investigated phenomena,
can be developed. Moreover, it is possible to adapt, withouttoo much difficulty, this formalism to the case of utmostimportance nowadays, namely, that of nanostructured ferro-magnetic films. In its main features, this technique can bereduced to the classical problem of the Brownian motiondriven by the Langevin force.
The goal of this paper is theoretical description of the
collective SW modes traveling in a periodic one-dimensionalarray of ferromagnetic stripes /H20849magnonic modes /H20850, typically
referred to as Bloch waves, and driven by a thermal “Lange-vin” source of magnetic field. Periodic structures of this typeare also known as 1D magnonic crystals. As their closestanalogs /H20849photonic and phononic crystals /H20850they manifest all
major features characteristic of wave propagation in periodicmedia, such as band gaps and Brillouin zone /H20849BZ /H20850. The latter
has been confirmed experimentally in Refs. 25and26 /H208492D
case /H20850. What makes their wave behavior especially interest-
ing, from the physical point of view, is a strongly pro-nounced magnetically adjustable dispersion. Theoreticalanalysis of three-dimensional magnonic crystals reveals, notsurprisingly, an even richer spectrum of wave phenomena.
27
Our paper, focusing on the stochastic properties of ther-
mally driven collective magnonic modes on 1D arrays ofdipole coupled nanostripes is organized in the following way.At a first stage, a theoretical formalism is developed, allow-ing representation of such modes as an ensemble of indi-vidual harmonic oscillators interpretable in terms of indepen-dent degrees of freedom of the magnetic system subject tothe low-energy Rayleigh-Jeans statistics.
28To this end, the
mathematical approach described in our earlier paper, Ref.29, will be further generalized. The second part of this paper
will be dedicated to the spatial correlation function playing akey role in various phenomena, such as Brillouin light scat-tering. More specifically, the correlation /H20849coherence /H20850length
l
cfor collective modes on an array of dipole coupled stripes,
coupled through DDIs, will be estimated. The latter describesthe spatial interval within which the phases of local pointMO scatterers are sufficiently correlated which ensures thespatial coherence of the inelastically scattered light. Finally,in the last part the results obtained in the previous paragraphwill be applied to the numerical estimation of the BLS an-gular spectrum. Special attention will be paid to the influenceof the correlation /H20849coherence /H20850length l
cand the size of the
incident optical beam don the form of such spectra. More
specifically, numerical simulations theoretically modeling thetransition from incoherent inelastic scattering to coherent in-elastic diffraction, experimentally studied in Ref. 30, will be
performed.
II. THEORY
A. Basic thermodynamics
The geometry of the problem is illustrated in Fig. 1.W e
study collective magnetic modes existing on a periodic arrayof parallel infinite ferromagnetic stripes with a width wand a
thickness Lseparated by a distance /H9004. This corresponds to a
spatial period equal to T=w+/H9004. The stripes are magnetized
by an external field He
/H6023zalong their axis, i.e., along z, which
means that the induced static magnetization within them Me/H6023z
is homogeneous. We limit our investigation to the case of the
lowest purely dipole magnetic mode. We also assume thatthe aspect ratio of the stripes is small L/w/H112701. In other
words, we study quasi-Damon-Eshbach /H20849DE /H20850collective
/H20849magnonic /H20850modes formed via dipole interactions between
the oscillations localized on individual stripes. They propa-gate along the “ x” axis and are characterized by a homoge-
neous distribution of the magnetization along the vertical “ y”
axis. The latter will make the dependence of the dipole fieldand the dynamic magnetization on yirrelevant which allows
one to reduce the initial 2D problem to a 1D problem byaveraging across the film thickness. Thus application of thehighly effective approximate approach proposed in Ref. 31
and generalized for the geometry studied in Ref. 29is fully
justified.
The linearized Landau-Lifschitz equation describing ther-
mally excited collective magnetic modes existing on an arrayof infinite ferromagnetic stripes can be written as
/H11509
/H11509tmx/H20849x,t/H20850+/H9275Hmy/H20849x,t/H20850−/H9275M/H20851G/H20849x,x/H11032/H20850/H20002my/H20849x/H11032,t/H20850/H20852
=/H9275M
4/H9266hy/H20849th/H20850/H20849x,t/H20850
/H11509
/H11509tmy/H20849x,t/H20850−/H9275Hmx/H20849x,t/H20850−/H9275Mmx/H20849x,t/H20850
−/H9275M/H20851G/H20849x,x/H11032/H20850/H20002mx/H20849x/H11032,t/H20850/H20852=−/H9275M
4/H9266hx/H20849th/H20850/H20849x,t/H20850/H20849 1/H20850
FIG. 1. Geometry of the considered array of dipole-interacting
stripes.M. P. KOSTYLEV AND A. A. STASHKEVICH PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-2where /H9275H=/H9253H,/H9275M=/H92534/H9266M, G/H20849x,x/H11032/H20850/H20002m/H20849x/H11032,t/H20850
=/H20848−/H11009/H11009G/H20849x,x/H11032/H20850m/H20849x/H11032,t/H20850dx/H11032is the convolution integral and
G/H20849x,x/H11032/H20850is a magnetic Green’s function describing DDI
within each stripe, as well as between different stripes,
G/H20849x,x/H11032/H20850=1
2/H9266Lln/H20875/H20849x−x/H11032/H208502
L2+/H20849x−x/H11032/H208502/H20876,
when xand x/H11032are within any stripes,
G/H20849x,x/H11032/H20850=0 ,
when xor/and x/H11032is/are outside any stripe.
h/H20849th/H20850/H20849x,t/H20850is a delta-correlated thermal Langevin force, de-
scribing thermal excitation of the magnetic modes studied,/H20855h/H9251/H20849th/H20850/H20849x,t/H20850h/H9252/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856=C/H9254/H20849x−x/H11032/H20850/H9254/H20849t−t/H11032/H20850/H9254/H9251/H9252, /H208492a/H20850
where Cis a constant, /H9254/H20849t−t/H11032/H20850is the Dirac delta function,
and/H9254/H9251/H9252is the Kronecker delta with /H9251,/H9252=x,y,z. We also
assume that its mean value is zero
/H20855h/H9251/H20849th/H20850/H20849x,t/H20850/H20856=0 . /H208492b/H20850
Note that we consider h/H9251/H20849th/H20850/H20849x,t/H20850to be completely real.
Introducing circular variables, corresponding to circular
polarizations
m/H11006=mx/H11006imy,h/H11006/H20849th/H20850=hx/H20849th/H20850/H11006ihy/H20849th/H20850/H208493/H20850
allows us to simplify the system /H208491/H20850in such a way that the
second equation is reduced to a complex conjugate of thefirst one
/H20902/H11509
/H11509tm/H20849x,t/H20850−i/H20873/H9275H+/H9275M
2/H20874m/H20849x,t/H20850−i/H9275M
2/H20851m/H11569/H20849x,t/H20850+G/H20849x,x/H11032/H20850/H20002m/H11569/H20849x/H11032,t/H20850/H20852
=−i/H9275M
4/H9266h/H20849th/H20850/H20849x,t/H20850;
c.c. /H20903/H208494/H20850
Here we used the identities m−=m+/H11569,h−/H20849th/H20850=h+/H20849th/H20850/H11569, and de-
noted m/H11013m+,h/H20849th/H20850=h+/H20849th/H20850.I nE q . /H208494/H20850the circular polarizations
of opposite directions, denoted by mand m/H11569, are coupled
through the presence of DDIs which is unavoidable in theDE geometry and which is described by the third term on theleft-hand side of Eq. /H208494/H20850. Physically this means, that the po-
larization eigenvectors are not circular, like in the case of theclassic ferromagnetic resonance, but elliptic. We will dealwith this later.
The solution to Eq. /H208494/H20850, which describes a traveling wave
on a periodic structure, just as in the case considered in Ref.29, can be represented in the form of Bloch waves,
32
mkn/H20849x/H20850=m˜kn/H20849x/H20850exp /H20849ikx /H20850, /H208495/H20850
where kis a Bloch wave vector taking on continuous values,
andm˜kn/H20849x/H20850is a spatially periodical function with the period
T,m˜kn/H20849x+jT/H20850=m˜kn/H20849x/H20850. Here nis a mode number and jis an
integer. It should be noted that in classic wave science thesolution /H208495/H20850is known as Floquet’s theorem.
33Being eigenfunctions of the Hermitian integral operator
/H9261/H20849k,n/H20850mkn/H20849x/H20850=G/H20849x,x/H11032/H20850/H20002mkn/H20849x/H11032/H20850/H20849 6/H20850
the individual Bloch waves are mutually orthogonal
/H20885
−/H11009/H11009
mkn/H20849x/H11032/H20850mk/H11032n/H11032/H11569/H20849x/H11032/H20850dx/H11032=/H9254nn/H11032/H9254/H20849k−k/H11032/H20850. /H208497/H20850
The general solution to Eq. /H208494/H20850is sought in the form of a
complete set of individual Bloch waves within the first Bril-louin zone
m/H20849x,t/H20850=/H20858
n=1/H11009/H20885
−/H9266/T/H9266/T
akn/H20849t/H20850m˜kn/H20849x/H20850exp /H20849ikx /H20850dk. /H208498/H20850
To obtain equations in amplitudes akn/H20849t/H20850let us insert Eq. /H208498/H20850
into Eq. /H208494/H20850and project both sides of the Eq. /H208494/H20850on the
eigenvectors, Eq. /H208495/H20850, taking advantage of the mutual or-
thogonality. Thus the problem is reduced to the solution of a
standard nonhomogeneous system of spin-wave equations ofmotion
28
/H20902/H11509
/H11509takn/H20849t/H20850+iAa kn/H20849t/H20850+iB /H20841k/H20841na−kn/H20849t/H20850/H11569=−i/H9275M/H20885
−/H11009/H11009
h/H20849th/H20850/H20849t,x/H20850m˜kn/H20849x/H20850/H11569exp /H20849−ikx /H20850dx
c.c., /H20903/H208499/H20850STOCHASTIC PROPERTIES AND BRILLOUIN LIGHT … PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-3where A=− /H20849/H9275H+/H9275M
2/H20850,B/H20841k/H20841n=−/H9275M
2−/H9275M/H9261/H20849/H20841k/H20841,n/H20850
Since the kernel in the integral operator in Eq. /H208496/H20850is sym-
metric its eigenvalues are real /H9261/H20849k,n/H20850=/H9261/H20849k,n/H20850/H11569. Moreover,
from Eq. /H208496/H20850it follows /H9261/H20849k,n/H20850/H11569=/H9261/H20849−k,n/H20850, which means that
/H9261/H20849k,n/H20850=/H9261/H20849−k,n/H20850=/H9261/H20849/H20841k/H20841,n/H20850.
To obtain two separate equations in bkn/H20849t/H20850andb−kn/H20849t/H20850/H11569, i.e.,
to diagonalize the system /H208499/H20850we apply the Bogoliubov trans-
formation
akn/H20849t/H20850=u/H20841k/H20841nbkn/H20849t/H20850+v/H20841k/H20841nb−kn/H20849t/H20850/H11569.
This results in an equation for normal elliptic spin-wave am-
plitudes,
/H11509
/H11509tbkn/H20849t/H20850+/H20849/H9253/H20841k/H20841n+i/H9275/H20841k/H20841n/H20850bkn/H20849t/H20850=fkn/H20849t/H20850. /H2084910a /H20850
Here
/H9275/H20841k/H20841n= sgn /H20849A/H20850/H20881A2−B/H20841k/H20841n2=− /H20853/H9275H/H20849/H9275H+/H9275M/H20850
+/H9275M2/H20851/H20841/H9261/H20849/H20841k/H20841,n/H20850/H20841−/H92612/H20849/H20841k/H20841,n/H20850/H20852/H208541/2, /H2084910b /H20850
u/H20841k/H20841n=/H20881A+/H9275/H20841k/H20841n
2/H9275/H20841k/H20841n,v/H20841k/H20841n= − sgn /H20849A/H20850B/H20841k/H20841n
/H20841B/H20841k/H20841n/H20841/H20881A−/H9275/H20841k/H20841n
2/H9275/H20841k/H20841n,
/H2084910c /H20850
fkn/H20849t/H20850=−i/H9275M/H20853u/H20841k/H20841nRkn/H20849t/H20850+v/H20841k/H20841n/H20851Rkn/H20849t/H20850/H20852/H11569/H20854, /H2084910d /H20850
where
Rkn/H20849t/H20850=/H20885
−/H11009/H11009
/H20851h/H20849th/H20850/H20849t,x/H20850m˜kn/H20849x/H20850/H11569exp /H20849−ikx /H20850/H20852dx, /H2084910e /H20850
and following Ref. 28, have phenomenologically introduced
magnetic damping /H9253/H20841k/H20841nthrough replacing /H9275/H20841k/H20841nwith/H9275/H20841k/H20841n
+i/H9253/H20841k/H20841n.I nE q . /H2084910a /H20850we have omitted the second complex
conjugate equation in the system: it returns formally the fre-quency of the same magnon but a negative sign.
The solution of Eq. /H2084910a /H20850can be written as follows:
b
kn/H20849t/H20850=/H20885
0t
dt/H11032fkn/H20849t/H11032/H20850exp /H20851−/H20849/H9253/H20841k/H20841n+i/H9275/H20841k/H20841n/H20850/H20849t−t/H11032/H20850/H20852
+bkn/H20849t=0 /H20850exp /H20851−/H20849/H9253/H20841k/H20841n+i/H9275/H20841k/H20841n/H20850t/H20852. /H2084911/H20850
In the state of thermodynamic equilibrium, i.e., for t
/H112711//H9253/H20841k/H20841n, the second term disappears. Each collective mode
is fully characterized by its integer index “ n” and a continu-
ous Bloch wave number k. To estimate the energy carried by
each mode in the state of thermodynamic equilibrium weneed to calculate the correlation function of the wave ampli-
tudes /H20855b
kn/H20849t/H20850bkn/H11569/H20849t/H20850/H20856fort/H112711//H9253/H20841k/H20841n,
Sknn/H20849t/H20850=/H20855bkn/H20849t/H20850bkn/H11569/H20849t/H20850/H20856
=/H20885
0t
dt/H11032/H20885
0t
dt/H11033/H20855fkn/H20849t/H11032/H20850fkn/H20849t/H11033/H20850/H11569/H20856exp /H20851i/H9275/H20849t/H11032−t/H11033/H20850/H20852
/H11003exp /H20851−/H9253/H20841k/H20841n/H208492t−t/H11032−t/H11033/H20850/H20852. /H2084912/H20850According to Eq. /H20849A6 /H20850the autocorrelation function reads
/H20855fkn/H20849t/H20850fkn/H20849t/H11032/H20850/H11569/H20856=2C/H9275M2/H9254/H20849t−t/H11032/H20850/H20849u/H20841k/H20841n2+v/H20841k/H20841n2/H20850
=2C/H9275M2/H9254/H20849t−t/H11032/H20850A
/H9275/H20841k/H20841n.
Here we have made use of Eqs. /H208499/H20850and /H2084910c /H20850. Thus
Sknn/H20849t/H20850=2C/H9275M2A
/H9275/H20841k/H20841n/H20885
0t
dt/H11032exp /H20851−2/H9253/H20841k/H20841nt/H11032/H20852
=C/H9275M2A
/H9253/H20841k/H20841n/H9275/H20841k/H20841n/H208511 − exp /H20849−2/H9253/H20841k/H20841nt/H20850/H20852→
t/H112711//H9253C/H9275M2 A
/H9253/H20841k/H20841n/H9275/H20841k/H20841n.
In thermodynamics it is the occupation number Nkn/H20849t/H20850that
describes the thermal energy of the mode identified by itsnumbers kandnin the state of equilibrium. In other words
N
kn/H11013Sknnand
Nkn/H11013Skn/H20849t=/H11009/H20850=C/H9275M2A
2/H9253/H20841k/H20841n/H9275/H20841k/H20841n. /H2084913/H20850
Therefore for the constant Cwe have
C=2/H9253/H20841k/H20841n/H9275/H20841k/H20841nNkn
/H9275M2A. /H2084914/H20850
On the other hand in the thermodynamic equilibrium the
spin-wave amplitude, Eq. /H2084913/H20850, should obey the Rayleigh-
Jeans distribution,28thus it should have the form
Nkn=kBT
/H20841/H9275kn/H20841, /H2084915/H20850
therefore
C=2
/H9275M2kBT
/H20841A/H20841/H9253/H20841k/H20841n /H2084916a /H20850
and
/H20855fkn/H20849t/H20850fkn/H20849t/H11032/H20850/H11569/H20856=4/H9253/H20841k/H20841nkBT
/H20841/H9275kn/H20841/H9254/H20849t−t/H11032/H20850. /H2084916b /H20850
Expression /H2084916b /H20850represents a modification of the FDT for
the collective DE mode, in the form of a Bloch wave, propa-gating on an array of dipole coupled ferromagnetic stripes.Similar formulas are known since long ago as fluctuation-dissipation relation in classical Brownian motion
15or
Nyquist’s noise theorem, relating the mean-square open-circuit thermal noise voltage to its resistance, in electricalengineering.
34As one sees from this expression all peculiari-
ties which are characteristic to the Bloch wave origin of col-lective excitations are hidden in the form of wave dispersion
/H9275kn. The general form of Eq. /H2084916b /H20850coincides with one
known for spin waves in a continuous magnetic medium28
which facilitates understanding.
B. Coherence length of thermally excited collective modes
Now we investigate the spatial correlation functions char-
acterizing distributions of magnetization in magnetostaticM. P. KOSTYLEV AND A. A. STASHKEVICH PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-4modes at a given temporal frequency . Knowledge of such
functions is instrumental for understanding a number of sig-nificant phenomena in spin-wave physics. For example, theyplay a major role in mechanisms of the Brillouin light scat-tering by thermal magnons. To streamline our analytical cal-culations we employed a highly effective mathematical for-malism developed in the field of Fourier optics in the1970s.
35,36
First, we pass from the direct temporal space “ t”t ot h e
frequency space “ /H9275” via the direct Fourier transformation.
The solution of Eq. /H2084910a /H20850can be rewritten in the frequency
domain as follows:
bkn/H20849/H9275/H20850=fkn/H20849/H9275/H20850
/H20851/H9253/H20841k/H20841n+i/H20849/H9275/H20841k/H20841n+/H9275/H20850/H20852/H2084917a /H20850
with
bkn/H20849/H9275/H20850=Fˆt→/H9275/H20851bkn/H20849t/H20850/H20852= lim
/H9008→/H110091
2/H9008/H20885
−/H9008/H9008
dtb kn/H20849t/H20850exp /H20849−i/H9275t/H20850,
fkn/H20849/H9275/H20850=Fˆt→/H9275/H20851fkn/H20849t/H20850/H20852. /H2084917b /H20850
Similarly, one can rewrite Eq. /H208492a/H20850in the frequency domain
as
/H20855h/H9251/H20849th/H20850/H20849x,/H9275/H20850h/H9252/H20849th/H20850/H20849x/H11032,/H9275/H20850/H20856=C/H9254/H20849x−x/H11032/H20850/H9254/H9251/H92521/H20849/H9275/H20850, /H2084918/H20850
where 1 /H20849/H9275/H20850is the Fourier transform of the Dirac delta func-
tion in Eq. /H208492a/H20850, as defined in the space of generalized
functions.35,36It is equals to the constant 1 on the whole /H9275axis. This allows us to obtain an explicit formula for fkn/H20849/H9275/H20850,
fkn/H20849/H9275/H20850=−i/H9275M/H20851u/H20841k/H20841nRkn/H20849/H9275/H20850+v/H20841k/H20841nRkn/H20849/H9275/H20850/H11569/H20852/H20849 19a /H20850
with
Rkn/H20849/H9275/H20850=/H20885
−/H11009/H11009
/H20851h/H20849th/H20850/H20849x,/H9275/H20850m˜kn/H20849x/H20850/H11569exp /H20849−ikx /H20850/H20852dx,
h/H20849th/H20850/H20849x,/H9275/H20850=Fˆt→/H9275/H20851h/H20849th/H20850/H20849x,t/H20850/H20852. /H2084919b /H20850
Thus the spatial distribution of the magnetization at a given
frequency can be written explicitly as
b/H20849x,/H9275/H20850=/H20858
n=1/H11009/H20885
−/H9266/T/H9266/T
dkb kn/H20849/H9275/H20850m˜kn/H20849x/H20850exp /H20849ikx /H20850, /H2084920/H20850
which allows us to define the corresponding spatial correla-
tion function, averaged over the ensemble, in the followingway,
/H20855/H20855b/H20849x,
/H9275/H20850b/H11569/H20849x+/H9264,/H9275/H20850/H20856x/H20856=/H20883/H20885
−/H11009/H11009
b/H20849x,/H9275/H20850b/H11569/H20849x+/H9264,/H9275/H20850dx/H20884
=/H20885
−/H11009/H11009
/H20855b/H20849x,/H9275/H20850b/H11569/H20849x+/H9264,/H9275/H20850/H20856dx.
/H2084921/H20850
Substituting Eq. /H2084920/H20850into Eq. /H2084921/H20850and taking into account
the orthogonality of the eigenfunctions /H208497/H20850we obtain
/H20855/H20855b/H20849x,/H9275/H20850b/H11569/H20849x+/H9264,/H9275/H20850/H20856x/H20856=/H20858
n/H20858
n/H11032/H20885
−/H9266/T/H9266/T
dkexp /H20849−ik/H9264/H20850/H20885
−/H9266/T/H9266/T
dk/H11032/H20855bkn/H20849/H9275/H20850bk/H11032n/H11032/H20849/H9275/H20850/H11569/H20856/H20885
−/H11009/H11009
dxm˜kn/H20849x/H20850m˜k/H11032n/H11032/H11569/H20849x+/H9264/H20850exp /H20849i/H20849k−k/H11032/H20850x/H20850.
/H2084922/H20850
To begin with, let us find the expression for /H20855bkn/H20849/H9275/H20850bk/H11032n/H11032/H20849/H9275/H20850/H11569/H20856, making use of Eqs. /H2084917a /H20850and /H20849A6 /H20850,
/H20855bkn/H20849/H9275/H20850bk/H11032n/H11032/H20849/H9275/H20850/H11569/H20856=/H20855fkn/H20849/H9275/H20850fk/H11032n/H11032/H11569/H20849/H9275/H20850/H20856
/H20851/H9253/H20841k/H20841n+i/H20849/H9275/H20841k/H20841n+/H9275/H20850/H20852/H20851/H9253/H20841k/H11032/H20841n/H11032−i/H20849/H9275/H20841k/H11032/H20841n/H11032+/H9275/H20850/H20852=2C/H9275M2A/H9254/H20849k−k/H11032/H20850/H9254nn/H11032
/H9275/H20841k/H20841n/H20851/H9253/H20841k/H20841n2+/H20849/H9275/H20841k/H20841n+/H9275/H208502/H20852.
Thus finally one obtains
/H20855/H20855b/H20849x,/H9275/H20850b/H11569/H20849x+/H9264,/H9275/H20850/H20856x/H20856=/H20858
n/H20885
−/H9266/T/H9266/T
dkF nk/H20849/H9264/H20850exp /H20849−ik/H9264/H208502CA/H9275M2
/H9275/H20841k/H20841n/H20851/H9253/H20841k/H20841n2+/H20849/H9275/H20841k/H20841n+/H9275/H208502/H20852/H2084923a /H20850
with
Fnk/H20849/H9264/H20850=/H20885
−/H11009/H11009
m˜kn/H20849x/H20850m˜kn/H11569/H20849x+/H9264/H20850dx. /H2084923b /H20850
In other words, Fnk/H20849/H9264/H20850is the autocorrelation of the periodic distribution of the dynamic magnetization m˜kn/H20849x/H20850.
For small magnetic damping /H20841Vk0n0/H20849g/H20850/H20841//H20849/H9253/H20841k/H20841nT/H20850/H112711/H20849the parameter Vk0n0/H20849g/H20850is explained below /H20850two important approximations,
simplifying further calculations, are justified. First, only the kvectors in the vicinity of k0values, that satisfies /H9275/H20841k0/H20841n0+/H9275=0,
contribute to the integral /H2084923a /H20850. Therefore we may expand the eigenfrequency /H9275/H20841k/H20841nin a Taylor series, in theSTOCHASTIC PROPERTIES AND BRILLOUIN LIGHT … PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-5vicinity of k0, keeping only the linear term /H9275/H20841k/H20841n+/H9275=/H11006/H20841Vk0n0/H20849g/H20850/H20841/H20849k−k0/H20850. This approximation is valid not very close to the center
and the edges of the first Brillouin zone. /H20849Near these special points Vk0n0/H20849g/H20850→0 and the second-order term of Taylor-series
expansion should be taken into account. /H20850Second, the limits of integration can be pushed up to /H20849−/H11009,/H11009/H20850which will allow us to
use the method of residues. Thus we obtain
/H20855b/H20849x,/H9275/H20850b/H11569/H20849x+/H9264,/H9275/H20850/H20856=2/H9266
/H20841Vk0n0/H20849g/H20850/H20849/H9275/H20850/H20841CA/H9275M2
/H9253/H20841k0/H20841n0/H9275/H20841k0/H20841n0Fn0k0/H20849/H9264/H20850exp/H20875−/H9253k0n0
/H20841Vk0n0/H20849g/H20850/H20841/H20841/H9264/H20841/H20876exp /H20849−ik0/H9264/H20850, /H2084924/H20850
and hence
/H20841/H20855b/H20849x,/H9275/H20850b/H11569/H20849x+/H9264,/H9275/H20850/H20856/H20841=2/H9266
/H20841Vk0n0/H20849g/H20850/H20849/H9275/H20850/H20841CA/H9275M2
/H9253/H20841k0/H20841n0/H9275/H20841k0/H20841n0Fn0k0/H20849/H9264/H20850exp/H20875−/H9253k0n0
/H20841Vk0n0/H20849g/H20850/H20841/H20841/H9264/H20841/H20876. /H2084925/H20850
It should be noted that the indices k0andn0indicate that the
corresponding values are calculated for k0andn0that satisfy
/H9275/H20841k0/H20841n0+/H9275=0.
Note that Eqs. /H2084925/H20850and /H2084926/H20850contain only the term of the
total solution which originates from the traveling-wave partof the spin-wave excitation Green’s function.
37The term
which corresponds to the source reactance was neglected asit is localized at the source and does not contribute to coher-ence of magnetization precession at a distance from thesource.
The obtained formula allows one estimating the spin-
wave coherence length l
c. We define it as the distance at
which the value of correlation function is exp /H208491/H20850times
smaller than its original value /H20849/H20855b/H20849x,/H9275/H20850b/H11569/H20849x+lc,/H9275/H20850/H20856=exp /H20849
−1/H20850/H20855b/H20849x,/H9275/H20850b/H11569/H20849x,/H9275/H20850/H20856/H20850. Therefore the correlation length /H20849or
coherence /H20850length for the collective mode is defined as fol-
lows:
lc/H20849k,n/H20850=/H20841Vkn/H20849g/H20850/H20841
/H9253/H20841k/H20841n. /H2084926/H20850
If the magnetic damping is small we may measure the coher-
ence length in the number of coupled stripes j. Therefore we
assume that lc/H20849k,n/H20850=jT, we obtain
j=/H20841Vkn/H20849g/H20850/H20841
/H9253/H20841k/H20841nT. /H2084927/H20850
The coherence length is proportional to the group velocity of
the collective mode /H20841Vkn/H20849g/H20850/H20841=/H11509/H9275/H20841k/H20841n
/H11509k. It may be calculated from
Eq. /H2084910b /H20850by taking its derivative over kwhich gives
Vkn/H20849g/H20850=−/H9275M/H20875/H9275M
2+/H9275M/H9261/H20849/H20841k/H20841,n/H20850/H20876
/H9275/H20841k/H20841n/H11509/H9261/H20849k,n/H20850
/H11509k. /H2084928/H20850
Moreover, the derivative/H11509/H9261/H20849k,n/H20850
/H11509kin Eq. /H2084928/H20850can be expressed
as the following integral:/H11509/H9261/H20849k,n/H20850
/H11509k=/H20885
−/H11009/H11009
dx/H20885
−/H11009/H11009
dx/H11032i/H20849x/H11032−x/H20850m˜kn/H20849x/H20850G/H20849x,x/H11032/H20850m˜kn/H20849x/H11032/H20850
/H11003exp /H20851ik/H20849x/H11032−x/H20850/H20852dx/H11032. /H2084929/H20850
This formula will be used below in numerical calculations.
Figure 2shows variation in the coherence length with k
X Data9.0e+9 1.0e+10 1.1e+10 1.2e+10 1.3e+10 1.4e+10 1.5e+10 1.6e +Bloch wavenumber k(105rad/cm)
0.00.20.40.60.81.01.21.4
Frequenc y(GHz)9 1 01 11 21 31 41 51 6Coherence length lcin number of periods
024681012141618n=1n=1n=2
n=2n=3
n=4
n=3n=5
n=4
FIG. 2. Dispersion /H20849upper panel /H20850and coherence length of col-
lective excitations. Parameters of calculation: stripe width: 350 nm,stripe thickness: 40 nm, stripe separation: 70 nm, saturation mag-netization 4
/H9266M=10 000 G, applied field: 500 Oe, Gilbert magnetic
damping constant: /H9251=0.008, gyromagnetic constant /H9253/2/H9266
=2.82 MHz /Oe. nin the figure denotes the mode number. The
fundamental mode is n=1.M. P. KOSTYLEV AND A. A. STASHKEVICH PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-6and/H9275. From this figure one sees that only the lowest /H20849fun-
damental /H20850n=1 mode of collective excitations can propagate
considerable distances across the periodic structure. As onecan see from the upper panel, this mode is the only modewith considerable dispersion and thus with a considerablegroup velocity. The latter allows this mode to cross a numberof stripes during its relaxation time 1 /
/H9253/H20841k/H20841n. The coherence
length drops near the middles /H20849k=2l/H9266/T,l=0,1,... /H20850and
the edges of Brillouin zones /H20851k=/H208492l+1/H20850/H9266/T/H20852, where Bloch
waves represent standing-wave oscillations.
It is worth noticing that the decrease in the group velocity
till zero toward the middle of the first BZ is very sharp andhappens in a very narrow krange 0–100 rad/cm. That is why
the change in the curvature near k=0 is not seen it the upper
panel of Fig. 2. Such a narrow range of kvalues where the
group velocity changes from the maximum to zero is a sig-nature of strong dipole coupling of stripes in this example.Furthermore, this reflects the fact that across the BZ the di-pole coupling is strongest for the zone middle where themotion of magnetization is quasihomogeneous across thewhole array, as the Bloch wavelength is much larger than thestructure period. With increase in the distance betweenstripes this krange increases and flattening of dispersion near
k=0 becomes visible for /H9004/H11022w.
Figure 3shows variation in the coherence length with the
distance between adjacent stripes /H9004. This graph was calcu-
lated for the fundamental collective mode and for a Blochnumber near the middle of the first BZ /H20849k=0.17
/H9266/T/H20850. Withthe increase in the distance, dipole coupling of stripes de-
creases. This results in a decrease in the bandwidth of thefirst magnonic band /H20849
/H9275k=/H9266/T,n=1−/H9275k=0,n=1/H20850and, consequently,
in the slope of the dispersion /H9275k,n=1/H20849k/H20850. The former is evi-
denced by the upper panel of this figure which shows in-crease in frequency for the fundamental mode with decreasein the dipole coupling. At large separations the frequencytends to one for uncoupled stripes for which the width of themagnonic band is zero and the dispersion slope is zero too.The collective mode coherence length is zero. With the in-crease in the dipole coupling the collective dipole field ofstripes pushes the frequency for the middle of BZ down andfor the edge of the first BZ up with respect to the uncoupledstripes /H20849see Fig. 6 in Ref. 29/H20850. The dispersion slope increases
and the coherence length grows, respectively.
C. BLS intensities
Making use of Eq. /H2084925/H20850one can also estimate BLS inten-
sities seen at particular angle of incidence of the laser light inthe conventional /H20849reciprocal space-resolved BLS /H20850.
The BLS spectroscopy, in its conventional nonmicro-BLS
version, is based on the analysis of the intensity of the lightinelastically scattered by a magnon in the inverse k
/H20849s/H20850space
as a function of the magnon frequency /H9275. The latter is related
to the polarization induced through the interaction of theincident light wave and a magnetostatic mode in the follow-ing way:
I/H20851k
/H20849s/H20850,/H9275/H20852=/H20855E/H20851k/H20849s/H20850,/H9275/H20852E/H11569/H20851k/H20849s/H20850,/H9275/H20852/H20856=/H20855Fˆx→k/H20849s/H20850/H20851P/H20849x/H20850/H11569P/H11569/H20849x/H20850/H20852/H20856.
/H2084930/H20850
P/H20849x/H20850/H11569P/H11569/H20849x/H20850=/H20848−/H11009/H11009P/H20849/H9264/H20850P/H11569/H20849x+/H9264/H20850d/H9264corresponds to the autocor-
relation of the polarization with its complex conjugate,which is denoted by the symbol
/H11569. Here we do not consider
the complex tensor nature of the MO interactions thus focus-ing on the stochastic aspect of the problem. One can findcalculations of the effective cross section elsewhere /H20849see, for
example, Refs. 38and39/H20850. Typically, in the conventional
BLS technique the divergence of the incident optical beam issmall to ensure resolution in the inverse kspace and the
dependence of the MO cross section on the angle of inci-dence can be neglected. That is why we define the inducedpolarization, in the scalar approximation, as P/H20849x/H20850
=b/H20849x,
/H9275/H20850E/H20849i/H20850/H20849x,/H9275/H20850.
In the particular case of a plane incident light wave char-
acterized by an in-plane wave vector k/H20849i/H20850, the Bloch wave
number kin Eq. /H2084923a /H20850is to be replaced by k/H20849i/H20850+k. Thus one
obtains the classic formula38
I/H20851k/H20849s/H20850,/H9275/H20852=/H20885
−/H11009/H11009
d/H9264/H20855b/H20849x,/H9275/H20850b/H11569/H20849x+/H9264,/H9275/H20850/H20856exp /H20853i/H20851k/H20849s/H20850−k/H20849i/H20850/H20852/H9264/H20854,
/H2084931/H20850
where the ensemble average is estimated through the FDT.
Actually, however the incident optical beam is of finite
size both in the direct and inverse space E/H20849i/H20850/H20849x,/H9275/H20850
=D/H20849x/H20850exp /H20849ik/H20849i/H20850x/H20850. Here function D/H20849x/H20850describes the distribu-
tion of the optical field in space. ThusXD a t a0 200 400 600 800 1000Frequency (GHz)
10.010.210.410.610.811.0
Stripes eparation (nm)0 200 400 600 800 100 0Coherence length lcin number of periods
0246810121416
FIG. 3. Coherence length of the fundamental collective mode
n=1 as a function of strip separation /H9004for a Bloch wave number
near the middle of the first Brillouin zone k=0.17/H9266/T. Parameters
of calculation are the same as for Fig. 2.STOCHASTIC PROPERTIES AND BRILLOUIN LIGHT … PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-7I/H20851k/H20849s/H20850,/H9275/H20852=/H20885
−/H11009/H11009
d/H9264/H20885
−/H11009/H11009
dx/H20855D/H20849x/H20850b/H20849x,/H9275/H20850D/H20849x+/H9264/H20850b/H11569/H20849x+/H9264,/H9275/H20850/H20856exp /H20853i/H20851k/H20849s/H20850−k/H20849i/H20850/H20852/H9264/H20854
=Fˆ/H9264→k/H20849s/H20850−k/H20849i/H20850/H20855/H20853D/H20849x/H20850b/H20849x,/H9275/H20850/H11569/H20851D/H20849x/H20850b/H20849x,/H9275/H20850/H20852/H11569/H20854/H20856. /H2084932/H20850
The latter means that in the inverse q=k/H20849s/H20850−k/H20849i/H20850space the Fourier transform of D/H20849x/H20850b/H20849x,/H9275/H20850and its complex conjugate are
multiplied. To be specific let us suppose that the light intensity within the optical spot of width dis homogeneous, i.e.,
D/H20849x/H20850= Rect /H208492x/d/H20850, where Rect /H208732x
d/H20874=/H209041 if−d
2/H11021x/H11021d
2
0if x/H11350d
2and x /H11349−d
2./H20841
To begin with, we consider a particular magnetostatic mode ncharacterized by a particular value of the Bloch wave number
k. Thus, making use of Eq. /H2084924/H20850, the autocorrelation function in Eq. /H2084932/H20850can be rewritten
/H20855D/H20849x/H20850b/H20849x,/H9275/H20850/H11569/H20851D/H20849x/H20850b/H20849x,/H9275/H20850/H20852/H11569/H20856=/H20885
−/H11009/H11009
dxRect/H208732x
d/H20874Rect/H208752/H20849x+/H9264/H20850
d/H20876/H20855b/H20849x,/H9275/H20850b/H11569/H20849x+/H9264,/H9275/H20850/H20856
=H/H20849/H9275/H20841k/H20841n/H20850Fnk/H20849/H9264/H20850exp/H20875−/H9253kn
/H20841Vkn/H20849g/H20850/H20841/H20841/H9264/H20841/H20876exp /H20849−ik/H9264/H20850/H20875Rect/H208732/H9264
d/H20874/H20002Rect/H208732/H9264
d/H20874/H20876.
To simplify notations we have put2/H9266
/H20841Vkn/H20849g/H20850/H20841CA/H9275M2
/H9253/H20841k/H20841n/H9275/H20841k/H20841n=H/H20849/H9275/H20841k/H20841n/H20850.
In other words, in Eq. /H2084932/H20850the Fourier operator is applied
to a product of three functions of /H9264, which means that this
operator returns a double convolution of the correspondingFourier transforms,
Fˆ
/H9264→q/H20875Rect/H208732/H9264
d/H20874/H20002Rect/H208732/H9264
d/H20874/H20876=d2Sinc2/H208492q/d/H20850,
Fˆ/H9264→q/H20877exp/H20875−/H9253kn
/H20841Vkn/H20849g/H20850/H20841/H20841/H9264/H20841/H20876exp /H20849−ik/H9264/H20850/H20878=2/H9253kn
/H20841Vkn/H20849g/H20850/H20841
/H20849q−k/H208502+/H20875/H9253kn
/H20841Vkn/H20849g/H20850/H20841/H208762
and /H20851see Eq. /H2084923b /H20850/H20852
Fˆ/H9264→q/H20851Fnk/H20849/H9264/H20850/H20852=Fˆ/H9264→q/H20851m˜kn/H20849/H9264/H20850/H11569m˜kn/H20849/H9264/H20850/H20852=/H20841M˜kn/H20849q/H20850/H208412
with M˜kn/H20849q/H20850=Fˆ/H9264→q/H20851m˜kn/H20849/H9264/H20850/H20852andq=k/H20849s/H20850−k/H20849i/H20850.
The periodic function m˜kn/H20849x/H20850can be regarded as a convo-
lution of the distribution of the dynamic magnetization on a
single element skn/H20849/H9264/H20850=Rect /H20849/H9264
T/2/H20850m˜kn/H20849/H9264/H20850with a periodic comb
of delta functions with Tspacing, known as the Dirac comb
and conventionally denoted comb /H20849/H9264
T/H20850,
m˜kn/H20849/H9264/H20850=skn/H20849/H9264/H20850/H20002comb/H20873/H9264
T/H20874
with comb /H20873/H9264
T/H20874=/H20858
l=−/H11009/H11009
/H9254/H20849/H9264−lT/H20850.
Consequently, its Fourier transform is a product of the re-
spective Fourier transformsFˆ/H9264→q/H20851m˜kn/H20849/H9264/H20850/H20852=Skn/H20849q/H20850T
2/H9266comb/H20873q
/H9004q/H20874
and consequently
Fˆ/H9264→q/H20851m˜kn/H20849/H9264/H20850/H11569m˜kn/H20849/H9264/H20850/H20852=T
2/H9266/H20858
l=−/H11009/H11009
/H20841Skn/H20849q−l/H9004q/H20850/H208412/H9254/H20873q−l/H9004q
/H9004q/H20874.
Here Skn/H20849q/H20850=Fˆ/H9264→k/H20851skn/H20849/H9264/H20850/H20852and/H9004q=2/H9266/T. We have also used
the well-known relation Fˆ/H9264→q/H20851comb /H20849/H9264
T/H20850/H20852=1
/H9004qcomb /H20849q
/H9004q/H20850. Thus
the first convolution yields
/H20841M˜kn/H20849q/H20850/H208412/H20002/H20851d2Sinc2/H208492q/d/H20850/H20852
=T
2/H9266/H20858
l=−/H11009/H11009
/H20841Skn/H20849q−l/H9004q/H20850/H208412/H9254/H20873q−l/H9004q
/H9004q/H20874/H20002d2Sinc2/H208492q/d/H20850
=Td2
2/H9266/H20858
l=−/H11009/H11009
/H20841Skn/H20849q−l/H9004q/H20850/H208412Sinc2/H208752/H20849q−l/H9004q/H20850
d/H20876.
A second convolution leads to the final result
I/H20849q,/H9275/H20850=Td2
/H9266/H9253kn
/H20841Vkn/H20849g/H20850/H20841/H20858
l=−/H11009/H11009/H20885
−/H11009/H11009
dq/H11032/H20841Skn/H20849q/H11032−l/H9004q/H20850/H208412
/H11003Sinc2/H208752/H20849q/H11032−l/H9004q/H20850
d/H208761
/H20849q−q/H11032−k/H208502+/H20875/H9253kn
/H20841Vkn/H20849g/H20850/H20841/H208762.
/H2084933/H20850
The square of the Sinc function, known as Fejer kernel, is a
delta sequence. Thus if the width of the beam in Eq. /H2084933/H20850
tends to the infinity d→/H11009, it must be replaced by a DiracM. P. KOSTYLEV AND A. A. STASHKEVICH PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-8delta function. Due to the filtering properties of the latter the
integration in Eq. /H2084933/H20850disappears and one obtains for an
infinitely wide beam
I/H20849q,/H9275/H20850=I0/H20849k,n/H20850/H20858
l=−/H11009/H11009/H20841Skn/H20849l/H9004q/H20850/H208412
/H20849q−l/H9004q−k/H208502+/H20873/H9253kn
/H20841Vkn/H20849g/H20850/H20841/H208742,
I0/H20849k,n/H20850=Td2
/H9266/H9253kn
/H20841Vkn/H20849g/H20850/H20841. /H2084934a /H20850
In the inverse qspace, each collective mode, due to its peri-
odic character, will give rise to multiple responses of Lorent-zian type. The weight of each peak is determined by theFourier coefficients /H20841S
kn/H20849l/H9004q/H20850/H208412while the width of each
Lorentzian line depends entirely on the coherence length /H20851see
Eqs. /H2084926/H20850and /H2084934a /H20850/H20852. This not surprising, since the coherence
length lc/H20849k,n/H20850describes the spatial localization of coherent
scattering sources.
In the general case, however each Lorentzian line is
smeared by the finite angular spectrum of the incident lightway, which is mathematically taken into account through aconvolution of the Lorentzian function and the Fejer kernel/H20851see Eq. /H2084933/H20850/H20852. Without unnecessary loss of accuracy, the
main lobe of the latter can be replaced by an equivalentrectangular function /H20849see below /H20850, which makes the calcula-
tion straightforward, extremely rapid and reliable.
The expression /H2084934a /H20850can be rewritten in the domain of
temporal frequencies
/H9275,
I/H20849q,/H9275/H20850=I0/H20849k,n/H20850/H20841Vkn/H20849g/H20850/H208412
/H9253/H20841k/H20841n2+/H20849/H9275/H20841k/H20841n+/H9275/H208502/H20858
l/H20841Skn/H20849l/H9004q/H20850/H208412. /H2084934b /H20850
The BLS lines for all the responses will be centered at the
frequency of resonance excitation of the mode by a thermalsource /H20841
/H9275/H20841k/H20841n/H20841=/H20841/H9275/H20841. The responses will be seen at incidence
angles which correspond to the transferred wave numbers
k+l/H9266/T,l=0 ,/H110061,/H110062,... /H2084935/H20850
/H20849Recall, − /H9266/T/H11021k/H11021/H9266/T/H20850. In which Brillouin zone /H20849l+1
−/H9266/T+2/H9266l/T/H11021q/H11021/H9266/T+2/H9266l/T/H20850a mode gives a maximum
response depends on the mode eigenprofile m˜kn/H20849x/H20850/H20849through
Skn/H20850. The fundamental mode is characterized by a quasiho-
mogeneous distribution of dynamic magnetization across thestripes and thus gives the maximum response in the first BZ.The next mode is antisymmetric and has one node across thestripe width. Its spectrum is obviously composed from oddharmonics of the structure period 2
/H9266l/T,l=/H110061,/H110063,...
with the maximum response in the second BZ /H20849l+1=2 /H20850, etc.
A real BLS setup has a finite qresolution as it collects
light from a finite range of incidence angles /H9004/H9258. Then the
corresponding range of uncertainty /H9004kinq/H20849and thus in k/H20850
results in broadening of the BLS line. For simplicity wemay assume that within /H9004
/H9258intensity of all spectral compo-
nents of light incident on the sample is the same. Thus in thescattered light resonance lines for eigenexcitations with fre-quencies ranging from
/H9275k−/H9004k/2nto/H9275k+/H9004k/2nwill be present
with equal amplitude. Then in order to account for this effect
one has to substitute the term1
/H9253/H20841k/H20841n2+/H20849/H9275/H20841k/H20841n+/H9275/H208502in Eq. /H2084934b /H20850byits integral over the range of uncertainty in /H9004k:U/H20849/H9004k/H20850
=/H20848k−/H9004k/2k+/H9004k/2 dk/H11032
/H9253/H20841k/H11032/H20841n2+/H20849/H9275/H20841k/H11032/H20841n+/H9275/H208502. Approximating /H9275k/H11032n=/H9275kn+Vkn/H20849g/H20850/H20849k/H11032−k/H20850
one obtains
U/H20849/H9004k/H20850=/H20875arctan/H20873/H9275kn+/H9275+Vkn/H20849g/H20850/H9004k
/H9253kn/H20874
+ arctan /H20873/H9275+/H9275kn+Vkn/H20849g/H20850/H9004k
/H9253kn/H20874/H20876//H20849/H9253knVkn/H20849g/H20850/H20850./H2084936/H20850
Figure 4shows plots of I/H20849q,/H9275/H20850in which gray scale is for the
mode intensity I. It was calculated using Eq. /H2084934a /H20850with the
term1
/H9253/H20841k/H20841n2+/H20849/H9275/H20841k/H20841n+/H9275/H208502substituted by U/H20849k/H20850as defined by Eq. /H2084936/H20850.
The uncertainty in the transferred wave number was taken
5% of the width of a Brillouin zone 2 /H9266/T. The lower panel
of this figure is for stripes placed far apart from one another.Dipole coupling of stripes in this geometry is small for allmodes which results in a small group velocity and, conse-quently in a small coherence length. As a result, all themodes are practically dispersionless, as previously seen innumerous experiments.
16,19,21,40
The middle panel is for strongly dipole coupled stripes.
From this panel one clearly sees the opposite tendency: thelowest /H20849fundamental /H20850mode gives rise to a BLS response in
the first BZ, the second one in the second BZ, and so on.Cross sections of this figure along the lines q=0.2/H1100310
5and
0.6/H11003105rad /cm are given in Fig. 5. Positions of the respec-
tive cross sections are shown in Fig. 4by the respective
vertical lines.
The middle panel is for an array of strongly dipole
coupled stripes but consisting of wider stripes than for theupper panel. The width of the stripe is chosen such as it iscomparable with the free propagation path in an unstructured
film
/H9253Vunstruct/H20849g/H20850. From this figure one sees the BLS responses
for the highest-order modes practically collapse into a con-tinuous dispersion law for an unstructured film. This phe-nomenon was previously observed on uncoupled stripes.
20
Recall that the highest-order modes have a negligible widthof the magnonic band and thus are not practically dipolecoupled. BLS intensity for stripes at a large distance fromeach other is given for comparison in the lower panel.
In the last series of calculations we have estimated BLS
intensity for different collection solid angles which introducedifferent uncertainties in the transferred wave numbers. Thiswork was partially inspired by Ref. 30in which BLS from a
periodical array of elongated nanodots was experimentallystudied. To apply our theory we treat rows of nanodots as500-nm-wide stripes of infinite length with 250 nm inter-stripe separation. Our calculation shows that these effectivestripes are efficiently dipole coupled. The collective modedispersion as seen by BLS with a small collection solid angleis shown in Fig. 6, upper right panel. The upper left panel
demonstrate the same calculation for a collection angle
which corresponds to
1
2of the width of the BZ for this qua-
sicrystal lattice /H20849/H9004q=/H9266/T/H20850. One sees a broad intensity peak
for the main mode and much narrower peaks for the higher-order modes. Cross sections of the 2D plots in the upperpanels along the edge of the first BZ q=
/H9266/Tare shown in
the lower panels.STOCHASTIC PROPERTIES AND BRILLOUIN LIGHT … PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-9The lowest collective mode gives rise to the broadest in-
tensity peak for /H9004q=/H9266/T. This mode is characterized by the
largest correlation length due to the largest group velocity/H20849dispersion slope /H20850. Furthermore, it is characterized by the
largest frequency band /H20849magnonic band /H20850. The closest higher-
order mode forms a much smaller magnonic band. Further-more, it is almost dispersionless which results in a muchsmaller correlation length for this mode. Thus, in our calcu-lation decreasing the collection angle for the case of themode with a large correlation length results in a considerablenarrowing of the BLS peak and decrease in its intensity. Onthe contrary, the first higher-order mode does not exhibit aconsiderable change in the peak width with decrease in thecollection angle. Importantly, the peak intensity decreasesconsiderably similar to the lowest-order mode.
FIG. 4. “Intensities” of collective modes as seen by Brillouin
light scattering technique for different stripe widths wand separa-
tions d. Upper panel: w=350 nm and /H9004=70 nm. Middle panel:
w=1050 nm and /H9004=70 nm. Lower panel: w=/H9004=350 nm. Laser
beam width d=/H11009. Brighter gradations of gray correspond to larger
intensity. The other parameters of calculation are the same as in Fig.2. The Gilbert damping constant entering the expression for mag-
netic damping
/H9253nk=/H9251/H9275nkis as for permalloy /H9251=0.008. /H20849The spot
structure seen in the data is an artefact of presentation of calculateddata by the plotting software used. It is connected with discreetnessof input data for the software. /H20850Frequenc y(GHz)7 8 9 1 01 11 21 3Intens ity(arb.u nit.)
024681012
FIG. 5. Cross sections of the 2D plot in Fig. 4, middle panel,
along the lines q=0.2/H11003105rad /cm /H20849solid line /H20850and 0.6
/H11003105rad /cm /H20849dashed line /H20850. Positions of the respective cross sec-
tions are shown in Fig. 4by the respective vertical lines.
FIG. 6. Intensities for different collecting lens apertures. Left
panels: the lens collects the light from the solid angle corresponding
to1
2of the Brillouin zone. Right panel: 1/10 of the Brillouin zone.
Upper panels: intensities. Lower panels: cross sections of the upperpanels along the edge of the first Brillouin zone
/H9266/T. Brightness
scale is the same for both upper panels.M. P. KOSTYLEV AND A. A. STASHKEVICH PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-10Thus the behavior of the peak amplitude is in good agree-
ment with Ref. 30, which is not the case for the evolution of
the peak width. We suggest the following explanation for thisdisagreement. First, the array in Ref. 30is a set of nanodots.
The nanodots as 2D objects are characterized by a muchricher spectrum of eigenoscillations with broader frequencybands than the quasi-1D nanostripes /H20849see, e.g., Ref. 41/H20850.
Therefore, increasing the collection angle results in collect-ing a BLS response from a larger number of eigenexcitationsthus from a larger frequency band. If the dynamics is drivenby a spectrally narrow source, like a microwave generator,the increase in the collection angle does not result in achange in the peak width, as the peak width is given by thelinewidth of the microwave generator, which is negligible,and the instrumental linewidth of the Sandercock interferom-eter.
One has to note that a periodic stripe array represents a
diffraction lattice for the incident laser light. In particular, theauthors of Ref. 30note that the diffracted beams originating
from the patterned sample are clearly visible to the nakedeye. Thus multiple maxima of diffraction of the laser light inreflection can be formed. This scattering is “elastic” as thefrequency of light is conserved. In the backscattering geom-etry of BLS experiment the light which has elastically scat-tered into all orders of diffraction n
dcan then scatter from all
harmonics m˜knlof the collective modes. This modifies the
resonance scattering condition /H2084935/H20850. The more precise condi-
tion for resonance scattering of the light reads,
q=k+2/H9266/H20849l−nd/H20850/T. /H2084937/H20850
Following this condition inelastically scattered light col-
lected at an incidence angle /H9258=arcsin /H20853/H20851k+2/H9266/H20849l
−nd/H20850/T/H20852/H20849/H9261las/4/H9266/H20850/H20854will represent a combination of responses
from all orders of elastic diffraction ndand of inelastic scat-
tering from all harmonics lof the collective modes which
satisfy the above condition for /H9258. This reflects the double-
scattering nature of this contribution: at the first stage, thelight is diffracted elastically by the relief lattice and after thisthe second MO scattering occurs. In the present calculationfor simplicity reasons we do not account for this effect, as forahighly pronounced collective behavior the stripes should be
closely spaced /H20849/H11021200 nm apart /H20850. This means that the elastic
scattering is dominated by near-field mechanisms, whichmakes it relatively inefficient.
As a final note for this section we now discuss validity of
our theory of the magneto-optical interaction. Its obviouslimitation is its scalar character. An important consequenceof this is a loss of the so-called Stokes-anti-Stokes asymme-try of BLS peaks for the Damon-Eschbach wave.
42,43This
effect represents a difference in the BLS amplitudes for thepositive and negative frequencies. This difference is seen,e.g., in Fig. 5 of Ref. 22.
One can separate two contributions to this effect. One is
connected to the fact that the magneto-optical interaction isdescribed by a tensor magnitude: the magneto-optical tensor.
Its action on the circularly polarized vector amplitude of dy-
namic magnetization depends on the direction of the trans-ferred wave number. An interested reader can find an exten-sive discussion concerning this point in Ref. 44.A sw ed onot include the magneto-optical tensor into the derivation of
Eq. /H2084934a /H20850, and treat the magneto-optical interaction as a sca-
lar, we loose this contribution to the Stokes/anti-Stokesasymmetry.
The second contribution to the Stokes-anti-Stokes asym-
metry appears in experiments for larger wave numbers suchaskLis on order of 1. This contribution is related to the
surface character of the Damon-Eshbach wave and to theskin depth law valid for the optical field in the sample. Insimple words, the thickness profile of the Damon-Eshbachwave propagating along the film surface facing the incidentoptical beam has a larger overlap integral with the opticalfield than the mode profile for the wave localized at the sec-ond film surface. This contribution is not included in ourtheory either, since to include it one should have treated themagnetization dynamics in the stripes thickness resolved, asit was done in a recent paper.
45In the present paper, to keep
the results simple we use the simple quasi-one-dimensionaldescription of the magnetization dynamics /H20849see discussion in
the beginning of Sec. II A /H20850. This description is valid for kL
/H110210.5.
46For these wave numbers the Damon-Eshbach wave
localization at the film surfaces is not important and is ne-glected from very beginning of the derivation.
III. CONCLUSION
Formation of collective magnetostatic modes via dipolar
coupling between individual elements is the main physicalmechanism underlying magnonic wave phenomena in peri-odic ferromagnetic structures. In the present paper, this fun-damental problem has been addressed for the case of ther-mally driven MSW on a one-dimensional array of magneticstripes.
It has been shown that partially phase-correlated oscilla-
tions localized on individual stripes can be regarded as anensemble of individual harmonic oscillators interpretable interms of independent degrees of freedom of the magneticsystem subject to the low-energy Rayleigh-Jeans statistics.
Further theoretical analysis, based on the spatial correla-
tion approach, has revealed the importance of the parameterl
cknown as correlation or coherence length of a Bloch mode,
driven by a thermal “Langevin magnetic source.” The latterdescribes the number of dipole coupled individual oscilla-tions localized on individual stripes, whose phases are effec-tively correlated according to the Bloch wave number q, im-
posed by the collective mode.
Numerical simulations of the BLS spectra, based on this
approach, have shown that the nth Bloch mode in strongly
coupled stripes contributes mainly to the scattering in the nth
Brillouin zone. This is not the case for weakly coupledstripes with higher values of interwire spacing. In such ge-ometries l
ccan decrease drastically and, as a result, for ex-
ample, the fundamental Bloch mode will contribute signifi-cantly to the scattering in several lowest Brillouin zones. Ourcalculations have also confirmed numerically the noncoher-ent wide-angle character of the BLS, demonstrated experi-mentally in Ref. 30.
ACKNOWLEDGMENTS
Support by the Australian Research Council and LPMTP,STOCHASTIC PROPERTIES AND BRILLOUIN LIGHT … PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-11Université Paris-13 is gratefully acknowledged.
APPENDIX
Let us try to estimate the correlation function, describing
the Langevin force exciting elliptically polarized Blochmodes, which is given below. This expression will be ex-tremely useful in the context of the main text of the paper
/H20855f
kn/H20849t/H20850fk/H11032n/H11032/H20849t/H11032/H20850/H11569/H20856=/H9275M2/H20851u/H20841k/H20841nu/H20841k/H11032/H20841n/H11032/H20855Rkn/H20849t/H20850Rk/H11032n/H11032/H20849t/H11032/H20850/H11569/H20856
+v/H20841k/H20841nv/H20841k/H11032/H20841n/H11032/H20855Rkn/H20849t/H20850/H11569Rk/H11032n/H11032/H20849t/H11032/H20850/H20856
+u/H20841k/H20841nv/H20841k/H11032/H20841n/H11032/H20855Rkn/H20849t/H20850Rk/H11032n/H11032/H20849t/H11032/H20850/H20856
+v/H20841k/H20841nu/H20841k/H11032/H20841n/H11032/H20855Rkn/H20849t/H20850/H11569Rk/H11032n/H11032/H20849t/H11032/H20850/H11569/H20856/H20852./H20849A1 /H20850Each particular correlation function, out of four, can be
evaluated independently. We will begin with the first and thethird.
/H20855R
kn/H20849t/H20850Rk/H11032n/H11032/H20849t/H11032/H20850/H11569/H20856=/H20885
−/H11009/H11009/H20885
−/H11009/H11009
dxdx /H11032mkn/H11569/H20849x/H20850mk/H11032n/H11032/H20849x/H11032/H20850
/H11003/H20855h/H20849th/H20850/H20849x,t/H20850h/H20849th/H20850/H11569/H20849x/H11032,t/H11032/H20850/H20856, /H20849A2a /H20850
/H20855Rkn/H20849t/H20850Rk/H11032n/H11032/H20849t/H11032/H20850/H20856=/H20885
−/H11009/H11009/H20885
−/H11009/H11009
dxdx /H11032mkn/H11569/H20849x/H20850mk/H11032n/H11032/H11569/H20849x/H11032/H20850
/H11003/H20855h/H20849th/H20850/H20849x,t/H20850h/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856. /H20849A2b /H20850
In Eq. /H20849A2 /H20850a key role is played by the averaged expressions
within the brackets,
/H20855h/H20849th/H20850/H20849x,t/H20850h/H20849th/H20850/H11569/H20849x/H11032,t/H11032/H20850/H20856=/H20855/H20851hx/H20849th/H20850/H20849x,t/H20850+ihy/H20849th/H20850/H20849x,t/H20850/H20852/H20851hx/H20849th/H20850/H20849x/H11032,t/H11032/H20850−ihy/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20852/H20856
=/H20855hx/H20849th/H20850/H20849x,t/H20850hx/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856+/H20855hy/H20849th/H20850/H20849x,t/H20850hy/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856+i/H20855hx/H20849th/H20850/H20849x,t/H20850hy/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856+/H20855hy/H20849th/H20850/H20849x,t/H20850hx/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856,
/H20849A3a /H20850
/H20855h/H20849th/H20850/H20849x,t/H20850h/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856=/H20855/H20851hx/H20849th/H20850/H20849x,t/H20850+ihy/H20849th/H20850/H20849x,t/H20850/H20852/H20851hx/H20849th/H20850/H20849x/H11032,t/H11032/H20850+ihy/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20852/H20856
=/H20855hx/H20849th/H20850/H20849x,t/H20850hx/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856−/H20855hy/H20849th/H20850/H20849x,t/H20850hy/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856+i/H20855hx/H20849th/H20850/H20849x,t/H20850hy/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856+/H20855hy/H20849th/H20850/H20849x,t/H20850hx/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856.
/H20849A3b /H20850
Here we used the expression of the Langevin force in circular polarizations h/H20849x,t/H20850=hx/H20849x,t/H20850+ihy/H20849x,t/H20850/H20851see Eq. /H208493/H20850/H20852. It should be
reminded that the Cartesian components of the thermal magnetic field are purely real. Making use of Eq. /H208492/H20850one can rewrite
Eq. /H20849A3 /H20850as
/H20855h/H20849th/H20850/H20849x,t/H20850h/H20849th/H20850/H11569/H20849x/H11032,t/H11032/H20850/H20856=2C/H9254/H20849x−x/H11032/H20850/H9254/H20849t−t/H11032/H20850, /H20849A4a /H20850
/H20855h/H20849th/H20850/H20849x,t/H20850h/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856=0 . /H20849A4b /H20850
Moreover
/H20855h/H20849th/H20850/H11569/H20849x,t/H20850h/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856=/H20855h/H20849th/H20850/H20849x,t/H20850h/H20849th/H20850/H11569/H20849x/H11032,t/H11032/H20850/H20856/H11569=2C/H9254/H20849x−x/H11032/H20850/H9254/H20849t−t/H11032/H20850, /H20849A4c /H20850
/H20855h/H20849th/H20850/H11569/H20849x,t/H20850h/H20849th/H20850/H11569/H20849x/H11032,t/H11032/H20850/H20856=/H20855h/H20849th/H20850/H20849x,t/H20850h/H20849th/H20850/H20849x/H11032,t/H11032/H20850/H20856/H11569=0 . /H20849A4d /H20850
Inserting Eqs. /H20849A4a /H20850and /H20849A4b /H20850in Eqs. /H20849A2a /H20850and /H20849A2b /H20850, respectively, one obtains
/H20855Rkn/H20849t/H20850Rk/H11032n/H11032/H20849t/H11032/H20850/H11569/H20856=2C/H9275M2/H20885
−/H11009/H11009/H20885
−/H11009/H11009
dxdx /H11032mkn/H11569/H20849x/H20850mk/H11032n/H11032/H20849x/H11032/H20850/H9254/H20849x−x/H11032/H20850/H9254/H20849t−t/H11032/H20850
=2C/H9275M2/H9254/H20849t−t/H11032/H20850/H20885
−/H11009/H11009
dxmkn/H11569/H20849x/H20850mk/H11032n/H11032/H20849x/H20850=2C/H9275M2/H9254/H20849t−t/H11032/H20850/H9254/H20849k−k/H11032/H20850/H9254nn/H11032, /H20849A5a /H20850
/H20855Rkn/H20849t/H20850Rk/H11032n/H11032/H20849t/H11032/H20850/H20856=0 . /H20849A5b /H20850
Similarly
/H20855Rkn/H20849t/H20850/H11569Rk/H11032n/H11032/H20849t/H11032/H20850/H20856=/H20855Rkn/H20849t/H20850Rk/H11032n/H11032/H20849t/H11032/H20850/H11569/H20856/H11569=2C/H9275M2/H9254/H20849t−t/H11032/H20850/H9254/H20849k−k/H11032/H20850/H9254nn/H11032, /H20849A5c /H20850
/H20855Rkn/H11569/H20849t/H20850Rk/H11032n/H11032/H11569/H20849t/H11032/H20850/H20856=/H20855Rkn/H20849t/H20850Rk/H11032n/H11032/H20849t/H11032/H20850/H20856/H11569=0 . /H20849A5d /H20850
Inserting Eqs. /H20849A5a /H20850–/H20849A5d /H20850into Eq. /H20849A1 /H20850and taking into account the orthonormality of the eigenfunctions Eq. /H208497/H20850one finally
obtainsM. P. KOSTYLEV AND A. A. STASHKEVICH PHYSICAL REVIEW B 81, 054418 /H208492010 /H20850
054418-12/H20855fkn/H20849t/H20850fk/H11032n/H11032/H20849t/H11032/H20850/H11569/H20856=/H20851u/H20841k/H20841nu/H20841k/H11032/H20841n/H110322C/H9275M2/H9254/H20849t−t/H11032/H20850/H9254/H20849k−k/H11032/H20850/H9254nn/H11032+v/H20841k/H20841nv/H20841k/H11032/H20841n/H110322C/H9275M2/H9254/H20849t−t/H11032/H20850/H9254/H20849k−k/H11032/H20850/H9254nn/H11032/H20852
=2C/H9275M2/H9254/H20849t−t/H11032/H20850/H9254/H20849k−k/H11032/H20850/H9254nn/H11032/H20849u/H20841k/H20841n2+v/H20841k/H20841n2/H20850=2AC/H9275M2
/H9275/H20841k/H20841n/H9254/H20849t−t/H11032/H20850/H9254/H20849k−k/H11032/H20850/H9254nn/H11032. /H20849A6 /H20850
Similar calculations are applicable for the correlation function in the frequency domain
/H20855fkn/H20849/H9275/H20850fk/H11032n/H11032/H11569/H20849/H9275/H20850/H20856=/H9275M2/H20877u/H20841k/H20841nu/H20841k/H11032/H20841n/H11032/H20885
−/H11009/H11009/H20885
−/H11009/H11009
mkn/H20849x/H20850/H11569mk/H11032n/H11032/H20849x/H11032/H20850/H20855/H20851hx/H20849th/H20850/H20849x,/H9275/H20850+ihy/H20849th/H20850/H20849x,/H9275/H20850/H20852/H20851hx/H20849th/H20850/H20849x/H11032,/H9275/H20850−ihy/H20849th/H20850/H20849x/H11032,/H9275/H20850/H20852/H20856dxdx /H11032
+v/H20841k/H20841nv/H20841k/H11032/H20841n/H11032/H20885
−/H11009/H11009/H20885
−/H11009/H11009
mkn/H20849x/H20850mk/H11032n/H11032/H20849x/H11032/H20850/H11569/H20855/H20851hx/H20849th/H20850/H20849x,/H9275/H20850−ihy/H20849th/H20850/H20849x,/H9275/H20850/H20852/H20851hx/H20849th/H20850/H20849x/H11032,/H9275/H20850+ihy/H20849th/H20850/H20849x/H11032,/H9275/H20850/H20852/H20856dxdx /H11032
+u/H20841k/H20841nv/H20841k/H11032/H20841n/H11032/H20885
−/H11009/H11009/H20885
−/H11009/H11009
mkn/H20849x/H20850/H11569mk/H11032n/H11032/H20849x/H11032/H20850/H11569/H20855/H20851hx/H20849th/H20850/H20849x,/H9275/H20850+ihy/H20849th/H20850/H20849x,/H9275/H20850/H20852/H20851hx/H20849th/H20850/H20849x/H11032,/H9275/H20850+ihy/H20849th/H20850/H20849x/H11032,/H9275/H20850/H20852/H20856dxdx /H11032
+v/H20841k/H20841nu/H20841k/H11032/H20841n/H11032/H20885
−/H11009/H11009/H20885
−/H11009/H11009
mkn/H20849x/H20850mk/H11032n/H11032/H20849x/H11032/H20850/H20855/H20851hx/H20849th/H20850/H20849x,/H9275/H20850−ihy/H20849th/H20850/H20849x,/H9275/H20850/H20852/H20851hx/H20849th/H20850/H20849x/H11032,/H9275/H20850−ihy/H20849th/H20850/H20849x/H11032,/H9275/H20850/H20852/H20856dxdx /H11032/H20878
which leads finally to
/H20855fkn/H20849/H9275/H20850fk/H11032n/H11032/H11569/H20849/H9275/H20850/H20856=2AC/H9275M2
/H9275/H20841k/H20841n1/H20849/H9275/H20850/H9254/H20849k−k/H11032/H20850/H9254nn/H11032. /H20849A7 /H20850
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054418-14 |
PhysRevLett.124.117202.pdf | Coherent Spin Pumping in a Strongly Coupled Magnon-Magnon Hybrid System
Yi Li,1,2Wei Cao ,3Vivek P. Amin,4,5Zhizhi Zhang ,2,6Jonathan Gibbons,2Joseph Sklenar,7John Pearson ,2
Paul M. Haney,5Mark D. Stiles,5William E. Bailey,3,*Valentine Novosad,2Axel Hoffmann,2,‡and Wei Zhang1,2,†
1Department of Physics, Oakland University, Rochester, Michigan 48309, USA
2Materials Science Division, Argonne National Laboratory, Argonne, Illinois 60439, USA
3Materials Science and Engineering, Department of Applied Physics and Applied Mathematics, Columbia University,
New York, New York 10027, USA
4Maryland Nanocenter, University of Maryland, College Park, Maryland 20742, USA
5Physical Measurement Laboratory, National Institute of Standards and Technology, Gaithersburg, Maryland 20899, USA
6School of Optical and Electronic Information, Huazhong University of Science and Technology, Wuhan 430074, China
7Department of Physics and Astronomy, Wayne State University, Detroit, Michigan 48202, USA
(Received 1 September 2019; accepted 23 January 2020; published 17 March 2020)
We experimentally identify coherent spin pumping in the magnon-magnon hybrid modes of yttrium iron
garnet/permalloy (YIG/Py) bilayers. By reducing the YIG and Py thicknesses, the strong interfacial
exchange coupling leads to large avoided crossings between the uniform mode of Py and the spin wavemodes of YIG enabling accurate determination of modification of the linewidths due to the dampinglike
torque. We identify additional linewidth suppression and enhancement for the in-phase and out-of-phase
hybrid modes, respectively, which can be interpreted as concerted dampinglike torque from spin pumping.Furthermore, varying the Py thickness shows that both the fieldlike and dampinglike couplings vary like
1=ffiffiffiffiffiffit
Pyp, verifying the prediction by the coupled Landau-Lifshitz equations.
DOI: 10.1103/PhysRevLett.124.117202
Coherent phenomena have recently become an emerging
topic for information processing with their success inquantum computing [1,2]. In spintronics, exchange-
induced magnetic excitations, called spin waves, or mag-nons [3,4], are good candidates for coherent information
processing where information can be encoded by both the
amplitude and the phase of spin waves. For example, theinterference of coherent spin waves can be engineered forspin wave logic operations [5–7], the coherent interaction
of spin-torque oscillators leads to mutual synchronization[8–13], which can be applied in artificial neural networks
[14,15] . and the coherent coupling between magnons and
microwave cavities [16–23]opens up new opportunities for
magnon-based quantum information science [24,25] .
Recently, strong coupling between two magnonic
systems has enabled excitations of forbidden spin wavemodes [26–28]and high group velocity of propagating spin
waves [29,30] . The coupling is dominated by the exchange
interaction at the interface of the magnetic bilayers,
providing a new pathway to coherently transfer magnon
excitations between two magnetic systems possessingdistinctive properties: from conductor to insulator, fromuniform to nonuniform mode, and from high-damping tolow-damping systems. However, the underlying physicalmechanisms of the coupling are still not fully understood.
First, what are the key parameters that dictate the coupling
efficiency and enable one to reach the strong-couplingregime? Second, with the interfacial exchange couplingacting as a fieldlike torque, is there a dampinglike torque
associated with spin pumping [31–34]? To resolve both
questions, large separations of the two hybrid modes arerequired in order to quantitatively analyze the coupling
mechanism. The second question is also important for
optimizing the coherence of spin wave transfer in hybridsystems. Furthermore, the parasitic effect on the incoherentspin current from the conduction band is absent [35–37]
when using magnetic insulators such as yttrium iron garnet(Y
3Fe5O12, YIG) [30,38,39] , which facilitates the study of
spin pumping coherency.
In this work, we study YIG/permalloy (Ni 80Fe20, Py)
bilayers. By using much thinner YIG and Py films than
studied in previous works [26,28] , we achieve an exchange-
induced separation of the two hybrid modes much larger
than their linewidths, allowing us to study the evolution of
their linewidths in the strong-coupling regime. We find apronounced suppression of the total linewidth for the in-
phase hybrid modes and a linewidth enhancement for the
out-of-phase hybrid modes. The linewidths can be under-
stood from the Landau-Lifshitz-Gilbert (LLG) equation
with interfacial exchange coupling and mutual spin pump-
ing, which provide the fieldlike and dampinglike interlayer
coupling torques, respectively. Furthermore, the thicknessdependence of the two coupling strengths agrees with the
modeling of coupled LLG equations with mutual spin
pumping. The sign of the fieldlike torque also reconfirms
that the YIG and Py are coupled antiferromagnetically [26].
Our results provide important insights for improving thePHYSICAL REVIEW LETTERS 124, 117202 (2020)
0031-9007 =20=124(11) =117202(6) 117202-1 © 2020 American Physical Societycoupling strength and coherence in magnon-magnon hybrid
systems and pave the way for coherent information process-
ing with exchange-coupled magnetic heterostructures.
The samples consist of YIG ð100nmÞ=PyðtPyÞbilayers
where tPyvaries from 5 to 60 nm. YIG(100 nm) films were
deposited by magnetron sputtering from a YIG target onto
Gd3Ga5O12ð111Þsubstrates and annealed in air at 850°C
for 3 h to reach low-damping characteristics [40]. Before
the deposition of Py films on top of YIG, the YIG surfaces
were ion milled in situ for 1 min in order to enable good
exchange coupling between Py and YIG [41]. For each Py
thickness, one additional reference Py film was deposited
on a Si =SiO 2substrate during the same deposition.
The hybrid magnon dynamics were characterized by
broadband ferromagnetic resonance with field modulationon a coplanar waveguide [Fig. 1(a)]. An in-plane magnetic
field H
Bsaturates both the YIG and Py magnetizations. Their
Kittel modes, which describe spatially uniform magnetization
precession, are formulated as ω2=γ2¼μ2
0HrðHrþMsÞ,
where ωis the mode frequency, γ=2π¼ðgeff=2Þ×
27.99GHz=T is the gyromagnetic ratio, Hris the resonancefield, and Msis the magnetization [42]. For YIG, the spatially
nonuniformperpendicularstandingspinwave(PSSW)modes
can also be measured. An effective exchange field Hexwill
lower the resonance field by μ0HexðkÞ¼ð 2Aex=M sÞk2,
where Aexis the exchange stiffness, k¼nπ=t,nlabels the
index of PSSW modes, and tis the film thickness [43].
Figure 1(b)shows the line shapes of the resonance fields
for the first three resonance modes of YIG ( n¼0, 1, 2) and
the Py uniform mode ( n¼0) measured for tPy¼9nm. For
illustration, the YIG ( n¼0) resonance is shifted to zero
field. An avoided crossing is clearly observed when the
Py uniform mode is degenerate with the YIG ( n¼2) mode.
This is due to the exchange coupling at the YIG/Py interface
[26–28]providing a fieldlike coupling torque. Both in-phase
and out-of-phase YIG/Py hybrid modes are strongly excitedbecause the energy of the Py uniform mode is coherentlytransferred to the YIG PSSW modes through the interface
[26]. The full-range frequency dependencies of the extracted
resonance fields are plotted in Fig. 1(c). To analyze the two
hybrid modes, we analyze our results with two independent
Lorentzians because it facilitates a transparent physical
picture and the fit line shapes agree well with our measure-ments. The mode crossing happens at ω
c=2π¼9.4GHz
(black dashed line), which corresponds to the minimal
resonance separation of the two hybrid modes. Fitting
to the Kittel equation, we extract μ0MYIGs¼0.21T,
μ0MPy
s¼0.86T. From the exchange field offset as shown
in Fig. 1(b), an exchange stiffness Aex¼2.6pJ=mi s
calculated for YIG, which is similar to previous reports [44].
The avoided crossing can be fitted to a phenomenologi-
cal model of two coupled harmonic oscillators, as pre-viously shown in magnon polaritons [16–18,20] :
μ
0H/C6c¼μ0HYIGrþHPy
r
2/C6ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi ffi/C18
μ0HYIGr−HPy
r
2/C192
þg2cs
;ð1Þ
where HYIGðPyÞ
r is the resonance field of YIG (Py) and gcis
the interfacial exchange coupling strength. HYIGrandHPy
r
are both functions of frequency and are equal at ωc. Note
that for in-plane biasing field, the resonance field isnonlinear to the excitation frequency. This nonlinearity
will be accounted for in the analytical reproduction of
Eq.(1). The fitting yields g
c¼8.4mT for tPy¼9nm.
Next, we focus on the linewidths of the YIG-Py
hybrid modes. Figure 2(a) shows the line shape of the
two hybrid modes for tPy¼7.5nm at ωc=2π¼9.4GHz
(same value as for 9-nm Py). These two eigenmodescorrespond to the in-phase and out-of-phase magnetization
precession of Py and YIG with the same weight, so they
should yield the same total intrinsic damping. Nevertheless,a significant linewidth difference is observed, with the
extracted full width at half maximum linewidth μ
0ΔH1=2
varying from 3.5 mT for the lower field resonance to
8.0 mT for the higher field resonance. Figure 2(b) shows(a) (b)
(c)
FIG. 1. (a) Illustration of the magnetization excitations in the
YIG/Py bilayer with a coplanar waveguide. (b) Line shapes of theYIGð100nmÞ=Pyð9nmÞsample for the first three resonance
modes of YIG and the uniform mode of Py. The field axis isshifted so that the resonance field of the YIG ðn¼0Þmode is
zero. (c) Unshifted evolution of the four modes in (b). Curvesshow the fits as uncoupled modes. The vertical dashed line
denotes where the YIG ðn¼2Þand Py ðn¼0Þmodes cross on
the frequency axis at ω
c=2π¼9.4GHz.PHYSICAL REVIEW LETTERS 124, 117202 (2020)
117202-2the full-range evolution of the linewidth. Compared with
the dotted lines which are the linear extrapolations of the
YIG ( n¼2) and Py linewidths, the linewidth of the higher-
field hybrid mode (blue circles) exceeds the Py linewidth
and the linewidth of the lower-field hybrid mode (green
circles) reduces below the YIG linewidth when the fre-quency is near ω
c. This is the central result of this Letter. It
suggests a coherent dampinglike torque which acts along or
against the intrinsic damping torque depending on the
phase difference of the coupled dynamics of YIG and Py,the same as the fieldlike torque acting along or against the
Larmor precession. The dominant mechanism for the
dampinglike torque is the spin pumping from the concerteddynamics of YIG and Py [31,32] .
Because spin pumping is dissipative, we determine the
mode with a broader (narrower) linewidth as the out-of-
phase (in-phase) precession mode. In Fig. 2(a)the broader-
linewidth mode exhibits a higher resonance field than thenarrower-linewidth mode. This is a signature of antiferro-
magnetic exchange coupling at the YIG/Py interface [26].
From the resonance analysis we also find that all theSiO
2=Py samples show lower resonance fields than the
Py samples grown on YIG [45], which agrees with the
antiferromagnetic nature of the YIG/Py interfacial coupling.
To reproduce the data in Fig. 2(b), we introduce the
linewidths as the imaginary parts of the resonance fields in
Eq.(1):μ0ðH/C6cþiΔH/C6
1=2Þ
¼μ0HYIGrþHPy
r
2þiμ0κYIGþκPy
2
/C6ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi/C18
μ0HYIGr−HPy
r
2þiμ0κYIG−κPy
2/C192
þ˜g2cs
; ð2Þ
where κYIGðPyÞis the uncoupled linewidth of YIG (Py) from
the linear extraction (dotted lines) in Fig. 2(b), and ˜gc¼
gcþiκcis the complex interfacial coupling strength with an
additional dampinglike component κcfrom spin pumping.
In order to show the relationship between the spin pumpingfrom the coherent YIG-Py dynamics and the incoherent spin
pumping from the individual Py dynamics, we identify the
latter as the linewidth enhancement of Py(7.5 nm), ΔHPy
sp,
between the linearly extrapolated YIG/Py [red dots in
Fig.2(b)] and Si =SiO 2=Py [red stars in Fig. 2(b)]. Then,
we quantify the coherent dampinglike coupling strength κc
asκcðωÞ¼βμ0ΔHPy
spðωÞ, where βis a unitless and fre-
quency-independent value measuring the ratio between the
coherent and incoherent spin pumping. For the best fit value,
β¼0.82, Eq. (2)nicely reproduces the data in Fig. 2(b).F o r
comparison, if we set κcðωÞ¼0in Eq. (2), we obtain the
blue and green dashed curves, which result in identical
linewidth at ωcas opposed to the data in Fig. 2(a).
In order to understand the physical meaning of ˜gc,w e
consider the coupled LLG equations of the YIG/Py bilayer[26,32,34] in the macrospin limit:
dmi
dt¼−μ0γimi×Heffþαimi×dmi
dt−γimi×J
Mitimj
þΔαi/C18
mi×dmi
dt−mj×dmj
dt/C19
; ð3Þ
wheremi;jis the unit magnetization vector, Heffis the
effective field including HB,Hex, and the demagnetizing
field, and αiis the intrinsic Gilbert damping. The index is
defined as ði; jÞ¼ð 1;2Þor (2,1). In the last two coupling
terms, Jis the interfacial exchange energy and Δαi¼
γiℏg↑↓=ð4πMitiÞis the spin pumping damping enhance-
ment with g↑↓the spin mixing conductance. The two terms
provide the fieldlike and dampinglike coupling torques,respectively, between m
iandmj. To view the dampinglike
coupling on a similar footing, we define its coupling energy
J0as
J0ðωÞ¼g↑↓
4πℏω: ð4Þ
Here J0describes the number of quantum channels per unit
area ( g↑↓) for magnons ( ℏω) to pass through [31,34] ;
similarly, Jdescribes the number and strength of exchange
bonds between YIG and Py per unit area. From the
definition, we can express the spin pumping linewidth(a)
(b)
FIG. 2. (a) The line shape of the YIG ð100nmÞ=Pyð7.5nmÞ
sample at ωc=2π¼9.4GHz, showing different linewidths be-
tween the two hybrid modes of YIG ðn¼2Þand Py ðn¼0Þ
resonances. (b) Linewidths of the two hybrid modes as a functionof frequency. Dotted lines show the linear fit of the linewidthsfor the two uncoupled modes. Dashed curves show the theo-retical values with κ
c¼0. Solid curves show the fits with finite κc.PHYSICAL REVIEW LETTERS 124, 117202 (2020)
117202-3enhancement as μ0ΔHispðωÞ¼J0ðωÞ=M iti, in pair with the
exchange field term in Eq. (3). By solving Eq. (3)we find
κiðωÞ¼αiω
γiþJ0ðωÞ
Miti; ð5aÞ
gc¼fðωcÞffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
J
M1t1J
M2t2s
; ð5bÞ
κcðωcÞ¼fðωcÞffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
J0ðωcÞ
M1t1J0ðωcÞ
M2t2s
; ð5cÞ
with the dimensionless factor fðωÞaccounting for the
precession elliptical asymmetry. fðωÞ¼1for identical
ellipticity ( M1¼M2) and fðωcÞ¼0.9in the case of
YIG and Py; see the Supplemental Material for details [45].
Equation (5)shows that both gcandκcðωcÞare propor-
tional to 1=ffiffiffitip, which comes from the geometric averaging
of the coupled magnetization dynamics. This is in contrast to
the1=tidependence of the uncoupled exchange field and
spin pumping damping enhancement for a single layer, ass h o w ni nE q . (5a).I nF i g . 3(a), a good fitting of g
cto1=ffiffiffiffiffiffitPyp
rather than 1=tPyvalidates the model. In the limit of zero Py
thickness, the model breaks down due to the significance of
boundary pinning and the assumption of macrospin dynam-
ics, as reflected in the reduction of gcattPy¼5nm.
For the dampinglike coupling, we plot βinstead as a
function of tPyin order to minimize the variation in the
quality of interfacial coupling and the frequency depend-
ence of κcðωcÞ. By taking the ratio between κcðωcÞand
μ0ΔHPy
spðωcÞfrom the analytical model, we obtain the
macrospin expression β¼fðωcÞffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi ffiMPytPy=M YIGtYIGpwith
fðωcÞ¼0.9. Figure 3(b)shows that the extracted β2varies
linearly with tPy, rather than being independent of it aswould be expected for incoherent spin pumping. The fit is
not perfect, which may be caused by (i) the variation of
inhomogeneous broadening of Py in YIG/Py bilayers or(ii) the multipeak line shapes in YIG [see YIG n¼0line
shapes in Fig. 1(b)] due to possible damage during the ion
milling process.
If we calculate βfrom the macrospin approximation, the
prediction, shown in the red dashed arrow in Fig. 3(b),
differs significantly from the experimental data. To accountfor the difference, we consider a spin wave model for the
YIG/Py bilayer, where finite wave numbers exist in both
layers and are determined from the boundary condition[46]. For simplicity, we consider free pinning at the two
exterior surfaces of YIG and Py and Hoffmann exchange
boundary conditions for the interior interface of YIG/Py[47]. From the spin wave model, we find an additional
factor offfiffiffi
2p
in Eqs. (5b) and(5c); see the Supplemental
Material for details [45]. This factor arises because the
nonuniform profile of the PSSW mode in YIG reduces
the effective mode volume by a factor of 2 compared with
the uniform mode. A similar effect has been previouslydiscussed in spin pumping from PSSW modes [48,49] .I n
Fig. 3(b) the theoretical calculation from the spin wave
model (cyan dashed arrow) is close to the experimentalvalues. This is an additional evidence of the coherent spin
pumping in YIG/Py bilayers.
Figure 4compares the values of Jand J
0obtained
from the hybrid dynamics. For convenience we esti-
mate the value of J0from Eq. (5c),a s J0ðωcÞ¼
κcðωcÞ=fðωcÞffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiMYIGtYIGMPytPy=2p. Noting the frequency
(a) (b)
FIG. 3. (a) Extracted gcas a function of tPy. (b) Extracted β2as
a function of tPy. In both panels, the solid and dashed curves are
the fits of data to the coherent and incoherent models, respec-
tively. In (b), the red and cyan dotted arrows show the theoreticalpredictions for the coherent models based on the macrospin andspin wave approximations, respectively. Error bars indicate singlestandard deviations found from the fits to the line shape.FIG. 4. Thickness dependence of J(circles) and J0ðωcÞ(tri-
angles), which are calculated from gcandκcðωcÞ, respectively.
Blue points denote the results for YIG ð100nmÞ=PyðtPyÞand red
points for YIG ð50nmÞ=PyðtPyÞ. The blue stars denote J0spðωcÞ,i n
which ΔHPy
spðωcÞis calculated from the Py linewidth enhance-
ment from Py ðtPyÞto YIG ð100nmÞ=PyðtPyÞ. Error bars indicate
single standard deviations found from the fits to the line shape.PHYSICAL REVIEW LETTERS 124, 117202 (2020)
117202-4dependence of J0ðωÞ, all the values of J0ðωÞin this work are
obtained around ωc=2π¼9GHz. We can also calculate
J0ðωcÞfrom the uncoupled spin pumping effect, as
J0spðωcÞ¼μ0ΔHPy
spðωcÞMPytPy. For the YIG/Py interface,
the value of Jstays at the same level; the value of J0ðωcÞ
fluctuates with samples but is well aligned with J0spðωcÞ,
which again supports that the dampinglike interfacial
coupling comes from spin pumping. Furthermore, we
have also repeated the experiments for a thinnerYIGð50nmÞ=PyðtÞsample series and obtained similar
values of JandJ
0ðωcÞ, as shown in Fig. 4.
Table Isummarizes the values of J,J0, and g↑↓for the
YIG/Py interface, where J0is taken from the vicinity of
ωc=2π¼9GHz and g↑↓is calculated from J0ðωcÞby
Eq.(4). The value of Jis much smaller than a perfect
exchange-coupled interface, which is not surprising giventhe complicated and uncharacterized nature of the YIG/Pyinterface. For Py, the interfacial exchange energy can be
estimated [46] by2A
ex=a, where for Py Aex¼12pJ=m
[49] and the lattice parameter a¼0.36nm. We find
2Aex=a¼68mJ=m2, 3 orders of magnitude larger than
J. Comparing with similar interfaces, our reported Jis
similar to YIG/Ni ( 0.03mJ=m2[27]) and smaller than
YIG/Co ( 0.4mJ=m2[26]). A different interlayer exchange
coupling from Ruderman-Kittel-Kasuya-Yosida interaction
may generate a larger J[50–52]but a smaller g↑↓[53].
There could also be a fieldlike contribution of Jfrom g↑↓
[23,26,54 –56]. But since the exchange Jdominates in the
coupled dynamics, it is difficult to distinguish the spinmixing conductance contribution in our experiments.
In conclusion, we have characterized the dampinglike
coupling torque between two exchange-coupled ferromag-
netic thin films. By exciting the hybrid dynamics in the
strong-coupling regime, this dampinglike torque can eitherincrease or suppress the total damping in the out-of-phase
or in-phase mode, respectively. The origin of the damp-
inglike torque is the coherent spin pumping from thecoupling magnetization dynamics. Our results reveal newinsight for tuning the coherence in magnon-magnon hybrid
dynamics and are important for magnon-based coherent
information processing.
Work at Argonne on sample preparation was supported by
the U.S. DOE, Office of Science, Office of Basic EnergySciences, Materials Science and Engineering Division under
Contract No. DE-AC02-06CH11357, while work at
Argonne and National Institute of Standards andTechnology (NIST) on data analysis and theoreticalmodeling was supported as part of Quantum Materials for
Energy Efficient Neuromorphic Computing, an Energy
Frontier Research Center funded by the U.S. DOE,Office of Science. Work on experimental design atOakland University was supported by AFOSR
under Grant No. FA9550-19-1-0254 and the NIST
Center for Nanoscale Science and Technology, AwardNo. 70NANB14H209, through the University ofMaryland. Work on microwave spectroscopy at Columbia
University was supported by NSF under Grant No. NSF-
DMR1411160.
*web54@columbia.edu
†weizhang@oakland.edu
‡Current address: Department of Materials Science and
Engineering, University of Illinois at Urbana-Champaign,Urbana, IL 61801, USA.axelh@illinois.edu
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117202-6 |
PhysRevB.95.054422.pdf | PHYSICAL REVIEW B 95, 054422 (2017)
Spin transfer and spin-orbit torques in in-plane magnetized (Ga,Mn)As tracks
L. Thevenard,1,*B. Boutigny,1N. G ¨usken,1L. Becerra,1C. Ulysse,2S. Shihab,1A. Lema ˆıtre,2
J.-V . Kim,2V . Jeudy,3and C. Gourdon1
1Sorbonne Universit ´es, UPMC Univ Paris 06, CNRS, Institut des Nanosciences de Paris, 4 place Jussieu, 75252 Paris, France
2Centre de Nanosciences et de Nanotechnologies, CNRS, Univ. Paris-Sud, Universit ´e Paris-Saclay, 91460 Marcoussis, France
3Laboratoire de Physique des Solides, CNRS - Universit ´e Paris-Sud, b ˆat. 510, 91405 Orsay, France
(Received 15 October 2016; revised manuscript received 10 January 2017; published 16 February 2017)
Current-driven domain wall motion is investigated experimentally in in-plane magnetized (Ga,Mn)As tracks.
The wall dynamics is found to differ in two important ways with respect to perpendicularly magnetized(Ga,Mn)As: the wall mobilities are up to ten times higher and the walls move in the same direction as thehole current. We demonstrate that these observations cannot be explained by spin-orbit field torques (Rashba andDresselhaus types) but are consistent with nonadiabatic spin transfer torque enhanced by the strong spin-orbitcoupling of (Ga,Mn)As. This mechanism opens the way to domain wall motion driven by bulk rather thaninterfacial spin-orbit coupling as in ultrathin ferromagnet/heavy metal multilayers.
DOI: 10.1103/PhysRevB.95.054422
I. INTRODUCTION
Nonvolatile memory and logic devices based on magnetic
domain-wall (DW) manipulation [ 1,2] remain technologically
challenging as they require narrow DWs, large velocities,and low voltage/current density operation, features that aredifficult to combine in a given material. This has led toconstant endeavors to optimize the torques experienced byDWs under an applied current. Initial works focused on spintransfer torques (STT [ 3–7]). Recently, torques originating
from the spin-orbit interaction (SOI) have been evidencedin ferromagnetic/nonmagnetic multilayers [ 8–14]. The
mechanisms involved in DW propagation are still partiallyunder debate, but signatures of the Rashba effective field,the spin Hall effect, and the chiral Dzyaloshinskii-Moriyainteraction (DMI) have been suggested [ 8,11,15,16].
These observations have been limited to out-of-planemagnetized heavy metal/metallic ferromagnet combinations(Pt/Co/AlOx,GdOx or Gd [ 13,17], Pt/Co/Ni/Co [ 12], Pt/ or
Ta/CoFe/MgO [ 11,14]), in which the main source of SOI was
interfacial inversion asymmetry along the sample normal z.
The purpose of this work is to investigate experimentally thecase of a ferromagnet that is its own source of (bulk) spin-orbitinteraction, without relying on adjacent layers. For this, westudied the dilute magnetic semiconductor (Ga,Mn)As, inwhich the complex anisotropy and rich spin-orbit couplingphysics enable numerous configurations to be tested.
In (Ga,Mn)As, spin-orbit coupling gives rise to two effects
very different in magnitude. The main one is described by theKohn-Luttinger (KL) Hamiltonian. It splits the manifold ofvalence states with L=1 orbital quantum number and S=
1/2 spin into J=3/2 and J=1/2 states with J=L+S
[18]. For nonzero kwave vectors, the J=3/2 states are further
split into heavy hole ( J=±3/2) and light hole ( J=±1/2)
states, each with twofold degeneracy. The second and muchweaker effect is a lifting of this degeneracy analogous to ak-dependent magnetic field. This small spin-orbit effect arises
from the lack of centrosymmetry of the zinc-blende lattice
*thevenard@insp.jussieu.fr(k3Dresselhaus term). A further lowering of the symmetry
induced by epitaxial strain ( ε) yields a Dresselhaus term linear
ink. An even weaker Rashba term, also linear in k, exists due
to the nonequivalence of [110] and [1 ¯10] directions induced
during the growth [ 19], formally equivalent to an in-plane shear
strain or an electric field perpendicular to the interface [ 18].
This is reminiscent of the one encountered in the z-asymmetric
metallic stacks mentioned earlier.
These spin-orbit effects have two consequences. First, the
heavy-light hole splitting modifies the usual spin transfertorques in the presence of a domain wall since valence statesare not pure spin states. A significant hole reflection should oc-cur at the domain wall, resulting in spin accumulation [ 20–22].
The resulting spin transfer torque is expected to be up to tenfoldmore efficient than the standard torque but has up to now notbeen evidenced experimentally. Secondly, Rashba or Dressel-haus spin-orbit splittings of the valence bands result, under cur-rent, in an out-of-equilibrium hole spin polarization. The anti-ferromagnetic exchange interaction between the carrier spinsand the Mn spins then yields corresponding effective spin-orbitfields on the magnetization [ 23–26]. These fields have been
evidenced experimentally [ 27–30] to be in-plane and perpen-
dicular to the current density, but their effect on DWP remainsto be shown. Note that these terms are about 100 times weakerthan the Rashba term in metals which were claimed to beresponsible for fast DWP against the electron direction [ 9,13].
To explore these spin-orbit interaction effects, we have
worked on in-plane magnetized (Ga,Mn)As tracks, a configu-ration that has been rarely studied up to now [ 31,32]. We show
that DWs propagate at high mobilities under current and oppo-site to the direction given by the spin-transfer torque observedin out-of-plane magnetized (Ga,Mn)As [ 33–37], a radically
different phenomenology. We demonstrate our observations tobe only partially reconcilable with SO field torques. We sug-gest instead that they may be a signature of the Kohn-LuttingerHamiltonian-induced spin accumulation at the domain wall.
II. SAMPLES AND EXPERIMENTAL SETUP
DW propagation was studied on a 50 nm thick epilayer
of (Ga,Mn)As grown on (001) GaAs. After an 8 h /200◦C
2469-9950/2017/95(5)/054422(10) 054422-1 ©2017 American Physical SocietyL. THEVENARD et al. PHYSICAL REVIEW B 95, 054422 (2017)
FIG. 1. (a),(b) Two track configurations and device schematics: the hole current (red arrows) flows either parallel (C //) or perpendicular
(C⊥) to the magnetization (dark arrows) whose easy direction is along the crystallographic axis [1 ¯10]. With the reservoir grounded, the hole
current direction shown in this schematics therefore results from a negative potential applied to the opposite tip of the track. The hydrogenated
(Ga,Mn)As:H has turned paramagnetic, thus defining the stripe. (c),(g),(j) Phenomenology of current-induced DW motion. The effective
spin-orbit field ( /vectorHSO) is the sum of the Rashba and the Dresselhaus contributions (see text). (d)–(f) and (h),(i) Longitudinal Kerr microscopy
images (divided by a reference image taken after saturation) showing domain wall displacements under the application of successive current
pulses (1 ,2, etc.). The white dotted lines are guides for the eyes and the black dashed ones materialize the edges of the track and reservoir.
(d)–(f) 2 μmw i d eC //track, 70 ns long current pulses of J=24.5G Am−2under μ0H=1.1m T( Teff=40 K). (h) 10 μmw i d eC ⊥track,
120 ns long current pulses of J=14.9G Am−2,n oa p p l i e dfi e l d( Teff=80 K). A domain is easily nucleated in the middle of the track under
current by /vectorHSO(pulses 1 and 5). (i) 2 μmw i d eC ⊥track, 100 ns long current pulses of J=23.5G Am−2under μ0H=1.3m T( Teff=50 K).
anneal, the Curie temperature reached T C=116 K and
the magnetically active Mn concentration x=3.7%. The
layer was grown under compressive strain, which led to themagnetization lying in the plane. SQUID magnetometry andcavity ferromagnetic resonance (FMR) evidenced a uniaxialmagnetic anisotropy with the easy axis along the [1 ¯10]
direction.
The tracks were 2, 4, and 10 μm wide and 95 μm long,
oriented either parallel to the easy axis—“C
//” configuration—
or perpendicular to it—“C ⊥” configuration, with one end
leading into a large grounded reservoir [Figs. 1(a) and1(b)].
The reservoir and tracks were patterned by locally passivatingthe layer at 130
◦C using a hydrogen plasma over a Ti
mask [ 38]. This selectively turns the (Ga,Mn)As paramagnetic,
whilst maintaining the bidimensionality of the layer, thuslimiting diffraction-related imaging issues. It also preventsthe lattice from relaxing perpendicular to the track, whichwould pull the easy axis towards the track direction [ 32],
and therefore render C
//and C ⊥configurations nonequivalent
anisotropywise. Finally, Cr(10 nm) /Au(200 nm) contacts were
thermally evaporated on the sample. Domains were observedwith an in-house built longitudinal Kerr microscope, using aλ=635 nm LED source [ 39]. A generator was used to apply
a continuous or pulsed voltage.
In (Ga,Mn)As, Rashba and Dresselhaus spin-orbit fields are
positively (negatively) collinear for J//[110] ( J//[1¯10]//x),
with the total SO effective field /vectorH
SOlying transverse to the
tracks [Figs. 1(c) and1(g)]. The field intensity for J//[110]
is about three times larger than for J//[1¯10] [ 27–30]. This
geometry is distinct from those explored in metallic structuresin two respects: (i) the spin-orbit effect is generated in themagnetic layer itself, and does not require a distinct high-SOImaterial next to it; (ii) the spin-orbit field can be eitherperpendicular or collinear to the magnetization, a configurationthat has not been explored in DWP yet due to the lackof strongly uniaxial in-plane metals subject to spin-orbitfields [ 40].
III. PHENOMENOLOGY
We first describe the DW propagation phenomenology
under field and current [Figs. 1(c)–1(j)]. After saturation by
an external field Hsat, a reversed domain was nucleated by a
high current pulse. In the narrowest, 2 and 4 μm wide tracks,
054422-2SPIN TRANSFER AND SPIN-ORBIT TORQUES IN IN- . . . PHYSICAL REVIEW B 95, 054422 (2017)
DWs required a small field opposite to Hsatto depin. Under
this small field only, note that the DWs did not move. Inthe 10 μm track, the pinning of DWs was sufficiently low
to enable current-induced motion without external magneticfield. In the C
//track [see Figs. 1(d)–1(f)], we observed that
DWs only depin in the hole current direction, regardless ofthe DW charge (tail-to-tail or head-to-head), as summarized inFig.1(c). Holes flow in the same direction as the conventional
current, i.e., opposite the electrons. We will for now call thiseffect “STT-like”, and suppose the DW feels a local field
/vectorH
STT oriented parallel to the easy axis. In the C ⊥tracks,
the DW behavior is more complex [see Figs. 1(h) and1(i)],
and seems to consist of two competing effects. It depends onthe DW polarity which we label [Fig. 1(g)]p=+1(p=−1)
when the magnetization of the first domain crossed by thecurrent is +π/2(−π/2) rotated with respect to the current
direction. We observed that regardless of the current andH
satsigns, p=−1 DWs alway propagate, whereas p=+1
DWs are always pinned, as summarized schematically inFig. 1(g). This suggests the current creates an effective field
/vectorH
effpointing in the magnetization direction of the expanding
domain, competing with the STT-like contribution. When afield is needed to depin, as in the 2 μm wide tracks, an identical
phenomenology was observed [images in Fig. 1(i)]. Note that
in one particular configuration, DWs occasionally depinned inthe direction opposite to the current flow [Fig. 1(j)]. Finally,
the reproducibility of these observations was verified in detailbetween 4 K and 80 K, as well as the robustness of thephenomenology [ 41]. These results are in stark contrast with
those obtained by transport-only measurements on planar(Ga,Mn)As with biaxial anisotropy. They had shown either
no dependence on current polarity [ 31], or deduced indirectly
a DW propagation direction against the hole current [ 32].
To get an insight on the nature of the torques at play in
the DW motion, we then acquired hysteresis cycles on the2μmw i d eC
⊥track for different values of a dc current [see
Fig.2(a)]. In order to maintain a constant effective temperature
(Teff=83 K), the temperature rise during sample excitation
was carefully characterized and adjusted for by tuning thecryostat temperature (see Appendix A). Figure 2(a) shows
that the hysteresis cycles are shifted in opposite directionsfor positive or negative currents, indicating that the effectof current is equivalent to an effective magnetic field alongthe easy axis. In order to study this effect, we monitoredthe depinning field out of a particular defect along thestripe, H
dep, as a function of current, and compared it to its
value without any current: δHdep(J)=Hdep(J)−Hdep(J=
0). Positive and negative dc currents were used, so thatthe four different relative orientations of current/field wereexplored [see side schematics in Fig. 2(b)], allowing us
to disentangle the two competing effects. They reproducedthe blocking/passing configurations observed under pulsed
current in Figs. 1(i)and1(j). In the resulting δH
dep(J)p l o t
of Fig. 2(b),δHdep<0(δHdep>0) implies that the current
made it easier (more difficult) to depin the DW. At lowcurrent density and in the south-east quadrant of Fig. 2(b),
it becomes very difficult to pinpoint precisely how differentthe depinning field is from the J=0 one. As the current
density becomes higher, however, we notice that the δH
dep(J)
data essentially consists of two intersecting lines of positive
(negative) slopeδHdep+
J(δHdep−
J). We can therefore extract an ef-
fective fieldlike contributionμ0Heff
J=μ0
2(|δHdep+
J|+|δHdep−
J|)=
(3.6±0.2)×10−2mT/GA m−2and a domain-independent,
STT-like contributionμ0HSTT
J=μ0
2(|δHdep+
J|−|δHdep−
J|)=(6±
1)×10−3mT/GA m−2. We therefore conclude thatHeff
Jis six
times larger than the STT-like contributionHSTT
J, and is of the
same order of magnitude as the total spin-orbit field efficiencyin Refs. [ 27–30]. Note that H
effexhibits the same symmetry
as the Oersted field accompanying the passage of the current.Micromagnetic simulations under J=20 GA m
−2show that
the transverse ( y) component of the Oersted field is around
±0.2 mT (in the center of the top/bottom interfaces), and its
out-of-plane ( z) component is ±0.8 mT (at midheight of the
track edges). However, the substrate being quite insulating, thecurrent density is mostly confined to the magnetic layer, andwe expect the average Oersted field in the track to be close tozero.
FIG. 2. Estimation of the current-induced STT-like and FL-like contributions in the 2 μmw i d eC ⊥track, at Teff=83 K. (a) Normalized
hysteresis cycles under continuous current J=±8.3G Am−2, and without current. They are obtained by taking longitudinal Kerr images as the
field is cycled, and averaging the signal over the entire surface of the track. Hysteresis cycles averaged on the reservoir under current coincide
with those averaged on the track without current. (b) The DW depinning field out of a given trap Hdep(J) is monitored as a function of current
density and compared to the one without applied current Hdep(J=0). The difference is indicated in the yaxis. The four schematics represent
the physical situations encountered in the four corresponding quadrants of the plot, with the same arrow legend as in Fig. 1.
054422-3L. THEVENARD et al. PHYSICAL REVIEW B 95, 054422 (2017)
FIG. 3. Domain-wall velocity: (a) velocity versus field curves (C //and C ⊥2μm wide tracks) at constant temperature and current density.
(b) Velocity versus current density for tracks C //(2μmw i d e , μ0H=1.1 and 1.2 mT) and C ⊥(2μmw i d e , μ0H=1.3m T ,a n d1 0 μmw i d e ,
no field). Measurements taken at Teff=49±1Kf o rt h e2 μm wide tracks, and at Teff=77±2 K for the 10 μm wide one.
We can now summarize the current-induced DW mo-
tion phenomenology in (Ga,Mn)As with uniaxial in-planeanisotropy as follows. When the current flows colinear tothe magnetization (C
//tracks), DW motion occurs in the
hole current direction regardless of domain charge. This isopposite to the direction observed for spin-transfer torquein perpendicularly magnetized (Ga,Mn)As films. When thecurrent flows perpendicular to the magnetization (C
⊥tracks),
this STT-like contribution competes with an effect six timeslarger, an effective transverse field H
effproportional to the
current.
Finally, we performed DW velocity measurements on
the C //and C ⊥tracks (see Fig. 3). Displacements under
increasing current pulse lengths were obtained as describedin Appendix B. Figure 3(a) shows v
J(H) curves displaying
the DW velocity as a function of the applied magnetic field,in the presence of current pulses of constant amplitude. Themaximum measurable velocity is determined by the tracklength. After a depinning regime at low fields, the DW velocityincreases linearly with field, reaching up to 300 m s
−1on the
2μmw i d eC //track. These velocities are typical of those
measured under field only on a very similar nonpatternedlayer [ 39], and result from the large DW width of in-plane
(Ga,Mn)As. In the C
⊥tracks, velocities are overall smaller [up
to 150 m s−1,F i g . 3(a)]. Comparing C //and C ⊥vJ(H) curves
taken at the same current density shows that the∂v
∂Hmobilities
lie in a ratio of 4:1 (measured after the depinning regime).In the stationary regime, we expect field mobilities to varyin a first approximation like the static DW width, estimatedby micromagnetic simulations [Fig. 4(a)] to be almost three
times larger in the charged DWs of C
//tracks ( /Delta10=40
nm), than in the uncharged DWs of C ⊥(/Delta10=15 nm).
The measured mobility ratio is therefore a signature of thestationary regime. Also, the precessional regime is expectedto be preceded by a large velocity plateau, seen under field onlyon unpatterned samples [ 39] and in micromagnetic simulations
for C
⊥and C //tracks [Fig. 4(b)]. This plateau was not observed
experimentally under applied field/current.
The field was then kept constant (1.1, 1.2, 1.3, or 0 mT), and
current pulses ( J=7–25 GA m−2) were applied at constant
effective temperature. This generated vH(J) curves [Fig. 3(b)].
Once more, velocities of up to 300 m s−1were observed
on the 2 μmw i d eC //track, and up to 150 m s−1in C ⊥tracks, again pointing to the stationary regime. The resulting
current mobility∂v
∂Jis 11±1m m3C−1for the 2 μmw i d eC //
tracks ( Teff=49 K) and 10 μmw i d eC ⊥track ( Teff=77 K),
over ten times larger than the mobilities measured on out-of-plane magnetized (Ga,Mn)As [ 34–37]. No field assistance
was required for the wider 10 μmC
⊥track [Fig. 3(b)], on
which creep motion was also observed at low current densities(J=7G Am
−2, velocities too small to appear on the curve).
(b)(a)
mxmy
0 1 23 4 5050100150200
FIG. 4. Micromagnetic simulations ( T=60 K micromagnetic
parameters of the sample, and T=0 in mumax code [ 42]) for
both track configurations. (a) Static domain wall width. Smaller DW
widths translate into smaller mobilities under field. (b) Field-driven
DW propagation, subtracting surface magnetic charges at wire endsto simulate infinite wire. The best agreement with measurements
on unpatterned samples [ 39] was obtained with α=0.025. The
precessional regime is reached at a few mT, in the plateau of thecurve.
054422-4SPIN TRANSFER AND SPIN-ORBIT TORQUES IN IN- . . . PHYSICAL REVIEW B 95, 054422 (2017)
In the 2 μmC⊥track, a lower mobility of 6 ±1m m3C−1was
measured.
IV . POSSIBLE TORQUES AT PLAY
To make sense of these unexpected results, we begin by
considering two types of current-induced torques: torquesthat push DWs unidirectionally regardless of their polarityor charge, which will be named STT-like, or torques driven bythe Rashba and Dresselhaus spin-orbit effective fields.
A. Spin-orbit effective field torques
Dresselhaus and Rashba terms in strained (Ga,Mn)As
induce a total effective field /vectorHsoproportional to the current
density and transverse to the track direction [Figs. 1(a)
and 1(b)], expected to be slightly larger in C ⊥than in
C//tracks [ 27–30,43]. Similar to what has been calculated
and observed in metals [ 7,44–47], this field can act on
the magnetization via two torques: a fieldlike torque [ 48]
(FL-SOT) /vectorHso×/vectorMor a Slonczweski-like torque (SL-SOT)
/vectorM×/vectorHSLwith /vectorHSL∝/vectorM×/vectorHso. The FL-SOT is sensitive
to the charge or polarity of the DW, but not to its chirality(magnetization orientation inthe DW), while the SL-SOT
is sensitive to the magnetization configuration within theDW (Bloch/N ´eel, chirality). Both torques have been cal-
culated [ 26,43] and measured [ 27–30,43] in monodomain
(Ga,Mn)As and (Ga,Mn)(As,P) and found to be of the sameorder of magnitude [ 43].
We have summarized schematically their expected effect
on DWs of C
//and C ⊥tracks in Fig. 5.I nC //tracks, the
FL-SOT simply stabilizes a N ´eel DW structure against Walker
breakdown, and possibly imposes a DW chirality during its
creation [Fig. 5(a)]. In C ⊥tracks however, /vectorHsois collinear to
the domain magnetization, so will act like the effective field
/vectorHeffevidenced earlier. Hence we suggest μ0/vectorHeff=μ0/vectorHSO.
We established above that at 83 K it varies with current as3.6×10
−2mT/GA m−2[Fig. 2(b)], close to the (2 .0–10.6)×
10−2mT/GA m−2SO field efficiencies found by other authors[27–30]f o r J//[110]. This yields for our typical current
densities (e.g., J=20 GA m−2)μ0HSO=0.4–2.7m T ,v e r y
much of the order of the applied static fields. Its directionis represented in Figs. 1(g) and5(b),5(d) by a green hollow
arrow.
Note that the total spin-orbit field we find for J//[110]
is of opposite sign to the one found in previous studies ofin-plane magnetized (Ga,Mn)As devices [ 27–30,43]. These
measurements were done on samples quite similar to ours inMn content, Curie temperature, of varying anisotropy (uniaxialor biaxial), and monodomain or not. A notable differencewould be our sample thickness (50 nm), e.g., twice that ofthe thickest of these studies (25 nm). One could tentativelysay that a thicker layer would reduce the Rashba (interfacial)
contribution to the total /vectorH
socompared to thinner layers.
However, since it is unclear what governs the sign of theRashba field, and how exactly it varies from layer to layer,it is very difficult to infer anything from this observation. Amore flagrant discrepancy is that the studies of Refs. [ 27–30]
are all based on magnetotransport measurements, whereas weproceed via a direct visualization of domains. However, witha correct characterization of both hole current and appliedfield directions, this should not affect the sign of μ
0HSO.T h e
reason for this sign difference therefore remains elusive for themoment.
The SL-SOT was proposed to explain similar intriguing
DW propagation direction and velocities in metals [ 49]. We
label it “efficient” (propagation in the stationary regime)when it tilts the magnetization out of the plane of rotationof the DW (materialized by dotted lines in Fig. 5), and
“inefficient” (propagation in the precessional regime only)when it merely rotates the DW magnetization. As representedschematically in Figs. 5(a) and 5(b), the SL-SOT will be
inefficient for C
//and C ⊥. We also consider DW structures
other than the N ´eel or transverse ones [ 50]. The SL-SOT can
then induce efficient propagation for C //tracks provided a
significant Bloch component is present [Fig. 5(c)]. For the
resulting DW propagation direction to be independent of theDW charge, as observed experimentally [Figs. 1(c)–1(f)],
FIG. 5. Effective fields acting on the magnetization (blue arrows) involved in the fieldlike torque (green hollowed arrows) and the
Slonczweski-like torque (black hollowed arrows), /vectorHSL∝/vectorHso×/vectorM. Their effect on C //(a),(c) and C ⊥(b),(d) configurations, and supposing
N´eel (a),(b) or Bloch (c),(d) domain walls are represented using dashed contours if the field is only efficient in the precessional regime, or
continuous contours if it is efficient in the stationary regime. The direction of the hole current is indicated by a red arrow and the dotted contoursmaterialize the plane of rotation of the magnetization in the domain wall. The direction of /vectorH
sohas only been inferred experimentally in (b).
054422-5L. THEVENARD et al. PHYSICAL REVIEW B 95, 054422 (2017)
DWs would however need to be chiral, meaning that the
magnetization would for instance need to point “up” in head-to-head DWs, and “down” in tail-to-tail DWs. This propertyusually accompanies the DMI [ 16], a point that would require
further theoretical development for the case of (Ga,Mn)As.This torque would however be inefficient in the C
⊥tracks
[Fig. 5(d)].
To summarize, Rashba and Dresselhaus spin-orbit effective
fields could only explain the fieldlike torque observed in C ⊥
tracks. To make sense of the STT-like effects with a torqueinvolving an effective field proportional to the current, onewould need it to be along z, instead of in-plane and transverse
to the track. Under the form of a Slonzweski-like torque /vectorM×
/vectorH
eff,z×/vectorM, it could indeed push DWs efficiently along the hole
current on both types of tracks, provided it had the correctsign and DWs were chiral. Such a field has recently beenevidenced in monodomain Ta/CoFeB/TaOx trilayers [ 51]. It
is equivalent to an in-plane electric field perpendicular to thetrack, and proportional to the current density. In Yu et al. [51]
it originated from the lateral structural asymmetry inducedby the wedged cross section of their sample, but its originin our case would be unclear. It would also be problematicto reconcile it with current-induced domain wall propagationin out-of-plane magnetized (Ga,Mn)As and (Ga,Mn)(As,P):
a/vectorH
eff,zfield would prevent consecutive DWs from shifting
synchronously under current, as has been observed in thesesamples [ 35–37].
To conclude on this part on spin-orbit effective fields,
we wish to comment on an implicit hypothesis made in our
approach. Here the spin-orbit field /vectorH
sois assumed to be only
weakly affected by the presence of a domain wall [as repre-sented schematically in Figs. 1(c)and1(g)]. However, domain
walls could be the locus of significant Mn (and therefore hole)depolarization [ 20,52], which could in turn modify the local
spin-orbit field amplitude. /vectorH
sohas so far mainly been measured
in monodomain samples, and for current/magnetization onhigh symmetry axes [ 27,29]. Let us mention however that Li
et al. [30] have measured /vectorH
soon 10μm wide devices probably
accommodating DWs, and found it to be similar to those ofthe 80 nm wide monodomain devices of Fang et al. [29]
along [1 ±10],[100], which supports our initial hypothesis.
Kurebayashi et al. [43] moreover studied, on a monodomain
sample, the dependence of the SL field /vectorH
z∝/vectorHso×/vectorMon the
angle ( /vectorM,/vectorJ), and evidenced weak anisotropic effects.
B. Spin-transfer-like torques
We now consider the effect of STT-like torques, and focus
on the generic “nonadiabatic” term β/vectorM×[(/vectorJ·/vector∇)/vectorM], where
Jis the current density and βis a phenomenological factor
related to spin accumulation at the domain wall. In thestationary regime, a velocity proportional to the current densityis expected, with v∝
β
αJ,αbeing the Gilbert damping term.
Previous work [ 35–37] done on 25–50 nm thick out-of-
plane magnetized (Ga,Mn)As or (Ga,Mn)(As,P) has evidenceda negative mobility of DWs driven by current. Assuming aspin-relaxation transfer torque [ 3],
∂v
∂J=βsr
α|Pc|μB
eMs<0w a s
then justified by the negative carrier polarization Pcarising
from the antiferromagnetic Mn spin/hole spin interaction,and a value of βsr/α≈−1.0±0.5 was found [ 53]. The
positive mobilities measured on both C//and C ⊥tracks,
however, suggest that in planar (Ga,Mn)As this effect is in factdominated by a counterpropagating one. From the velocitycurves [Fig. 3(b)], we estimate β/α≈12 (see numerical
details in Appendix C)f o rt h eC
//tracks. Assuming βsr/α≈
−1 implies that an STT-like mechanism of opposite sign needs
to account for the remaining 13. Note that the spin-relaxationtransfer torque is very probably present though, since themeasured M
s(T) curve exhibits a very standard shape, which is
consistent with the efficient mutual polarization of the Mn andhole spin populations. This contrasts with ultrathin metallicfilms sandwiched between other layers, which end up beingpoorly spin polarized due to their weak relative conductivity inthe stack [ 11,13]. In C
⊥tracks a lower ratio of β/α < +0.7–5
was estimated from both the velocity curves and the hysteresiscycles taken under dc current (Fig. 2and Appendix C).
The term βphenomenologically accounts for many differ-
ent microscopic phenomena leading to spin relaxation suchas spin-flip scattering or DW-induced relaxation [ 4,54]. In
metals it also covers the appearance of a DW resistance atabrupt interfaces [ 55–58], leading to a momentum transfer
force [ 7,59–62] never clearly identified experimentally [ 63].
Two contributions have been identified in the spin-relaxationnonadiabatic torque. The first one is “interband” and resultsfrom the modification of the electron wave functions under anapplied electric field [ 21,22,43,54]. It is weakly affected by the
(Ga,Mn)As KL SOI. The second one is “intraband” and reflectsthe modification of the band populations by the electric field,via the Fermi-Dirac coefficient. In (Ga,Mn)As, the “interband”component dominates as a result of the strong SOI, withpredicted [ 20,21]β/α≈10. In particular, it can overcome the
intrinsic limited efficiency of a total momentum-conservingtorque transfering exactly ¯ hbetween conduction carriers and
local magnetic moments. Interestingly, Garate et al. [21]
predict a sign opposite to the traditional adiabatic STT incertain cases for the intraband component. The large effectiveβ/α observed in our in-plane tracks makes this torque the most
likely mechanism at work. The influence of the anisotropy andof the domain-wall width having not been addressed yet inthese calculations, the reason why this contribution wouldbe absent in out-of-plane magnetized (Ga,Mn)As remainselusive. We have calculated k-space maps of the spin and
orbital components S
zandLzby/vectork·/vectorptheory for in-plane
and out-of-plane magnetized (Ga,Mn)As, and have not foundany noteworthy differences. In particular, the calculated holepolarization at the Fermi energy is identical. Instead, apossibility to be explored is the influence of the domain-wallwidth. Indeed we do observe that the high positive mobilityunder current seems to decrease with domain-wall width:β/α≈+12 for /Delta1≈40 nm [C
//tracks, Fig. 4(a)],β/α <
+0.7–5 for /Delta1≈15 nm (C ⊥tracks), and finally β/α≈−1f o r
/Delta1≈5 nm [out-of-plane magnetized (Ga,Mn)As]. Although
this agrees with the tendency of the SOI-induced torques toincrease with domain-wall width calculated in ballistic nickeldomain walls [ 58], it disagrees with the prediction of Nguyen
et al. [20].
At this stage, based on this phenomenological study
and to reconcile all current-induced observations in(Ga,Mn)As/(Ga,Mn)(As,P), one can infer that the KL SOI
054422-6SPIN TRANSFER AND SPIN-ORBIT TORQUES IN IN- . . . PHYSICAL REVIEW B 95, 054422 (2017)
spin transfer torque is responsible for DW propagation along
the hole current in in-plane layers with wide domain walls,but is absent in out-of-plane layers. The domain-wall widthis however clearly not the only relevant parameter, sinceDe Ranieri et al. [37] have observed current-induced DWP
opposite the hole current on perpendicularly magnetized(Ga,Mn)(As,P) tracks with N ´eel DWs. Further theoretical
work on the domain-wall width and anisotropy depen-dence of this torque would therefore greatly enrich thisdiscussion.
C. Spin Hall and anomalous Hall effects torques
Finally, we mention some of the other effects likely
to affect current-driven DWP. Among them, the spin Halleffect [ 64] torque that appears when a ferromagnet is adjacent
to a nonmagnetic high spin-orbit coupling metal has proveddecisive to explain propagation against the electron flow inultrathin metallic layers [ 10–14]. It is however very unlikely
to exist in the bulk of a ferromagnet. One could argue thatif current leaked into the GaAs substrate, the presence of thespin-asymmetric vacuum/(Ga,Mn)As/GaAs interfaces couldin theory pump a spin current perpendicular to the layer. Thescaling of the tracks’ resistance with their width howeverpoints to a sufficiently insulating substrate to neglect thiscontribution. Closely related to it, the anomalous Hall effect islarge in (Ga,Mn)As. It was recently shown both theoreticallyand experimentally to be a possible source of large β/α ratio
in Permalloy [ 65,66]. This effect however seems limited to
vortex domain walls.
V . CONCLUSIONS
We have observed current-induced domain-wall propa-
gation in uniaxial in-plane (Ga,Mn)As tracks. The current-dependent DW mobility is up to ten times higher and ofopposite sign than in out-of-plane magnetized (Ga,Mn)Asand cannot be explained by the arguments put forward inmetallic structures, where similar effects were evidenced. Inparticular, the fieldlike and Slonczweski-like torques asso-ciated with the Rashba/Dresselhaus spin-orbit fields alonecannot account for these observations. The existence ofan efficient Kohn-Luttinger SOI spin-transfer mechanism,overshadowing the usual spin-relaxation channel seems sofar the most likely candidate, with the constraint that itwould need to be much stronger in in-plane than in out-of-plane (Ga,Mn)As/(Ga,Mn)(As,P) layers. This work, however,provides a strong motivation to further study in-plane mag-netized (Ga,Mn)As tracks, and more generally to engineeruniaxial in-plane materials showing strong intrinsic spin-orbit interactions. This should allow one to explore thepossibility of obtaining these high mobilities without therequirement of a pure-spin current source like in metallicheterostructures.
ACKNOWLEDGMENTS
We thank A. Thiaville for his continuous interest in this
work, as well as V . Cros, J. Sampaio, and A. Manchonfor stimulating discussions. We acknowledge M. Bernard,S. Majrab, and M. Rostiche for their technical assistance, andJ. von Bardeleben for the cavity-FMR measurements. This
work has been supported by the French RENATECH network.
APPENDIX A: ESTIMATION OF THE EFFECTIVE
TEMPERATURE
As routinely done on (Ga,Mn)(As,P) and (Ga,Mn)As
samples [ 35–37], the strong temperature dependence of the
resistance Rwas used to evaluate the effective temperature of
the tracks. After taking a calibration R(T) curve under very
low current, the cryostat was set at a given temperature. Aconstant voltage Uwas then applied, and the track resistance
Rmeasured. This yielded a R(P) curve where P=U
2/R.
Using the low current R(T) calibration curve, this was turned
into a Tstat(P) curve where Tstatis the track temperature in
the stationary regime. In a 1D heat diffusion model, thislinear relationship depends solely on the track dimensions,the substrate thickness, and the thermal conductivity K[67].
We could therefore extract experimentally an effective valueofKfor the different tracks, and from different starting
temperatures T
0. Typical values of K=100–150 W m−1K−1
were obtained. This in turn was used to estimate the ef-
fective temperature ( Teff) after short current pulses, using
the specific heat from Ref. [ 68] (e.g., C=77 J kg−1K−1
around 50 K):
/Delta1T(τ)=P
2πKlln/parenleftbigg16Dτ
w2/parenrightbigg
, (A1)
/Delta1T(τ→∞ )=P
πKl/bracketleftbigg3
2+ln/parenleftbigg2L
w/parenrightbigg/bracketrightbigg
, (A2)
Teff
stat=T0+/Delta1T, (A3)
where wandlare respectively the track width and length,
L=350μm is the substrate thickness, D=K/ρC is the heat
diffusion coefficient, and ρis the mass density.
APPENDIX B: METHODOLOGY OF DW VELOCITY
MEASUREMENT
The procedure for image acquisition was identical to the
one used in Ref. [ 39]. An image was first taken in zero field,
after saturating the sample ( μ0Hsat=±8 mT). Consecutive
images (after field/current application) were divided by thisreference image in order to enhance the domain contrast.Different DW propagation behaviors—pinned, depinning, anddepinned regimes—were observed depending on the value ofcurrent/field [Fig. 6(a)]. Given the high velocity of the DWs,
short pulses were required. The velocity was obtained as theslope of the averaged displacements versus pulse length τ
[Fig. 6(b)]. For each τ, several acquisitions were made, giving
a distribution of displacements.
APPENDIX C: EXPERIMENTAL ESTIMATION OF β
This was done using either the velocity curves taken under
pulsed current [Fig. 3(b)], or the hysteresis cycles taken under
dc current (Fig. 2). The magnetization at saturation was
determined by SQUID: Ms=33 kA /m at 49 K and Ms=
16 kA /m at 77 K. The domain wall widths were taken as
15 nm (40 nm) for C ⊥(C//) tracks (Fig. 4).
054422-7L. THEVENARD et al. PHYSICAL REVIEW B 95, 054422 (2017)
FIG. 6. 2 μmw i d eC //tracks: (a) position of the DW versus current pulse number at fixed applied field μ0H=0.7m Ta n d Teff≈62 K,
pulse duration τ=100 ns. Pinned (magenta), depinning (blue), and depinned (black) regimes are clearly identified for increasing current
densities. No pr1opagation or depinning are observed for negative values of the current. (b) Domain wall velocity determination from the
averaged domain-wall displacement, at fixed applied field μ0H=1.3m T , J=21.75 GA m−2,a n dTeff≈49 K.
From the velocity curves : in the stationary regime, the
velocity is given by∂v
∂J=β
αPcμB
eMsfor the C //tracks, and
∂v
∂J=βsr
αPcμB
eMs+γ/Delta1
α∂μ0HSO
∂Jfor the C ⊥tracks.∂μ0HSO
∂J=3.6×
10−2mT/GA m−2was determined experimentally from the
hysteresis cycles at 83 K (Fig. 2). For lack of lower temperature
measurement, we will take this as a lower boundary of the 49and 77 K
∂μ0HSO
∂Jvalues, giving an upper boundary of β/α.T h e
polarization of holes at the Fermi energy Pcwas calculated
byk.ptheory with a hole density of p=3×1020cm−3:
|Pc|=0.53 at 49 K and |Pc|=0.4a t7 7K .From the hysteresis cycles : converting the STT-like contri-
bution into a value of βwithμ0HSTT
J=β
γ/Delta1, following Ref. [ 69].
For C //tracks :a tTeff=49 K, the mobility of the 2 μm
wide track∂v
∂J=+11.1±0.5m m3C−1leads to β/α≈12.
For C ⊥tracks :a tTeff=49 K, the mobility of the
2μm wide track∂v
∂J=+5.7m m3C−1leads to β/α < 2.
AtTeff=77 K, the mobility of the 10 μm wide track
∂v
∂J=+11.1m m3C−1leads to β/α < 5. AtTeff=83 K, the
STT-like contribution found by the hysteresis cyclesμ0HSTT
J=
+6.5×10−3mT/GA m−2leads to β/α≈0.7.
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RevModPhys.84.119.pdf | Domain wall nanoelectronics
G. Catalan
Institut Catala de Recerca i Estudis Avanc ¸ats (ICREA), 08193, Barcelona, Spain
Centre d’Investigacions en Nanociencia i Nanotecnologia (CIN2), CSIC-ICN,
Bellaterra 08193, Barcelona, Spain
J. Seidel
Materials Sciences Division, Lawrence Berkeley National Laboratory,
Berkeley, California 94720, USA
Department of Physics, University of California at Berkeley, Berkeley, California 94720, USASchool of Materials Science and Engineering, University of New South Wales,
Sydney NSW 2052, Australia
R. Ramesh
Materials Sciences Division, Lawrence Berkeley National Laboratory,
Berkeley, California 94720, USA
Department of Physics, University of California at Berkeley, Berkeley, California 94720, USADepartment of Materials Science and Engineering, University of California at Berkeley,
Berkeley, California 94720, USA
J. F . Scott
Department of Physics, Cavendish Laboratory, University of Cambridge,
Cambridge CB3 0HE, United Kingdom
(published 3 February 2012)
Domains in ferroelectrics were considered to be well understood by the middle of the last century:
They were generally rectilinear, and their walls were Ising-like. Their simplicity stood in stark
contrast to the more complex Bloch walls or Ne ´el walls in magnets. Only within the past decade and
with the introduction of atomic-resolution studies via transmission electron microscopy, electronholography, and atomic force microscopy with polarization sensitivity has their real complexity
been revealed. Additional phenomena appear in recent studies, especially of magnetoelectric
materials, where functional properties inside domain walls are being directly measured. In thispaper these studies are reviewed, focusing attention on ferroelectrics and multiferroics but making
comparisons where possible with magnetic domains and domain walls. An important part of this
review will concern device applications, with the spotlight on a new paradigm of ferroic deviceswhere the domain walls, rather than the domains, are the active element. Here magnetic wall
microelectronics is already in full swing, owing largely to the work of Cowburn and of Parkin and
their colleagues. These devices exploit the high domain wall mobilities in magnets and theirresulting high velocities, which can be supersonic, as shown by Kreines’ and co-workers 30 years
ago. By comparison, nanoelectronic devices employing ferroelectric domain walls often have
slower domain wall speeds, but may exploit their smaller size as well as their different functionalproperties. These include domain wall conductivity (metallic or even superconducting in bulkinsulating or semiconducting oxides) and the fact that domain walls can be ferromagnetic while the
surrounding domains are not.
DOI: 10.1103/RevModPhys.84.119 PACS numbers: 77.80.Fm, 68.37.Ps, 77.80.Dj, 73.61.Le
CONTENTS
I. Introduction 120
II. Domains 121
A. Boundary conditions and the formation of domains 121B. Kittel’s law 121C. Wall thickness and universality of Kittel’s law 122D. Domains in nonplanar structures 123
E. The limits of the square root law: Surface effects,
critical thickness, and domains in superlattices 124F. Beyond stripes: Vertices, vortices, quadrupoles,
and other topological defects 125
G. Nanodomains in bulk 128H. Why does domain size matter? 130
III. Domain Walls 130
A. Permissible domain walls: Symmetry
and compatibility conditions 130
B. Domain wall thickness and domain wall profile 131
C. Domain wall chirality 133D. Domain wall roughness and fractal dimensions 134REVIEWS OF MODERN PHYSICS, VOLUME 84, JANUARY–MARCH 2012
0034-6861 =2012=84(1)=119(38) 119 /C2112012 American Physical SocietyE. Multiferroic walls and phase transitions
inside domain walls 136
F. Domain wall conductivity 138
IV. Experimental Methods for the Investigation
of Domain Walls 138
A. High-resolution electron microscopy
and spectroscopy 138
B. Scanning probe microscopy 139
C. X-ray diffraction and imaging 141
D. Optical characterization 141
V. Applications of Domains and Domain Walls 142
A. Periodically poled ferroelectrics 142
1. Application of Kittel’s law to electro-optic
domain engineering 143
2. Manipulation of wall thickness 143
B. Domains and electro-optic response of LiNbO 3 144
C. Photovoltaic effects at domain walls 144D. Switching of domains 145E. Domain wall motion: The advantage of magnetic
domain wall devices 145
F. Emergent aspects of domain wall research 147
1. Conduction properties, charge, and
electronic structure 147
2. Domain wall interaction with defects 1493. Magnetism and magnetoelectric properties
of multiferroic domain walls 149
VI. Future Directions 150
I. INTRODUCTION
Ferroic materials (ferroelectrics, ferromagnets, ferroelas-
tics) are defined by having an order parameter that can pointin two or more directions (polarities), and be switched be-
tween them by application of an external field. The different
polarities are energetically equivalent, so in principle they all
have the same probability of appearing as the sample is
cooled down from the paraphase. Thus, zero-field-cooledferroics can, and often do, spontaneously divide into small
regions of different polarity. Such regions are called
‘‘domains,’’ and the boundaries between adjacent domains
are called ‘‘domain walls’’ or ‘‘domain boundaries.’’ The
ordered phase has a lower symmetry compared to the parentphase, but the domains (and consequently domain walls)
capture the symmetry of both the ferroic phase and the para-
phase. For example, a cubic phase undergoing a phase tran-
sition into a rhombohedral ferroelectric phase will exhibit
polar order along the eight equivalent 111-type crystallo-graphic directions, and domain walls in such a system sepa-
rate regions with diagonal long axes that are 71
/C14, 109/C14, and
180/C14apart. We begin our description with a general discus-
sion of the causes of domain formation, approaches to under-
standing the energetics of domain size, factors that influencethe domain wall energy and thickness, and a taxonomy of the
different domain topologies (stripes, vertices, vortices, etc.).
As the article unfolds, we endeavor to highlight the common-alities and critical differences between various types of fer-
roic systems.
Although metastable domain configurations or defect-
induced domains can and often do occur in bulk samples,an ideal (defect-free) infinite crystal of the ferroic phase is
expected to be most stable in a single-domain state (Landauand Lifshitz). Domain formation can thus be regarded insome respect as a finite size effect, driven by the need to
minimize surface energy. Self-induced demagnetization or
depolarization fields cannot be perfectly screened and alwaysexist when the magnetization or polarization has a componentperpendicular to the surface. Likewise, residual stresses dueto epitaxy, surface tension, shape anisotropy, or structuraldefects induce twinning in all ferroelastics and most ferro-
electrics. In general, then, the need to minimize the energy
associated with the surface fields overcomes the barrier forthe formation of domain walls and hence domains appear.Against this background, there are two observations and acorollary that constitutes the core of this review:
(1) The surface-to-volume ratio grows with decreasing
size; consequently, small devices such as thin films,
which are the basis of modern electronics, can have
small domains and a high volume concentration ofdomain walls.
(2) Domain walls have different symmetry, and hence
different properties, from those of the domains theyseparate.
The corollary is that the overall behavior of the films may
be influenced, or even dominated, by the properties of the
FIG. 1. Schematic of logic circuits where the active element is not
charge, as in current complementary metal oxide semiconductor(CMOS) technology, but domain wall magnetism. From Allwood
et al. , 2005 .120 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012walls, which are different from those of the bulk material.
Moreover, not only do domain walls have their own proper-
ties but, in contrast to other types of interface, they are
mobile. One can therefore envisage new technologies wheremobile domain walls are the ‘‘active ingredient’’ of the
device, as highlighted by Salje (2010) . A prominent example
of this idea is the magnetic ‘‘racetrack memory’’ where thedomain walls are pushed by a current and read by a magnetic
head ( Parkin, Hayashi, and Thomas, 2008 ); in fact, the entire
logic of an electronic circuit can be reproduced using mag-
netic domain walls ( Allwood et al. ,2 0 0 5 ) (see Fig. 1).
Herbert Kroemer, Physics Nobel Laureate in 2000 for his
work on semiconductor heterostructures, is often quoted for
his dictum ‘‘the interface is the device.’’ He was, of course,referring to the interfaces between different semiconductor
layers. His ideas were later extrapolated, successfully, to
oxide materials, where the variety of new interface propertiesseems to be virtually inexhaustible ( Mannhart and Schlom,
2010 ;Zubko et al. , 2011 ). However, this review is about a
different type of interface: not between different materials,
but between different domains in the same material.
Paraphrasing Kroemer, then, our aim is to show that ‘‘thewall is the device.’’
II. DOMAINS
A. Boundary conditions and the formation of domains
The presence and size of domains (and therefore the
concentration of domain walls) in any ferroic depends on
its boundary conditions. Consider, for example, ferroelec-trics. The surfaces of a ferroelectric material perpendicular
to its polar direction have a charge density equal to the
dipolar moment per unit volume. This charge generates anelectric field of sign opposite to the polarization and magni-
tudeE¼P=" (where "is the dielectric constant). For a
typical ferroelectric ( P¼10/C22C=cm
2,"r¼100–1000 ), this
depolarization field is c.a. 10–100 kV =cm, which is about an
order of magnitude larger than typical coercive fields. So, if
nothing compensates the surface charge, the depolarizationwill in fact cancel the ferroelectricity. Charge supplied by
electrodes can partly screen this depolarization field and,
although the screening is never perfect ( Batra and
Silverman, 1972 ;Dawber, Jung, and Scott, 2003 ;Dawber
et al. , 2003 ;Stengel and Spaldin, 2006 ), good electrodes can
stabilize ferroelectricity down to films just a few unit cellsthick ( Junquera and Ghosez, 2003 ). But a material can also
reduce the self-field by dividing the polar ground state into
smaller regions (domains) with alternating polarity, so that
theaverage polarization (or spin, or stress, depending on the
type of ferroic material considered) is zero. Although thisdoes not completely get rid of the depolarization (locally,
each individual domain still has a small stray field), the
mechanism is effective enough to allow ferroelectricity tosurvive down to films of only a few unit cells thick ( Streiffer
et al. , 2002 ;Fong et al. , 2004 ). The same samples (e.g.,
epitaxial PbTiO
3onSrTiO 3substrates) can in fact show
either extremely small (a few angstroms) domains or an
infinitely large monodomain configuration just by changing
the boundary condition ( Fong et al. , 2006 ), i.e., by allowingfree charges to screen the electric field so that the formation
of domains is no longer necessary (and it is noteworthy that
such effective charge screening can be achieved just by
adsorbates from the atmosphere).
An important boundary condition is the presence or other-
wise of interfacial ‘‘dead layers’’ that do not undergo theferroic transition. Dead layers have been discussed in thecontext of ferroelectrics, where they are often proposed as
explanations for the worsening of the dielectric constant of
thin films, although the exact nature, thickness, and evenlocation of the dead layer, which might be inside the elec-trode, is still a subject of debate ( Sinnamon, Bowman, and
Gregg, 2001 ;Stengel and Spaldin, 2006 ;Chang et al. , 2009 ).
In ferroelectrics, dead layers prevent screening causing do-
mains to appear ( Bjorkstam and Oettel, 1967 ;Kopal et al. ,
1999 ;Bratkovsky and Levanyuk, 2000 ). More recently,
Luk’yanchuk et al. (2009) proposed that an analogous
phenomenon may take place in ferroelastics, so that ‘‘ferroe-lastic dead layers’’ can cause the formation of twins (Fig. 2).
Surfaces have broken symmetries and are thus intrinsicallyuncompensated, so interfacial layers are likely to be a general
property of all ferroics, including, of course, multiferroics
(Marti et al. , 2011 ).
B. Kittel’s law
For the sake of simplicity, most of this discussion will
assume ideal open boundary conditions and no screening ofsurface fields. The geometry of the simplest domain morphol-ogy, namely, stripe domains, is depicted in Fig. 3. Although a
FIG. 2. Surface ‘‘dead’’ layers that do not undergo the ferroic
transition can cause the appearance of ferroelastic twins in other-wise stress-free films. Dead layers also exist in other ferroics such as
ferroelectrics and ferromagnets. From Luk’yanchuk et al. , 2009 .
δd
yxzY
wdY
d
yxzY
wdY
FIG. 3 (color online). Schematic of the geometry of 180/C14stripe
domains in a ferroelectric or a ferromagnet with out-of-plane
polarity.G. Catalan et al. : Domain wall nanoelectronics 121
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012stripe domain is by no means the only possible domain
structure, it is the most common ( Edlund and Jacobi, 2010 )
and conceptually the simplest. It also captures the physics ofdomains that is common to all types of ferroic materials. For
more specialized analyses, the reader is referred to mono-
graphs about domains in different ferroics: ferromagnets(Hubert and Schafer, 1998 ), ferroelectrics ( Tagantsev,
Cross, and Fousek, 2010 ), and ferroelastics or martensites
(Khachaturyan, 1983 ).
Domain size is determined by the competition between the
energy of the domains (itself dependent on the boundary
conditions, as emphasized above) and the energy of thedomain walls. The energy density of the domains is propor-tional to the domain size: E¼Uw, where Uis the volume
energy density of the domain and wis the domain width.
Smaller domains therefore have smaller depolarization, de-magnetization, and elastic energies. But the energy gained by
reducing domain size is balanced by the fact that this requires
increasing the number of domain walls, which are themselvesenergetically costly.
The energy cost of the domain walls increases linearly
with the number of domain walls in the sample, and there-fore it is inversely proportional to the domain size
(n¼1=w). Meanwhile, the energy of each domain wall is
proportional to its area and, thus, to its vertical dimension. Ifan individual domain wall stopped halfway through thesample, the polarity beyond the end point of the wall wouldbe undefined, so, topologically, a domain wall cannot dothis; it must either end in another wall (as it does for needledomains) or else cross the entire thickness of the sample. For
walls that cross the sample, the energy is proportional to the
sample thickness. Thus, the walls’ energy density per unitarea of thin film is E¼/C27d=w , where /C27is the energy density
per unit area of the wall. Adding up the energy costs ofdomains and domain walls, and minimizing the total withrespect to the domain size, leads to the famous square root
dependence:
w¼ffiffiffiffiffiffiffiffi
/C27
Udr
: (1)
Landau and Lifshitz (1935) and Kittel (1946) proposed
this pleasingly simple model within the context offerromagnetism, where the domain energy was provided
by the demagnetization field (assuming spins pointing out
of plane). It is nevertheless interesting to notice that Kittel’sclassic article predicted that pure stripes were in fact ener-getically unfavorable compared to other magnetic domainconfigurations (see Fig. 4); this is because his calculations
were performed for magnets with relatively small magnetic
anisotropy. Where the anisotropy is large, as in cobalt,
stripes are favored, and this is also the case for uniaxialferroelectrics or for perovskite ferroelectrics under in-planecompressive strain (which strongly favors out-of-plane po-larization). Closure domains are common in ferromagnets(where anisotropy is intrinsically smaller than in ferroelec-trics), but the width of the ‘‘closure stripes’’ also scales as
the square root of the thickness ( Kittel, 1946 ). We return
again to the subject of closure domains toward the end ofthis section, as it has become a hot topic in the area of
ferroelectrics and multiferroics.
Kittel’s law was extended by Mitsui and Furuichi (1953)
for ferroelectrics with 180
/C14domain walls, by Roitburd
(1976) for ferroelastic thin films under epitaxial strain,
byPompe et al. (1993) and Pertsev and Zembilgotov
(1995) for epitaxial films that are simultaneously ferroelec-
tric and ferroelastic, and, more recently, by Daraktchiev,
Catalan, and Scott (2008) for magnetoelectric multifer-
roics. The square root dependence of stripe domain widthon film thickness is therefore a general property of allferroics, and it also holds for other periodic domainpatterns ( Kinase and Takahashi, 1957 ;Craik and Cooper,
1970 ;Thiele, 1970 ).
C. Wall thickness and universality of Kittel’s law
The exact mathematical treatment of the ‘‘perfect stripes’’
model assumes that the domain walls have zero or at least
negligible thickness compared to the width of the domains. Inreality, however, domain walls do have a finite thickness /C14,
which depends on material constants ( Zhirnov, 1959 ).Scott
(2006) observed that for each given material one could
rewrite the square root dependence as
w2
/C14d¼G; (2)
where Gis an adimensional parameter. This equation is also
useful in that it can be used in reverse in order to estimate thedomain wall thickness of any ferroic with well-definedboundary conditions ( Catalan et al. , 2007a ). Indirect versions
of it have been calculated for the specific case of ferroelec-trics ( Lines and Glass, 2004 ;De Guerville et al. , 2005 ), but in
fact Eq. ( 2) is independent of the type of ferroic and allows
comparisons between different material classes. Schilling
et al. (2006a) did such a comparison and showed explicitly
that, while all ferroics scaled with a square root law, ferro-magnetic domains were wider than ferroelectric domains.Meanwhile, the walls of ferromagnets are also much thickerthan those of ferroelectrics ( Zhirnov, 1959 ), so that when the
square of the domain size is divided by the wall thickness as
per Eq. ( 2), all ferroics look the same (see Fig. 5), meaning
FIG. 4. Kittel’s classic study of the minimum energy of different
domain configurations: I are ‘‘closure stripes’’ with no demagneti-
zation; II are conventional stripes; and III is a monodomain with the
polar direction in plane. Note that in the early calculations formagnetic domains, the conventional stripes were not stable at any
finite thickness, due to the small anisotropy assumed. From Kittel,
1946 .122 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012thatGis the same for all the different ferroics. The value of G
has been calculated ( De Guerville et al. , 2005 ;Catalan et al. ,
2007a ,2009 )1as
G¼1:765ffiffiffiffiffiffi/C31x
/C31zs
; (3)
where Gdepends on the anisotropy between in-plane ( /C31x)
and out-of-plane ( /C31z) susceptibilities, but in practice the
dependence on material properties is weak because theyare inside a square root.
Equation ( 2) is useful in several ways. First, it allows one
to estimate domain wall thicknesses just by measuring do-main sizes, and it is easier to measure wide domains than it isto measure narrow domain walls. As we discuss in thefollowing sections, domain wall thicknesses have tradition-ally been difficult to determine precisely due to their narrow-
ness (see Sec. III.B ). Second, Eq. ( 2) is also a useful guide asto what the optimum crystal thickness should be in order to
stabilize a given domain period, and this may be useful, forexample, in the fabrication of periodically poled ferroelec-trics for enhancement of the second-harmonic generation.
Specific examples of this are discussed in detail in Sec. V
of this review.
Although Eq. ( 2) may appear slightly ‘‘miraculous’’ in that
it links in a simple and useful way some quantities that are notat first sight related, closer inspection removes the mystery. Adirect comparison between Eqs. ( 1) and ( 2) shows that at
heart, the domain wall renormalization of Kittel’s law is a
consequence of the fact that the domain wall surface energydensity /C27is of the order of the volume energy density U
integrated over the thickness of the domain wall /C14, i.e.,
/C27/C24U/C14, which one could have guessed just from a
dimensional analysis. We emphasize also that these equa-tions are derived assuming open boundary conditions and
are not valid when the surface fields are screened.
D. Domains in nonplanar structures
Kittel’s simple arguments can be adapted to describe more
complex geometries. For instance, one can extend them to
calculate domain size in nonplanar structures such as nano-wires and nanocrystals or nanodots. The interest in thesethree-dimensional structures stems originally from the factthat they allow the reduction of the on-chip footprint ofmemory devices. The size of the domains in simple three-
dimensional shapes such as, say, a parallelepiped (cuboid)
can be readily rationalized by adding up the energy of thedomain walls plus the surface energy of the six faces of theparallelepiped with lateral dimensions d
x,dy, and dz.
Minimizing this with respect to domain width wleads to
(Catalan et al. , 2007b )
w2¼ffiffiffi
2p
2/C27
ðUx=dxÞþðUy=dyÞþðUz=dzÞ; (4)
where /C27is the energy per unit area of the domain walls, and
Ux,Uy, and Uzare the contributions to the volume energy
density coming from the x,y, and zfacets of the domains.
Equation ( 4) becomes the standard Kittel law when two of the
dimensions are infinite (thin-film approximation). It can alsobe seen that domains become progressively smaller as the
sample goes from thin film (one finite dimension) to column
(two finite dimensions) to nanocrystal (three finite dimen-sions) ( Schilling et al. , 2009 ).
These arguments also work for the grains of a polycrystal-
line sample (ceramic or nonepitaxial film), which are gener-ally found to have small domains that scale as the square root
of the grain size rather than the overall size dimensions ( Arlt,
1990 ). Arlt also observed and rationalized the appearance of
bands of correlated stripe domains, called ‘‘herringbone’’domains (see Fig. 6)(Arlt and Sasko, 1980 ;Arlt, 1990 ).
The concept of correlated clusters of domains was latergeneralized for more complex structures as ‘‘metadomains’’or ‘‘bundle domains’’ ( Ivry, Chu, and Durkan, 2010 ), and
their local functional response was studied using piezores-
ponse force microscopy (PFM) ( Anbusathaiah et al. , 2009 ;100101102103104105106107108
100101102103104105106100101102103104105106107w2(nm2)
Rochelle salt (ferroelectric)
Rochelle salt (ferroelectric)
Co (ferromagnetic)
PbTiO3 (ferroelectric)
PbTiO3 (ferroelectric)
BaTiO3 (ferroelastic)w2/( n m )
film thickness(nm)
FIG. 5 (color online). Comparisons between stripe domains of
different ferroic materials show (i) that all of them scale with the
same square root dependence of domain width on film thickness;
(ii) that Kittel’s law holds true for ferroelectrics down to smallthickness; (iii) that when the square of the domain size is normal-
ized by the domain wall thickness, the different ferroics fall on
pretty much the same master curve. Adapted from Catalan et al. ,
2009 .
1We note that different values have been given for the exact
numerical coefficient. The discrepancies are typically factors of 2
and are due to the different conventions regarding whether /C14is the
domain wall thickness or the correlation length, and whether wis
the domain width or the domain period. It is therefore important to
carefully define the parameters: Here /C14is twice the correlation
length (which is a good approximation to the wall thickness),whereas wis the domain size (half the domain period).G. Catalan et al. : Domain wall nanoelectronics 123
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012Ivry, Chu, and Durkan, 2010 ). Herringbone domains appear
only above a certain critical diameter, above which thedomain size dependence gets modified: The stripes scale asthe square root of the herringbone width, while the herring-bone width scales as r
2=3(where ris the grain radius), so that
the stripe width ends up scaling as r1=3(Arlt, 1990 ).
Randall and co-workers also studied in close detail the
domain size dependence within ceramic grains ( Cao and
Randall, 1996 ;Randall et al. , 1998 ) and concluded that the
square root dependence is valid only within a certain range ofgrain sizes, with the scaling exponent being smaller than
1
2for
grains larger than 10/C22m, and bigger than1
2for grains smaller
than1/C22m. The same authors observed cooperative switching
of domains across grain boundaries, as did Gruverman et al.
(1995a ,1995b ,1996) , evidence that the elastic fields associ-
ated with ferroelastic twinning are not easily screened and
can therefore couple across boundaries.
Similar ideas underpin the description of domains in nano-
columns and nanowires, where domain size is found to bewell described by Eq. ( 4) with one dimension set to infinity
(Schilling et al. , 2006b ). An interesting twist is that the
competition between domain energy and domain wall energycan be used not just to rationalize domain size, but to actuallymodulate the orientation of the domains just by changing therelative sample dimensions ( Schilling et al. , 2007 ) (see
Fig. 7).
These are a few examples, but there is still work to be done.
The geometry of domains in noncompact nanoshapes such asnanorings or nanotubes, for example, remains to be rational-ized. The interest in such structures goes beyond purelyacademic curiosity, as ferroelectric nanotubes may have
real life applications in nanoscopic fluid-delivery devicessuch as ink-jet printers and medical drug delivery implants.
Another important question that is only beginning to be
studied concerns the switching of the ferroelectric domainsin such nonplanar structures: Spanier et al. (2006) showed
that it was possible to switch the transverse polarization even
in ultrathin nanowires (3 nm diameter), while Gregg and co-
workers have shown that the longitudinal coercive field canbe modified by introducing notches or antinotches along thewires ( McMillen et al. , 2010 ;McQuaid, Chang, and Gregg,
2010 ). The same group of authors are also pioneering re-
search on the static and dynamic response of correlatedbundles of nanodomains, showing that such metadomainscan, to all intents and purposes, be treated as if they were
domains in their own right ( McQuaid et al. , 2011 ).
E. The limits of the square root law: Surface effects, critical
thickness, and domains in superlattices
In spite of its simplicity, the square root law holds over a
remarkable range of sizes and shapes. It is natural to ask when
or whether this law breaks down. For large film thicknessthere is no theoretical threshold beyond which the law shouldbreak down, and, experimentally, Mitsui and Furuichi (1953)
observed conformance to Kittel’s law in crystals of millimeter
thickness. In epitaxial thin films, however, screening effectsand/or defects have been reported to induce randomness andeven stabilize monodomain configurations in PbTiO
3films
thicker than 100 unit cells ( Takahashi et al. , 2008 ). As for the
existence of a lower thickness limit, Kittel’s derivation makesa number of assumptions that are size dependent. One of themis that the domain wall thickness is negligible in comparison
with the domain size. Domain walls are sharp in ferroelastics
and even more so in ferroelectrics ( Merz, 1954 ;Kinase and
Takahashi, 1957 ;Zhirnov, 1959 ;Padilla, Zhong, and
Vanderbilt, 1996 ;Meyer and Vanderbilt, 2002 ), so that this
assumption is robust all the way down to an almost atomic
scale ( Fong et al. , 2004 ), but this is not the case for
ferromagnets, where domain walls are thicker (10–100 nm).For ferromagnets, Kittel’s law breaks down at film thick-
nesses of several tens of nanometers ( Hehn et al. , 1996 ).
A second assumption of Kittel’s law is that the two sur-
faces of the ferroic material do not ‘‘see’’ each other. That isto say, the stray field lines connecting one domain to itsneighbors are much denser than the field lines connecting
one face of the domain to the opposite one. However, if and/
or when the size of the domains becomes comparable to thethickness of the film, the electrostatic interaction with theopposite surface starts to take over ( Kopal, Bahnik, and
Fousek, 1997 ).Takahashi et al. (2008) recently suggested
that the square root law breaks down at a precise thresholdvalue of the depolarization field. Below that critical thickness,the domain size no longer decreases but it increases again,
and diverges as the film thickness approaches zero.
Neglecting numerical factors of order unity and also neglect-ing dielectric anisotropy, the critical thickness for a ferro-electric is ( Kopal, Bahnik, and Fousek, 1997 ;Streiffer et al. ,
2002 )d
C/C25/C27ð"=P2Þ(where "¼"0"ris the average dielec-
tric constant), while for ferroelastic twins in an epitaxial
FIG. 6. (Left) Classic herringbone twin domain structure in large
grains of ferroelastic ceramics, and (right) bundles of correlatedstripes in smaller grains. From Arlt, 1990 .
x 300nm
300nmyz
dy>dxdy<dx
..
..
..
..
..z
xy
FIG. 7. Ferroelastic and ferroelectric 90/C14domains in single-
crystal nanocolumns of BaTiO 3. The domains arrange themselves
so as to have the depolarizing fields only on the narrowest dimen-sion of the column, thus minimizing the overall surface energy.
Adapted from Schilling et al. , 2007 .124 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012structure it is ( Pertsev and Zembilgotov, 1995 )dC¼
½/C27=Gðsa/C0scÞ2/C138, where Gis the shear modulus and saand
scare the spontaneous tetragonal strains (along aandcaxes,
respectively). The theoretical divergence from the square rootlaw for ferroelastic twins in epitaxial films is shown in Fig. 8.
Notice that, as a rule of thumb, these critical thicknesses
for domain formation are reached when the size of thedomains becomes comparable to the size of the interfacial
dead layers ( Luk’yanchuk et al. , 2009 ). They are typically
in the 1–10 nm range, and therefore ferroelectric andferroelastic domains persist even for extremely thin layers,as shown by Fong et al. (2004) for single films and by Zubko
et al. (2010) in fine-period superlattices.
In the particular case of epitaxial ferroelastics there are
further geometrical constraints on the domain size that are not
readily captured by continuum theories. Ferroelastic twinningintroduces a canting angle between the atomic planes ofadjacent domains. The canting angle /C11is, for the particular
case of 90
/C14twins in tetragonal materials (e.g., BaTiO 3orPbTiO 3),/C11¼90/C14/C02tan/C01ða=cÞ. The existence of this cant-
ing angle, combined with the tendency of the bigger domainsto be coplanar with the substrate, introduces a geometrical
lower limit to domain size ( Vlooswijk et al. , 2007 ): in order
to ensure coplanarity between Bragg planes across the small-est domain, the minimum domain size must be w
mina¼
c=sinð/C11Þ(see Fig. 9). For the particular case of PbTiO 3,
wmina¼7n m . This geometrical minimum domain size ap-
plies only to films that are epitaxial ( Ivry, Chu, and Durkan,
2009 ;Vlooswijk, Catalan, and Noheda, 2010 ).
F. Beyond stripes: Vertices, vortices, quadrupoles, and other
topological defects
A final question regarding the domain scaling issue con-
cerns what happens to domains beyond the square root range?Other domain morphologies are possible that can be reached
in extreme cases of confinement, or when the polarization is
coupled to other order parameters. In the ultrathin-film re-gime, for example, atomistic simulations predict that theperfect 180
/C14domains of ferroelectrics should become akin
to the closure configuration of ferromagnets ( Kornev, Fu, and
Bellaiche, 2004 ;Aguado-Fuente and Junquera, 2008 ) (see
Fig. 10). It may seem preposterous to care about a domain
structure that takes place only in films that are barely a few
unit cells thick, but with the advent of ferroelectric super-
lattices these domains become accessible, as the thickness ofeach individual layer in the superlattice can be as thin as onesingle unit cell ( Dawber et al. , 2005 ;Zubko et al. , 2010 ). In
the weak-coupling regime, the ferroelectric slabs within the
superlattice act as almost separate ultrathin entities(Stephanovich, Luk’yanchuk, and Karkut, 2005 ), so that it
is quite possible that these closure stripes are achieved. It is
worth noticing that the orientation of the in-plane component
of the polarization is such that, if the domain walls werepushed toward each other, there would be a head-to-headcollision of polarizations; the electrostatic repulsion between
these in-plane components might explain why it seems to be
almost impossible to eliminate the domain walls in ferroelec-tric superlattices ( Zubko et al. , 2010 ).
On a related note, while the 180
/C14domain walls of ferro-
electrics have traditionally been considered nonchiral (i.e.,
the polarization just decreases, goes through zero, and in-
creases again, but does not change orientation through thewall), recent calculations challenge this view and show thatthey do have some chirality, i.e., the polarization rotates
within them as in a magnetic Bloch wall ( Lee et al. , 2009 ).
Therefore, when the domains are sufficiently small to becomparable to the thickness of the walls, the end result willbe indeed something resembling the closure stripe configu-
ration of Fig. 10. The existence of this domain wall chirality
might seem surprising, but it was explained two decadesago by Houchmandzadeh, Lajzerowicz, and Salje (1991) :I f
there is more than one order parameter involved in a
ferroic (and perovskite ferroelectrics are always ferroelastic
as well as ferroelectric), then the coupling introduces chi-rality. This, of course, is also true of magnetoelectric multi-ferroics ( Seidel et al. , 2009 ;Daraktchiev, Catalan, and Scott,
2010 ). The theoretical prediction of ferroelectric closurelike
structures where domain walls meet an interface has been
FIG. 9 (color online). Schematic of the geometrical minimum
domain size in a tetragonal twin structure such that widercdomains are coplanar with the substrate while the narrow
adomains are tilted with the inherent twinning angle /C11. From
Vlooswijk, Catalan, and Noheda, 2010 .
FIG. 8. Calculated domain size for 90/C14ferroelastic domains in an
epitaxial film as a function of film thickness. Below a certain critical
thickness the domain size stops following the square root depen-dence and begins to diverge. This critical thickness is of the order of
the domain wall thickness. From Pertsev and Zembilgotov, 1995 .G. Catalan et al. : Domain wall nanoelectronics 125
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012experimentally confirmed by two different groups ( Jiaet al. ,
2011 ;Nelson et al. , 2011 ) (see Fig. 11).
It is worth noticing here that the arrangements in Fig. 11
are not a classic fourfold closure structure, with four walls at90
/C14converging in a central vertex. Instead, these domain
structures should be seen as half of a closure quadrant. Thebifurcation of a quadrant into two threefold vertices, withwalls converging at angles of 90
/C14and 135/C14, was predicted by
Srolovitz and Scott (1986) ; their schematic depiction of the
bifurcation process is reproduced in Fig. 12. The reverse
process of coalescence of two threefold vertices to formone fourfold vertex, also predicted by Srolovitz and Scott,
was recently observed in BaTiO 3by Gregg et al. (private
communication). Vertices are a topological singularity
closely related to vortices, the main difference being that avortex implies flux closure, whereas a vertex is just a con-fluence of domain walls; some vertices are also vortices (e.g.,the vertices of 90
/C14closure quadrants in ferromagnets and
ferroelectrics), but others are not.
Vortices are frequently observed in ferromagnetic nanodots
(Shinjo et al. , 2000 ). At the vortex core, the spin must
necessarily point out of the plane of the nanodot: This out-of-plane magnetic singularity is extremely small, yet stable,and could therefore be useful for memories. Ferroelectricvortices are also theoretically possible ( Naumov, Bellaiche,
and Fu, 2004 ), and Naumov and co-workers predicted that
such structures are switchable and should yield an unusuallyhigh density of ‘‘bits’’ for memory applications ( Naumov
et al. , 2008 ).
So far, there is tantalizing experimental evidence for vor-
tices in ferroelectrics ( Gruverman et al. , 2008 ;Rodriguez
et al. , 2009 ;Schilling et al. , 2009 ). However, although
vortices almost certainly appear as transients during switch-
ing ( Naumov and Fu, 2007 ;Gruverman et al. , 2008 ;Sene
et al. , 2009 ), it is difficult to observe static ferroelectric
vortices, or even just closure structures, in conventionaltetragonal ferroelectrics. This is because a simple quadrantarrangement generates enormous disclination strain ( Arlt and
Sasko, 1980 ) (see Fig. 13); for dots above a certain critical
FIG. 11 (color online). Observation of closurelike polar arrange-
ments at the junction between ferroelectric domain walls and aninterface, for thin films of BiFeO
3(left) and PbTiO 3(right). Note
that the wall angles are 135/C14,90/C14,135/C14, as in the Srolovitz-Scott
model, not 120/C14. Adapted from Nelson et al. , 2011 (left) and Jia
et al. , 2011 (right).
FIG. 12. A fourfold vertex in a 90/C14quadrant is predicted by a
Pott’s model to bifurcate into two threefold vertices. From Srolovitz
and Scott, 1986 .Above Tc Below Tc
FIG. 13. (Left) Schematic illustration of the disclination stresses
that are generated in the center of a closure structure of a tetragonal
ferroelectric or ferroelastic; (right) experimental observation that
ferroelastic stripes appear within the quadrants, probably in order toalleviate the stress. Adapted from Schilling et al. , 2009 .
FIG. 10 (color online). Ferroelectric ‘‘closure stripes’’ predicted by atomistic simulations of ultrathin films. From Kornev, Fu, and
Bellaiche, 2004 andAguado-Fuente and Junquera, 2008 .126 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012size, alleviation of associated stresses will be provided by the
formation of ferroelastic stripe domains within each quadrant.A back-of-the-envelope calculation allows us to estimate thesize at which the stripes will break the quadrant configuration.
We do so by comparing the elastic energy stored within a
single quadrant domain with the energy cost of a domainwall. The dimensions of the nanodot are L/C2L/C2d,Gis the
elastic shear modulus, and "is the disclination strain, which
is of the same order of magnitude as the spontaneous strain.The elastic energy density stored in a quadrant of volume
L
2d=4is given by
Eelastic¼1
2Gs2L2d
4: (5)
The energy cost of the first wall to divide the quadrant is the
surface energy density of the wall ( /C27) times the area of the
new domain wall:
Ewall¼/C27ffiffiffi
2p
2Ld: (6)
When these two quantities are equal, the quadrant configura-
tion stops being energetically favorable. By making Eelastic¼
Ewallwe therefore obtain an approximate critical size
L¼4ffiffiffi
2p/C27
Gs2; (7)
which, for the case of BaTiO 3(G¼55 GPa ,/C27¼
3/C210/C03J=m2, and s¼0:01), gives a critical size of only
3 nm. That small size explains why in larger ferroelectricnanocubes one observes a quadrantlike structure split bymultiple ferroelastic stripes ( Schilling et al. , 2009 ) (see
Fig. 13). More recently, ferroelectric flux closure has been
confirmed in metadomain formations consisting of finely
twinned quadrants ( McQuaid et al. , 2011 ).
Equation ( 7) shows that, in order to find a ‘‘pure’’ (non-
twinned) ferroelectric quadrant structure, one will have tolook for ferroelectrics with small spontaneous strain and highdomain wall energy. BiFeO
3has a large domain wall energy
(Catalan et al. , 2008 ;Lubk, Gemming, and Spaldin, 2009 )
due to the coupling of polarization to antiferrodistortive andmagnetic order parameters ( BiFeO
3is simultaneously ferro-
electric, ferroelastic, ferrodistortive, and antiferromagnetic),while at the same time its piezoelectric deformation is small.That helps stabilize closure structures in this material ( Balke
et al. , 2009 ;Nelson et al. , 2011 ).
In purely magnetic materials, of course, vortex domains
are well known and even their switching dynamics are nowbeing studied, as illustrated in Fig. 14: Note that this figure
shows that one can create magnetic vortex domains by re-petitive application of demagnetizing fields to single-domainsoft magnets. Similarly, Ivry et al. (2010) observed that
application of depolarizing electric fields has a similar effect
in ferroelectrics.
As mentioned earlier, a close relative of vortices and
closure domains is what we call ‘‘vertex’’ domains. A vertexis the intersection between two or more domain walls in aferroic. In the classic quadrant structure, the vertex is a four-fold intersection between 90
/C14domains, while in a needle
domain the vertex is a twofold intersection. It is important to
note that each of the domain walls intersecting the vertex isequivalent through symmetry; that is, they cannot be different
walls, such as (011) and (031), a point to which we return
below. Using topological arguments, Janovec (1983) showed
that the number Nof domain walls intersecting at the vertex is
equal to the dimensionality of the order parameter. Janovec
and Dvorak further developed the theory in a longer review in
1986. However, complicating the general theory of Janovec is
the fact that several order parameters might coexist (as inmultiferroic materials), and that the domains do not neces-
sarily have the same energy.
The energetics and stability of vertex domains were ana-
lyzed by Srolovitz and Scott (1986) using Potts and clock
models. They showed that fourfold vertices, such as are found
inBa
2NaNb 5O15(Pan et al. , 1985 ) can, in some materials,
spontaneously separate into pairs of adjacent threefold verti-
ces. There is an apparent paradox regarding closure domainsbetween the group theoretic predictions of Janovec (1983)
andJanovec and Dvorak (1986) , and the clock-model calcu-
lations of Srolovitz and Scott (1986) . In particular, Janovec
states that threefold closure vertices are forbidden, whereas
Srolovitz and Scott show that they may be energetically
favored over fourfold vertices. The paradox is reconciled as
follows: What Janovec specifically forbids are isolated three-
fold vertices with three 120
/C14angles between the domain
walls. What Scott and Srolovitz predict is a separation of
energetically metastable fourfold vertices into closely spaced
pairs of threefold vertices; but these pairs each consist of one
original 90/C14angle between domain walls, and two 135/C14
angles along the line between the vertex pairs. Hence this
FIG. 14. Dynamic response of magnetic vortices, from the work
of Cowburn’s and co-workers: (a)–(e) Hysteresis curves showing the
decay of a single-domain state into a vortex state via a series of
minor hysteresis cycles. The entire decay process is shown in (a).The arrowed solid line indicates the direction of the transition fromsingle domain to vortex state. The dashed line outlines the Kerr
signal corresponding to the positive and negative applied saturation
fields. The first three and the last demagnetizing cycles are dis-played in separate panels; (b) first cycle, (c) second cycle, (d) third
cycle, and (e) 18th cycle. From Ana-Vanessa, Xiong, and Cowburn,
2006 .G. Catalan et al. : Domain wall nanoelectronics 127
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012should properly be regarded as not a threefold domain vertex
but rather a fourfold vertex that has separated slightly at itscenter. This phenomenon is analogous to the separation of thefourfold closure domains in BaTiO
3.
Another example of vertex structures that does not satisfy
the basic model of Janovec is that in thiourea inclusion
compounds ( Brown and Hollingsworth, 1995 ). In this case
inclusions in a thiourea matrix result in large strains (straincoupling is not directly included in the Janovec model). Theresult, illustrated in Fig. 15, is a beautiful 12-fold vertex
structure. Note that this is despite the fact that the orderparameter is of N¼2dimensions in thiourea ( Toledano
and Toledano, 1987 ). The reason is strain. The domain cluster
shown in thiourea is of domain walls of different symmetry,notably f130gandf110g. Yet another example of domain wall
vertices is provided by the charge density wave domainsobserved by Chen, Gibson, and Fleming (1982) in
2H-TaSe
2(see Fig. 15); this system, with three spatial in-
plane orientations and þand/C0out-of-plane distortions, is
equivalent to ferroelectric YMnO 3. Both violate the simpler
requirement described by Janovec (1983) that the number of
domains Nat a vertex must equal the dimensionality nof the
order parameter and require incorporation of coupling termsplus energy considerations to determine the equilibriumstructure, as done by Janovec et al. (1985 ,1986) .O na
more general level, Saint-Gregoire et al. (1992) showed
that domain wall vertex structure classifications consist of36 twofold vertices with five equivalence classes, 96 fourfoldvertices of ten classes, and 63 sixfold vertices of nine classes.
It is notable that, even where walls carrying opposite þP
zand
/C0Pzpolarizations meet, the vertex can still have a polar point
group (rod) symmetry, which is not intuitively obvious, butcan be useful as these rods are analogous in this respect to thepolar singularity at the core of a vortex. Note also that the so-called layer groups, such as 2
z0, keep the central plane of a
wall invariant, whereas the other groups do not. Rod groups
can be chiral; for example, a regular sixfold vertex withsymmetry 6
z0has a helical structure with polarization along
z. There are two equivalent sixfold vertices with the same
helicity by opposite polarization; the chirality does not dictatethe polarization.
This situation is also encountered in multiferroic YMnO
3.
Although the sixfold vertices of YMnO 3were observed long
ago by Safrankova, Fousek, and Kizhaev (1967) , interest has
been rekindled by more recent studies studying these forma-tions in detail ( Choi et al. , 2010 ;Jungk et al. , 2010 ) (see
Fig.16). The correct domain analysis requires the tripled unit
cell of Fennie and Rabe (2005) for proper description, and not
the simpler primitive cell proposed by Van Aken et al.
(2004) . The coupling of ferroelectricity to the other order
parameters (antiferromagnetic and antiferrodistortive) yieldsthe required dimensionality for the sixfold vertices toform. YMnO
3is also interesting because its domain walls
are less conducting than the domains ( Choi et al. ,2 0 1 0 ),
which is the exact opposite of what happens in the otherpopular multiferroic, BiFeO
3(Seidel et al. ,2 0 0 9 ). The issue
of domain wall conductivity is extensively discussed in latersections.
Recently, the functional properties of vertices and vortices
are also starting to be studied. In the case of BiFeO
3, for
example, it has been found that the conductivity of ferroelec-tric vortices is considerably higher than that of the domainwalls, which are in turn more conductive than the domains(Balke et al. , 2011 ).
G. Nanodomains in bulk
Kittel’s law implies that small domains can appear in small
or thin samples, but nanodomains occur in some bulk com-positions. Trivially, any material with a first-order phasetransition will experience the nucleation of small nonperco-lating domains above the nominal T
c. In the case of BaTiO 3,
these can occur more than 100/C14above Tc(Burns and Dacol,
1982 ). This, however, has little implication for the functional
FIG. 15 (color online). (Left) Twelvefold ferroelectric domain
vertex in thiourea. From Brown and Hollingsworth, 1995 . (Right)
Sixfold vertex intersection between charge density wave domains in2H-TaSe
2(Chen, Gibson, and Fleming, 1982 ). Schematic in (a) and
actual microscopy image in (b). These formations are topologically
equivalent to the vertex domains YMnO 3.
FIG. 16 (color online). Observation of sixfold vertices in domain ensembles of multiferroic YMnO 3: (left) from Safrankova, Fousek, and
Kizhaev, 1967 ; (middle) from Choi et al. , 2010 , and (right) from Jungk et al. , 2010 .128 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012properties because the volume fraction occupied by such
nanodomains is small. But there are other material familieswhere nanodomains are inherent. These are nearly alwayslinked to systems with competing phases and frustration, andthe functional properties of nanoscopically disordered mate-rials are often striking: colossal magnetoresistance in man-
ganites, superelasticity in tweedlike martensites, and giant
electrostriction in relaxors, to name a few.
Relaxors combine chemical segregation at the nanoscale
and nanoscopic polar domains ( Cross, 1987 ;Bokov and Ye,
2006 ). The key technological impact of these materials lies in
their large extension under applied fields for piezoelectricactuators and transducers ( Park and Shrout, 1997 ). Despite
many papers on the basic physics of relaxor domains, aholistic theory is still missing. The presence of polar domainsin the cubic phases of relaxors, where they are nominallyforbidden, may be caused by flexoelectricity and internalstrains due to local nonstoichiometry ( Ahn et al. , 2003 ).
When mixed with ordinary ferroelectrics such as PbTiO
3,o r
subjected to applied fields E, these nanodomains increase in
size to become macroscopic ( Mulvihill, Cross, and Uchino,
1995 ;Xu et al. , 2006 ). As for the shape of the domains, in
pure PbZn 1=3Nb2=3O3(PZN), the domain walls may be
spindlelike ( Mulvihill, Cross, and Uchino, 1995 ) or dendritic
(Liu, 2004 ) but become increasing lamellar with increasing
additions of PbTiO 3. The condensed h110idomain structure
is stable in perovskites and rather unresponsive to fields E
along [111] ( Xuet al. , 2006 ), and the polar nanoregions arise
from a condensation of a dynamic soft mode along [110], asshown via neutron spin-echo techniques ( Matsuura et al. ,
2010 ). Multiferroic (magnetoelectric) relaxors also exist
(Levstik et al. , 2007 ;Kumar et al. , 2009 ), but little is yet
known about their domains.
From the perspective of this review, the key point about
relaxors is that, since they are formed by nanodomains, theymust have a large concentration of domain walls. It is there-fore reasonable to expect that the domain walls contribute to
the extraordinary electromechanical properties of these ma-
terials. Rao and Yu (2007) show that indeed there is an
inverse correlation between domain size and piezoelectricbehavior, and suggest that the linking mechanism is a field-induced broadening of the domain walls. On the other hand,domain walls may contribute not only by their static proper-ties or broadening, but also by their dynamic response(motion) under applied electric fields, as suggested by the
Rayleigh-type analyses of Davis, Damjanovic, and Setter
(2006) andZhang et al. (2010) .
Polar nanodomains also exist in another nonpolar material,
SrTiO
3, which is important as it is the most common substrate
for growing epitaxial films of other perovskites. SrTiO 3is
cubic at room temperature, but tetragonal and ferroelastic
below 105–110 K ( Fleury, Scott, and Worlock, 1968 ). It is
also an incipient ferroelectric whose transition to a macro-
scopic ferroelectric state is frustrated by quantum fluctuationsof the soft phonon at low temperature; hence, the material is
also called a ‘‘quantum paraelectric’’ ( Muller and Burkard,
1979 ). By substituting the oxygen in the lattice for a heavier
isotope,
18O, the lattice becomes heavier, and the phonon
slows down and freezes at a higher temperature, causing aferroelectric transition ( Itoh et al. , 1999 ). However, polar
nanodomains have been detected even in the normal
16O
composition of SrTiO 3(Uesu et al. ,2 0 0 4 ;Blinc et al. ,
2005 ), and their local symmetry is triclinic and not tetragonal
(Blinc et al. , 2005 ). The ferroelectric phase of the heavy-
isotope composition is also poorly understood, but it has
finely structured nanodomains reminiscent of those observed
in relaxors ( Uesu et al. , 2004 ;Shigenari et al. , 2006 ), while
relaxorlike behavior has also been observed in SrTiO 3thin
films ( Jang et al. , 2010 ). Again, the high concentration of
domain walls concomitant with this fine domain structure
shows important implications for functionality, since the
domain walls of SrTiO 3are thought to be polar ( Tagantsev,
Courtens, and Arzel, 2001 ;Zubko et al. , 2007 ). We also note
thatSrTiO 3at low temperatures has giant electrostriction
comparable to that observed in relaxor ferroelectrics ( Grupp
and Goldman, 1997 ).
The above are examples of nanodomains that appear spon-
taneously in some special materials. But nanodomains canalso be made to appear in conventional ferroelectrics by
clever use of poling. Fouskova, Fousek, and Janous ˇek estab-
lished that domain wall motion enhanced the electric-field
response of ferroelectric material ( Fouskova, 1965 ;Fousek
and Janous ˇek, 1966 ), and domain engineering of crystals
yields a piezoelectric performance far superior to that of
normal ferroelectrics ( Zhang et al. , 1994 ;Eng, 1999 ;
Bassiri-Gharb et al. , 2007 ). However, a newer and more
relevant twist is that even static domain walls may signifi-
cantly enhance the properties of a crystal, due to the superior
FIG. 17 (color online). Measurements and calculations relating decreased domain size (and thus increased domain wall concentration) to
enhancement of piezoelectricity in BaTiO 3single crystals. The results suggest that the increased piezoelectric coefficient is due to the internal
piezoelectricity of the domain walls. From Hlinka, Ondrejkovic, and Marton, 2009 .G. Catalan et al. : Domain wall nanoelectronics 129
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012piezoelectric properties of the domain wall itself (see
Fig. 17). The concept of ‘‘domain wall engineering’’ was
introduced by Wada and co-workers as a way to enhance thepiezoelectric performance of ferroelectric crystals ( Wada
et al. , 2006 ). At present, however, the size or even the exact
mechanism whereby domain walls contribute to the piezo-electric enhancement is still a subject of debate ( Hlinka,
Ondrejkovic, and Marton, 2009 ;Jin, He, and Damjanovic,
2009 ).
H. Why does domain size matter?
The above is a fairly comprehensive discussion of the
scaling of domains with device size and morphology. Themain take-home message is that, as device size is reduced,domain size decreases in a way that can often be described by
Kittel’s law in any of its guises. Thus, the concentration of
domain walls will increase. We can quantify this domain wallconcentration fairly easily: Let us just rearrange the terms ofthe ‘‘universal’’ Kittel’s law, [Eq. ( 2)]:
/C14
w¼ffiffiffiffiffiffiffi
/C14
Gds
: (8)This equation shows that, as the film thickness ddecreases,
the fraction /C14=w (i.e., the fraction of the material that is made
of domain walls) increases. Taking standard values for the
domain wall thickness /C14(typically 1–10 nm), we can see that,
for 100-nm-thick films, between 6% and 20% of the film’s
volume will be domain walls. Of course, as mentioned before,this percentage assumes that the surface energy is
unscreened, so a correction factor must be applied when there
is partial screening (the most general case). However, Eq. ( 8)
is not completely unrealistic: Strain, for example, cannot be
screened at all, and therefore ferroelastic domains (which inperovskite multiferroics tend to be ferroelectric and/or mag-
netic as well) can indeed be small. By way of illustration,
consider the extremely dense ferroelastic domain structure in
Fig. 18.
The high concentration of domain walls is important be-
cause domain walls not only have different properties from
domains but, for specific applications, they can in fact be
better ( Wada et al. , 2006 ). A sufficiently large number
density of walls can therefore lead to useful emergent behav-
ior in samples with nanodomains. This idea is barely in itsinfancy, but already there are hints that it could work.
Daumont and co-workers, for example, report a strong corre-
lation beween the macroscopic magnetization of a nominally
antiferromagnetic thin film, and its concentration of domain
walls (see Fig. 18).
The rest of this review will discuss the properties of
domain walls, the experimental tools used to characterize
them, and their possible technological applications.
III. DOMAIN WALLS
A. Permissible domain walls: Symmetry and compatibility
conditions
Polar ferroics are those for which an inversion symmetry is
broken: space inversion for ferrroelectrics or time inversion
for ferromagnets. In these cases, domain walls separating
regions of opposite polarity are possible, and they are called
180/C14walls (in reference to the angle between the polar
vectors on either side of the wall). 180/C14walls tend to be
parallel to the polar axis, so as to avoid head-to-head con-
vergence of the spins or dipoles at the wall, as these are
energetically costly due to the magnetic or electrostatic re-
pulsion of the spins or dipoles. It is nevertheless worth
mentioning that, although energetically costly, head-to-head180
/C14walls are by no means impossible. 180/C14head-to-head
domains have been studied for decades in ferroelectrics.
When they annihilate each other, large voltage pulses are
emitted, called ‘‘Barkhausen pulses’’ ( Newton, Ahearn, and
McKay, 1949 ;Little, 1955 ); these voltage spikes are orders of
magnitude larger than thermal noise. Most recently, head-to-
head (charged) 180/C14walls have been directly visualized
using high-resolution transmission electron microscopy and
found to be about 10 times thicker than neutral walls ( Jia
et al. , 2008 ) (see Fig. 19). The difference in thickness be-
tween neutral and charged walls was historically first ob-
served by Bursill, who noted the bigger thickness of thelatter ( Lin and Bursill, 1982 ;Bursill, Peng, and Feng, 1983 ;
Bursill and Peng, 1986 ). According to Tagantsev (2010) , this
FIG. 18 (color online). (Top) The ferroelastic domains of ortho-
rhombic TbMnO 3film grown on cubic SrTiO 3are so small
(/C255n m ) as to be comparable to the domain wall thickness, so
that approximately 50% of the material is domain wall. (Bottom)
The same authors report a strong correlation between inverse
domain size (and thus domain wall concentration) and remnantmagnetization in the films. From Daumont et al. , 2009 ,2010 .130 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012increased thickness is due to the aggregation of charge car-
riers at the wall in order to screen the strong depolarizing fieldof the head-to-head dipoles. An interesting corollary to thisobservation is that the thickness of charged domain walls insemiconducting ferroelectrics will be different depending on
whether they are head to head or tail to tail, due to the
different availability of majority carriers; for example, in ann-type semiconductor, there is an abundance of electrons, and
so head-to-head domain walls can be efficiently screened,while tail-to-tail cannot, meaning that the latter will bebroader ( Eliseev et al. , 2011 ). Domain wall thickness is
further discussed in Sec III.B .
The order parameter in ferroelastic materials is the sponta-
neous strain, which is not a vector but a second-rank tensor.Since the spontaneous strain tensor does not break inversion
symmetry, purely ferroelastic materials do not have 180
/C14
domains. Instead, a typical example of ferroelastic domains
(also called twins) is the 90/C14twins in tetragonal materials,
where the spontaneous lattice strains in adjacent domains areperpendicular. In the case of 90
/C14domains, the locus of the
wall is the bisector plane at 45/C14with respect to the f001g
planes, because along these planes the difference between the
spontaneous strains of the adjacent domains is zero, and thus
the elastic energy cost of the wall is minimized (also knownas the invariant plane). In the case of multiferroics that aresimultaneously ferroelectric and ferroelastic, the polar com-patibility conditions (e.g., no head-to-head polarization) mustbe added to the elastic ones. Fousek and Janovec did preciselythat and compiled a table of permissible domain walls in
ferroelectric and ferroelastic materials ( Fousek and Janovec,
1969 ;Fousek, 1971 ). Whenever the domains are in an epi-
taxial thin film, there are further elastic constraints imposed
by the substrate, as analyzed in the paper by Speck and
Pompe (1994) . A case study of permissible walls in epitaxial
thin films of rhombohedral ferroelectricis was done by
Streiffer et al. (1998) , and this is relevant for BiFeO
3(space
group R3c). In this case, the polar axis is the pseudocubic
diagonal h111i, and domain walls separating inversions of
one, two, or all three of the Cartesian components of thepolarization are possible (these are called, respectively, 71
/C14,
109/C14, and 180/C14walls).
More generally, Aizu (1970) explained that the number of
ferroic domain states, and thus of possible domain walls, is
given by the ratio of the point group orders of the high- and
low-symmetry phases, although Shuvalov, Dudnik, and
Wagin (1985) argued that a higher number of domains
(‘‘superorientational states’’) may be permissible than given
by the Aizu rule, as indeed observed in ferroelastic
YBa 2Cu3O7/C0/C14(Schmid et al. , 1988 ). Another important
rule is given by Toledano (1974) : It is necessary and sufficient
for ferroelastic phase transitions that the crystal undergoes a
change in crystal class (trigonal and hexagonal is regarded as
a single superclass in this argument). The converse of that
rule is that if there is no change in crystal class, then thematerial is not ferroelastic, and thus naturally there will not be
any ferroelastic twin walls. Further restrictions apply to the
type of domain walls that can exist in magnetoelectric mate-
rials ( Litvin, Janovec, and Litvin, 1994 ).
Because these rules place strict conditions on what types
of walls can exist in a ferroic, domain wall taxonomy can
help clarify not only the true symmetry of the ferroic phase
in a material, but also its relationship with the paraphase. Anillustrative example is yet again BiFeO
3: The classification
of its domain walls allowed the determination that the high-
temperature /C12phase (above 825/C14C) was orthorhombic
(Palai et al. ,2 0 0 8 ). The existence of orthorhombic twins
was also used by Arnold et al. (2010) to argue that the
highest-symmetry phase of BiFeO 3should be cubic, even
though this cubic phase may be ‘‘virtual,’’ as it probably
occurs above the (also orthorhombic) /C13phase and beyond
the melting temperature in most samples; however, Palai
et al. (2010) found Raman evidence that a reversible
orthorhombic-cubic transition exists in some specimens.
The determination of this ‘‘virtual paraphase’’ is not trivial,since previously other authors had argued that the ultimate
paraphase of BiFeO
3should be hexagonal R3c,a si n
LiNbO 3(Ederer and Fennie, 2008 ), which is likely incorrect.
The correct determination of the paraphase symmetry is of
utmost importance because polar displacements are mea-sured with respect to it.
B. Domain wall thickness and domain wall profile
Experimentally, domain wall thicknesses can be measured
accurately only by using atomic-resolution electron micros-
copy techniques. Theoretical estimates can be obtained usinga variety of methods, ranging from ab initio calculations
to phenomenological treatments or pseudospin models. We
FIG. 19 (color online). High-resolution transmission electron mi-
croscopy image of a head-to-head charged domain wall in ferro-electric PbðZr;TiÞO
3. The domain wall is found to be approximately
10 unit cells thick, which is about 10 times thicker than for normal
(noncharged) ferroelectric domain walls. From Jia et al. , 2008 ,
Nature Publishing Group.G. Catalan et al. : Domain wall nanoelectronics 131
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012begin this section by offering a simple physical model that
captures the essential physics of domain wall thickness.
The volume energy density of any ferroic material has at
least two components: one from the ordering of the ferroic
order parameter, and one from its gradient. Inside the do-
mains, there is no gradient, and so only the homogeneous partof the energy has to be considered. The leading term in thisenergy is quadratic: U¼
1
2/C31/C01P02for ferroelectrics,
1
2/C22/C01M02for ferromagnets, and1
2Ks02, where Kis the elastic
constant and s0is the spontaneous strain. Meanwhile, inside
the domain walls there is a strong gradient whose energy
contribution is also quadratic, since it obviously cannot de-pend on whether you cross the wall from left to right orvice versa. Although the exact shape of the gradient is bestdescribed as a hyperbolic tangent, as a first approximationone can linearize the polarization profile across the wall asPðxÞ¼P
0½x=ð/C14=2Þ/C138(/C0/C14=2<x< /C0/C14=2). In this linearized
approximation, the gradient is simply the switched polariza-
tion (or magnetization, or strain) divided by the wall thick-ness, and hence the gradient energy can be approximated as
1
2kð2P0=/C14Þ2(where kis the gradient coefficient or ‘‘ex-
change’’ constant, since it measures the energy cost of locally
changing the order parameter with respect to its nearest
neighbors). Although in this discussion we use polarization
as an example, all the equations and conclusions are valid forany other type of ferroic material.
The wall also has a contribution from the ferroic ordering,
which changes across the wall: It is zero exactly at the centerof the wall and it grows to reach the saturation value at the
beginning and end of the wall. The energy density per unit
area of the wall is obtained by integrating the two energyterms across its thickness. Hence,
/C27¼Z
/C14=2
/C0/C14=2/C201
2k/C182P0
/C14/C192
þ1
2/C31/C01PðxÞ2/C21
dx
¼2kP02
/C14þ1
6/C31/C01P02/C14: (9)
The actual domain wall thickness will be that which mini-
mizes this domain wall energy density; hence
@/C27
@/C14¼0¼/C02kP02
/C142þ1
6/C31/C01P02; (10)
which leads to
/C14¼2ffiffiffi
3pffiffiffiffiffiffi
k/C31p
: (11)
More elaborate phenomenological treatments are based on
Landau theory ( Zhirnov, 1959 ), the simplest potential being
G¼a
2P2þb
2P4þk
2/C18@P
@x/C192
: (12)
Variational minimization of the order parameter across a
domain wall at x¼0yields tanhðx=/C21Þ, with the correlation
length /C21¼2P/C01
0ffiffiffiffiffiffiffiffiffiffiffi
2k=bp
. Using P0¼ffiffiffiffiffiffiffiffiffiffiffiffiffi
/C0a=bp
and/C31¼
/C01=2aand defining the domain wall thickness as /C14¼2/C21,
we get
/C14¼2ffiffiffiffiffiffiffiffiffiffi ffi
/C02k
as
¼4ffiffiffiffiffiffi
/C31kp
: (13)Note the remarkable similarity between Eqs. ( 11) and ( 13),
despite the linear simplification assumed in the former.
An issue that appears to have been neglected by most [but
not all, see Tagantsev, Courtens, and Arzel (2001) ] phenome-
nological analyses of ferroelectric and ferroelastic domainwalls is that the existence of large strain gradients at the walls
must necessarily lead to considerable flexoelectricity inside
them. Zubko (2008) performed some preliminary calculations
for the gradients inside the ferroelastic domain walls ofSrTiO
3, using the strain profile calculated by Cao and
Barsch (1990) . The results are shown in Fig. 20. Assuming
a ferroelastic correlation length /C24/C244/C23A(one unit cell) and a
flexoelectric coefficient of 10/C08(Zubko et al. , 2007 ) (mea-
sured at room temperature and therefore smaller than the low-
temperature value), the flexoelectric polarization in the
middle of the domain wall is of the order of 5m C =m2
(0:5/C22C=cm2), which is not negligible. This is only an
approximate result, however, because the flexoelectric inter-
action must be incorporated into the domain wall structurecalculations in a self-consistent manner, rather thana posteriori . We parenthetically note that strain gradients
are significant at the nanoscale, and therefore flexoelectric
effects are expected to be important. The large flexoelectriceffects associated with nanodomains in ferroelectric thin
(a)
(b)
FIG. 20 (color online). (a) Ferroelastic strain components in the
low-temperature domain walls of SrTiO 3and (b) flexoelectric polar-
izations caused by the strain gradients in the walls. From Zubko,
2008 .132 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012films are currently being studied by several groups ( Catalan
et al. , 2011 ;Lee et al. , 2011 ;Luet al. , 2011 ).
At any rate, putting typical values into Eq. ( 13), it is found
that ferroelectrics and ferroelastics have typical domain wall
thicknesses in the range of 1–10 nm, whereas ferromagnetshave typically thicker walls in the range 10–100 nm. Thisdifference in thickness is not entirely surprising: Wall thick-ness is given by the competition between exchange andanisotropy (in ferromagnets) with the corresponding terms
being dipolar energy and elastic anisotropy energy (in ferro-
electrics). The exchange constant measures the energy cost oflocally changing a spin, a dipole, or an atomic displacement(depending on the type of ferroic) with respect to its neigh-bors; in phenomenological treatments this was introduced as
the energy cost of creating a gradient in the ferroic order
parameter, exchange ¼ðk=2ÞðrPÞ
2. If this energy is big, the
ferroic will try to reduce the size of the gradient by increasingthe thickness of the domain wall.
Likewise, the softness of the order parameter (its suscep-
tibility) will also tend to broaden the walls: A material that
has high susceptibility, dielectric, magnetic, or elastic, allows
its order parameter to fluctuate more easily, meaning thatbroad domain walls, with a large number of unit cells de-parted from the equilibrium value, are still relatively cheap.Zhirnov (1959) offered a similar argument: The anisotropy
measures the energy cost of misaligning the order parameter
with respect to the crystallographic polar axes; if this energyis big, the ferroic will try to minimize the number of mis-aligned spins, dipoles, and strains by making the wall as thinas possible. Because both ferroelectricity and ferroelasticityare, at heart, structural properties, their anisotropy (arising
from structural anisotropy such as, e.g., the tetragonality of a
perovskite ferroelectric) will normally be larger than that offerromagnets, and thus their wall thickness will be smaller.Hlinka (2008) andHlinka and Marton (2008) have recently
discussed the role of anisotropy on the domain wall thickness
of the different phases of ferroelectric BaTiO
3. The anisot-
ropy argument is completely analogous to the susceptibilityone, just by realizing that susceptibility is inversely propor-tional to anisotropy. It follows from the above that materialsthat are uniaxial and have small susceptibility should have far
narrower domain walls than ferroics with several easy axes
(so that they are more isotropic) and large permittivity; inparticular, one may expect morphotropic phase boundaryferroelectrics to have anomalously thick domain walls, sothat a significant volume fraction of the material may be madeof domain walls. This is also the case for ultrasoft magnetic
materials such as permalloys, or structurally soft materials
such as some martensites and shape-memory alloys ( Ren
et al. , 2009 ).
Domain wall thickness has traditionally been a contentious
issue for ferroelectrics, where it has been hard to measure
experimentally. The earliest electron microscopy measure-
ments were reported by Blank and Amelinckx (1963) , and
they placed an upper bound of 10 nm on the 90
/C14wall
thickness of barium titanate. Bursill and co-workers ( Lin
and Bursill, 1982 ;Bursill, Peng, and Feng, 1983 ,Bursill
and Lin, 1986 ) used high-resolution electron microscopy to
confirm that the domain walls of LiTaO 3andKNbO 3are
indeed thin and atomically sharp in the case of 180/C14walls.Meanwhile, Floquet et al. (1997) combined high-resolution
transmission electron microscopy with x-ray diffraction tomeasure a width of 5 nm for the 90
/C14walls of BaTiO 3.Shilo,
Ravichandran, and Bhattacharya (2004) used atomic force
microscopy (AFM) to measure the same type of walls in
PbTiO 3; although the tip radius of scanning probe micro-
scopes (AFM, PFM) is typically 10 nm, a careful statisticalanalysis allowed the intrinsic domain widths of ferroelectricand ferroelastic 90
/C14walls to be extracted; a wide range of
thicknesses between 1 and 5 nm were recorded. They sug-
gested that the intrinsic width is less than 1 nm, and that the
broadening observed in some measurements is due to theaccumulation of point defects at the wall. The thickness offerroelectric 180
/C14walls is harder to measure experimentally
and is discussed in more detail in Sec. IV, but reliable
theoretical predictions ( Merz, 1954 ;Kinase and Takahashi,
1957 ;Padilla, Zhong, and Vanderbilt, 1996 ;Meyer and
Vanderbilt, 2002 ) and recent measurements by Jia et al.
(2008) indicated that they are atomically sharp, confirming
the measurements of Bursill.
An interesting and still not fully resolved problem is that of
the domain wall thickness in multiferroics. In materials withweak coupling, it is assumed that the two ferroic parameters
have essentially independent correlation lengths and thus
different thicknesses for the two ferroic parameters, even ifthe middle of the wall is shared ( Fiebig et al. , 2004 ). In the
converse situation of one order parameter being completelysubordinated to the other, e.g., a proper ferroelectric and animproper ferroelastic such as BaTiO
3, or a proper magnet and
an improper ferroelectric such as TbMnO 3, it seems that the
principal order parameter dictates a unique thickness of the
shared domain wall, so that the ferroelectric domain walls ofTbMnO
3are predicted to be as thick as those of ferromagnets
(Cano and Levanyuk, 2010 ). In the intermediate case of two
proper order parameters with moderate coupling, it seemsthat there will still be two correlation lengths for each order
parameter, but each will be affected by the coupling;
Daraktchiev, Catalan, and Scott (2010) have shown that the
ferroelectric wall thickness in a magnetoelectric material withbiquadratic coupling is
/C14
MP/C1721=2ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi/C18/C12b/C20
2/C13/C12a/C0/C11/C132/C0/C11/C12b/C19s
ffi/C14P/C18
1þ/C13a
b/C11þOð/C132Þ/C19
; (14)
where /C14MPis the ferroelectric wall thickness in the magneto-
electric material, and /C14Pis the ferroelectric wall thickness in
the absence of magnetoelectricity. This is thicker than thewalls of normal ferroelectrics and thus more magnetlike,which also agrees with the bigger width of the ferroelectricdomains of BFO compared to those of normal ferroelectrics
(Catalan et al. , 2008 ).
C. Domain wall chirality
In magnetism, the spin is quantized, so it cannot change its
magnitude across the wall. Instead, then, the magnetization
reverses through rigid rotation of the spins. The rotation plane
may be contained within the plane of the domain wall (Ne ´elG. Catalan et al. : Domain wall nanoelectronics 133
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012walls), or it may be perpendicular to it (Bloch walls). Ne ´el
and Bloch walls are generically termed as Heisenberg-like, orchiral. Ferroelectric polarization, on the other hand, is notquantized, so it is allowed to vary in magnitude. This canproduce domain walls where the polarization axis does notchange orientation but simply decreases in size, changes sign,and increases again. Such nonchiral domain walls are calledIsing-like (see schematic of different types of walls inFig.21). In ferroelectrics, 180
/C14Ising walls should be favored
against chiral walls for two reasons: First, the piezoelectriccoupling between polarization and spontaneous strain meansthat rotating the polarization away from the easy axis has abig elastic cost. Second, there is also a large electrostatic cost,as any change in the polarization perpendicular to the domainwall will cause, via Poisson’s equation, an accumulation ofcharge at the walls: /C1D¼"/C1P¼/C26. It is worth mentioning
that the above assumes that the dielectric constant is constant;when it is not, then the correct form of Poisson’s equation is/C1D¼"/C1PþE/C1r"¼/C26. The permittivity gradient can be
important in thin films ( Scott, 2000 ), and must be important
also for the domain wall, where large structural changes takeplace within a narrow region.
For the above reasons, 180
/C14domain walls in ferroelectrics
have been traditionally viewed as Ising-like. This commonassumption, however, has recently been challenged by Lee
et al. (2009) andMarton, Rychetsky, and Hlinka (2010) , who
show that ferroelectric 180
/C14domain walls of perovskite
ferroelectrics can be at least partially chiral. The fact thatchirality can appear in a system where none would be ex-pected was examined by Houchmandzadeh, Lajzerowicz, and
Salje (1991) . They showed that, whenever there are two order
parameters involved (as in any multiferroic system), thecoupling between them can induce chirality at the domainwalls. Perovskite ferroelectrics are multiferroic, because theyare both ferroelectric and ferroelastic. While their 180
/C14walls
tend to be seen as purely ferroelectric, they nevertheless havean elastic component, because the suppression of the polar-ization inside the wall affects its internal strain ( Zhirnov,
1959 ).
Domain walls in BiFeO
3are also multiferroic, and in a big
way, ferroelectricity, ferroelasticity, antiferromagnetism, andantiferrodistortive octahedral rotations all occur in this mate-
rial. It is therefore not surprising that the domain walls of this
material are found to be chiral ( Seidel et al. , 2009 ). Unlike in
normal ferroelectrics, the rotation of the polar vector is quite
rigid, meaning that the component of the polarization per-
pendicular to the domain wall is not constant. This polar
discontinuity means that there is charge density at the walls
(see Poisson’s equation above). In order to screen this chargedensity, charge carriers aggregate to the wall, and this carrier
increase has been hypothesized to be a cause for the increased
conductivity at the domain walls of BiFeO
3(Seidel et al. ,
2009 ;Lubk, Gemming, and Spaldin, 2009 ). The issue of
domain wall conductivity is discussed in greater detail in
Secs. III.F andV.F.1 .
Chirality has important consequences for magnetoelectric
materials. Magnetic spin spirals can by themselves cause
ferroelectricity: indeed, a spin spiral arrangement is knownto cause weak ferroelectricity in some multiferroics
(Newnham et al. , 1978 ;Mostovoy, 2006 ;Cheong and
Mostovoy, 2007 ). The relationship between spin helicity
and polarization is valid not just for bulk but also for the
local spin arrangement inside a domain wall; thus, ferromag-netic Ne ´el walls are expected to be electrically polarized.
Experimental evidence for this was provided by Logginov
et al. (2008) , who applied a voltage to an AFM tip placed near
the ferromagnetic domain wall of a garnet, and observed the
domain wall to shift its position in response to the voltage
(see Fig. 22). Since the garnet is itself centrosymmetric, the
piezoelectric response of the domain wall was attributed to its
spin spiral.
D. Domain wall roughness and fractal dimensions
Irregular domain walls have been studied in thin films of
ferromagnets ( Lemerle et al. ,1 9 9 8 ), ferroelectrics ( Tybell
et al. , 2002 ;Paruch, Giamarchi, and Triscone, 2005 ), and
multiferroics ( Catalan et al. , 2008 ). Quantitatively, the ir-
regular morphology can be characterized by a roughness
coefficient (see Fig. 23), which describes the deviations ( u)
from a straight line (the ideal domain wall) as the length of
FIG. 22 (color online). (a) Logginov et al. applied voltage pulses
to a sharp tip in the vicinity of a ferromagnetic Ne ´el wall in a
magnetic garnet. (b) The wall was observed to move toward or away
from the tip depending on the polarity of the voltage, suggesting that
the domain wall is electrically polarized even though the garnetitself is a nonpolar material. The domain wall polarization is caused
by the spin spiral inherent to the Ne ´el wall. From Logginov et al. ,
2008 .
FIG. 21 (color online). (a) Ising wall, (b) Bloch wall, (c) Ne ´el
wall, and (d) mixed Ising-Ne ´el wall. Recent calculations show that
domain walls in perovskite ferroelectrics tend to be of mixedcharacter. From Lee et al. , 2009 .134 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012wall is increased ( Lemerle et al. , 1998 ;Paruch, Giamarchi,
and Triscone, 2005 ). The wandering deviation uincreases
with the distance traveled along the wall, resulting in a power
law dependence of the correlation coefficient, BðLÞ/C17
h½uðxþLÞ/C0uðxÞ/C1382i/L2/C16, where /C16is the roughness
exponent.
If the domain wall closes in on itself, forming a ‘‘bubble’’
domain, the roughness coefficient of the wall becomes adirect proxy for the Hausdorff dimension, which relates thearea contained within the domain ( A) to the domain wall
perimeter (see Fig. 23); thus, films with rough walls have
fractal domains in the sense that the perimeter does not scaleas the square root of the area, but as the square root of thearea to the power of the Hausdorff dimension, P/A
H=2
(Rodriguez et al. , 2007a ;Catalan et al. , 2008 ).
Since domain size is dictated by the competition between
the domain energy (proportional to the area of the domain)and wall energy (proportional to the domain perimeter) it is
quite natural that the scaling of the domain size should reflect
the Hausdorff dimension of the domains, or, equivalently, theroughness coefficient of the walls. Catalan et al. (2008)
showed that, when the domains are fractal, the Kittel lawmust be modified as w¼A
0tH?=ð3/C0HllÞ, where A0is a constant,
tis the film’s thickness, and H?andHkare the perpendicular
and parallel (out-of-plane and in-plane with respect to the
film’s surface) Hausdorff dimensions of the walls. When both
these dimensions are 1 (i.e., smooth walls), the classic Kittelexponent (
1
2) is recovered. In the particular case of BFO
films, the dimension was found to be 1.5 in the in-planedirection, and 2.5 in total, consistent with domain walls that
meander in the horizontal direction but are completely
straight vertically, much like hanging curtains. This is fully
expected in ferroelectric 180/C14walls, as any vertical bend
would incur in a strong electrostatic cost due to Poisson’s
equation. The fractional dimensionality has also been ob-served in studies of switching dynamics ( Scott, 2007 ), as
discussed later in this section.
In a perfect system, the domain wall energy cost is mini-
mized by minimizing the wall area, i.e., by making the wall assmooth as possible. Whenever domain walls are rough, then,
it is because they are being pinned by defects in the lattice.
The upshot of this is that the roughness of a domain wall
contains information about the type of defects present in the
sample ( Natterman, 1983 ). Specifically, the theoretical rough-
ness coefficient in a random bond system is /C16¼2=3for a
linelike domain wall ( Huse, Henley, and Fisher, 1985 ;Kardar
and Nelson, 1985 ), and this has been experimentally verified
for ultrathin ferromagnetic films ( Lemerle et al. , 1998 ). In
the more general case, it is /C16¼4/C0D=5(Lemerle et al. ,
1998 ). Random bond systems can be viewed as systems with
a variable depth of the double well. If the asymmetry of the
double well changes, then one speaks of random field sys-
tems, for which the roughness coefficient is /C16¼4/C0D=3
(Fisher, 1986 ;Tybell et al. , 2002 ), where Dis the dimen-
sionality of the wall, which can be fractional. For ferro-
electric thin films the roughness coefficient was found to
be 0.26, consistent with the random bond system of di-
mensionality D¼2:7(Paruch, Giamarchi, and Triscone,
Lu
A
P(a)
(b) (c)
(d)
FIG. 23 (color online). (a) The probability of having a deviation ( u) from the straight line increases with the distance dbetween two points
of the wall, resulting in a power law relationship between the size of the wall and its horizontal length. By the same token, if the domain wall
closes in on itself (b), the perimeter will not increase as the square root of the area (as would be the case for a smooth circular domain), but asP/A
H=2, where His the Hausdorff dimension. (c) Measurement of domain wall roughness in PFM-written ferroelectric domain walls of
BiFeO 3thin films and (d) measurement of the Hausdorff dimension in spontaneous domains of the same BiFeO 3films. Panels (c) and (d)
partially adapted from Catalan et al. , 2008 .G. Catalan et al. : Domain wall nanoelectronics 135
Rev. Mod. Phys., V ol. 84, No. 1, January–March 20122005 ). In multiferroic BiFeO 3, the roughness was larger,
/C16¼0:56(Catalan et al. , 2008 ).
Since the roughness of the walls arises directly from the
local pinning by defects, and pinning slows down the motionof the domain walls, it is natural to relate the roughness of thedomain walls to their dynamics. This has been done both forferromagnetic films ( Lemerle et al. , 1998 ) and for ferroelec-
tric films ( Tybell et al. , 2002 ;Paruch, Giamarchi, and
Triscone, 2005 ). The domain wall velocity is characterized
by an exponent that, similar to the roughness exponent, is alsodirectly related to the type of pinning defects in the samples.Specifically, the velocity of the wall is
v¼v
0exp/C20
/C0U
kT/C18Fcrit
F/C19/C22/C21
;
where FandFcritare the applied and critical fields (magnetic
or ferroelectric) of the sample, Uis an activation energy, and
/C22is the critical exponent, which is related to the roughness
exponent by /C22¼ðDþ2/C16/C02Þ=ð2/C0&Þ(Lemerle et al. ,
1998 ). The value of /C22depends on whether the domain wall
motion proceeds by creep or by viscous flow; in ferroelectric
thin films /C22¼1was measured, consistent with a creep
process (see Fig. 24).
The study of the switching dynamics in ferroelectric thin
films generally yields an effective dimensionality that is notinteger but fractional. In early switching studies Scott et al.
(1988) found from fits to the Ishibashi theory that dimension-
ality of the domain kinetics was often D¼2:5(approxi-
mately). At the time it was not clear whether this was aphysical result or an artifact of the Ishibashi approximations(especially the simplifying assumption that wall velocities v
were independent of domain radius r—actually vvaries as
1=r). However, more recent studies ( Scott, 2007 ) indicate that
D¼2:5is physically correct; Scott also calculated by inter-
polation the critical exponents in mean field for D¼2:5and
found, for example, that the order parameter exponent /C12¼
1
4for a second-order transition, compared with /C12¼1
2for bulk
D¼3. Since this is the same1
4exponent as in a bulk tricritical
transition, second-order transitions for D¼2:5may be mis-
taken as tricritical.
E. Multiferroic walls and phase transitions inside
domain walls
The idea that domain walls have their own symmetry and
properties is not new. Shortly after Ne ´el hypothesized the
existence of antiferromagnetic domains ( Ne´el, 1954 ),Li
(1956) showed that such walls would have uncompensated
spins that could account for the weak ferromagnetism mea-
sured in /C11-Fe2O3. An important and often overlooked aspect
of Li’s classic model is that the size of the uncompensatedmoment at the wall is inversely proportional to the wallthickness. This, to some extent, is trivial: An atomically sharpantiphase boundary should have a fully uncompensated pair
of moments (see Fig. 25), whereas in a broad domain wall the
gradual change means that only the fractional differencebetween nearest neighbors is uncompensated. Although ithas not been explicitly stated anywhere, a natural corollaryis that the domain walls of antiferroelectrics should be ferro-
electric, or at least pyroelectric. One must bear in mind that
the walls of ferroelectrics are atomically sharp, as discussedabove, so antiferroelectric domain walls are expected to beclose to perfect antiphase boundaries, although we know ofno studies of domain wall thickness in antiferroelectrics.
In the case of multiferroics, the interplay between the
symmetries of all the phases involved is more complex and
can lead to rich behavior. Privratska, Janovec, and othersmade a theoretical survey of which properties are allowedinside the domain walls as a function of the space group of theferroic material. Based on this, they predicted that the domain
walls of ferroelastics can be polar ( Janovec, Richterova ´, and
Privratska, 1999 ), as confirmed by atomistic calculations for
CaTiO
3(Gonc¸alves-Ferreira et al. , 2008 ) and experimentally
inferred for SrTiO 3(Zubko et al. , 2007 ).Privratska and
Janovec (1997 ,1999) , and Privratska (2007) also predicted
that there can be net magnetization inside the ferroelectric
FIG. 24. Ferroelectric domain wall speed as a function of applied
electric field for films of various thicknesses. The critical exponent
was found to be /C22¼1, characteristic of creep. From Tybell et al. ,
2002 .
FIG. 25 (color online). The relative heights of the boxes illustrate
how a sharp antiphase boundary must have a net magnetization and
polarization in its center that is bigger than that of a broad domain
wall such as a chiral wall. Adapted from Li, 1956 .136 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012domain walls of multiferroics. Among the symmetries where
this domain wall magnetization is allowed is the space groupR3c(Privratska and Janovec, 1999 ) (i.e., that of BiFeO
3).
Symmetry analyses are not quantitative. The knowledge
that a property is symmetry allowed is essential, but one stillneeds to know how big that property is. This quantitativeanalysis can be achieved using phenomenological approachessuch as those pioneered by Lajzerowicz and Niez (1979) , who
were the first to realize that it was possible for domain walls
to undergo their own internal phase transitions. This is pos-
sible because the free energy inside the wall is different fromthat inside the domains: Inside the domains the order parame-ter is homogeneous and there are no gradients, whereas insidethe domain walls the order parameter is suppressed and there
are strong gradients. Since the free energy of the wall is
different, its thermodynamic properties must also be differ-ent, and hence its thermal evolution and phase transitions mayalso be different.
This idea becomes, of course, more interesting when sev-
eral order parameters are involved. These order parameters
may be present at finite temperature (as in multiferroic
materials), or they may be suppressed or ‘‘latent’’ (havelow or ‘‘negative’’ critical temperatures) but still may beable to manifest inside the domain walls. The phenomenonof emerging order parameters inside a wall was first explained
byHouchmandzadeh, Lajzerowicz, and Salje (1991) in the
context of ferroelastic materials. They realized that if asecondary ferroic order is latent (suppressed) due to a positivecoupling energy to the primary order parameter, it will beable to emerge wherever the primary order parameter is zero,i.e., in the middle of the domain wall. For example, it is
known that, in perovskites, rotations of the oxygen octahedra
are normally opposed to ferroelectric polarization. Hence,where such rotations are suppressed, polarization may beable to emerge, as was theoretically calculated for the anti-ferrodistortive antiphase boundaries of SrTiO
3(Tagantsev,
Courtens, and Arzel, 2001 ). Given that BiFeO 3is known to
also have strong octahedral rotations ( Megaw and Darlington,
1975 ) that oppose the polarization ( Dupe´et al. , 2010 ), it
seems eminently plausible that the ferrodistortive antiphaseboundaries of this material also have a polar enhancement.
Daraktchiev, Catalan, and Scott (2010) studied in some
detail the analytical solutions for domain walls in multifer-
roics with biquadratic coupling between the order parameters,/C13P
2M2; the biquadratic coupling was chosen because (i) it is
the smallest power that is symmetry allowed for all materials(the coupling term places no constraint on inversion of either
order parameter), and (ii) an effective biquadratic interaction
will always be present when strain mediates the coupling,since electrostriction couples strain to the square of polariza-tion while magnetostriction couples strain to the square ofmagnetization. Strain coupling terms are of course large in
ferroelectrics, and therefore they will always be important for
multiferroics. Another important aspect of this biquadraticcoupling that perhaps has not been emphasized enough isthat, because it is even, the solutions must also be even,meaning that any emerging parameter inside the wall willhave at least two equally stable polarities and may be switch-
able between them. This can be seen, for example, in Fig. 26,
which shows that there are two equivalent least-energytrajectories connecting the ferroelectric double well through
two saddle points at þMand/C0M, and thus there are two
possible magnetic polarities for the wall. Experimentally,
Pyatakov et al. (2011) demonstrated the converse situation
by showing switching of the ferroelectric polarity inside amagnetic domain wall. The exact phenomenology, of course,
depends on the sign and symmetry of the coupling elements,
and the possibilities are far too numerous to be describedhere, but the basic principle is always the same: Start with the
Landau expansion of the free energy and examine the con-
sequence of forcing one of the order parameters to be zero, asin the middle of the domain wall. In this context, it is useful to
also look at the recent work of Marton, Rychetsky, and Hlinka
(2010) , who found new phases with enhanced electrome-
chanical properties inside the domain walls of a typical
perovskite ferroelectric such as BaTiO
3.
So far group-symmetry arguments and phenomenological
(thermodynamic) models have been mentioned, but there arealso microscopic calculations for some systems. For example,
Goltsev and others calculated the profile of the magnetization
across the domain walls of YMnO
3(Goltsev et al. , 2003 ;
Fiebig et al. , 2004 ). Meanwhile, Lubk, Gemming, and
Spaldin (2009) calculated the octahedral rotations, polariza-
tion profile, and band gap across the domain walls of BiFeO 3,
and Gonc¸alves-Ferreira et al. (2008) calculated the polar
displacements inside the ferroelastic walls of CaTiO 3.
Generally, the reduced thickness of ferroelectric and ferroe-lastic walls means that they are computationally affordable
for first-principles calculations, whereas the broader magnetic
walls tend to require analytical approaches or finite-element
FIG. 26 (color online). (a) Ferroelectric polarization profile across
the wall, (b) magnetization profile across the wall, (c) relationshipbetween the order parameters across the wall, showing that the
magnetization can be either positive or negative, and (d) free-energy
landscape, showing one of the two least-energy trajectories con-necting the two ferroelectric polarities through one of the saddle
points at M/C2220. Adapted from Daraktchiev, Catalan, and Scott,
2010 .G. Catalan et al. : Domain wall nanoelectronics 137
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012and molecular dynamics calculations. Multiferroic walls
fall somewhere in between in terms of thickness, although
we suspect that the magnetic part of their behavior will
always be more difficult to compute using first-principles
approaches.
F. Domain wall conductivity
The changes in structure (and as a consequence electronic
structure) that occur at ferroelectric (multiferroic) domain
walls can thus lead to changes in transport behavior.
Indeed, domain wall (super)conductivity was studied by
Aird and Salje (1998) . Reducing WO 3with sodium vapor,
they observed preferential doping along the ferroelastic do-
main walls. Transport measurements showed superconduc-
tivity, while magnetic measurements did not; this suggested
that the superconductivity was located only at the domain
walls, which provided a percolating superconductive path
while occupying a small volume fraction of the crystal.
Later, Bartels et al. (2003) used a conducting-tip scanning
probe microscope to show the converse behavior: The domain
walls of a calcium-doped lead orthophosphate crystal were
found to be more resistive than the domains.
The above effects relied on preferential doping along
domain walls, but the differential domain wall conductivity
was reproduced also in undoped multiferrroics, although with
different transport behavior: The domain walls of BiFeO 3
were found to be more conductive than the domains ( Seidel
et al. , 2009 ), while those of YMnO 3were found to be more
insulating ( Choi et al. , 2010a ). Multiferroic YMnO 3, a so-
called improper ferroelectric multiferroic, in which ferroelec-
tricity is induced by structural trimerization coexisting with
magnetism, domain walls are found to be insulating ( Choi
et al. , 2010 ). The increase of the Y-O bond distance at domain
walls may be responsible for the reduction of local conduc-
tion. The observed conduction suppression at domain walls at
high voltages (still much less than the electric coercivity) is in
striking contrast with what was reported on BiFeO 3.
A useful clue for interpreting these results is perhaps the
analysis of the paraphase. Whereas the high-temperature,
high-symmetry phase of BiFeO 3is more conducting than
the ferroelectric phase ( Palai et al. , 2008 ), the converse is
true for YMnO 3(Choi et al. , 2010 ). This illustrates an
important point: In some respects the internal structure of
the walls can be considered to be in the paraelectric state; by
way of trivial example, the 180/C14domain walls of a ferroic are
nonpolar, just like its paraphase. The examples of BiFeO 3and
YMnO 3suggest that the paraphaselike behavior can be ap-
plied to domain wall properties other than just the polariza-
tion: The insulating paraelectric state of YMnO 3is consistent
with the insulating nature of its domain walls, and conversely
the conducting state of the paraphase of BiFeO 3is consistent
with its domain wall conductivity. Nevertheless, in the con-ductivity of the BiFeO
3walls at least there are several other
considerations: octahedral rotations, electrostatic steps aris-
ing from rigid rotation of the polar vector, and increased
carrier density at the wall are all thought to play a role in
the domain wall conductivity of BiFeO 3and potentially also
of other perovskites. A more detailed discussion of these
factors is provided in Sec. V.F.1 .The resistive behavior of purely magnetic domain
walls has also been studied. The domain walls of metallicferromagnets were found to be more resistive than the do-
mains due to spin scattering ( Viret et al. , 2000 ;Danneau
et al. ,2 0 0 2 ). On the other hand, the domain walls of man-
ganites (which are ferromagnetic and ferroelastic) have beenpredicted to be more conducting than the domains, due to
strain coupling: The Jahn Teller distortion is smaller and theoctahedral rotation angle is straighter inside the domain wallthan outside ( Salafranca, Yu, and Dagotto, 2010 ), leading to
increased orbital overlap and thus bigger bandwidth. The
same interplay between octahedral rotation straighteningand increased conductivity has been postulated for the do-main walls of bismuth ferrite ( Catalan and Scott, 2009 ), and
the straightening of the octahedral rotation angle inside thewalls of this material has been confirmed by electron micros-copy ( Borisevich et al. , 2010 ). To complete the picture, it
should be mentioned that enhanced domain wall conductivity
has also been observed in standard ferroelectrics such asPbðZr;TiÞO
3(Guyonnet et al. , 2011 ), suggesting that this
may be a more general property than previously thought.
The challenge is now to make a resistive switching device
based on domain walls. Two approaches may be pursued
here. One was suggested by Lee and Salje (2005) , who
observed that the percolation of a zigzag configuration offerroelastic walls between the two surfaces of a crystal couldbe controlled by bending. The other approach pursued isselective doping. The experimental study of domain wallconductivity and the electronic devices that can be madeusing wall properties will be the subject of the following
sections.
IV. EXPERIMENTAL METHODS FOR THE
INVESTIGATION OF DOMAIN WALLS
A variety of structural and near-field probes are available to
probe both the macroscopic and microscopic details of do-main walls. Atomic-scale imaging of the domain wall struc-
ture is now possible with transmission electron microscopy,
but of particular emphasis in this review is scanning probe(scanning tunneling microscopy, atomic force microscopy,conducting AFM (c-AFM), and the related piezoforce micro-socopy) techniques, which allow the probing of actual func-tional properties of the domain walls. Readers interested inthe details of all of these structural probe techniques are
referred to several reviews on this subject; here we give an
overview of the information pertinent to domain walls.
A. High-resolution electron microscopy and spectroscopy
Among the methods available for the investigation of
domain walls is high-resolution electron microscopy ( Goo
et al. , 1981 ;Bursill, Peng, and Feng, 1983 ;Bursill and Lin,
1986 ;Stemmer et al. , 1995 ;Hytch, 1998 ;Lichte, 2002 ;Jia,
2003 ). This method allows direct visualization of the lattice
distortion across the domain wall by measuring the continu-ous deviation of a set of planes with respect to the undistortedlattice (exit-wave reconstruction) ( Foeth et al. , 1999 ).
Current, state-of-the-art techniques permit atomic-scale
resolution at 0:5/C23Athrough aberration-corrected imaging138 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012(Figs. 27and 28). The exit-wave reconstruction approach
eliminates the effects of objective-lens spherical aberrations,
and images can be directly interpreted in terms of the pro-jection of the atomic columns ( Allen et al. , 2004 ). Weak-
beam transmission electron microscopy has been used for aquantitative analysis of the thickness fringes that appear onweak-beam images of inclined domain walls. By fittingsimulated fringe profiles to experimental ones, it is possible
to extract the thickness of the domain walls in a quantitative
way. Regarding high-resolution transmission electron micros-copy (HRTEM) images of domain walls, it has to be takeninto account that the samples in these kinds of experimentsare thin (typically a few nanometers) so that surface pinningof the domain walls could play an important role ( Meyer and
Vanderbilt, 2002 ). The atomic displacements across a typical
wall are on the order of 0.02 nm, which still makes directimaging and interpretation a challenge ( Gopalan, Dierolf, and
Scrymgeour, 2007 ). HRTEM also offers the possibility of
imaging the local polarization dipoles at atomic resolution,thus quantitatively measuring the local polarization and in-
vestigating the domain structure ( Jiaet al. , 2008 ).
Using the negative spherical-aberration imaging technique
in an aberration-corrected transmission electron microscope,large differences in atomic details between charged and un-charged domain walls have been reported, and cation-oxygendipoles near 180
/C14domain walls in epitaxial PbZr 0:2Ti0:8O3
thin films have been resolved on the atomic scale ( Jiaet al. ,
2008 ).Elemental and electronic structure analysis by electron-
energy-loss spectroscopy has also been applied to the study ofdomain walls ( Jia and Urban, 2004 ;Urban et al. ,2 0 0 8 ).
Using high-resolution imaging in an aberration-corrected
TEM, the concentration of oxygen in BaTiO
3twin bounda-
ries was measured at atomic resolution. These measurementsprovide quantitative evidence for a substantial reduction ofthe oxygen occupancy, i.e., the presence of oxygen vacanciesat the boundaries. It was also found that the modified Ti
2O9
group unit formed reduces the grain boundary energy and
provides a way of accommodating oxygen vacancies occur-
ring in oxygen-deficient materials. This type of atomically
resolved measurement technique offers the potential to studyoxide materials in which the electronic properties sensitivelydepend on the local oxygen content (important in view ofcurrent work on LaAlO
3=SrTiO 3superconducting interfa-
ces). The attraction between domain walls and vacancies isfurther discussed in Sec. V.
B. Scanning probe microscopy
Atomic force microscopy and its variations (e.g., c-AFM,
PFM) are well suited for direct writing (‘‘ferroelectric lithog-raphy’’) and characterization of prototype ferroelectric struc-
tures (Fig. 29), including domain walls ( Eng, 1999 ). These
methods provide the tools to get information about localmechanisms of twin-wall broadening that cannot be obtainedby existing experimental methods ( Shilo, Ravichandran, and
Bhattacharya, 2004 ). With conductive AFM (c-AFM) one can
artificially modify the domain structure as a function of pulsewidth and amplitude ( Tybell et al. ,2 0 0 2 ). PFM is also under
continuous development and is currently undergoing a shift of
focus from imaging static domains to (i) dynamic character-ization of the switching process (with developments such asstroboscopic PFM and PFM spectroscopy) and (ii) the struc-ture of domain walls ( Gruverman et al. , 2005 ;Jungk,
Hoffmann, and Soergel, 2006 ;Rodriguez et al. , 2007a ,
2007b ;Morozovska et al. , 2008 ;Kalinin et al. , 2010 ) (see
also Fig. 30).
Let us take a closer look at the relationship between
domain walls and the effect of electric fields on ferroelectrics.When the applied field is higher than the coercive field, thewalls will move; however, the threshold field at which pre-existing domain walls begin to move can be much lower than
FIG. 29 (color online). (a) PFM amplitude and (b) PFM
phase images of a BFO sample with 109/C14stripe domains;
(c) simultaneously acquired c-AFM image of the same area showing
that each 109/C14domain wall is electrically conductive. From Seidel
et al. , 2010 .
FIG. 28 (color online). (a) 71/C14and (b) 109/C14domain walls in
bismuth ferrite.
FIG. 27 (color online). Atomic-scale TEM image of the electricdipoles formed by the relative displacements of the Zr/Ti cationcolumns and the O anion columns in PbZr
0:2Ti0:8O3. Adapted from
Jiaet al. , 2008 .G. Catalan et al. : Domain wall nanoelectronics 139
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012the coercive field required for nucleation ( Gopalan, Dierolf,
and Scrymgeour, 2007 ;Choudhury et al. , 2008 ). From
preliminary theory and experiments, Gopalan, Dierolf, and
Scrymgeour (2007) argued that the thickness of the domain
wall is different when an external electric field is applied
because of changes in its Landau energy potential. This
prediction is also supported by the calculations of Rao and
Yu (2007) andHlinka, Ondrejkovic, and Marton (2009) .F o r
PbTiO 3, the effect of an applied electric field leads to an
increase in the wall thickness of 2 to 4 times and for LiNbO 3
the thickness increases up to 10%–30%, but this phenomenon
is expected to be general for all compositions. At the same
time, a thicker (or diffuse) domain wall has a lower threshold
field ( Choudhury et al. , 2008 ) for lateral movement, as it is
not narrow enough to drag against the washboardlike Peierls
potential. This effect was used to explain low thresholdfields for domain reversal in ferroelectrics. However, the
same authors predict that an increase in wall thickness at
surfaces will be of influence only when the crystal thickness
is 1–10 nm and that, in general, the region with the lowest
wall thickness will dominate the threshold field for the mo-
tion of the entire wall.
Analysis of both complete area images and individual line-
scan profiles provides essential information about local
mechanisms of twin-wall broadening, which cannot be ob-
tained by other experimental methods ( Shilo, Ravichandran,
and Bhattacharya, 2004 ). Surface topography measured usingatomic force microscopy is compared with candidate dis-
placement fields, and this allows for the determination ofthe twin-wall thickness and other structural features. Closed-form analytical expressions for vertical and lateral PFM
profiles of a single ferroelectric domain wall for the conical
and disk models of the tip, beyond point charge and sphereapproximations have been investigated ( Morozovska et al. ,
2008 ). Here the analysis takes into account the finite intrinsic
width of the domain wall and dielectric anisotropy of thematerial. The analytical expressions provide insight into themechanisms of PFM image formation and can be used for aquantitative analysis of the PFM domain wall profiles.
Ferroelectric thin films typically contain various structural
defects such as cationic and/or anionic point defects, dislo-cations, and grain boundaries. Since the electric and stressfields around such defects in a ferroelectric thin film arelikely to be inhomogeneous, it is expected that the switchingbehavior near a structural defect will be different fromthe one found in a single-domain state. The role of a single
ferroelastic twin boundary has been studied in tetragonal
PbZr
0:2Ti0:8O3ferroelectric thin film ( Choudhury et al. ,
2008 ). It was shown that the potential required to nucleate
a 180/C14domain is lower near ferroelastic twin walls
(/C241:6V) compared with /C242:6Vaway from the twin walls.
A recently increased interest in combined PFM and con-
ductivity measurements arises from both nonvolatile memory
application perspective and a potential for electroresitive
memory devices ( Yang et al. , 2009 ). The work of
Gruverman, Isobe, and Tanaka (2001) explored the interplay
of domain dynamics and conductivity at interfaces in thinferroelectric films. The combination of local electromechani-cal and conductivity measurements revealed a connectionbetween local current and pinning at bicrystal grain bounda-ries in bismuth ferrite ( Rodriguez et al. , 2008 ).
Electroresistance in ferroelectric structures was recently re-
viewed by Watanabe (2007) . The presence of extended de-
fects and oxygen vacancy accumulation has been shown toinfluence transport mechanisms at domain walls ( Seidel
et al. , 2010 ). Recently, direct probing of polarization-
controlled tunneling into a ferroelectric surface was shown(Garcia et al. , 2009 ;Maksymovych et al. , 2009 ). Scanning-
near-field optical microscopy has been used to observe pin-
ning and bowing of a single 180
/C14ferroelectric domain wall
under a uniform applied electric field ( Yang, 1999 ;Kim
et al. , 2005 ).
Typically the imaging resolution in PFM is about 5–30 nm .
The achievable resolution is ultimately limited by the tip-sample contact area, which is nominally determined by the
radius of the tip apex. There are additional mechanisms for
resolution broadening such as electrostatic interactions andthe formation of a liquid neck under ambient conditions in thetip-surface junction. The PFM amplitude typically providesinformation on the magnitude of the local electromechanicalcoupling under the tip, and the PFM phase gives informationabout the ferroelectric domain orientation.
Scanning tunneling spectroscopy can be used to directly
probe the superconducting order parameter at nanometer
length scales. Scanning tunneling microscopy (STM) andspectroscopy (STS) have been used to investigate the elec-tronic structure of ferroelastic twin walls in YBa
2Cu3O7/C0/C14
FIG. 30 (color online). Schematic piezoresponse across a single
180/C14domain wall in lithium niobate crystal. (a) The surface
displacement (solid line) due to the electric field across the domainwall displayed in (e). The dotted line is the original surface plane.
(b) The piezoresponse, both XandYsignals, across the domain
wall. Xis the product of amplitude ( R) and the sine of the phase, q,
andYis the product of amplitude and cosine of the phase. (c) The
piezoresponse, both Xsignal and Ysignals, on both þcand/C0c
surfaces plotted in a vectorial XYplane. (d) The amplitude and
phase of the piezoresponse across the domain wall. (e) Schematicdomain structure and electrical field. From Tian, 2006 .140 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012(YBCO) ( Maggio-Aprile et al. , 1997 ). Twin boundaries
play an important role in pinning the vortices and therebyenhancing the currents that YBCO can support while remain-ing superconducting. An unexpectedly large pinning strengthfor perpendicular vortex flux across such boundaries wasfound, which implies that the critical current at the boundaryapproaches the theoretical ‘‘depairing’’ limit.
In the case of insulators, STM and STS are by definition a
lot more difficult to implement, primarily because a reliabletunneling current cannot be used to establish proximal con-tact. The emergence of ferroelectrics with smaller band gapsand the possibility of conduction at domain walls (see later)has stimulated renewed interest in exploring STM as a probeof the local electronic structure. The emergence of combinedAFM and STM or SEM (scanning electron microscopy) andSTM systems should be a boon in terms of exploring theelectronic properties of domain walls in such insulatingmaterials. Research using such combined tools is in itsinfancy ( Wiessner et al. , 1997 ;Yang et al. , 2005 ;Garcı ´a,
Huey, and Blendell, 2006 ;Chiu et al. , 2011 ).
C. X-ray diffraction and imaging
Diffuse x-ray scattering can also be used to investigate the
structure of domains and domain walls in densely twinnedferroelastic crystals ( Bruce, 1981 ;Andrews and Cowley,
1986 ;Locherer, Chrosch, and Salje, 1998 ). The scattering
is characterized by strong, well-defined Bragg peaks, with adiffuse streak between these arising from the domain walls(see Fig. 31). The streak typically is several orders of magni-
tude lower in intensity. Comparison with an analytical modelfor the scattering allows one to extract the effective domainwall width on the unit-cell level ( Locherer, Chrosch, and
Salje, 1998 ). Critical fluctuations and domain walls of, for
example, KH
2PO4(KDP) and KD2PO4(DKDP) were inves-
tigated ( Andrews and Cowley, 1986 ). The intensity of thecritical scattering near two different reciprocal lattice points
was determined and used to find the atomic displacements inthe ferroelectric fluctuations. The x-ray scattering from the
domain walls was observed below T
cand enabled measure-
ments to be made of the width of the domain walls and theatomic displacements in the walls. The width of the domainwalls was shown to increase with temperature toward T
c.
Synchrotron x-ray sources have also been used for direct
imaging of strain near ferroelectric 180/C14domain walls in
congruent LiNbO 3andLiTaO 3crystals and in BaTiO 3crys-
tals ( Kim, 2000 ;Rogan, 2003 ;Jach, 2004 ). Direct evidence
for wide regions of strain on length scales of many micro-
meters associated with 180/C14domain walls in congruent
LiNbO 3andLiTaO 3crystals was found. The observed strain
contrast in symmetric high-resolution diffraction images inBragg geometry arises in part from curvature in the basalplanes across a domain wall as well as from lateral variation
in the lattice spacing of the basal planes extending across a
wall. In BaTiO
3local triaxial strain fields around 90/C14do-
mains were found. Specifically, residual strain maps in aregion surrounding an isolated, approximately 40-/C22m-wide,
90
/C14domain were obtained, revealing significant residual
strains.
D. Optical characterization
Ferroelectrics offer the possibility of engineering their
domain structure down to the nanometer regime and thereforeallow for interesting optical functionality such as mode shap-ing and frequency conversion, as well as the integration intocompact optical devices ( Chen et al. , 2001 ;Kurz, Xie, and
Fejer, 2002 ;Scrymgeour et al. , 2002 ). Ferroelectric crystals
in general are anisotropic and show birefringence. Regions
with different orientations of the polar axis are, for example,easily differentiated by polarization microscopy ( Tarrach
et al. , 2001 ). Because of the symmetry of the optical indica-
trix, regions of opposite polarization cannot be distinguished
by linear optics. Nonlinear effects, however, such as second-
harmonic generation ( Dolino, 1973 ) or the electro-optic ef-
fect ( Hubert and Levy, 1997 ;Otto et al. , 2004 ) revealed the
eccentricity of the crystal. Regarding materials, lithium nio-bate ( LiNbO
3) and lithium tantalate ( LiTaO 3) emerged as key
technological materials for photonic applications (se Fig. 32).
High quality of crystal growth, optical transparency over a
FIG. 32. Piezoelectric force microscopy phase contrast images of
domain shapes in LiNbO 3andLiTaO 3. From Scrymgeour et al. ,
2005 .
FIG. 31 (color online). X-ray intensity profile of the ð400Þ=ð040Þ
peak along (110) in a WO 3crystal. The dashed line shows a
Gaussian fit to the contribution from the domain walls. The bold
solid line is the overall fit. Figure courtesy of Ekhard Salje, adapted
from Locherer, Chrosch, and Salje, 1998 .G. Catalan et al. : Domain wall nanoelectronics 141
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012wide frequency range (240 nm to 4:5/C22mwavelength), and
their large electro-optic and nonlinear optical coefficients are
the main advantages of these materials. Emerging fields of
optical communication, optical data storage, optical displays,biomedical device applications, and sensors all rely heavily
on such ferroelectric materials as a versatile solid-state pho-
tonic platform. The process of domain control is difficult andhas received tremendous attention over the past years. The
central focus of work has been set on developing a funda-
mental understanding of shaping and controlling domainwalls in ferroelectrics, specifically in lithium niobate and
lithium tantalate, for photonic applications.
An understanding of the domain wall phenomena has
been approached at the macroscale and the nanoscale.Different electric-field poling techniques have been devel-
oped and used to create domain shapes of arbitrary and
controlled orientation. A theoretical framework based onthe Landau-Devonshire theory is typically used to determine
the preferred domain wall shapes in these materials ( Lines
and Glass, 2004 ). Differences in the poling characteristics
and domain wall shapes between the materials as well as
differences in material composition have been identified to
be related to nonstoichiometric defects in these crystals.(Shur, 2006 ).
V. APPLICATIONS OF DOMAINS AND DOMAIN WALLS
When applying an external field to a material with do-
mains, the walls will move so as to expand those domains that
are energetically favored by the field and contract those thatare not. Having a large density of mobile domain walls
facilitates this change in domain populations and can there-
fore dramatically enhance the susceptibility of any ferroic, beit magnetic susceptibility, elastic compliance, dielectric con-
stant or piezoelectric coefficient. The contribution of domain
walls to the susceptibility of ferroelectrics was first studied inPrague more than four decades ago ( Fouskova, 1965 ;Fousek
and Janous ˇek, 1966 ), and presently there exist good articles
and reviews about the dynamic domain wall contribution tosusceptibility and piezoelectricity ( Zhang et al. , 1994 ;
Bassiri-Gharb et al. , 2007 ) so we do not dwell on this
topic here. Instead, we focus on the applications of staticferroelectric domain configurations (chiefly, electro-optical
devices) on one hand, and on the newer concept of devicesexploiting domain wall shift (the so-called racetrackmemories).
A. Periodically poled ferroelectrics
Prior to the recent flurry of activity on domain engineering,
the primary device application requiring control and manipu-lation of ferroelectric domains involved periodic poling offerroelectrics. This application is for nonlinear optics, such as
second-harmonic generation: The efficiency of the wave-
length conversion is increased by having periodic antiparalleldomains, with the maximum theoretical efficiency beingachieved when the wavelength of the pump laser matchesthe full repeat length of a pair of þPand/C0Pdomains, as first
pointed out by Bloembergen in his Nobel prize-winning work(Armstrong et al. ,1 9 6 2 ).
The production of highly efficient nonlinear electro-optic
devices via the technique of periodically poling ferroelectric
crystals (quasiphase matching) emphasized devices madefrom lithium niobate ( LiNbO
3) and lithium tantalate
(LiTaO 3), both congruent and stoichiometric, KTP
(KTiOPO 4), and tungsten bronzes of the barium sodium
niobate family. Generally speaking, these have been success-ful commercial devices, but a few problems remain thatprevent optimization of real products. First, the domainwidths are sometimes not stable with time; second, there is
a particular problem in achieving narrow (submicrometer)
widths. In this section we examine some real device parame-ters and suggest that the crystal (or film) thicknesses have notbeen optimized in a way that is compatible with the domainwidths, connected through the Landau-Lifshitz-Kittel law(see Table I).
Since the original report of efficient nonlinear optics
from phase-matched periodically poled ferroelectrics by
Armstrong et al. (1962) there have been numerous develop-
ments and commercial production of such devices, startingabout two decades ago, first in Japan ( Yamada et al. , 1993 ),
and then in the USA ( Myers et al. , 1995 ). From the early
1990s interest was perhaps evenly divided between KTP(KTiOPO
4)(Chen and Risk, 1994 ;Karlsson, 1997 ;Reid,
TABLE I. Some device parameters for periodically poled ferroelectrics. Wall thicknesses tmeasured using PFM or optical methods
overestimate the true crystallographic wall thicknesses, as pointed out by Jungk, Hoffmann, and Soergel (2007) . The quoted wall thickness
for KTP is therefore likely to be too high.
Sample thickness d Domain width w Wall thickness t Domain depth d0
(mm) (nm) (nm) (nm) Reference
KTiOPO 4
0.5 mm 283–360 nm 20–80 ( aface) /C25100 nm Wittborn et al. (2002) ;Canalias,
Pasiskevicius, and Laurell (2005) ;
Laurell and Canalias (2009)
0.5 mm 65 ( bface) Canalias, Pasiskevicius, and
Laurell (2006) ;Canalias et al. (2006)
LiNbO 3
1m m 150 nm –6/C22m <3n m <100 nm Shur et al. (2000) ;Rosenman et al.
(2003a ,2003b) ;Grilli et al. (2005) ;
Jungk, Hoffmann, and Soergel (2007)
LiTaO 3
0.15 875 nm Mizuuchi, Yamamoto, and Kato (1997)142 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 20121997 ;Wang, 1998 ;Rotermund, 1999 ) and lithium niobate
(Hu, Thomas, and Webjo ¨rn, 1996 ;Galvanauskas, 1997 ;
Penman, 1998 ). This mix of materials continued in more
recent studies ( Rosenman et al. , 2003a ,2003b ;Tiihonen,
Pasiskevicius, and Laurell, 2006 ;Canalias, Pasiskevicius, and
Laurell, 2006 ;Canalias et al. , 2006 ;Lagatsky et al. , 2007 ;
Henriksson et al. , 2006 ;Hirohashi et al. , 2007 ), augmented
by results on the tungsten bronzes of the Ba2NaNb5O 15
family ( Jaque et al. , 2006 ). Note that, as pulled from the
congruent melt, LiNbO 3is not stoichiometric; the spectro-
scopic differences between congruent and stoichiometric
LiNbO 3were first illuminated by Okamoto, Wang, and
Scott (1985) . We also note parenthetically that
LiNbO 3=LiTaO 3andKTiOPO 4are both nonferroelastic fer-
roelectrics since their crystal classes do not change at their
ferroelectric phase transitions (rhombohedral-rhombohedraland orthorhombic-orthorhombic, respectively). This meansthat only 180
/C14domains are present, which simplifies switch-
ing dynamics, and it implies that there is no hysteretic stress
during switching, which minimizes energy cost in poling.
1. Application of Kittel’s law to electro-optic domain
engineering
As discussed in Sec. II, the domain width wis proportional
to the square root of the crystal (or film) thickness d(see
Fig. 1). The proportionality constant is material dependent
and not easily evaluated, and this was simplified by the group
of Luk’yanchuk ( De Guerville et al. , 2005 ) and by some of us
(Catalan et al. , 2007a ): By dividing the Landau-Lifshitz-
Kittel formula by the domain wall thickness /C14, a dimension-
less constant results [Eq. ( 2)]. Our basic hypothesis, already
advanced by Catalan et al. (2007a) , is that periodically poled
electro-optic devices often have domain periodicities anddomain walls that are unstable with time because they are
fabricated at thicknesses and widths that do not satisfy the
Kittel equation [Eq. ( 2)]. We consider how to improve and
optimize this situation.
Note three things in Eq. ( 2): First, the domain wall thick-
ness/C14is assumed to be an intrinsic constant, whereas, in fact,
/C14can be manipulated experimentally to optimize stability.
Secondly, dis not necessarily the thickness of the crystal, but
the depth of the domains, which can be much less thanthe total film thickness. And, finally, the material-specificparameter in Eq. ( 2) is the square root of the ratio of in-plane
and out-of-plane electric susceptibilities. As shown, this ratio
is different for the three electro-optic materials recently ex-plored for periodically poled devices. The devices are typi-cally fabricated on specimens that are 0.15 to 1.0 mm in
thickness. The typical domain widths that one strives for
(in order to match visible or near-visible wavelengths) are100–900 nm, and the typical wall thicknesses are 10 nm orless. These numbers do not satisfy the Kittel law; in particu-
lar, for a domain wall thickness of 10 nm, a 500-nm domain
width would be thermodynamically stable in LiNbO
3or
KTiOPO 4only for a much thinner specimen of /C2510/C22m,
significantly less than the actual 1 mm.
It is not easy to circumvent thermodynamics or to fool
Mother Nature. If one constrains the domain widths to be
smaller than the equilibrium Kittel value via spatially abruptapplied fields, thermodynamics ‘‘retaliates’’ by making thestable domains not penetrate through the sample from anode to
cathode of the applied poling voltage, but instead only partially
to a few micrometers in depth ( Batchko et al. , 1999 ).
ForBa
2NaNb 5O15the out-of-plane (polar-axis) dielectric
constant is 32. The in-plane is biaxial but nearly isotropic at
222 ( xaxis) and 227 ( yaxis) ( Warner, Coquin, and Frank,
1969 ). So the square root of the ratio is 2.65. Hence for
excitation with 1:064-/C22mNd:YAG (yttrium aluminum gar-
net) (doubling to the green at 532 nm), and remembering that
two ferroelectric stripes make up one full wavelength, we
calculate the optimum thickness dfrom Eq. ( 2):w2=ðd/C14Þ¼
2:455/C22:65¼5:5.F o r/C14of 1.0 nm (more about this choice
below), this yields an optimum d¼180/C22m.F o r LiNbO 3
(congruent) the out-of-plane dielectric constant is 27.9 and
the in-plane one is 85.2 ( Smith and Welsh, 1971 ). Therefore
the ratio is 3.05 and w2=ðd/C14Þ¼2:455/C21:75¼4:3.F o r
KTP, the dielectric constant is unusually low (average
13.0); the in-plane values are 11.3 and 11.9 (average 11.6),
and the out-of-plane one is frequency dependent but /C2517:5
at low frequencies and 15.4 at high frequencies ( Bierlein
and van Herzeele, 1989 ;Noda et al. , 2000 ). Using the
high-frequency value, this gives a susceptibility ratioof 1.2, for which the square root is 1.1. Hence, w
2=ðd/C14Þ¼
2:455/C21:1¼2:7. For the 1-nm domain wall thickness given
above as an example, this requires a crystal thickness two and
one-half times as great as that for LiNbO 3, approximately
0.45 mm. These three materials thus require different thick-
nesses for optimum phase matching at 1/C22m, as shown in
Fig.33. As can be seen, the different dielectric anisotropy of
the three materials has a relatively small impact on the
optimum domain size, due to the fact that the crystal anisot-
ropy is inside a square root of a square root. A much bigger
variation of optimum domain size can be obtained by tuning
instead the domain wall thickness, as discussed in the next
section.
2. Manipulation of wall thickness
The wall thickness parameter /C14is not an intrinsic constant.
It can be increased by an order of magnitude by impurity10-610-510-410-310-210-810-710-610-510-4
=10nmw (m)
d (m) BNN
LNO
KTP
=1nm
FIG. 33 (color online). Domain size as a function of thickness for
three uniaxial ferroelectrics commonly used in electro-optical ap-plications. The continuous lines are calculated assuming domain
wall thickness of 1 nm, while the dashed lines are for a wall
thickness of 10 nm.G. Catalan et al. : Domain wall nanoelectronics 143
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012doping and it can also be increased via application of an
electric poling field orthogonal to the polar axis.
a. Doping
We see in Reznik et al. (1985) that impurity doping can
greatly increase the domain wall thickness in ferroelectrics.This will decrease the stability thickness dfor a given
wavelength, or alternatively permit longer-wavelengthelectro-optic devices for a fixed film thickness. Similarly,wall thicknesses in congruent lithium niobate are about10 times thicker than in stoichiometric specimens. For
many years only LiNbO
3grown from a congruent melt was
available for study. These crystals have 1% (or 1021cm/C03)
defects. The spectroscopic difference between congruent andstoichiometric LiNbO
3was first shown by Okamoto, Wang,
and Scott (1985) andChowdhury (1978) . Recent periodically
poled LiNbO 3devices favor stoichiometric samples because
their domain walls are more stable. See, for example, Chu
et al. (2008) .
b. Photovoltaic tensor and off-axis poling
The theoretical model of Rao and Wang (2007) implies
that off-axis poling can significantly widen wall thicknesses.This brings us into a more general discussion of photovoltaic
tensors. Over the years, perhaps misled by the standard text
byLines and Glass (2004) , which implies that photovoltaic
response in LiNbO
3is along the polar zaxis, many scientists
failed to recognize that the photovoltaic tensor is neitherdiagonal nor second rank, despite the correct theory ofChen (1968 ,1969) . As a result, large voltages and fields
can arise perpendicular to the polar axis when illuminated.
In a 1-W beam at 514.5 nm wavelength, focused to /C2550/C22m
diameter, lithium niobate exhibits a field of approximately40 kV =cmin the xyplane, due to the /C12
15photovoltaic tensor
component ( Odulov, 1982 ,Anikiev et al. , 1985 ;Reznik
et al. , 1985 ;Chaib, Otto, and Eng, 2003 ) (note that we used
the reduced notation, the photovoltaic tensor is third rank).These off-axis photovoltages can be mitigated via application
of a thermal gradient, which causes charge diffusion tomitigate the photovoltaic effect via the Seebeck effect
(Kostritskii et al. , 2007 ,2008 ). Hence it would be useful to
more carefully examine the effects of off-axis poling and ofphotovoltage normal to the polar axis. In particular, in thepresence of high-intensity laser light the symmetry of
LiNbO
3is actually lowered; the threefold symmetry axis is
lost.
B. Domains and electro-optic response of LiNbO 3
In assessing the microscopic dynamics of domains in poled
lithium niobate, it is useful to point out that the local electricfield is not necessarily along the polar axis, and that for
electro-optic devices, in the presence of light there is a strong
electric polarization induced perpendicular to this threefold c
axis. This was first established by Chen (1969) , and later
evaluated quantitatively by Anikiev et al. (1985) who found
an orthogonal electric field of /C2540 kV =cmin the presence of
moderately focused 0.5 W power at 514.5 nm from an argonlaser. Most recently this result has been confirmed by Chaib,
Otto, and Eng (2003) . We emphasized this point here because
it is contrary to the claims in the textbook by Lines and Glass
(2004) (its first edition was written two years before Chen’s
work). It can significantly influence domain widths. All ofthese effects differ in congruent and stoichiometric LiNbO
3,
as do the phonon spectra ( Scott, 2002 ) and especially the
quasielastic scattering ( Chowdhury, 1978 ;Okamoto, Wang,
and Scott, 1985 ).
C. Photovoltaic effects at domain walls
Recently it was reported that an anomalous photovoltaic
effect in BFO thin films arises from a unique, new mecha-nism, namely, structurally driven steps of the electrostatic
potential at nanometer-scale domain walls ( Yang et al. , 2010 ;
-4-4-40-4-4-4
-15 -10 -5 0 5 10 15-3x10-4-2x10-4-1x10-401x10-42x10-43x10(a) (b)
(c)
-4
Dark currentPhoto-currentCurrent density (A/cm2)
Voltage (V)05 0 1 0 0 1 5 0 2 0 005101520
100 nmVoc (V)
Electrode distance ( m)(d)
FIG. 34 (color online). Light and dark I-Vmeasurements on ordered arrays of 71/C14domain walls in bismuth ferrite showing large open
circuit voltages above the band gap of the material. (a), (b) Schematics of the electrode geometry (c) corresponding I-Vmeasurement
perpendicular to the domain walls over 200/C22mdistance; (d) linear scaling of open circuit voltage with the number of domain walls.144 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012Seidel et al. , 2011 ). In conventional solid-state photovoltaics,
electron-hole pairs are created by light absorption in a semi-
conductor and separated by the electric field spanning a
micrometer-thick depletion region. The maximum voltage
these devices can produce is equal to the semiconductor
electronic band gap, although in noncentric systems such asferroelectrics the photovoltage can be bigger than the band
gap ( Sturman and Fridkin, 1992 ). Interestingly, domain walls
can give rise to a fundamentally different mechanism for
photovoltaic charge separation, which operates over a dis-
tance of 1–2 nm and produces voltages that are significantlyhigher than the band gap (see Fig. 34). The separation
happens at previously unobserved nanoscale steps of the
electrostatic potential that naturally occur at ferroelectric
domain walls in the complex oxide BiFeO
3. Electric-field
control over domain structure allows the photovoltaic effect
to be reversed in polarity or turned off.
Currently, the overall efficiency of those photovoltaic
devices is limited by the conductivity of the bulk bismuth
ferrite material. Methods to increase the carrier mobility as
well as inducing the spatially periodic potential in an adja-cent material with a lower gap than BFO are possible routes
to achieve larger current densities under white light illumi-
nation, and more generally, they demonstrate what the
source of periodic potential and the PðVÞcurrent flow can
be in different materials. Low-band-gap semiconductors withasymmetric electron and hole mobilities are possible candi-
dates to show such an effect. In addition, photoelectrochemic
effects at domain walls are a possible further interesting
route, e.g., for applications in water splitting ( Kudo and
Miseki, 2009 ).
D. Switching of domains
Rather comprehensive reviews of ferroelectric domain
switching have been published elsewhere ( Shur,
Gruverman, and Rumentsev, 1990 ;Scott, 2000 ), and so, after
a few brief remarks, we concentrate on what is new andparticularly pertinent to thin ferroelectric films with high
densities (volume fractions) of domain walls or twin
boundaries.
At present the best way to monitor domain wall switching
is probably via measurement of displacement current IðtÞ
versus time t. This gives a rapid rise followed by a roughly
Gaussian peak. Assuming that the rise is not current limited
from the drive voltage source and that the decay is notlimited by the RCtime constant, such data are popularly
fitted to a model due to Ishibashi and Takagi (1971) and
based upon earlier work by Avrami (1939) for the analogous
problem of crystal growth. The fitting parameters used
involve a characteristic switching time tð0Þand, importantly,
a dimensionality D. One of the important aspects of this
theory is that for a given dimensionality there is a preciseprediction of the dimensionless ratio iðmÞtðmÞ=P, where iðmÞ
is the maximum displacement current density during switch-
ing and occurs at time tðmÞ, and Pis the spontaneous
polarization. In principle the dimension Dis an integer,
but because of other approximations made in the model,particularly that the domain wall speed vis independent of
domain radius r(it actually varies as 1=r), noninteger valuesusually result from least-squares fitting to the data. Other
approximations are not so important, but Dalton, Jacobs, and
Silverman (1971) pointed out that the model fails mathe-
matically for finite dimensions. This model has been used
extensively to fit data as functions of field E, thickness d,
temperature T, and fatigue cycles n. An interesting obser-
vation is that domain dimensionality Doften decreases from
/C253to 2 or 1 with fatigue ( Araujo et al. , 1986 ).
Of particular interest is what happens in thin films of
highly twinned ferroelectrics and ferroelastics. This was first
described by Bornarel, Lajzerowicz, and Legrand (1974) ,
who found that in such cases ferroelectric polar domain wallscould strongly interact with nearby ferroelastic nonpolarwalls, tilting both walls and making the nonpolar wallsslightly polar. This was recently demonstrated rather spec-
tacularly in ferroelectric tris-sarcosine calcium chloride by
Jones et al. (2011) . Of relevance here is also the fact that
ferroelectric domain walls are easily pinned by defects andvacancies, so the switching properties and dielectric contri-bution of the walls can be modified by manipulating thedopant chemistry. Fujii et al. (2010) discussed this in some
detail and explicitly showed how defect dipoles are more
effective at domain wall pinning than are oxygen vacancies.
E. Domain wall motion: The advantage of magnetic
domain wall devices
The development of prototype devices based upon mag-
netic domain devices has been pioneered by Cowburn and co-
workers ( Allwood et al. , 2005 ;Allwood, Xiong, and
Cowburn, 2006a ,2006b ;Atkinson et al. ,2 0 0 6 ) as listed
and shown schematically in Fig. 1. His devices are suitably
small for commercial production (typically 15F2, where F2is
the square of the feature size F), and extremely fast. His
devices include NOT gates, AND gates, ( Zeng et al. ,2 0 1 0 )
shift registers ( O’Brien et al. , 2009 ), read/write memory
devices ( Allwood, Xiong, and Cowburn, 2006a ,2006b ),
signal fan-out devices, and data input and crossover structures(Allwood et al. , 2005 ). On the fundamental physics side, this
group also investigated vortex domain wall transitions, which
have a close relationship with the ferroelectric vortex do-
mains discussed in Sec. III. They also examined magnetic
comb structures (shown in Fig. 35) in detail ( Lewis et al. ,
2010 ).
It is not an exaggeration to say that microelectronic devices
based upon magnetic domain dynamics are a full decade
ahead of those based upon ferroelectric domains.
In some important respects, it is difficult for ferroelectrics
to catch up, literally. This is because magnetic domain wallsinvolve only flipping of spins (no mass) and can easily bedriven at near the speed of sound ( km=s). In fact, they can
even be driven supersonically, with acoustic phonons being
produced in high magnetic fields by supersonic magnetic
domain walls at a phase angle related to that in the analogousproblems of bow waves in water or in Cerenkov radiation(Demokritov et al. , 1988 ,1991 ). By comparison, ferroelec-
tric walls have real momentum and they cannot travel faster
than the theoretical limit set by the transverse acoustic pho-
non, the speed of sound, for otherwise the sonic boom wouldshatter the crystal. Moreover, domain walls satisfy a ballisticG. Catalan et al. : Domain wall nanoelectronics 145
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012equation of motion with viscous damping ( Dawber et al. ,
2005 ) which causes a saturation or ‘‘terminal velocity’’ that is
often (but not always) below the speed of sound.
On the other hand, the terminal velocity, however, is
dependent on the sample and the technique used to deliverthe voltage pulse, and it can be significantly raised. Millermeasured ferroelectric domain wall velocities in LiNbO
3over
9 orders of magnitude from 10/C09mm=supward and found
that they saturate near 1:0m=sat high fields ( Miller, 1998 ).
But more recent studies by Gruverman set a higher limit,between 10 and 100 m =s(Gruverman, Wu, and Scott, 2008 ).
And much faster switching, with velocities approaching thespeed of sound, was achieved by Li and co-workers in directmeasurements of the switching dynamics using an ultrafastphotoconducting switch enabled electric pulse with a rise
time of tens of picoseconds ( Liet al. , 2004 ). They showed
intrinsic switching time scales of 50–70 psec in fullyintegrated capacitors of 2/C23/C22m
2in lateral dimensions,fabricated with films of 150 nm thickness, suggesting veloc-
ities of 2000 –3000 m =s. It should be noted that such mea-
surements are not routine: Indeed, it is quite likely that asignificant number of measurements in the literature are
compromised by either the rise time of the pulse generator,
theRCtime constant of the measurement system, or the rise
time of the oscilloscope system. It is also worth mentioningthat ultrahigh fields can be achieved in sufficiently thinsingle-crystal samples: Morrison et al. (2005) reported fields
of1:3G V =minBaTiO
3lamellae, and nobody knows what
the domain wall speed is under such high fields.
As well as maximizing domain wall speed, the future
development of ferroelectric domain wall devices will proba-
bly require denser domain arrays, so that the walls travel ashorter distance, or rely on device designs that do not requirehigh wall speeds, such as domain conduction devices. Thefirst criterion can be readily met, since ferroelectric domainsare known to be generally narrower than their magneticcounterparts, as seen in previous sections. The second (con-
ductivity of domain walls) has also been discussed and will be
examined further in the next section.
Another important question, which is only now begin-
ning to be explored, is that of domain wall dynamics inmagnetoelectric multiferroics. The different response of themagnetic and ferroelectric components of multiferroicwalls to external fields has been proposed by
Fontcuberta and co-workers as a new mechanism for
eliciting switchable control of exchange bias in hexagonalmultiferroics such as YMnO
3(Skumryev et al. , 2011 ). On
the theoretical front, little is yet known about the dynam-ics of coupled domain walls, so this line of work certainlymerits further attention.
Parkin and co-workers have made considerable progress
in memory devices based upon magnetic domain wall mo-
tion, introducing the concept of the racetrack memory
(Fig. 36). This design concept in principle offers storage
densities that are larger than conventional solid-state mem-ory devices such as flash memory with a better read andwrite performance. Key in these devices is the fact thatmagnetic domain walls can exhibit considerable momentum,moving about a micron after a current pulse is applied
(Thomas, Moriya, and Rettner, 2010 ). This is about an order
of magnitude less than the inertial travel distance of ferro-electric domain walls subjected to large pulsed fields, but itis not negligible. This is important for magnetic domainmemories because it implies that the spatial positioning ofwalls can be precisely controlled by the current pulse length.(This is somewhat surprising, since the magnetic domain
motion follows the Landau-Lifshitz-Gilbert equation, which
is first order in time, whereas ferroelectric domain wallssatisfy Newton’s equations, which are second order in timeand hence explicitly display momentum.)
The basic mechanism to ‘‘push’’ domain walls along the
racetrack using a current is the ‘‘spin torque.’’ The underlyingprinciple is that when spin-polarized electrons in a ferromag-netic material pass through a magnetic domain wall, there is a
torque on the electrons that acts to reorient their spin mag-
netic moments along the magnetization direction (Fig. 37).
Angular momentum in this system is conserved by a reactiontorque, termed the spin transfer torque, which acts from the
FIG. 35. (a) Electron microscope images of a magnetic strip and
magnetic comb structures; the scale bar is 1/C22min all cases.
Magnetic comb structures are designed to speed up domain walls,as experimentally demonstrated in (b). Note the high velocity of the
magnetic domain walls (in excess of 1500 m =s) that can be
achieved in the combed structures. From Lewis et al. , 2010 .146 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012electrons onto the material magnetization in a way such that it
displaces the domain wall in the direction of the electron flow(Stiles and Miltat, 2006 ;Ralph and Stiles, 2008 ). Domain
wall motion can be achieved when the current density throughthe device is sufficiently high.
Current designs of racetrack memories use a spin-coherent
electric current to move magnetic domains along a nano-scopic permalloy wire with a cross section of 200/C2100 nm
2.
As a current is passed through the wire, the domain walls passby read and write heads. A memory device is made frommany such elements. Improvements in domain wall detection
capabilities, based on the development of new magnetoresis-tive materials, allow the use of increasingly smaller magneticdomains to reach higher storage densities. The basic opera-
tion of the racetrack magnetic domain wall memory system is
described by Parkin, Hayashi, and Thomas (2008) , and recent
details concerning wall pinning discussed by Jiang et al.
(2010) , although the basic idea that magnetic domain walls
could be moved into precise positions was developed adecade earlier by Ono et al. (1999a ,1999b) . A recent review
of this aspect of magnetic electronics (‘‘spintronics’’) has
been given by Bader and Parkin (2010) , which follows an
earlier review on fundamentals and applications of nanomag-netism by Bader (2006) .
F. Emergent aspects of domain wall research
We focus on some emergent behavior at domain walls,
particularly in materials such as multiferroics, that exhibitcoupled order parameters, i.e., the charge and spin degree offreedom are coupled. In order to focus the discussion on whatis understood and what remains to be explored, we use the
multiferroic BiFeO
3as our model system. The richness of
phase evolution and electronic properties in this system isnow well established, and we are beginning to understand themanipulation of its electronic structure, correlation effects,and order parameter evolution on the unit-cell level. What arethe consequences and the opportunities? This we discuss
next.
1. Conduction properties, charge, and electronic structure
By far one of the most fascinating aspects of research on a
bismuth ferrite as a multiferroic has to do with the changes in
electronic structure as a function of crystal chemistry andparticularly at domain walls. Rhombohedral BiFeO
3has been
shown to possess ferroelectric domains in thin films that areinsulatorlike, whereas conduction in its domain walls issignificant ( Seidel et al. , 2009 ) (Fig. 38). The observed
conductivity correlates with structurally driven changes in
both the electrostatic potential and the local electronic struc-ture, which shows a decrease in the band gap at the domainwall.
In light of the intriguing electrical conductivity, detailed
electronic properties of the domain walls have been inves-tigated by Lubk, Gemming, and Spaldin (2009) . The layer-
by-layer densities of states was calculated to see if the
structural deformations in the wall region lead to a closingof the electronic band gap. In particular, the ideal cubicstructure, in which the 180
/C14Fe-O-Fe bond angles maximize
the Fe 3d–O2phybridization and hence the bandwidth, has a
significantly reduced band gap compared to the R3cstructure.
Figure 39shows the local band gap extracted from the layer-
by-layer densities of states across the three wall types. In allcases a reduction in the band gap in the wall can be seen, withthe 180
/C14wall showing the largest effect. In no case, however,
does the band gap approach zero in the wall region. The samefirst-principles calculations supporting the experimentalwork of Seidel et al. also give insight into the changes in
the Fe-O-Fe bond angle in BiFeO
3, in addition to the fact that
walls in which the rotations of the oxygen octahedra do not
FIG. 37 (color online). Schematic of spin scattering from an
interface with a ferromagnet in a simple limit of ideal spin-
dependent transmission and reflection. From http://www.nist.gov/
cnst/epg/spin_transfer_torque.cfm.
FIG. 36 (color online). The racetrack: a ferromagnetic nanowire.Pulses of highly spin-polarized current move domain walls coher-
ently in either direction via spin torque. (a) A vertical-configuration
racetrack. Magnetic patterns in the racetrack before and after thedomain walls have moved down one branch of the U, past the read
and write elements, and then up the other branch. (b) A horizontal
configuration. (c) Reading data from the stored pattern by measur-ing the tunnel magnetoresistance of a magnetic tunnel junctionelement connected to the racetrack. (d) Writing data by the fringing
fields of a domain wall moved in a second ferromagnetic nanowire.
(e) Arrays of racetracks on a chip for high-density storage. FromParkin, Hayashi, and Thomas, 2008 .G. Catalan et al. : Domain wall nanoelectronics 147
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012change their phase when the polarization reorients are sig-
nificantly more favorable than those with rotation disconti-
nuities, i.e., antiphase octahedral rotations are energetically
costly.
The analysis of the local polarization and electronic prop-
erties also revealed steps in the electrostatic potential for all
wall types, and these must also contribute to the conductivity.
Steps in the electrostatic potential at domain walls are corre-lated with (and caused by) small changes in the component ofthe polarization normal to the wall ( Seidel et al. , 2010 ).
These changes in normal polarization are a consequence of
the fair rotation of the polar vector across the domain wall and
are not exclusive of BiFeO
3. Tetragonal PbTiO 3, for example,
shows a similar effect for a 90/C14wall ( Meyer and Vanderbilt,
2002 ) (Fig. 40). Extended phase-field calculations for tetrago-
nalBaTiO 3also allow calculating the intrinsic electrostatic
potential drop across the 90/C14domain wall, regardless of the
consideration of the ferroelectric as an n-type semiconductoror dielectric ( Hong et al. , 2008 ). This potential change
creates a large electric field that promotes an asymmetriccharge distribution around the walls, where electrons and
oxygen vacancies concentrate on the opposite sides. The
increased charge density presumably promotes increasedconductivity.
As mentioned, the semirigid rotation of the polar vector
across a ferroelectric-ferroelastic wall leads to an electrostaticpotential that is screened by free charges which enhance the
local charge density and thus, presumably, the conductivity.
Since this polar rotation is not exclusive of BiFeO
3, other
perovskite ferroelectrics should also be expected to displayenhanced conductivity, and perhaps this mechanism is behindthe enhanced conductivity recently reported also for the
domain walls of PbðZr;TiÞO
3(Guyonnet et al. , 2011 ). In
BiFeO 3, several other factors might be further helping the
conductivity enhancement: First, the magnetoelectric cou-pling between polarization and spin lattice is such that themagnetic sublattice rotates with the polarization ( Zhao et al. ,
2006 ;Lebeugle et al. , 2008 ). Since spins rotate rigidly (see
Sec. III.B ), they might favor a more rigid rotation of the
polarization and hence a bigger electrostatic step at the wall(and, of course, the polarization of BiFeO
3is itself bigger
than that of other known perovskite ferroelectrics, whichmeans that all other things being equal a rigid polar rotation
inBiFeO
3will cause a bigger electrostatic step). Also, the
increased spin alignment at the wall should lower the mag-netic contribution to the band gap ( Dieguez and In ˜iguez,
2011 ). But perhaps the most obvious consideration is the
fact that BiFeO
3has an intrinsically smaller band gap than
other prototypical perovskite ferroelectrics ( /C242:7e V instead
of 3.5–4 eV). This means that the screening charges accumu-
lated at the wall will be closer to the bottom of the conductionband and hence will more easily contribute to the conductiv-ity. It would be interesting to see if highly insulating
FIG. 40. 90/C14domain walls in lead titanate: (a) potential steps at
domain walls; (b) theoretical conduction and valence band alignment;
(c) potential in equilibrium. From Meyer and Vanderbilt, 2002 .
FIG. 39 (color online). Local band gap at domain walls in bismuth
ferrite extracted from the layer-by-layer densities of states. From
Lubk, Gemming, and Spaldin, 2009 .
FIG. 38 (color online). (a) The three different types of domain
walls in rhombohedral bismuth ferrite. Arrows indicate polarization
directions in adjacent domains. (b) In-plane PFM image of a written
domain pattern in a monodomain BFO (110) film showing all threetypes of domain wall. (c) Corresponding c-AFM image showingconduction at both 109
/C14and 180/C14domain walls; note the absence of
conduction at the 71/C14domain walls. This stands in contrast with
recent results reporting enhanced conductivity in the 71/C14walls
(Farokhipoor and Noheda, 2011 ). Adapted from Seidel et al. , 2009 .148 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012single-crystal samples such as those studied by Chishima
et al. (2010) display the same domain wall conductivity as
do the thin-film samples studied so far. The current density of
these single-crystal samples can be as low as 10/C09A=cm2
even at electric fields in excess of 50 kV =cm, while typical
resistivities of thin films are in the region of 106–108/C10c m ,
comparable to the resistivity of good quality BiMnO 3
(Eerenstein et al. , 2005 ).
The role of defect accumulation at the walls also deserves
close scrutiny, because defects control the transport behavior,
as recently emphasized by Farokhipoor and Noheda (2011) .
Localized states are found in the spectrum of ferroelectricsemiconductors, and states localized at the walls and insidethe domain but close to the wall split off from the bulk
continuum. These nondegenerate states have a high disper-
sion, in contrast with the ‘‘heavy-fermion’’ states at an iso-lated domain wall ( Idlis and Usmanov, 1992 ). Charged
double layers can be formed due to coupling between polar-ization and space charges at ferroelectric-ferroelastic domainwalls ( Xiao et al. , 2005 ). Charged domain wall energies are
about 1 order larger than the uncharged domain wall energies
(Gureev, Tagantsev, and Setter, 2009 ), and phenomenological
calculations show decoration of walls by defects such asoxygen vacancies. The presence of charge and defect layersat the walls means that such walls promote electrical failure
by providing a high conductivity pathway from electrode to
electrode ( Xiao et al. , 2005 ).Eliseev et al. (2011) have also
shown how the relative sign between the wall charge and thetype of majority carriers also matters: positively chargedwalls in an n-type ferroelectric are more easily screened
(and thus have smaller thickness and lower energy) than
negatively charged walls, due to the bigger abundance of
screening charges. Vice versa for negatively charged wallsin ap-type ferroelectric semiconductor.
The control of the electronic structure at walls by doping
and strain in ferroelectric and ferroeleastic oxides opens a way
to effectively engineer nanoscale functionality in such mate-
rials. For the case of BiFeO
3A-site doping with Ca, and
magnetic B-site substitution such as Co or Ni, might prove to
be a viable way to achieve new domain wall properties bymanipulating the electronic structure, spin structure, and di-
polar moment in this material ( Yang et al. , 2009 ). Of obvious
future interest is the question of what sets the limits to thecurrent transport behavior at walls: Can one ‘‘design’’ thetopological structure of the domain wall to controllably induceelectronic phase transitions within the wall arising from thecorrelated electron nature? Is it possible to trigger an Anderson
transition by doping of domain walls or straining them?
Recently, some of us reported the observation of tunable
electronic conductivity at domain walls in La-doped BFOlinked to oxygen vacancy concentration ( Seidel et al. , 2010 ).
The conductivity at 109
/C14walls is thermally activated with
activation energies of 0.24 to 0.5 eV. From a broader perspec-
tive, these results are the first step toward realizing thetantalizing possibility of inducing an insulator-metal transi-tion ( Imada, Fujimori, and Tokura, 1998 ) locally within the
confines of the domain wall through careful design of theelectronic structure, the state of strain, and chemical effects at
the domain wall. For actual device applications the magni-
tude of the wall current needs to be increased. The choice ofthe right shallow-level dopant and host material might prove
to be key factors in this respect. Further study of correlations
between local polarization and conductivity is an exciting
approach to understanding the conduction dynamics andassociated ferroelectric properties in the presence of strongcoupling between electronic conduction and polarization incomplex oxides.
2. Domain wall interaction with defects
Defect–domain wall interaction is an important area of
research that deserves increased attention ( Robels and Arlt,
1993 ;Gopalan, Dierolf, and Scrymgeour, 2007 ). Point de-
fects can broaden the wall ( Shilo, Ravichandran, and
Bhattacharya, 2004 ;Lee, Salje, and Bismayer, 2005 ). The
width of twin walls in PbTiO 3, for example, can be strongly
modified by the presence of point defects within the wall. Theintrinsic wall width of PbTiO
3is about 0.5 nm, but clusters of
point defects can increase the size of the twin wall up to
15 nm ( Salje and Zhang, 2009 ). Trapped defects at the
domain boundary play a significant role in the spatial varia-tion of the antiparallel polarization width in the BaMgF
4
single crystal as seen by PFM ( Zeng et al. , 2008 ), and
asymmetric charge distribution around 90/C14domain walls in
BaTiO 3have also been reported, where electrons and oxygen
vacancies concentrate on the opposite sides ( Hong et al. ,
2008 ).
Interaction between the order parameter and the point
defect concentration causes point defects to accumulate
within twin walls ( Salje and Zhang, 2009 ); conversely such
defects contribute to the twin-wall kinetics and hysteresis, asthey tend to clamp the walls. Oxygen vacancies, in particular,
have been shown to have a smaller formation energy in the
domain wall than in the bulk, thereby confirming the ten-dency of these defects to migrate to, and pin, the domainwalls ( He and Vanderbilt, 2003 ). This leads to a mechanism
for the domain wall to have a memory of its location during
annealing ( Xiao et al. , 2005 ).
3. Magnetism and magnetoelectric properties of multiferroic
domain walls
An important question to ask at this point is what is
the true state of magnetism at a multiferroic domain wall.Temperature-dependent transport measurements are a pos-
sible route to follow to understand the actual spin structure
and whether it exhibits a glasslike or ordered ferromagneticstate. Of interest is the effect of extra carriers introduced intothe system, e.g., by doping or electric gating, on magnetism.Is there a way to change the magnetic interaction from super-
exchange to double exchange? The strength of the coupling
between the ferroelectric and antiferromagnetic walls inBiFeO
3is an issue that still needs to be resolved from both
a theoretical and an experimental perspective. The role of the
dimensionality on electrical and magnetoelectrical transport
needs to be elucidated and compared to known systems, suchas manganites ( Dagotto, 2003 ;Salafranca, Yu, and Dagotto,
2010 ). We note that the interaction between ferroelectric and
antiferromagnetic domain walls has been studied in model
multiferroics such as YMnO
3(Goltsev et al. , 2003 ) and
BiFeO 3(Gareeva and Zvezdin, 2011 ). In both cases it hasG. Catalan et al. : Domain wall nanoelectronics 149
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012been shown that the antiferromagnetic domain walls are
significantly wider (by /C241–2orders of magnitude) compared
to the ferroelectric walls. This is also in agreement with the
phenomenological predictions of Daraktchiev, Catalan, and
Scott (2010) for coupling-mediated wall broadening.
VI. FUTURE DIRECTIONS
It is safe to say that the phenomena and physics of domain
walls in ferroelectrics form an exciting and growing field of
interest. As device size is reduced, the number density of
domain walls grows, with consequences for functionalbehavior. Based on the differences between domain wall
types, the inclusion of a ‘‘wrong’’ domain type could give
the system entirely different properties. With the current
developments surrounding the conductive properties there
are many remaining questions and some new ones.
Electronic conduction was predicted for ferroelectric domain
walls based on the fact that charged double layers may formon either side of these walls ( Hong et al. , 2008 ). Since the
ferroelectric in which the conductive walls were found is a
multiferroic, the obvious next step is to verify that multi-
ferroics also have this double layer and determine whether it
is responsible for the conduction. If this double layer isindeed present and responsible for the conduction, it should
be interesting to combine this with the idea that multiferroics
have broader walls compared to pure ferroelectrics. Is there a
maximum on the thickness of a domain wall to still have this
double layer and be conductive? In a more general sense one
could ask oneself whether the physics and assumptions based
on the findings in pure ferroelectrics are valid for the multi-ferroic materials as well. Conversely, we need to also identify
the aspects of domain wall behavior that are exclusive to
multiferroics: Order parameter coupling and chirality are two
features of multiferroic walls that have unique roles.
Another front of research is the investigation of dynamic
conductivity at domain walls ( Maksymovych et al. , 2011 ).
This addresses important factors: a possible electric-field
induced distortion of the polarization structure at the domainwall, the dependence of conductivity on the degree of dis-
tortion, and weak-pinning scenarios of the distorted wall. The
domain wall is likely not a rigid electronic conductor, instead
offering a quasicontinuous spectrum of voltage-tunable elec-
tronic states ( Maksymovych et al. , 2011 ). This is different
from ferroelectric domains, where switching may give rise to
discrete (often only two) conductance levels ( Garcia et al. ,
2009 ;Maksymovych et al. , 2009 ). The intrinsic dynamics of
domain walls and other topological defects are expected not
only to influence future theoretical and experimental inter-
pretations of the electronic phenomena, but also to pose the
possibility of finding unique properties of multiferroic do-
main walls, e.g., magnetization and magnetoresistance within
an insulating antiferromagnetic matrix ( Heet al. , 2011 ), also
due to order parameter coupling and localized secondary
order parameters ( Salje and Zhang, 2009 ;Daraktchiev,
Catalan, and Scott, 2010 ). Of future interest is the question
of what sets the limits to the current transport behavior at
walls: Can one design the topological structure of the domainwall to controllably induce electronic phase transitions within
the wall arising from the correlated electron nature? Is itpossible to trigger an Anderson transition by doping of
domain walls ( Yang et al. , 2009 ) or straining them? The
observation of superconductivity in ferroelastic walls of WO
3
certainly points to various exciting and unexplored areas of
domain boundary physics ( Aird and Salje, 1998 ).
Another interesting direction for domain wall engineering
in ferroelectrics is by the size and design of the system, andthis includes not only the domains themselves but also theirhierarchical self-organization into bigger metastructures.Recently, Schilling et al. (2009) presented work on nano-
ferroelectrics, which shows considerably more domain wallsper unit volume, thanks to the size constraints in two and
three dimensions, as opposed to the single finite dimension of
thin films. Yet another unique design feature of the samples ofSchilling et al. is that they are free-standing ferroelectrics,
unlike those that are grown on a substrate, and for whichintrinsic surface tension can play a bigger role ( Luk’yanchuk
et al. , 2009 ). Such nanostructures are also prone to new types
of topological defects beyond the classic domain walls; for
example, recent work by Hong et al. (2010) shows that arrays
of ferroelectric nanowires have switchable quadrupoles andthus potential as nanodevices. Exotic topological defects innanostructures (vertices, vortices, quadrupoles, etc.) are cur-rently an active area of research.
Another interesting feature that is being studied intensively
is the fact that the domains in nanocrystals clearly show
organization on several length scales, with correlation not
just between narrow stripe domains but also between packetsof stripes. Ivry et al. (2011) found a variety of mesoscopic-
scale domain packets or bundles with considerable cross-talkacross PbðZr;TiÞO
3(PZT) grain boundaries. More strikingly,
McQuaid et al. (2011) showed metadomains or superdo-
mains that are composed of thin stripes but reproduce on amesoscopic scale the exact shape and functional behavior of
closure domains such as those of Figs. 10and11. The physics
and functional engineering of mesoscopic metadomains orbundles is a rapidly growing topic that will no doubt see moreactivity in the near future.
Several applications have been suggested to make use of
domain walls in ferroelectric materials based on their addi-tional functionalities as well as their affects on existing
devices. Uses that have been mentioned are as a local strain
sensor incorporated on an AFM probe or a multilevelresistance-state device that is written by an electrical current(Be´a and Paruch, 2009 ). Other possibilities include nonvola-
tile memories, piezoelectric actuators, ultrasound trans-ducers, surface acoustic wave devices, and opticalapplications ( Gopalan, Dierolf, and Scrymgeour, 2007 ). For
existing devices, the discovery of conducting domain walls
stimulates engineers to prevent their products from having thewrong domain walls that could cause leakage and prevent itsuse in ferroelectric memories. This use of ferroelectrics inmemory has recently been reviewed, and it has been arguedthat conductivity may not be a detriment but an opportunityfor new memory reading mechanisms ( Be´a and Paruch, 2009 ;
Garcia et al. , 2009 ;Maksymovych et al. , 2009 ;Zubko and
Triscone, 2009 ;Jiang et al. , 2011 ).
Experimental results and theoretical investigations in
recent years have convincingly demonstrated that certaintransition metal oxides and some other materials have150 G. Catalan et al. : Domain wall nanoelectronics
Rev. Mod. Phys., V ol. 84, No. 1, January–March 2012dominant properties driven by spatial inhomogeneity.
Strongly correlated materials incorporate physical interac-tions (spin, charge, lattice, and/or orbital hybridization), al-
lowing complex interactions between electric and magnetic
properties, resulting in ferromagnetic, or antiferromagneticphase transitions. Of even higher interest are the heterointer-faces formed between correlated materials showing new stateproperties. Domain walls are only one example of ‘‘natu-rally’’ occurring interfaces in such materials. The challenge is
to determine whether such complex interactions can be
controlled in those materials or heterointerfaces at suffi-ciently high speeds and densities to enable new logic devicefunctionality at the nanometer scale. Parameters such asinterface energy, switching speed and threshold, tunability,
dynamics of the states, and size dependencies need to be
quantified to determine if domain boundary materials couldbe employed as a building block for information processingsystems.
In addition, there are some new phenomena associated
with ferroelectric domain walls that merit fundamental study:
As shown in Sec. III, 2D arrays of vertex domains on ferro-
electric surfaces often come in pairs of threefold vertices(Srolovitz and Scott, 1986 ). Fourfold vertices of domains
exist in barium sodium niobate, and sixfold domains arewell known since 1967 in YMnO
3(Safrankova, Fousek,
and Kizhaev, 1967 ). And so one might ask whether these
arrays of vertex domains ‘‘melt’’ at temperatures below theCurie temperature at which stripe domains disappear, i.e., doferroelectric vertex arrays undergo Kosterlitz-Thouless melt-ing ( Kosterlitz and Thouless, 1973 ) involving defect pair
production and annihilation? A second and rather deep phe-
nomenon has been recently discovered by Schilling et al.
(2011) : Vertex domains in rectangular ferroelectrics have off-
centered vertices, whose position can be calculated accordingto a Landau theory with aspect ratio replacing temperature;the resulting novel shape-generated phase transition can
therefore occur at0 K (quantum criticality).
The ferromagnetic properties of ferroelectric walls in para-
magnetic and antiferromagnetic materials ( Goltsev et al.
(2003) ;Daraktchiev, Catalan, and Scott (2008 ;2010 ) suggest
that much more research and development should be done on
domain walls in multiferroics and also on the dynamics of
domain walls in these materials ( Skumryev et al. , 2011 ): We
note in this respect that BiFeO
3is no longer the only room-
temperature multiferroic, nor Cr2O3the only good room-
temperature magnetoelectric, with the lead-iron-tantalate,lead-iron-niobate, lead-iron-tungstate family now being
studied in various laboratories (Josef Stefan Institute,
University of Puerto Rico, University of Cambridge), andnew chromates being reported at Florida State, all of whichfunction at room temperature. Many of these are relaxorlikesystems and therefore have intrinsic nanodomains.
In summary, we have provided an overview on ferroelectric
and multiferroic nanodomain and domain wall electronics.The state of understanding and especially of application lagsthat for magnetic domains, with which comparisons are made;the work of Cowburn et al. and Parkin et al. makes it hard for
ferroelectric domain electronics to compete with magnetic
devices based on spatial manipulation; this is simply because
the magnetic domains have greater mobilities. Thus it isunlikely that ferroelectrics will provide the equivalent of race-
track memories, or fast
AND orNOT gates, as developed by
those groups. Instead it is likely that they will provide com-
plementary devices that exploit the electrical conductivity
and/or ferromagnetisn of ferroelectric domain walls. Hence
these may involve fewer memory devices but more intercon-
nects, switches, and sensors and actuators. Domain wall elec-
tronics, particularly with ferroelectrics and multiferroics, may
also provide useful hybrid devices involving carbon nanotubes
(Kumar, Scott, and Katiyar, 2011 ).
It is always risky to predict the next generation of devices,
but it is likely that ferroelectric nanodomains and domain
walls may first find commercial application not in consumer
electronics but in high-end products. Medical physics (par-
ticularly implants), satellite physics (NASA reported in
August 2011 its test results of PZT 94. Ferroelectric random
access memories (FRAMs) in microsatellites), and military
applications all pay a premium for smaller size and lower
power. Nanoscience has yet to live up to the publicity and
hype it has received, but such initial applications, where cost
is less important than size and power consumption, will
surely lead the way as disruptive technologies.
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PhysRevB.103.024524.pdf | PHYSICAL REVIEW B 103, 024524 (2021)
Spin pumping between noncollinear ferromagnetic insulators through thin superconductors
Haakon T. Simensen , Lina G. Johnsen , Jacob Linder, and Arne Brataas
Center for Quantum Spintronics, Department of Physics, Norwegian University of Science and Technology, NO-7491 Trondheim, Norway
(Received 25 November 2020; revised 11 January 2021; accepted 12 January 2021; published 22 January 2021)
Dynamical magnets can pump spin currents into superconductors. To understand such a phenomenon, we
develop a method utilizing the generalized Usadel equation to describe time-dependent situations in supercon-ductors in contact with dynamical ferromagnets. Our proof-of-concept theory is valid when there is sufficientdephasing at finite temperatures, and when the ferromagnetic insulators are weakly polarized. We derive theeffective equation of motion for the Keldysh Green’s function focusing on a thin film superconductor sandwichedbetween two noncollinear ferromagnetic insulators, one of which is dynamical. In turn, we compute the spincurrents in the system as a function of the temperature and the magnetizations’ relative orientations. When theinduced Zeeman splitting is weak, we find that the spin accumulation in the superconducting state is smaller thanin the normal states due to the lack of quasiparticle states inside the gap. This feature gives a lower backflow spincurrent from the superconductor as compared to a normal metal. Furthermore, in superconductors, we find thatthe ratio between the backflow spin current in the parallel and antiparallel magnetization configuration dependsstrongly on temperature, in contrast to the constant ratio in normal metals.
DOI: 10.1103/PhysRevB.103.024524
I. INTRODUCTION
Superconductivity and ferromagnetism are conventionally
considered antagonistic phenomena. Superconductors (SCs)in contact with ferromagnets (FMs) lead to mutual suppres-sion of both superconductivity and ferromagnetism [ 1,2].
Despite this apparent lack of compatibility, several intriguingeffects also emerge from the interplay between superconduc-tivity and ferromagnetism [ 3,4]. A singlet s-wave SC either
in proximity with an inhomogeneous exchange field [ 5], or
experiencing a homogeneous exchange field and spin-orbit
coupling [ 6,7], induces spin-polarized triplet Cooper pairs.
The generation of spin-polarized Cooper pairs is of particu-lar interest, paving the way for realizing dissipationless spintransport [ 4]. In recent developments, the combination of
magnetization dynamics and superconductivity has gainedattention. This is motivated by spin-pumping experimentsreporting observations of pure spin supercurrents [ 8,9]. Ex-
hibiting a wide range of interesting effects and phenomena,SC-FM hybrids are promising material combinations in theemerging field of spintronics [ 10].
It is well known that the precessing magnetization in FMs
generates spin currents into neighboring materials via spinpumping [ 11–13]. The injection of a spin current into a neigh-
boring material generates a spin accumulation, which in turngives rise to a backflow spin current into the FM. Spin pump-ing has a reactive and a dissipative component, characterizedby how it affects the FM’s dynamics. Reactive spin currentsare polarized along the precession direction of the magnetiza-tion, ˙m, and they cause a shift in the ferromagnetic resonance
(FMR) frequency. Dissipative spin currents resemble Gilbertdamping and are polarized along m×˙m, relaxing the magne-
tization toward its principal axis. The dissipative spin currentenhances the effective Gilbert damping coefficient [ 14], and
broadens the FMR linewidth [ 12,15].
In SCs, both quasiparticles and spin-polarized triplet
Cooper pairs can carry spin currents. In the absence of spin-polarized triplet pairs, spin pumping is typically much weakerthrough a superconducting contact than a normal metal (NM)[16,17]. The reduced efficiency is because the supercon-
ducting gap /Delta1prevents the excitation of quasiparticles by
precession frequencies ω< 2/Delta1. When spin-polarized triplet
pairs are present, spins can flow even for low FMR fre-quencies as pure spin supercurrents. Reference [ 8] reported
evidence for such pure spin supercurrents. An enhanced FMRlinewidth was measured in a FM–SC–heavy-metal hybridsystem as it entered the superconducting state, which is a sig-nature of an enlarged dissipative spin current [ 18]. The authors
attributed this observation to spin transport by spin-polarizedtriplet pairs. These findings and the rapid development ofspintronics have lately sparked a renewed interest in spintransport through FM|SC interfaces [ 9,19–27]. Several earlier
works have also considered spin transport resulting from mag-netization dynamics in SC-FM hybrids [ 28–35].
Progress has been made in developing a theoretical under-
standing of the spin pumping through SCs [ 17,19,21–23,25
].
For instance, assuming suppression of the gap at the interface,Ref. [ 17] computed the reduced spin-pumping efficiency in
the superconducting state using quasiclassical theory. How-ever, to the best of our knowledge, a full understanding ofthe boundary conditions’ complicated time dependence be-tween dynamical ferromagnets and superconductors is notyet in place. This development is required to give improvedspin-pumping predictions in multilayers of FMs, SCs, andNMs. Furthermore, spin-pumping in superconducting sys-tems with a noncollinear magnetization configuration remains
2469-9950/2021/103(2)/024524(12) 024524-1 ©2021 American Physical SocietySIMENSEN, JOHNSEN, LINDER, AND BRATAAS PHYSICAL REVIEW B 103, 024524 (2021)
theoretically underexplored, but it can provide additional in-
sight into spin-transport properties.
We present a self-consistent method designed to solve the
explicit time dependence arising from magnetization dynam-ics by using the generalized Usadel equation. The explicittime dependence complicates the treatment and understandingof spin-transport properties. We aim to describe a consistentproof-of-concept approach that is as simple as possible tounderstand. We will therefore use simplifying assumptionsthat are justified in weak insulating ferromagnets. Hopefully,the main message is then less hindered by subtleties. (i) Weexplore trilayers with a thin film SC between two noncollinearferromagnetic insulators (FMIs). (ii) We exclusively considerthe imaginary part of the spin-mixing conductance in thecontacts between the FMIs and the SC film. (iii) We considerinsulating ferromagnets. The first assumption requires that theinterface resistance is larger than the superconductor’s bulkresistance in the normal state, and that the superconductor isthinner than the coherence length. The second assumption isvalid in weak ferromagnets.
Our first main result is the equation of motion for the
Green’s function in the SC film when the magnetizationprecesses. Based on these results, we present quantitativepredictions for the spin current as a function of temperatureand the relative magnetization orientation between the FMIs.
II. THE GENERALIZED USADEL EQUATION AND ITS
SOLUTION
In this section, we will first present the generalized Usadel
equation, taking into account the magnetization precession.We will demonstrate that it is possible to find an approxi-mate solution to the time dependence when the precessionfrequency is sufficiently slow. In superconductors, we willdiscuss how this approach requires sufficient dephasing, sinceotherwise the peaks in the density of states invalidate theadiabatic assumption. Finally, we will solve the generalizedUsadel equation and compute the resulting spin-current drivenby the magnetization precession. Our analytical approach issupplemented by a numerical solution demonstrating the con-sistency of our assumptions.
A. The Generalized Usadel equation in a FMI|SC|FMI trilayer
The generalized Usadel equation determines the time evo-
lution of the electron Green’s function ˇGin the dirty limit. In
a SC the generalized Usadel equation reads [ 36]
−iD∇ˇG◦∇ˇG+i∂t1ˆτ3ˇG(t1,t2)+iˇG(t1,t2)∂t2ˆτ3
+[ˆ/Delta1(t1)δ(t1−t/prime)◦,ˇG(t/prime,t2)]=0, (1)
where Dis the diffusion coefficient and δ(t) is the Dirac delta
function. The symbol ◦denotes time convolution,
(a◦b)(t1,t2)=/integraldisplay∞
−∞dt/primea(t1,t/prime)b(t/prime,t2), (2)
IMFC S FMI
e
e
FIG. 1. FMI|SC|FMI trilayer. The superconductor is a thin film.
The large red arrows depict the magnetic moments of localized d
electrons in the FMIs. The green cloud illustrates a gas of selectrons
with spin up (red) and down (blue). An attractive interaction between
theselectrons (red sawtooth-like line) gives rise to superconductiv-
ity. The s-dexchange interaction at the interfaces gives rise to the
indirect exchange interaction between the left and right FMI (wiggly
gray lines). The precessing magnetization in the left FMI gives riseto spin currents j
s
Landjs
Rfrom the FMIs into the SC.
and [ a◦,b]=a◦b−b◦a.ˇGand ˆ/Delta1are matrices,
ˇG=/parenleftbiggˆGR ˆGK
0 ˆGA/parenrightbigg
,ˆ/Delta1=⎛
⎜⎝00 0 /Delta1
00 −/Delta1 0
0/Delta1∗00
−/Delta1∗00 0⎞
⎟⎠,(3)
where R,A, and Kdenote the retarded, advanced, and Keldysh
components, respectively. /Delta1is the superconducting gap. We
choose to work in the gauge where /Delta1=/Delta1∗is real. In our
notation, the hat (e.g., ˆG) denotes 4 ×4 matrices in the sub-
space of particle-hole ⊗spin space. The inverted hat (e.g.,
ˇG) denotes matrices spanning Keldysh space as well. σiare
Pauli matrices spanning spin space, where i∈{0,x,y,z},
andσ0is the identity matrix. τiare Pauli matrices span-
ning particle-hole space, where i∈{0,1,2,3}, andτ0is the
identity matrix. To simplify the notation, we will omit outerproduct notation between matrices in spin and particle-holespace. Consequently, τ
iσjshould be interpreted as the outer
product of the matrices τiandσj. Moreover, we use the
following notation for matrices that are identity matrices inspin space: ˆ τ
i≡τiσ0.
We consider thin film SCs sandwiched between two iden-
tical, homogeneous, weakly magnetized FMIs, illustrated inFig. 1. Because of the insulating nature of the FMIs, we disre-
gard any tunneling through the FMIs. The interaction betweenelectrons in the SC region and the FMIs is therefore localizedat the interfaces. This s-dexchange interaction couples the
localized delectrons in the FMIs to the selectrons in the
SC at the interface. In thin film SCs, where the thickness ofthe superconductor is much shorter than the coherence length,L
S/lessmuchξS, we can approximate the effect of the s-dexchange
interaction as an induced, homogeneous magnetic field in theSC [ 37–40]. Furthermore, in computing the transport prop-
erties, this assumption requires that the interface resistances(inverse ”mixing” conductances) are larger than the SC’s bulkresistance in the normal state. When L
S/lessmuchξS, the Green’s
function changes little throughout the SC, and we thereforeneglect the gradient term in the generalized Usadel equation
024524-2SPIN PUMPING BETWEEN NONCOLLINEAR … PHYSICAL REVIEW B 103, 024524 (2021)
within the SC. The resulting effective generalized Usadel
equation for the FMI|SC|FMI trilayer then reads
i∂t1ˆτ3ˇG(t1,t2)+iˇG(t1,t2)∂t2ˆτ3+[ˆ/Delta1(t1)δ(t1−t/prime)◦,ˇG(t/prime,t2)]
+meff[m(t1)·ˆσδ(t1−t/prime)◦,ˇG(t/prime,t2)]=0, (4)
where m(t)=mL(t)+mR(t), and where mL/Ris the magne-
tization unit vector for the left /right FMI. meffis the effective
magnetic field that each of the two identical FMIs wouldseparately induce in the SC (in units of energy), and ˆσ=
diag( σ,σ
∗), where σis the vector of Pauli matrices in spin
space. Note that when mL=−mR, the effective magnetic
field in the superconductor vanishes, in agreement with theconclusions of Ref. [ 41].
The effective generalized Usadel Eq. ( 4) was phenomeno-
logically derived. We find the same equation by includingboundary conditions to the FMIs [ 42,43], and then averaging
the Green’s function over the thickness of the superconductor.In principle, one could also have included other terms that arehigher order in both the Green’s functions and magnetizations.However, we consider weak ferromagnets, where the phasedifference /Delta1ϕ=ϕ
↑−ϕ↓in the spin-dependent reflection co-
efficients r↑/↓is small. Then it is sufficient to include the
imaginary part of the spin mixing conductance, which resultsin Eq. ( 4). In other words, we disregard the real part of the
mixing conductance, which is central in strong ferromagnets[17].
B. Gradient expansion in time and energy
The Green’s function ˇG(t1,t2) correlates wave functions
at times t1and t2. By shifting variables to relative time
τ≡t1−t2and absolute time t≡(t1+t2)/2, and performing
a Fourier transformation in the relative time coordinate, thefollowing identity holds [ 44,45]:
F{(a◦b)(t
1,t2)}=exp/braceleftbiggi
2/parenleftbig
∂a
E∂b
t−∂a
t∂b
E/parenrightbig/bracerightbigg
a(E,t)b(E,t),
(5)
where Fdenotes Fourier transform in τ,a(E,t) and b(E,t)
are the Fourier transforms of a(τ,t) and b(τ,t) in the relative
time coordinate, and ∂a(b)
E(t)denotes partial differentiation of the
function a(b) with respect to the variable E(t). We will now
Fourier transform and rewrite the generalized Usadel Eq. ( 4)
into ( E,t) coordinates.
The first two terms of Eq. ( 4) contain time differential oper-
ators. After rewriting these terms as the relative and absolutetime coordinates, and Fourier-transforming the relative timecoordinate, we find [ 46]
F/braceleftbig
i∂
t1ˆτ3ˇG(t1,t2)+iˇG(t1,t2)∂t2ˆτ3/bracerightbig
=E[ˆτ3,ˇG(E,t)]+i
2{ˆτ3,∂tˇG(E,t)}. (6)
The remaining two terms in Eq. ( 4) contain commutators
of time convolutions of one-point functions /Delta1(t1) and m(t1)
and the Green’s function ˇG(t1,t2). These two terms transform
equally. We will therefore consider only the term containingthe magnetization in detail. By straightforward substitutioninto the term containing the magnetization of Eq. ( 4)i n t oEq. ( 5), we find that
F{[m(t
1)·ˆσδ(t1−t/prime)◦,ˇG(t/prime,t2)]}
=exp/braceleftbigg
−i
2∂m
t∂ˇG
E/bracerightbigg
m(t)·σˇG(E,t)
−exp/braceleftbiggi
2∂m
t∂ˇG
E/bracerightbigg
ˇG(E,t)m(t)·σ. (7)
In the following, we drop the arguments Eandtto ease the
notation.
We proceed by expanding the exponential function with
differential operators,
exp/braceleftbigg
−i
2∂m
t∂ˇG
E/bracerightbigg
(m·σ)ˇG−exp/braceleftbiggi
2∂m
t∂ˇG
E/bracerightbigg
ˇG(m·σ)
=[(m·ˆσ),ˇG]−/parenleftbiggi
2/parenrightbigg
{∂t(m·ˆσ),∂EˇG}
+1
2!/parenleftbiggi
2/parenrightbigg2/bracketleftbig
∂2
t(m·ˆσ),∂2
EˇG/bracketrightbig
−1
3!/parenleftbiggi
2/parenrightbigg3/braceleftbig
∂3
t(m·ˆσ),∂3
EˇG/bracerightbig
+(···), (8)
where {... ,... }denotes an anticommutator. Here and later
on, for ease of notation, we drop the superscript of the differ-ential operators. Instead, we let the differential operators onlyact on the factor directly to the right of it. We keep terms onlyup to linear order in the gradients. This is justified when
/vextendsingle/vextendsingle/vextendsingle/vextendsingle1
23/bracketleftbig
∂n
t(m·ˆσ),∂n
EˇG/bracketrightbig
ij/vextendsingle/vextendsingle/vextendsingle/vextendsingle/lessmuch/vextendsingle/vextendsingle/bracketleftbig
∂
n−2
t(m·ˆσ),∂n−2
EˇG/bracketrightbig
ij/vextendsingle/vextendsingle,(9)
/vextendsingle/vextendsingle/vextendsingle/vextendsingle1
23/braceleftbig
∂n
t(m·ˆσ),∂n
EˇG/bracerightbig
ij/vextendsingle/vextendsingle/vextendsingle/vextendsingle/lessmuch/vextendsingle/vextendsingle/braceleftbig
∂
n−2
t(m·ˆσ),∂n−2
EˇG/bracerightbig
ij/vextendsingle/vextendsingle,(10)
where ∂n
tdenotes the nth partial derivative with respect to t.
The magnetization precesses at a frequency ω. Therefore, ω
must be much smaller than the energy gradient of the Green’sfunction. First, to avoid a diverging energy gradient of theGreen’s function, we assume finite temperatures. Second, weadd a phenomenological dephasing parameter δ=1/τ
depto
the Green’s function, E→E+iδ, where τdepis a character-
istic dephasing time. We then find that the requirements ( 9)
and ( 10) are satisfied when ( ωτdep)2/8/lessmuch1 and ( ωβ)2/8/lessmuch1,
where β=1/kBTis the inverse temperature.
To linear order, the effective generalized Usadel equation
in the FMI|SC|FMI trilayer reads
E[ˆτ3,ˇG]+i
2{ˆτ3,∂tˇG}+[ˆ/Delta1,ˇG]−i
2{∂tˆ/Delta1,∂ EˇG}
+meff[m·ˆσ,ˇG]−imeff
2{∂tm·ˆσ,∂EˇG}=0. (11)
In the next section, we will supplement this equation with
terms arising from spin-memory loss.
C. Spin relaxation
To obtain a realistic model, we additionally need to include
some sort of spin relaxation mechanism in the generalizedUsadel Eq. ( 11). As a simple model, we model the relaxation
as a coupling to a NM reservoir, parametrized by the coupling
024524-3SIMENSEN, JOHNSEN, LINDER, AND BRATAAS PHYSICAL REVIEW B 103, 024524 (2021)
coefficient V. This coupling relaxes the Green’s function in
the SC toward the equilibrium solution around the Fermilevel in the NM reservoir. The effective generalized Usadelequation including this relaxation reads
E[ˆτ
3,ˇG]+i
2{ˆτ3,∂tˇG}+[ˆ/Delta1,ˇG]−i
2{∂tˆ/Delta1,∂ EˇG}
+meff[m·ˆσ,ˇG]−imeff
2{∂tm·ˆσ,∂EˇG}
+iV[ˇN,ˇG]−V
2{∂EˇN,∂tˇG}=0, (12)
where ˇNis the equilibrium Green’s function in the NM
reservoir. Additionally, this coupling gives a dephasing E→
E−iVin the Green’s function in the SC. This relaxation is
therefore a possible source of the dephasing which we havealready introduced in Sec. II B.
D. Parametrization
We now aim to express the generalized Usadel Eq. ( 12)i n
a form that is easier to treat both analytically and numerically.We use a parametrization [ 47] that maps the eight nonzero
components of ˆG
R,ˆGA, and ˆGKonto two scalars (chargesector) and two vectors (spin sector), one of each reflecting
the normal and anomalous parts of the Green’s function. Weexpand the Green’s function as (this applies to the R,A, and
Kcomponents)
ˆG=/summationdisplay
i∈{0,1,2,3}/summationdisplay
j∈{0,x,y,z}Gijτiσj, (13)
where Gij=1
4TrˆGτiσj. We gather the nonzero components
into the following functions:
G0≡G30,
G≡[G0x,G3y,G0z],
F0≡G1y,
F≡[−G2z,G10,G2x].(14)
The scalar G0and the vector Gdescribe the diagonal elements
in particle-hole space of ˆG. The scalar F0and the vector F
characterize the corresponding anomalous off-diagonal ele-ments of ˆG. By inserting the definitions ( 13) and ( 14)i n t o
the effective generalized Usadel Eq. ( 12), we arrive at the
following parametrized differential equations for the normalcomponents:
∂GR/A
0
∂t=meff/parenleftbigg∂GR/A
∂E/parenrightbigg
·/parenleftbigg∂m
∂t/parenrightbigg
−i/parenleftBigg
∂FR/A
0
∂E/parenrightBigg/parenleftbigg∂/Delta1
∂t/parenrightbigg
, (15)
∂GR/A
∂t=2meff(GR/A×m)+meff/parenleftBigg
∂GR/A
0
∂E/parenrightBigg/parenleftbigg∂m
∂t/parenrightbigg
−i/parenleftbigg∂/Delta1
∂t/parenrightbigg/parenleftbigg∂FR/A
∂E/parenrightbigg
, (16)
∂GK
0
∂t=meff/parenleftbigg∂GK
∂E/parenrightbigg
·/parenleftbigg∂m
∂t/parenrightbigg
−i/parenleftbigg∂FK
0
∂E/parenrightbigg/parenleftbigg∂/Delta1
∂t/parenrightbigg
−2V/bracketleftbigg
GK
0−/parenleftbig
GR
0−GA
0/parenrightbig
tanh/parenleftbiggβE
2/parenrightbigg/bracketrightbigg
−iVβ
2/parenleftbigg∂GR
0
∂t+∂GA
0
∂t/parenrightbigg
sech2/parenleftbiggβE
2/parenrightbigg
,
(17)
∂GK
∂t=2meff(GK×m)+meff/parenleftbigg∂GK
0
∂E/parenrightbigg/parenleftbigg∂m
∂t/parenrightbigg
−i/parenleftbigg∂/Delta1
∂t/parenrightbigg/parenleftbigg∂FK
∂E/parenrightbigg
−2V/bracketleftbigg
GK−(GR−GA) tanh/parenleftbiggβE
2/parenrightbigg/bracketrightbigg
−iVβ
2/parenleftbigg∂GR
∂t+∂GA
∂t/parenrightbigg
sech2/parenleftbiggβE
2/parenrightbigg
. (18)
We also obtain additional equations given in Appendix A
for the anomalous components F0andFfor the R,A, and
Kcomponents. These equations ( A1)–(A4) are large and less
transparent algebraic expressions. Lastly, we need the gapequation,
/Delta1=−iN
0λ
4/integraldisplayωD
−ωDdE FK
0, (19)
where ωDis the Debye cutoff energy, N0is the Fermi-level
electron density of states, and λis the BCS electron-phonon
coupling constant. We will hereafter refer to /Delta10as the gap
at zero temperature, and /Delta1as the gap at the temperature and
effective magnetic field that is being considered.
For a self-consistent solution, all of the equations ( 15)–
(18), (A1)–(A4), and ( 19) are needed. If we assume a static
gap, however, only Eqs. ( 15)–(18) are needed to determine the
time evolution of the Green’s functions once we know theirsolution at a given time t.E. Spin currents and effects on FMR
The magnetization dynamics in FMs generates spin cur-
rents into neighboring materials. In the trilayer FMI|SC|FMIunder consideration, these spin currents read
j
s
X,x=−iN0meff
8/integraldisplay∞
−∞dETr{σxτ3[mX·ˆσ◦,ˇG]K}, (20)
js
X,y=−iN0meff
8/integraldisplay∞
−∞dETr{σyτ0[mX·ˆσ◦,ˇG]K}, (21)
js
X,z=−iN0meff
8/integraldisplay∞
−∞dETr{σzτ3[mX·ˆσ◦,ˇG]K}, (22)
where mXis the magnetization at interface X∈{L,R}, and
where positive signs indicate spin-currents going from theFMIs into the SC. After expanding the convolution productsin Eqs. ( 20)–(22) to first order in time and energy gradients,
we find
j
s
X=N0meff
4/integraldisplay∞
−∞dE/bracketleftbigg1
2/parenleftbigg∂GK
0
∂E/parenrightbigg/parenleftbigg∂mX
∂t/parenrightbigg
+(GK×mX)/bracketrightbigg
.
(23)
024524-4SPIN PUMPING BETWEEN NONCOLLINEAR … PHYSICAL REVIEW B 103, 024524 (2021)
The first term in this expression is the so-called spin-
pumping current arising from the imaginary part of themixing conductance. The spin-pumping current equals
j
p=(N0meff/2)∂mX/∂tboth in SCs and NMs. The second
term in Eq. ( 23) is the backflow spin current jbdue to spin-
accumulation in the SC [ 48]. The spin-pumping current is
independent of temperature, relative magnetization angles,and of whether the system is superconducting or not. Thebackflow spin current depends on these system parameters,and it will therefore be our main focus henceforth.
If we assume that the magnetizations of the FMIs are
uniform, the Landau-Lifshitz-Gilbert equation for the left FMIcan be written
∂m
L
∂t=−γ0mL×Beff+α0/parenleftbigg
mL×∂mL
∂t/parenrightbigg
−γ0
Msdjs
L,(24)
where γ0is the gyromagnetic ratio of the ferromagnetic spins,
Beffis the effective field in the FMI, α0is the Gilbert damping
parameter, Msis the saturation magnetization in the FMI, and
dis the thickness of the FMI. If we express js
Lin reactive
and dissipative components, js
L=Cr∂mL
∂t+Cd(mL×∂mL
∂t),
we find the following renormalized properties in the FM:
γ0→γ=γ0
1+Crγ0
Msd, (25)
α0→α=γ
γ0/parenleftbigg
α0+Cdγ0
Msd/parenrightbigg
. (26)
For later convenience, we define the reactive and dissipative
spin currents, js
r≡Cr∂mL
∂tandjs
d≡Cd(mL×∂mL
∂t).
III. RESULTS AND DISCUSSIONS
We will now use the equations of motion of ( 15)–(18),
(A1)–(A4), and the gap Eq. ( 19), to find the spin current
generated by FMR in a FMI|SC|FMI trilayer. We considerhomogeneous magnetizations m
LandmRin the left and right
FMIs, respectively. The angle between the principal axes ofthe magnetizations is θ. The left magnetization is precessing
circularly around its principal axis at a precession angle ϕwith
angular frequency ω. The right magnetization is static. The
system is illustrated in Fig. 1.
We will initially search for an analytical solution by treat-
ing the dynamic magnetization component as a perturbationfrom an equilibrium solution. Due to the complexity of theequations, we first assume that the gap is static. This approxi-mation enables us to solve the problem for arbitrary relaxation
V. Section III A presents this analytical approach. In prin-
ciple, it is also possible to find a self-consistent analyticalsolution. However, the solution becomes extremely complexin the presence of relaxation due to the coupling betweenthe retarded /advanced and Keldysh Green’s functions. Hence,
the full self-consistent problem is better suited for numer-ical treatments. In Sec. III B , we compare the results of a
self-consistent numerical solution to the analytical solution inSec. III A . We additionally outline a self-consistent analytical
solution in Appendix Bin the absence of relaxation. This latter
solution has restricted physical relevance, but is supplied forthe convenience of further work in this framework.A. Analytical solution with static gap approximation
We first separate the magnetization vector minto a
static and a dynamic component, m=m(0)+m(1). The static
component m(0)=m(0)
L+m(0)
Ris the sum of the static magne-
tizations of the left and right FMIs. The dynamic componentm
(1)is the dynamic part of mL. It has magnitude δmand
precesses around the zaxis with angular frequency ω,m(1)=
δm[cos(ωt),sin(ωt),0]. This decomposition of the magne-
tization vectors is illustrated in Fig. 1. We now assume the
following: (i) The dynamic magnetization component is muchsmaller than the gap, m
effδm/lessmuch/Delta1. (ii) The fluctuations in
the gap are much smaller than the dynamic magnetizationamplitude, δ/Delta1/lessmuchm
effδm.
Assumption (i) enables us to expand the Keldysh Green’s
function components in the perturbation δm,
GK
0=GK(0)
0+GK(1)
0+(···),
GK=GK(0)+GK(1)+(···),(27)
where the nth-order terms are assumed to be ∝δmn. We con-
sider the first-order expansion in δmonly, and we choose
therefore to disregard second- and higher-order terms. As-sumption (ii) implies that the generalized Usadel equationsfor the advanced and retarded Green’s functions [Eqs. ( 15)
and ( 16)] decouple from the Keldysh component. In what fol-
lows, we will derive the solution for the Keldysh component.The retarded /advanced Green’s functions can then be found
simply by substituting K→R/Aand by setting V=0i nt h e
Keldysh component solution.
To first order in δm, the effective generalized Usadel equa-
tions for the Keldysh component read
∂G
K(1)
0
∂t=meff/parenleftbigg∂GK(0)
∂E/parenrightbigg
·/parenleftbigg∂m(1)
∂t/parenrightbigg
−2V/bracketleftbigg
GK(1)
0−/parenleftbig
GR(1)
0−GA(1)
0/parenrightbig
tanh/parenleftbiggβE
2/parenrightbigg/bracketrightbigg
,
(28)
∂GK(1)
∂t=2meff(GK(0)×m(1)+GK(1)×m(0))
+meff/parenleftbigg∂GK(0)
0
∂E/parenrightbigg/parenleftbigg∂m(1)
∂t/parenrightbigg
−2V/bracketleftbigg
GK(1)−(GR(1)−GA(1)) tanh/parenleftbiggβE
2/parenrightbigg/bracketrightbigg
.
(29)
We propose the Ansätze
GK(1)
0=GK(1)
0+eiωt+GK(1)
0−e−iωt,
GK(1)=GK(1)
+eiωt+GK(1)
−e−iωt. (30)
After inserting the Ansätze in Eq. ( 30) into Eqs. ( 28) and ( 29),
we note that the differential equations separate into decoupledequations for the +/−components. By solving for G
K(1)
0±and
024524-5SIMENSEN, JOHNSEN, LINDER, AND BRATAAS PHYSICAL REVIEW B 103, 024524 (2021)
GK(1)
±, we obtain
GK(1)
0±=meff±ω
±ω+2V/parenleftbigg∂G(0)
∂E/parenrightbigg
·m(1)
±
+2V
±ω+2V/parenleftbig
GR(1)
0−GA(1)
0/parenrightbig
tanh/parenleftbiggβE
2/parenrightbigg
, (31)
GK(1)
±=meffA−1
±ωB±ωm(1)
±
+2VA−1
±ω(GR(1)−GA(1)) tanh/parenleftbiggβE
2/parenrightbigg
, (32)
where the matrices A±ωandB±ωare defined as
A±ω=⎛
⎜⎝±iω+2V−2meffm(0)
z 2meffm(0)
y
2meffm(0)
z ±iω+2V−2meffm(0)
x
−2meffm(0)
y 2meffm(0)
x ±iω+2V⎞
⎟⎠,(33)
B±ω=⎛
⎜⎝±iωC(E)−2GK(0)
z 2GK(0)
y
2GK(0)
z ±iωC(E)−2GK(0)
x
−2G(0)
y 2GK(0)
x ±iωC(E)⎞
⎟⎠, (34)
and where
C(E)=tanh/parenleftbiggβE
2/parenrightbigg/parenleftbigg∂GR(0)
0
∂E−∂GA(0)
0
∂E/parenrightbigg
+/parenleftbigg/bracketleftbig
GR(0)
0−GA(0)
0/bracketrightbig
−iV/bracketleftbigg∂GR(0)
0
∂E+∂GA(0)
0
∂E/bracketrightbigg/parenrightbigg
×β
2sech2/parenleftbiggβE
2/parenrightbigg
. (35)
The solution to GK(1)is particularly simple when θ=0o r
θ=π.F o rθ=0, we obtain
GK(1)
θ=0=meff/parenleftbig
2GK(0)
z+ωC(E)/parenrightbig(4meff+ω)m(1)+2V
ω∂m(1)
∂t
(2V)2+(4meff+ω)2
+2V2m(1)−V
ω(4meff+ω)∂m(1)
∂t
(2V)2+(4meff+ω)2GK(0)
z, (36)
where we have inserted m(0)
z=2. We observe that a finite V
introduces a component of GKparallel to ∂mL/∂t. When we
insert this component into the spin current in Eq. ( 23), we
see that it generates both a reactive and a dissipative backflowcurrent, j
b
randjb
d. Hence, even though the spin pumping
current is purely reactive, the backflow spin current can indeedcarry a dissipative part due to relaxation in the SC. Moreover,we note that the effective magnetic field 2 m
effsuppresses the
amplitude of GK(1). This feature is due to Hanle precession of
GK(1)around the effective magnetic field, which reduces the
effect of the excitation.
When θ=π, the Hanle precession is more or less absent
due to a very small effective magnetic field ∝meffsinϕ. Under
the assumption that the precession angle is sufficiently small,sinϕ/lessmuchω/m
eff, we obtain
GK(1)
θ=π=meffωC(E)ωm(1)+2V
ω∂m(1)
∂t
(2V)2+ω2. (37)
As a control check, we can verify that we obtain the instanta-
neous equilibrium solution ( GR(1)−GA(1)) tanh( βE/2) when
V/greatermuchω.In the second line of C(E)i nE q .( 35), we have iso-
lated the source of nonequilibrium behavior of GK.T h i s
nonequilibrium part arises from the energy gradient ofthe distribution function, and is therefore proportional tosech
2(βE
2). In the normal metal limit, we have ∂GR
0/∂E=0,
and/integraltext∞
−∞dE C (E)=4 is therefore constant and independent
of temperature. The spin current is therefore independent oftemperature in the NM limit.
The coefficient C(E)i nE q .( 35) predicts that the nonequi-
librium effects mostly arise within a thermal energy interval±β
−1from the Fermi level. There are two tunable parame-
ters that affect the number of quasiparticle states within thisenergy interval in a SC: First, at higher temperatures, the en-ergy interval in which quasiparticles can be excited broadens.The more overlap there is between this energy window andthe gap edge, the larger we expect the spin accumulation tobe. Another thermal effect is that the gap /Delta1decreases with
increasing temperature, which enhances the above-mentionedeffect. Second, the effective magnetic field introduces a spin-split density of states, which pushes half of the quasiparticlestates closer to the Fermi level. An additional effect is that thegap decreases with an increasing effective magnetic field, aneffect that moreover is temperature-dependent. Therefore, theeffective magnetic field also affects the number of quasipar-ticle states within a thermal energy interval from the Fermilevel. Both the temperature and effective magnetic field canhence be tuned to increase the spin accumulation. The spinaccumulation in turn generates a backflow spin current intothe FMIs. We therefore expect a larger backflow spin currentfrom a SC at higher temperatures and for stronger effectivemagnetic fields.
We will now evaluate the angular and temperature de-
pendence of the backflow spin current for a particular
FMI|SC|FMI trilayer. We choose the parameters in the
SC so that they match those of Nb. That is, we choose1/V=τ
sf/2π∼10−10s[49] and a critical temperature
Tc=9.26 K [ 50]. Moreover, we use an effective magnetic
field strength meff=0.1/Delta10, and a magnetization precession
angleϕ=arcsin(0 .01). Last, we use a precession frequency
ω=0.005/Delta10≈10 GHz, which is an appropriate frequency
for, e.g., yttrium iron garnet (YIG). The relaxation introduces
a dephasing V=0.05/Delta10, which is sufficient to justify the
gradient expansion. The gap /Delta1=/Delta1(T,θ,meff) is found by
solving the gap equation self-consistently [ 51] to zeroth order
in the dynamic magnetization, as well as checking that the freeenergy of the superconducting state is lower than in the normalmetal state. The assumptions (i) and (ii) underlying the staticgap approximation can be satisfied for any effective field m
eff
providing we choose an appropriate precession amplitude, δm,
which can be tuned with the ac magnetic field used to exciteFMR in the FMI.
In the FMI|SC|FMI trilayer, the expression for the backflow
spin current in Eq. ( 23) implies that there is a static RKKY
contribution to the spin current. This RKKY contribution isdue to the finite G
Kclose to the Fermi level. However, other
terms also contribute to the RKKY interaction beyond thequasiclassical theory. Therefore, we subtract the instantaneousRKKY-like static contribution to the spin current.
Figure 2plots the backflow spin current as a function of θ
for two different temperatures, T=0.1T
candT=0.9Tc.T h e
024524-6SPIN PUMPING BETWEEN NONCOLLINEAR … PHYSICAL REVIEW B 103, 024524 (2021)
FIG. 2. The reactive (red) and dissipative (blue) backflow spin
current, normalized to the density of states N0, as a function of θ
through the left interface of a FMI|SC|FMI trilayer for two different
temperatures, T=0.1Tc(upper plot) and T=0.9Tc(lower plot). We
have used the parameters given in the main text, with meff=0.1/Delta10.
In the lower plot, we have also plotted the spin current through an
analogous FMI|NM|FMI trilayer (dotted lines).
spin-pumping currents in both cases are purely reactive and
equal to jp/N0=10−5J2/m. The first striking observation
is that the spin current is much lower in the SC system atT=0.1T
cthan at T=0.9Tc. Singlet pair formation hinders
injection of spin currents into the superconductor. Next, weobserve that the total spin current grows as θapproaches π,
which is the case for both the SC and NM systems, and at bothtemperatures. This is due to the decreased impact of Hanleprecession on the spin accumulation as the effective magneticfield decreases. Moreover, we note that the reactive spin cur-rent is favored close to θ=0, whereas the dissipative spin
current is favored close to θ=π. This is because the Hanle
precession affects the reactive and dissipative spin currentdifferently. Inspecting Eq. ( 36), we see that the reactive and
dissipative spin current are suppressed by a factor ∝(m
eff)−1
and∝(meff)−2close to θ=0, respectively. For large effective
magnetic fields, that is, close to θ=0, the dissipative spin
current is therefore strongly suppressed compared to the re-active spin current. Close to θ=π, where Hanle precession
is negligible, the reactive and dissipative spin currents aresuppressed ∝V
−2and∝V−1, respectively, as can be seen inFIG. 3. (a) The temperature dependence of the total spin current
in the superconducting system for two relative magnetization angles,θ=0a n dθ=π. The spin current is normalized to the normal metal
limit, where the spin current is independent of temperature. (b) The
ratio j
s,θ=0
d/js,θ=π
d plotted as a function of temperature for both the
SC and NM systems. We have used the parameters given in the
main text. The lowest temperature included is T=0.03Tcin order
to ensure that the gradient expansion is justified.
Eq. ( 37). Hence, the dissipative spin current dominates close
toθ=π.
Let us now explore the temperature dependence in detail.
In Fig. 3(a) we plot the total spin current as a function of
temperature for two angles, θ=0 and θ=π, and for dif-
ferent effective field strengths meff. We have normalized the
spin currents with the respect to the analogous NM limitspin currents. The latter are independent of temperature. Dueto the gradient expansion, the parameters must satisfy thecondition β
−1/greatermuchω/√
8≈0.003kBTc. We therefore restrict
the temperature analysis to T/greaterorequalslant0.03Tc. First, we observe
that the spin currents approach the NM limit at the criticalfields for the respective effective magnetic fields. We havealready discussed this behavior, which is due to the amount ofquasiparticle states within a thermal energy interval from theFermi energy. This entails an overall decrease in the total spincurrent for the θ=0 configuration, and an increase for the
θ=πconfiguration. This is due to the nature of the backflow
spin current. In the θ=0 configuration, the backflow spin
current is dominated by a reactive component that counteractsthe spin-pumping current. In the θ=πconfiguration, the
backflow spin current is dominated by a dissipative compo-nent. This spin current is oriented almost 90
◦relative to the
spin-pumping current, and therefore increases the total spincurrent.
024524-7SIMENSEN, JOHNSEN, LINDER, AND BRATAAS PHYSICAL REVIEW B 103, 024524 (2021)
Next, Fig. 3(a) demonstrates that the temperature depen-
dence of the normalized spin current for the θ=0 andθ=π
states differ. To investigate this further, we plot the ratiobetween the dissipative spin currents in the parallel and an-tiparallel configurations, j
s,θ=0
d/js,θ=π
d, both in the NM and
SC state, in Fig. 3(b). Here, we observe that this ratio is a
constant function of temperature in the NM limit, whereas itdepends strongly on temperature in the superconducting state.The ratio peaks at slightly different temperatures for differenteffective fields m
effin the superconducting state. The height
of the peak increases with an increasing effective field meff.
As the temperature approaches Tc, the ratio in the SC state
converges toward the NM limit result.
This behavior is due to the aforementioned effect of
temperature and effective magnetic field. In the parallel con-figuration, the effective magnetic fields of the two FMIs addconstructively and cause a strong spin-splitting in the densityof states. In the antiparallel configuration, the effective fieldsadd destructively and cause only a weakly spin-split densityof states. At very low temperatures, the difference betweenthe parallel and antiparallel configurations is small for thechosen values of m
eff. This is because neither state has a large
density of states close to the almost δ-function-like thermal
energy interval around the Fermi level. At slightly higher tem-peratures, the states that are pushed closer to the Fermi levelstart overlapping with the thermal energy interval E
F±β−1.
The difference between the two states is maximized for someintermediate temperature, k
BT/lessorapproxeql/Delta1(T), where we observe the
peaks in Fig. 3(b). At even higher temperatures, the thermal
energy interval broadens further. The difference between theparallel and antiparallel states then starts decreasing for highertemperatures, and eventually approaches the NM limit.
B. Numerical analysis
We aim here to briefly present a numerical solution to the
problem that was solved analytically in Sec. III A .O u rm a i n
goal is to evaluate whether the assumption of a static gap canbe justified to a good approximation. A subsidiary goal is toshow the time evolution of the gap, and the usefulness of anumerical method in this framework also when the static gapapproximation is not valid.
We see from Eqs. ( 16) and ( 18) that the vectors G
A,GR,
andGKprecess around the effective magnetic field. For such
a class of equations, employing a fourth-order Runge-Kuttamethod is suitable for obtaining a numerical solution. Totest the validity of the static gap approximation, we want toperform a simulation of the system where the oscillationsin the gap are maximized. This is expected to occur wherethe magnitude of the effective field oscillates with the largestamplitude. From Eq. ( B9) one can show that this occurs at
θ=π/2 in the absence of relaxation, and we hence expect it
to occur at θ=π/2 also with the inclusion of relaxation.
Figure 4(a) forθ=π/2 shows the fluctuation of the gap
δ/Delta1(t) normalized to /Delta1
0over one period 2 π/ω and for sev-
eral temperatures T, with meff=0.1/Delta10. The gap oscillates
harmonically with frequency ωfor all temperatures up to
T=0.85Tc. At temperatures close to the critical temperature
for the given effective magnetic field, the gap shows a non-linear response to the dynamical magnetization. This effectFIG. 4. (a) The fluctuations of the gap δ/Delta1(t) plotted over one
period 2 π/ω at different temperatures for θ=π/2. (b) The detailed
temperature dependence of the gap fluctuation amplitude max |δ/Delta1|
for different magnetization angles θ. The gap fluctuations are nor-
malized to the gap at zero temperature, /Delta10, and we have used
meff=0.1/Delta10.
is visible for T=0.95Tc, and is due to the increased sensi-
tivity to fluctuations in the magnetic field as the temperatureapproaches the critical temperature. In Fig. 4(b), we further
explore θand the temperature dependence of the gap fluc-
tuation amplitude, max |δ/Delta1|, in the linear response regime.
We observe that the fluctuations are largest at θ=π/2,
and that they are maximized at about T≈0.8T
c. Moreover,
we observe that the fluctuations are not larger than about5.5×10
−5/Delta10. Let us now briefly remind the reader that
the formal requirement for the static gap approximation wasδ/Delta1/lessmuchm
effδm, where δmis the dynamic magnetization am-
plitude. We have meffδm≈0.001/Delta10/greatermuchδ/Delta1/lessorequalslant5.5×10−5/Delta10,
which implies that the static gap assumption is an excellentapproximation in this instance.
IV . CONCLUSION
We have derived an effective, time-dependent generalized
Usadel equation in noncollinear FMI|SC|FMI trilayers witha thin superconducting layer and weakly magnetized FMIs.We have provided analytical solutions to these equations interms of perturbations in the dynamic magnetization, firstunder the assumption of a static gap, and then a self-consistentsolution in the absence of relaxation. Lastly, we have provided
024524-8SPIN PUMPING BETWEEN NONCOLLINEAR … PHYSICAL REVIEW B 103, 024524 (2021)
numerical procedures to obtain self-consistent solutions of the
full equations without any further simplifications.
From the solutions to the generalized Usadel equation, we
computed the spin currents generated by ferromagnetic reso-nance in one of the FMIs. We have explored this spin currentas a function of both temperature and relative magnetizationangle between the FMIs. The spin current has been decom-posed into a reactive and a dissipative part, which changethe effective gyromagnetic ratio and Gilbert damping coef-ficient of the FMI. We found that the backflow spin currentis generally largest when the magnetization orientations ofthe FMIs are antiparallel. The ratio between the spin currentin the parallel and antiparallel configuration strongly dependson temperature in the SC. The origin is the Zeeman splitting
of the quasiparticles at the gap edge. Lastly, we performed anumerical simulation to verify that the static gap assumptionis a good approximation in our regime, also showing theusefulness of a numerical solution in this framework.
ACKNOWLEDGMENTS
This work was supported by the Research Council of
Norway through its Centres of Excellence funding scheme,Project No. 262633 “QuSpin,” as well as by the EuropeanResearch Council via Advanced Grant No. 669442 “Insula-tronics.”
APPENDIX A: ADDITIONAL PARAMETRIZED USADEL EQUATIONS
In the main text, we provided four of the generalized Usadel equations, Eqs. ( 15)–(18), that were equations of motion for
the normal components of the Green’s functions. The remaining four equations that are needed to solve a system with nonzeroanomalous Green’s functions self-consistently are given as follows:
FR/A
0=i/parenleftBig
/Delta1/parenleftbig
meffm·GR/A−(E−iV)GR/A
0/parenrightbig
−im2
eff
2m·/parenleftbig∂m
∂t×∂FR/A
∂E/parenrightbig/parenrightBig
m2
effm2−(E−iV)2, (A1)
FR/A=i/Delta1GR/A
(E−iV)
−i/parenleftbig
meff/Delta1/parenleftbig
meffm·GR/A−(E−iV)GR/A
0/parenrightbig
m−im3
eff
2/bracketleftbig
m·/parenleftbig∂m
∂t×∂FR/A
∂E/parenrightbig/bracketrightbig
m+imeff
2/bracketleftbig
m2
effm2−(E−iV)2/bracketrightbig/parenleftbig∂m
∂t×∂FR/A
∂E/parenrightbig/parenrightbig
(E−iV)/bracketleftbig
m2
effm2−(E−iV)2/bracketrightbig ,
(A2)
FK
0=i/parenleftbig
/Delta1/parenleftbig
meffm·GK−EGK
0/parenrightbig
−im2
eff
2m·/parenleftbig∂m
∂t×∂FK
∂E/parenrightbig/parenrightbig
m2
effm2−E2−iVtanh/parenleftbigβE
2/parenrightbig/bracketleftbig
m·(FR+FA)−E/parenleftbig
FR
0+FA
0/parenrightbig/bracketrightbig
/parenleftbig
m2
effm2−E2/parenrightbig
−βVsech2/parenleftbigβE
2/parenrightbig/bracketleftbig
m·/parenleftbig∂FR
∂t−∂FA
∂t/parenrightbig
−E/parenleftbig∂FR
0
∂t−∂FA
0
∂t/parenrightbig/bracketrightbig
4/parenleftbig
m2
effm2−E2/parenrightbig , (A3)
FK=i/Delta1GK
E−i/parenleftbig
meff/Delta1/parenleftbig
meffm·GK−EGK
0/parenrightbig
m−im3
eff
2/bracketleftbig
m·/parenleftbig∂m
∂t×∂FK
∂E/parenrightbig/bracketrightbig
m+imeff
2(m2
effm2−E2)/parenleftbig∂m
∂t×∂FK
∂E/parenrightbig/parenrightbig
E/parenleftbig
m2
effm2−E2/parenrightbig
+iVtanh/parenleftbigβE
2/parenrightbig/bracketleftbig/braceleftbig
m·(FR+FA)−E/parenleftbig
FR
0+FA
0/parenrightbig/bracerightbig
m−(m2−E2)(FR+FA/parenrightbig/bracketrightbig
E/parenleftbig
m2
effm2−E2/parenrightbig
+βVsech2/parenleftbigβE
2/parenrightbig/bracketleftbig/braceleftbig
m·(∂FR
∂t−∂FA
∂t)−E/parenleftbig∂FR
0
∂t−∂FA
0
∂t/parenrightbig/bracerightbig
m−(m2−E2)/parenleftbig∂FR
∂t−∂FA
∂t/parenrightbig/bracketrightbig
4E/parenleftbig
m2
effm2−E2/parenrightbig , (A4)
where the notation is defined in the main text.
APPENDIX B: SELF-CONSISTENT SOLUTION IN THE ABSENCE OF SPIN RELAXATION
We will derive here a self-consistent solution to the generalized Usadel equations, Eqs. ( 15)–(18), Eqs. ( A1)–(A4), and the
gap Eq. ( 19), in the absence of spin relaxation ( V=0). This solution has restricted physical relevance, and it only applies in the
limit where the precession frequency is much larger than the relaxation rate. However, it is included as a proof of concept that aself-consistent solution is in principle possible.
The derivation follows the lines of what was presented in Sec. III A , with a few exceptions. In addition to the perturbation
expansion in Eqs. ( 27), we also expand
F
0=F(0)
0+F(1)
0+F(2)
0+(···),
F=F(0)+F(1)+F(2)+(···),
/Delta1=/Delta1(0)+/Delta1(1)+/Delta1(2)+(···).(B1)
024524-9SIMENSEN, JOHNSEN, LINDER, AND BRATAAS PHYSICAL REVIEW B 103, 024524 (2021)
We have dropped the retarded /advanced and Keldysh superscript in order to keep the derivation as general as possible. This
derivation hence applies to all Green’s-function components. We also propose one additional Ansatz ,
/Delta1(1)=/Delta1(1)
+eiωt+/Delta1(1)
−e−iωt. (B2)
If we insert this into the generalized Usadel equations to first order in δm, and with V=0, we obtain the solutions
G(1)
0±=meff/parenleftbigg∂G(0)
∂E/parenrightbigg
·m(1)
±−i/parenleftbigg∂F(0)
0
∂E/parenrightbigg
/Delta1(1)
±, (B3)
G(1)
±=meff˜A−1
±ω˜B±ωm(1)
±±ω/Delta1(1)
±˜A−1
±ω∂F(0)
∂E, (B4)
where
˜A±ω=⎛
⎝±iω 2meff−m(0)
z 2meffm(0)
y
2meffm(0)
z ±iω −2meffm(0)
x
−2meffm(0)
y 2meffm(0)
x ±iω⎞
⎠ (B5)
and
˜B±ω=⎛
⎜⎜⎝±iω∂G(0)
0
∂E−2G(0)
z 2G(0)
y
2G(0)
z ±iω∂G(0)
0
∂E−2G(0)
x
−2G(0)
y 2G(0)
x ±iω∂G(0)
0
∂E⎞
⎟⎟⎠. (B6)
To solve for /Delta1(1)(t), we look closer at the gap equation given in Eq. ( 19). If we insert the generalized Usadel equation for
FK
0[Eq. ( A3)] into the gap equation while using V=0, divide both sides by /Delta1, and assume that |meffm(1)|/lessmuchδ, the first- and
second-order gap equations read
1=N0λ
4/integraldisplayωD
−ωDdE/parenleftbig
meffm(0)·GK(0)−EGK(0)
0/parenrightbig
m2
eff(m(0))2−E2, (B7)
0=/integraldisplayωD
−ωDdE1
m2
eff(m(0))2−E2/braceleftBigg
meff(m(1)·GK(0)+m(0)·GK(1))−EGK(1)
0−2m2
eff(m(0)·m(1))/parenleftbig
meffm(0)·GK(0)−EGK(0)
0/parenrightbig
m2
eff(m(0))2−E2/bracerightBigg
.
(B8)
Here, we used m(0)·(∂m(1)
∂t×∂FK(0)
∂E)=0, since FK(0)/bardblm(0). We have moreover used E→E+iδand
meff|m(0)·m(1)|/lessmuch|m(0)|δ, ensuring that the expansion is also valid when Re {E}→ meff|m(0)|.E q .( B7)i ss i m p l yt h e
zeroth-order gap equation, while Eq. ( B8) must be used to find self-consistent solution to the first-order Green’s-function
components. All that remains now is to insert the Ansätze Eqs. ( 30) and ( B2) into Eq. ( B8). The resulting solution for the
first-order components /Delta1(1)
±reads
/Delta1(1)
±=1
T±/integraldisplayωD
−ωDdEmeff
m2
eff(m(0))2−E2/braceleftBigg
/parenleftbig
m(1)
±·GK(0)/parenrightbig
+meff/parenleftbig/bracketleftbig
A−1
±ωB±ωm(1)
±/bracketrightbig
·m(0)/parenrightbig
−E/parenleftbigg
m(1)
±·∂GK(0)
∂E/parenrightbigg
−2meff(m(1)
±·m(0))/parenleftbig
meffm(0)·GK(0)−EGK(0)
0/parenrightbig
m2
eff(m(0))2−E2/bracerightBigg
, (B9)
where T±is defined by
T±=−/integraldisplayωD
−ωDdE±ωmeff/bracketleftbig
A−1
±ω∂FK(0)
∂E/bracketrightbig
·m(0)+iE∂FK(0)
0
∂E
m2
eff(m(0))2−E2. (B10)
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024524-12 |
PhysRevB.95.140404.pdf | RAPID COMMUNICATIONS
PHYSICAL REVIEW B 95, 140404(R) (2017)
Self-focusing skyrmion racetracks in ferrimagnets
Se Kwon Kim,1Kyung-Jin Lee,2,3and Yaroslav Tserkovnyak1
1Department of Physics and Astronomy, University of California, Los Angeles, California 90095, USA
2Department of Materials Science and Engineering, Korea University, Seoul 02841, South Korea
3KU-KIST Graduate School of Converging Science and Technology, Korea University, Seoul 02841, South Korea
(Received 10 February 2017; published 14 April 2017)
We theoretically study the dynamics of ferrimagnetic skyrmions in inhomogeneous metallic films close to the
angular momentum compensation point. In particular, it is shown that the line of the vanishing angular momentumcan be utilized as a self-focusing racetrack for skyrmions. To that end, we begin by deriving the equations ofmotion for the dynamics of collinear ferrimagnets in the presence of a charge current. The obtained equations ofmotion reduce to those of ferromagnets and antiferromagnets at two special limits. In the collective coordinateapproach, a skyrmion behaves as a massive charged particle moving in a viscous medium subjected to a magneticfield. Analogous to the snake orbits of electrons in a nonuniform magnetic field, we show that a ferrimagnet withnonuniform angular momentum density can exhibit the snake trajectories of skyrmions, which can be utilized asracetracks for skyrmions.
DOI: 10.1103/PhysRevB.95.140404
Introduction. A free particle with a magnetic moment
precesses at a frequency proportional to the applied magneticfield and its gyromagnetic ratio, which is the ratio of itsmagnetic moment to its angular momentum. When a magnetis composed of equivalent atoms, its net magnetizationand net angular momentum density are collinear with theproportionality given by the gyromagnetic ratio of constituentatoms. The magnetic and spin variables then represent the samedegrees of freedom, and thus are interchangeable in describingthe magnetization dynamics. One-sublattice ferromagnets andtwo-sublattice antiferromagnets are examples of such magnets.
When a magnet consists of inequivalent atoms, however,
its magnetization and spin density can constitute independentdegrees of freedom [ 1]. One such class of magnets is rare-earth
transition-metal (RE-TM) ferrimagnetic alloys [ 2], in which
the moments of TM elements and RE elements tend to beantiparallel due to superexchange. Because of the differentgyromagnetic ratios between RE and TM elements, one canreach the angular momentum compensation point and themagnetization compensation point by varying the relativeconcentrations of the two species or changing the temperature.These compensation points (CPs) are absent in ferromagnetsand antiferromagnets, which have been mainstream materialsin spintronics [ 3], and thereby have been bringing a novel
phenomenon to the field such as the ultrafast optical magne-tization reversal [ 2]. In particular, the angular momentum CP
may provide a tunable crossover between the ferromagnetic(away from the CP) [ 4] and antiferromagnetic (at the CP) [ 2,5]
regimes of collective dynamics, with a promise for unusualbehavior in the vicinity of the CP. Here, we are exploring thisquestion in regard to the topological spin-texture dynamics.
Topological solitons in magnets [ 6] have been serving as
active units in spintronics. For example, a domain wall, whichis a topological soliton in quasi-one-dimensional magnetswith easy-axis anisotropy, can function as a memory unit, asdemonstrated in magnetic domain-wall racetrack memory [ 7].
Two-dimensional magnets with certain spin-orbit coupling canalso stabilize another particlelike topological soliton, whichis referred to as a skyrmion. Skyrmions have been gainingattention in spintronics as information carriers, an alternative todomain walls, because of fundamental interest as well as their
practical advantages such as a low depinning electric current[8]. Several RE-TM thin films such as GdFeCo and CoTb have
been reported to possess perpendicular magnetic anisotropyand a bulk Dzyaloshinskii-Moriya interaction [ 9,10], and thus
are expected to be able to host skyrmions under appropriateconditions.
In this Rapid Communication, we study the dynamics of
skyrmions in metallic collinear ferrimagnets, in the vicinity ofthe angular momentum CP in RE-TM alloys. To that end,we first derive the equations of motion for the dynamicsof general collinear magnets in the presence of an electriccurrent. The resultant equations of motion reduce to those offerromagnets and antiferromagnets at two limiting cases. Thedynamics of a skyrmion is then derived within the collectivecoordinate approach [ 11]. Generally, it behaves as a massive
charged particle in a magnetic field moving in a viscousmedium. When there is a line in the sample across whichthe net angular momentum density reverses its direction, theemergent magnetic field acting on skyrmions also changes itssign across it. Motivated by the existence of a narrow channelin two-dimensional electron gas localized on the line acrosswhich the perpendicular magnetic field changes its direction[12], we show that, under suitable conditions, the line of the
vanishing angular momentum in RE-TM alloys can serve asa self-focusing racetrack for skyrmions [ 13]a sar e s u l to ft h e
combined effects of the effective Lorentz force and the viscousforce. We envision that ferrimagnets with a tunable spin densitycan serve as a natural platform to engineer an inhomogeneousemergent magnetic field for skyrmions, which would provideus a useful knob to control them.
Main results. The system of interest to us is a two-
dimensional collinear ferrimagnet. Although the angular mo-mentum can be rooted in either the spin or the orbital degrees offreedom, we will use the term, spin, as a synonym for angularmomentum throughout for the sake of brevity. For temper-atures much below than the magnetic ordering temperature,T/lessmuchT
c, the low-energy dynamics of the collinear ferrimagnet
can be described by the dynamics of a single three-dimensionalunit vector n, which determines the collinear structure of
2469-9950/2017/95(14)/140404(5) 140404-1 ©2017 American Physical SocietyRAPID COMMUNICATIONS
SE KWON KIM, KYUNG-JIN LEE, AND YAROSLA V TSERKOVNYAK PHYSICAL REVIEW B 95, 140404(R) (2017)
the magnet [ 4]. Our first main result, which will be derived
later within the Lagrangian formalism taken by Andreev andMarchenko [ 4] for the magnetic dynamics in conjunction with
the phenomenological treatment of the charge-induced torques[14], is the equations of motion for the dynamics of nin the
presence of a charge current density Jand an external field h
to the linear order in the out-of-equilibrium deviations ˙n,J,
andh,
s˙n+s
αn×˙n+ρnרn
=n×fn+ξ(J·∇)n+ζn×(J·∇)n, (1)
where sis the net spin density along the direction of n,sα
andρparametrize the dissipation power density P=sα˙n2
and the inertia associated with the dynamics of n, respectively,
andfn≡−δU/δ nis the effective field conjugate to nwith
U[n] the potential energy [ 15]. Here, ξandζare the
phenomenological parameters for the reactive and dissipativetorques due to the current, respectively.
When the inertia vanishes, ρ=0, the obtained equations of
motion are reduced to the Landau-Lifshitz-Gilbert equation forferromagnets augmented by the spin-transfer torques [ 16,17],
in which s
α/sandξcan be identified as the Gilbert damping
constant and the spin polarization of conducting electrons,respectively. When the net spin density vanishes, s=0, it
corresponds to the equations of motion for antiferromagnets[14]. The equations of motion for the dynamics of a two-
sublattice ferrimagnet in the absence of an electric current anddissipation, s
α=0 and J=0, have been obtained by lvanov
and Sukstanskii [ 18].
The low-energy dynamics of rigid magnetic solitons in
two-dimensional collinear magnets can be derived from Eq. ( 1)
within the collective coordinate approach [ 11], where the dy-
namics of the order parameter is encoded in the time evolutionof the soliton position, n(r,t)=n
0[r−R(t)]. The resultant
equations of motion for the position of a circularly symmetricsoliton, which are obtained by integrating Eq. ( 1) multiplied
byn
0×∂Rn0over the space, are our second main result,
M¨R=Q˙R×B−D˙R+FU+FJ, (2)
where M≡ρ/integraltext
dxdy (∂xn0)2is the soliton mass [ 19],D≡
sα/integraltext
dxdy (∂xn0)2is the viscous coefficient, FU≡−dU/d R
is the internal force, and ( FJ)i≡/integraltext
dxdy [ξn0·(J·∇)n0×
∂in0−ζ∂in0·(J·∇)n0] is the force due to the charge current.
The first term on the right-hand side is the effective Lorentzforce on the soliton, which is proportional to its topologicalcharge
Q=1
4π/integraldisplay
dxdy n0·(∂xn0×∂yn0), (3)
which measures how many times the unit vector n0(r) wraps
the unit sphere as rspatially varies [ 20], and the fictitious
magnetic field
B≡Bˆz=−4πsˆz. (4)
According to the equations of motion, a skyrmion in chiral
ferrimagnets, which is characterized by its topological chargeQ=±1, behaves as a massive charged particle in a magnetic
field moving in a viscous medium. The fictitious magnetic fieldis proportional to the net spin density salong the direction of(a)
(b)
xy
zxy
z
s>0s<0
Q=−1 Q=1F
Q=−1 Q=1F
FIG. 1. Schematic illustrations of a steady-state skyrmion motion
[Eq. ( 5)] in the presence of a current-induced force F=Fˆx. Four
possible types are classified by its skyrmion charge Qand the sign of
the net spin density s. See the main text for discussions.
the order parameter n, which leads us to consider collinear
magnets with tunable sto look for a possibly interesting
dynamics of a skyrmion. The RE-TM ferrimagnetic alloys [ 2]
are such materials. For example, Co 1−xTbxhas been shown to
exhibit the vanishing angular momentum s≈0a tx≈17% at
room temperature [ 10] by varying the chemical composition.
As another example, the angular momentum compensationtemperature of Gd
22%Fe75%Co3%has been reported as T≈
220 K [ 21].
A skyrmion can be driven by an electric current, as can be
seen in Eq. ( 2). In the presence of the corresponding current-
induced force FJ≡Fˆx, the direction of which is defined as
thexaxis, the steady state of a skyrmion is given by
˙R→V=F
B2+D2(Dˆx−QBˆy). (5)
See Fig. 1for illustrations of a steady-state skyrmion motion
forF> 0. The skyrmion with a topological charge Q=1
moves down for s<0 and up for s>0, while moving to
the right regardless of the sign of s. If the ferrimagnet is
prepared in such a way that s<0f o r y>0 and s>0
fory<0, the skyrmion with Q=1 will move along the
horizontal line y=0 after a certain relaxation time because it
is constantly pushed back to the line via the effective Lorentzforce. Note that the skyrmion experiences no Lorentz forceon the angular momentum compensation line, and thus willmove as an antiferromagnetic skyrmion strictly along the lineat a potentially higher speed compared to a ferromagneticskyrmion [ 22]. A similar phenomenon has been predicted for
a magnetic vortex moving around the interface between twoferromagnetic materials having opposite signs of the differencebetween the Gilbert damping constant αand the nonadiabatic
spin-transfer torque coefficient η[23].
To corroborate the qualitative prediction, we numerically
solve the equations of motion [Eq. ( 2)] in their dimensionless
form,
Id
2˜R
d˜t2+4πsQ
sαd˜R
d˜t׈z+Id˜R
d˜t=˜Fˆx, (6)
in which time, length, and energy are measured in units of the
relaxation time τ≡ρ/sα, the characteristic length scale for
the skyrmion size l[24], and /epsilon1≡s2
αl2/ρ, respectively, where
I=/integraltext
dxdy (∂xn0)2is a dimensionless number determined
by the skyrmion structure. The symbols with the tilde willdenote the dimensionless quantities throughout. Figure 2(a)
shows the two trajectories of skyrmions of charge Q=1
140404-2RAPID COMMUNICATIONS
SELF-FOCUSING SKYRMION RACETRACKS IN FERRIMAGNETS PHYSICAL REVIEW B 95, 140404(R) (2017)
05
−5(a)
(b)˜y024
˜y
0
0.1−0.1s/sα
0
0.1−0.1s/sα
0˜x20 40 60 800˜x20 40 60 800˜Vx8
10 20˜t
−2
−4˜Y(0) = 2
˜Y(0) =−3
FIG. 2. Trajectories of skyrmions with the topological charge
Q=1 in the presence of a current-induced force F=Fˆx,w h i c h
are obtained by numerically solving the dimensionless equations of
motion for the dynamics of skyrmions in Eq. ( 6). (a) Two trajectories
for the monotonic net angular momentum density s. The inset shows
the convergence of the skyrmion velocities. (b) Multiple trajectories
for the periodic net angular momentum density s. See the main text
for detailed discussions.
departing from ( ˜X,˜Y)=(0,2) and ( ˜X,˜Y)=(0,−3) with a
zero initial velocity under the following configurations: I=
π/2,˜F=4π, ands/sα=−0.1 tanh( ˜y). We refer to the paths
as skyrmion snake trajectories due to their shapes, analogousto the electronic snake orbits in an inhomogeneous magneticfield [ 12]. The inset shows that the skyrmion speed converges
as˜V
x→˜F/I after a sufficiently long time, ˜t/greatermuch1. Figure 2(b)
depicts the multiple trajectories of skyrmions when the netspin density is spatially periodic, s/s
α=−0.1s i n ( 2 π˜y/5).
Skyrmions are attracted to angular momentum compensationlines and their velocities converge to a finite value. This leadsus to state our third main result: Self-focusing narrow guidesfor skyrmions can be realized in certain ferrimagnets such asthe RE-TM alloys along the lines of the angular momentumcompensation points, which can be useful in using skyrmionsfor information processing by, e.g., providing multiple parallelskyrmion racetracks in one sample [ 25].
The dynamics of collinear magnets. The derivation of the
equations of motion for the dynamics of collinear magnetsin [Eq. ( 1)] is given below, which follows the phenomeno-
logical approach taken for antiferromagnets by Andreev andMarchenko [ 4]. Within the exchange approximation that
the Lagrangian is assumed invariant under the global spinrotations, we can write the Lagrangian density for the dynamicsof the directional order parameter nin the absence of an
external field as
L=−sa[n]·˙n+ρ˙n
2
2−U[n], (7)
to the quadratic order in the time derivative, where a[n]i st h e
vector potential for the magnetic monopole, ∇n×a=n[26].The first term accounts for the spin Berry phase associated
with the net spin density along n; the second term accounts for
the inertia for the dynamics of n, which can arise due to, e.g.,
the relative canting of sublattice spins [ 15].
Next, the effects of an external field can be taken into
account as follows. The conserved Noether charge associatedwith the symmetry of the Lagrangian under global spinrotations is the net spin density, and it is given by s=sn+
ρn×˙n. The magnetization in the presence of an external field
Hcan be then written as M=g
lsn+gtρn×˙n+χH, where
glandgtare the gyromagnetic ratios for the longitudinal and
transverse components of the spin density with respect to thedirection n, respectively, and χis the magnetic susceptibility
tensor. The relation M=∂L/∂H[4] requires the susceptibility
to be χ
ij=ρg2
t(1−ninj), with which the Lagrangian is
extended to
L=−sa[n]·˙n+ρ(˙n−gtn×H)2
2−U[n], (8)
whereU[n] includes the Zeeman term, −glsn·H. Finally, the
dissipation can be accounted for by the Rayleigh dissipationfunction R=s
α˙n2/2, which is half of the dissipation rate of
the energy density P=2R. The equations of motion obtained
from the Lagrangian and the Rayleigh dissipation function aregiven by Eq. ( 1) without the current-induced torques.
Current-induced torques. To derive the torque terms due to
an electric current, it is convenient to begin by phenomenologi-cally constructing the expression for the charge current densityJ
pumpinduced by the magnetic dynamics, and subsequently to
invoke the Onsager reciprocity to obtain the torque terms asdone for antiferromagnets in Ref. [ 14]. To the lowest order of
the space-time gradients and to the first order in the deviationsfrom the equilibrium, we can write two pumping terms thatsatisfy the appropriate spatial and spin-rotational symmetries,
˙n·∂
inandn·(˙n×∂in). The resultant expression for the
induced current density is given by
Jpump
i/σ=ζ˙n·∂in+ξn·(∂in×˙n), (9)
where σis the conductivity.
To invoke the Onsager reciprocity that is formulated
in the linear order in the time derivative of the dynamicvariables, we turn to the Hamiltonian formalism instead ofthe Lagrangian formalism. We shall restrict ourselves hereto the case of a vanishing external field for simplicity, butit can be easily generalized to the case of a finite externalfield. The canonical conjugate momenta of nis given by
p≡∂L/∂˙n=ρ(˙n−g
tn×h)−sa. The Hamiltonian density
is then given by
H[n,p]=p·˙n−L=(p+sa)2
2ρ+U, (10)
which resembles the Hamiltonian for a charged particle
subjected to an external magnetic field [ 27]. The Hamilton
equations are given by
˙n=∂H
∂p≡−hp, (11)
˙p=−∂H
∂n−∂R
∂˙n≡hn−sα˙n=hn+sαhp, (12)
140404-3RAPID COMMUNICATIONS
SE KWON KIM, KYUNG-JIN LEE, AND YAROSLA V TSERKOVNYAK PHYSICAL REVIEW B 95, 140404(R) (2017)
where hpandhnare conjugate fields to pandn, respectively.
In terms of the conjugate fields, the pumped charge current isgiven by J
pump=−ζ∂in·hp−ξ(n×∂in)·hp.B yu s i n gt h e
Onsager reciprocity and Ohm’s law for the current J=σE,
we can obtain the torque terms in Eq. ( 1).
Discussion. Let us discuss approximations that have been
used in this Rapid Communication. First, we have developedthe theory for the dynamics of collinear magnets within theexchange approximation [ 4], in which the total energy is
invariant under the simultaneous rotation of the constituentspins. The relativistic interactions including the magneticanisotropy, which weakly break the exchange symmetry ofthe magnet, are added phenomenologically to the potentialenergy. Second, when studying the dynamics of skyrmions ininhomogeneous ferrimagnetic films, we have considered thenonuniform spin density s, while neglecting possible spatial
variations of the other parameters such as inertia ρor damping
s
α. As long as skyrmions are attracted to the line of vanishing
angular momentum due to the combined effects of the effectiveLorentz force, the viscous force, and the current-induced force,smooth variations of various parameters away from it shouldnot significantly affect the dynamics.Ferrimagnetic RE-TM alloys not only have an angular
momentum CP, which we have focused on in this RapidCommunication, but also a magnetic moment CP. Motivatedby the attraction of skyrmions toward the angular momentumcompensation lines that we have discussed, it would be worthlooking for an interesting phenomenon that can occur on themagnetic moment compensation line. For example, since themagnetic moment governs the magnetostatic energy, there maybe unusual magnetostatic spin-wave modes [ 28] localized at
the line. In addition, we have considered the dynamics of asoliton in two-dimensional ferrimagnets driven by an electriccurrent. In general, the dynamics of a soliton can be inducedby other stimuli such as an external magnetic field [ 29] and
a spin-wave excitation [ 30–32], which may exhibit peculiar
features of ferrimagnets that are absent in ferromagnets andantiferromagnets.
Acknowledgments . We thank Kab-Jin Kim and Teruo Ono
for enlightening discussions. This work was supported bythe Army Research Office under Contract No. W911NF-14-1-0016 (S.K.K. and Y .T.) and by the National ResearchFoundation of Korea (NRF) grant funded by the Koreagovernment (MSIP) (NRF-2015M3D1A1070465) (K.-J.L.).
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140404-5 |
PhysRevLett.126.196601.pdf | Spin-Flip Diffusion Length in 5 dTransition Metal Elements:
A First-Principles Benchmark
Rohit S. Nair ,1Ehsan Barati ,1,‡Kriti Gupta,1Zhe Yuan ,2,*and Paul J. Kelly1,2,†
1Faculty of Science and Technology and MESA+Institute for Nanotechnology, University of Twente,
P.O. Box 217, 7500 AE Enschede, Netherlands
2The Center for Advanced Quantum Studies and Department of Physics, Beijing Normal University,
100875 Beijing, China
(Received 13 October 2020; accepted 16 April 2021; published 12 May 2021)
Little is known about the spin-flip diffusion length lsf, one of the most important material parameters in
the field of spintronics. We use a density-functional-theory based scattering approach to determine valuesofl
sfthat result from electron-phonon scattering as a function of temperature for all 5dtransition metal
elements. lsfdoes not decrease monotonically with the atomic number Zbut is found to be inversely
proportional to the density of states at the Fermi level. By using the same local current methodology tocalculate the spin Hall angle Θ
sHthat characterizes the efficiency of the spin Hall effect, we show that the
products ρðTÞlsfðTÞandΘsHðTÞlsfðTÞare constant.
DOI: 10.1103/PhysRevLett.126.196601
Spin-orbit coupling (SOC) leads to the loss of spin
angular momentum. A current of electrons injected from aferromagnet into a nonmagnetic material loses its spinpolarization over a length scale of l
sf, the spin-flip diffusion
length (SDL) [1–4], making the observation of spin
currents difficult. The giant magnetoresistance (GMR)effect was discovered in magnetic multilayers [5,6] only
when the thickness of the spacer layers separating themagnetic films was made to be of order l
sf. A review of
the SDL in metals and alloys some twenty years after thediscovery of GMR concerned mainly the free-electron-like
metals Cu, Ag, Au, and Al that have large values of l
sf; for
just a few of the transition metal elements, there was asingle, low temperature entry [7]. With the “rediscovery ”
[8,9] of the spin Hall effect (SHE) [10]and its observation
in semiconductors [11,12] and metals [13,14] , this situation
has changed radically [15,16] . However, even for well-
studied materials like Pt, values of l
sfreported over the last
decade span an order of magnitude [16,17] . Discernible
trends in lsfhave not been reported for different transition
metal elements.
The SHE is another consequence of SOC whereby the
passage of a charge current through a metal gives rise to a
transverse spin current that can enter an adjacent magnetic
material and exert a torque on its magnetization causing itto switch its orientation. The efficiency of the SHE is givenby the spin Hall angle (SHA) Θ
sHthat is the ratio of the
transverse spin current (measured in units of ℏ=2) to the
charge current (measured in units of the electron charge−e). From being a curiosity, the SHE has rapidly become a
leading contender to form the basis for a new magneticmemory technology [18] bringing with it the need to find
materials with optimal values of Θ
sHwith a primary focuson heavy metals like Pt [14,19] ,T a [20], and W [21].
Striking discrepancies between different room temperature(RT) measurements, with reported values of, e.g., Θ
Pt
sH
ranging between 1% and 11% [15], led to the realization
that the bulk parameters lsfandΘsH, as well as the
resistivity ρwere very sample dependent and needed to
be determined simultaneously. Doing this did not, however,lead to a consensus about the values of these parameters[16]. Whether the SHA is determined using spin pumping
and the inverse SHE [14,22 –24], the SHE and spin-transfer
torque [25], or nonlocal spin injection [19,26] , interfaces
are always involved leading to the suggestion that interfaceprocesses like interface spin flipping (spin memory loss)[27–30]or an interface SHE [31,32] should be taken into
consideration in interpreting experiment. Attempts to do sohave, if anything, made matters worse with recentlydetermined values of l
Pt
sfranging from 1.4 to 11 nm and
ΘPt
sHranging between 3% and 39%; see Table V in Ref. [17].
The only attempt we are aware of to study the intrinsic
SDL theoretically is the phonon-induced spin relaxation
work by Fabian and Das Sarma on aluminium [33]that is
not readily generalized to transition metals. The purpose ofthis Letter is to present benchmark calculations of l
sfand
ΘsHfor all bulk 5dmetals at temperatures where the
resistivity is dominated by electron-phonon scattering andthe extrinsic scattering that dominates low temperaturemeasurements, but whose microscopic origin is seldomknown, can be disregarded. These first quantitative theo-retical predictions give us insight into how l
sfmay be
modified and confirm long-standing speculations aboutrelationships between ρ,l
sf,ΘsH, and the temperature T.
Method.—We recently demonstrated that it was possible
to distinguish bulk transport properties from the interfacePHYSICAL REVIEW LETTERS 126, 196601 (2021)
0031-9007 =21=126(19) =196601(7) 196601-1 © 2021 American Physical Societyeffects that are inherent to scattering formulations of
transport [34]by evaluating local charge and spin currents
from the solutions of quantum mechanical scattering
calculations [17,35] as sketched in the inset to Fig. 1.
Our density-functional-theory scattering calculations
include temperature-induced lattice and spin disorder in
the adiabatic approximation [36,37] as well as SOC [38].
An example of the results of such a calculation is shown inFig. 1, where we plot the natural logarithm of the spin
current that results from injecting a fully polarized current
into a length Lof room temperature (RT, T¼300K)
disordered Ta where a Gaussian distribution of random
atomic displacements was chosen to reproduce the exper-
imentally observed resistivity of bulk Ta [39]. From the
near-perfect exponential decay over 5 orders of magnitude,
we extract a value of l
Ta
sfðT¼300KÞ∼6.2nm that is
independent of the lead material [17]. Spin memory loss at
the left interface manifests itself in the deviation from
exponential behavior close to z∼0[35].
Results.—The parameter ξcontained in the SOC term
ξl:sof the Pauli Hamiltonian scales as the square of the
atomic number Z[40,41] as shown in the inset to Fig. 2.For the 5delectrons, ξdincreases monotonically from
∼0.22eV for Hf to ∼0.63eV for Au. This might lead us to
expect a decreasing trend in lsfwith Z. The calculated RT
values of lsfshown in Fig. 2for all 5delemental metals
exhibit no such decrease. For example, Ta and W are both
bcc and as neighbors in the periodic table have very similar
values of ξdyetlW
sfis some 5 times larger than lTa
sf. We find
instead that the dominant trend is given by the inverse of the
Fermi level density of states (DOS), gðεFÞ, shown in orange
in Fig. 2averaged over an energy window of /C6kBTabout
the Fermi energy. A low DOS means fewer possibilities to
scatter with a spin flip. The same correlation with the
inverse DOS is found on calculating lsfas a function of
band filling for bcc and fcc structures (not shown).
Reported experimental values of lsfat RT are 1.8 and
1.9 nm for bcc Ta, 2.1 nm for bcc W, between 1 and 11 nmfor Pt, and from 27 to 86 nm for Au [16]. The lack of any
correlation with the “intrinsic ”values we calculate suggests
that the measurements are dominated by other, as yet
unidentified, factors.
Temperature dependence. —By varying the mean square
displacement of the atoms in the scattering region toreproduce experimental resistivities, we can study the
temperature dependence of l
sfdue to electron-phonon
coupling. For temperatures in the range 100 –500 K, the
product ρðTÞlsfðTÞis plotted for all 5delements in Fig. 3,
where it is seen to be independent of temperature within the
error bars of the calculations. (The large value of lW
sf∼
30nm at 300 K requires calculations with an excessively
long geometry putting values for 100 and 200 K out of
reach.) This is in agreement with predictions made byElliott and Yafet for doped semiconductors and alkali
FIG. 1. Natural logarithm of a spin current injected into RT bcc
Ta as a function of the coordinate zin the transport direction,
L→R. The upper inset sketches the transport geometry with a
scattering region Swith temperature dependent lattice disorder
sandwiched between ideal semi-infinite ballistic leads, LandR.A
fully polarized spin current injected from the left lead Lundergoes
spin flipping leading to spin equilibration on a length scale given
by the spin-flip diffusion (SFD) length lsfas suggested by the red
arrows. An unpolarized charge current injected from Lundergoes
spin dependent scattering leading to a transverse spin Hall currentdepicted by the purple arrow. The lower inset shows the spincurrent on a linear scale. The current was extracted from the resultsof a scattering calculation for a two-terminal Ta ↑jTajTa configu-
ration using a 7×7lateral supercell where Ta ↑indicates an
artificial, fully polarized Ta lead. The red line is a weighted linearleast squares fit; the error bar in the value 6.20/C60.06results from
different “reasonable ”weightings and cutoff values [17].FIG. 2. Black (left): spin-flip diffusion length lsffor5d
transition metals calculated at room temperature (300 K), theerror bars correspond to the spread of values for ten differentconfigurations. For hcp metals, the c-axis values are shown.
Orange (right): inverse of ¯gðε
FÞ, the density of states averaged
over an energy window of /C6kBTabout the Fermi energy εF.
Inset: spin-orbit coupling parameter ξdas a function of the square
of the atomic number Zfor the 5delements.PHYSICAL REVIEW LETTERS 126, 196601 (2021)
196601-2elements [42,43] but now for Fermi surfaces that are far
more complex than those they considered, for which their
approximations are not applicable. As such, this result is
nontrivial. While lsfvaries from 4 to 50 nm at room
temperature, the product ρlsfspans a smaller range, varying
between 0.5 and 2fΩm2.
Although ξdattains its maximum value for Au, the d
bands are then completely filled and well below the Fermi
energy so Au is expected to have a long SDL. The low
resistivity and weak effective SOC of Au make a directcalculation computationally very challenging. To determine
l
Au
sfat room temperature, we considered an elevated
temperature of T¼1000 K and then assumed that
ρðTÞlsfðTÞwas a constant in order to estimate the RTvalue of lsf∼50nm shown in Fig. 2(as a black asterisk)
and given in Table I.
Relationship of τsftoτ.—The product ρðTÞlsfðTÞis
expected to be a constant when momentum scattering is
dominated by phonons and τsf∝τ[42,43] . We can
estimate τand τsfas follows. In the relaxation time
approximation, the conductivity is given in terms of the
kdependent velocities υnðkÞ¼ð 1=ℏÞ∇kεnðkÞfor band
nas
σij¼e2X
nZZZd3k
8π3τnðkÞυniðkÞυnjðkÞ/C18
−∂f
∂ε/C19
ε¼εnðkÞ;
which becomes an integral over the Fermi surface SFwhen
−ð∂f=∂εÞ→δðε−εFÞin the low temperature limit and
assuming τðkÞ¼τ½εnðkÞ/C138soσ¼e2gðεFÞτðεFÞhv2
Fi. Both
gðεFÞand hv2
Fican be evaluated from standard bulk LMTO
electronic structure calculations [44]. Since σ≡1=ρis
known [39,45] ,τcan be evaluated as
τ¼σ
e2gðεFÞhv2
Fi:
The diffusion coefficient D[3]can be determined from the
Einstein relation σ¼De2gðεFÞ. Using the spin-flip dif-
fusion length lsfevaluated from the exponential decay of an
injected spin current and the relationship l2
sf¼Dτsfallows
us to determine τsf. The ratio of the spin relaxation time, τsf,
toτis finally
τsf
τ¼½e2ρlsfgðεFÞ/C1382hv2
Fi:
In spite of the apparent complexity of this relationship,
Fig.4shows that the factor dominating the Zdependence
of both relaxation times is the inverse Fermi-level density
of states. In this sense τsf∝τ, consistent with ρlsfbeing
independent of temperature. We note that the electron-phonon coupling and phonon-modulated SOC effects enterFIG. 3. Product of the spin-flip diffusion length and resistivity
for5dmetals calculated at different temperatures. For hcp metals,
thec-axis values are shown. The error bars are estimated from the
average spreads over 10 configurations for both lsfand ρ.
TABLE I. Room temperature transport parameters of 5dmetallic
elements (El.): resistivity ρ(μΩcm); Fermi level density of states
¯gðεFÞ(states/eV .atom); diffusion constant D(cm2=s); Fermi
velocity υF≡hυ2
Fi1=2(108cm=s); relaxation time τ(fs); spin-flip
diffusion length lsf(nm); spin relaxation time τsf(fs); spin Hall
angleΘsH(%). kand⊥refer to parallel to and perpendicular to the
hcp hexagonal axis, respectively.
El. Latt. ρ ¯gðεFÞD υF τ lsf τsfΘsH
Hf hcp k35.6 0.79 4.94 0.40 9.07 4.97 50 1.35
hcp⊥59.0 2.98 5.47 4.2 60 0.98
Ta bcc 12.1 1.25 7.37 0.89 2.79 6.16 50 −0.50
W bcc 5.49 0.35 51.2 1.13 12.0 29.6 170 −0.40
Re hcp k19.7 1.04 4.52 0.71 2.69 4.46 44 −1.28
hcp⊥25.8 3.45 2.05 3.22 30 −1.90
Os hcp k9.48 0.63 14.77 0.88 5.73 6.06 25 0.71
hcp⊥10.0 3.41 5.44 5.90 25 −0.66
Ir fcc 5.31 0.90 18.4 0.76 9.68 14.1 110 0.22Pt fcc 10.8 1.62 5.37 0.43 8.71 5.21 50 4.02Au fcc 2.27 0.29 160 1.39 24.8 50.9 160 0.25
FIG. 4. Momentum relaxation time τand spin-flip relaxation
time τsfin fs for all 5delements at room temperature.PHYSICAL REVIEW LETTERS 126, 196601 (2021)
196601-3our calculation implicitly via the resistivity ρwhile the
density of states gðεFÞis calculated with SOC explicitly
included in the Hamiltonian. Room temperature values ofall the transport parameters calculated as described above
are given in Table I.
Spin Hall angle. —Because of the correlation between
the SHA and SDL observed in measurements [27],i ti s
desirable to determine Θ
sHusing the same approximations
as were used to calculate lsf. Most quantitative theoretical
studies of the SHE [47–50]are based upon the Kubo
formalism and have focused on the so-called intrinsic
contribution that does not consider the role of the elec-tron-phonon scattering mechanism that dominates the
resistivity of elemental metals at room temperature where
the vast majority of Θ
sHdeterminations have been made
[16]. In the linear response regime, the scattering theory we
use is equivalent to the Kubo formalism [51]and therefore
includes the intrinsic contribution as well as that fromelectron-phonon coupling. The advantage of the scattering
formalism is that extrinsic mechanisms can be included on
an equal footing. By calculating the transverse spin currentresulting from a longitudinal charge current using the localcurrent method [17] introduced previously to study Θ
Pt
sH
[31], we determined ΘsHas a function of temperature for all
5delements.
The5dm e t a ls p i nH a l lc o n d u c t i v i t y( S H C ) σsH¼ΘsH×σ
is shown for a number of different temperatures in Fig. 5and is
seen to be weakly dependent on temperature, except for Re.
The element ( Z) dependence is in qualitative agreement with
the linear response calculations by Tanaka et al. who used anempirical “quasiparticle damping parameter ”to represent
disorder [48]. In these latter calculations, the correct bcc,
fcc, and hcp structures were used for each element but Hf andAu were not considered. Based upon a rigid band study for the
fcc structure, Guo et al. identified a switch from positive
values of σ
sHfor band filling corresponding to Pt to negative
values for band fillings corresponding to Ta and W [47]and
this has been interpreted in terms of Hund ’s third rule [52].W e
reproduced the peaks observed by Guo et al. as a function of
band filling for the fcc structure in [17]and note that they
originate in regions of the Brillouin zone with degeneracies
that are strongly affected by SOC. The energies and numbers
of these degeneracies depend on the lattice structure andexplicit calculation for the bcc and hcp structures shows that
the correspondence between Guo ’s rigid band picture for the
fcc structure and observations for materials with otherstructures is accidental [53]. For example, it predicts a small,
negative SHC for Hf. However, for hcp Hf we find a small,
positive value of σ
sHin agreement with recent experi-
ments [54,55] .
Our finding of a weak temperature dependence of σsHis
in qualitative agreement with the temperature independencefound for Pt by Isasa et al. [57] who, however, reported a
substantially lower value of σ
sH∼1200 ðΩcmÞ−1(note that
we use the ℏ=2econvention [58]). A subsequent meas-
urement by the same group yielded a room temperature
spin Hall conductivity of ∼3200 ðΩcmÞ−1[30]in excellent
agreement with our value. At low temperatures in cleansamples, they observed an enhancement of σ
sHwith
decreasing temperature. Such an enhancement was recently
found [59] in calculations in which phonon modes of Pt
were explicitly populated as a function of temperature [37]
and it was pointed out that the temperature independence of
σsHthat we find is characteristic of the classical equiparti-
tion approximation [59]. When the resistivity is no longer
linear in temperature, our description of thermal disorder in
terms of a Gaussian distribution of uncorrelated atomic
displacements is not suitable for studying the weak scatter-ing limit. This is typically well below 100 K [39].
In view of the proportionality of Θ
Pt
sHto the resistivity ρ
[31]and of lPt
sfto the conductivity [28,37] , their product is
expected to be independent of temperature. ΘsH×lsfis
shown in the inset to Fig. 5for all 5delements for a number
of temperatures between 100 and 500 K. As a function of Z,
it is seen to follow the trend of σsHand as a function of
temperature it is indeed approximately constant for allmetals except rhenium for which additional theoretical and
experimental studies are desirable. It remains to be seen
howΘ
sH×lsfbehaves when different scattering mecha-
nisms are present simultaneously, in particular interfacescattering and bulk thermal disorder.
Conclusions. —We have presented a comprehensive
ab initio study of two important spin-orbit coupling related
transport parameters in the 5dmetals as a function of
temperature verifying the generality of the Elliot-YafetFIG. 5. The spin Hall conductivity σsH(¼ΘsH×σ) calculated
at different temperatures compared to the room temperature spinHall conductivity for all 5delements (except Hf and Au) reported
by Tanaka et al. [48]using a Green function method (GFM) and a
phenomenological quasiparticle damping rate to account fordisorder. The inset shows the product Θ
sH×lsfas a function of
temperature. Only one value is plotted for Au based on anextrapolation of l
sfto RT. For hcp metals, the c-axis values
are shown.PHYSICAL REVIEW LETTERS 126, 196601 (2021)
196601-4mechanism and establishing numerical benchmarks for
experiment. The values of ρlsf,σsH, andΘsHlsfcalculated
in this work can be directly used to predict the values of lsf
andΘsHfor the most experimentally relevant temperatures.
In particular, the direct correspondence between the spin-
flip diffusion length and density of states at the Fermi level
implies that spin-flip scattering can be effectively con-
trolled by alloying, whereas a high spin Hall conductivity
may be achieved by tuning the Fermi level with respect to
degeneracies at high symmetry points. Our results indicate
that the magnitude of the SOC is not the sole determinant of
lsfandΘsHbut that crystal structure and associated details
of the electronic structure are just as important.
This work was financially supported by the “Nederlandse
Organisatie voor Wetenschappelijk Onderzoek ”(NWO)
through the research programme of the former “Stichting
voor Fundamenteel Onderzoek der Materie, ”(NWO-I,
formerly FOM) and through the use of supercomputer
facilities of NWO “Exacte Wetenschappen ”(Physical
Sciences). R. S. N (Project No. 15CSER12) and K. G.
(Project No. 13CSER059) acknowledge funding from the
Shell-NWO/FOM “Computational Sciences for Energy
Research (CSER) ”Ph.D. program. The work was also
supported by the Royal Netherlands Academy of Arts
and Sciences (KNAW). Work in Beijing was supported
by the National Natural Science Foundation of China (Grant
No. 61774018), the Recruitment Program of Global Youth
Experts, and the Fundamental Research Funds for the
Central Universities (Grant No. 2018EYT03).
*zyuan@bnu.edu.cn
†P.J.Kelly@utwente.nl
‡Present address: Department of Chemistry, Brown Univer-
sity, Providence, Rhode Island 02912, USA.
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196601-7 |
PhysRevB.79.184423.pdf | Microscopic model for current-induced switching of magnetization for half-metallic leads
N. Sandschneider *and W. Nolting
Institut für Physik, Humboldt-Universität zu Berlin, Newtonstr. 15, 12489 Berlin, Germany
/H20849Received 22 April 2009; published 20 May 2009 /H20850
We study the behavior of the magnetization in a half-metallic ferromagnet/nonmagnetic insulator/
ferromagnetic metal/paramagnetic metal tunnel junction. It is calculated self-consistently within the nonequi-librium Keldysh formalism. The magnetic regions are treated as band ferromagnets and are described by thesingle-band Hubbard model. We developed a nonequilibrium spectral density approach to solve the Hubbardmodel approximately in the switching magnet. By applying a voltage to the junction it is possible to switchbetween antiparallel /H20849AP/H20850and parallel /H20849P/H20850alignments of the magnetizations of the two ferromagnets. The
transition from AP to P occurs for positive voltages while the inverse transition from P to AP can be inducedby negative voltages only. This behavior is in agreement with the Slonczewski model of current-inducedswitching and appears self-consistently within the model, i.e., without using half-classical methods such as theLandau-Lifshitz-Gilbert equation.
DOI: 10.1103/PhysRevB.79.184423 PACS number /H20849s/H20850: 85.75. /H11002d, 72.25. /H11002b, 73.23. /H11002b, 73.40.Rw
There has been considerable interest in the phenomenon
of current-induced switching of magnetization since it was
first proposed over 10 years ago.1,2The basic idea behind this
effect is as follows. The spin direction of electrons moving ina ferromagnet /H20849FM1 /H20850will be mostly aligned parallel to the
magnetization axis. When these spin-polarized electrons aretransported to a second ferromagnet, e.g., by applying a volt-age, then the spin angular momentum of the itinerant elec-trons will exert a torque on the local magnetic moment. Thistorque is known as the spin-transfer torque. It will have aninfluence on the direction of magnetization. If the parametersof the materials are chosen in the right way and if the currentthrough the junction is high enough it is even able to switchthe magnetization of one ferromagnet from parallel to anti-parallel or vice versa relative to the other one. This effectwas seen both in all-metallic junctions
3–5such as Co/Cu/Co
and in magnetic tunnel junctions /H20849MTJs /H20850consisting of two
ferromagnets divided by a thin nonmagnetic insulator.6–8In
this paper we focus on a special case of the latter, where theferromagnetic lead is half-metallic, i.e., there are only elec-trons of one spin direction present at the Fermi energy.
Some of the possible technological applications of spin-
transfer torques in MTJs have been discussed by Diao et al.
9
Most of the theoretical work in this area of research have
been focused on the Landau-Lifshitz-Gilbert /H20849LLG /H20850
equation,10–14which is a macroscopic, half-classical equa-
tion. The torques entering this equation were usually calcu-lated in a microscopic picture while treating the interactionson a mean-field level. In this paper we propose a modelwhich takes interactions beyond mean field into account. Wemake no use of the LLG equation or other macroscopic ap-proaches and thus we stay on the quantum-mechanical levelthroughout this paper.
We will start the presentation of the theory by introducing
a model Hamiltonian which describes the magnetic tunneljunction shown schematically in Fig. 1. There are two ferro-
magnetic metals /H20849LandR/H20850divided by a nonmagnetic insula-
tor /H20849I/H20850and additionally a paramagnetic metal /H20849P/H20850which is
necessary to have a well-defined chemical potential on theright side of the second ferromagnet. Each region consists ofa single s-like band. The two outer leads LandPare treated
as semi-infinite.
The total Hamiltonian consists of several parts
H=H
L+HLI+HI+HRI+HR+HRP+HP, /H208491/H20850
where HL/H20849R/H20850describes the left /H20849right /H20850ferromagnet, HIthe
insulator, and HPthe paramagnet. Both insulator and para-
magnet are assumed to be noninteracting so their Hamilto-nians consist of the kinetic energy only
H
X=/H20858
kX/H9268/H20849/H9280kX−VX/H20850dkX/H9268+dkX/H9268 /H20849X=I,P/H20850, /H208492/H20850
where dkX/H9268/H20849dkX/H9268+/H20850is the annihilation /H20849creation /H20850operator of an
electron with wave vector kXand spin /H9268./H9280kXis the disper-
sion of the lattice which throughout this paper is chosen as a
tight-binding bcc lattice. The applied voltage Vwill shift the
center of gravity of the paramagnet by VP=Vand half of that
amount for the insulator, VI=V/2. Positive voltage, V/H110220,
will shift the bands to lower energies while negative appliedvoltages result in a shift toward higher energies.
The Hamiltonians of the left /H20849L/H20850and right /H20849R/H20850ferromag-
nets are formally almost identical. Besides the kinetic energythey also include on-site Coulomb interaction. They aregiven in a mixed Bloch-Wannier representation
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/1 Lµ
eVInsulator FM 1 FM 2 PM
µP
FIG. 1. Schematic picture of the magnetic tunnel junction with
applied voltage V. The conduction bands are shown as rectangles.
Occupied states in the metals are hatched and the directions ofmagnetization in the ferromagnets are symbolized by thick arrows.PHYSICAL REVIEW B 79, 184423 /H208492009 /H20850
1098-0121/2009/79 /H2084918/H20850/184423 /H208496/H20850 ©2009 The American Physical Society 184423-1HM=/H20858
kM/H9268/H20849/H9280kM−VM/H20850ckM/H9268+ckM/H9268+UM
2/H20858
iM/H9268nˆiM/H9268nˆiM−/H9268,/H208493/H20850
where Mstands for either LorR. The Hubbard Udetermines
the interaction strength. nˆiM/H9268=ciM/H9268+ciM/H9268is the occupation
number operator. The voltage Vshifts only the band center of
the right ferromagnet, VR=Vwhile the left ferromagnet is not
directly influenced by V, i.e., VL=0.
The remaining three terms of the Hamiltonian are respon-
sible for the coupling between the different regions. Thesecouplings act as a hybridization
15between the bands and
therefore the Hamiltonians are /H20849M=L,R;X=I,P/H20850,
HMX=/H20858
kMkX/H9268/H20849/H9280kMkXckM/H9268+dkX/H9268+ H.c. /H20850. /H208494/H20850
They are characterized by the coupling constants /H9280kMkXwhich determine the strength of the hybridization between
the different bands. In general the couplings are wave vectordependent but for the sake of simplicity we neglect this de-pendence,
/H9280kMkX/H11013/H9280MX/H11013/H9280XM. Furthermore we assume the
coupling between the ferromagnets and the insulator to be
equal so that /H9280LI=/H9280RI/H11013/H9280MI. Altogether there remain two cou-
plings /H9280MIand/H9280RPwhich cannot be calculated within this
model so they will be treated as parameters.
The main topic of this work will be the calculation of the
nonequilibrium magnetization mof the right ferromagnet
within the Keldysh formalism.16It can be calculated with the
help of the Fourier transform of the so-called lesser Green’s
function defined as GkR/H9268/H11021/H20849t,t/H11032/H20850=i/H20855ckR/H9268+/H20849t/H11032/H20850ckR/H9268/H20849t/H20850/H20856,
m=n↑−n↓=1
2/H9266iN/H20885
−/H11009+/H11009
dE/H20858
kR/H20851GkR↑/H11021/H20849E/H20850−GkR↓/H11021/H20849E/H20850/H20852,/H208495/H20850
where n/H9268=/H20855nˆ/H9268/H20856is the occupation number of particles with
spin/H9268in the right ferromagnet. In order to derive the lesser
Green’s function one first has to calculate the retarded one,
GkR/H9268r/H20849E/H20850=/H20855/H20855ckR/H9268;ckR/H9268+/H20856/H20856E. By using the equation of motion
method one finds
GkR/H9268r/H20849E/H20850=1
E−/H9280kR−/H9018kR/H9268r/H20849E/H20850−/H9004kR/H9268r/H20849E/H20850. /H208496/H20850
Two different self-energies appear in the Green’s function.
First there is the interaction self-energy which can only becalculated approximately for the Hubbard model. We pro-pose a nonequilibrium spectral density approach /H20849NSDA /H20850.
The basic idea behind this approach is to choose the self-energy in such a way that the first four spectral moments arereproduced by the theory. Some details of its derivation aregiven in the Appendix. The mean-field /H20849Stoner /H20850solution of
the Hubbard model on the other hand satisfies only the firsttwo moments. One finds for the self-energy
/H9018
kR/H9268r/H20849E/H20850=URn−/H9268E−T0,R−B−/H9268
E−T0,R−B−/H9268−UR/H208491−n−/H9268/H20850. /H208497/H20850
This expression is coincidentally formally identical to the
equilibrium spectral density approach.17The difference is in
the spin-dependent band correction B−/H9268which is given byn−/H9268/H208491−n−/H9268/H20850/H20849B−/H9268−T0,R/H20850
=1
2/H9266iN/H20858
kR/H20885
−/H11009/H11009
dE/H20875/H20877/H208752
UR/H9018kR−/H9268r/H20849E/H20850−1/H20876
/H11003/H20851E−T0,R−/H9018kR−/H9268r/H20849E/H20850/H20852+/H208732
UR−1/H20874/H20849/H9280kR−T0,R/H20850
/H11003/H20851E−/H9280kR−/H9018kR−/H9268r/H20849E/H20850/H20852/H20878GkR−/H9268/H11021/H20849E/H20850+2
UR/H9004kR−/H9268/H11021/H20849E/H20850/H20876.
/H208498/H20850
It has to be calculated self-consistently since B−/H9268also ap-
pears on the right-hand side as part of the lesser Green’sfunction. T
0,Ris the center of gravity of the right ferromag-
net. The second self-energy is the transport self-energywhich is due to electrons hopping between the different ma-terials. Its retarded /H20849lesser /H20850component is given by
/H9004
kR/H9268r/H20849/H11021/H20850/H20849E/H20850=/H20858
kI/H9280MI2GkI/H9268/H20849L/H20850,r/H20849/H11021/H20850/H20849E/H20850+/H20858
kP/H9280RP2gkP/H9268r/H20849/H11021/H20850/H20849E/H20850, /H208499/H20850
where GkI/H9268/H20849L/H20850,r/H20849E/H20850is the Green’s function of the insulator when
it is only coupled to the left ferromagnet, i.e.,
GkI/H9268/H20849L/H20850,r/H20849E/H20850=1
E−/H9280kI−/H20858kL/H9280MI2gkL/H9268r/H20849E/H20850. /H2084910/H20850
Since we neglected the wave vector dependence of the cou-
plings, the transport self-energy is only formally dependent
on the wave vector. gkL/H9268r/H20849E/H20850andgkP/H9268r/H20849E/H20850are the equilibrium
Green’s functions of the left ferromagnet and the paramag-
net, respectively. They can be easily calculated by the equa-tion of motion method. One finds for M=L,P,
g
kM/H9268r/H20849E/H20850=1
E−/H9280kM−/H9018kM/H9268r/H20849E/H20850. /H2084911/H20850
The paramagnet does not include interactions so that /H9018kP/H9268r
/H11013−i0+. Since we are mainly interested in the properties of
the right ferromagnet, we assume that the left one is halfmetallic so that its minority states play no role for smallvoltages. This is done by using the mean-field self-energy
/H9018
kL/H9268r=ULnL,−/H9268with sufficiently large UL. Thus the retarded
Green’s function is known.
The lesser Green’s function follows immediately from the
Keldysh equation
GkR/H9268/H11021/H20849E/H20850=GkR/H9268r/H20849E/H20850/H9004kR/H9268/H11021/H20849E/H20850GkR/H9268a/H20849E/H20850, /H2084912/H20850
where the advanced Green’s function is simply the complex
conjugated of the retarded one, GkR/H9268a/H20849E/H20850=/H20851GkR/H9268r/H20849E/H20850/H20852/H11569. Fur-
thermore we need the lesser component of the transport self-
energy which was already defined in Eq. /H208499/H20850. The lesser part
of the insulator Green’s function can again be calculated withthe help of the Keldysh equation
G
kI/H9268/H20849L/H20850,/H11021/H20849E/H20850=/H20858
kLGkI/H9268/H20849L/H20850,r/H20849E/H20850/H9280MI2gkL/H9268/H11021/H20849E/H20850GkI/H9268/H20849L/H20850,a/H20849E/H20850. /H2084913/H20850
Since the Green’s functions in the left ferromagnet and the
paramagnet are equilibrium quantities, their lesser parts readN. SANDSCHNEIDER AND W. NOLTING PHYSICAL REVIEW B 79, 184423 /H208492009 /H20850
184423-2gkL/H20849P/H20850/H9268/H11021/H20849E/H20850=−2 ifL/H20849P/H20850/H20849E/H20850ImgkL/H20849P/H20850/H9268r/H20849E/H20850, /H2084914/H20850
where fL/H20849P/H20850/H20849E/H20850is the Fermi function in lead L/H20849P/H20850with chemi-
cal potential /H9262L/H20849P/H20850. They are related by /H9262L−/H9262P=V. Thus we
have a closed set of equations for calculating the magnetiza-tion of the ferromagnet.
In Fig. 2a typical numerical solution for the voltage-
dependent magnetization is shown. We will first discuss theblack curve, which was calculated with a hybridizationstrength of
/H9280MI=0.5 eV. For the calculation we started with
parallel alignment of the two magnetizations /H20849point Ain the
figure /H20850. Then a negative voltage is applied, i.e., the right
ferromagnet is shifted to higher energies compared to the leftone. At a critical voltage the parallel alignment becomes un-stable and the magnetization reverses its sign /H20849BtoC/H20850. Thus
the magnetizations are now antiparallel. When the voltage isfurther decreased the magnetization stays more or less con-stant until point Dis reached. Then the process is reversed
and the voltage is reduced to zero again. The magnetizationfollows the same line as before until the switching point Cis
reached. There it does not switch back to parallel alignmentbut rather stays at about the same level. When Eis reached
the direction of the voltage is reversed, i.e., the right ferro-magnet will now be shifted to lower energies. For small volt-ages there is only a slight increase until a critical voltage isreached /H20849F/H20850. This voltage has approximately the same value
as the first one at point Bbut of course with an opposite sign.
There the antiparallel alignment is no longer stable and thesystems returns to its initial parallel state which is not influ-enced by higher voltages /H20849GtoH/H20850. Then the voltage is turned
off and the system will be at its starting point Aagain so the
hysteresis loop is complete.
As another test we start again at point Abut this time we
turn on a positive voltage. Then no switching occurs and thesystem will move reversibly to point H. A similar reversible
behavior is seen when the alignment is antiparallel /H20849E/H20850and
the voltage is decreased. This is shown by the arrows in thefigure. So, one has to conclude that switching of magnetiza-
tion from parallel to antiparallel alignment is only possiblefor negative voltages and the reverse process will only ap-pear for positive voltage. The behavior just described is oneof the hallmarks of current-induced switching of magnetiza-tion and thus our proposed model is indeed able to simulatethis effect without leaving the microscopic picture.
Now we want to give a short explanation on how exactly
our model is able to provide these results. The key to theunderstanding lies in the effect the hybridization parts of theHamiltonian have on the quasiparticle density of states/H20849QDOS /H20850of the switching magnet and in the polarization of
the current. A hybridization between two bands generallywill lead to a repulsion between them, i.e., the energetic dis-tance between their respective centers of gravity will in-crease the stronger the effect of the hybridization is. Themagnitude of this shift is mainly influenced by three quanti-ties: the strength of the hybridization itself /H20849
/H9280RPand/H9280MI
in our case /H20850, the energetic distance between the two bands
/H20849the closer they are to each other, the stronger they will be
repelled /H20850, and their spectral weight /H20849higher spectral weight
leads to stronger repulsion /H20850. In the upper part of Fig. 3we
plotted a typical QDOS for the NSDA without applied volt-age for parallel alignment of the two magnetizations. Thedashed line represents the density of states of the left ferro-magnet. The splitting of the right QDOS into lower andupper Hubbard bands at E/H110150 and E/H11015U
Ris clearly visible.
Additionally there are contributions of the insulator atE/H11015T
0,I=5 eV which are due to the hybridization. What
happens when a voltage is turned on depends on its sign. Theleft ferromagnet FM1 is not influenced by the voltage so itsQDOS will be the same. Let us first discuss the case V/H110220
where both spin bands of the right ferromagnet FM2 areshifted to lower energies. But due to the repulsion betweenthe spin-up bands of FM1 and FM2 the shift of the spin-up-0.4 -0.3 -0.2 -0.1 0 0.1 0.2 0.3 0. 4
Volta ge (V)-0.8-0.400.40.8Magnetization=0.2 eV
=0.5 eVA
B
C
D E FGH
εεMI
MI
FIG. 2. /H20849Color online /H20850Numerical results for the magnetization
as a function of applied voltage for two different values of thehybridization strength
/H9280MIbetween the metals and the insulator.
Arrows indicate in which direction the voltage was changed. Pa-rameters: band occupation n=0.7; band widths: W
L=3 eV, WI
=1 eV, WR=2 eV, and WP=5 eV; interaction strengths: UR
=4 eV, UL=4 eV; band center of the insulator T0,I=5 eV; hybrid-
ization strength: /H9280RP=0.05 eV; temperature: T=0 K-3S--10123QDOS
-2 0 2 4 6
Ener gy (eV)-3-2-10123QDOSFM1
FM2
FIG. 3. /H20849Color online /H20850Quasiparticle density of states for the
parameter set of Fig. 2forV=0 and /H9280MI=0.5 eV. Upper picture for
parallel alignment of the magnetizations /H20849point A /H20850; lower picture for
antiparallel alignment /H20849point E /H20850. Spin up is shown along the posi-
tive; spin down along the negative axis. Black line is the QDOS ofthe right ferromagnet treated within the NSDA and red /H20849gray /H20850bro-
ken line shows the QDOS of the left ferromagnet in mean field.MICROSCOPIC MODEL FOR CURRENT-INDUCED … PHYSICAL REVIEW B 79, 184423 /H208492009 /H20850
184423-3band will actually be stronger than for spin-down, where the
repulsion is much weaker. So a positive voltage leads to astabilization of the magnetization. This effect is enhanced bythe current. For positive voltages it will flow from left toright. Since the left ferromagnet is fully polarized there areonly spin-up electrons tunneling into the right ferromagnet.These are the reasons for the slight increase in magnetizationin Fig. 2between points A and H and also an explanation
why there can be no switching in this case. On the otherhand, if we apply a negative voltage, V/H110210, the right spin
bands will be shifted to higher energies. For the same rea-sons as discussed above the shift of the spin-up band will beenhanced by the hydridization. Thus the difference betweenthe centers of gravity of both spin bands will be decreased. Ifthe hybridization strength is sufficiently large this additionalshift together with the self-consistency will be enough topush the spin-up band above the spin-down band and thusthe magnetization changes sign. The self-consistency is im-
portant since it will enhance the shift because the occupationin one band depends on the occupation in the other one. Inthis case current flows from the right to the left lead. Sincethere are only spin-up states available for tunneling in theleft ferromagnet, the tunneling current flowing out of theswitching magnet will consist of spin-up electrons only. Thisleads to an additional decrease in the right magnetization.This explains the behavior shown by the parallel alignedcurve in Fig. 2.
The antiparallel case can be explained in a very similar
way. In the lower part of Fig. 3the corresponding quasipar-
ticle density of states is shown, again without applied volt-age. The obvious difference to the case discussed above isthat the center of gravity of the lower spin-down band isbelow the lower spin-up band. This is the reason for thenegative magnetization of course but it is also responsible forthe reversed behavior with respect to the applied voltage. Inthis case a negative voltage cannot push the center of gravityof the spin-up band below the spin-down band. It rather hasthe opposite effect because the repulsion pushes the spin-upband to even higher energies and thus leads to a more stablemagnetization which can also be seen in Fig. 2between
points E and D. For a positive voltage the spin-up band ofFM2 moves below the spin-up band of FM1 so that the hy-bridization will shift it to lower energies compared to thespin-down band. Again, if the hybridization strength is largerthan a critical value this additional shift will be enough toreverse the two spin directions such that the magnetizationchanges sign. For the same reasons as discussed for the par-allel case, a positive voltage will increase the magnetizationwhile a negative voltage has the opposite effect. Thereforethe behavior of the magnetization in Fig. 2can be understood
in terms of the quasiparticle density of states.
In order to prove the explanation based on the hybridiza-
tion we plotted a second magnetization curve in Fig. 2with
smaller hybridization strength
/H9280MI=0.2 eV. Obviously in
this case no switching occurs. There is only a slight changein magnetization. Starting from parallel /H20849antiparallel /H20850align-
ment the magnetization is reduced for negative /H20849positive /H20850
voltages. This is in agreement with the explanation givenabove. Since the hybridization is weaker the repulsion be-tween the bands is also reduced. It is not strong enough topush the spin-down band above the spin-up band or vice
versa. Thus the direction of magnetization is not changed.The current density through the junction is closely linked tothe coupling strength between the materials:
15smaller /H9280MI
corresponds to a weaker current. From the results shown inFig.2we can conclude that in order to switch the magneti-
zation the current has to exceed a certain value.
To summarize, we presented a self-consistent calculation
of the voltage-dependent magnetization in a magnetic tunneljunction within a microscopic nonequilibrium framework.The magnetization shows a hysteresis behavior similar tothat seen in experiments. The reason for this effect was ex-plained to be the hybridization between left and right ferro-magnets which could be seen with the help of the quasipar-ticle density of states. It should be noted that the behaviordiscussed above does only appear for very special parametersets /H20849such as low band occupation, small U/H20850when one uses
the mean-field approximation for the right ferromagnet. Thisseems reasonable because it is known that mean fieldstrongly overestimates the stability of ferromagnetism. Thusit should be more difficult to switch the direction of magne-tization. We have to conclude that higher correlations seemto be an important factor when describing current-inducedswitching of magnetization within this model. One mightargue that the Kondo peak is missing in the NSDA whichshould have considerable influence on the magnetization.However, we investigated the strong-coupling regime only,where it is known that the Kondo peak does not play a majorrole. On the other hand it would be a very interesting expan-sion of the model to examine its weak-coupling behavior.Another important extension would be the inclusion of spin-orbit coupling which is widely believed to be the micro-scopic origin of phenomenological damping effects
18which
play a crucial role in the macroscopic description of switch-ing of magnetization.
APPENDIX: NONEQUILIBRIUM SPECTRAL
DENSITY APPROACH
The basic idea behind the NSDA is to choose the self-
energy in such a way that the first four spectral moments
MkR/H9268/H20849n/H20850=−1
/H9266/H20885
−/H11009/H11009
dEEnImGkR/H9268r/H20849E/H20850/H20849 A1/H20850
of the spectral density are reproduced exactly. The moments
are calculated with the help of the following exact relation:
MkR/H9268/H20849n/H20850=1
N/H20858
iRjRe−ikR·/H20849RiR−RjR/H20850
/H11003/H20855/H20853/H20851.../H20851ciR/H9268,H/H20852−, ..., H/H20852−,/H20851H, ..., /H20851H,cjR/H9268+/H20852−.../H20852−/H20854+/H20856,
/H20849A2/H20850N. SANDSCHNEIDER AND W. NOLTING PHYSICAL REVIEW B 79, 184423 /H208492009 /H20850
184423-4where the total number of commutators on the right-hand
side must be equal to n. Inserting the Hamiltonian /H208491/H20850into
this expression yields after some calculation
MkR/H9268/H208490/H20850=1 , /H20849A3/H20850
MkR/H9268/H208491/H20850=/H9280kR+URn−/H9268, /H20849A4/H20850
MkR/H9268/H208492/H20850=/H9280kR2+2UR/H9280kRn−/H9268+UR2n−/H9268+/H9280MI2+/H9280RP2, /H20849A5/H20850
MkR/H9268/H208493/H20850=/H9280kR3+2/H9280kR/H20849/H9280MI2+/H9280RP2/H20850+/H9280MI2T0,I+/H9280RP2T0,P
+UR/H208533/H9280kR2n−/H9268+2/H20849/H9280MI2+/H9280RP2/H20850n−/H9268/H20854+UR2/H20853/H208492
+n−/H9268/H20850/H9280kRn−/H9268+n−/H9268/H208491−n−/H9268/H20850B−/H9268/H20854+UR3n−/H9268.
/H20849A6/H20850
The moments of the transport self-energy /H9004kR/H9268r/H20849E/H20850can be
derived in the same way. One gets
DkR/H9268/H208490/H20850=0 , /H20849A7/H20850
DkR/H9268/H208491/H20850=/H9280MI2+/H9280RP2, /H20849A8/H20850
DkR/H9268/H208492/H20850=/H9280MI2T0,I+/H9280RP2T0,P. /H20849A9/H20850
The band correction B−/H9268is given by
n−/H9268/H208491−n−/H9268/H20850/H20849B−/H9268−T0,R/H20850
=1
N/H20858
iRjR/H20849TiRjR−T0,R/H20850/H20855ciR−/H9268+cjR−/H9268/H208492nˆiR/H9268−1/H20850/H20856
+1
N/H20858
X=I,P/H20858
iRiXTiXiR/H20855diX−/H9268+ciR−/H9268/H208492nˆiR/H9268−1/H20850/H20856,/H20849A10 /H20850
where TiRjRis the hopping integral between lattice sites RiRandRjR. The two higher correlation functions can be reduced
to single-particle lesser Green’s functions.17We find
/H20855diX−/H9268+ciR−/H9268nˆiR/H9268/H20856=i
2/H9266NU R/H20858
kRkX/H20885
−/H11009/H11009
dEei/H20849kR·RiR−kX·RiX/H20850
/H11003/H20853/H20851−E+/H9280kR+/H9004kR−/H9268r/H20849E/H20850/H20852·GkRkX−/H9268/H11021/H20849E/H20850
+/H9004kR−/H9268/H11021/H20849E/H20850GkRkX−/H9268a/H20849E/H20850/H20854 /H20849 A11 /H20850
and
/H20855ciR−/H9268+cjR−/H9268nˆiR/H9268/H20856=−i
2/H9266NU R/H20858
kReikR·/H20849RjR−RiR/H20850
/H11003/H20885
−/H11009/H11009
dE/H9018kR−/H9268r/H20849E/H20850GkR−/H9268/H11021/H20849E/H20850./H20849A12 /H20850
The nondiagonal lesser Green’s function GkRkX/H9268/H11021/H20849E/H20850=i/H20855dkX/H9268+ckR/H9268/H20856is closely related to the right Green’s function
and the transport self-energy
/H20858
X=I,P/H20858
kXGkRkX/H9268/H11021/H9280XR=GkR/H9268r/H9004kR/H9268/H11021+GkR/H9268/H11021/H9004kR/H9268a./H20849A13 /H20850
Putting all these expressions into the band correction leads to
the result in Eq. /H208498/H20850.
The Dyson equation of the right ferromagnet reads
EGkR/H9268r/H20849E/H20850=1+ /H20851/H9280kR+/H9018kR/H9268r/H20849E/H20850+/H9004kR/H9268r/H20849E/H20850/H20852GkR/H9268r/H20849E/H20850.
/H20849A14 /H20850
Inserting the high-energy expansion for both self-energies
and the Green’s function
GkR/H9268r/H20849E/H20850=/H20858
n=0/H11009MkR/H9268/H20849n/H20850
En+1, /H20849A15 /H20850
/H9004kR/H9268r/H20849E/H20850=/H20858
m=0/H11009DkR/H9268/H20849m/H20850
Em, /H20849A16 /H20850
/H9018kR/H9268r/H20849E/H20850=/H20858
m=0/H11009CkR/H9268/H20849m/H20850
Em, /H20849A17 /H20850
yields a system of equations for the unknown moments CkR/H9268/H20849m/H20850
of the interaction self-energy. It can be solved by sorting
according to the order of 1 /Eand the use of the moments
given earlier in this appendix. The results are quite simple
CkR/H9268/H208490/H20850=URn−/H9268, /H20849A18 /H20850
CkR/H9268/H208491/H20850=UR2n−/H9268/H208491−n−/H9268/H20850, /H20849A19 /H20850
CkR/H9268/H208492/H20850=UR2n−/H9268/H208491−n−/H9268/H20850B−/H9268+UR3n−/H9268/H208491−n−/H9268/H208502./H20849A20 /H20850
These expressions are formally identical to the equilibrium
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17For high energies it is acceptable to neglect higher
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/H9018kR/H9268/H20849E/H20850/H11015CkR/H9268/H208490/H20850+CkR/H9268/H208491/H20850
E+CkR/H9268/H208492/H20850
E2/H11015CkR/H9268/H208490/H20850+CkR/H9268/H208491/H20850
E−CkR/H9268/H208492/H20850
CkR/H9268/H208491/H20850
=URn−/H9268E−T0,R−B−/H9268
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184423-6 |
PhysRevB.91.195203.pdf | PHYSICAL REVIEW B 91, 195203 (2015)
Manipulating femtosecond spin-orbit torques with laser pulse sequences to control magnetic
memory states and ringing
P. C. Lingos,1J. Wang,2and I. E. Perakis1,3,*
1Department of Physics, University of Crete, Box 2208, Heraklion, Crete, 71003, Greece
2Ames Laboratory and Department of Physics and Astronomy, Iowa State University, Ames, Iowa 50010, USA
3Institute of Electronic Structure and Laser, Foundation for Research and Technology-Hellas, Heraklion, Crete, 71110, Greece
(Received 24 November 2014; revised manuscript received 21 April 2015; published 19 May 2015)
Femtosecond (fs) coherent control of collective order parameters is important for nonequilibrium phase
dynamics in correlated materials. Here, we propose such control of ferromagnetic order based on usingnonadiabatic optical manipulation of electron-hole ( e-h) photoexcitations to create fs carrier-spin pulses with
controllable direction and time profile. These spin pulses are generated due to the time-reversal symmetrybreaking arising from nonperturbative spin-orbit and magnetic exchange couplings of coherent photocarriers. Bytuning the nonthermal populations of exchange-split, spin-orbit-coupled semiconductor band states, we can excitefs spin-orbit torques that control complex magnetization pathways between multiple magnetic memory states. We
calculate the laser-induced fs magnetic anisotropy in the time domain by using density matrix equations of motionrather than the quasiequilibrium free energy. By comparing to pump-probe experiments, we identify a “sudden”out-of-plane magnetization canting displaying fs magnetic hysteresis, which agrees with switchings measuredby the static Hall magnetoresistivity. This fs transverse spin-canting switches direction with magnetic state andlaser frequency, which distinguishes it from the longitudinal nonlinear optical and demagnetization effects. Wepropose that sequences of clockwise or counterclockwise fs spin-orbit torques, photoexcited by shaping two-colorlaser-pulse sequences analogous to multidimensional nuclear magnetic resonance (NMR) spectroscopy, can beused to timely suppress or enhance magnetic ringing and switching rotation in magnetic memories.
DOI: 10.1103/PhysRevB.91.195203 PACS number(s): 78 .47.J−,75.50.Pp,75.30.Hx,75.78.Jp
I. INTRODUCTION
Femtosecond (fs) control of switching between condensed
matter states [ 1–4] may address challenges posed by multi-
functional devices used for information storage and processingon a single chip at up to thousand times faster terahertzspeeds. One of the main obstacles for widespread use of
magnetic materials in such applications is the lack of efficient
control of magnetization. Fast spin manipulation is one of themain challenges for spin electronics, spin photonics, magneticstorage, and quantum computation [ 5]. To meet this challenge,
different magnetic systems must be explored. In diversesystems ranging from ferromagnetic semiconductors [ 6–8]
to doped topological insulators [ 9,10], magnetic effects arise
from exchange interactions ( ∝S·s) between two distinct
subsystems: mobile, spin-orbit-coupled electron spins s, and
magnetic local moments S[11]. These interactions couple, for
example, magnetic impurity spins with Dirac fermions in topo-logical insulators [ 9] or valence-band holes in (III,Mn)V semi-
conductors [ 6]. Such couplings break time-reversal symmetry
and result in ferromagnetic states with two distinct but stronglycoupled collective-spin order parameter components [ 6,9].
When brought out of thermodynamic equilibrium, interacting
mobile and local collective spins allow more “knobs” for
manipulating ultrafast magnetism [ 12] by using fs laser pulses.
As is known, in both semiconductors [ 13–17] and met-
als [18–20], depending on the time scale, a distinction must be
made between e-hquantum excitations, nonthermal eandh
populations, and Fermi-Dirac populations [see the schematicin Fig. 1(a)]. Initially, only coherent e-hpairs are photoexcited
*Corresponding author: ilias@physics.uoc.gr[left part of Fig. 1(a)], which dephase within a time interval
T2.F o r T2shorter than the laser pulse duration, this e-h
coherence is only important for determining the photoexcited e
andhpopulations. The contribution of such nonthermal (i.e.,
non-Fermi-Dirac) carrier populations to the spin and chargedynamics must be taken into account when their relaxationtimesT
1are not too short compared to the ∼100 fs time scales
of interest [ 18]. Nonthermal population effects are observable
in semiconductors [ 13,14] and metals [ 18–20]. Recent pump-
probe measurements [ 21] also identified a fs nonthermal hole
spin relaxation in (Ga,Mn)As ferromagnetic semiconductors.This temporal regime lasts for 160–200 fs and diminishes withincreasing temperature, together with the ferromagnetic order.It precedes a picosecond (ps) hole energy relaxation, whichoccurs on a time scale of 1–2 ps and is not very sensitive to tem-perature. The above experimental observations [ 21] indicate
that the photohole populations redistribute between band stateswith different spin polarizations during T
1∼100 fs prior to
relaxation into hot Fermi-Dirac distributions [Fig. 1(a)].
While the quantum kinetics of charge photoexcitations has
been studied [ 13,18], fs nonadiabatic magnetic correlation is
not well-understood [ 1,3,4,22]. Collective spin dynamics is
triggered when coupled magnetic order parameter components
are “suddenly” brought out of equilibrium via laser excitation.
The relative contributions of spins due to coherent, nonthermal,and hot thermal (Fermi-Dirac) carrier populations, whichinteract with local magnetic moments, [ 1,3,4] depend on
laser intensity and frequency, relaxation parameters, materialproperties, and probed time scales. Sequences of fs laser pulsesanalogous to multidimensional NMR spectroscopy [ 15,23,24]
offer possibilities for clarifying and controlling such transient
magnetic responses. Here, we show that coherent optical
1098-0121/2015/91(19)/195203(20) 195203-1 ©2015 American Physical SocietyP. C. LINGOS, J. W ANG, AND I. E. PERAKIS PHYSICAL REVIEW B 91, 195203 (2015)
FIG. 1. (Color online) (a) Schematic of two contributions to
the transient magnetic anisotropy: e-hexcitations (nonthermal and
coherent carrier contribution, left) and Fermi sea holes (thermalcontribution, right). For /planckover2pi1ω
p∼3.1 eV, the holes are excited in
high-k, nonparabolic, HH or LH exchange-split valence band states.
(b) The thermal hole Fermi sea free energy gives four in-planemagnetic memory states X
+,Y+,X−,a n dY−, slightly tilted from
the corresponding crystallographic axes.
control of nonequilibrium mobile carrier spin induced by
laser excitation of a nonthermal population imbalance can
be used to suppress or start magnetization ringing andswitching rotation by exerting fs spin-orbit torque sequences
in controlled directions. We propose that such a nonadiabaticoptical approach may allow control of magnetic stateswithout relying on magnetic field pulses, circularly-polarizedlight [ 17,25,26], demagnetization [ 8,27–29], quasithermal
processes [ 2,30–33], or the precession phase [ 34].
The fs photoexcitation of (Ga,Mn)As has revealed different
transient magneto-optical responses, such as ultrafast increase(decrease) of magnetization amplitude under weak (strong)excitation [ 8,28,29,35] and magnetization reorientation due
to spin torque [ 17,26] and spin-orbit torque [ 3,36,37]. There
is mounting evidence that nonthermal magnetic processesplay an important role in the fs magnetization time evolu-tion [ 3,17,36,37]. (III,Mn)V heterostructures are advantageous
for optical control of magnetic order due to their well-characterized optical and electronic properties and their ma-nipulable carrier-induced ferromagnetism. Useful for demon-strating our theoretical predictions is that these systems havefour different in-plane magnetic states ( X
+,Y+,X−, andY−),
due to biaxial magnetic anisotropy between the [100] and [010]crystallographic axes [see Fig. 1(b) and Appendix A]. While
in conventional ferromagnets switching involves spin-flippingbetween two magnetic states (spin-up/spin-down, uniaxialmagnetic anisotropy), the existence of four magnetic statesallows for complex multistate switching pathways and moreelaborate magnetization control schemes. Four-state magneticmemories may be useful for ultrahigh-density magneticrecording applications, as the two equivalent easy axes doublethe recording density by recording two bits of information onthe same spot [ 38]. To take advantage of such multistate mag-
netic memories for ultrafast spintronics applications, we mustbe able to selectively access all magnetic states in any desiredsequence. There is no generally accepted scheme on how to dothis. Optical spin manipulation has, however, reached a highlevel of sophistication [ 3,8,17,25,33,34,36,38–42] and control
of magnetization on a 100-ps time scale has been demonstratedin various systems, by using magnetic field or laser-generatedmagnetic pulses [ 43–45] or photoinduced effects [ 2,46]. Two
outstanding challenges must, nevertheless, be better addressed:(i) how to initiate and stop controlled deterministic switchings
during fs time intervals and (ii) how to suppress the magneticringing associated with switchings, which limits the prospectsfor high-speed applications [ 47]. Similar challenges also
apply to conventional uniaxial magnetic memories. From amore general perspective, the nonthermal dynamical disen-tanglement, during coherent nonlinear optical excitation, ofdegrees of freedom that are strong-coupled in equilibrium,such as the mobile photocarrier and localized collectivespins here, may lead to a better understanding of correlatedsystems [ 1,4,48,49]. The advantage of using spin-charge
quantum kinetics to overcome the limitations of incoherentprocesses for meeting the above challenges is now beginningto be recognized [ 1,3,4,17,41,42,50,51].
This work contributes to the debate of how fs coherent pho-
toexcitation could drive and control ultrafast switchings [ 1,12]
and magnetic ringing [ 47]. We consider the very early
nonthermal and coherent temporal regimes and focus mostlyon magnetization changes that occur during the fs laser pulse
and are triggered by the photoexcited carriers. We show that bychoosing appropriate sequences of time-delayed laser pulses,we can control the direction, magnitude, and time-profile of theshort-lived nonthermal photocarrier spin. The latter drives themagnetization away from equilibrium by exerting fs spin-orbittorque on the collective local spin. By coherent manipulationof the e-hphotoexcitations, we photogenerate a controlled
population imbalance between spin-orbit-coupled/exchange-split bands. Such photoexcited band carrier population andspin imbalance is not restricted by the chemical potential ortemperature and leads to a controllable “sudden” magnetiza-tion canting in selected directions at desirable times. Based ondirect manipulation of the above nonthermal processes by theoptical field, we propose possible protocols that drive complex360
◦magnetization pathways, here involving sequential 90◦
deterministic switchings between four different magneticmemory states. Such spin control, as well as suppression ofboth magnetic ringing and switching rotations, are possiblewithout circularly-polarized light due to relativistic spin-orbitcoupling of the photocarriers leading to spin-orbit torque.
For linearly-polarized fs optical pulses, we show that the
photoexcited carrier spin direction and amplitude is deter-mined by the competition between spin-orbit coupling, withcharacteristic energy /Delta1
so∼340 meV given by the /Gamma1-point
energy splitting of the GaAs spin-orbit-split valence band,and the S·smagnetic exchange coupling, with characteristic
energy /Delta1
pd=βcS∼100 meV in Ga(Mn)As [ 6], where S
andcdenote the Mn spin amplitude and concentration,
respectively, and βis the magnetic exchange constant. The
time-reversal symmetry breaking can be characterized bythe energy ratio /Delta1
pd//Delta1 so[∼1/3 in (Ga,Mn)As]. It leads
to fs photoexcitation of short-lived mobile spin-pulses s,
whose direction is controlled by selectively populating thecontinua of exchange-split heavy-hole (HH) or light-hole(LH) spin-orbit-coupled band states with different spin su-perpositions. We model the fs nonlinear photoexcitationprocesses, driven by sequences of time-delayed laser-pulsetrains, with density matrix equations of motion [ 13], which
describe photocarrier populations coupled nonperturbativelyto interband coherences and time-dependent local spins. Ourtime-domain calculations describe a nonequilibrium magnetic
195203-2MANIPULATING FEMTOSECOND SPIN-ORBIT TORQUES . . . PHYSICAL REVIEW B 91, 195203 (2015)
anisotropy during the laser pulse, which we estimate by
treating strong band nonparabolicity and spin-orbit couplingsusing the tight-binding band structure of GaAs with mean-fieldmagnetic exchange interaction [ 6,52]. We relate the calculated
photoexcitation of fs spin-orbit torque to existing experimentsand make predictions for new ones to observe switchings byusing pulse-shaping.
The paper is organized as follows. In Sec. II, we discuss
the symmetry-breaking processes leading to photoexcitationof a 100-fs mobile carrier spin pulse with direction andmagnitude that depend on the ratio /Delta1
pd//Delta1 so. In Sec. III,
we compare theory and experiment to demonstrate coherentcontrol of fs spin-orbit torque direction and magnitude bytuning populations of four exchange-split HH and LH valencebands excited by a 100-fs laser pulse. We show that thecanting direction of the excited transverse (out-of-plane)fs magnetization component displays a magnetic hysteresisabsent without pump. In experiment, the above fs spincanting can be distinguished from longitudinal amplitude andnonlinear optical effects by sweeping a perpendicular magneticfield. In Sec. IV, we show that we can initiate controlled
switching rotations to any one of the available magnetic statesby shaping a laser-pulse train. In Sec. V, we propose two
protocols for controlling four sequential 90
◦switchings in
clockwise or counterclockwise directions. In Sec. VI,w eu s e
two time-delayed laser-pulse trains to suppress or enhance thenonlinear switching rotation at any intermediate state and tosuppress magnetic ringing at any time, long or short. Ratherthan relying on the magnetization precession phase, we achievethis coherent control by switching the directions of fs spin-orbittorques. We end with conclusions and a broader outlook. In twoappendices, we present the density matrix equations describingnonlinear coherent excitation of fs spin-orbit torque, distin-guish the nonadiabatic/nonthermal from the adiabatic/thermaltransient magnetic anisotropy, and treat the nonparabolic andanisotropic spin-orbit-coupled band continua.
II. FEMTOSECOND SPIN PHOTOEXCITATION
In this section, we discuss the processes leading to pho-
toexcitation of carrier spin with direction determined by non-perturbative symmetry-breaking interactions. In the systemsof interest, the magnetic effects arise from antiferromagneticinteractions between localized and mobile (delocalized) carrierspins [ 6]. In contrast to magnetic insulators studied before [ 25],
the localized electrons do not contribute to the fs magneticanisotropy but mainly determine the magnetization (collective
local spin)
S=1
cV/summationdisplay
i/angbracketleftˆSi/angbracketright, (1)
where Vis the volume and Siare the local magnetic moments
at positions i, with concentration c. For example, in (III,Mn)V
magnetic semiconductors, the local magnetic moments arepureS=5/2 Mn spins with zero angular momentum, L=0,
and no spin-orbit interaction. The magnetic anisotropy comesfrom band electrons, which are clearly distinguished fromthe local spins. Unlike for the localized electrons, theseband electrons are subject to spin-orbit interactions andcouple directly to light. The spin-exchange coupling of suchphotoexcited mobile carriers with the local spins induces the
magnetization dynamics of interest here. The widely-usedmean-field treatment of the magnetic exchange interaction(Zener model) captures the symmetry breaking of interesthere [ 6]. We thus consider the dynamics of a single-domain
macrospin S(t) and neglect spatial fluctuations [ 40,41]. This
approximation describes metallic-like (III,Mn)V magneticsemiconductors [ 6].
Our main goal here is to control the nonequilibrium spin
of band carriers in order to manipulate the magnetizationmotion during fs time scales. While spin-lattice couplingalso affects the easy axis, lattice heating occurs on longer(picosecond) time scales, following energy transfer from theelectronic system [ 33,37]. Unlike previous demagnetization
studies, the optical control scheme proposed here does notrely on population changes due to laser-induced electronicheating [ 8,28,29]. It is based on direct carrier-spin photoexci-
tation without circularly-polarized light. The laser excites e-h
pairs between different exchange-split valence and conductionbands [Fig. 1(a)]. The magnetic exchange interaction of inter-
est mainly involves the photoexcited valence hole collectivespin/Delta1s
h(t). Denoting by sh
knthe contribution from valence
bandnand momentum k, we obtain the total hole spin:
sh(t)=1
V/summationdisplay
k/summationdisplay
nsh
kn(t). (2)
Below, we demonstrate coherent control of sh
kn(t) by exciting
a nonthermal imbalance between different band states ( n,k)
during the laser pulse. We describe this nonthermal populationimbalance by extending the discrete- kcalculation of fs spin-
orbit torque in Ref. [ 3] to include the anisotropic continua of
the nonparabolic (Ga,Mn)As bands. This allows us to estimatethe photocarrier density and net spin of different bands asfunction of laser-pulse frequency and intensity for comparisonto experiment. In addition, here we consider sequences of time-delayed laser-pulse trains. The mechanism of Ref. [ 3] is anal-
ogous to the current-induced spin-orbit torque [ 53] observed
in (Ga,Mn)As [ 54] and other spin-orbit-coupled ferromagnets.
Unlike our earlier work [ 17] on fs spin-transfer torque analo-
gous to the one induced by spin-polarized currents in spintron-ics applications [ 55,56], which requires circularly-polarized
light [ 26], here spin is not conserved due to spin-orbit coupling.
As a result, transfer of angular momentum from the photons isnot necessary for carrier spin excitation. Instead, the photoex-cited spin is determined by symmetry-breaking due to the com-petition between spin-orbit and magnetic exchange couplings.
To initiate ultrafast spin dynamics, we create a short-lived
spin imbalance by optically controlling s
h
kn(t) from different
bands nand Brillouin zone (BZ) directions k. For this,
we express the carrier spin in terms of the density matrix
/angbracketleftˆh†
−knˆh−kn/prime/angbracketrightdefined in terms of an adiabatic basis of band
eigenstates created by the operators ˆh†
−kn:
sh
kn=ˆsh
knn/angbracketleftˆh†
−knˆh−kn/angbracketright+/summationdisplay
n/prime/negationslash=nˆsh
knn/prime/angbracketleftˆh†
−knˆh−kn/prime/angbracketright, (3)
where ˆsh
kn/primenare the spin matrix elements. The latter describe
the direction of the carrier spin for the band states ( n,k).
Such spin dependence is determined by spin-mixing due
195203-3P. C. LINGOS, J. W ANG, AND I. E. PERAKIS PHYSICAL REVIEW B 91, 195203 (2015)
to the nonperturbative interplay of spin-orbit and magnetic
exchange couplings, which is characterized by the energy ratio/Delta1
pd//Delta1 so. The first term on the right-hand side (rhs) of Eq. ( 3)
describes the population contribution (coherent, nonthermal,and quasithermal transient populations). The second termdescribes a contribution due to coupling of different bands(intervalence-band coherence). The latter Raman coherencearises when spin is not conserved, ˆs
h
knn/prime/negationslash=0, and vanishes in
equilibrium. We choose as basis ˆh†
−knthe eigenstates of the
adiabatic Hamiltonian (Appendix A)
Hb(S)=H0+Hso+Hpd(S0). (4)
H0+Hsodescribes the band structure of the parent material
(undoped GaAs here), due to the periodic lattice potential ( H0)
and the spin-orbit coupling ( Hso)[52]. The symmetry-breaking
is induced by the magnetic exchange interaction Hpd(S0),
Eq. ( A1)[6]. Here, S0denotes the slowly-varying contribution
to the local macrospin that switches or oscillates during pstime scales (adiabatic contribution). The valence hole and
conduction electron basis states, ˆh†
−knand ˆe†
kmrespectively,
were obtained by diagonalizing Hb(S0) using the tight-binding
approximation of Ref. [ 52] (Appendix A).
In (III,Mn)V semiconductors, a thermal hole Fermi sea
bath, characterized by the Fermi-Dirac distribution fnk,i s
already present in the ground state [Fig. 1(a)][6]. Similar
to ultrafast studies of the electron gas in metals [ 18] and
semiconductors [ 57–59], we distinguish this quasiequilibrium
contribution to Eq. ( 3) from the non-Fermi-Dirac femtosecond
contribution (Appendix A):
/angbracketleftˆh†
knˆhkn/prime/angbracketright=δnn/primefnk+/Delta1/angbracketleftˆh†
knˆhkn/prime/angbracketright. (5)
At quasiequilibrium, only the Fermi-Dirac populations con-
tribute. These are characterized by a temperature and chemicalpotential and give the adiabatic field due to the thermalizedFermi sea (FS) carriers: [ 6,25,37]
γH
FS[S]=−∂Eh(S)
∂S, (6)
where γis the gyromagnetic ratio and
Eh(S)=/summationdisplay
knεv
nkfnk (7)
is the total (free) energy of the relaxed Fermi-Dirac carriers.
The latter defines the magnetic memory states of Fig. 1(b)
(Appendix A).εv
nk(S) are the (valence band) eigenvalues of
the adiabatic Hamiltonian Hbfor frozen local spin S.T h e
laser-induced heating of the Fermi-Dirac hole distibution ( fnk)
is one source of demagnetization [ 28,29], while the subsequent
heating of the lattice is also known to thermally alter themagnetic anisotropy fields during ps time scales [ 32,33]. Since
the changes of this electronic E
hwithSare notoriously small
for numerical calculations of the quasiequilibrium magneticanisotropy [ 37,60], while the low-energy states of (III,Mn)V
systems are complicated by sample-dependent disorder, im-purity bands, defect states, and strain [ 6,28,39,61], here we
approximate E
h(S) by using the symmetry-based Eq. ( A9)
with parameters extracted from experiment [ 6,39,61]. In this
way, we introduce the realistic four-state magnetic memoryof the (III,Mn)V materials. For the low 10–100 μJ/cm
2pumpfluences considered here, we neglect the laser-induced changes
in the Fermi-Dirac distribution temperature and chemicalpotential, which add to the predicted effects on the timescale of energy and population relaxation [ 21]. Calculations
assuming Fermi-Dirac distributions [ 28,37] gave order-of-
magnitude smaller magnetization dynamics than experimentand concluded that the nonequilibrium hole distribution mustbe very broad [ 28]. Here, we study the possible role of
short-lived non-Fermi-Dirac populations, which are observedprior to full electronic thermalization [ 21] (we assume T
1∼
100 fs). We calculate the fs anisotropy due to such nonthermalspin populations in the time domain, by solving the mean-
field equations of motion for /Delta1/angbracketleftˆh†
knˆhkn/prime/angbracketrightderived with time-
dependent Hamiltonian (Appendix A)
H(t)=Hb(S0)+/Delta1H exch(t)+HL(t). (8)
While the adiabatic Hb(S0) changes during 10’s of ps, the other
two contributions to Eq. ( 8) are nonadiabatic and vary during
fs time scales. HL(t), Eq. ( A3), describes the dipole coupling
of the fs laser Efield [ 13], while
/Delta1H exch(t)=1
V/summationdisplay
kβkc/Delta1S(t)ˆsh
k, (9)
where ˆsh
kis the hole spin operator and
/Delta1S(t)=S(t)−S0, (10)
describes the “sudden” changes in magnetization during the fs
photoexcitation. We assume exchange constant βk≈βfor the
relevant range of k.
We describe the non-Fermi-Dirac electronic contribution
/Delta1/angbracketleftˆh†
knˆhkn/prime/angbracketright,E q .( 5), similar to the well-established semicon-
ductor Bloch equation [ 13,62] or local-field [ 16,63] Hartree-
Fock treatments of ultrafast nonlinear optical response. Inparticular, we solve coupled equations of motion for the
electronic populations and interband coherences /angbracketleftˆh†
kmˆhkn/angbracketright,
/angbracketleftˆe†
kmˆekn/angbracketright, and/angbracketleftˆekmˆh−kn/angbracketright, which are nonperturbatively coupled
to the time-dependent local spin S(t). This coupling modifies
the electronic dynamics, which, in turn, modifies the motionofS(t) (Appendix A). To obtain meaningful numerical results
in the case of switching, the basis defined by the adiabaticH
b(S0) is constantly adjusted due to the large changes in
S0during the time evolution. Our equations of motion
describe, in addition, the nonadiabatic effects of /Delta1S(t) on the
time-dependent band states. We consider linearly-polarizedoptical pulses with zero angular momentum. We do not in-clude the carrier-carrier, carrier-phonon, and carrier-impurityinteractions in the Hamiltonian, but treat the photocarrierrelaxation phenomenologically, by introducing e-hdephasing
timesT
2and nonthermal population relaxation times T1.O u r
calculation thus describes the “initial condition” that bringsthe system out of equilibrium and initiates relaxation [ 28,51].
The latter redistributes the nonthermal carriers among bandstates with different spins and momentum directions k, which
leads to spin relaxation. Here, we model this by introducing the
relaxation time T
1of the populations /angbracketleftˆh†
−knˆh−kn/angbracketrightdetermining
the hole spin in Eq. ( 3), which reflects the 100–200-fs hole spin
relaxation time measured experimentally in (Ga,Mn)As [ 21].
The latter was calculated in Ref. [ 51] to be several 10’s of fs.
On the other hand, momentum scattering and carrier relaxation
195203-4MANIPULATING FEMTOSECOND SPIN-ORBIT TORQUES . . . PHYSICAL REVIEW B 91, 195203 (2015)
giveT2’s of few 10’s of fs [ 6,51]. Below we estimate the
dependence of the predicted nonthermal effects on T1andT2.
The calculations in this paper describe photogeneration
of spin that initiates fs dynamics. We describe the averagehole spin /Delta1s
h(t) of e-hpairs excited in band continuum
states determined by the pump laser frequency ωp.T h e
main results were obtained for /planckover2pi1ωp≈3.1e V [ 7,36]. For
such pump frequencies, the (Ga,Mn)As disorder-inducedimpurity/defect states [ 28] do not contribute significantly and
the photoexcited carriers are initially well separated in energyfrom the Fermi sea holes [see Fig. 1(a)]. We mainly excite
HH and LH band states along the eight {111}symmetry
lines of the BZ, at high k, where the conduction and valence
bands are strongly nonparabolic and almost parallel to eachother [ 7]. As a result, a large number of interband optical
transitions are excited simultaneously and a broad continuumof hole band momenta k, inaccessible at quasiequilibrium, is
populated during the laser pulse [see Fig. 1(a)]. Such highly
anisotropic band continua are accounted for here as describedin Appendix B. Magnetic anisotropy arises since, due to the
symmetry-breaking introduced by S(t), the eight photoexcited
{111}directions are not equivalent. The calculated hole spin
matrix elements ˆs
h
knn/prime, which determine the photohole spin
direction, are fairly constant for each given band over a widerange of high k. Optical transitions at /planckover2pi1ω
p≈3.1eV then
add constructively to the hole spin from each of the {111}
directions and enhance its magnitude, which depends on the
total photohole densities1
V/summationtext
k/Delta1/angbracketleftˆh†
−knˆh−kn/angbracketrightfor each band n
assuming a smooth kdependence of the exchange constant
βk. By tuning the pump frequency around 3.1 eV , our goal
is to control, a short-lived imbalance between the populationsof bands with different spin-admixtures. Our present calcu-lations describe /Delta1s
h(t) prior to interband relaxation or large
momentum scattering between different kdirections, which
occur on a time scale T1of spin relaxation. On the other
hand, pump frequencies /planckover2pi1ωp≈1.5e V [ 37] excite smaller
kalong {100},{010},{001},{110},{101},{011}, and
{111}symmetry directions [ 64], as well as impurity/defect
states inside the semiconductor band gap [ 6,28]. Figure 6
shows the quantitative differences between /planckover2pi1ωp≈1.5 eV and
≈3.1e V,which arise from the differences in band structure.
In addition to the difference in closely-lying valence bands,disorder-induced states, and density of states at differentenergies, the kdependence of the spin matrix elements ˆs
h
knn/prime
determining the photoexcited spin is stronger for the small
wave vectors contributing around /planckover2pi1ωp≈1.5e V .
Important for bringing the coupled local and mobile spin
subsystems away from equilibrium is their different dynamics.For example, unlike for the band carriers, there is no spin-orbitor optical coupling of the local spins. In equilibrium, the localand mobile collective spins are correlated in the ferromagneticstate, so that S×H
FS=0[6]. Within the mean-field approx-
imation, S(t) is driven out of this equilibrium configuration
by both quasiequilibrium ( HFS) and nonthermal ( /Delta1sh) carrier
spins according to a Landau-Lifshitz-Gilbert equation:
∂tS=−γS×HFS[S(t)]−βS×/Delta1sh(t)+α
SS×∂tS,(11)
where αcharacterizes the slow local spin precession
damping [ 33]. The longitudinal magnetization amplitude
Δpd__
Δso
1/6
1/3
2/3
5/3
7/33/3[010][010]
_
[100]_[100]
FIG. 2. (Color online) Maximum of anisotropy spin pulse
β/Delta1sh(t), photoexcited by a single 100-fs linearly-polarized laser
pulse, as a function of the energy ratio /Delta1pd//Delta1 sothat characterizes the
time-reversal-symmetry breaking. The direction of the ground-state
magnetization is along the X+easy axis, shown by the black arrow
close to [100]. /planckover2pi1ωp=3.14 eV , E0=7×105V/cm,T1=100 fs,
andT2=50 fs.
changes, due to spin-charge correlations [ 4,28,40,41], are not
captured by this mean-field approximation.
The dynamics of the mobile carrier spins depends, in
addition to magnetic exchange interaction with the local spins,on spin-orbit coupling, direct nonlinear coupling to the opticalfield, and fast carrier relaxation [ 17]:
∂
tsh
k=βcS×sh
k+i/angbracketleftbig/bracketleftbig
Hso,sh
k/bracketrightbig/angbracketrightbig
+Imhk(t)+∂tsh
k/vextendsingle/vextendsingle
rel.(12)
The above equation is not useful here, as it does not distinguish
between different bands in order to treat the spin-orbitcoupling H
so. Nevertheless, it demonstrates four processes
that determine the nonthermal carrier spin. The first termdescribes spin-torque due to magnetic exchange. The secondterm describes spin-orbit torque , obtained here by calculating
the density matrix ( 5). The third term describes the Raman-type
coherent nonlinear optical processes that excite the carrierspin [ 17]:
h
k(t)=2/summationdisplay
mn/angbracketleftˆh−knˆekm/angbracketright/summationdisplay
m/primed∗
kmm/prime(t)·sh
km/primen, (13)
where dkmm/prime=μkmm/prime·Eare the Rabi energies of optical
transitions between band states ( mk) and ( m/primek) and Eis the
laserEfield. The last term describes spin relaxation.
The nonperturbative interplay between spin-orbit and
magnetic exchange couplings determines the direction andmagnitude of the net spin excited by a fs laser pulse. Figure 2
shows a strong dependence of the maximum and directionof the photoexcited hole-spin-pulse β/Delta1s
h(t) on the energy
ratio/Delta1pd//Delta1 so. We obtained this result by solving the coupled
equations of motion of Appendix A. In the ground state, the
magnetization S0points along the X+easy axis (Fig. 2). For
/Delta1pd/lessmuch/Delta1so, the net spin /Delta1shis negligible without circularly-
polarized light, since all symmetric directions in the BZ areexcited equally. With increasing /Delta1
pd, the magnetic exchange
interaction introduces a preferred direction along S(t). This
breaks the time-reversal symmetry of GaAs and results ina net /Delta1s
h(t) while the laser pulse couples to the magnetic
system. With increasing /Delta1pd//Delta1 so,t h i s/Delta1shincreases and its
direction changes. For /Delta1pd//Delta1 so∼1/3 [as in (Ga,Mn)As],
195203-5P. C. LINGOS, J. W ANG, AND I. E. PERAKIS PHYSICAL REVIEW B 91, 195203 (2015)
Fig. 2shows that the in-plane component of the fs anisotropy
fieldβ/Delta1shpoints close to the [ ¯1¯10] diagonal direction for
/planckover2pi1ωp=3.14 eV . As discussed below, this result explains the
experimental observations. The above /Delta1sh(t) only lasts during
the 100-fs laser pulse and drives a “sudden” magnetizationcanting /Delta1S(t) via fs spin-orbit torque. As /Delta1
pdapproaches /Delta1so,
/Delta1shis maximized while it changes direction. The photohole
spin decreases again for /Delta1pd/greatermuch/Delta1so.
III. EXCITING FS SPIN DYNAMICS WITH A SINGLE
PULSE: THEORY VERSUS EXPERIMENT
Ultrafast magneto-optical experiments in (III,Mn)V semi-
conductors have revealed control of magnon oscillationswith frequency /Omega1∼100 ps
−1. In these experiments, the
magnon excitation is suppressed (enhanced) with a laser pulsedelayed by τsuch that /Omega1τ=π(/Omega1τ=2π)[34]. In this
paper, we propose a different optical control scheme, basedon controlling the direction, duration, and magnitude of fsspin-orbit torque sequences photoexcited at any time τ.F i r s t ,
however, we validate our original prediction [ 3] of fs spin-orbit
torque as a source of nonthermal laser-induced spin dynamicsin (III,Mn)V materials. For this, we connect here the numericalresults obtained for anisotropic and nonparabolic band con-tinua with the few existing experiments showing femtosecondnonthermal spin dynamics. In this section, we show that ourcalculations validate the experimental observation in Ref. [ 36]
of fs magnetic hysteresis and spin rotations excited by a single100-fs laser pulse in (Ga,Mn)As. We also show that theyare consistent with the observation of “sudden” nonthermal(subpicosecond) magnetization rotation reported in Ref. [ 37].
The fs temporal regime of nonthermal spin dynamics, which isless understood as compared to the extended ps time scales, ismost relevant for the main purposes of this paper, which are to(i) make numerical predictions of all-optical control of spin ro-tation and magnetic ringing, and (ii) propose complex switch-ing protocols similar to multidimensional NMR, but based onfs laser pulse trains with various timing sequences and colors.
We start by discussing the experimental technique and
(Ga,Mn)As sample used in Ref. [ 36]. We argue that our static
and time-resolved experimental curves and their comparisonwith our theory indicate that the measured magneto-opticalresponse for in-plane ground-state magnetization is dominatedby the transverse out-of-plane magnetization component S
z
and the polar Kerr effect. We performed two-color time-
resolved MOKE spectroscopy in order to better discern thegenuine spin dynamics [ 8,65]. Prior to the relaxation time
T
1, the high-energy nonthermal carriers excited by the 3.1-eV
pump have small effect on the population of the low-energyband states seen by the 1.55-eV probe. By comparing two-color Kerr rotation, ellipticity, and reflectivity pump-probesignals, we distinguish fs magnetization dynamics fromnonlinear optical effects [ 65,66] and identify a fs component
displaying magnetic hysteresis induced by a perpendicularmagnetic field.
Different magneto-optical effects are observed for different
experimental setups. These may be broadly divided based onrotation angles θ
K(S) of the linearly-polarized probe electric
field that are linear (odd) or quadratic (even) functions ofS. Previous linear magneto-optical spectroscopy experimentsin ferromagnetic (Ga,Mn)As observed a giant magnetic linear
dichroism (MLD) signal for probe frequencies between 1.4 and2.4 eV [ 67,68], with quadratic dependence on S. In contrast,
the polar Kerr effect signal [ 65] is linear in the perpendicular
S
z, without contribution from the in-plane spin components.
The relative contribution of these two magneto-optical effectsdepends on the direction of light propagation kand linear
polarization Ewith respect to the magnetization [ 65,67,68].
Below we discuss the details of our experimental design andmeasured quantities.
The main sample studied here was grown by low-
temperature molecular beam epitaxy (MBE) and consists of a73-nm Ga
0.925Mn 0.075As layer on a 10-nm GaAs buffer layer
and a semi-insulating GaAs [100] substrate. The in-planeground-state magnetization points along the X
+easy axis
close to the [100] crystallographic axis [Fig. 1(b)]. For probe
we used a NIR beam tuned at 1.55 eV , which propagatesalong a direction almost perpendicular to the sample plane(∼0.65
◦from the normal). The probe linear polarization is
along [100], almost parallel to the ground-state magnetization.
The pump, on the other hand, was chosen as a UV beam tunedat/planckover2pi1ω
p=3.1 eV and was linearly-polarized at an angle ∼12◦
from [100], with ∼10μJ/cm2peak fluence smaller than in
previous experiments. Its ∼40-nm penetration depth implies
photoexcitation of only the 73-nm-thick magnetic layer. Theduration of the pump and probe pulses was 100 and 130 fs,respectively, while the laser repetition rate was 76 MHz. A de-tailed description of our measurement may be found in section3.1.2 of Ref. [ 65]. We extracted the background-free MOKE
rotation angle θ
Kby measuring the difference between s- and
p-polarized probe light (linear polarization along the [100] and
[010] crystallographic axes, i.e., parallel and perpendicular tothe ground-state magnetization). This is achieved by reflectings-polarized light from the sample surface and then passing it
through a combination of a half wave plate and Wollastonprism. Further technical details of our setup can be found inRef. [ 8]. The chosen design minimizes the MLD contribution
to our measured magneto-optical signals shown in Figs. 3
and4, discussed below. The sweeping of an external magnetic
field B almost perpendicular to the sample and easy axes planeproduced the fs magnetic hysteresis shown in Fig. 3(b).T h i s
laser-induced hysteresis is consistent with the behavior ofthe static Hall magnetoresistance [inset of Fig. 3(a)], which
is known to arise from in-plane magnetization switchingsbetween the four easy axes of Fig. 1(b). However, no magnetic
hysteresis is observed in the linear magneto-optical signalwithout pump for the same experimental conditions [compareFigs. 3(a) and 3(b)]. This result implies that the measured
signal is dominated by S
z(polar Kerr effect) for the linear
polarization direction used here.
As discussed, e.g., in Refs. [ 65,66], a signature of genuine
magnetization dynamics is the complete overlap of thepump-induced transient Kerr rotation /Delta1θ
K/θKand ellipticity
/Delta1ηK/ηKsignals. Indeed, nonlinear optical effects are expected
to contribute differently to /Delta1θKand/Delta1ηK, as determined by
the real and imaginary parts of the pump-induced changes inthe Fresnel coefficients [ 65,66]. In our experiment, /Delta1θ
K/θK≈
/Delta1ηK/ηKthroughout the fs time-scan range of interest [ 36]. We
thus conclude that the measured /Delta1θK/θKprimarily reflects
the pump-induced magnetization /Delta1Sz/S. This claim is further
195203-6MANIPULATING FEMTOSECOND SPIN-ORBIT TORQUES . . . PHYSICAL REVIEW B 91, 195203 (2015)
FIG. 3. (Color online) By sweeping a perpendicular Bfield, tilted
by 5◦from the Zaxis and 33◦from the Xaxis, “up” (red curve)
and “down” (blue curve), we measure the Bdependence of the
magnetization component perpendicular to the sample plane at 5 K
in the polar MOKE geometry (normalized by the ∼4 mrad MOKE
angle). (a) Static measurements (no pump). The coinciding “up” and
“down” polar Kerr rotation angles θKshow no magnetic hysteresis
in the static case. In contrast, the Hall magnetoresistivity (inset)shows 90
◦in-plane magnetization switchings between the XZand
YZplanes, which manifest themselves as a “major” hysteresis loop.
This difference implies that the magneto-optical signal in the presentconfiguration is insensitive to the in-plane magnetization components,
which switch. (b) Time-dependent measurements (pump on). The
pump-induced change /Delta1θ
K/θK≈/Delta1Sz/S, measured at probe time
delay /Delta1t=600 fs for the same experimental conditions as in (a),
shows a magnetic hysteresis similar to the static Hall magnetore-
sistivity. In comparison, the ultrafast differential reflectivity /Delta1R/R
(inset) is up to thousand times smaller, which points to a magnetic
origin of our /Delta1θK/θKsignal.
supported by the simultaneous measurent of a differential
reflectivity signal /Delta1R/R [inset, Fig. 2(b)] that is up to thousand
times smaller than the Kerr rotation and ellipticity signals. Theabove two experimental observations imply that the relativepump-induced change in the Fresnel coefficients, which addsto the magneto-optical response [ 65], is much smaller than
/Delta1S
z/Sin the studied configuration. As discussed below, the
magnetic origin of the measured fs /Delta1θK/θKis further seen
when sweeping an external Bfield slightly tilted from the
perpendicular direction [Fig. 4(a)], which reveals a magnetic
hysteresis absent in the measured linear response.
The interpretation of the static θKin the absence of pump
[Fig. 3(a)] does not suffer from the complexity of interpreting
the fs pump-probe signal. θK(B) switches sign with B
field and saturates for |B|>250 mT. It coincides between
“up” and “down” sweeps (no magnetic hysteresis). In sharpcontrast, for the same experimental conditions, the static Hallmagnetoresistivity ρ
Hallshows in-plane magnetic switchings
(planar Hall effect), which manifest themselves as jumps in thefour-state magnetic memory hysteresis (inset of Fig. 3). Since
FIG. 4. (Color online) Magneto-optical pump-probe experimen-
tal measurements showing development of laser-induced magnetiza-
tion canting /Delta1Sz(t) within ∼100 fs. This fs canting displays magnetic
hysteresis and switches direction when switching in-plane magneticstate. (a) We sweep a perpendicular Bfield, applied at a small angle
∼5
◦from the [001] axis. This Bfield tilts the B=0 in-plane easy axes
(X±
0andY±
0) out of the plane (Appendix A). (b)–(f): the “sudden”
out-of-plane magnetization tilt /Delta1Sz/S, induced by a 100 fs laser
pulse with fluence ∼7μJ/cm2, switches direction when sweeping
theBfield between B=− 1 and 1 T. The two sweeping directions
correspond to increasing (“up”) and decreasing (“down”) Bfield. For
each of the measured B=1, 0.2, 0, −0.2, and −1 T, the fs temporal
profiles of /Delta1Sz/Sdepend on the equilibrium magnetic state switched
byB.
the measured static magneto-optical signals show no signature
of the above in-plane magnetization switchings between theXZandYZplanes, they are dominated by the polar MOKE
Kerr effect that is proportional to S
zand thus insensitive to
the in-plane magnetization [ 65,67]. In contrast, MLD [ 67]
is a second-order effect and includes contributions such asS
xSythat are sensitive to the in-plane magnetization switching.
Their absence in Fig. 3(a) implies that MLD is not the main
origin of our measured magneto-optical signal, which thus isdominated by the polar Kerr effect and S
z(B). Furthermore, the
probe photon energy (1.55 eV) that we chose gives a MOKEangle of 4 mrad at 5 K. This value is very close to the maximumMOKE angle quoted in the literature and few times largerthan the typical MLD angles observed in (Ga,Mn)As samples.To understand why the polar Kerr effect dominates overMLD in our experimental set-up, we recall that two differentgeometries are used to measure magneto-optical signals:(i) probe linear polarization along [100], almost parallel tothe ground-state magnetization. This is the case here and, asdiscussed, e.g., in Ref. [ 68], only minimal MLD is expected.
(ii) The probe linear polarization is close to the [110] directionas in Ref. [ 68]. In this case, one measures a mixed signal with
both MLD and polar MOKE contributions [ 67]. While MLD
dominates in (Ga,Mn)As when the probe is polarized alongthe [110] or [1 −10] directions [ 67,68], i.e., at ∼45
◦degrees
with respect to the easy axis, our data here was obtained forprobe polarization along [100] or [010].
Unlike previous experiments that measured the dynamics
of (III,Mn)V ferromagnets on a ps time scale, Fig. 4shows
directly the ∼100 fs temporal profile of the pump-probe
195203-7P. C. LINGOS, J. W ANG, AND I. E. PERAKIS PHYSICAL REVIEW B 91, 195203 (2015)
magneto-optical signal as a function of perpendicular Bfield.
The pump optical field, with amplitude E0∼2×105V/cm
and fluence ∼7μJ/cm2, excites a total photohole density of
n∼6×1018cm−3, a small perturbation of the 3 ×1020cm−3
ground-state hole density in our (Ga,Mn)As sample. As seen
in Fig. 3, our experimental setup measures the transverse
magnetization component /Delta1Sz(t), which is perpendicular to
the ground-state magnetization. During fs time scales, Fig. 4
shows a systematic B-field dependence and sign-switching
of/Delta1θKthat is absent in θKwithout pump. This behavior
correlates with the magnetic switchings observed in the statictransverse Hall magnetoresistivity and demonstrates that thepump-induced out-of-plane magnetization component /Delta1S
z(t)
switches direction when the in-plane magnetic state switches.Furthermore, the steplike temporal profile of /Delta1θ
K/θK≈
/Delta1Sz/Sindicates that such spin reorientation completes during
the laser pulse and is therefore driven by e-hphotoexcitation.
This fs time dependence is clearly distinguished from subse-quent magnon oscillations during ∼100 ps times [ 21].
We now relate our theory to the observed dependence of
/Delta1θ
K/θKwith∼100-fs duration on the transverse magnetic
fieldBof Fig. 4(a).F o rB=0, the magnetic states X±
0and
Y±
0lie inside the plane [Fig. 1(b)]. ForB/negationslash=0, Eq. ( A11)g i v e s
an out-of-plane canting of X±andY±easy axes [Fig. 4(a)].
The measured smooth change of static Kerr rotation angle θK
as function of Bfield reflects such canting without magnetic
hysteresis. As shown by our calculation below, while Szvaries
smoothly with increasing or decreasing Bfield, when the
magnetization switches between X±andY±the direction of
pump-induced fs component /Delta1Szreverses. The above depen-
dence of pump-induced magnetization reversal on the easy axiscannot be explained by conventional nonlinear optical effectsor magnetization amplitude longitudinal changes [ 8,27–29].
When the latter dominate, X
+(X−)g i v et h e same/Delta1Szas
Y+(Y−), as the two in-plane magnetic states are equivalent
(symmetric) with respect to the probe propagation directionperpendicular to the X-Yplane. Figure 4(d) (B=0) and
Figs. 4(c) and4(e) (B=± 0.2T) clearly show that this is not
the case in the experiment. In sharp contrast, for B=± 1T ,
Figs. 4(b) and4(f)show the same fs changes for both increasing
and decreasing B. The fs response is independent of the easy
axis for large B, which aligns the magnetization along [001].
Our calculations show that the fs magnetization reorientationdue to fs spin-orbit torque diminishes with increasing perpen-dicular B, consistent with the above behavior.
ForB=0, Fig. 4(d) reveals a symmetric and opposite
out-of-plane fs canting /Delta1S
z(t) between the X0andY0initial
states. In this case, the initial magnetization S0lies inside
the sample plane [Fig. 4(a)] and thus the observed /Delta1Sz(t)
cannot be associated with an amplitude change, as it occurs ina direction [001] perpendicular to S
0.F o rl a r g e B, on the other
hand, the magnetization aligns with the Bfield along [001],
Sz≈S, and thus /Delta1Sz(t) primarily reflects longitudinal fs
changes in magnetization amplitude [ 28,41]. When Sz≈0, as
forB=0,/Delta1Sz(t) reflects transverse changes in magnetization
direction. We conclude that the observation of opposite signof laser-induced fs /Delta1S
z(t) between the X±
0andY±
0states
[Fig. 4(d)] can only arise from fs magnetization rotation
towards opposite out-of-plane directions. Except for this signdifference, the fs temporal profiles of /Delta1S
z/Sin Fig. 4(d) are-0.5 0 0.5 1
t (ps)-0.004-0.00200.0020.004ΔSz/|S| ωp=3.02eV
ωp=3.14eV
-0.5 0 0.5 1
t (ps)-0.3-0.2-0.100.1βΔs[110] (Tesla)
ωp=3.02eV
ωp=3.14eV
-0.5 0 0.5 1
t (ps)012341018 (carriers/cm3) LH-
LH+
HH-
HH+
-0.5 0 0.5 1
t (ps)0123451018 (carriers/cm3) LH-
LH+
HH-
HH+
ωp=3.02eV ωp=3.14eV(a) (b)
(c) (d)
FIG. 5. (Color online) Frequency dependence of local and mo-
bile spin dynamics and photohole populations following excitation
by a 100-fs linearly-polarized laser pulse with low pump fluence∼10μJ/cm
2, with initial magnetization along the X+easy axis.
(a) Comparison of “sudden” out-of-plane magnetization for /planckover2pi1ωp=
3.14 eV (LH optical transitions) and /planckover2pi1ωp=3.02 eV (HH optical
transitions). (b) Comparison of nonadiabatic photoexcited hole spin
component along [110] for the two above frequencies. (c) Photoex-
cited nonthermal hole total populations of the four exchange-split HHand LH bands for /planckover2pi1ω
p=3.02 eV . (d) Same as (c) for /planckover2pi1ωp=3.14 eV .
symmetric between X0andY0. This symmetry implies that
the out-of-plane /Delta1Szis driven by a laser-induced anisotropy
field pulse that points close to the diagonal direction betweenX
0andY0. The steplike temporal profile implies that this field
has∼100 fs duration. The above experimental observations
are consistent with the direction and duration of the calculated/Delta1s
h, shown in Fig. 2for anisotropy parameter /Delta1pd//Delta1 so∼1/3
as in (Ga,Mn)As. Such carrier-spin-pulse, discussed furtherbelow, exerts a fs spin-torque ∝/Delta1s
h×S0, whose out-of-plane
direction changes sign for S0alongX0orY0, while its magni-
tude remains the same. Note here that, although laser-inducedthermal effects due to spin-lattice coupling can also changethe equilibrium easy axis, such changes occur gradually intime, over many picoseconds [ 33,37]. In contrast, here we
observe steplike magnetization changes that follow the 100fslaser pulse and are consistent with our predicted fs spin-orbittorque. Note also that the experiment may show, in additionto the predicted magnetic contribution, “coherent antifacts”that appear, e.g., as a small “overshoot” at the very beginingof Fig. 4(d). Such details do not change our conclusion about
laser-induced spin canting during the 100-fs pulse.
To compare our theory to Fig. 4, we first consider B=0 and
show in Fig. 5the calculated spin and charge dynamics for a
single linearly-polarized 100-fs pump laser pulse with electricfield amplitude E
0=2×105V/cm similar to the experiment.
We compare the spin and charge population dynamics for twodifferent laser frequencies, /planckover2pi1ω
p=3.02 and 3.14 eV , tuned to
excite different HH and LH band continua. In Fig. 5(a),w e
show the development in time of the optically induced out-of-plane local spin component /Delta1S
z(t). The calculated steplike fs
temporal profile and magnitude for T1=100 fs agrees with
Fig. 4. Furthermore, we observe a reversal in the direction
of/Delta1Szwhen tuning the photoexcitation frequency. The fs
195203-8MANIPULATING FEMTOSECOND SPIN-ORBIT TORQUES . . . PHYSICAL REVIEW B 91, 195203 (2015)
-0,4 -0,2 0 0,2 0,4
Bz (Tesla )-4-2024ΔSz/|S| (10-3) X+
Y+
X-
Y-
1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2
ωp (eV)-1-0.500.51ΔSz/|S| (10-4)
2.7 2.8 2.9 3.0 3.1 3.2 3.3
ωp (eV)-8-6-4-202468ΔSz/|S| (10-3)all
HH +
HH -
LH +
LH -(a)(b) (c)
ωp=3.14eV
t=500fst=1ps t=1ps
FIG. 6. (Color online) Calculated fs magnetic hysteresis and frequency dependence of the laser-induced magnetization canting /Delta1Sz/S
due to fs spin-orbit torque. (a) The direction of out-of-plane component /Delta1Sz/Satt=500 fs depends on easy axis and magnetic field. This
fs magnetic hysteresis diminishes with increasing perpendicular Bfield, which suppresses laser-induced magnetization reorientation, and
separates “transverse” from “longitudinal” contributions to spin dynamics. (b) and (c) Frequency dependence of the laser-induced /Delta1Sz/S
and its individual contributions from the four exchange-split HH and LH bands, calculated at t=1p sf o r E0=2×105V/cm. We compare
between /planckover2pi1ωp∼1.5( b )a n d ∼3 eV (c). Spin-canting at the former frequency is smaller by factor of 10 due to the differences in band structure.
The band continua significantly affect the frequency dependence of /Delta1Sz(t) as compared to discrete- kspecial point calculations.
spin-orbit torque leading to such /Delta1Sz(t) is exerted by the
photohole spin-pulse /Delta1sh(t), whose component along the
diagonal [110] direction is shown in Fig. 5(b) for the two
above frequencies. The magnitude, direction, and temporalprofile of both local and mobile spin components shownin Figs. 5(a) and 5(b) are consistent with the experimental
results of Fig. 4(d). Important for controlling the four-state
magnetic memory is that we are able to reverse the directionof the out-of-plane magnetization tilt /Delta1S
z,F i g . 5(a), and
photoexcited hole spin-pulse, Fig. 5(b), by exciting e-HH
(/planckover2pi1ωp=3.02 eV) or e-LH ( /planckover2pi1ωp=3.14 eV) optical transitions.
The origin of this spin-reversal can be seen by comparing the
total populations1
V/summationtext
k/Delta1/angbracketleftˆh†
−knˆh−kn/angbracketrightfor the four different
exchange-split HH and LH valence bands nin all {111}k
directions. These band-resolved total populations are shown inFigs. 5(c) and5(d) as function of time for T
1=100 fs, which is
comparable to the measured [ 21] and calculated [ 51] hole spin
relaxation time. More than one bands are populated simulta-neously due to the energy dispersion and laser-pulse-width.With frequency tuning, we control a short-lived imbalancebetween these exchange-split bands with different spin-orbitcouplings and spin admixtures. In this way, we coherentlycontrol the superposition of spin- ↑and spin- ↓states prior to
spin relaxation, here mostly during the 100 fs pulse.
The order of magnitude of the photocarrier densities
calculated by including the band continua along all eight{111}kdirections using the GaAs tight-binding parameters
of Ref. [ 52] (Appendix B) agrees with the experimentally
measured density, n∼6×10
18/cm3, for the same pump
fluence. For such photohole populations, we also obtain /Delta1Sz/S
with the same order of magnitude and direction as in the exper-iment [compare Figs. 5(a) and4(d)]. The calculated ∼250 mT
component of β/Delta1s
h(t) along [110], Fig. 5(b), agrees with
the 100-fs magnetic anisotropy field extracted from Fig. 4(d)
and is larger than typical fields obtained from calculationsthat assume a nonequilibrium Fermi-Dirac distribution [ 37].
This theory-experiment agreement indicates that nonthermalpopulations with lifetimes T
1=100 fs comparable to the hole
spin lifetimes in (Ga,Mn)As [ 21,51] can explain the observed
impulsive /Delta1Sz(t).
Further evidence in support of our proposed fs spin-orbit
torque mechanism is obtained from the pump-induced fsmagnetic hysteresis observed in the experiment of Fig. 4.I n
Fig. 6(a), we compare the out-of-plane spin canting /Delta1Sz/S
calculated at t=500 fs, as function of Bfield pointing along
the perpendicular [001] direction for the four B-dependent
equilibrium magnetic states X±andY±. Figure 6(a) shows that
switching between the XandYinitial magnetic states switches
the sign of pump-induced /Delta1Sz(t) (fs magnetic hysteresis).
Furthermore, Fig. 6(a) shows that fs magnetization reorien-
tation diminishes with increasing B. The above results are
consistent with Fig. 4and explain the observed coincidence of
/Delta1Szswitchings with static planar Hall effect switchings [ 36],
as well as the absence of fs hysteresis at high B.W h i l e
nonlinear effects such as dichroic bleaching also contribute tothe fs magneto-optical signal, the observed systematic B-field
dependence and magnetic hysteresis in the sign of /Delta1θ
K/θK
indicate a nonadiabatic physical origin that is consistent with
our calculations of fs spin-orbit torque.
For high Bfields, the magneto-optical signal comes only
from longitudinal changes in the magnetization amplitude [ 29]
and from nonlinear optical effects [Figs. 4(b) and 4(f)]. The
mean-field density matrix factorization used here does notcapture magnetization amplitude changes, which appear atthe level of electron-magnon spatial correlations [ 40,41].
As discussed in Ref. [ 28], any photoinduced imbalance of
spin-↑and spin- ↓states will lead to fs demagnetization and
inverse Overhauser effect, which, however, is independent ofeasy axis direction. While such imbalance may arise fromphotoinduced changes in the Fermi-Dirac temperature andchemical potential, a large electronic temperature increaseis required to produce the broad distributions implied bythe magnitude of the experimentally observed effects [ 28].
The broad nonthermal populations photoexcited here createa fs charge imbalance that, for T
1/lessorequalslant100 fs, follows the laser
pulse and also contributes to demagnetization. Both “longi-tudinal” (demagnetization) and “transverse” (reorientation) fsspin dynamics arise from the competition of spin-orbit andmagnetic-exchange interactions described here. However, theymanifest themselves differently for different photoexcitationconditions and external magnetic fields. For example, fsdemagnetization (decrease in Mn spin amplitude) throughdynamical polarization of longitudinal hole spins dominatesfor high fluences of 100s of μJ/cm
2[21]. By using pulse
195203-9P. C. LINGOS, J. W ANG, AND I. E. PERAKIS PHYSICAL REVIEW B 91, 195203 (2015)
trains, we may achieve spin rotational switching with lower
pump intensities, which reduces the fs demagnetization.
As already shown in Fig. 5, by coherently controlling the
nonthermal population imbalance between the four exchange-split HH and LH bands, we can control the direction ofout-of-plane /Delta1S
z/S. This is seen more clearly in Figs. 6(b)
and 6(c), which show the frequency-dependence of /Delta1Sz/S
and compare its individual contributions obtained by retainingone valence band at a time. The nonequilibrium population ofband states with different spin admixtures leads to differentdirections of laser-induced spin-canting /Delta1S
z(t), which allows
for magnetization control via pump frequency tuning. Forexample, photoholes excited in the two exchange-split (HHor LH) valence bands may induce opposite out-of-plane tilts.The finite pulse-duration and nonparabolic band dispersion[Appendix Band Fig. 1(a)] lead to different populations of
more than one bands and BZ directions at all frequencies. Asalready discussed, such populations and spin-orbit interactionsdiffer between /planckover2pi1ω
p∼1.5 and∼3 eV due to the difference in
band structure. As seen by comparing Figs. 6(b) and 6(c),
the band structure close to the Fermi level, where all {100},
{110}, and {111}symmetry directions are populated, leads to
order of magnitude smaller /Delta1Sz/Sas compared to the high- k
bands along {111}excited for /planckover2pi1ωp∼3 eV . This theoretical
result is consistent with the difference in order of magnitudeof photoexcited spin and populations observed experimentallybetween the two above frequencies [ 36,37]. We conclude
that optical control of the photoexcited carrier populationscan be used to switch the directions of photoexcited fsspin-orbit torques and, in this way, control the direction offs magnetization canting at different laser frequencies.
The precise magnitude of the proposed effects depends on
the relaxation time scales. The nonthermal populations are cre-ated during the 100-fs laser pulse via e-hoptical polarization.
Following dephasing after T
2, these photocarriers relax on a
time scale T1. The above characteristic relaxation times are
expected to be in the 10–200-fs range in (Ga,Mn)As [ 21,51].
For pump fluences of ∼10μJ/cm2, the experiment gives
/Delta1Sz/S∼0.5%, reproduced by our theory for T1=100 fs
andT2=50 fs. This spin tilt decreases to /Delta1Sz/S∼0.01% as
T2decreases to 3 fs with fixed T1=100 fs. For fixed short
T2=10 fs, /Delta1Sz/Svaries between 0.05%–0.1% as T1varies
between 30 and 100 fs. In all cases, we conclude that the fsspin-orbit torque contribution has the same order of magnitudeas the experimental results unless T
1andT2are few fs or less.
From now on we fix T1=100 fs and T2=50 fs.
The nonthermal fs spin-orbit torque contribution can be en-
hanced by increasing the laser intensity. Figure 7(a) shows that,
for easily attainable ∼100μJ/cm2low pump fluences [ 37],
the “sudden” magnetization tilt increases to /Delta1Sz/S∼4% (for
E0=7×105V/cm). Figure 7(b) then shows that β/Delta1sh(t)
along [110] grows into the Tesla range. The precise magnitudeof this fs magnetization canting is sample-dependent anddepends on relaxation. The different intensity dependenceand temporal profiles of the thermal and coherent/nonthermalcarrier-spin components distinguishes these two contributionsto the photoexcited spin. While the quasiequilibrium contribu-tionH
FSis limited by the chemical potential, /Delta1shis controlled
by the laser frequency. A distinct impulsive component of fastmagnetic anisotropy was observed in the ps magnetization0123
t (ps)-0.04-0.0200.020.04ΔSz/|S|ωp=3.14eV (SGS//X+)
ωp=3.02eV (SGS//X+)
ωp=3.14eV (SGS//Y+)
-0.4 -0.2 0 0.2 0.4 0.6 0.8 1
t (ps)-2-1.5-1-0.500.5βΔ[110] (Tesla )ωp=3.02eV
ωp=3.14eV
SGS//X+(a) (b)
FIG. 7. (Color online) Calculated fs spin dynamics similar to
Fig. 5but with order of magnitude higher pump fluence
∼100μJ/cm2. (a) Comparison of out-of-plane magnetization com-
ponents for two different initial magnetic states and ωp. (b) Photohole
fs anisotropy fields along [110] for the two ωp.
trajectory measured in Ref. [ 37] for pump fluences above
∼70μJ/cm2at/planckover2pi1ωp∼1.5 eV. Figure 7(a) also compares
the spin canting dynamics for initial magnetization along theX
+
0orY+
0easy axis for B=0. Similar to the experiment of
Fig. 4(d), it displays symmetric temporal profiles of /Delta1Sz(t),
with opposite signs for the two perpendicular easy axes. In thisway, we can distinguish the two magnetic states within 100 fs.The equal magnitude of /Delta1S
zbetween the two perpendicular
in-plane easy axes arises from the diagonal direction of /Delta1sh
for/Delta1pd//Delta1 so∼1/3 as in (Ga,Mn)As (Fig. 2). The overall
agreement between theory and experiment suggest that amagnetic state can be read within 100 fs, by monitoring thedirection of out-of-plane laser-induced magnetization canting.
The above theory-experiment comparison of fs magnetism
and the connection of Fig. 6(b) to other ps-resolved magneto-
optical experiments [ 37] make a case that optical control of a
short-lived coherent population imbalance between exchange-split, spin-orbit-coupled anisotropic bands can generate fsspin-orbit torque with controllable direction, temporal profile,and magnitude. The latter initiates “sudden” magnetizationdynamics. This result is not specific to the (Ga.Mn)As four-state magnetic memory but may also apply to other magneticmaterials with strong spin-orbit coupling [ 9,10] and uniaxial
magnetic anisotropy. In (III,Mn)V ferromagnets, we are notaware of any experiment so far showing nonthermal 360
◦
switchings between multiple magnetic states induced by asingle laser pulse. This may be due to the fact that a 100-fslaser pulse not only excites magnon oscillations around theequilibrium easy axis but, even for low ∼10μJ/cm
2fluences,
also induces undesired fs electronic heating of spins [ 28,29]. A
complete quenching of ferromagnetism in (III,Mn)Vs has beenreported for pump fluences on the mJ/cm
2range [ 8,29]. Our
calculations show that, with a single 100fs pulse, similarlyhigh fluences are required to induce a sufficiently strong“initial condition” /Delta1S(t) that achieves switching to a different
magnetic state. Below we show that, alternatively, pulseshaping [ 23] can be used to initiate switching in a more
controlled way, while keeping the peak laser fluence per pulse
as low as possible to reduce fs electronic heating. In this way,we may maximize the “transverse” hole spin excitations whilereducing the “longitudinal” demagnetization by keeping thepump fluence per pulse in the 10–100 μJ/cm
2range.
A more general message conveyed by our theory-
experiment results is that laser-driven dipolar coupling me-diated by spin-orbit fluctuations in pd-coupled ferromagnetic
195203-10MANIPULATING FEMTOSECOND SPIN-ORBIT TORQUES . . . PHYSICAL REVIEW B 91, 195203 (2015)
ground states favors local spin canting during fs optical exci-
tation. Interestingly, in strongly correlated electron materialssuch as colossal magnetoresistive manganites, laser-drivendipolar bonding mediated by quantum spin-flip fluctuationswas shown to induce local spin canting in an antiferromagneticground state [ 1,4]. This quantum spin canting was shown
to drive a magnetic phase transition during <100 fs laser
pulses [ 1]. Such quantum femtosecond magnetism originates
from transient modification of the interatomic hopping ofvalence electrons by the laser Efield, which nonadiabatically
generates spin-exchange coupling and ferromagnetic correla-tion as photoelectrons hop while simultaneously flipping localspins. Such results point to a more universal behavior: laser-induced dipolar coupling mediated by spin-dependent valencefluctuations favors spin-symmetry-breaking even during thehighly nonequilibrium and nonthermal femtosecond timescales.
IV . INITIATING DETERMINISTIC SWITCHINGS
WITH A LASER-PULSE TRAIN
Results so far imply that a single 100-fs laser pulse with
∼10–100 μJ/cm2fluence excites magnon oscillations around
the equilibrium easy axis. Switching of the magnetization to adifferent magnetic state requires photoexcitation of a stronger“initial condition” /Delta1S(t). While switching via thermally
assisted processes may be possible by increasing the fluenceto the mJ/cm
2range [ 38], pulse shaping [ 23] can initiate
switching in a more controlled way while keeping the laserfluence per pulse in the μJ/cm
2range to reduce fs electronic
heating of spins. Here, we coherently control /Delta1sh(t)b y
usingMtime-delayed laser pulse-trains, each consisting of N
Gaussian pulses with duration τp=100 fs. The optical field is
E(t)=M/summationdisplay
j=1E0N/summationdisplay
i=1exp/bracketleftbig
−(t−τj−/Delta1τij)2/τ2
p/bracketrightbig
×exp/bracketleftbig
−iω(j)
p(t−τj−/Delta1τij)/bracketrightbig
. (14)
Here, we tune τj, the time delay of the jth laser-pulse-train, and
ω(j)
p, the pulse-train central frequency, but fix /Delta1τij=500 fs
for simplicity. In this section we consider M=1 and control
the net duration of the spin-orbit torque with a single trainofNlaser pulses. In Fig. 8, we compare the components of
β/Delta1s
h(t) and γ/Delta1HFSobtained for N=8 in the coordinate
system defined by the [110], [1 −10], and [001] directions.
We use the same ∼100μJ/cm2fluence as in Fig. 7.T h e
nonthermal contribution β/Delta1sh(t) prevails over the thermal
contribution /Delta1HFS(t), which builds-up as /Delta1shdrives /Delta1S(t)
and forces the spin of the Fermi sea bath to adjust to the newdirection of S(t)[17]. This /Delta1S(t) builds-up in a step-by-step
fashion well before relaxation, driven by a sequence ofsuccessive photoexcited fs spin-orbit torques.
/Delta1H
FS(t) originates from the spin of the thermal hole Fermi
sea and is therefore restricted by the Fermi-Dirac distribution.The latter thermal populations give anisotropy fields of theorder of few 10’s of mT in (Ga,Mn)As [ 6,37], as they
are restricted by the equilibrium anisotropy parameters and∼μeV free energy differences with S. On the other hand,
the experiments observe anisotropy fields that are at least01234 56
t (ps)-2-1.5-1-0.50TeslaβΔs[1-10]
βΔs[110]
βΔs[001]
ΔHFS[1-10]
ΔHFS[110]
ΔHFS[001]
FIG. 8. (Color online) Comparison of nonthermal and quasither-
mal components of laser-induced magnetic anisotropy fields β/Delta1sh(t)
and/Delta1HFS(t) during coherent nonlinear photoexcitation with a train
ofN=8 100-fs laser pulses separated by 500 fs, with E0=
7×105V/cm and /planckover2pi1ωp=3.14 eV .
one order of magnitude larger [ 36,37]. Figure 8compares
the thermal anisotropy field /Delta1HFS(t) to the nonthermal
photohole contribution β/Delta1sh(t) obtained at /planckover2pi1ωp∼3.1e V
for the ∼100μJ/cm2pump fluence used in Ref. [ 37]. This
nonthermal photohole spin was calculated in the time-domainby solving density matrix equations of motion after takinginto account the (Ga,Mn)As band structure at 3.1 eV . For/planckover2pi1ω
p∼1.5e V,a similar calculation shown in Fig. 6(b) gives
smaller photoexcited spin due to the different band structureand populated BZ directions close to the Fermi level. In ourcalculations, the photoexcited populations are not restricted bythe Fermi-Dirac distribution. By tuning the laser frequency,the photocarriers can populate nonparabolic anisotropic partsof the BZ that cannot be accessed close to quasiequilibrium.Our quantum kinetic calculation far from equilibrium givesmore flexibility as compared to assuming quasiequilibriumchanges in the temperature and chemical potential, which areonly established after a short but finite time T
1. As seen in
Fig. 8,β/Delta1sh(t) can grow to ∼2 T along [110] for experimen-
tally relevant pump fluences and T1∼100 fs. For such fast
photocarrier relaxation, /Delta1sh(t) follows the laser-pulse-train
temporal profile and the relative phase of consequative pulsesdoes not play a role. However, /Delta1s
h(t) is not the same for
different pulses, as the nonequilibrium electronic states changenonadiabatically with /Delta1S(t) (Appendix A).
We now show that, by increasing N, we can initiate
switching rotation to any one of the available magneticstates. Figure 9shows three such magnetization switching
trajectories up to long times t=800 ps. These ps trajectories
are initiated at t=0b yN=7 [Fig. 9(a)],N=9 [Fig. 9(b)],
orN=12 [Fig. 9(c)] pulses with ∼100μJ/cm
2fluence.
By increasing N, we can switch from X+to all three
other magnetic states Y+,X−, andY−.I nF i g . 9(a),N=7
pulses with /planckover2pi1ωp=3.02 eV (HH photoexcitation) initiate
a counterclockwise 90◦switching rotation that stops after
reaching the next magnetic state, Y+, within ∼80 ps. The
magnetization oscillates around the final state with a significantamplitude that cannot be controlled with a single pulse-train(magnetic ringing) [ 47]. This ringing results from the weak
(nanosecond) Gilbert damping of the local-spin precessionobserved in annealed (Ga,Mn)As [ 33,37]. While magnetic
ringing can make multiple 90
◦switchings unstable, below
195203-11P. C. LINGOS, J. W ANG, AND I. E. PERAKIS PHYSICAL REVIEW B 91, 195203 (2015)
FIG. 9. (Color online) Magnetization switching trajectories from X+to the other three magnetic states, controlled by tuning the frequency
ωpand triggered by a single laser-pulse train with increasing number of pulses NandE0=7×105V/cm. All switchings are followed by
pronounced magnetic ringing. (a) Counterclockwise 90◦switching X+→Y+, initiated by HH photoexcitation with N=7 pulses. (b) 180◦
magnetization reversal via clockwise pathway X+→Y−→X−, initiated by LH photoexcitation with N=9 pulses. (c) Photoexcitation as in
(a), but with N=12 pulses. By increasing N, the magnetization moves past the Y+andX−intermediate states and accesses the Y−state via
the 270◦counterclockwise pathway X+→Y+→X−→Y−.
we show that we can suppress it by exerting opposing fs
spin-orbit torques. By increasing the number of pulses toN=9, the magnetization continues past Y
+to the next
available state, X−. Figure 9(b) then shows magnetization
reversal via clockwise instead of counterclockwise rotation,since /planckover2pi1ω
p=3.14 eV excites e-LH instead of e-HH optical
transitions. This X+→Y−→X−pathway completes within
∼150 ps and is again followed by magnetic ringing. By
increasing the number of pulses to N=12, the fs spin-
orbit torque is sufficient to move the magnetization evenbeyond X
−. Figure 9(c) shows 270◦switching to the Y−
state within ∼200 ps, following a X+→Y+→X−→Y−
pathway initiated by e-HH photoexcitation.
V . OPTICAL CONTROL OF SEQUENTIAL 90◦
SWITCHINGS BETWEEN FOUR STATES
In this section, we provide an example of how our proposed
optical manipulation of fs spin-orbit torques could be used togain full access of a four-state magnetic memory. Figure 10
shows two switching protocols that achieve 360
◦control of
the magnetic states of Fig. 1(b). The upper panel shows
the sequences of laser-pulse-trains used to control the foursequential 90
◦switchings. Two different laser frequencies
excite e-HH or e-LH optical transitions, which allow us to
stop and restart the magnetization motion at each of the fourmagnetic states as desired. By tuning the laser frequency wechoose the direction of fs spin-orbit torques and multistepswitching process, which takes place via counterclockwise[Fig. 10(a) ] or clockwise [Fig. 10(b) ] magnetization rotations
forced to stop at all intermediate states at will. To control thephotoexcited /Delta1s
h(t) and fs spin-orbit torques, we turn three
experimentally accessible “knobs.” (i) Pulse shaping [23]b y
changing N, which controls the net duration and temporal
profile of the spin-orbit torques. In this way, we tailor /Delta1S(t)
that initiates or modifies the switching rotations with low in-tensity per laser pulse. (ii) Frequency-tuning enables selective
photoexcitation of exchange-split LH or HH nonequilibriumpopulations with different superpositions of spin- ↑and spin- ↓
states. In this way, we control the population imbalance thatdecides the directions of /Delta1s
h, fs spin-orbit torque, and /Delta1S(t).
(iii) By controlling the time delays τj, we exert fs spin-orbit
torques at desirable times in order to stop and restart theswitching rotation at all intermediate states and suppress
magnetic ringing. This is discussed further in the next section.To understand the role of the twelve laser-pulse trains chosenin Fig. 10, we note the following points: (i) a laser-pulse train
initiates switchings or magnon oscillations via fs spin-orbittorque with direction that depends on both laser frequency
and magnetic state, (ii) when the magnetization reaches a newmagnetic state, we use a laser-pulse-train to exert opposingfs spin-orbit torques, in a direction that stops the switchingrotation and suppresses the magnetic ringing so that we canaccess the state, and (iii) when we are ready to move on, alaser-pulse train with the appropriate color restarts the 360
◦
switching process by exerting fs spin-orbit torques in thedesirable direction.
Figure 10shows four sequential 90
◦switchings controlled
by/Delta1sh(t). In Fig. 10(a) , a counterclockwise X+→Y−
switching is initiated by e-HH photoexcitations with N=12
pulses. After τ=35 ps, the magnetization reaches the vicinitylh
hh
X-0X+Sx
X-0X+Sx
Y-0Y+Sy
Y-0Y+Sy
0 50 100 150 200 250 300 350
t (ps)Z-0Z+Sz
0 50 100 150 200 250 300
t (ps)Z-0Z+Szhh
lh
(a) (b)
FIG. 10. (Color online) Two protocols for 360◦control of the full
four-state magnetic memory via four sequential 90◦switchings that
stop and restart at each intermediate magnetic state. (a) Counter-
clockwise sequence X+→Y+→X−→Y−→X+, (b) Clockwise
sequence X+→Y−→X−→Y+→X+. (Top) Timing sequences
and colors of the laser-pulse trains ( N=12) that create the needed fs
spin-orbit torque sequences. Blue pulses excite HH optical transitions,
magenta pulses excite LH transitions. E0=7×105V/cm (pump
fluence of ≈100μJ/cm2).
195203-12MANIPULATING FEMTOSECOND SPIN-ORBIT TORQUES . . . PHYSICAL REVIEW B 91, 195203 (2015)
-6-4-20246ΔSz/|S| (10-2)ω1=3.14eV
ω1=3.02eV
-6-4-20246ΔSz/|S| (10-2)ω1=3.14eV
ω1=3.02eV
0 100 200 300
t (ps)-6-4-20246ΔSz/|S| (10-2)ω1=3.14eV
ω1=3.02eV
0 100 200 300
t (ps)-6-4-20246ΔSz/|S| (10-2)ω1=3.14eV
ω1=3.02eVτ1=74ps
τ1=148psτ1=74ps
τ1=148ps(a) Sgs//X+(b) Sgs//Y+
FIG. 11. (Color online) Two 100-fs laser pulses, delayed by τ, enhance or suppress magnon oscillations via fs spin-orbit torque. The first
pulse, /planckover2pi1ωp=3.14 eV , starts the precession (frequency /Omega1)a tτ=0. The second pulse, /planckover2pi1ωp=3.02 or 3 .14 eV, arrives at τ=74 ps ( /Omega1τ=π)
orτ=148 ps ( /Omega1τ=2π). Equilibrium magnetic state: (a) X+and (b) Y+.
of the intermediate Y+state. We then stop the switching
process by exciting e-HH optical transitions. We restart the
motion at τ=85 ps, after waiting for about 50 ps, by using
e-LH photoexcitations to switch the magnetization to the X−
state. There we again stop the process at τ=160 ps, by
exciting e-LH optical transitions. We restart at τ=170 ps with
e-HH photoexcitations, which trigger switching to Y−.T h i s
switching completes within ∼35 ps, after we stop the motion
withe-HH photoexcitations at τ=205 ps. We finish the 360◦
switching loop by using e-LH photoexcitations to restart the
counterclockwise motion back to X+,a tτ=250 ps, and later
to terminate the process at τ=330 ps. Figure 10(b) shows an
opposite clockwise switching sequence X+→Y−→X−→
Y+→X+, obtained by changing the laser-pulse frequencies
frome-HH to e-LH excitations and vice-versa. In this case,
e-LH optical transitions with N=12 pulses trigger clockwise
magnetization rotation, which we suppress at Y−with LH
excitations at τ=75 ps. We restart the process with e-HH
photoexcitation at τ=85 ps and suppress it again at X−with
e-HH optical transitions at τ=120 ps. We restart with e-LH
excitation at τ=140 ps and switch to Y+, where we suppress
the motion at τ=225 ps with e-LH optical transitions. We
complete a closed switching loop to the initial X+state with
e-HH photoexcitation at τ=235 ps and suppress the rotation
withe-HH optical transitions at τ=275 ps. In the next
section, we analyze how tunable fs spin-orbit torque directionoffers more flexibility for controlling switching rotations andmagnetic ringing.
VI. CONTROLLING MAGNETIC SWITCHING AND
RINGING WITH A LASER-PULSE TRAIN
While the optical control scheme via fs spin-orbit torque
discussed in the previous section allows for elaborate switchingof a multistate magnetic memory, it may also apply to conven-tional memories exhibiting uniaxial magnetic anisotropy. Itsmain advantage, in addition to initiating selective switchings
and flipping the spin between two states, is that it can suppressthe magnetization motion and magnetic ringing at any time,at any intermediate magnetic state. Magnetic ringing arisesfrom the weak damping of the magnetization precessionaround an easy axis following excitation with either opticalor magnetic field pulses and limits the read/write times inmany magnetic materials [ 47]. One known way to reduce
it is to take advantage of the phase /Omega1τ of magnetization
precession with frequency /Omega1[34,47]. With magnetic field
pulses, this can be done by adjusting the duration of a longpulse to the precession period [ 47]. With ultrashort laser pulses,
one can suppress (enhance) the precession by exciting when/Omega1τ=π(/Omega1τ=2π)i nt h es a m ew a ya sa t τ=0[34]. Such
coherent control of spin precession is possible for harmonicoscillations. Below we show that we can optically controlboth magnon oscillations and nonlinear switching rotations byapplying clockwise or counterclockwise fs spin-orbit torquepulse sequences when needed.
We start with the harmonic limit and demonstrate magnon
control via fs spin-orbit torque with tunable direction. First,we excite at τ=0 magnon oscillations with frequency /Omega1
(thick solid line in Fig. 11). We thus initiate magnetization
precession around the X
+[Fig. 11(a) ]o rt h e Y+[Fig. 11(b) ]
easy axis with e-LH excitation ( /planckover2pi1ωp=3.14 eV). An impulsive
magnetization at τ=0 is observed in the ps trajectory of
Fig. 11. The initial phase of these magnon oscillations is
opposite between the X+
0andY+
0states, due to the opposite
directions of the fs spin-orbit torques [Fig. 7(a)]. We then send
a control laser pulse at τ=74 ps ( /Omega1τ=π)o ra t τ=148 ps
(/Omega1τ=2π), but use either /planckover2pi1ωp=3.14 eV ( e-LH optical
transitions) or /planckover2pi1ωp=3.02 eV ( e-HH optical transitions). By
controlling the direction of fs spin-orbit torque with suchfrequency tuning, we show that we can both enhance andsuppress the amplitude of the magnetization precession at both
/Omega1τ=πand/Omega1τ=2π. While for /Omega1τ=πwe suppress the
195203-13P. C. LINGOS, J. W ANG, AND I. E. PERAKIS PHYSICAL REVIEW B 91, 195203 (2015)
X-0X+
X-0X+
X-0X+
X-0X+
Y-0Y+
Y-0Y+
Y-0Y+
Y-0Y+
0 100 200 300 400
t (ps)Z-0Z+
0 100 200 300 400
t (ps)Z-0Z+
0 100 200 300 400
t (ps)Z-0Z+
0 100 200 300 400
t (ps)Z-0Z+(a) (b) (c) (d)
FIG. 12. (Color online) Time-dependence of magnetization components controlled by a time-delayed fs spin-orbit torque pulse train. (a)
X+→Y+→X−→Y−switching pathway is initiated at τ=0 with HH photoexcitation (dashed line). After switching completes, the
unavoidable magnetic ringing is reduced by a control laser-pulse-train that can exert opposing fs spin-orbit torques at any time (solid line).
(b) The X+→Y−switching of (a) is terminated by opposing fs spin-orbit torques after magnetization reversal to X−.( c )T h e X+→Y−
switching is terminated by a control laser-pulse-train after 90◦rotation to Y+.( d )T h e X+→Y−switching is stopped immediately after it is
initiated, by opposing fs spin-orbit torque at τ=2p s .
magnetic ringing when applying the same fs spin-orbit torque
as for τ=0(/planckover2pi1ωp=3.14 eV), we can also enhance it by
applying an opposite fs spin-orbit torque ( /planckover2pi1ωp=3.02 eV).
Similarly, at time /Omega1τ=2π, we enhance the ringing when
applying fs spin-orbit torque in the same direction as forτ=0 and suppress it by reversing the direction. We thus gain
flexibility in both starting and stopping magnon oscillations.
Unlike for harmonic precession, switching also involves
nonlinearities and anharmonic effects. In Fig. 12(a) ,aX
+→
Y+→X−→Y−switching pathway (dashed line) is initiated
atτ=0a si nF i g . 9(c). After about 200 ps, the magnetization
switches to Y−, after overcoming the intermediate states Y+
andX−.T h eXcomponent of the magnetization then oscillates
with significant amplitude [magnetic ringing, see dashedcurve in Fig. 12(a) ]. Figure 12(a) (solid curve) demonstrates
suppression of this ringing by a control laser-pulse-train thatcan arrive at any time after the switching is completed.To accomplish this, we tune the direction, duration, andstrength of the exerted fs spin-orbit torques. Figures 12(b)
and 12(c) show that the control pulse-train can also stop the
X
+→Y+→X−→Y−switching at one of the intermediate
magnetic states before reaching Y−. However, we must use
different ωpatY+andX−in order to get an opposing fs
spin-orbit torque, as the direction of the latter depends onthe magnetic state. In Fig. 12(b) , we stop the switching at
theX
−magnetic state, after passing through Y+, by exciting
with /planckover2pi1ωp=3.14 eV at τ∼100 ps ( e-LH photoexcitation).
Figure 12(c) shows that we can stop at Y+after∼35 ps,
by exerting a clockwise spin-torque using /planckover2pi1ωp=3.02 eV
(HH photoholes). A more dramatic demonstration of theflexibility offered by fs spin-orbit torque is given in Fig. 12(d) .
Here, we initiate the X
+→Y−switching as above and then
stop it immediately, by applying a control laser-pulse trainatτ=2 ps, i.e., long before any oscillations can develop.
Instead of relying on the precession phase as in Fig. 11,w e
apply a sufficiently strong clockwise fs spin-orbit torque thatopposes the magnetization motion. In this way, we stop themagnetization at its tracks, after a minimal motion withoutoscillations. We conclude that coherent optical control of
the mobile spin excited during fs laser pulses allows usto suppress both magnetic ringing and nonlinear switchingrotations, by controlling the direction, duration, and magnitudeof fs spin-orbit torques.
VII. CONCLUSIONS AND OUTLOOK
In this paper, we used density-matrix equations of motion
with band structure to describe photoexcitation and frequency-dependent control of fs spin-orbit torques analogous tothe static current-induced ones in spintronics. In this all-optical way, we initiate, stop, and control multiple magneticswitchings and magnetic ringing. The proposed nonadiabaticmechanism involves optical control of direction, magnitude,and temporal profile of fs spin-orbit torque sequences. Thisis achieved by tuning, via the optical field, a short-livedcarrier population and spin imbalance between exchange-splitbands with different spin-orbit interactions. The photoexcitedspin magnitude and direction depend on symmetry-breakingarising from the nonperturbative competition of spin-orbitand spin-exchange couplings of coherent photoholes. Wevalidated our initial prediction of fs spin-orbit torque [ 3]
by comparing our calculations to existing magneto-opticalpump-probe measurements monitoring the very early ∼100 fs
temporal regime following excitation with a single linearly-polarized laser pulse. The most clear experimental signatureis the observation of laser-induced fs magnetic hysteresisand switching of the direction of out-of-plane femtosecondmagnetization component with magnetic state. Such magnetichysteresis is absent without pump, while static planar Halleffect measurements observe similar in-plane switchings inthe transverse component of the Hall magnetoresistivity.The observation of switching of laser-induced fs transversemagnetization with magnetic state cannot arise from longitu-dinal nonlinear optical effects and demagnetization/amplitudechanges. The dependence on magnetic state indeed disap-pears with increasing perpendicular magnetic field, which
195203-14MANIPULATING FEMTOSECOND SPIN-ORBIT TORQUES . . . PHYSICAL REVIEW B 91, 195203 (2015)
suppresses the magnetization reorientation. In this way, we
can separate experimentally longitudinal and transverse fem-tosecond magnetization changes. We discussed two theoreticalresults that may be useful for coherent control of magneticmemory states and magnetic ringing via fs spin-orbit torque:(i) we showed that femtosecond optical excitation can start,stop, and restart switching pathways between the adiabaticfree energy magnetic states in any direction. Based on this, wegave an example of sequences of laser-pulse trains that canprovide controlled access to four different magnetic states viaconsequative 90
◦switchings, clockwise or counterclockwise.
(ii) We demonstrated optical control of magnon oscillationsand switching rotations and suppression of magnetic ringingat any time, long or short. For this we enhance spin-orbit torquevia pulse-shaping and control its direction via laser frequency.
The full nonthermal control of a magnetic memory demon-
strated here requires the following: (i) The competitionbetween spin-orbit and magnetic exchange couplings breaksthe symmetry while the laser electric field couples to thematerial. As a result, e-hpair excitations are photoexcited with
finite spin. There is no need to transfer angular-momentumfrom the photons (no circular polarization) since spin-orbitcoupling does not conserve spin. (ii) The direction, magnitude,and duration of the nonthermal carrier spin-pulse is coherentlycontrolled by the optical field. In particular, the direction ofphotoexcited spin is controlled by the laser frequency, themagnetic state, and the symmetry-breaking. Importantly, itsmagnitude increases with laser intensity and E
2, while its
temporal profile follows that of the laser pulse if relaxationis sufficiently fast. Such characteristics of fs spin-orbit torquecan distinguish it from adiabatic free energy effects. (iii) Thephotoexcited spin-pulses exert fs spin-orbit-torques on thecollective local spin and move it “suddenly,” in a control-lable direction that depends on the magnetic state and thelaser frequency. By coherently controlling the nonthermalpopulation imbalance of exchange-split carrier bands withdifferent spin-orbit interactions, we can move the local spinvia nonadiabatic interaction with mobile spins. (iv) Laser-pulseshaping [ 23] and increased pump fluence allow us to access
optically the magnetic nonlinearities of the carrier free energy.In this way, we may initiate or modify, during fs time scales,deterministic switchings to any available magnetic state.(v) By using control pulse-trains with appropriate frequencies,we suppress and restart switching rotations at intermediatemagnetic states and suppress magnetic ringing after switchingscomplete. While coherent suppression of magnon oscillationsis possible by taking advantage of the precession phase, herewe mainly rely on controlling the direction of fs spin-orbittorque with respect to the direction of magnetization rotation.In this way, we suppressed and enhanced both switchingrotations and ringing at long and short times.
To control the entire four-state memory as in Fig. 10, we had
to use time-delayed laser-pulse trains with different frequen-cies at different magnetic states. The first excitation suppressesthe switching rotation/ringing in order to access the state, whilethe second excitation restarts the process and moves the mag-netization to the next magnetic state in the desired direction.While such control of the magnetization trajectory occurs onthe 100-fs time scale of coherent photoexcitation, the initiateddeterministic switchings complete on ∼100-ps time scales, asdetermined by the free energy and micromagnetic parameters.
In a massively-parallel memory, we can control ndifferent
bits simultaneously on the 100fs time scale without waitingfor each switching to complete. For large n, this would ideally
result in memory reading and writing at ∼10 THz speeds.
Our proposed fs spin-orbit torque mechanism may be
relevant to different unexplored spin-orbit coupled materialswith coexisting mobile and local carriers [ 11], for example,
topological insulators doped with magnetic impurities [ 9,10].
Important for practical implementations and experimentalproof of fs spin-orbit torque is to identify materials wherethe quasithermal/adiabatic and nonthermal/nonadiabatic con-tributions to the magnetic anisotropy can be distinguishedexperimentally. It is possible to separate these two based ontheir temporal profiles and their dependence on photoexci-tation intensity, laser frequency, and external magnetic field.In (Ga,Mn)As, Fig. 4shows photogeneration of a “sudden”
magnetization reorientation and fs magnetic hysteresis formagnetic field perpendicular to the sample plane. Suchmagnetic field cants the ground-state magnetization out of theplane, from S
z=0(B=0) toSz≈±S(large B). When Sz≈
0 in equilibrium, /Delta1Sz(t) measures transverse magnetization
reorientation and magnetic hysteresis correlated with in-planeswitching, while when S
z≈Slongitudinal changes dominate
/Delta1Sz(t) and there is no hysteresis. In this way, a perpen-
dicular magnetic field can be used to elucidate the physicalorigin of the fs magneto-optical pump-probe signal dynamics.Distinct thermal and nonthermal contributions to the psmagnetization trajectory were also observed experimentallyat/planckover2pi1ω
p∼1.5e V[ 37]. They were separated based mainly on
pump fluence dependence and by controlling the material’smicromagnetic parameters. Qualitative differences in themagnetization trajectory were observed above ∼70μJ/cm
2
pump fluence. Below this, the easy axis rotates smoothly
inside the plane, due to laser-induced temperature increaseduring ∼10 ps time scales [ 33,37]. Above ∼70μJ/cm
2,a
subpicosecond “sudden” magnetization component is clearlyobserved [ 33,37]. Importantly, while the precession frequency
γH
FSincreases linearly with equilibrium temperature, it
saturates with pump fluence above ∼70μJ/cm2, even though
the impulsive out-of-plane magnetization tilt continues toincrease [ 37]. In contrast, the pump-induced reflectivity
increases linearly with pump intensity up to much higherfluences ∼150–200 μJ/cm
2[37], which indicates nonthermal
photocarriers. Here we suggest that the numerical resultsof Fig. 6(b), which show frequency-dependent fs spin pho-
toexcitation for /planckover2pi1ω
p∼1.5e V,may explain the “sudden”
out-of-plane magnetization canting observed in Ref. [ 37].
This requires ∼100μJ/cm2pump fluences consistent with our
theory. Our results describe the initial condition that triggersrelaxation not treated here.
In closing, we note that the discussed concepts are of
more general applicability to condensed matter systems.The main idea is the possibility to tailor order parameterdynamics via optical coherent control of nonthermal carrierpopulations, as well as via charge fluctuations and interactionsdriven while the optical field couples to the material. Theinitial coherent excitation temporal regime may warrant moreattention in various condensed matter systems [ 1,4]. An
analogy can be drawn to the well-known coherent control of
195203-15P. C. LINGOS, J. W ANG, AND I. E. PERAKIS PHYSICAL REVIEW B 91, 195203 (2015)
femtosecond chemistry and photosynthetic dynamics, where
the photoproducts of chemical and biochemical reactions canbe influenced by creating coherent superpositions of molecularstates [ 69]. Similarly, in condensed matter systems, laser-
driven e-hpairs (optical polarization) can tailor nonadiabatic
“initial conditions” that drive subsequent phase dynamicsgoverned by the adiabatic free energy. An analogy can alsobe drawn to parameter quenches studied in cold atomicgases. There, quasi-instantaneous quenches drive dynamicsthat, in some cases such as BCS superconductors, can bemapped to classical spin dynamics. Coherent dynamics ofsuperconducting order parameters are now beginning to bealso studied in condensed matter systems [ 70,71], and an
analogy to the magnetic order parameter studied here is clear.Other examples include quantum femtosecond magnetismin strongly-correlated manganites [ 1,4], photon-dressed Flo-
quet states in topological insulators [ 72], and the existence
of nonequilibrium phases in charge-density-wave correlatedsystems [ 48]. Femtosecond nonlinear optical and THz spec-
troscopy [ 73] offers the time resolution needed to disentangle
different order parameters that are strongly coupled in theground state, based on their different dynamics after “sudden”departure from equilibium [ 48,49]. Multipulse switching
protocols based on nonadiabatic quantum excitations cancontrol nonequilibrium phase transitions, by initiating phasedynamics in a controllable way [ 1,4].
Note added to proof. After our paper was submitted,
we became aware of a recent preprint on time-resolvedmagneto-optical measurements of the collective magnetiza-tion ultrafast dynamics in (Ga,Mn)As [ 75]. This experiment
observed a strong pump-frequency dependence of the mag-netization precession above the semiconductor band gap,which originates from the nonthermal holes photoexcitedin the semiconductor band states similar to our theoreticalpredictions here. The experimental results reveal a systematicbut complex sample-dependent frequency dependence, whichdiffers between annealed and as-grown samples. The observedeffect is consistent with our predictions in Fig. 6(b).F o r
example, the quasithermal anisotropy effects predicted here(e.g., /Delta1H
FSin Fig. 8) are mainly driven by the fs /Delta1Sz.
The latter “sudden” magnetization drives a laser-inducedcontribution to the quasithermal magnetic anisotropy fieldEq. ( A10) determining the precession frequency (especially
for in-plane initial magnetization S
z≈0, as for small Bfields).
While the present theory neglects any laser-induced changes inthe magnetic anisotropy parameters that characterize the freeenergy E
h(S), which add to our predicted effects, it suggests
that the frequency-dependent initial femtosecond change /Delta1Sz
may be important for explaining the frequency dependence of
the precession frequency determined by Eq. ( A10). Note that
the decay of /Delta1Sphotoinduced during femtosecond time scales
due to magnetic exchange interaction with the nonthermalphotohole spin is determined by the sample-dependent Gilbertdamping. The latter differs markedly between annealed andas-grown samples [ 33].
ACKNOWLEDGMENTS
This work was supported by the European Union Seventh
Framework Programme (FP7-REGPOT-2012-2013-1) underGrant Agreement No. 316165, by the European Union Social
Fund and National resources through the THALES programNANOPHOS, by the Greek GSRT project ERC02-EXEL(Contract No. 6260), by the Greek Ministry of EducationARISTEIA-APPOLO, and by the National Science Founda-tion Contract No. DMR-1055352.
APPENDIX A: FERMI-DIRAC/ADIABATIC VERSUS
NONTHERMAL/NONADIABATIC MAGNETIC
ANISOTROPY
In this Appendix, we discuss the two contributions to laser-
induced anisotropy: nonthermal and quasithermal. The adi-abatic/quasithermal contribution comes from relaxed Fermi-Dirac carriers. The nonadiabatic contribution comes from thecoherent/nonthermal photoexcited carriers, whose populationsincrease with intensity during photoexcitation. In the initialstage, these nonthermal carriers come from the continuum ofe-hexcitations excited by the fs laser pulse, so they follow its
temporal profile. At a second stage, they redistribute amongthe different kand band states while also scattering with the
Fermi sea carriers.
1. Nonthermal/nonadiabatic magnetic anisotropy
We use density matrix equations of motion and band struc-
ture to describe the femtosecond photoexcitation of short-livedphotohole spin pulses driven by four competing effects: (i)magnetic exchange interaction between local and mobile spins,
(ii) spin-orbit coupling of the mobile carriers, (iii) coherent
nonlinear optical processes, and (iv) fast carrier relaxation. Theinterplay of these contributions breaks the symmetry and ex-cites a controllable fs magnetic anisotropy field due to nonther-mal photocarriers. The photoexcited spin, Eq. ( 3), is expressed
in terms of the electronic density matrix, which resolves thedifferent band and k-direction contributions. Density matrix
equations of motion were derived for the time-dependentHamiltonian H(t), Eq. ( 8), with band structure treated within
standard tight-binding and mean-field approximations. ThisHamiltonian has fast and slow contributions. Its adiabaticpartH
b(S0), Eq. ( 4), depends on the slowly varying (ps)
spinS0. The eigenstates of Hb(S0) describe electronic bands
determined by periodic potential, spin-orbit, and adiabaticmagnetic exchange coupling. The latter interaction
H
pd(S0)=βcS0·ˆsh, (A1)
where ˆshis the hole spin operator, leads to exchange-splitting
of the HH and LH semiconductor valence bands determinedby the exchange energy /Delta1
pd=βcS. It also modifies the
direction of photoexcited spin, by competing with thespin-orbit coupling of the mobile carriers characterizedby the energy splitting /Delta1
soof the spin-orbit-split valence
band of the parent material (GaAs) at k=0. By adding to the
Hamiltonian carrier-carrier and carrier-phonon interactions,we can also treat relaxation, included here by introducingthe nonthermal population relaxation time T
1and the e-h
dephasing time T2.
We describe the band eigenstates of the adiabatic electronic
Hamiltonian Hb(S0) by using the semiempirical tight-binding
model that reliably describes the GaAs band structure [ 52].
Compared to the standard k·peffective mass approximation,
195203-16MANIPULATING FEMTOSECOND SPIN-ORBIT TORQUES . . . PHYSICAL REVIEW B 91, 195203 (2015)
this tight-binding approach allows us to also address states with
large momenta k. Such anisotropic and nonparabolic band
states contribute for laser frequencies away from the bandedge. Following Ref. [ 52], we include the quasiatomic spin-
degenerate orbitals 3 s,3p
x,3py,3pz, and 4 sof the two atoms
per GaAs unit cell and use the tight-binding parameter valuesof the Slater-Koster sp
3s∗model. As in Ref. [ 3], we add to
this description of the parent material the mean-field couplingof the Mn spin, Eq. ( A1), which modifies spin-mixing in a
nonperturbative way. Similar to Ref. [ 52], we diagonalize the
Hamiltonian H
b=Hc
b+Hv
bto obtain the conduction ( Hc
b)
and valence ( Hv
b) bands:
Hb(S0)=/summationdisplay
knεc
knˆe†
knˆekn+/summationdisplay
knεv
−knˆh†
−knˆh−kn.(A2)
The eigenvalues εc
kn(S0) andεv
−kn(S0) describe the conduction
and valence-band energy dispersions.
While S0varies on a ps time scale much slower than
the laser-induced electronic fluctuations, the rapidly-varying(fs) part of the Hamiltonian H(t),/Delta1H
exch(t)+HL(t), drives
“sudden” deviations from adiabaticity. /Delta1H exch(t), Eq. ( 9),
describes nonadiabatic interactions of photocarrier spins withthe fs magnetization /Delta1S(t) induced by fs spin-orbit torque.
H
L(t) describes the optical field dipole coupling within the
rotating wave approximation:
HL(t)=−/summationdisplay
nmkdnmk(t)ˆe†
kmˆh†
−kn+H.c., (A3)
where dnmk(t)=μnmkE(t) is the Rabi energy, E(t) is the pump
electric field, and μnmkis the dipole transition matrix element
between the valence band nand the conduction band mat
momentum k. These dipole matrix elements also depend on
S0and are expressed in terms of the tight-binding parameters
ofHb(k)a si nR e f .[ 74]:
μnmk=i
εmk−εnk/angbracketleftnk|∇kHb(k)|mk/angbracketright. (A4)
The density matrix /angbracketleftˆρ/angbracketrightobeys the equations of motion
i/planckover2pi1∂/angbracketleftˆρ/angbracketright
∂t=/angbracketleft[ˆρ,H (t)]/angbracketright+i/planckover2pi1∂/angbracketleftˆρ/angbracketright
∂t|relax. (A5)
The hole populations and coherences between valence bands
are given by the equation of motion
i/planckover2pi1∂t/angbracketleftˆh†
−knˆh−kn/prime/angbracketright−/parenleftbig
εv
kn/prime−εv
kn−i/Gamma1h
nn/prime/parenrightbig
/angbracketleftˆh†
−knˆh−kn/prime/angbracketright
=/summationdisplay
md∗
mnk(t)/angbracketleftˆh−kn/primeˆekm/angbracketright−/summationdisplay
mdmn/primek(t)/angbracketleftˆh−knˆekm/angbracketright∗
+βc/Delta1S/summationdisplay
l/bracketleftbig
sh
kn/primel/angbracketleftˆh†
−knˆh−kl/angbracketright−sh∗
knl/angbracketleftˆh†
−klˆh−kn/prime/angbracketright/bracketrightbig
,(A6)
where n=n/primedescribes the nonthermal populations and n/negationslash=
n/primethe coherent superpositions of different valence band
states. /Gamma1h
nn=/planckover2pi1/T1characterizes the nonthermal population
relaxation. /Gamma1h
nn/primeare the intervalence-band dephasing rates,
which are short and do not play an important role here. Thefirst term on the rhs describes the photoexcitation of holepopulations in band states ( n,k) that depend on S
0. The second
term is beyond a simple rate equation approximation anddescribes the nonadiabatic changes in the hole states inducedby their interaction with the rapidly varying (fs) photoinduced
magnetization /Delta1S(t), Eq. ( 9). Similarly,
i/planckover2pi1∂
t/angbracketleftˆe†
knˆekn/prime/angbracketright−/parenleftbig
εc
kn/prime−εc
kn−i/Gamma1e
nn/prime/parenrightbig
/angbracketleftˆe†
knˆekn/prime/angbracketright
=/summationdisplay
m/primed∗
nm/primek/angbracketleftˆh−km/primeˆekn/prime/angbracketright−/summationdisplay
m/primedn/primem/primek/angbracketleftˆh−km/primeˆekn/angbracketright∗,(A7)
where the rates /Gamma1e
nn/primecharacterize the electron relaxation.
In the above equations of motion, the photoexcitation
of the carrier populations and coherences is driven by thenonlinear e-hoptical polarization /angbracketleftˆh
−knˆekm/angbracketright(off-diagonal
density matrix element). This coherent amplitude characterizesthee-hexcitations driven by the optical field, which here only
exist during the laser pulse since their lifetime T
2(dephasing
time) is short:
i/planckover2pi1∂t/angbracketleftˆh−knˆekm/angbracketright−/parenleftbig
εc
km+εv
kn−i/planckover2pi1/T2/parenrightbig
/angbracketleftˆh−knˆekm/angbracketright
=−dmnk(t)[ 1−/angbracketleftˆh†
−knˆh−kn/angbracketright−/angbracketleft ˆe†
kmˆekm/angbracketright]
+βc/Delta1S(t)·/summationdisplay
n/primesh
knn/prime/angbracketleftˆh−kn/primeˆekm/angbracketright
+/summationdisplay
n/prime/negationslash=ndmn/primek(t)/angbracketleftˆh†
−kn/primeˆh−kn/angbracketright
+/summationdisplay
m/prime/negationslash=mdm/primenk(t)/angbracketleftˆe†
km/primeˆekm/angbracketright. (A8)
The nonlinear contributions to the above equation include
phase space filling (first line), transient changes in the nonequi-librium hole states due to the nonadiabatic magnetic exchangeinteraction /Delta1H
exch(t) (second line), and coupling to h-h(third
line) and e-e(fourth line) Raman coherences. The coupled
Eqs. ( A6), (A7), (A8), and ( 11) describe photoexcitation
of nonthermal carriers modified by the local spin rotation.They were derived in Refs. [ 3,17] using the Hartree-Fock
factorization [ 13,62]. To obtain meaningful numerical results,
we re-adjust our basis ˆh
−knto reflect the eigenstates of Hb(S0)
following large changes in S0during 360◦switching.
2. Adiabatic/Fermi-Dirac anisotropy
The equilibrium mobile carriers can be described by Fermi-
Dirac populations, fnk, of the eigenstates of the adiabatic
Hamiltonian Hb(S0), which determine the quasiequilibrium
anisotropy field HFS,E q .( 6)[25,32,37]. We simplify this
thermal contribution by neglecting any laser-induced changesin carrier temperature and chemical potential, which add toour predicted effects. A laser-induced thermal field /Delta1H
FS(t)
develops indirectly from fs spin-orbit torque as the net spin ofthe hole Fermi sea bath adjusts to the new nonequilibriumdirection of S(t)[17]. As already seen from calculations
of magnetic anisotropy that assume a Fermi-Dirac distribu-tion [ 6,37], the small ( ∼μeV) free energy differences with
Sresult in anisotropy fields of the order of 10’s of mT. The
discrepancies between theory and experiment seem to implythat nonequilibrium distributions broad in energy are necessaryto explain the magnitude of the observed effects [ 28]. Our
time-domain calculation of laser-induced magnetic anisotropydriven by photoexcited fs population agrees with experimentalmeasurements. However, we must still include the thermalFermi sea anisotropy in order to describe the four-state
195203-17P. C. LINGOS, J. W ANG, AND I. E. PERAKIS PHYSICAL REVIEW B 91, 195203 (2015)
magnetic memory. For this we express the free energy in the
experimentally observed form dictated by symmetry [ 6,39,61],
also obtained by expanding the theoretical expression [ 6]:
Eh(S)=Kc/parenleftbigˆS2
xˆS2
y+ˆS2
xˆS2
z+ˆS2
yˆS2
z/parenrightbig
+KuzˆS2
z−KuˆSxˆSy,
(A9)
where ˆS=S/Sis the unit vector that gives the instantaneous
magnetization direction. Kcis the cubic anisotropy constant,
Kuzis the uniaxial constant, which includes both strain and
shape anisotropies , andKudescribes an in-plane anisotropy
due to strain. We used measured anisotropy parameter val-ues [ 39]K
c=0.0144 meV , Ku=0.00252 meV , and Kuz=
0.072 meV . We thus obtain the thermal anisotropy field
γHFS=−2Kc
SˆS+1
S/parenleftbig
2KcˆS3
x+KuˆSy,
2KcˆS3
y+KuˆSx,2KcˆS3
z−2KuzˆSz/parenrightbig
. (A10)
The above expression describes the equilibrium magnetic
nonlinearities of the realistic material. By expressing Sin
terms of the polar angles φandθ, defined with respect to
the crystallographic axes, we obtain the easy axes from thecondition S×H
FS=0, by solving the equations
2Kccos3θ−(Kc+Kuz) cosθ+BS
2=0,(A11)
sin 2φ=Ku
Kcsin2θ, (A12)
where we added the external magnetic field Balong the [001]
direction. For B=0, the above equation gives θ=π/2, which
corresponds to in-plane easy axes as in Fig. 1(b). For small Ku,
these magnetic states X+,X−,Y+, andY−are tilted from the
[100] and [010] crystallographic directions by few degreesinside the plane [ 33,61]. As can be seen from Eq. ( A11), the
Bfield along [001] cants the easy axes out of the plane. In this
case,θ/negationslash=π/2 is a smooth function of B, consistent with the
behavior of the static polar Kerr rotation angle θ
K(B) observed
experimentally [see Fig. 3(a)]. Equation ( A12) also shows that
the out-of-plane tilt θinduces a magnetization rotation inside
the plane. It gives two different values for φ(XandYeasy
axes), which can switch due to either B-field sweeping [as seen
in the transverse Hall magnetoresistivity, inset of Fig. 3(a)]o r
laser-induced fs spin-orbit torque (as predicted here).
APPENDIX B: BAND CONTINUUM OF
ELECTRONIC STATES
The average hole spin sh(t), Eq. ( 3), that triggers the
fs magnetization dynamics here has contributions sh
kn(t)
from an anisotropic continuum of photoexcited nonparabolicband states. At /planckover2pi1ω
p∼1.5e V,this continuum also includes
disordered-induced states below the band gap of the pure semi-conductor [ 28]. At /planckover2pi1ω
p∼3.1e V,photoexcitation of such
impurity band/defect states is small, while the almost parallelconduction and valence bands lead to excitation of a wide rangeofkstates. Integration over the BZ momenta, as in Eq. ( 3),
presents a well-known challenge for calculating magneticanisotropies and other properties of real materials [ 60]. To sim-
plify the problem, one often calculates the quantities of interestat select kpoints and replaces the integral by a weighted sumover these “special points” (special point approximation) [ 60].
In our previous work [ 3], we considered eight special kpoints
(/Lambda1point [ 7]) along {111}. While this approximation takes into
account the general features of the anisotropic states, it missesimportant details, such as strong band nonparabolicity, densityof states, and photoexcited carrier densities. To comparewith the photocarrier densities in the experiment and toaddress issues such as the frequency dependence of thephotoexcited spins, we must include continua of band statesin our calculation. Here, we integrate over the band momentaalong the eight {111}symmetry lines by using the “special
lines approximation” discussed in Ref. [ 64]. At/planckover2pi1ω
p≈3.1e V,
we approximate the three-dimensional momentum integral bya sum of one-dimensional integrals along the eight kdirections
populated by photoexcited carriers. This simple approximationincludes the anisotropic, nonparabolic band continua [ 64].
At/planckover2pi1ω
p≈1.5e V,Fig. 6(b) was obtained by calculating the
one-dimensional integrals along all symmetry lines {100},
{010},{001},{110},{101},{011}, and {111}as in Ref. [ 64].
Following Ref. [ 64], we first express
1
V/summationdisplay
k/Delta1sh
k=1
(2π)3/integraldisplay
BZ/Delta1sh
kdk
=/integraldisplayd/Omega1
4π/bracketleftbigg1
(2π)3/integraldisplaykBZ
04πk2dk/Delta1sh
k/bracketrightbigg
,(B1)
where kBZis the BZ boundary and d/Omega1is the angular integral.
To calculate the above angular average, we use the speciallines approximation [ 64]
/integraldisplayd/Omega1
4π/Delta1sh
k=/summationdisplay
αwα/Delta1sh
kα, (B2)
where αruns over the dominant symmetry directions, kis the
wave-vector amplitude, and wαare weight factors. For /planckover2pi1ωp∼
3.1e V,the dominant contribution comes from the eight {111}
symmetry directions, so we approximate
1
V/summationdisplay
k/Delta1sh
k=1
(2π)3/summationdisplay
α={111}wα/integraldisplaykBZ
04πk2/Delta1sh
kαdk. (B3)
Instead of eight discrete k-point populations as in Ref. [ 3],
here we consider continuum distributions along the eight one-dimensional klines. While the estimation of optimum weight
factors w
αis beyond the scope of this paper [ 60], the order
of magnitude of the predicted effects is not sensitive to theirprecise value. We fix w
α=wby reproducing the net photohole
density nat one experimentally measured intensity:
n=1
V/summationdisplay
k/summationdisplay
n/Delta1/angbracketleftˆh†
−knˆh−kn/angbracketright
=w
(2π)3/summationdisplay
n/summationdisplay
β={111}/integraldisplaykBZ
04πk2/Delta1/angbracketleftˆh†
kβnˆhkβn/angbracketright. (B4)
For the results of Fig. 4, the photocarrier density n∼6×1018
cm−3for pump fluence ∼7μJ/cm2givesw∼1/15. The same
order of magnitude of nis obtained, however, for all other
reasonable values of w[64]. We then used this weight factor
for all other laser intensities.
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195203-20 |
PhysRevB.69.214409.pdf | Large-angle, gigahertz-rate random telegraph switching induced by spin-momentum transfer
M. R. Pufall, W. H. Rippard, Shehzaad Kaka, S. E. Russek, and T. J. Silva
Electromagnetics Division 818, National Institute of Standards and Technology, Boulder, Colorado 80305, USA
Jordan Katine and Matt Carey
Hitachi Global Storage Technologies, San Jose, California 95120, USA
(Received 14 January 2004; published 8 June 2004 )
We show that a spin-polarized dc current passing through a small magnetic element induces two-state,
random telegraph switching of the magnetization via the spin-momentum transfer effect. The resistances of thestates differ by up to 50% of the change due to complete magnetization reversal. Fluctuations are seen for awide range of currents and magnetic fields, with rates that can exceed 2 GHz, and involve collective motion ofa large volume s10
4nm3dof spins. Switching rate trends with field and current indicate that increasing
temperature alone cannot explain the dynamics. The rates approach a stochastic regime wherein dynamics aregoverned by both precessional motion and thermal perturbations.
DOI: 10.1103/PhysRevB.69.214409 PACS number (s): 72.25.Pn, 85.75. 2d
The recent observations of high-frequency precessional
motion and magnetization switching induced by a spin-polarized dc current have further spurred the study of thespin-momentum transfer (SMT )effect as a possible means of
efficiently switching the small magnetic elements in mag-netic memory, and as the basis for high-frequency,nanometer-sized microwave oscillators.
1–4In addition to
high-frequency precessional motion, the excitation of an un-expected lower-frequency “broadband instability” extendingfrom dc to several gigahertz has also been observed.
1,3Here,
we report real-time measurements of this SMT-inducedlower-frequency response of spin-valve structures, both ofpatterned structures, and of lithographic point contacts madeto continuous films. We show that the broadband instabilityis the result of the magnetization in these structures under-going large-angle fluctuations between two distinct states inresponse to the dc current. These fluctuations have the char-acteristics of classic random telegraph switching (RTS), and
are observed for a wide range of currents and applied mag-netic fields, and for various device geometries and sizes. Thefluctuations occur on time scales ranging from microseconds
to fractions of a nanosecond, and can be observed over thesame range of currents and fields as the coherent high-frequency precessional excitations reported previously.
1,3As
the dimensions of magnetoelectronic devices decrease, as forhard-disk drive read heads and spintronic devices, devicevolumes will reach the point where SMT effects such asthose reported here must be addressed.
Two-state systems exhibiting RTS—that is, each state
having an independent dwell time—have instances across thephysical sciences, from solid-state physics
5–9to biology,10as
well as in magnetic systems.11–13Spin-transfer-induced RTS
at hertz to kilohertz rates has also been observed previously14
for systems in which two well-defined magnetostatic statesare accessible, i.e., when the applied field H
appis less than
Hc, the coercive field of a patterned device with uniaxial
anisotropy. In this case, the spin-transfer current modifies thethermally activated fluctuation rate between the two states.Here we explore spin-transfer-induced effects for larger ap-plied fields H
app.Hc, so that the applied field is of a mag-nitude sufficient to allow only onestable state in the absence
of an applied current.
It has been previously shown that SMT can induce ran-
dom switching15,16of the magnetization between parallel and
antiparallel (relative to the applied field )orientations, at rates
,1 MHz. The observations reported here significantly ex-
tend these measurements, showing that this spin-transfer-induced random telegraph switching persists in higher fields,and out to very high rates (in excess of 1 GHz ). Conse-
quently, these systems approach a dynamical regime inwhich the switching rate approaches the intrinsic dampingrate ofM, and the dynamics of Mhave both precessional
and thermal characteristics. Furthermore, we show that thefluctuation amplitude no longer corresponds to 180° reversalof the magnetization: Instead, the device exhibits resistancechanges of up to 50% of complete reversal, indicating thatthe spin torque induces a second (meta )stable configuration
of the magnetization, the properties of which are a functionof both applied field and current.
These features distinguish spin-transfer-induced telegraph
switching relative to other two-state systems: RTS in otherphysical systems frequently results from the fluctuation of asmall defect or region of a larger structure, typically showingcharacteristic rates from subhertz to megahertz before thebreakdown of two-state behavior. In contrast, SMT-inducedtwo-state switching corresponds to the large-amplitude col-
lectivemotion of the entire device, a volume of <10
4nm3,a t
GHz rates. Though the system is driven by the spin-transfercurrent, we show that nonetheless the general analytical tech-niques developed for the study of two-state switching sys-tems enable us to study in new ways the interaction betweenthe polarized current and the local magnetic moment, and weshow evidence that SMT significantly modifies the energysurface experienced by the free-layer magnetization.
Room-temperature, high-bandwidth I-Vresistance mea-
surements were made on Cu s100 nm d/IrMn s7n m d/
Cos7.5 nm d/Cus4n m d/Cos3n m d/Cus20 nm d/Aus150 nm d
spin-valve structures patterned into 50 3100 nm
2elongated
hexagonal pillars. The exchange bias field from the IrMnPHYSICAL REVIEW B 69, 214409 (2004 )
0163-1829/2004/69 (21)/214409 (5)/$22.50 69214409-1layer s,1m T ddid not have a significant effect on the mag-
netics. The thinner Co layer, having a lower total moment,
responds more readily to spin torques than the thick Colayer.
4These layers are referred to as the “free” magnetiza-
tionMfreeand the “fixed” magnetization Mfixedlayers, re-
spectively [see Fig. 1 (a)inset ]. In a spin valve, changes in
the relative alignment of the magnetizations of these twolayers result in variations in device resistance through thegiant magnetoresistance (GMR )effect. By dc current biasing
the device, these resistance changes are seen as changes inthe voltage across the device. In the following analysis, weassume that all SMT-induced voltage changes in these de-vices are due to GMR.
17,18Measurements were also made on
larger s753150 nm2delongated hexagons, circular devices
of 50–100 nm radii, and lithographically defined 40 nm
point contacts made to unpatterned spin-valve multilayers.3
All devices showed similar RTS, indicating that the bistabil-ity is a generic feature associated with SMT rather than anartifact of a specific device geometry.
When a dc current Iis driven through these devices in the
presence of an in-plane field H
appsufficient to align the mag-
netizations of the two layers, we observe a reversible step inthe dc resistance at a critical current I
c, as has been describedelsewhere.3,4,19A typical dc resistance trace is shown in Fig.
1(a), withIc<6m A (corresponding to a current density Jc
<108A/cm2). This step occurs for only one sign of current,
with electrons flowing from the free to fixed layer [see Fig.
1(a)inset ], indicating that the resistance change is due to
spin torque rather than current-generated magnetic fields.4,20
The position of the step is a function of applied field, and isalso, as shown in the real-time voltage traces in Fig. 1 (b),
correlated as follows with the appearance of two-state tele-graph switching of M
free.15BelowIc, the device lies prima-
rily in the low resistance state, switching occasionally butrapidly into (and out of )the higher resistance state. As the
current approaches I
c[see Fig. 1 (b)], this switching occurs
with greater frequency. The transient switching time betweenthe states is quite fast, and varies with Ifrom 1 ns to 2 ns for
low currents to <0.7 ns for higher I.A sIincreases, the
characteristic time spent in each state changes, with the timespent inR
low(the dwell time tlow)decreasing, and the time in
Rhigh(thigh)increasing. The step in dc resistance occurs
where tlow<thigh. Above Ic,Rhighbecomes most likely (a
fact also reflected in the dc resistance trace ).
The states between which the magnetization switches are
functions of both current and field. From triggered real-timevoltage traces taken at a fixed current and field (taken on a
different device than for the data shown in Fig. 1 ), we deter-
mined the distribution of voltage changes (as it is an ac-
coupled measurement ), and from this calculated the resis-
tance change DRbetween the two states. As shown in Fig.
2(c),DRvaries with current and applied field, and is not
monotonic with Ifor a given H
app, having a maximum value
aroundIc. On the other hand, the peak value in DRdecreases
approximately linearly with Happ, in a manner similar to the
dc resistance step [see Fig. 2 (b)].
FIG. 1. (a)dcI-Vcurve for 100 350 nm2spin-valve nanopillar
device for m0Happ=0.1 T. SMT-induced step in resistance denoted
byIc. Inset graphic shows device structure, field, and current flow
directions. Black circles denote currents for real-time traces shownin lower panel. (b)Real-time ac resistance traces taken at specified
currents. DRdefined as noted on trace at I=5.2 mA, individual
dwell events shown for I=5.7 mA. Device dc response and ac-
coupled time-dependent response monitored as functions of currentand applied field, through 40 GHz probe contacts. Real-time tracesacquired with a 1.5 GHz (sampling rate of 8 310
9/s)bandwidth
single-shot real-time oscilloscope, used to either capture traces upto 8
ms in length [as in Fig. 1 (b)], or to measure pulse widths and
heights of a succession of individual triggered switching events at afixed current and field, as in subsequent figures. Power spectra [see
Fig. 3 (g)]acquired with a 50 GHz spectrum analyzer.
FIG. 2. (Color online )(a)R-Hcurve of device, showing DRfor
180° rotation of layers. (b)dcI-Vtraces for nanopillar, as a function
of field, with current scanned both up and down. Note small hys-teresis between up and down scans, also manifested in dynamic DR
traces and Fig. 3 time traces. (c)Measured dynamic DRfor 100
350 nm
2nanopillar, as a function of current and m0Happ. Device
structure is the same as for Fig. 1. DRdefined as in Fig. 1 (b).DR
determined from 150 triggered switches. Error bars are sx¯from a
Gaussian fit to DRdistribution at fixed I,m0Happ. Right axis: esti-
mated angular deviations of Mfree, using model described in text.M. R. PUFALL et al. PHYSICAL REVIEW B 69, 214409 (2004 )
214409-2Field- [see Fig. 2 (a)]and current-induced switching
measurements4indicate that these devices are sufficiently
small such that the free-layer magnetization vector Mfreebe-
haves as a single domain, and that uMfreeuis not reduced by
the current.21Assuming this, a cosine dependence of Rsud
due to GMR, and taking one of the states as MfreeiMfixed
(because DRand angle are not uniquely related ), we esti-
mated the dynamic rotation angle of the free layer, shown onthe right axis in Fig. 2 (c). The motions of M
freeinduced by
the dc current are not simply small perturbations about equi-librium, as is typically observed in thermally driven two-state magnetic systems:
7,11,13For low fields and currents, the
magnetization rotates a full 90°, a value that decreases to<40° at higher H
appandI. The larger amplitudes previously
observed at lower fields and fluctuation rates15are consistent
with this trend.
The characteristic times thighand tlowat a given Iand
Happwere determined from the conditional probability distri-
bution functions PsRhighuRhighatt=0dandPsRlowuRlowatt
=0d. These probabilities were constructed from multiple trig-
gered real-time traces, and show an exponential falloff with
time. Fitting the expression pstd=e−t/t(in which tis the
elapsed time after a switch, and tisthigh,low )to the measured
distributions gives thighandtlow, shown as functions of Ifor
several fields in Figs. 3 (a)–3(f). Measurements were made
from 4 mA to 12 mA. Dwell times longer than the acquisi-tion wait time (<1 ms before autotriggering )were not re-
cordable; consequently very long dwell times (i.e., quasis-
table magnetic configurations )are indicated by an absence of
dwell times at that current. The
tof each state varies by
several orders of magnitude over the applied current range,corresponding to states that vary from nominally long-liveds
tdwell.8msdto highly unstable stdwell<1n sd. The plots in
Fig. 3 represent quantitatively what was described qualita-
tively for Fig. 1: Initially tlow@thigh, and asIincreases, the
dwell times converge, cross at Ic(at the step in dc
resistance15), and diverge, with thighbecoming the longer
dwell time.
As seen in Figs. 3 (a)–3(f),thighvaries with current in a
markedly different fashion from tlow. On a logarithmic scale,
tlowis roughly linear with current, whereas thighis a more
complicated function of current. Furthermore, the functionalform of
thighis a strong function of applied field, whereas
tlowremains roughly linear, primarily shifting to higher cur-
rents and changing slope slightly. The states, and the poten-tial barrier between them inhibiting fluctuations, are evi-dently distinct functions of current and field. Finally, therange of currents over which fluctuations are observed in-creases with field: The onset current for fluctuations is arelatively weak function of field, while the current at whichfluctuations cease moves rapidly out to higher currents. So,though more field is being applied, the fluctuations are notmore stabilized.
For
m0Happ.0.19 T, the instability is still observed, but
the fluctuation rates exceed the bandwidth of the real-timeoscilloscope. However, with some general assumptions aboutthe system, the dwell times can instead be determined fromthe power spectra. Two state or telegraph noise, in which thedwell times in the two states are independent, produces aLorentzian power spectral density, centered about dc,
9of the
form
Ssvd=DV2
4pthtl
teff21/teff
v2+1/teff2, s1d
in which DV=1DRis the change in voltage, and 1/ teff
=1/thigh+1/tlow. Power spectra for several currents with
m0Happ=0.24 T are shown in Fig. 3 (g). Lorentzians fit the
data well, as shown for I=12 mA. From the width, a teffof
0.37 ns is determined, corresponding to a single-state switch-ing rate in the range 1.4 GHz–2.7 GHz.
22In other devices,
we observed rates in excess of 4 GHz.The lack of deviationsof the spectral shape from a dc-centered Lorentzian indicatesthe validity of the random, two-state assumption. The pre-ponderance of SMT-induced low frequency noise induced inthese devices is due to two-state switching. This signature oftelegraph switching was observed for a wide range of fields:Even fields in excess of 0.5 T were insufficient to suppressthe SMT-induced RTS.
It is important to note that these SMT-induced two-state
fluctuations are observed for applied fields such that, magne-
tostatically , only one orientation of M
freeis allowed: In the
FIG. 3. (a–f)Measured dwell times thighandtlowvs current, for
several applied fields m0Happ. Dwell times determined from mea-
sured conditional probabilities of the form Phighslowdstd
=PsRhighslowduRhighslowdatt=0d, constructed from 150 triggered
events, as described in text. (g)Power spectrum of device at
m0Happ=0.24 T for several device currents. Lorentzian fit to I
=12 mA shown.LARGE-ANGLE, GIGAHERTZ-RATE RANDOM PHYSICAL REVIEW B 69, 214409 (2004 )
214409-3absence of current, no second state into which the magneti-
zation can switch, and the potential surface is parabolic witha single minimum. The spin-polarized current inducesa sec-
ond metastable magnetization configuration at sufficientlyhigh current densities, analogous to an applied field.This is asomewhat surprising conclusion, since typical formulationswrite spin torque as an “antidamping” term in a Landau-Lifshitz-Gilbert dynamical equation, rather than as a field,and damping will ordinarily not affect the energy states of asystem. Indeed, while single-domain numerical models
1,23
based on Slonczewski’s theory of SMT-induced magnetiza-tion dynamics
20have reproduced aspects of the precessional
motion observed in Refs. 1 and 3, these models fail to de-scribe this broadband instability. Stochastic switching hasbeen observed in simulations, but either only over small cur-rent ranges near transitions between two different current-dependent precessional states (rather than over a large range
ofIas shown here )or between two states with identical
GMR values.
24In addition, these simulations describe fluc-
tuations between precessional states. However, we have ob-served two-state switching both in the presence of and inde-
pendent of the existence of high-frequency precessional
signals, up to the bandwidth limit of our system (<12 GHz,
for the nanopillar structures, 40 GHz for the lithographicpoint contacts ).
The random occurrences of the two-state fluctuations such
as those shown in Fig. 1 (b)certainly suggest an Arrhenius-
Néel two-state analysis describing a thermally activated pro-cess over a barrier as a way of parametrizing the effects ofthe spin torque and the applied field on the system. Previouswork also used anArrhenius-type analysis to parametrize thelow-frequency RTS, employing an independent magnetictemperature for each state.
15This work used a two-
temperature model that does not succeed in describing ourdata over the ranges of currents and fields presented here;
25
here we will use a single-temperature model. A possiblecomplicating factor against using anArrhenius-Néel analysis(a factor that also drives new effects such as the observed
high-frequency precession
3)is that torques due to SMT are
not conservative, and as a consequence the work done by thetorque is path dependent.
26Therefore, it is not necessarily the
case that a “barrier” is well defined for this system. None-theless, previous experimental
14and theoretical26work sup-
ports the applicability of a two-state model27if the energy
barrier is replaced by an “activation energy” that includes thework done by the spin torque.
Subject to these caveats, the expression
thigh,low=t0eUsI,Hdhigh,low/kBTs2d
describes the characteristic time tfor thermal activation over
a barrier, in which UsI,Hdhigh,loware the respective effective
barrier heights for the high and low resistance states (shown
schematically in Fig. 4 ),1/t0is the “attempt frequency,” kB
is Boltzmann’s constant, and Tis the magnetic system tem-
perature, which is possibly different from the phonon (sys-
tem)temperature. By comparing ln sthigh/tlowd=sUhigh
−Ulowd/kBTto ln sthightlow/t02d=sUhigh+Ulowd/kBTwe can
estimate a upperlimit on t0of 1 ns,28of the same order as
the dwell time determined from the power spectrum in Fig.3(b). The attempt frequency 1/ t0is set by the intrinsic
damping rate of Mand is typically several gigahertz for
these systems,29consistent with these values.
Assuming a value of 0.5 ns for t0, we calculated the ef-
fective barrier heights Uhigh/kBTandUlow/kBTas a function
ofI, shown for several fields in Fig. 4. These plots show that
the current modifies the effective barrier seen by each statefrom roughly 1 k
BTto 10kBTover the measurement range.
By comparison, the barrier height between the two bistablestates at zero field and current is over hundred times thisvalue. As expected, the barrier heights vary opposite to eachother with current. For low currents, the low resistancesM
freeiMfixeddstate is preferred, having a larger barrier im-
peding escape, while the high resistance state becomes the
more probable state at higher currents with I.Ic. Recall that
this high-resistance state does not exist in the absence of thecurrent for these applied fields, as there is no secondary po-tential minimum. In Fig 4, we can see evolution of the state,with the current progressively increasing the barrier heightdefining it. However, though the two barriers have oppositetrends with current, the functional forms are markedly differ-ent:U
lowis roughly a linear function of I, whileUhighdis-
plays a more complicated dependence. In this sense, theseresults deviate substantially from previous, low-frequencySMT-mediated two-state switching data
14,15in which both
states showed a linear dependence on current (though over a
smaller field and current range ). In addition, it is also clear
that the effective barrier heights do not asymptotically ap-proach zero with increasing current, as would be the case ifan Ohmic or other monotonic temperature increase were thesource of the telegraph noise. Indeed, temperatures far abovethe Curie temperature of the ferromagnet would be requiredto reduce the ratio U/k
BTsufficiently to approach the ob-
served switching rates.
We have shown that a spin-polarized dc current passing
through a small magnetic element induces an instability in
FIG. 4. (Color online )Plot of calculated effective energy barri-
ersUhighandUlow, in units of kBT, as a function of current for
several fields. A value of t0=0.5 ns was assumed. Data for up and
down scans of current averaged together for clarity. Inset: Diagramshowing definition of effective energy barriers.M. R. PUFALL et al. PHYSICAL REVIEW B 69, 214409 (2004 )
214409-4the magnetization, resulting in classic two-state, random tele-
graph switching for a wide range of currents and for appliedmagnetic fields that magnetostatically allow only one orien-tation ofM.Alarge magnetic volume collectively undergoes
large-amplitude fluctuations between two states, at gigahertzrates, resulting in a broadband dc-centered Lorentzian powerspectrum. These fast fluctuation rates suggest that SMT sig-nificantly modifies the potential surface experienced by M.The fluctuation rate trends observed with applied field and
current indicate that an increase in temperature — whether ofthe device or magnetic system—does not by itself describethe dynamics. With the rapidly shrinking device dimensionsin magnetoelectronics, device volumes will reach the pointwhere SMT effects are unavoidable. The results presentedhere indicate that attention should be paid to SMT-induceddynamics as a source of broadband, large-amplitude noise.
1S. I. Kiselev et al., Nature (London )425, 380 (2003 ).
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35, 2592 (1999 ).
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18While other sources of voltage have been proposed [see L.
Berger, Phys. Rev. B 54, 9353 (1996 )], previous work usingGMR to sense time-varying magnetization motion indicates that
GMR is the dominant source of ac or dc impedance change inspin-valve devices. For example, see Refs. 1 and 3. The mea-surement geometry makes inductive coupling between the de-vice and waveguide negligible.
19M. R. Pufall, W. H. Rippard, and T. J. Silva, Appl. Phys. Lett. 83,
323(2003 ).
20J. C. Slonczewski, J. Magn. Magn. Mater. 159,L 1 (1996 ).
21B. Özyilmaz et al., Phys. Rev. Lett. 91, 067203 (2003 ).
22Knowing DR, and also which is the more likely of the two states,
one can invert these spectra to determine the respective dwelltimes. However, because DRis a function of both current and
field, this is not possible for switching rates faster than 1.5 GHz(our oscilloscope bandwidth ).
23J. Z. Sun, Phys. Rev. B 62, 570 (2000 ).
24Z. Li and S. Zhang, Phys. Rev. B 68, 024404 (2003 ).
25The applied fields and currents used here are too large, so that the
“magnetic temperature” will exceed the Curie temperature of themagnet.Also, the energy barriers in this theory are only affectedby the current by the reduction of M
sthrough the increase in
effective temperature.
26Z. Li and S. Zhang, cond-mat/0302339 (unpublished ).
27This assumes that the damping and the out-of-plane component of
Mremain small. Simulations suggest that the second assumption
is questionable for SMT-induced precessional modes.
28Equivalently, the shortest dwells we observe are <1 ns.
29N. D. Rizzo, T. J. Silva, and A. B. Kos, Phys. Rev. Lett. 83, 4876
(1999 ).LARGE-ANGLE, GIGAHERTZ-RATE RANDOM PHYSICAL REVIEW B 69, 214409 (2004 )
214409-5 |
PhysRevB.89.064412.pdf | PHYSICAL REVIEW B 89, 064412 (2014)
Theory of magnon-skyrmion scattering in chiral magnets
Junichi Iwasaki,1,*Aron J. Beekman,2and Naoto Nagaosa2,1,†
1Department of Applied Physics, The University of Tokyo, 7-3-1, Hongo, Bunkyo-ku, Tokyo 113-8656, Japan
2RIKEN Center for Emergent Matter Science (CEMS), Wako, Saitama 351-0198, Japan
(Received 9 September 2013; published 14 February 2014)
We study theoretically the dynamics of magnons in the presence of a single skyrmion in chiral magnets
featuring Dzyaloshinskii-Moriya interaction. We show by micromagnetic simulations that the scattering processof magnons by a skyrmion can be clearly defined although both originate in the common spins. We find that (i) themagnons are deflected by a skyrmion, with the angle strongly dependent on the magnon wave number due to theeffective magnetic field of the topological texture, and (ii) the skyrmion motion is driven by magnon scatteringthrough exchange of the momenta between the magnons and a skyrmion: the total momentum is conserved. Thisdemonstrates that the skyrmion has a well-defined, though highly non-Newtonian, momentum.
DOI: 10.1103/PhysRevB.89.064412 PACS number(s): 75 .78.−n,75.30.Ds,12.39.Dc,75.78.Cd
I. INTRODUCTION
The skyrmion is a topological texture of field configu-
ration and was first proposed as a model for hadrons innuclear physics [ 1,2] and has been discussed in a variety
of condensed-matter systems [ 3–6]. Most recently skyrmions
have been found in magnets with Dzyaloshinskii–Moriya(DM) interaction, attracting intensive interest [ 7–10]. Here
it is a swirling spin structure characterized by the skyrmionnumber Q, which counts how many times the mapping from
the two-dimensional real space to the spin space wraps thesurface of the sphere. The skyrmion has a finite size determinedby the ratio of the ferromagentic exchange interaction J
and the DM interaction D, i.e., localized in real space
within 3–100 nm, and has very long lifetime because oftopological protection, i.e., any continuous deformation ofthe field configuration cannot change the skyrmion number.Therefore, the skyrmion can be regarded as a particle made outof the spin field. These advantages, i.e., small size and stability,together with ultralow threshold current density for the motion(∼10
6A/m2)[11,12] compared with that for the domain-wall
motion ( ∼1010–1012A/m2)[13,14], make the skyrmion an
appealing and promising candidate as an information carrierin magnetic devices [ 15–18].
On the other hand, the low-energy excitations in magnets
are magnons [ 19]: propagating small disturbances in the under-
lying spin texture. In sharp contrast to the skyrmion, a magnonis a propagating wave, and can be created and destroyed easily,i.e., it belongs to the topologically trivial sector. Therefore,an important issue is the interaction between magnons andskyrmions, which offers an ideal laboratory to examine theparticle-field interaction in field theory, and also provides thebasis for the finite temperature behavior of skyrmions. It hasbeen known that the motion of a domain wall in ferromagnetscan be induced by magnons: the domain wall moves againstthe direction of the magnon current [ 20–22]. Recently the
skyrmion version of the magnon-induced motion has been
*iwasaki@appi.t.u-tokyo.ac.jp
†nagaosa@riken.jpstudied [ 23,24], when magnons are produced by a temperature
gradient. However, the elementary process involving a singleskyrmion and magnons has not been studied up to now. Theonly work on magnon-skyrmion dynamics we are aware of(Ref. [ 25]) precludes from the outset, in the context of quantum
Hall systems, any skew scattering, which does not agree withthe observations in chiral magnets. Another work consideredmagnon scattering off skyrmions in time-reversal invariantsystems [ 26].
The skyrmion is characterized by a spin gauge field aand
carries an emergent magnetic flux b=∇× aassociated with
the solid angle subtended by the spins. This spin gauge field ais
coupled to the conduction electrons, which results in nontrivialeffects such as the spin transfer torque driven skyrmion motionand topological Hall effect. Surprisingly, a tiny current density∼10
6A/m2can drive the motion of the skyrmion crystal via
spin transfer torque [ 11,12], which is orders of magnitude
smaller than that in domain-wall motion in ferromagnets(10
10–1012A/m2)[13,14]. This has been attributed to the
Magnus force acting on the skyrmion and its flexible shapedeformation reducing the threshold current [ 27,28]. An in-
teresting recent development is the discovery of skyrmions
in an insulating magnet Cu
2OSeO 3[10,29,30], where the
electric-field-induced motion is associated with multiferroicbehavior. It is expected that in this insulating system, theonly low-energy relevant excitations are the magnons, and theinteraction between magnon and skyrmion becomes especiallyrelevant.
In this paper, we study the scattering process of a magnon
by a skyrmion by solving numerically the Landau-Lifshitz-Gilbert (LLG) equation for magnons with the center of wavenumbers kincident on a skyrmion of size ξin Sec. II.
The simulations clearly show wave-number-dependent skewscattering of the magnon, and furthermore similar large Hallangle of skyrmion motion due to the back action. This processis well analyzed in terms of momentum conservation, stronglyindicating that the skyrmion is particlelike with a well-definedmomentum as worked out in Sec. III. By mapping the situation
to a charged particle scattered by a tube of magnetic fluxwe show in Sec. IVthat the principal contribution to skew
scattering is the emergent Lorentz force generated by theskyrmion.
1098-0121/2014/89(6)/064412(7) 064412-1 ©2014 American Physical SocietyJUNICHI IW ASAKI, ARON J. BEEKMAN, AND NAOTO NAGAOSA PHYSICAL REVIEW B 89, 064412 (2014)
(a1) t=0 (a2) t=250 (a3) t=1000 (a4) t=2000
(b1) t=0 (b2) t=500 (b3) t=2000 (b4) t=3000
(c1) t=0 (c2) t=2000 (c3) t=4000 (c4) t=8000
kξ=0.52 π kξ=0.83 π kξ=1.87 π
Φφ
ξ
ξ
ξλ
λ
λ
FIG. 1. (Color online) Snapshots of scattering processes with three different wave numbers. (a1)–(a4): ¯kξ/similarequal1.87π; (b1)–(b4): ¯kξ/similarequal0.83π;
(c1)–(c4): ¯kξ/similarequal0.52π; time steps of the snapshots as indicated. The inset of (a1) shows the color representation of the in-plane spin component
in (xy) spin space. In (a1), (b1), and (c1), the wavelengths λ≡2π/¯kof the incident waves are compared with the size of the skyrmion ξ.T h e
vertical blue line in (a4), (b4), and (c4) denotes the incoming magnon direction. For the higher wave numbers we can clearly identify the skewscattering of the magnons. In (a4) the white dashed lines indicate the equal phase contour of the scattered magnons, and blue line perpendicular
to those defines the scattering skew angle ¯ ϕ. The yellow lines represent the path traversed by the skyrmion, also clearly showing skew scattering
over an angle /Phi1. Hence we see that the skyrmion skew angle is nearly half of the magnon skew angle as expected from the conservation of the
momentum.
II. NUMERICAL RESULTS
Our model is the chiral magnet on the 2D square lattice:
H=−J/summationdisplay
rmr·/parenleftbig
mr+aex+mr+aey/parenrightbig
−D/summationdisplay
r/parenleftbig
mr×mr+aex·ex+mr×mr+aey·ey/parenrightbig
−B/summationdisplay
r(mr)z. (1)
Here, mris the unit vector representing the direction of
the local magnetic moment and ais the lattice constant. In
the following, we measure all physical quantities in units ofJ=/planckover2pi1=a=1, where /planckover2pi1is the reduced Planck constant. For a
typical set of parameters J=1 meV and a=0.5 nm, in these
units we have the correspondences for time t=1: 6.58×
10
−13s; mass M=1: 2.78×10−28kg; and magnetic field
B=1: 17.3 T. We fix DM interaction D=0.18. The ground
state for the Hamitonian ( 1) is the helical state for external field
B<B c1=0.0075, the ferromagnetic state for B>B c2=
0.0252, and the skyrmion crystal for Bc1<B<B c2[28].
To study the scattering of magnon plane waves off a single
skyrmion, we have performed micromagnetic simulationsbased on the Landau-Lifshitz-Gilbert (LLG) equation:
dm
r
dt=−mr×Beff
r+αmr×dmr
dt, (2)where αis the Gilbert damping coefficient fixed to α=0.04 in
the whole paper and Beff
r=−∂H
∂mr. We perform the simulation
atB=0.0278 ( >B c2), putting a metastable skyrmion at the
center of ferromagnetic background [Fig. 1(a1)]. The size of
the skyrmion ξin this paper is defined as the distance from the
core (mz=− 1) to the perimeter ( mz=0), and ξ=8 for our
parameter set. At the lower boundary a forced oscillation offrequency ωwith fixed amplitude A≡/angbracketleftm
2
x+m2
y/angbracketright=0.0669 is
imposed on the spins, producing spin waves with wave vectork=(0,k) traveling toward the top. Here, the amplitude of the
magnon with wave number kis proportional to
1
ω2−ω2
k+iαω,
where ωkis the dispersion of the magnon with energy gap B.
We estimated the averaged ¯kfrom the real-space image of the
magnon propagation. For ω=0.08,0.04,0.02,0.0125,and
0.01, we find ¯kξ/similarequal1.87π,1.20π,0.83π,0.64π, and 0 .52π,
respectively. Note that the latter three frequencies are belowthe magnon gap.
Figure 1shows snapshots of the scattering processes with
three different wavelengths (see also Supplemental Material,movies 1 and 2 [ 31]). These lead to several remarkable
observations. First, one can clearly see that the identity ofthe skyrmion remains intact even though some distortion ofits shape occurs. This originates in the topological protection,and is not a trivial fact since both the skyrmion and magnonsare made out of the same spins. Namely, the skyrmion numberQ=
1
4π/integraltext
d2xm·(∂xm×∂ym)i s−1 for the skyrmion while
that of magnons is zero, and hence the conservation of
064412-2THEORY OF MAGNON-SKYRMION SCATTERING IN . . . PHYSICAL REVIEW B 89, 064412 (2014)
0 5 10 15 20 25 30 35 40
0 0.5 1 1.5 2 2.5 0 0.005 0.01 0.015 0.02Φ (o)
v
k (π/ξ)skyrmion Hall angle
skyrmion velocity
(a) (b) (c)
FIG. 2. (Color online) The scattering properties obtained by numerical and analytical calculations. (a) The Hall angles /Phi1(red line)
and velocities v(blue line) of skyrmion motion are estimated from the numerical results for different wave numbers ¯k. To obtain
these values, we traced the center-of-mass coordinate Rof a skyrmion between Y=51 and Y=31. The coordinate Ris defined as
R≡/integraltext
d2rρtop(r)r//integraltext
d2rρtop(r), where ρtop(r)≡m(r)·[∂xm(r)×∂ym(r)]. There is a strong nonmonotonic wave-number-dependent behavior
in both quantities. We compare these observations to the idealized cases of magnons scattering off a uniform flux tube by an Aharonov-Bohm-typecalculation: (b) Expectation of the magnon Hall angle ¯ ϕas a function of wave number k. It is strongly peaked around kξ≈1, and vanishes
for both low and high wave number, in the latter case as ∼1/k. The relation /Phi1=¯ϕ/2 derived by momentum conservation seems to be well
obeyed by comparing images (a) and (b). (c) Magnon scattering amplitude of several wave numbers k. The asymmetry in left or right scattering
can be clearly seen and is due to the effective Lorentz force induced by the Berry phase of the skyrmion. For low wave numbers, the scattering
amplitude is almost flat, indicating the wave “missing” or “ignoring” the skyrmion; for high wave numbers it is strongly peaked, indicating
mostly forward scattering, which is well known in the Aharonov-Bohm effect.
the skyrmion number protects the identity of the skyrmion.
Second, the incident wave is clearly scattered by the skyrmion,with sizable “skew angle” or “Hall angle.” As the wavenumber ¯kis increased, the diffraction becomes smaller and
one can define the trajectory of the scattered magnons clearlyin Figs. 1(a1)–1(a4) for ¯kξ/similarequal1.87π. As shown in the blue
lines in Fig. 1(a4), the scattered trajectory has an angle ¯ ϕ
compared with the direction of the incident magnons (verticalline). As the wave number ¯kis reduced, the diffraction is
enhanced, but the skewness of the scattered waves can still beseen in Figs. 1(b2)–1(b4) for ¯kξ/similarequal0.83πand 1(c2)–1(c4) for
¯kξ/similarequal0.52π. Therefore, the skew angle ¯ ϕstrongly depends
on¯kξ. Third, by tracing the center-of-mass position of the
skyrmion, it is found that it moves in turn backward andsidewards in the opposite direction as indicated by the yellowlines in Figs. 1(a4), 1(b4), and 1(c4). The skew angle /Phi1of the
skyrmion motion is plotted in Fig. 2(a), which shows strong
¯kdependence. Also the speed vof the skyrmion depends on
the wave number ¯kfor fixed amplitudes of the magnons, as
s h o w ni nF i g . 2(a). This skyrmion motion can be understood by
the magnons exerting spin transfer torque on the skyrmion, orequivalently analyzed in the light of momentum conservationas will be discussed below.
III. SKYRMION MOMENTUM
The dynamic term of a skyrmion particle is Sdyn=/integraltext
dtL,
where [ 32]
L=2πQ(Y∂tX−X∂tY)+M
2[(∂tX)2+(∂tY)2]. (3)
Here, X,Y are the skyrmion center-of-mass coordinates, and
Mis the mass of the skyrmion. Then the momentum is
Px=∂L
∂∂tX=2πQY+M∂tXandPy=∂L
∂∂tY=− 2πQX +
M∂tY. Assuming a massless skyrmion ( M=0) and elastic
scattering ( p(in)
mag=p(out)
mag+/Delta1Pskyrm ), we can estimate the skewangle as follows. For the magnon p(in)
mag=(0,k) and p(out)
mag=
(ksin ¯ϕ,kcos ¯ϕ), then
/Delta1Pskyrm=(−ksin ¯ϕ,k(1−cos ¯ϕ)). (4)
Using Px=2πQY,P y=− 2πQX one finds the skyrmion
Hall angle:
/Phi1=arctan( /Delta1X//Delta1Y )=¯ϕ/2. (5)
The numerics, i.e., /Phi1and ¯ϕin Fig. 1(a4), is consistent with
this relation. In the present simulation, the displacement /Delta1R
of the skyrmion is about 30, over the time period of 2000forkξ/similarequal1.87π. The velocity vis of the order of 30 /2000∼=
1.5×10
−2.T h em a s s Mis of the order of the number of spins
constituting one skyrmion and is of the order of 200 in oursimulation. Therefore, Mv∼3/lessmuch2π/Delta1R ∼200, and hence
the assumption of the massless skyrmion above is justified.
We can estimate the velocity of the skyrmion purely in terms
of momentum transfer of the spin wave to the skyrmion. A
plane wave√
Ae−iωt+i¯kyhas momentum p(in)=A¯k. The part
of the incident wave that interacts with the skyrmion is of size2ξ, the diameter of the skyrmion. Hence the momentum of the
part of the magnon plane wave interacting with the skyrmionisk=2ξA¯k. The magnitude of the transferred skyrmion
momentum is |/Delta1P
skyrm|=k√2−2 cos ¯ϕ=4ξA¯ksin1
2¯ϕ.
Now we are sending in a continuous plane wave instead
of a single magnon. The time it takes for the plane wave topass by/through the skyrmion is T
k≡2ξ/vkwhere vkis the
group velocity of the magnon, given by vk=∂ωk
∂k=2Jk, and
ωk=Jk2+Bis the magnon dispersion. Hence in one unit
of time, the plane wave interacts with the 1 /Tkpart of the
skyrmion. Thus the amount of momentum transferred in oneunit of time is
/Delta1˜P≡|/Delta1P
skyrm|
Tk=4ξA¯ksin1
2¯ϕ
2ξ/2J¯k=4JA¯k2sin1
2¯ϕ. (6)
064412-3JUNICHI IW ASAKI, ARON J. BEEKMAN, AND NAOTO NAGAOSA PHYSICAL REVIEW B 89, 064412 (2014)
In our units J=1. The incoming magnons of average
wave number ¯kare generated by a forced oscillation with
magnitude A≡/angbracketleftm2
x+m2
y/angbracketright=0.0669 per lattice spin. For
the case of ¯kξ=1.87π(¯k=1.87π/ξ=1.87π/8≈0.73) we
find ¯ϕ/2≈15◦,s os i n ¯ ϕ/2≈0.26 [see Fig. 1(a4)]. In this case
we therefore find /Delta1˜P≈0.036 and skyrmion velocity V=
/Delta1˜P/2π=0.0058. This is different from the value obtained
in the simulations (0 .015) by a factor of ∼=2.5 [Fig. 2(a)], but
considering the rough and tentative nature of the estimate, theagreement is rather good.
These simple momentum conservation considerations lead
us to conclude that the skyrmion is a particle with well-defined momentum, that nevertheless defies the Newtonianintuition. For instance, here an elastic scattering process causesbackwards motion of the skyrmion, which is impossible forNewtonian particles.
IV . EFFECTIVE MAGNETIC FIELD
To further identify the nature of the magnon skew scattering,
we map the situation onto that of a charged particle (themagnon) moving in the background of a static magnetic field(the skyrmion), assuming the disturbances of the magnon onthe emergent fictitious magnetic field are small. The emergentfield corresponds to the skyrmion number, so the sign ofthe scattering direction is fixed, but would be opposite foran antiskyrmion configuration. This situation correspondsprecisely to Aharonov-Bohm (AB) scattering, and usingresults from the extensive literature [ 33–37], we shall derive an
exact expression for the scattering amplitude of the magnon.
In the continuum limit, the Hamiltonian Eq. ( 1) for the local
moments m(x,y) reads
H=/integraldisplay
d
2x/bracketleftbiggJ
2(∇m)2+Dm·(∇×m)−B·m/bracketrightbigg
.(7)
We can make a change of variables to a complex 2-vector
zρ=(z↑,z↓)( aCP1field) via m=z∗
ρσρσzσ, where σρσare
the Pauli matrices and the constraint/summationtext
ρ|zρ|2=1m u s tb e
imposed [ 38]. The Hamiltonian turns into
H=/integraldisplay
d2x2J|(∇+ia+iκσ)zρ|2−B·z∗
ρσρσzσ,(8)
where κ=D/2Janda=iz∗
ρ∇zρ. The Hamiltonian is invari-
ant under gauge transformations zρ→zρeiεanda→a+∇ε,
where ε(r) is any smooth scalar field. The gauge field is related
to the Berry curvature b=∇× a, and the skyrmion number
Q≡1
4π/integraltext
d2xbz=1
4π/integraltext
d2xm·(∂xm×∂ym) is quantized.
We now separate zρ=˘zρ+z0
ρinto magnon and skyrmion
contributions, and assume that a static skyrmion a0of size ξ
withQ=− 1 has formed while the magnons ˘zρmove in this
skyrmion background. A typical skyrmion solution in polarcoordinates is a
r=0,a ϕ=r
ξ2+r2. For small deviations from
this background configuration we need only to consider the
exchange term; the DM and Zeeman contributions are constanton this energy scale. Summarizing, we are considering thelow-energy dynamics of
H
LE=/integraldisplay
d2x2J|(∇+ia0)˘zρ|2. (9)This is precisely the Hamiltonian of a charged particle moving
in an external magnetic field b0=∇× a0. Notice that the
components ˘z↑,˘z↓are now decoupled at this level of the
approximation. We are interested in the scattering outcomeof an incoming plane wave, far away from the origin ofthe skyrmion. Then in this ferromagnetic regime, the spinspoint along the out-of-plane zdirection, and we can make the
approximation z
↑≈1. In other words, we only consider the
field ˘z↓.
The problem of a charged particle scattered by a magnetic
flux was intensively studied in and after the discovery ofthe Aharonov-Bohm (AB) effect [ 33–37]. There, one is
usually interested in the case that the particle does not enterregions of finite magnetic flux, but nevertheless the case of auniform magnetic flux tube of radius ξhas been considered
in Refs. [ 34–37]. They also consider an electrostatic shielding
potential Vto prevent the particle from entering the region of
nonzero flux, but the results are in fact general for any V, and
the limit of V→0 may be taken without additional treatment,
as we do from now on. To make use of these establishedresults we shall approximate our smooth skyrmion potentiala
ϕ=r/(ξ2+r2) with that of a uniform magnetic flux:
aϕ=/braceleftbigg1/r, r /greaterorequalslantξ,
r/ξ2,r/lessorequalslantξ.(10)
One can verify that the total fictitious flux Qis the same for
both potentials (in the AB setup, the value of Qcorresponds
to the product of the electric charge and magnetic flux). As the
magnon will principally scatter due to the fictitious Lorentz
force, this approximation will not deviate too much fromthe actual situation, and has the advantage of allowing foran exact solution. The full derivation is quite technical andnot essentially different from the earlier work and is deferredto the Appendix. The wave function can then be expressedin terms of Bessel functions, with coefficients determined bythe properties of the flux tube. The wave function outsideof the flux tube ˘z
>can be written as a superposition of an
incoming plane wave and a scattered spherical wave, ˘z>=
exp(ikx)+F(ϕ)exp(ikr)√rwhere F(ϕ) is called the scattering
amplitude. In the Appendix it is derived that the exact solution
for the scattering amplitude is
F(ϕ)=fAB(ϕ)+e−iπ/4
√
2πk∞/summationdisplay
n=−∞eiπ(n−|n+Q|)(e2i/Delta1n−1)einϕ.
(11)
Here the AB contribution fAB(ϕ) vanishes for integer
skyrmion number Q, and /Delta1nis the phase shift of the nth
partial wave.
The scattering amplitude is evaluated numerically; the
results are shown in Figs. 2(b) and 2(c).W ec l e a r l ys e ea
large skew angle at the scattering of the magnon for k≈1/ξ.
For both very low and very high wave numbers the skew angletends to zero, and the maximum skew angle is about 60
◦around
¯kξ≈1.1.
V . CONCLUSIONS
We have studied the scattering process of magnons and
a skyrmion both numerically and analytically. The numerics
064412-4THEORY OF MAGNON-SKYRMION SCATTERING IN . . . PHYSICAL REVIEW B 89, 064412 (2014)
show a large skew angle of the magnon scattering, and
skyrmion motion as the back action of the scattering. Wehave demonstrated that the principal contribution of the skewscattering is due to the emergent magnetic field generated bythe Berry curvature of the skyrmion. The obtained scatteringamplitude shows that the magnon skew scattering is stronglywave-number dependent, up to 60
◦around kξ=1.1, which is
consistent with the numerical results. This should be comparedwith the case of topological Hall effect of the conductionelectrons coupled to the skyrmions [ 39–42], where the Hall
angle is typically of the order of 10
−3because the Fermi wave
number kFof the electrons is much larger than ξ−1. For both
very low and very high wave numbers the skew angle tends tozero. For large k, the skew angle is reduced and asymptotically
behaves as ∝1/k. This indicates that the velocity of the
skyrmion induced by the back action should increase linearlyin the large kregion of Fig. 2(a) since the momentum transfer
from magnons to skyrmion is ∝k
2×/Phi1∼k2×1/k∼kin
that region assuming the elastic scattering. Unfortunately, thislargeklimit was not successfully analyzed in the numerical
simulation due to a technical difficulty, which requires furtherstudies.
The skyrmion retains its identity during the scattering
process as a result of topological protection. Furthermore,the skyrmion can be interpreted as a (semiclassical) particlewith a well-defined momentum which is however highlynon-Newtonian. The observed behavior can then simply beviewed as an elastic scattering process, and the skyrmion isnearly massless in this situation.
Due to the topological nature of the interaction, the magnon
scattering of a skyrmion is qualitatively different from otherscattering, namely it has a transverse component. Thereforeany experimental signature of transverse motion of magnonswould be evidence of the presence of skyrmions, sincetopologically trivial configurations such as magnetic bubblesor domain walls cannot induce skew scattering. We are ledto think that insulating systems such as Cu
2OSeO 3, in which
there are no conduction electrons, would be most suitable forsuch studies. One promising way of inducing spin waves is viathe inverse Faraday effect using laser light [ 43].
ACKNOWLEDGMENTS
The authors thank M. Mochizuki for providing us the
basic code of the micromagnetic simulation. This work wassupported by Grant-in-Aids for Scientific Research (GrantNo. 24224009) from the Ministry of Education, Culture,Sports, Science and Technology (MEXT) of Japan, StrategicInternational Cooperative Program (Joint Research Type) fromJapan Science and Technology Agency, and by FundingProgram for World-Leading Innovative R&D on Science andTechnology (FIRST Program). A.J.B. was supported by theForeign Postdoctoral Researcher program at RIKEN.
APPENDIX: DERIVATION OF
THE SCATTERING AMPLITUDE
Here we derive Eq. ( 11). For a0=0E q .( 9) describes plane
waves of energy E=a2Jk2, where ais the lattice constant
andkis the wave number. For nonzero a0the equation ofmotion for a particle of this energy reads in polar coordinates
/bracketleftbigg
∂2
r+1
r∂r+1
r2[∂ϕ−ir(−Q)aϕ]2+k2/bracketrightbigg
˘z↓=0.(A1)
Here we tentatively allow the skyrmion number Qto deviate
from the value −1. The only term dependent on ϕis the one
involving ∂ϕ, and we can make a partial wave expansion
˘z↓(r,ϕ)=/summationtext
n˘zn=/summationtext
nwn(r)einϕ.F o r r/greaterorequalslantξ,t h e wnare
eigenfunctions of the equation
/bracketleftbigg
∂2
r+1
r∂r+k21
r2(n+Q)2/bracketrightbigg
w>
n=0. (A2)
This is precisely Bessel’s equation, and the general solution is
˘z>
n=einϕ[anJ|n+Q|(kr)+bnY|n+Q|(kr)]. (A3)
For the region r/lessorequalslantξ, the Schr ¨odinger equation reads
/bracketleftbigg
∂2
r+1
r∂r−1
r2/parenleftbigg
n+Qr2
ξ2/parenrightbigg2
+k2/bracketrightbigg
w<
n(r)=0.(A4)
We make a change of variables v=Qr2/ξ2andfn(v)=
rw<
n(r). The above equation is then rewritten as
/bracketleftbigg
∂2
v+1/4−n2/4
v2+k2ξ2/4Q−n/2
v−1
4/bracketrightbigg
fn(v)=0.
(A5)
This is known as Whittaker’s equation for the parameters
κ=k2ξ2/4Q−n/2 and μ2=n2/4. The solutions, known
as Whittaker functions Mκ,μ(v), are not well defined for
μ=− 1,−2,..., but for our purposes it suffices to choose
μ=|n/2|. These solutions are
fn(v)=Mκ,μ(v)=e−z/2zμ+1/2/Phi1/parenleftbig1
2+μ−κ,2μ+1,v/parenrightbig
,
(A6)
where /Phi1is the confluent hypergeometric series,
/Phi1(a,c,v )=1+a
cv+a(a+1)
c(c+1)1
2!v2+··· . (A7)
Continuity in the wave function and its first derivative at the
matching point r=ξleads to the equalities
cnw<
n(ξ)=anJ|n+Q|(kξ)+bnY|n+Q|(kξ), (A8)
[cn∂rw<
n(r)=an∂rJ|n+Q|(kr)+bn∂rY|n+Q|(kr)]r=ξ.(A9)
With the notation /Phi1κ,μ(v)=/Phi1(1
2+μ−κ,2μ+1,v) one can
derive
∂rw<
n/vextendsingle/vextendsingle
r=ξ=Mκ,μ(Q)
ξ2/parenleftbigg
|n|−Q+2Q∂v/Phi1κ,μ(v)/vextendsingle/vextendsingle
v=Q
/Phi1κ,μ(Q)/parenrightbigg
.
(A10)
Substituting Eq. ( A8)i nE q .( A9) we eventually find
bn
an=−AnJ|n+Q|−∂¯rJ|n+Q|(¯r)/vextendsingle/vextendsingle
¯r=kξ
AnY|n+Q|−∂¯rY|n+Q|(¯r)/vextendsingle/vextendsingle
¯r=kξ, (A11)
064412-5JUNICHI IW ASAKI, ARON J. BEEKMAN, AND NAOTO NAGAOSA PHYSICAL REVIEW B 89, 064412 (2014)
where we have defined
An=1
kξ/parenleftbigg
|n|−Q+2Q∂v/Phi1κ,μ(v)/vextendsingle/vextendsingle
v=α
/Phi1κ,μ(α)/parenrightbigg
. (A12)
We expect to retrieve the Aharonov-Bohm result,
˘zAB=∞/summationdisplay
n=−∞einϕeiδAB
nJ|n+Q|(kr), (A13)
where δAB=− |n+Q|π/2, in the limits of vanishing
skyrmion size ξ→0 or vanishing flux Q→0. Brown [ 37]
has shown that the solution
an=cos/Delta1nei/Delta1neiδAB,b n=sin/Delta1nei/Delta1neiδAB,(A14)
which defines the partial wave shifts /Delta1nin terms of anand
bn, corresponds to an incoming plane wave and an outgoing
propagating scattered wave, and this solution does reduce tothe AB results in the mentioned limits, for which all /Delta1
n≡
tan(−bn/an)→0. Brown has also shown that, for any Q,
/Delta1n→0a sn→∞ , and in practice the /Delta1nvanish quicklyforn>k ξ . Writing the solution as the superposition of an
incoming and a scattered wave, ˘z>=exp(ikx)+F(ϕ)exp(ikr)√r,
Brown obtains the scattering amplitude,
F(ϕ)=fAB(ϕ)
+e−iπ/4
√
2πk∞/summationdisplay
n=−∞eiπ(n−|n+Q|)(e2i/Delta1n−1)einϕ.(A15)
HerefABis the Aharonov-Bohm scattering amplitude,
fAB(ϕ)eiπ/4
√
2πksin(π|Q|)eiϕsgn(Q)
cos/parenleftbig1
2ϕ/parenrightbig. (A16)
The AB scattering amplitude is clearly vanishing for integer Q.
We evaluate this exact solution Eq. ( A15) numerically. Here
we make use of the fact that the phase shifts /Delta1ntend to zero
quickly for n>k ξ , meaning that only the lowest few partial
waves contribute to scattering. The scattering amplitude andthe skew angle ¯ ϕ=/integraltext
ϕ|F(ϕ)|
2//integraltext
|F(ϕ)|2for several values
of¯kξare shown in Fig. 2.
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064412-7 |
PhysRevB.103.245403.pdf | PHYSICAL REVIEW B 103, 245403 (2021)
Interlayer ferromagnetism and high-temperature quantum anomalous Hall effect
inp-doped MnBi 2Te4multilayers
Yulei Han ,1Shiyang Sun,2Shifei Qi,2,1,*Xiaohong Xu,3,†and Zhenhua Qiao1,‡
1ICQD, Hefei National Laboratory for Physical Sciences at Microscale, CAS Key Laboratory of Strongly-Coupled Quantum Matter Physics,
and Department of Physics, University of Science and Technology of China, Hefei, Anhui 230026, China
2College of Physics, Hebei Normal University, Shijiazhuang, Hebei 050024, China
3Research Institute of Materials Science, and School of Chemistry and Materials Science,
Shanxi Normal University, Linfen, Shanxi 041004, China
(Received 1 February 2021; revised 21 May 2021; accepted 21 May 2021; published 2 June 2021)
The interlayer antiferromagnetic coupling hinders the observation of quantum anomalous Hall effect in
magnetic topological insulator MnBi 2Te4. We demonstrate that interlayer ferromagnetism can be established
by utilizing the p-doping method in MnBi 2Te4multilayers. In two septuple layers system, the interlayer
ferromagnetic coupling appears by doping nonmagnetic elements (e.g., N, P, As, Na, Mg, K, and Ca), dueto the redistribution of orbital occupations of Mn. We further find that Mg and Ca elements are the mostsuitable candidates because of their low formation energy. Although, the p-doped two septuple layers exhibit
topologically trivial band structure, the increase of layer thickness to three (four) septuple layers with Ca (Mg)dopants leads to the formation of the quantum anomalous Hall effect. Our proposed p-doping strategy without
introducing additional magnetic disorder not only makes MnBi
2Te4become an ideal platform to realize the
high-temperature quantum anomalous Hall effect without external magnetic field, but also can compensate theelectrons from the intrinsic n-type defects in MnBi
2Te4.
DOI: 10.1103/PhysRevB.103.245403
I. INTRODUCTION
Quantum anomalous Hall effect (QAHE) is a typical topo-
logical quantum phenomena with quantized Hall resistanceand vanishing longitudinal resistance in the absence of ex-ternal magnetic field [ 1–3]. It is promising in designing
low-power electronic devices due to its dissipationless elec-tronic transport properties. Although it was first theoreticallyproposed by Haldane in 1988 [ 4], the exploration of the
QAHE began to attract huge interest ever since the first ex-foliation of monolayer graphene in 2004 [ 5]. After that, there
have been various proposed recipes in designing the QAHE[6–17], among which the magnetic topological insulator is the
most favorable system by both theoretical and experimentalstudies due to its inherently strong spin-orbit coupling [ 18,19].
To realize the QAHE, the ferromagnetism is prerequisite andcan be engineered by magnetic doping [ 9,20–26]. It was
indeed theoretically proposed [ 9] in 2010 and later experimen-
tally observed in 2013 in the magnetically doped topologicalinsulator thin films [ 27–31]. However, the major obstacle,
hindering the practical applications of QAHE, is the extremelylow QAHE-observation temperature. Therefore, more effortsare being made to increase the QAHE observation temperaturevia various doping schemes in topological insulators [ 24–26].
Alternatively, MnBi
2Te4, composed of septuple-layer (SL)
blocks stacking along the [0001] direction via van der Waals
*Correspondence author: qisf@hebtu.edu.cn
†Corresponding author: xuxh@dns.sxnu.edu.cn
‡Corresponding author: qiao@ustc.edu.cninteraction [see Figs. 1(a) and1(b)], becomes an appealing
host material to realize exotic topological phases [ 32–35].
It exhibits intrinsic magnetism, following the A-type anti-ferromagnetic order, where the neighboring ferromagneticMn layers are coupled in an antiparallel manner [ 33,34].
It was reported that the QAHE can be observed at 6.5 Kin a five-SL MnBi
2Te4flake, when an external magnetic
field is applied; while the zero-field QAHE can only be
observed at 1.4 K with ultrahigh sample quality [ 36,37].
The sensitivity of the QAHE on the sample quality in-dicates that the interlayer antiferromagnetic coupling is acritical obstacle in the QAHE formation, and the interlayerferromagnetism is highly desired. The interlayer magneticcoupling of van der Waals materials is determined by the d-
orbital occupation of transition metals [ 38–40]. One approach
to manipulate the interlayer ferromagnetism is by stackingdifferent d-orbital occupied van der Waals materials, e.g.,
MnBi
2Te4/V(Eu)Bi 2Te4[39,40]. As demonstrated in below,
another most efficient approach is by directly doping nonmag-netic p-type elements into MnBi
2Te4.
In this work, we provide a systematic study on the
magnetic and electronic properties of nonmagnetic p-doped
MnBi 2Te4multilayers by using first-principles calculation
methods. In two-SL MnBi 2Te4, the interlayer ferromagnetic
coupling can be realized by doping various nonmagnetic p-
type elements (e.g., N, P, As, and Na, Mg, K, Ca) with theCurie temperature up to T
C=54 K. The underlying phys-
ical origin is the redistribution of d-orbital occupation of
Mn element induced hopping channels between t 2gand e g
from different SLs. Although it is topologically trivial in the
2469-9950/2021/103(24)/245403(10) 245403-1 ©2021 American Physical SocietyHAN, SUN, QI, XU, AND QIAO PHYSICAL REVIEW B 103, 245403 (2021)
FIG. 1. Top view and side views of crystal structures of 2-4 SLs MnBi 2Te4and formation energies of p-type doped systems. (a) Two-SL
MnBi 2Te4with one N /P/As substitution at sites Te 1-Te 4, or one Na /Mg/K/Ca substitution at sites Bi 1-Bi 2; (b) The 3-4 SLs MnBi 2Te4with
one N/P/As substitution at sites Te 1-Te 6, or one Na /Mg/K/Ca substitution at sites Bi 1-Bi 4. [(c) and (d)] Formation energies of (c) N /P/As
or (d) Na /Mg/K/Ca doped two-SL MnBi 2Te4as a function of the host element chemical potentials.
p-doped two-SL case, the topological phase transition occurs
to harbour the high-temperature QAHE with a Chern numberofC=−1 when the system thickness is increased, i.e. Ca-
doped three-SL, and Ca /Mg-doped four-SL MnBi
2Te4, with
the interlayer ferromagnetism still being preserved. Our workdemonstrates a p-doping mechanism in producing ferromag-
netism in MnBi
2Te4to form the high-temperature QAHE,
which is experimentally accessible.
II. CALCULATION METHODS
Our first-principles calculations are performed by using the
projected augmented-wave method [ 41] as implemented in the
Vienna ab initio simulation package (V ASP) [ 42,43]. The gen-
eralized gradient approximation (GGA) of the Perdew-Burke-Ernzerhof type is utilized to treat the exchange-correlationinteraction [ 44]. In our calculations, the lattice constant of
MnBi
2Te4is chosen as the experimental value of a0=4.33 Å
[45]. We use zero damping DFT-D3 method [ 46,47] to de-
scribe the van der Waals interaction of adjacent SLs ofMnBi
2Te4. All atoms are allowed to move during the struc-
tural optimization. The kinetic energy cutoff and energyconvergence threshold are set to be 450 and 10
−6eV , respec-
tively. The Hellmann-Feynman force tolerance criterion forconvergence is 0.01 eV /Å. The Gaussian smearing method
with a smearing width of 0.01 eV is adopted. A vacuum spaceof 20 Å is considered to avoid interaction between neigh-boring slabs. A /Gamma1-centered 7 ×7×1( 5×5×1)kmesh is
adopted for the 2 ×2( 3×3) supercell. The 3 dstates of
Mn are treated with GGA +Uapproach [ 48,49], with U =5.34 eV , as in previous studies [ 50,51]. The topological related
quantities are calculated by constructing maximally localizedWannier function as implemented in the Wannier90 package[52]. The Curie temperature T
Cwas estimated within the
mean-field approximation kBTC=2/3Jx[53], where kBis
the Boltzmann constant, xis the dopant concentration, and
Jis the exchange parameter obtained from the total energy
difference between ferromagnetic and antiferromagnetic con-figurations in different heterostructures. The phonon spectrumcalculations are carried out by using the density functionalperturbation theory as implemented in the
PHONOPY package
[54].
III.p-TYPE DOPING SCHEME IN MnBi 2Te4
It was known that interlayer magnetic coupling in
MnBi 2Te4is dominated by p-orbital mediated superexchange
interaction, while d-orbital occupation has vital influence on
the sign of interlayer magnetic coupling [ 39,40]. Based on
the superexchange mechanism, doping p-type nonmagnetic
elements can change the d-orbital occupation of Mn in the
same SL. With the aid of hopping channel between 3 d-orbital
of Mn in undoped SL and virtual 3 d-orbitals of Mn in p-doped
SL, the interlayer ferromagnetic coupling becomes possible.In experiments, MnBi
2Te4was found to be electron-doping
due to their intrinsic n-type defects [ 33]. Therefore another
natural benefit of p-doping is the charge-compensation, which
is a prerequisite for realizing the QAHE.
We now first study the possibility of pdoping
in MnBi 2Te4multilayers. Substituting Te /Bi atoms by
245403-2INTERLAYER FERROMAGNETISM … PHYSICAL REVIEW B 103, 245403 (2021)
FIG. 2. Phonon dispersions of monolayer MnBi 2Te4with
(a) pristine structure, (b) Ca dopant and (c) Mg dopant. A 2 ×
2M n B i 2Te4supercell is used to calculate phonon dispersion of
Ca/Mg doped system.
nonmagnetic dopants is experimentally feasible, as imple-
mented in Bi 2Te3-family topological insulators. The Te and
Bi elements in MnBi 2Te4exhibit respectively 2−and 3+
valence states. In order to employ p-doping, the correspond-
ing substituted elements can be 3−,1+, and 2+valence
states, respectively. Therefore, the typical candidates of p-
type nonmagnetic dopants include N /P/As for Te sites, or
Na/Mg/K/Ca for Bi sites. As displayed in Fig. 1(a) for
at w o - S LM n B i 2Te4, there are four Te substitutional sites
(i.e., Te 1,T e 2,T e 3,T e 4), and two Bi substitutional sites (i.e.,
Bi1,B i 2). The formation energies can be evaluated from the
expression [ 55–57]:/Delta1HF=ED
tot−Etot−/summationtextniμi, where ED
tot,
Etotare respectively the total energies of the p-doped and
undoped systems, μiis the chemical potential for species i
(host atoms or dopants), and niis the corresponding number
of atoms added to or removed from the system.
Considering the formation energies of N /P/As substitu-
tions at Te sites in one SL as displayed in Fig. 1(c), one
can find that the Te 4site is preferred. The formation energy
of N substitution (2.5–3.0 eV) is larger than that of either P(0.6–1.2 eV) or As (about 0.4–1.0 eV). For Na /Mg/K/Ca
substitutions at Bi sites in Fig. 1(d), one can find that the Bi
2
site is preferred, and the formation energies of Bi-site substi-
tutions are always lower than those of Te-site substitutions. Inparticular, the formation energies of Na /Mg/Ca-substituted
Bi
2site are negative, suggesting that these dopings are ex-
perimentally feasible. As far as we know, the C-doped ZnOcan also be experimentally realized, even thought the esti-mated formation energy of C substituted O in ZnO is about5.3 eV [ 58], which is larger than those of aforementioned
p-type dopants in MnBi
2Te4. Moreover, phonon dispersions
of two most feasible dopants, i.e., Mg and Ca, are calculatedas displayed in Fig. 2, which suggests the stability of p-doped
MnBi
2Te4systems. Hereinbelow, we concentrate on the most
stable substitional sites (i.e., Te 4and Bi 2) to study the mag-
netic and electronic properties of p-doped two-SL MnBi 2Te4.
IV . INTERLAYER FERROMAGNETISM FROM p-DOPING
Figures 3(a)and3(b) display the energy differences ( /Delta1E=
EFM−EAFM) between interlayer ferromagnetic (FM) and
antiferromagnetic (AFM) states of the optimal configurationsat different p-doped concentrations in two-SL MnBi
2Te4.
FIG. 3. [(a)–(c)] The energy differences between interlayer fer-
romagnetic (FM) and interlayer antiferromagnetic (AFM) states ofthe optimal configurations in (a) N /P/As doped two-SL MnBi
2Te4
at 3.13% and 1.39% concentrations, (b) Na /Mg/K/Ca doped two-SL
MnBi 2Te4at 6.25% and 2.78% concentrations, (c) Mg /Ca doped 3-4
SLs MnBi 2Te4at 4.17% and 3.13% concentrations. [(d) and (e)]
Differential charge density of (d) Ca doped and (e) pristine two-SL MnBi
2Te4. Yellow and green isosurface represent respectively
charge accumulation and reduction. (f) Local density of states of Ca
doped and pristine two-SL MnBi 2Te4.T e -p,B i -p,a n dM n - dorbitals
[t2gand e g] in each SL of MnBi 2Te4are displayed.
In the absence of doping, the two-SL MnBi 2Te4indeed
exhibits interlayer antiferromagnetism (see Table I). The
introduction of p-type dopants leads to /Delta1E<0, strongly
indicating that interlayer ferromagnetic state is more stablethan the interlayer antiferromagnetic state. For N /P/As dop-
ing at Te
4site [see Fig. 3(a)],/Delta1Echange respectively from
−12.4/−11.2/−10.3 meV to −24.5/−19.5/−17.2 meV ,
along with the increase of doping concentration. ForNa/Mg/K/Ca substitution at Bi
2site [see Fig. 3(b)],/Delta1E
are respectively −43.5/−11.8/−35.4/−14.5 meV at 2.78%
doping concentration, and −48.6/−24.9/16.7/−19.2 meV at
6.25% doping concentration.
Besides the energy difference for optimal doping sites, we
also investigate magnetic properties of the remaining dopingsites. Figure 4displays the /Delta1
Eof different configurations in
p-doped two-SL MnBi 2Te4. One can find that all p-doped sys-
tems prefer interlayer ferromagnetic coupling, and the dopingsites near the van der Waals gap (e.g., Te
4for N/P/As, Bi 2for
Na/Mg/K/Ca) exhibit much larger ferromagnetic coupling
strength.
In addition, the ferromagnetic Curie temperature plays
a crucial role in determining the QAHE observation
245403-3HAN, SUN, QI, XU, AND QIAO PHYSICAL REVIEW B 103, 245403 (2021)
FIG. 4. The energy differences between interlayer ferromag-
netic(FM) and interlayer antiferromagnetic (AFM) states of different
configurations in N /P/As doped two-SL MnBi 2Te4at (a) 3.13%
and (c) 1.39% doping concentrations. Na /Mg/K/Ca doped two-SL
MnBi 2Te4at (b) 6.25% and (d) 2.78% doping concentrations.
temperature. The estimated Curie temperature from mean-
field theory is listed in Table I, which ranges between 15.7
and 53.7 K depending on the dopants. For example, the Curietemperature of Ca-doped MnBi
2Te4can reach TC=21.2K
at 6.25% doping concentration, which can be further raisedwith the increase of doping concentration. Note that the higherdoping concentration may decrease the spin-orbit coupling ofthe whole system.
For thicker MnBi
2Te4films (i.e., three-SL and four-SL
films), we calculate the /Delta1Eof two most favorable dopants
(Mg and Ca). For different substitutional sites, it is foundthat Bi
3(Bi4) site is most stable in three-SL (four-SL)
MnBi 2Te4films. And for different magnetic configurations
of the most stable doping site, the energy differences showthat the ferromagnetic states are preferred (see Tables IIand
III). Figure 3(c) displays the energy difference /Delta1
Eof one
Mg or Ca dopant at Bi 3(Bi4) site in 2 ×2 supercells of
three-SL (four-SL) MnBi 2Te4. One can see that ferromagnetic
coupling strength is dependent on doping concentration thatis determined by the number of layers, i.e., for one dopantthe increase of septuple layers leads to rapidly decrease offerromagnetic coupling strength. Therefore larger ferromag-netic coupling strength in a multilayer system requires higherp-type doping concentration.
The formation mechanism of interlayer ferromagnetic cou-
pling can be explained from the differential charge densityand local density of states. Let us take the Ca-doped two-SLMnBi
2Te4as an example [see in Fig. 3(d)]. In the pristine
case [see Fig. 3(e)], the charge distribution in the top SL
is the same as that in the bottom SL. After Ca-doping inbottom SL, the charge of Mn atoms in the same SL is clearlydecreased whereas that in top SL remains nearly unchanged.Such a charge redistribution leads to new hopping channelsbetween Mn atoms in adjacent SLs. In pristine case, the t
2g
and e gorbitals are fully occupied, leading to the absence
of electron hopping between t 2gand e gorbitals. While as
displayed in Fig. 3(f), the decrease of d-orbital occupation
in bottom SL generates new hopping channels from t 2g(top
SL) to e g(bottom SL) and e g(top SL) to e g(bottom SL),FIG. 5. Band structures and corresponding band gaps of Mg-
and Ca-doped 2 SLs MnBi 2Te4with optimal configurations along
high-symmetry lines. [(a) and (b)] Doping one Mg or Ca atom in
2×2t w o - S LM n B i 2Te4with the concentration of 6.25%. [(c) and
(d)] Doping one Mg or Ca atom in 3 ×3t w o - S LM n B i 2Te4with the
concentration of 2.78%.
which are allowed for ferromagnetic coupling. In addition,
in Fig. 3(f), one can also find that a large spin polarization
appears in the Te element after Ca doping, which suggests thatthe interlayer ferromagnetic coupling in Ca-doped two-SLMnBi
2Te4is mediated via the interlayer Te-Te superexchange
interaction.
V . ELECTRONIC STRUCTURES AND TOPOLOGICAL
PROPERTIES
Next, we explore the electronic band structures of the
Mg and Ca doped multi-SL MnBi 2Te4(see Figs. 10and11
for band structures of other pdopants). Figure 5displays
the band structure along high-symmetry lines of the optimalconfigurations of Mg and Ca doped two-SL MnBi
2Te4.A s
illustrated in Figs. 5(a) and5(b), a band gap about 53.6 meV
(26.9 meV) opens at /Gamma1point with Mg (Ca) dopant for a dop-
ing concentration of 6.25%. When the doping concentrationreduces to 2.78%, the band gap decreases to about 35.0 meV(18.9 meV) for Mg (Ca) dopant [see Figs. 5(c) and5(d)].
To verify whether such a gap can host the QAHE or not,one can directly calculate the anomalous Hall conductanceσ
xyby integrating Berry curvature of the occupied valence
bands [ 59,60]. Unfortunately, we obtained σxy=0e2/hfor all
p-doped two-SL MnBi 2Te4, indicating that it is still a topo-
logical trivial phase, even though the ferromagnetism is wellestablished. The possible reasons include: (i) the decrease ofspin-orbit coupling originated from the light doping elements,and (ii) the film thickness influence [ 37,51]. To address these
concerns, we first choose to dope some heavy metal elements(i.e., Sn, Pb, In, Tl) in two-SL MnBi
2Te4systems. As dis-
played in Table I, doping In or Tl results in the interlayer
anti-ferromagnetic coupling; whereas although doping Sn orPb gives rise to interlayer ferromagnetic coupling, no bandgap opens at moderate doping concentrations (see Fig. 10).
245403-4INTERLAYER FERROMAGNETISM … PHYSICAL REVIEW B 103, 245403 (2021)
FIG. 6. Band structures along high-symmetry lines of MnBi 2Te4
doped with Mg in (a) three-SL and (b) four-SL, doped with Ca in
(c) three-SL and (d) four-SL, and (e) doped with two Ca in three-SL.The inset displays the anomalous Hall conductivity as a function of
Fermi energy. (f) The dependence of band gap (solid lines) and Chern
number (dashed lines) on the doping concentrations of Mg /Ca. The
decrease of doping concentration indicates the increase of number of
MnBi
2Te4SL.
We then consider the influence of film thickness of MnBi 2Te4
in below.
Figures 6(a) and6(b) display respectively the band struc-
tures of Mg-doped three- and four-SL MnBi 2Te4, where
the corresponding band gaps are respectively 24.9 meV (at4.17% doping concentration) and 7.0 meV (at 3.13% dopingconcentration). The Hall conductance σ
xyevaluation gives
respectively 0 and −1 in the units of e2/hfor three-SL and
four-SL Mg-doped systems, strongly signaling a topologicalphase transition from trivial insulator to the QAHE with theincrease of film thickness. For the Ca-doped cases as dis-played in Figs. 6(c) and6(d), one can see that the band gaps
are respectively 13.7 meV (three-SL) and 6.8 meV (four-SL).Surprisingly, the Hall conductance in the band gap is σ
xy=
−e2/hfor both three- and four-SL Ca-doped MnBi 2Te4.
Therefore the increase of film thickness can lead to a topo-logical phase transition in p-doped MnBi
2Te4multilayers.
which can be attributed to magnetic Weyl semimetal natureof ferromagnetic MnBi
2Te4, as observed in similar systems
with thickness dependent Chern number [ 37,39].
For three-SL Ca-doped system, we also investigate the
role of doping concentration on the electronic properties byincluding two Ca dopants at different substitutional sites. Wefind that all the calculated configurations display interlayerferromagnetism, and Ca
2Ca4doped configuration is preferred
with the Curie temperature of 52 K (see Fig. 12and Table IV).
As illustrated in Fig. 6(e), the band gap slightly decreases
to 11.2 meV , with the nontrivial topology being preserved,but the Curie temperature is greatly enhanced from 20.3 K(one Ca dopant) to 52.0 K (two Ca dopants). Figure 6(f)FIG. 7. [(a) and (b)] Formation energies of (a) N /P/As or
(d) Na /Mg/K/Ca doped two-SL MnBi 2Te4as a function of the
host element chemical. (c) The energy differences between interlayer
ferromagnetic(FM) and interlayer antiferromagnetic (AFM) states
of the most stable configurations in (a) and (b). The red dashedline represents energy difference of pristine two-SL MnBi
2Te4as a
reference.
summarizes the band gaps and Hall conductance as functions
of doping concentration. Compared with Mg dopant, the Cadoped MnBi
2Te4is preferred since that the topological phase
appears in system with thinner thickness. Therefore the Mg-and Ca-doped MnBi
2Te4multilayers are beneficial for realiz-
ing the high-temperature QAHE.
VI. FORMATION ENERGIES AND MAGNETIC
PROPERTIES OF ANTISITE SUBSTITUTIONS
In above, we have studied formation energies of N /P/As
substitutions at Te sites and Na /Mg/K/Ca substitutions at
Bi sites. Here we consider two type of representative anti-site substitutions, i.e., N /P/As substitutions at Bi sites and
Na/Mg/K/Ca substitutions at Mn sites. Figures 7(a)and7(b)
display the corresponding formation energies as a function ofthe host element chemical potentials. We can observe that theBi
1site is preferred for N /P/As substitutions and the positive
formation energies is similar to that of N /P/As substitutions
at Te sites as displayed in Fig. 1(c).F o rN a /Mg/K/Ca substi-
tutions at Mn sites, the formation energies is also negative. It is
FIG. 8. Formation energies of Na /Mg/K/Ca doped Bi /Mn in
two-SL MnBi 2Te4. The chemical potentials of Na /K/Mg/Ca are
evaluated by choosing Na 2Te, K 2Te, MgTe, and CaTe as reference.
245403-5HAN, SUN, QI, XU, AND QIAO PHYSICAL REVIEW B 103, 245403 (2021)
FIG. 9. (a) Two-SL MnBi 2Te4with one pair of native antisite defect Mn Biand Bi Mn. The six substitutional sites are labeled as Bi 1-Bi 5
and Mn 6.( b )F o r m a t i o ne n e r g i e so fM g /Ca substitutions at the most stable Bi 5site and at Mn site. The gray dashed line represents formation
energy of native antisite defect. (c) The energy differences between interlayer ferromagnetic(FM) and interlayer antiferromagnetic (AFM)
states of the six configurations doped with Mg /Ca. The presence of native antisite defect displays weak FM coupling with energy difference
of∼− 0.32 meV .
worth noting that the chemical potentials from single element
are usually larger than that from compound, resulting in aslightly underestimated formation energy. To quantitativelycompare the formation energies of Mg /Ca dopants in Bi /Mn
sites, we choose MgTe and CaTe as reference to evaluate thechemical potentials of Mg /Ca. Figure 8displays formation
energies of Mg /Ca doped Bi /Mn in two-SL MnBi
2Te4.W e
can find that formation energy for dopants at Bi site is lowerthan that at Mn site in almost all range, indicating that Bi siteis preferred for Mg /Ca dopants.
Figure 7(c) shows the corresponding energy difference
between FM and AFM states. The presence of N /P/As sub-
stitutions at Bi sites does not obviously change the AFMcoupling compared with pristine two-SL MnBi
2Te4.F o rN a
and K, the substitutions at Mn site displays interlayer FMcoupling due to different valence states between Na /K( 1
+)
and Mn (2+) elements induced charge redistribution. For Mg
FIG. 10. Band structures and corresponding band gaps of p-
doped two-SL (2 ×2) MnBi 2Te4with optimal configurations along
high-symmetry lines. (a)–(i) are respectively for N, P, As, Na, Mg, K,
Ca, Sn, and Pb doped two-SL MnBi 2Te4. The doping concentrations
are respectively 3.13% and 6.25% for substituted Te and Bi sites.and Ca substitutions at Mn site, interlayer AFM coupling
is preserved since the same valence states between Mg /Ca
and Mn elements. These results indicate that, even if Mg /Ca
substitutions at Mn sites, the magnetic coupling strength ofMnBi
2Te4is almost unchanged. Therefore the p-dopant at
Bi sites plays a crucial role in determining magnetism ofMnBi
2Te4.
Besides above antisite substitutions, we also explore the
doping possibility in the presence of native antisite defect, i.e.,Mn
Biand Bi Mn. Figure 9(a)displays the six substitutional sites
labeled as Bi 1-Bi5and Mn 6. We find that Bi 5site are preferred
for Bi substitution. Formation energies of dopants at Bi 5and
Mn 6sites are shown in Fig. 9(b), where formation energy of
the native antisite defect Mn Biand Bi Mnis depicted in gray for
comparison [The MgTe and CaTe are chosen as reference toevaluate the chemical potentials of Mg /Ca]. We can observed
that Mg /Ca substitutions at Bi sites have lower formation
FIG. 11. Band structures and corresponding band gaps of p-
doped two-SL (3 ×3) MnBi 2Te4with optimal configurations along
high-symmetry lines. (a)-(i) are respectively for N, P, As, Na, Mg, K,
Ca, Sn, and Pb doped two-SL MnBi 2Te4. The doping concentrations
are respectively 1.39% and 2.78% for substituted Te and Bi sites.
245403-6INTERLAYER FERROMAGNETISM … PHYSICAL REVIEW B 103, 245403 (2021)
TABLE I. The band gap for the ground states, the energy difference /Delta1E=EFM−EAFM, and the estimated Curie temperature T Cofp-doped
two-SL MnBi 2Te4with the optimal configurations. For 2 ×2M n B i 2Te4supercell, the doping concentrations are respectively 3.13% and 6.25%
for substituted Te and Bi sites. For 3 ×3M n B i 2Te4supercell, the doping concentrations are respectively 1.39% and 2.78% for substituted Te
and Bi sites. The red color indicates the antiferromagnetic ground state.
2×2 supercell 3 ×3 supercell
Structure Gap (meV) /Delta1E(meV) T C(K) Gap (meV) /Delta1E(meV) T C(K)
N4(N1) 40.0 −24.5 27.1 5.4 −2.0 2.3
P4 6.0 −19.5 21.6 0.4 −11.2 12.3
As4 5.3 −17.2 19.0 4.0 −10.3 11.4
Na2 9.3 −48.6 53.7 15.5 −43.5 48.1
Mg2 53.6 −24.9 27.5 35.0 −11.8 13.0
K2 25.9 −16.7 18.4 3.8 −35.4 39.1
Ca2 26.9 −19.2 21.2 18.9 −14.5 16.0
Sn2 Metallic −14.2 15.7 2.8 −14.3 15.8
Pb2 Metallic −17.1 18.9 13.3 −7.5 8.3
In2 197.9 1.7 – 145.5 3.1 –
Tl2 163.3 6.1 – 149.5 7.5 –
MnBi 2Te4 80.0 1.0 – 2.3 –
energy than that at Mn sites, indicating that Bi site is preferred
for Mg /Ca dopants in the presence of native antisite defect.
Figure 9(c)displays the energy differences between interlayer
FM and AFM states of the six configurations doped withMg/Ca. In the presence of native antisite defect, the system
demonstrates weak FM coupling ( −0.32 meV), whereas the
further inclusion of Mg /Ca dopants at Bi or Mn sites greatly
enhances FM coupling strength of MnBi
2Te4.
Based on the results displayed in this Section, we can con-
clude that (i) Mg /Ca substitutions at Bi sites are preferred than
that at Mn sites; (ii) magnetic coupling strength of MnBi 2Te4
is almost unchanged even if Mg /Ca substitutions at Mn sites;
(iii) in the presence of native antisite defect, Mg /Ca doped
system displays interlayer ferromagnetism regardless of thedoping sites.
VII. SUMMARY
In conclusion, we propose that a feasible p-type doping
strategy in MnBi 2Te4can be used to realize interlayer fer-
romagnetism and the high-temperature QAHE. We provideproof-of-principle numerical demonstration that (1) interlayerferromagnetic transition can appear when some nonmagneticp-type elements are doped into MnBi
2Te4; (2) band structures
and topological property calculations show that Ca- and Mg-doped MnBi 2Te4multilayer can realize the QAHE with Chern
number of C=−1.
Experimentally, Mg, Ca and some nonmagnetic elements
doped topological insulators have been successfully fabricatedin order to tune carrier type and density [ 61–63]. For example,
to compensate the n-type carrier induced by Se vacancies
in topological insulator Bi
2Se3, a small concentration of Ca
is doped, and insulating behavior is preserved whereas theFermi level is tuned into the band gap [ 61]. For the MnBi
2Te4,
from our calculation, the formation energies of Ca substitutionare only −2.5 to −3.0 eV . Hence the p-type Ca dopants
in MnBi
2Te4are very feasible in experiment. The merits of
p-type doping in MnBi 2Te4is that it can not only result in
interlayer ferromagnetic coupling without introducing addi-tional magnetic disorder, but also compensate the intrinsicn-type carrier, which in principle guarantees the insulating
state and is beneficial to realize the high-temperature QAHEin MnBi
2Te4. Our work provide a highly desirable scheme
to overcome the difficulty of the observing of the QAHE inMnBi
2Te4without applying external magnetic field.
ACKNOWLEDGMENTS
This work was financially supported by the NNSFC
(No. 11974098, No. 11974327 and No. 12004369),
TABLE II. The structural and magnetic properties of Ca /Mg doped three-SL MnBi 2Te4with doping concentration of 4.17%. The spin
direction of each septuple layer is denoted by the up /down arrow. The ground state of each dopant is denoted by red. The energy differences
between the specific structure and ground state are shown. The energy is in unit of meV .
Structure /Delta1E(↑↓↑ ) /Delta1E(↑↑↓ ) /Delta1E(↑↓↓ ) /Delta1E(↑↑↑ )
Mg1 91.0 84.1 91.8 84.7
Mg2 46.9 24.5 44.9 24.7
Mg3 25.1 6.3 20.9 0
Ca1 107.3 99.0 108.1 100.3
Ca2 50.6 35.3 48.3 34.2
Ca3 18.3 3.2 15.0 0
MnBi 2Te4 0 1.2 1.1 2.5
245403-7HAN, SUN, QI, XU, AND QIAO PHYSICAL REVIEW B 103, 245403 (2021)
TABLE III. The structural and magnetic properties of Ca /Mg doped four-SL MnBi 2Te4with doping concentration of 4.17%. The spin
direction of each septuple layer is denoted by the up /down arrow. The ground state of each dopant is denoted by red. The energy differences
between the specific structure and ground state are shown. The energy is in unit of meV .
Structure /Delta1E(↑↓↑↓ )/Delta1E(↑↑↑↓ )/Delta1E(↑↑↓↑ )/Delta1E(↑↑↓↓ )/Delta1E(↑↓↑↑ )/Delta1E(↑↓↓↑ )/Delta1E(↑↓↓↓ )/Delta1E(↑↑↑↑ )
Mg2 41.3 20.9 23.0 24.2 42.7 43.4 39.2 22.0
Mg3 26.3 1.8 9.3 9.6 26.7 20.5 20.2 3.4
Mg4 20.7 3.5 14.7 11.7 17.9 8.4 6.8 0
Ca2 48.1 33.0 35.2 36.2 48.8 44.9 45.9 34.0
Ca3 44.6 6.7 13.1 13.1 25.6 17.6 18.4 7.4
Ca4 19.6 2.7 11.5 7.7 14.6 7.4 5.2 0
MnBi 2Te4 0 1.9 0.9 1.8 0.9 0.9 1.8 2.8
Natural Science Foundation of Hebei Province
(A2019205037), China Postdoctoral Science Foundation(2020M681998) and Science Foundation of Hebei NormalUniversity (2019B08), Fundamental Research Funds for theCentral Universities (WK2030020032 and WK2340000082)Anhui Initiative in Quantum Information Technologies.The Supercomputing services of AM-HPC and USTC aregratefully acknowledged.
APPENDIX A: BAND STRUCTURES OF p-DOPED TWO-SL
MnBi 2Te4
In Figs. 10and11, we plot the band structures of p-doped
two-SL MnBi 2Te4with optimal configurations with different
doping concentrations. In Fig. 10, we can observe that finite
gaps are opened around /Gamma1point except for Sn- and Pb-doped
systems. When reduces doping concentration, as displayed inFig.11, one can find that the gaps for N /P/As/Na/Mg/K/Ca
doped systems are decreased whereas small gaps exists forSn/Pb doped systems.
In Table I, we summarize the band gap for the ground
states, the energy difference /Delta1
E=EFM−EAFM, and the es-
timated Curie temperature T Cofp-doped two-SL MnBi 2Te4
with the optimal configurations. Besides the p-doped systems
showing interlayer ferromagnetism as discussed above, it isnoteworthy that In /Tl heavy metal-doped MnBi
2Te4exhibits
FIG. 12. (a) The substitutional sites for two Ca dopants in three-
SL MnBi 2Te4. (b) The comparison of energy differences between
FM and AFM states with /without spin-orbit coupling in p-doped
two-SL MnBi 2Te4.a enhanced interlayer antiferromagnetic coupling compared
with the pristine two-SL MnBi 2Te4.
APPENDIX B: MAGNETIC PROPERTIES OF p-DOPED
THREE- AND FOUR-SL MnBi 2Te4
Table IIdisplays the structural and magnetic properties of
Ca/Mg doped three-SL MnBi 2Te4with doping concentration
of 4.17%. The corresponding doping sites are shown in themain text. One can find that Bi
3substitutional site is most
stable, and the ferromagnetic ground state is preferred inMg/Ca doped three-SL MnBi
2Te4.F o rC a /Mg doped four-
SL MnBi 2Te4, as shown in Table III, we can observe that
Bi4substitutional site is most stable, and the ferromagnetic
ground state is preserved.
APPENDIX C: STRUCTURAL AND MAGNETIC
PROPERTIES OF THREE-SL MnBi 2Te4WITH TWO Ca
DOPANTS
Figure 12(a) displays the possible substitutional sites for
two Ca dopants in three-SL MnBi 2Te4, where the sites near
van der Waals gap are considered because they are morestable. Due to the inversion symmetry, there are four com-binations of doping sites as shown in Table IV. We can find
that the Ca
2Ca4doped configuration is most stable with inter-
layer ferromagnetic coupling, and the Curie temperature canapproach 52 K.
APPENDIX D: MAGNETIC COUPLING WITH /WITHOUT
SPIN-ORBIT COUPLING IN p-DOPED TWO-SL MnBi 2Te4
In above magnetic coupling calculation, the spin-orbit
coupling is not included. Fig. 12(b) displays the energy dif-
ferences /Delta1Ebetween FM and AFM states with /without
TABLE IV . The structural and magnetic properties of two Ca
dopants in three-SL MnBi 2Te4. The energy differences between the
specific structure and ground state are shown. The ground state is
denoted by red. The energy is in unit of meV .
Structure /Delta1E(↑↓↑ ) /Delta1E(↑↑↑ )T C(K)
Ca2Ca4 47.1 0 52.0
Ca1Ca2 130.0 98.2 35.1
Ca1Ca4 61.5 17.2 48.9
Ca2Ca3 98.0 42.6 61.3
245403-8INTERLAYER FERROMAGNETISM … PHYSICAL REVIEW B 103, 245403 (2021)
spin-orbit coupling in p-doped two-SL MnBi 2Te4. We can
observe that, although the inclusion of spin-orbit couplingslightly increases the energy differences, the variation trendof/Delta1Eis similar before /after spin-orbit coupling is consid-
ered for different dopants and the interlayer ferromagneticcoupling is preserved.
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245403-10 |
PhysRevB.98.214428.pdf | PHYSICAL REVIEW B 98, 214428 (2018)
Temperature-dependent properties of CoFeB /MgO thin films: Experiments versus simulations
H. Sato,1,2,3,4,*P. Chureemart,5,6F. Matsukura,1,2,3,4,7R. W. Chantrell,5H. Ohno,1,2,3,4,7and R. F. L. Evans5,†
1Center for Spintronics Research Network, Tohoku University, 2-1-1 Katahira, Aoba-ku, Sendai 980-8577, Japan
2Laboratory for Nanoelectronics and Spintronics, Research Institute of Electrical Communication,
Tohoku University, 2-1-1 Katahira, Aoba-ku, Sendai 980-8577, Japan
3Center for Spintronics Integrated Systems, 2-1-1 Katahira, Aoba-ku, Tohoku University, Sendai 980-8577, Japan
4Center for Innovative Integrated Electronic Systems, Tohoku University, 468-1 Aramaki Aza Aoba, Aoba-ku, Sendai 980-0845, Japan
5Department of Physics, The University of York, York YO10 5DD, United Kingdom
6Department of Physics, Mahasarakham University, Mahasarakham 44150, Thailand
7WPI-Advanced Institute for Materials Research, Tohoku University, 2-1-1 Katahira, Aoba-ku, Sendai 980-8577, Japan
(Received 17 October 2017; revised manuscript received 1 July 2018; published 14 December 2018)
CoFeB/MgO heterostructures are a promising candidate for an integral component of spintronic devices due to
their high magnetic anisotropy, low Gilbert damping, and excellent magnetoresistive properties. Here, we presentexperimental measurements and atomistic simulations of the temperature and CoFeB thickness dependence ofspontaneous magnetization and magnetic anisotropy in CoFeB/MgO ultrathin films. We find that the thermalfluctuations are different between the bulk and interface magnetizations, and that the interfacial anisotropyoriginates from a two-site anisotropic exchange interaction. These effects lead to a complex temperatureand thickness dependence of the magnetic properties critical to device operation and stability at elevatedtemperatures.
DOI: 10.1103/PhysRevB.98.214428
I. INTRODUCTION
In recent years, an interfacial anisotropy at ferromagnetic
metal (FM)/oxides has been an interesting subject in the fieldof spintronics because of its importance for applications. Forinstance, the interfacial anisotropy reduces the intrinsic crit-ical current for spin-transfer-torque (STT)-induced magneti-zation switching in magnetic tunnel junctions (MTJs) with anin-plane easy axis (i-MTJs) without reduction of the thermalstability factor. In addition, the interfacial anisotropy enablesthe manufacture of MTJs with a perpendicular easy axis(p-MTJs) by reducing the FM layer thickness, which allows ahigher efficiency for the STT switching compared to i-MTJs.
A large interfacial perpendicular anisotropy energy den-
sityK
iof 1.18 mJ/m2at a FM/oxide interface was re-
ported in a single-crystal Fe substrate/MgO/Fe/Au struc-ture [ 1]. The presence of the interfacial anisotropy at
FM/oxide interfaces was also reported in polycrystalline filmswith Pt /Co(Fe) /MO
x(M:A l ,M g ,T a ,o rR u )[ 2,3] and
MgO/CoFeB/Pt structures [ 4]. In Ta/CoFeB/MgO structure,
a technologically relevant structure owing to its high tun-nel magnetoresistance ratio [ 5,6], the presence of K
iwas
also found [ 7]. This brought about the demonstration of
high-performance p-MTJs with Ta/CoFeB/MgO at a junction
*hsato@riec.tohoku.ac.jp
†richard.evans@york.ac.uk
Published by the American Physical Society under the terms of the
Creative Commons Attribution 4.0 International license. Further
distribution of this work must maintain attribution to the author(s)and the published article’s title, journal citation, and DOI.diameter of 40 nm [ 8], which triggered ongoing intensive
studies on p-MTJs with the CoFeB/MgO system at reduceddimensions less than 20 nm [ 9,10].
First-principles calculations indicated that the interfacial
perpendicular anisotropy is brought about by the hybridizationof Fe 3 dand O 2 porbitals [ 11]. The calculation is supported
by an experimental work on x-ray magnetic circular dichro-ism, which showed that the anisotropy is related to Fe 3 d
orbital anisotropy at the CoFeB/MgO interface [ 12]. While
the origin of the interfacial anisotropy appears to be wellunderstood, the origin of its temperature dependence, whichis important for further development of p-MTJs, is still to beelucidated.
As shown by Callen and Callen, the temperature Tdepen-
dence of the anisotropy energy density Kof ferromagnets has
a correlation with that of the spontaneous magnetization M
S
through a power-law scaling relationship [ 13],
K(T)
K(T∗)=/parenleftbiggMS(T)
MS(T∗)/parenrightbiggn
, (1)
where T* is a normalizing temperature originally taken as 0 K.
In this study we choose 10 K as T*, the lowest measurement
temperature, at which thermal spin fluctuation is expected tobe small. The exponent nis known to depend on the physical
mechanism causing the magnetic anisotropy; nis equal to 3
for materials with a uniaxial single-ion anisotropy [ 13], and is
closer to 2 for materials with a dominant two-site anisotropy[14]. However, one may need to care about a mixture of the
effects from bulk and surface properties on the anisotropy inthin films and nanoparticles with interfacial anisotropy [ 15].
Hence, the investigation of the correlation between KandM
S
2469-9950/2018/98(21)/214428(7) 214428-1 Published by the American Physical SocietyH. SATO et al. PHYSICAL REVIEW B 98, 214428 (2018)
-1.5 -1.0 -0.5 0.0 0.5 1.0 1.5-2-1012
tCoFeB=1 . 1n mm(Tnm)
0H(T)T=1 0K mS
FIG. 1. Magnetic moment mper unit area versus in-plane mag-
netic field Hfor 1.1-nm-thick CoFeB film measured at 10 K. From
the shaded area, areal magnetic anisotropy energy density KefftCoFeB
is evaluated.
as a function of Tis expected to provide us an insight of the
exchange mechanism relating to the interfacial anisotropy.
In this study, we investigate the temperature dependence of
MSandKof the thin CoFeB/MgO system. We compare the
experimental results with atomistic spin-model simulations[16], and show that their temperature dependence is related
to thermal spin fluctuations and the finite thickness of thesystem.
II. EXPERIMENT
A. Film fabrication and measurement method
A stack structure of Ta (5)/Ru (10)/Ta (5)/Co 20Fe60B20
(tCoFeB )/MgO (1.4)/Ta (5) was deposited on a thermally ox-
idized Si substrate by rf magnetron sputtering. Numbers inparentheses are nominal thicknesses in nm determined fromthe deposition rate. We prepared five samples with differentCoFeB thicknesses ( t
CoFeB=1.1, 1.3, 1.7, 3.0, and 4.0 nm).
The CoFeB composition is also nominal, and corresponds tothat of a sputtering target. The boron composition of the film isprobably higher than the nominal one, while the compositionratio of Co to Fe is almost the same [ 17]. The stacks were
annealed in vacuum at 300 °C for 1 h under an out-of-planemagnetic field of 0.4 T. We do not expect the formationof a magnetically dead layer in the structures as shownin the previous work [ 8]. We measured the magnetization
curve for the stacks along the hard-axis direction at varioustemperatures by a vibrating sample magnetometer. A typicalmagnetization curve is shown in Fig. 1for the stack with
t
CoFeB=1.1 nm at 10 K. From the curves, we determined the
spontaneous magnetic moment per unit area mSand areal
effective perpendicular magnetic anisotropy energy densityK
efftCoFeB (the area enclosed by the m-H curve and m=mS
in Fig. 1)[8].
B. Results
Figure 2(a) shows the temperature dependence of MS
between 10 and 300 K as a function of tCoFeB , where MSwas
determined from MS=mS/tCoFeB .T h eMSexhibits a mono-
tonic decreasing tendency in all the CoFeB films with dif-ferent t
CoFeB within experimental errors. The thinner CoFeB
film (tCoFeB<2 nm) shows a larger variation of MSwith
increasing temperature, as noticed from Fig. 2(b), in whichFIG. 2. Temperature Tdependence of (a) spontaneous magne-
tization MSand (b) normalized MS(T)/MS(10 K) for CoFeB/MgO
stacks as a function of CoFeB thicknesses tCoFeB .
the normalized spontaneous magnetization MS(T)/MS(10 K)
is presented.
Figure 3(a) shows the temperature dependence of the per-
pendicular anisotropy energy density K=Keff+MS2/2μ0,
where μ0is permeability in free space, as a function of tCoFeB .
Because the interfacial anisotropy plays a dominant role forthe perpendicular anisotropy in the CoFeB/MgO system, Kis
approximately equal to K
i/tCoFeB , where Kiis the interfacial
anisotropy energy density. As can be seen, Kdecreases with
increasing T, indicating that Kialso decreases with increasing
T. The thinner CoFeB film ( tCoFeB<2 nm) shows a larger
variation of Kwith change in T, as noticed from Fig. 3(b),
in which the normalized anisotropy energy density K(T)/K(10
K) is presented.
Figure 4shows the double-logarithm plot of K(T)/K(10
K) versus MS(T)/MS( 1 0K )a saf u n c t i o no f tCoFeB . A linear
fit to the data for the samples with tCoFeB<2n mg i v e st h e
slopenof 2.2, in agreement with previous experimental mea-
surements [ 18–20]. The scaling exponent n∼2 suggests that
the anisotropy is not dominated by single-ion anisotropy with
0.00.51.01.5
0 100 200 3000.60.81.01.2(a)
3
41.71.3K(MJ/m3)
1.1tCoFeB (nm)K(T)/K(10 K)
T(K)(b)
FIG. 3. Temperature Tdependence of (a) perpendicular
anisotropy energy density Kand (b) normalized K(T)/K(10 K) for
CoFeB/MgO stacks as a function of CoFeB thicknesses tCoFeB .
214428-2TEMPERATURE-DEPENDENT PROPERTIES OF CoFeB /MgO … PHYSICAL REVIEW B 98, 214428 (2018)
0.9 10.70.80.911.1
0.851.1
1.3
1.7
3
4K(T)/K(10 K)
MS(T)/MS(10 K)tCoFeB (nm)
Linear fit
1.02
FIG. 4. Double-logarithm plot of K(T)/K(10 K) versus
MS(T)/MS(10 K) for CoFeB/MgO with different CoFeB thicknesses
tCoFeB . Line is a linear fit for the sample with tCoFeB<2 nm.
n=3 according to the Callen-Callen theory [ 13]. A similar
experimental scaling exponent of n∼2.1 was observed for
FePt [ 21], and was explained theoretically by a model based
on two-site exchange anisotropy [ 14].
III. SIMULATIONS
A. Atomistic spin model with single-ion anisotropy
The simulations are based on the atomistic spin model
[22], which naturally models the influence of thermal spin
fluctuations on the intrinsic magnetic properties such as thespontaneous magnetization and magnetic anisotropy. We use aclassical atomistic spin model utilizing the
VA M P I R E software
package for the numerical calculations [ 22,23]. The spin
Hamiltonian using the Heisenberg form of exchange,
H=−/summationdisplay
i<jJijSi·Sj−/summationdisplay
iku(Si·ei)2, (2)
describes the energy of the system, where Jijis an isotropic
exchange constant between nearest-neighbor spins as usualin the Heisenberg model, S
iandSjare spin unit vectors at
local sites iand nearest-neighbor sites j, respectively, kuis the
uniaxial anisotropy constant per atom, and eiis a unit vector
along the magnetic easy axis.
The simulated system is shown schematically in Fig. 5.
The system is generated by creating a bulk body-centered-
MgO
CoFeB
15 nm
15 nmtCoFeB
FIG. 5. Schematic of the simulated system incorporating bulk
and interfacial CoFeB in contact with the MgO layer. The sys-tem dimensions are 15 nm ×15 nm ×t
CoFeB nm, where tCoFeB is the
thickness of the CoFeB layer. Boron impurities indicated by dark
spheres are randomly distributed through the CoFeB.TABLE I. Adopted model parameters.
Bulk Interface
ku(J/atom) 0 1 .35×10−22
Jij(J/link) 7 .735×10−211.547×10−20
cubic (bcc) crystal with lattice constant of 0.286 nm. The
dimensions of CoFeB layer in the simulation are 15 nm ×
15 nm ×tCoFeB nm, with periodic boundary conditions in the
in-plane xandydirections. The Fe and Co atoms are treated
as an average species with an averaged moment of 1 .6μB(μB
is the Bohr magneton). This approximation is not expected
to strongly affect the calculated temperature dependence ofM
SandKresulting from the thermal spin fluctuations. The
boron atoms are included explicitly as nonmagnetic impuri-ties randomly distributed in the CoFeB. Despite the boronbeing nonmagnetic, it strongly affects the magnetic properties,because the presence of the impurities reduces the numberof coordination of the magnetic atoms, and thus reduces theeffective Curie temperature of the whole sample. As withboron, the MgO is nonmagnetic, but has a strong influence onthe magnetic properties of the interfacial Co and Fe atoms.We consider two important effects: one is the presence ofstrong interfacial anisotropy k
u[24], and the other is an en-
hancement of the exchange interaction Jijat the CoFeB/MgO
interface [ 25]. We model the interfacial anisotropy using an
effective uniaxial anisotropy for the CoFeB/MgO interfaciallayer guided by previous first-principles calculations showinga localized enhancement of the anisotropy at the CoFeB/MgOinterface [ 11]. The enhancement of the interfacial exchange
interaction is treated in the same nearest-neighbor approxi-mation as the bulk CoFeB but with an enhanced exchangeconstant. The adopted values of k
uandJijare listed in Table I.
Thekuis derived from the experimental results in Fig. 3, and
the exchange constant Jijis derived from a mean-field expres-
sion of the effective exchange energy [ 22] including a cor-
rection for spin-wave excitations [ 26]. The bottom interfacial
layer of CoFeB to be in contact with Ta is assumed to have nospecial interfacial qualities other than the usual loss of coordi-nation. We do not consider the bulk anisotropy of the CoFeB,as experimentally it is known to be negligibly small [ 8].
The temperature-dependent properties are calculated us-
ing the constrained Monte Carlo method [ 16], in which the
direction of the magnetization is fixed, while the net mag-netization can be changed due to thermal fluctuations. Thecomputational approach chooses moves of two spins, whichare rotated in such a way as to conserve the direction of themagnetization. The static properties can be calculated whenthe system achieves thermal equilibrium after many suchmoves. Due to the symmetry of the system (consisting of asingle high-anisotropy interface layer with periodic bound-aries in the plane), the interfacial anisotropy is wholly uniaxialin nature, resulting in the angle-dependent torque followingas i nθform at all temperatures, where θis the angle from
the film normal. Applying a quadrature rule, the effectiveanisotropic free energy is calculated directly from the thermo-dynamic average of the total torque on the system [ 16]. Given
the sin θform of the torque, we fix θat 45°, at which the
214428-3H. SATO et al. PHYSICAL REVIEW B 98, 214428 (2018)
0.00.51.0
0 500 10000.00.51.01
2
3
4
5MS(T)/MS(0 K)t (nm)(a)
Bulk(b)MS(T)/MS(0 K)
T(K)Interface
t =3nm
FIG. 6. Simulated temperature Tdependence of normalized
spontaneous magnetization MS(T)/MS(0) for the CoFeB/MgO sys-
tem with B composition of 4% (a) as a function of CoFeB thicknessest
CoFeB and (b) surface and bulk components for CoFeB with tCoFeB=
3 nm. Lines are fits by Eq. ( 3).
torque is largest, to minimize the numerical error. The Monte
Carlo (MC) trial moves use the Hinzke-Nowak method using acombination of different trial moves to optimize the relaxationto thermal equilibrium [ 27]. After equilibrating the system by
10 000 MC steps, the thermodynamic averages of the torqueand magnetization are collected averaging over further 10 000MC steps.
B. Calculation of the spontaneous magnetization
Because of Jij/greatermuchku, the anisotropy has a negligible effect
on the calculated MS(T). Figure 6(a) shows the calculated
MS(T) normalized by MS(T=0) as a function of tCoFeB of the
CoFeB/MgO system with B composition of 4%. The value of4% is extracted from a series of calculations to give the bestagreement with the experimentally measured temperature-dependent magnetization. The reduced boron composition inthe simulation is consistent with an experimental result thatthe boron composition in the CoFeB film is reduced owing toabsorption by Ta adjacent to the CoFeB layer via annealing[28].
Because the CoFeB layers consist of a few monolayers, the
magnetization curves in Fig. 6(a) show significant finite-size
effects. This is apparent in the reduced criticality of the mag-netization curve compared with a bulk sample, as well as a vis-ible variation among samples with different t
CoFeB . It is clear
from the simulations that the low-temperature gradient of themagnetization is thickness dependent, as seen also in the ex-perimental data (Fig. 2). Quantitative agreement between the
experimental data and simulations is obtained for thin CoFeBafter tuning the boron concentration in the simulations.
Both experimental and simulated sets of data show a
decrease in the gradient with increasing t
CoFeB . In the case
of the simulations, this decrease is purely due to finite-sizeeffects. As the film thickness increases, the thermally fluc-tuating surface spins make up a smaller portion of the totalmagnetization, and thus the gradient approaches the classicallimit for the bulk with a slower variation of M
S(T). For the
experimental result, we see a similar behavior; however, thelarge change of the gradient for the thicker films seen in Fig. 2
may suggest the presence of an additional effect. For bulkCoFe, one would expect the usual Bloch-like behavior, wherethe gradient of the temperature-dependent magnetization issmall due to the quantum nature of the spin-wave spectrum[29]. For the thin-film samples studied in the present work,
however, it is clear that the gradient is much closer to that of aclassical system, where the atomic spins are unquantized. Weattribute this fundamental disparity to microstructural disorderand the polycrystalline nature of the films, which disruptthe long-range crystallinity and quantum nature of the spinwaves. One would therefore expect that these effects becomeless important for larger film thicknesses, and so the largerdecrease in the gradient of M
S(T) compared to the classical
simulations is indicative of a classical-quantum transition.This transition indicates an important finite-size effect, wherethe microstructural disorder can disrupt the quantum natureof the spin-wave spectrum leading to significantly differentM
S(T) from the expected bulk behavior.
The temperature-dependent magnetization MS(T)f o ra
classical system is well described by the expression [ 29]
MS(T)
MS(0)=/parenleftbigg
1−T
TC/parenrightbiggβ
, (3)
where βis a critical exponent. We fit Eq. ( 3) to simulated
MS(T) treating TCandβas free parameters. The obtained
TCis∼1100 K, which is not strongly dependent on tCoFeB .
However, it is important to note that the finite-size effect isvisible in the larger magnetization fluctuations in the inter-face layers, which has a strong influence on the temperaturedependence of the anisotropy. This is an important genericfeature of ultrathin films, arising from the loss of magnetic
coordination at the interface. In the case of CoFeB/MgO, an
enhanced exchange interaction at the surface included in thesimulation might be expected to somewhat compensate thiseffect [ 23].
To investigate the difference in the temperature depen-
dence between interface and bulk-like magnetization, we havecalculated separate contributions from the MgO-terminatedinterface and bulk atoms to the total magnetization, as shownin Fig. 6(b). The bulk atoms make up the majority of the com-
plete system, and so the average magnetization is generallycloser to the net magnetization. The temperature-dependentmagnetizations show a slightly elevated Curie temperature forthe MgO-terminated interface atoms compared with the bulk,owing to the stronger exchange interactions at the interface.The calculated Curie temperature for the interfacial atoms alsoconverges rapidly to an asymptotic value. The temperaturedependence of the interface magnetization is an importantquantity that determines the spin fluctuations of the interfaciallayer, which provides the magnetic anisotropy.
C. Calculation of the perpendicular anisotropy
b a s e do ns i n g l e - i o na n i s o t r o p y
The magnetocrystalline anisotropy in the CoFeB/MgO sys-
tem arises almost solely from the MgO-terminated interface.We proceed with calculation of the temperature dependence
214428-4TEMPERATURE-DEPENDENT PROPERTIES OF CoFeB /MgO … PHYSICAL REVIEW B 98, 214428 (2018)
0 500 1000012
1
2
3
4
5K(MJ/m3)
T(K)tCoFeB (nm)
FIG. 7. Calculated temperature Tdependence of magnetic
anisotropy energy densities Kfor the CoFeB/MgO as a function of
CoFeB thicknesses tCoFeB based on single-ion anisotropy.
of the interface anisotropy using the constrained Monte Carlo
method [ 16]. The calculated free anisotropy energy for dif-
ferent tCoFeB is shown in Fig. 7(a). All samples have a single
MgO-terminated interface with the same anisotropy energy,which leads to a change in the average magnetic anisotropyenergy density, allowing engineering of the magnetic proper-ties through thickness variation [ 8]. Additionally, the different
temperature dependence of the surface magnetization leads toa different temperature dependence of the anisotropy for thesamples with different t
CoFeB . According to Eq. ( 1), we make
double-logarithm plots of K(T)/K(10 K) versus MS(T)/MS(10
K) (Callen-Callen plots) (as shown by dashed line in Fig. 9
shown later) [ 13]. We determine the scaling exponent nto
be 2.82–3.26, which is close to 3 expected from single-ionanisotropy but inconsistent with the experimental observationin Fig. 4. This indicates that the magnetic anisotropy in
CoFeB/MgO thin films is not single ion in origin.
D. Calculation of the perpendicular anisotropy
b a s e do nt w o - s i t ea n i s o t r o p y
Two-site anisotropy arises from an orientation-dependent
exchange interaction. For example, in layered L10alloys such
as FePt, the symmetry of the crystal along the caxis causes an
asymmetry in the exchange interactions between atoms in thesame plane [ 14,15] leading to a two-site exchange anisotropy.
This is also expected to be the case for CoFeB/MgO layers,where the hybridization of the interfacial Fe layer leads toa change in symmetry along the zdirection. The two-site
anisotropy can be expressed by an exchange tensor as aperturbation of the usual isotropic exchange,
J
T
ij=⎡
⎣Jxx 00
0Jyy 0
00 Jzz⎤
⎦, (4)
where subscripts to Jof tensor components denote the compo-
nents of the spin direction at iandjsites. For a system with
only two-site anisotropy, the spin Hamiltonian is given by
Hex=−/summationdisplay
i<jSiJT
ijSj. (5)In the case of isotropic exchange, all the diagonal exchange
components are the same, Jxx=Jyy=Jzz. For anisotropic
exchange with asymmetry along the zdirection, Jxx=Jyy/negationslash=
Jzz.
The value of the effective anisotropy at very low tem-
peratures is the same and independent of its physicalorigin, where the origin is only evident from the scaling withrespect to the magnetization. Therefore, in our model wemust translate the value of anisotropy from Sec. II C intoa two-site exchange anisotropy. Considering the exchangeinteractions between two spins S
iandSj, we have the total
exchange energy Eex=−JxxSixSjx−JyySiySjy−JzzSizSjz,
where subscripts for Si(j)denote the x,y, andzcomponents
of spin at i(j) site, respectively. In ferromagnets at low
temperatures, all spins are well aligned and so it can beassumed that S
i≈Sj. For the case with an easy axis along
thezdirection and spin rotation in the z-xplane ( Sz=cosθ
andSx=sinθ), we obtain Eex=(Jzz−Jxx)sin2θ−Jzz, and
thus the anisotropic exchange gives the exchange energy withan identical sin
2θsymmetry to the single-ion anisotropy.
The total two-site exchange anisotropy is expressed by thedifference in the diagonal values of the exchange tensorJ
zz−Jxx.For spins with several neighbors, the anisotropy
energy should be divided amongst each of the interactions togive the same effective anisotropy. In the case of a nearest-neighbor model the coordination number defines the numberof interactions, giving geometric factors of 1 /6f o rs i m p l e
cubic, 1 /8 for bcc, and 1 /12 for face-centered-cubic and
hexagonal lattices. The CoFeB/MgO interfacial anisotropyis a special case, since the anisotropy arises from the Fe-Ohybridization and the interfacial atoms are only half coordi-nated. In this case, the anisotropic exchange energy should bedivided among the four nearest atoms in the interface, givinga geometric factor of 1 /4. In this case, the exchange values at
the interface in terms of the parameters from Table Iare given
by
J
xx=Jij,J yy=Jij,J zz=Jij+ku/4. (6)
The bulk parameters are unchanged. Revisiting the simu-
lations using the spin Hamiltonian given in Eq. ( 5), we now
explicitly exclude any single-ion contribution to the effective
0 500 10000.00.51.0
single ionK(MJ/m3)
T(K)tCoFeB =2nm
two site
FIG. 8. Calculated temperature Tdependence of magnetic
anisotropy energy densities Kfor the CoFeB/MgO with 2-nm-thick
CoFeB based on two-site anisotropy along with that based on single-
ion anisotropy shown in Fig. 7.
214428-5H. SATO et al. PHYSICAL REVIEW B 98, 214428 (2018)
0.9 10.70.80.911.1
1.021.1
1.3
1.7K(T)/K(10 K)
MS(T)/MS(10 K)tCoFeB (nm)
0.85
FIG. 9. Double-logarithm plot of K(T)/K(10 K) versus
MS(T)/M S(10 K) for CoFeB/MgO. Symbols correspond to the
experimental results for the samples with CoFeB thicknesses less
than 2 nm. Lines are determined from linear fitting to the simulatedresults (solid line for two-site anisotropy and dashed line for
single-ion anisotropy).
anisotropy. We note that in both cases the total effective
interfacial anisotropy at zero temperature is the same. Theobtained K(T) is shown in Fig. 8.
The scaling plots between K(T)/K(10 K) and M
S(T)/MS(10
K) give the scaling exponent nof 2.21, which is consis-
tent with the experimental observation as shown in Fig. 9.
The result indicates that the Callen-Callen plot gives n∼2
for systems with two-site anisotropy [ 14], indicating that the
Callen-Callen plot can be used to gain insight into the originof the anisotropy [ 30].
IV . CONCLUSION
We have conducted a joint experimental and computa-
tional study on the temperature-dependent magnetization andmagnetic anisotropy of CoFeB/MgO ultrathin films. Our ex-perimental measurements have found the strong temperaturedependence of the saturation magnetization in close agree-ment with classical atomistic spin-model simulations. The
scaling of the anisotropy with the magnetization providesdirect insight into the physical origin of the anisotropy bycomparison with the Callen-Callen theory. From the Callen-Callen theory, a scaling exponent of n=3 suggests local
single-site anisotropy while an exponent of n∼2 suggests
two-site exchange anisotropy. Experimental measurementsgive the scaling exponent of n=2.2, indicating the dominant
role of two-site exchange anisotropy in this material system.We have also performed atomistic simulations to comparewith experimental observation by considering thermal fluctu-ations due to the finite-size effect and a reduction in atomiccoordination at the interface. The atomistic simulations withsingle-ion anisotropy model result in n=3.03 as expected,
which does not agree with the experimental results. The sim-ulations with purely two-site exchange anisotropy reproducethe experimentally observed value ( n=2.2). In this work,
we assume identical magnetic atoms in a uniform structureand negligible anisotropy at CoFeB/Ta interface, suggestingthat the temperature-dependent magnetic properties are de-termined mainly by the MgO/CoFeB interface. This studyprovides information of the important factors determiningthe temperature-dependent thermal stability of CoFeB/MgOmagnetic tunnel junctions and to guide the design of structuresfor various applications.
ACKNOWLEDGMENTS
The work was partly supported by JSPS Core-to-Core
Program and RIEC Cooperative Research Projects. The workat Tohoku University was supported by ImPACT program ofCSTI and a Grant-in-Aid for Scientific Research from MEXT(Grant No. 26103002). This work made use of the facilitiesof N8 HPC Centre of Excellence, provided and funded bythe N8 consortium and EPSRC (Grant No. EP/K000225/1),coordinated by the Universities of Leeds and Manchester. P.C.gratefully acknowledges the funding from MahasarakhamUniversity.
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214428-7 |
PhysRevB.95.024409.pdf | PHYSICAL REVIEW B 95, 024409 (2017)
Skyrmion oscillations in magnetic nanorods with chiral interactions
M. Charilaou*and J. F. L ¨offler
Laboratory of Metal Physics and Technology, Department of Materials, ETH Zurich, 8093 Zurich, Switzerland
(Received 15 November 2016; published 10 January 2017)
We report that in cylindrical nanorods with chiral interactions spin textures corresponding to spatial skyrmion
oscillations can be stabilized depending on the initial state, as revealed by micromagnetic calculations. Theskyrmion oscillation, or skyrmion-chain state, occurs when the diameter of the rod is larger than the helical pitchlength of the material, and the number of skyrmions on the chain is proportional to the length of the nanorod. Thetopological charge is localized, breaking translational symmetry, but in the presence of a uniaxial anisotropy, orupon the application of an external field, the localization disappears and a single skyrmion line is formed. Thesefindings provide a deeper understanding of the interplay between geometry and topology, and show how spatialconfinement specifically in curved solids can stabilize skyrmionic spin textures.
DOI: 10.1103/PhysRevB.95.024409
I. INTRODUCTION
Competition between the symmetric exchange interac-
tion and the antisymmetric Dzyaloshinskii-Moriya interaction(DMI) [ 1] can give rise to the formation of complex spin
textures in magnetic matter. A fascinating example is theoccurrence of skyrmions [ 2–7] and skyrmion lattices [ 8–11]
upon the application of an external field or in the presenceof uniaxial anisotropy. Magnetic skyrmions are topologicalparticlelike spin configurations that are characterized by aninteger topological charge (winding number as defined forspin textures) [ 12]
Q=1
4π/integraldisplay
m·(∂xm×∂ym)dxdy, (1)
which can be either 1 (skyrmion) or −1 (antiskyrmion),
where mis the unit vector of the magnetization ( m=M/M S
withMSthe saturation magnetization).
The intense research on skyrmions is fueled on the one
hand by the new fundamental physics related to these complexspin structures, and on the other hand by the potential todevelop new technology for data-storage devices. The latteris motivated by the fact that skyrmions can be moved byrelatively low current densities [ 13–17], promising energy-
efficient spintronics, and the compatibility of skyrmion-baseddevices with domain-wall-based technology, which can beachieved by adjusting the geometry of the solid [ 18].
In bulk crystals with free surfaces skyrmions exist in a
narrow temperature-field range, close to the Curie temperature[8,19,20], but in thin films the skyrmion phase extends to wider
temperature and field ranges [ 7,20], and in nanostructured ma-
terials skyrmions are stable even at room temperature [ 21,22].
The stability of skyrmionic states is crucially dependent on thelow dimensionality and symmetry of the solid, as it confinesthe spin structure [ 23–25]. The confinement of skyrmionic spin
textures in nanostructures is thus a key element in creating andcontrolling them. As we will discuss in the following, using
high-resolution micromagnetic simulations considering B20
FeGe, the geometry of cylindrical nanostructures can give rise
*charilaou@mat.ethz.chto nontrivial spin textures, which break translational symmetryin the form of spatially oscillating topological charge.
II. THEORETICAL MODEL
For the theoretical description of magnetism in FeGe
nanorods we consider the following contributions to the totalfree energy density F: (i) ferromagnetic exchange
F
exc=Aexc(∇m)2, (2)
where Aexcis the exchange stiffness; (ii) Dzyaloshinskii-
Moriya interaction
FDMI=Dm·(∇×m), (3)
where Dis the strength of the DMI; (iii) Zeeman energy
FZ=−μ0MSHext·m, (4)
where Hextis the external field; and (iv) magnetostatic self-
energy due to dipolar interactions
Fdip=−μ0MS
2m·hdemag, (5)
where hdemag is the local demagnetizing field.
We start the simulations at a fully polarized configuration
(energy maximum), and observe the evolution of the spintexture inside the solid as a function of time by solving theLandau-Lifshitz-Gilbert equation of motion
∂
tm=−μ0γ(m×heff)+α(m×∂tm), (6)
where αis the dimensionless damping parameter [ α=
G/(γM S)], with Gthe Gilbert damping frequency con-
stant and γthe electron gyromagnetic ratio, and heff=
−[1/(μ0MS)]∂mFis the effective magnetic field consisting
of both internal and external fields. The material parametersfor FeGe taken from literature are: exchange stiffness A
exc=
8.78 pJ/m[26], saturation magnetization MS=385 kA /m
[27,28], and DMI strength D=1.58 mJ /m2[26]. Since the
DMI energy in FeGe is intrinsic and not of interfacial origin,it should not depend on the thickness, hence the DMI strengthwas kept constant throughout this study. For the numericalcalculations the graphics-processing-unit accelerated softwarepackage MuMax3 [29] was used in the high-damping case with
α=0.1 (occasional checks with α=0.01 were made to test
2469-9950/2017/95(2)/024409(5) 024409-1 ©2017 American Physical SocietyM. CHARILAOU AND J. F. L ¨OFFLER PHYSICAL REVIEW B 95, 024409 (2017)
(a) (b)
-10+1mzz
FIG. 1. Simulated ultrathin nanodisks with diameter of 120 nm
after an external field of 1 T has been applied (a) in-plane and (b)
out-of-plane. In (b) a skyrmion core forms.
the effects of damping on the simulation findings). Simulations
were performed with different cell sizes to test the numericalstability, with the smallest cell tested being 1 nm
3. Even though
very small sizes were used, quantum-mechanical effects werenot considered in our simulations.
III. RESULTS AND DISCUSSION
We begin the discussion by considering ultrathin FeGe nan-
odisks. A crucial aspect for the realization of a skyrmion in anultrathin structure is the presence of a perpendicular symmetry-breaking field, either external or internal, e.g., perpendicularmagnetic anisotropy (PMA). Without an external field or PMA,the state with lowest energy corresponds to a helical spintexture [see Fig. 1(a)]. If, however, we prepare the skyrmion
state by magnetizing the sample in the out-of-plane directionusing an external field ( μ
0Hz=1 T) and then switching off
the field, the resulting spin texture is that of a left-handedskyrmion core [see Fig. 1(b)], in which the zcomponent of
the magnetization in the center of the disk is m
z=+1 and
at the edge of the disk it is mz≈−1. The numerical value of
the topological charge for this spin texture is Q≈0.85 (for a
perfect skyrmion of Q=±1). The deviation from the integer
value is due to the tilting of the spins along the circumferenceof the disk by dipolar interactions [ 23,26], which generally
tend to align the moments along the physical edge of the solid[30]. A similar scenario, i.e., where the skyrmion state can be
prepared by a sequence of magnetic fields, was experimentallyobserved in artificial skyrmion lattices [ 31].
The formation of the skyrmion core, instead of the helical
state, can be explained with topological arguments: in orderto transfer from a collinear perpendicular state (global energymaximum) to a helical state (global energy minimum), the spintexture needs to undergo curling, which begins by a twisting ofthe spins near the edges of the disk. The twisting at the edgeslowers the total energy because it favors both the dipole-dipoleinteraction and DMI energy, and the system is trapped in thisstate (local energy minimum) because there is no continuousway to transfer the spin texture to a helical state due to theconfinement by the solid. In contrast, if the system is fullypolarized in the plane, there is a direct way to transfer the
spin texture from the collinear state to the helical state, thusgenerating the texture as seen in Fig. 1(a).
For the confinement of the skyrmionic spin texture, the
diameter ( d) of the disk needs to be comparable to the
skyrmion-core diameter, which depends on the interplaybetween the DMI and magnetostatic interactions [ 23]. For
d> 135 nm the spin texture forms concentric rings with
alternating m
z(not shown), similar to those discussed in Refs.
[23,26,32]. While the upper limit is set by the formation of the
ring state, defining a lower limit for dis not straightforward,
since with decreasing diameter the skyrmion core becomesincreasingly incomplete, and for very small dit corresponds to
a conical state. (This again shows that the transformation froma conical spin configuration to a skyrmion is continuous in ananodisk.) We find, however, that a single skyrmion in FeGeultrathin disks is stable for diameters in the range of 70 nm
(b)
(c)
(a)
mz
+1
-1
FIG. 2. Spin configurations in cylindrical nanowires with a length
of 500 nm and a diameter of 120 nm showing (a) the helicoid state and
(b) the skyrmion state with oscillating spin texture. The two slices
and their respective magnetization profile show the two modes ofoscillation. The dashed line is a fit with the 2 πdomain wall profile
(see text). (c) A contour plot of the zcomponent of the magnetization
inside the nanowire shown in (b) and the oscillation of the topologicalcharge [see Eq. ( 1)]Qalong the wire.
024409-2SKYRMION OSCILLATIONS IN MAGNETIC NANORODS . . . PHYSICAL REVIEW B 95, 024409 (2017)
(Q=0.7) to 135 nm ( Q=0.84), i.e., λ<d< 2λ, where
λ=4πA exc/D≈70 nm is the characteristic pitch length for
FeGe.
Note that without dipolar interactions the upper limit for a
single skyrmion core is d< 90 nm. Hence, dipolar interactions
are crucial in stabilizing the skyrmion, as they tend to alignthe spins along the physical edge of the disk, thus shrinkingor stretching the skyrmion in order to satisfy this condition.This importance of dipolar interactions was recently discussedwith regards to experiments on Pt/Co/MgO nanostructures
[22]. The interplay between dipolar interactions and DMI
can be studied by the two characteristic lengths, i.e., λand
the exchange length [ 12,33]δ
M=2√
Aexc/(μ0M2
S), which for
FeGe is 14 nm. When λ> >δ M, the curling period of the spin
structure is longer than the exchange length. As, however, theDMI increases and λdecreases, the curling is impeded by the
dipolar interactions and the role of magnetostatics becomesmore important.
Now we turn to three-dimensional (3D) structures, cylindri-
cal nanowires, in order to examine the dimensional evolutionof the skyrmion state in cylindrical geometry. The state wasprepared in the same way as for the nanodisks, i.e., initializingthe system at an energy maximum and observing the resultingstate. Similar to the nanodisks, there are two competing states:the helicoid (distorted helical) [ 34] state and the skyrmion
state. The helicoid state, prepared by applying an externalfield perpendicular to the rod axis, is shown in Fig. 2(a)
for a nanorod with 120 nm diameter and 500 nm length.If we apply the external field along the rod axis, however,the resulting spin structure is a striking spin texture withbroken translational symmetry, where the core of the rodis magnetized along the zaxis and the outer regions aremagnetized in the opposite directions, with a distinct spatial
oscillation [see Fig. 2(b)]. The oscillation of the spin structure
is characterized by the oscillation of the topological chargeQ, as shown in Fig. 2(c), which oscillates between Q≈0.9
andQ≈0.2 with a sinusoidal form Q∝sin(πl//Lambda1 ), with a
period of /Lambda1=95 nm. The regions with high Qcorrespond to
skyrmion formations, whereas the low Qregions resemble a
ring formation [ 23,26,32], a mexican-hat-like spin texture.
Figure 2(b) shows slices of the spin structure in these two
regions, and the corresponding magnetization profile. Thecore profile of both regions can be fitted well by that of a2πdomain, i.e., the profile of a skyrmion, which has the
form [ 12]θ
m=θs(−r/δ s+R)+θs(−r/δ s−R), with θs(ξ)=
2a r c t a n eξ, where θmis the angle of the magnetic moment at the
distance raway from the center (here the distance from the wire
center), Ris a variational parameter, and δsis the skyrmion
radius. Hence, both regions contain a skyrmion core, but inthe low Qregion the spin texture at the edge has an opposite
winding nearly canceling that of the inner skyrmion core, thusreducing Q. Given that the translational symmetry is broken,
and despite the fact that the spin texture appears continuous,the state seen in Fig. 2(b) corresponds to a skyrmion chain ,o r
a skyrmion stack, since the skyrmions are stacked/displacedvertically from each other.
In order to find the rod diameters, for which the skyrmion-
chain state is stable, we have simulated conical structures, witha base diameter of 200 nm and a tip diameter of 25 nm, havingan inclination of 2 .5
◦over a length of 4 μm. Figure 3shows a
vector plot of the spin texture and a contour plot of the magne-tization along the zaxis of the cone. On going from a very thin
nanowire to a 200 nm thick nanowire we find a number of pos-sible states: for small diameters ( d/lessorequalslant60 nm) we obtain a nearly
mz200 nm25 nmskyrmion chain helicoid helicoid conical ring state
60 nm 100 nm 140 nm 160 nm
D= 1.0 mJ/m
D= 1.4 mJ/m
D= 1.8 mJ/m2
2
2(a)
(b)
(c)
FIG. 3. (a) Snapshot of simulation performed on a FeGe cone, showing the possible spin textures at each range of diameters, starting
with a conical spin structure for thin rods d/lessorequalslant60 nm, then a helicoid spin structure for 60 <d/lessorequalslant100 nm, entering the skyrmion-chain state
for 100 <d/lessorequalslant140 nm, then again a helicoid structure for 140 <d/lessorequalslant160 nm, which then transforms to a ring state for d> 160 nm. (b)
Comparison between three systems with different DMI strength and (c) diameter ( dsc) at which the skyrmion-chain state becomes stable as a
function of DMI strength; circles are simulation results and solid lines are fits using dsc∝1/D:dscis proportional to the characteristic pitch
length [inset to (c)].
024409-3M. CHARILAOU AND J. F. L ¨OFFLER PHYSICAL REVIEW B 95, 024409 (2017)
(b)
(a)
FIG. 4. Cross section of cylindrical nanowires with diameter
120 nm and length 500 nm with (a) a uniaxial anisotropy ( Ku), and
(b) an external field. The spin structure corresponds to that of a single
skyrmion line, characterized by the absence of oscillations in Q.T h e
dashed line is a fit with the 2 πdomain wall profile.
collinear texture with some curling on the edge of the solid,
corresponding to a conical state; for 60 /lessorequalslantd/lessorequalslant100 nm we find
a helicoid structure, which is the 3D analog of the 2D helicalstructure in Fig. 1(a); then, for 100 /lessorequalslantd/lessorequalslant140 nm we find the
skyrmion-chain state, as shown in Fig. 2(b).F o rd> 140 nm a
helicoid texture is favored, which transforms to a complex ring-state oscillation that unfolds via the formation of hedgehogs,
or Bloch points, similar to those shown by Milde et al. [35].
In order to find the stability range of the skyrmion-chain
state, we have simulated nanowires with different DMIstrength and diameter, and we find that the diameters ( d
sc)
for which the skyrmion-chain state is stable are proportionalto the characteristic length d
sc∝λ∝1/D, i.e., when the DMI
is increased ( λis decreased) the skyrmion-chain state is stable
in thinner nanorods, and vice versa [see Fig. 3(c)]. This shows
how these complex spin textures are the result of competitionbetween the different energy contributions (exchange andDMI) and their characteristic lengths.
In the skyrmion-chain state the localization of Qcan be
suppressed by adding anisotropy in the energy of the system,
either with an external field or with uniaxial anisotropy. Let us
consider a hypothetical scenario of a system with exactly thesame material parameters ( M
S,Aexc, andD) as FeGe, which
additionally has a uniaxial magnetocrystalline anisotropy Ku
(see Fig. 4). For very small anisotropy ( Ku<103J/m3)t h e
skyrmion oscillation remains unchanged, but with increasingK
u, the oscillation of Qin the nanowire gradually decreases
(we quantify this by measuring /Delta1Q=Qmax−Qmin), and
forKu>2×104J/m3the oscillation vanishes. Figure 4(a)
shows the spin structure for Ku=105J/m3(we chose this
value because it is comparable to the magnetostatic self-energyμ
0M2
S/2), which is a continuous skyrmion line along the rod
withQ=0.85.Similarly, if we break the symmetry by an external field
along the zdirection opposing the magnetization in the core
(without having Ku), the resulting spin configuration is again
a single skyrmion line along the rod [see Fig. 4(b)]. For
a one-to-one comparison between the effect of internal vsexternal field, the applied field in this example was set equal tothe anisotropy field from the example shown in Fig. 4(a), i.e.,
(|μ
0Hz|=μ0Han=2Ku/M S=0.52 T). The external field
not only generates a single skyrmion line, but also decreasesthe skyrmion radius. In fact, with increasing (opposing) H
z,
the skyrmion radius decreases monotonically up to the criticalfield, at which Q→0 and m
z→− 1. Once mz=−1, if we
switch off the external field, the spin configuration will returnto that of a skyrmion chain, but with opposite polarity. Whenthe external field is applied parallel to the polarity in the rod,the skyrmion radius dramatically decreases and vanishes forvery small fields (in this case 100 mT).
All the predictions made here may be verified experimen-
tally, either by real-space observation, i.e., Lorentz transmis-sion electron microscopy or magnetic force microscopy, or byreciprocal space investigations, such as polarized small-angleneutron scattering. It is expected that the material propertiesmight deviate from the values used in this study, due toinhomogeneities, roughness, and the free surfaces, and thiscould have an effect on the nanowire diameters, for whichthe described magnetic state can be observed, as these areproportional to the characteristic length λ.
IV . CONCLUSIONS
In summary, we have shown that geometrical confinement
in cylindrical nanowires enables the occurrence of nontrivialskyrmion chains with broken translational symmetry, witha distinct oscillation of the topological charge along thewire. The wire thicknesses, for which this state is stable,depend linearly on the characteristic helical pitch-length ofthe material, which in turn depends on the ratio betweenthe strength of the ferromagnetic exchange stiffness and theDzyaloshinskii-Moriya interaction. An external field or uniax-ial anisotropy can turn the structure to that of a single skyrmionline, restoring translational symmetry. These findings providea deeper understanding of the stability of skyrmionic spinconfigurations in nanostructures, where spatial confinementplays a vital role. They may also be of great importance for thefurther development of spintronics towards skyrmion-basedtechnologies, where cylindrical nanostructures can be used toinject/read skyrmions when coupled to other devices.
ACKNOWLEDGMENTS
We would like to thank H.-B. Braun and C. Moutafis for
fruitful discussions. This work was funded by the ETH Zurich.
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024409-5 |
PhysRevLett.103.117201.pdf | Ultrafast Path for Optical Magnetization Reversal via a Strongly Nonequilibrium State
K. Vahaplar,1,*A. M. Kalashnikova,1,5A. V. Kimel,1D. Hinzke,2U. Nowak,2R. Chantrell,3A. Tsukamoto,4,6A. Itoh,4
A. Kirilyuk,1and Th. Rasing1
1Institute for Molecules and Materials, Radboud University Nijmegen, P .O. Box 9010 6500 GL Nijmegen, The Netherlands
2Fachbereich Physik, Universita ¨t Konstanz, D-78457 Konstanz, Germany
3Department of Physics, University of York, York YO10 5DD, United Kingdom
4College of Science and Technology, Nihon University, 7-24-1 Funabashi, Chiba, Japan
5Ioffe Physical-Technical Institute of the Russian Academy of Sciences, 194021 St. Petersburg, Russia
6PRESTO, Japan Science and Technology Agency, 4-1-8 Honcho Kawaguchi, Saitama, Japan
(Received 10 April 2009; revised manuscript received 28 July 2009; published 8 September 2009)
Using time-resolved single-shot pump-probe microscopy we unveil the mechanism and the time scale
of all-optical magnetization reversal by a single circularly polarized 100 fs laser pulse. We demonstratethat the reversal has a linear character, i.e., does not involve precession but occurs via a stronglynonequilibrium state. Calculations show that the reversal time which can be achieved via this mechanismis within 10 ps for a 30 nm domain. Using two single subpicosecond laser pulses we demonstrate that for a5/C22mdomain the magnetic information can be recorded and readout within 30 ps, which is the fastest
‘‘write-read’’ event demonstrated for magnetic recording so far.
DOI: 10.1103/PhysRevLett.103.117201 PACS numbers: 75.40.Gb, 75.60.Jk, 85.70.Li
The fundamental and practical limit of the speed of
magnetization reversal is a subject of vital importance for
magnetic recording and information processing technolo-
gies as well as one of the most intriguing questions of
modern magnetism [ 1–8]. The conventional way to re-
verse the magnetization Mis to apply a magnetic field
Hantiparallel to M. In this collinear M-H geometry the
reversal occurs via precession accompanied by damping
that channels the associated angular momentum into the
lattice. Although this process is perfectly deterministic, it
is also unavoidably slow, typically of the order of nano-seconds, due to the required angular momentum transfer
[8].
Alternatively, the driving field can be applied orthogonal
toM, so that the created torque [ M/C2H] leads to a rapid
change of the angular momentum and a possible switching
of the magnetization [ 1,3,4,9]. However, such precessional
switching requires a magnetic field pulse precisely tuned to
half of the precession period. The fastest precessional
reversal demonstrated so far using an external magnetic
field [ 1,5] or a spin-polarized current [ 6,7,10] is limited to
100 ps. Moreover, it has been shown that for field pulsesshorter than 2.3 ps such a switching becomes nondetermin-
istic [ 5,11].
Ultrafast laser-induced heating of a magnetic material is
known to stimulate the transfer of angular momentum fromspins to lattice on a femtosecond time scale [ 12,13]. It has
been recently demonstrated that a 40 fs, circularly polar-
ized, laser pulse is able to reverse magnetization in a col-
linear M-H geometry [ 14], as if it acts as an equally short
magnetic field pulse H
eff/C24½E/C2E/C3/C138(where Eis the
electric field of light) pointing along the direction of light
[15]. Although this experiment showed the intriguing pos-
sibility of triggering magnetization reversal with a subpi-cosecond stimulus, the relevant time scales and mechanism
of such an optically induced magnetization reversal arestill unanswered questions, since a precessional switchingwithin 40 fs would require enormous effective magneticfields above 10
2Tand unrealistically strong damping. To
address these questions we used femtosecond single-shot
time-resolved optical imaging of magnetic structures andmultiscale modeling beyond the macro-spin approxima-tion. The combination of these advanced experimentaland theoretical methods unveiled an ultrafast linear path-way for magnetization reversal that does not involve pre-cession but occurs via a strongly nonequilibrium state.
In our experiments the amorphous ferrimagnetic 20 nm
Gd
xFe100/C0x/C0yCoyfilms with perpendicular anisotropy [ 14]
were excited by a single circularly polarized laser pulse
(FWHM of about 100 fs, a central wavelength at /C210¼
800 nm ). A single linearly polarized probe pulse
(FWHM ¼100 fs ,/C210¼640 nm ) delayed with respect
to the pump was used for ultrafast imaging of the magneticdomain structure by means of the magneto-optical Faradayeffect. Magnetic domains with magnetization parallel(‘‘up’’) or antiparallel (‘‘down’’) to the sample normalare seen as white or black regions, respectively, in an imageon a CCD camera [ 16]. After each ‘‘write-read’’ event, the
initial magnetic state was restored by applying a magnetic
field pulse. Taking images of the magnetic structure fordifferent delays between the pump and probe pulses wewere able to visualize the ultrafast dynamics of the laser-induced magnetic changes in the material.
Figure 1(a) shows images of magnetic domains in a
Gd
24Fe66:5Co9:5sample at different delays after excitation
by right- ( /C27þ) or left-handed ( /C27/C0) circularly polarized
pulses. The images were obtained for both types of do-
mains with initial magnetization up and down. In the firstPRL 103, 117201 (2009)
Selected for a Viewpoint inPhysics
PHYSICAL REVIEW LETTERSweek ending
11 SEPTEMBER 2009
0031-9007 =09=103(11) =117201(4) 117201-1 /C2112009 The American Physical Societyfew hundreds of femtoseconds, pump pulses of both he-
licities bring the originally magnetized medium into astrongly nonequilibrium state with no measurable net mag-
netization, seen as a gray area in the second column of
Fig. 1(a), the size of which is given by the laser beam
intensity profile. In the following few tens of picosecondseither the medium relaxes back to the initial state or a small(/C245/C22m) domain with a reversed magnetization is formed.
It is thus obvious that (i) the switching proceeds via astrongly nonequilibrium demagnetized state, clearly notfollowing the conventional route of precessional motion,
and (ii) the final state is defined by the helicity of the 100 fs
pump pulse [last column of Fig. 1(a)].
As one can see from Fig. 1(a), the metastable state
corresponding to reversed magnetization is reached within60 ps after /C27
þ(/C27/C0) excitation. This state is, however,
slightly different from the final state [the last column inFig.1(a)], as clearly seen from Fig. 1(b). This happens due
to the laser-induced heating of the sample followed by slow(/C291n s) heat diffusion [ 17]. To take into account renor-
malization of the two metastable states of magnetization at
the subnanosecond time scale we introduce two asymptoticlevels [see dashed lines in Fig. 1(b)]. The characteristic
time of switching /C28
swcan be identified as the time required
to reconstruct 63% ( 1/C0e/C01) the difference between themetastable states [Fig. 1(b)]. For example, in Fig. 1,/C28sw¼
60 ps . After 1:5/C28swthe difference reaches 80% and, as also
can be seen from Fig. 1(a), this time can be reliably
assumed as the period required for a write-read event(/C28
w-r¼90 ps for the example in Fig. 1). The switching
time is in fact surprising, because in contrast to heat-
assisted magnetic recording [ 18], the reversal time is
much longer than the effective light-induced magnetic field
pulse Heff. The duration of the latter /C1teffis still an open
question but can be different from the FWHM of theoptical pulse. However, /C1t
effcan be estimated from the
spectrum of THz radiation generated by an Fe film when
the latter is excited by a subpicosecond visible laser pulse.According to Ref. [ 19], the intensity of the THz emission
depends on the polarization of the incoming light and has
to be explained in terms of difference-frequency genera-
tion. Phenomenologically, this is very similar to the inverse
Faraday effect. Based on a half-period oscillation with thelowest frequency in the THz spectrum [ 19], the maximum
/C1t
effis about 3 ps. The pulse amplitude Heff, for a typical
pump fluence of 2:5J=m2and the magneto-optical con-
stant of GdFeCo ( /C243/C2105deg=cm), reaches 20 T.
To understand this route for magnetization reversal via
such a strongly nonequilibrium state we solved the
Landau-Lifshitz-Bloch (LLB) equation. This macrospinapproach encapsulates very well the response of a set of
coupled atomic spins subjected to rapidly varying tempera-
ture changes, including the reduction of the magnitude ofM[20,21]. The temperature dependence of the anisotropy
constant K
uis introduced in the LLB equation via the
temperature dependence of the transverse susceptibility[22]. The temperature-dependent parameters for the LLB
equation, i.e., the longitudinal and transverse susceptibili-
ties and the temperature variation of the magnetization, are
calculated atomistically using Langevin dynamics com-
bined with a Landau-Lifshitz-Gilbert equation for eachspin [ 22]. It is well known that, due to the small heat
capacity of electrons, optical excitation by a subpicosec-
ond laser pulse can cause heating of the electron systemwell above 1000 K, whereafter the electrons equilibrate
with the lattice to a much lower temperature on a (sub)
picosecond time scale given by the electron-phonon inter-action [ 13]. This laser-induced increase of the kinetic
energy (temperature) of the electrons is simulated using a
two-temperature model [ 23], the parameters for which
were taken to be typical for a metal [ 24] (electron heat
capacity C
e¼1:8/C2106J=m3Kat room temperature and
electron-phonon coupling Gel-ph¼1:7/C21018J=Ks). The
simulations show that in the first 100 fs the electron tem-
perature Telincreases from 300 K up to T/C3
eland relaxes with
a time constant of 0.5 ps down to the vicinity of TC.
Simultaneously the spins experience a short pulse of effec-
tive magnetic field with amplitude Heff¼20 T and dura-
tion/C1teff. The possibility of magnetization reversal under
these circumstances has been analyzed numerically for a
volume of 30/C230/C230 nm3. The results of the simula-
FIG. 1 (color). (a) The magnetization evolution in
Gd24Fe66:5Co9:5after the excitation with /C27þand/C27/C0circularly
polarized pulses at room temperature. The domain is initiallymagnetized up (white domain) and down (black domain). The
last column shows the final state of the domains after a few
seconds. The circles show areas actually affected by pumppulses. (b) The averaged magnetization in the switched areas
(/C245/C22m) after /C27
þand/C27/C0laser pulses, as extracted from the
images in (a) for the initial magnetization up.PRL 103, 117201 (2009) PHYSICAL REVIEW LETTERSweek ending
11 SEPTEMBER 2009
117201-2tions are plotted in Fig. 2(a)as a phase diagram, defining
the combinations of T/C3
eland/C1tefffor which switching
occurs for the given Heff. The assumed perpendicular
anisotropy value was Ku¼6:05/C2105J=m3at 300 K.
As can be seen from the diagram, a field pulse as short as
/C1teff¼250 fs can reverse the magnetization. For better
insight into the reversal process we simulated the latter for/C1t
eff¼250 fs andT/C3
el¼1130 K . The result is plotted in
Fig.2(b), showing that, already after 250 fs, the effective
fields of two different polarities bring the medium into twodifferent states, while the magnetization is nearlyquenched within less than 0.5 ps. This is followed by
relaxation either to the initial state or to the state with
reversed magnetization, achieved already within 10 ps.The considered pulse duration /C1t
effof 250 fs is only
2.5 times larger than the FWHM of the optical pulse inour experiments [ 25] and well within the estimated lifetime
of a medium excitation responsible for H
eff. Importantly, in
simulations /C1teffwas found to be sensitive to the parame-
ters of the two-temperature model. In particular, an in-crease of G
el-phleads to a reduction of the minimum field
pulse duration. This shows that the suggested mechanism
may, in principle, explain the experimentally observedlaser-induced magnetization reversal. This magnetizationreversal does not involve precession; instead, it occurs via alinear reversal mechanism, where the magnetization first
vanishes and then reappears in a direction of H
eff, avoiding
any transverse magnetization components, just as seen inFig.1(a). Exactly as in the experiments, the initial 250 fs
effective magnetic field pulse drives the reversal process,
that takes 1–2 orders of magnitude longer.
The state of magnetization after the pulse is critically
dependent on the peak temperature T
/C3
eland the pulse du-
ration. For ultrafast linear reversal by a 250 fs field pulse itis necessary that, within this time, Telreaches the vicinity
ofTC. If, however, this temperature is too high and persists
above TCfor too long, the reversed magnetization is de-
stroyed and the effect of the helicity is lost. This leads to a
phase diagram [Fig. 2(a)], showing that the magnetization
reversal may occur in a certain range of T/C3
el. Such a
theoretically predicted reversal window of electron tem-
perature can be easily verified in the experiment when one
changes the intensity of the laser pulse. Figure 2(c)shows
the switchability, i.e., the difference between the final
states of magnetization achieved in the experiment with
/C27þ- and /C27/C0-polarized pulses, as a function of T/C3
el, calcu-
lated from the laser pulse intensity. It is seen that, indeed,
switching occurs within a fairly narrow laser intensityrange [ 26]. For intensities below this window no laser-
induced magnetization reversal occurs, while if the inten-
sity exceeds a certain level both helicities result in magne-
tization reversal, since the laser pulse destroys the
magnetic order completely, which is then reconstructed
by stray fields [ 27,28]. Such a good agreement between
experiment and theory supports the validity of the pro-
posed reversal mechanism.
Despite this qualitative agreement between simulations
and experiments, the experimentally observed reversal
time is several times larger than the calculated 10 ps. The
latter, however, is calculated for a 30 nm domain, whereas
in our experiments the magnetization in a 5/C22mspot is
manipulated. This size is defined by (i) the minimum size
of the stable domain in the material and (ii) by the area
within the laser spot, where the intensity favors the
helicity-dependent reversal. Inhomogeneities in the sample
and the intensity profile will lead to variations of T
/C3
elover
the laser spot. If due to these factors every 30 nm element
of the 5/C22mspot is reversed with a probability between
50% and 100%, the actual time of magnetization reversal
of this large spot will depend on its size and the speed of
domain walls. Their mobility increases dramatically in
GdFeCo alloys in the vicinity of their angular momenum
compensation point ( Tcomp); i.e., the temperature where the
angular momenta of the two sublattices cancel each other
[29–31]. Therefore, one should expect a dramatic accel-
eration of magnetization reversal near Tcomp. Note that this
would also perfectly explain the difference between the
times required for the formation of the switched domain
and the relaxation to the initial state [Fig. 1(b)]. Indeed, in
the former case the domain wall motion is additionally
accelerated by the demagnetizing field, while in the latter
case this field slows the motion down.
This hypothesis was verified experimentally by inves-
tigating the reversal process as a function of temperature
in three alloys Gd22Fe68:2Co9:8,Gd24Fe66:5Co9:5, and
Gd26Fe64:7Co9:3that are characterized by different com-
pensation temperatures. The observed write-read time /C28w-r
is plotted in Fig. 3as a function of the difference between
the sample temperature and the compensation point T/C0
Tcomp. The write-read time is the fastest and weakly de-ExperimentTheory Theory
FIG. 2 (color). (a) Phase diagram showing the magnetic state
of the ð30 nm Þ3volume achieved within 10 ps after the action of
the optomagnetic pulse with parameters Heff¼20 T ,/C1teff, and
T/C3
el. (b) The averaged zcomponent of the magnetization versus
delay time as calculated for 250 fs magnetic field pulses Heff¼
/C620 T andT/C3
el¼1130 K . (c) Switchability versus the pump
intensity for Gd22Fe68:2Co9:8at room temperature. We calculated
the peak electron temperature T/C3
elusing Ce. Note that in this
range of intensities the amplitude of the effective light-induced
magnetic field varies within 19.2–20.8 T.PRL 103, 117201 (2009) PHYSICAL REVIEW LETTERSweek ending
11 SEPTEMBER 2009
117201-3pends on temperature below Tcomp. This agrees with the
hypothesis that the relaxation time to the metastable state is
defined by the domain wall speed averaged over the photo-excited area. If the laser pulse brings the central part of theexcited area from initial temperature T<T
comp to the
vicinity of TC, somewhere within this area the material is
atTcomp, where the domain wall mobility is the largest.
Then, it is the mobility at Tcomp which dominates the
averaged domain wall speed in the photoexcited area
and, thus, determines the write-read time. Above Tcomp,
all-optical magnetization reversal can still be realized, but
the write-read time increases exponentially with increasingtemperature. For example, while /C28
w-rforGd22Fe68:2Co9:8
(Tcomp¼100 K ) at room temperature is found to be ex-
tremely slow (16 ns), a huge decrease of /C28w-rof 2 orders of
magnitude is observed as T/C0Tcompdecreases. Finally, at
10 K we succeeded to achieve all-optical magnetization
reversal within just 30 ps, which is the fastest write-readevent demonstrated for magnetic recording so far.
In conclusion, by time-resolved single-shot microscopy,
we found a novel and ultrafast path for magnetizationreversal triggered by a subpicosecond circularly polarizedlaser pulse. The reversal does not involve precession, butinstead has a linear character, proceeding via a strongly
nonequilibrium state. This all-optical reversal occurs only
in a narrow range of pulse energies. Using two singlesubpicosecond laser pulses we demonstrated the feasibilityof both all-optical recording and reading on an ultrashorttime scale. The magnetic information was recorded by asubpicosecond laser pulse in a 5/C22mdomain and readout
by a similarly short pulse within 30 ps, which is the fastestwrite-read event demonstrated for magnetic recording so
far. Simulations for 30 nm domains demonstrate the feasi-
bility of reversing magnetization within 10 ps. This timecan be even faster for media with a higher magneticanisotropy constant than the one used in our calculations.We thank A. J. Toonen and A. F. van Etteger for techni-
cal support and Dr. I. Radu for his help with sample char-
acterization and stimulating discussions. This research hasreceived funding from NWO, FOM, NanoNed and EC FP7
[Grants No. NMP3-SL-2008-214469 (UltraMagnetron)
and No. 214810 (FANTOMAS)].
*K.Vahaplar@science.ru.nl
[1] C. H. Back et al. , Science 285, 864 (1999).
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[3] Th. Gerrits et al. , Nature (London) 418, 509 (2002).
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(2002).
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[8] J. Sto ¨hr and H. C. Siegmann, Magnetism: From Funda-
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2006).
[9] H. W. Schumacher et al. , IEEE Trans. Magn. 38, 2480
(2002).
[10] J. C. Slonczewski, J. Magn. Magn. Mater. 159, L1 (1996).
[11] A. Kashuba, Phys. Rev. Lett. 96, 047601 (2006).
[12] C. Stamm et al. , Nature Mater. 6, 740 (2007).
[13] E. Beaurepaire et al. , Phys. Rev. Lett. 76, 4250 (1996).
[14] C. D. Stanciu et al. , Phys. Rev. Lett. 99, 047601 (2007).
[15] A. V. Kimel et al. , Nature (London) 435, 655 (2005).
[16] The angles of incidence for the pump and probe beams
were 20/C14and 0/C14, respectively.
[17] Note that the heat load brought to the sample by the laser
pulse is several orders of magnitude smaller than the oneduring current-induced magnetization reversal used in realdevices. Moreover, the heat diffusion can be accelerated
provided a proper nanostructure design.
[18] J. Hohlfeld et al. , Phys. Rev. B 65, 012413 (2001).
[19] D. J. Hilton et al. , Opt. Lett. 29, 1805 (2004).
[20] D. A. Garanin, Phys. Rev. B 55, 3050 (1997).
[21] U. Atxitia et al. , Appl. Phys. Lett. 91, 232507 (2007).
[22] N. Kazantseva et al. , Phys. Rev. B 77, 184428 (2008).
[23] N. Kazantseva et al. , Europhys. Lett. 81, 27004 (2008).
[24] G. Zhang, W. Hu ¨bner, E. Beaurepaire, and J.-Y. Bigot,
Spin Dynamics in Confined Magnetic Structures I , Topics
in Applied Physics Vol. 83 (Springer, New York, 2002).
[25] The switching was observed even for laser pulses with a
FWHM of /C243p s, which corresponds to a larger /C1t
eff.
[26] For T<T comp the intensity required for switching was
increasing with temperature decrease. For example, forsample Gd
24Fe66:5Co9:5the decrease of Tby 300 K caused
an increase of the required intensity by /C248%.
[27] T. Ogasawara et al. , Appl. Phys. Lett. 94, 162507 (2009).
[28] The slower reversal in heat-assisted recording actually
corresponds to Telabove our reversal window, when the
whole system is brought above TCand the dynamics is
determined by cooling in an external magnetic field [ 18].
[29] T. Miyama et al. , IEEE Trans. Magn. 14, 728 (1978).
[30] R. S. Weng and M. H. A. Kryder, IEEE Trans. Magn. 29,
2177 (1993).
[31] V. Randoshkin et al. , Phys. Solid State 45, 513 (2003).FIG. 3 (color). The write-read time /C28w-rversus the relative
temperature T/C0Tcomp forGd22Fe68:2Co9:8(Tcomp¼100 K ),
Gd24Fe66:5Co9:5(Tcomp¼280 K ), and Gd26Fe64:7Co9:3(Tcomp¼
390 K ). We achieved magnetization reversal within 30 ps for
Gd22Fe68:2Co9:8at10 K . The dashed line is guide to the eye.PRL 103, 117201 (2009) PHYSICAL REVIEW LETTERSweek ending
11 SEPTEMBER 2009
117201-4 |
PhysRevB.83.104422.pdf | PHYSICAL REVIEW B 83, 104422 (2011)
Current-induced dynamics of composite free layer with antiferromagnetic
interlayer exchange coupling
P. Bal ´aˇz1and J. Barna ´s1,2
1Department of Physics, Adam Mickiewicz University, Umultowska 85, PL-61-614 Pozna ´n, Poland
2Institute of Molecular Physics, Polish Academy of Sciences Smoluchowskiego 17, PL-60-179 Pozna ´n, Poland
(Received 25 November 2010; published 29 March 2011)
Current-induced dynamics in spin valves including a composite free layer with antiferromagnetic interlayer
exchange coupling is studied theoretically within the diffusive transport regime. We show that the current-induced dynamics of a synthetic antiferromagnet is significantly different from the dynamics of a syntheticferrimagnet. From macrospin simulations we obtain conditions for switching the composite free layer, as well asfor the appearance of various self-sustained dynamical modes. Numerical simulations are compared with simpleanalytical models of critical current based on a linearized Landau-Lifshitz-Gilbert equation.
DOI: 10.1103/PhysRevB.83.104422 PACS number(s): 67 .30.hj, 75.60.Jk, 75.70.Cn
I. INTRODUCTION
After the effect of spin transfer torque (STT) in thin
magnetic films had been predicted1,2and then experimentally
proven,3,4it was generally believed that current-controlled spin
valve devices would soon replace the memory cells operatedby an external magnetic field. Such a technological progress,if realized, would certainly offer higher data storage densityand faster manipulation with the information stored on ahard drive memory. However, soon it became clear that someimportant issues must be resolved before devices based onspin torque could be used in practice. The most important isthe reduction of current density needed for magnetic excitation(switching) in thin films, as well as enhancement of switchingefficiency and thermal stability. Some progress has been madeby using more complex spin valve structures and/or varioussubtle switching schemes based on optimized current and fieldpulses.
5–8
A significant enhancement of thermal stability can be
achieved by replacing a simple free layer (single homogeneouslayer) with a system of two magnetic films separated by a thinnonmagnetic spacer, known as a composite free layer (CFL).The spacer layer is usually thin so there is a strong Ruderman-Kittel-Kasuya-Yoshida (RKKY) exchange coupling betweenmagnetic layers.
9,10In practice, antiferromagnetic configura-
tion is preferred as it reduces the overall magnetic moment
of the CFL structure and makes the system less vulnerable
to external magnetic fields and thermal agitation. When theantiferromagnetically coupled magnetic layers are identical,we call the structure synthetic antiferromagnet (SyAF). If theyare different, then the CFL has an uncompensated magneticmoment, and such a system will be referred to as a syntheticferrimagnet (SyF).
Current- and/or field-induced dynamics of CFLs is
currently a subject of both experimental and theoreticalinvestigations.
11–14A switching scheme of SyAF by magnetic-
field pulses has been proposed in Ref. 11, and then the possi-
bility of current-induced switching of SyAF was demonstratedexperimentally.
12In turn, the possibility of critical current
reduction has been shown for a CFL with ferromagneticallycoupled magnetic layers.
15However, the reduction of critical
current in the case of antiferromagnetically coupled CFLsstill remains an open problem. In a recent numerical studyon switching a SyAF free layer
16it has been shown that the
corresponding critical current in most cases is higher than thecurrent required for switching of a simple free layer, and onlyin a narrow range of relevant parameters (exchange coupling,layer thickness, etc.) the critical current is reduced. Hence,proper understanding of current-induced dynamics of CFLsis highly required. We also note that CFL can be used as apolarizer, too. Indeed, it has been shown recently
17that SyAF
used as a reference layer (with the magnetic moment fixed to anadjacent antiferromangentic layer due to exchange anisotropy)might be excited due to dynamical coupling
18with a simple
sensing layer.19,20
The main objective of this paper is to study current-
induced dynamics of a CFL with antiferomagnetic RKKYcoupling in metallic spin valve pillars. We consider a systemAF/F
0/N1/F1/N2/F2, shown in Fig. 1, where AF is an antifer-
romagnetic layer (used to bias magnetization of the referencemagnetic layer F
0), F1and F 2are two magnetic layers, while N 1
and N 2are nonmagnetic spacers. The part F 1/N2/F2constitutes
the CFL structure with antiferromagnetic interlayer exchangecoupling. We examine current-induced dynamics of both SyAFand SyF free layers. These two structures differ only in thethickness of the F
1layer, while RKKY coupling and other
pillar parameters remain the same.
We assume that spin-dependent electron transport is diffu-
sive in nature, and employ the model described in Refs. 21
and 22. An important advantage of this model is the fact
that it enables calculating spin current components and spin
accumulation consistently in all magnetic and nonmagnetic
layers, as well as current-induced torques exerted on allmagnetic components. The torques acting at the internalinterfaces of CFL introduce additional dynamical couplingbetween the corresponding magnetic layers. Consequently,the magnetic dynamics of CFL has been modeled by two
coupled macrospins and described in terms of a Landau-
Lifshitz-Gilbert (LLG) equation. In addition, we derive someanalytical expressions for critical currents from the stabilityconditions of a linearized LLG equation in the static points,
23,24
and discuss results in the context of numerical simulations.
The paper is organized as follows. In Sec. IIwe describe
the assumed models for spin dynamics and STT calculations.In Sec. IIIwe analyze STT acting on CFL and present results
104422-1 1098-0121/2011/83(10)/104422(10) ©2011 American Physical SocietyP. BAL ´AˇZ AND J. BARNA ´S PHYSICAL REVIEW B 83, 104422 (2011)
AF
FIG. 1. (Color online) Scheme of the spin valve pillar structure
with a composite free layer.
from numerical simulations on current-induced switching and
magnetic dynamics. Some additional information on STTcalculation can be found in the Appendix. Critical currentsare derived and discussed in Sec. IV. Finally, a summary and
general conclusions are given in Sec. V.
II. MAGNETIZATION DYNAMICS
In the macrospin approximation, the magnetization dynam-
ics of the CFL is described by two coupled LLG equations,
dˆSi
dt+αˆSi×dˆSi
dt=/Gamma1i,
(1)
/Gamma1i=− |γg|μ0ˆSi×Heffi+|γg|
Msdiτi,
fori=1,2, where ˆSistands for a unit vector along the net spin
moment of the ith layer, whereas Heffiandτiare the effective
field and current-induced torque, respectively, both acting on
ˆSi. The damping parameter αand the saturation magnetization
Msare assumed to be the same for both magnetic components
of the CFL. Furthermore, γgis the gyromagnetic ratio, μ0is
the vacuum permeability, and distands for the thickness of the
Filayer.
The effective magnetic field for the F ilayer is
Heffi=−Happˆez−Hani(ˆSi·ˆez)ˆez+Hdemi(ˆSi)
+Hinti(ˆS0,ˆSj)+HRKKY iˆSj, (2)
where i,j=1,2 and i/negationslash=j. In the latter equation, Happis
the external magnetic field applied along the easy axis in thelayers’ plane (and oriented opposite to the axis z),H
aniis the
uniaxial anisotropy field (the same for both magnetic layers),andH
demi=(Ni·ˆSi)Msis the self-demagnetization field of
the F ilayer, with Nibeing the corresponding demagnetization
tensor. Similarly, Hinti=(N0i·ˆS0)Ms0+(Nji·ˆSj)Ms
describes the magnetostatic influence of the layers F 0and
Fjon the layer F i, respectively. Here, Ms0is the saturation
magnetization of the layer F 0, which might be generally
different from Ms. Components of the tensors Ni,N0i,
andNijused in our simulations have been determined by
the numerical method introduced by Newell et al.25This
method was originally developed for magnetic systemswith nonuniform magnetization. To implement it intoa macrospin model we considered discretized magneticlayers with uniform magnetizations, we calculated tensorsin each cell of the layer, and then we averaged themalong the whole layer. Since these tensors are diagonal,the demagnetization and magnetostatic fields can be
expressed as H
demi=(Hd
ixSix,Hd
iySiy,Hd
izSiz), and Hinti=
(H0i
xS0x,H0i
yS0y,H0i
zS0z)+(Hji
xSjx,Hji
ySjy,Hji
zSjz), with
Six,Siy, and Sizdenoting the components of the vector
ˆSi(i=0,1,2) in the coordinate system shown in Fig. 1.
Finally, HRKKY istands for the RKKY exchange field acting
onˆSi, which is related to the RKKY coupling constant as
HRKKY i=−JRKKY/(μ0Msdi).19
To include thermal effects we add to the effective field
(2) a stochastic thermal field Hthi=(Hthix,Hthiy,Hth iz). For
both spins its components obey the rules for Gaussianrandom processes /angbracketleftH
thiζ(t)/angbracketright=0 and /angbracketleftHthiζ(t)Hthjξ(t/prime)/angbracketright=
2Dδijδζξδ(t−t/prime), where i,j=1,2 and ζ,ξ=x,y,z . Here,
Dis the noise amplitude, which is related to the effective
temperature, Teff,a s
D=αkBTeff
γgμ2
0MsVi, (3)
where kBis the Boltzmann constant, and Viis the volume of
Filayer.
In general, the current-induced torques acting on ˆS1and
ˆS2can be expressed as a sum of their in-plane and out-
of-plane components τ1=τ1/bardbl+τ1⊥andτ2=τ2/bardbl+τ2⊥,
respectively. In a CFL structure, the layer F 1is influenced
by STT induced by the polarizer F 0, as well as by STT due to
the layer F 2. In turn, the layer F 2is influenced by the torques
from the layer F 1. Hence we can write
τ1/bardbl=IˆS1×/bracketleftbigˆS1×/parenleftbig
a(0)
1ˆS0+a(2)
1ˆS2/parenrightbig/bracketrightbig
, (4a)
τ1⊥=IˆS1×/parenleftbig
b(0)
1ˆS0+b(2)
1ˆS2/parenrightbig
, (4b)
τ2/bardbl=Ia(1)
2ˆS2×(ˆS2׈S1), (4c)
τ2⊥=Ib(1)
2ˆS2׈S1, (4d)
where Iis the charge current density, which is positive when
electrons flow from the layer F 2toward F 0(see Fig. 1), while
the parameters a(j)
iandb(j)
i(i,j=1,2) are independent of
current I, but generally depend on magnetic configuration.
We write the current density in the spin space as j=j01+
j·σ, where j0is the particle current density ( I=ej0),jis the
spin current density (in the units of ¯ h/2),σis the vector of
Pauli matrices, and 1is a 2×2 unit matrix. In the frame of the
diffusive transport model,21the parameters a(j)
iandb(j)
iare
given by the formulas
a(0)
1=−¯h
2j/prime
1y|N1/F1
Isinθ01,b(0)
1=¯h
2j/prime
1x|N1/F1
Isinθ01,
a(2)
1=−¯h
2j/prime/prime
2y|F1/N2
Isinθ12,b(2)
1=¯h
2j/prime/prime
2x|F1/N2
Isinθ12, (5)
a(1)
2=−¯h
2j/prime/prime/prime
2y|N2/F2
Isinθ12,b(1)
2=¯h
2j/prime/prime/prime
2x|N2/F2
Isinθ12,
where the angles θ01andθ12are given by cos θ01=ˆS0·ˆS1
and cos θ12=ˆS1·ˆS2. Here, j/prime
1yandj/prime
1xare transversal (to
ˆS1) components of spin current in the layer N 1(taken at
the N 1/F1interface) written in the local coordinate system
ofˆS1. Thus, j/prime
1yis parallel to the vector ˆS1×(ˆS1׈S0) (lying
in the plane defined by ˆS0and ˆS1) and j/prime
1xis aligned with
ˆS1׈S0(perpendicular to the plane defined by ˆS0and ˆS1).
104422-2CURRENT-INDUCED DYNAMICS OF COMPOSITE FREE ... PHYSICAL REVIEW B 83, 104422 (2011)
Note, that the zcomponent of spin current is aligned along
ˆS1and does not contribute to STT.26Similarly, we define the
torque amplitudes acting inside the CFL. Here, j/prime/prime
2yandj/prime/prime
2x
are the components of spin current in layer N 2(taken at the
N2/F1interface), transversal to ˆS1and lying respectively in the
plane and perpendicularly to the plane defined by ˆS1and ˆS2.
Analogically, j/prime/prime/prime
2yandj/prime/prime/prime
2xare spin current components in N 2
transversal to ˆS2. The relevant spin current transformations are
given in the Appendix. Note that the spin current components
depend linearly on I, so the parameters a(j)
iandb(j)
iare
independent of the current density I.
III. NUMERICAL SIMULATIONS
In this section we present results on our numerical
simulations of current-induced dynamics for two metal-lic pillar structures including CFL with antiferromagneticinterlayer exchange coupling. As described in the Intro-duction, the considered pillars have the general structureAF/F
0/N1/F1/N2/F2(see Fig. 1). More specifically, we consider
spin valves Cu-IrMn(10)/Py(8)/Cu(8)/Co( d1)/Ru(1)/Co( d2)-
Cu, where the numbers in parentheses stand for the layer thick-nesses in nanometers. The layer Py(8) is the Permalloy polariz-ing layer with its magnetization fixed due to exchange couplingto IrMn. In turn, Co( d
1)/Ru(1)/Co( d2)i st h eC F L( F 1/N2/F2
structure) with antiferromagnetic RKKY exchange coupling
via the thin ruthenium layer. The coupling constant betweenCo layers has been assumed as J
RKKY/similarequal−0.6m J/m2, which
is close to experimentally observed values.19,20Here, we shall
analyze two different geometries of CFL. The first one is aSyAF structure with d
1=d2=2 nm, while the second one is
a synthetic ferrimagnet (SyF) with d1=2d2=4n m .
Simulations have been based on numerical integration
of the two coupled LLG equations ( 1) with simultaneous
calculations of STT [see Eq. ( 4)]. We have assumed typical
values of the relevant parameters, i.e., the damping parameterhas been set to α=0.01, while the uniaxial anisotropy field
H
ani=45 kA m−1in both magnetic layers of the CFL. In
turn, saturation magnetization of cobalt has been assumed asM
s(Co)=1.42×106Am−1, and for Permalloy, Ms(Py)=
6.92×105Am−1. The demagnetization field and magneto-
static interaction of magnetic layers have been calculated forlayers of elliptical cross section, with the major and minor axesequal to 130 and 60 nm, respectively.
For both structures under consideration we have analyzed
the current-induced dynamics as a function of current densityand external magnetic field. The results have been presentedin the form of diagrams displaying time-averaged values ofthe pillar resistance. Numerical integration of Eq. ( 1) has been
performed using a corrector–predictor Heun scheme, and theresults have been verified for integration steps in the range from10
−4ns up to 10−6ns. The STT components acting on CFL
spins have been calculated at each integration step from thespin currents, which have been numerically calculated fromthe appropriate boundary conditions.
21Similarly, resistance
of the studied pillars has been calculated from spin accumula-tion in the frame of the model used also for the STT description(for details see also Ref. 27).-0.20-0.15-0.10-0.050.000.050.10
0 0.5 1 1.5 2Spin-transfer torque N1/F1 interface
-0.0010.0000.001
0 0.5 1 1.5 2
θ / πF1/N2 interface
-0.002-0.0010.0000.001
0 0.5 1 1.5 2
θ / πN2/F2 interface
τx
τy
τz
FIG. 2. (Color online) Angular dependence of the Cartesian
components of STT, in units of ¯ hI/|e|, acting at N/F interfaces,
when magnetization of the SyAF structure is rotated rigidly with
both ˆS1andˆS2remaining in the corresponding layer planes. Here, θ
is an angle between ˆS1andˆez.ˆS2is tilted away from the antiparallel
configuration with ˆS1by an angle of 1◦.
A. Spin transfer torque
Let us analyze first the angular dependence of STT
components in the structures under consideration. Althoughthe thicknesses of magnetic layers in the studied SyAF andSyF structures are different, the angular dependence of STTcomponents as well as their amplitudes are very similar. Thus,the analysis of STT in SyAF applies also qualitatively to thestudied SyF free layer.
First, we analyze STT components in the case when SyAF
is rotated as a rigid structure, i.e., the relative configurationofˆS
1and ˆS2is maintained. To have a nonzero torque
between F 1and F 2layers, ˆS2has been tilted away from the
antiparallel configuration by an angle of 1◦. Figure 2shows
all three Cartesian components (see Fig. 1for a definition of
the coordinate system) of STT acting at N/F interfaces asa function of the angle θbetween ˆe
zand ˆS1. While the y
andzcomponents are in the plane of the layers (the spins
of CFL are rotated in the layer plane), the component xis
normal to the layer plane. However, τxremains negligible at
all interfaces of the CFL. The STT acting at N 1/F1reveals a
standard (nonwavy28) angular dependence, and vanishes when
ˆS1is collinear with ˆS0. Its amplitude is comparable to STT in
standard spin valves with a simple free layer. The STT at F 1/N2
and N 2/F2interfaces also depends on the angle θ. However,
they are approximately two orders of magnitude smaller, whichis a consequence of a small angle (1
◦) assumed between ˆS1
andˆS2.
As will be shown in the following, CFL is usually not
switched as a rigid structure, but generally forms a configura-tion which deviates from the antiparallel one. Figure 3shows
how the STT components at the F
1/N2and N 2/F2interfaces
vary when ˆS2is rotated from ˆezby an angle θ/prime, while ˆS1
remains fixed and is parallel to ˆS0=ˆez. In such a case, the
torque acting at N 1/F1interface remains zero, as ˆS1stays
collinear to ˆS0. As before, the out-of-plane components are
also negligible in comparison to the in-plane ones. The in-plane
104422-3P. BAL ´AˇZ AND J. BARNA ´S PHYSICAL REVIEW B 83, 104422 (2011)
-0.04-0.020.000.020.04
0 0.5 1 1.5 2Spin-transfer torque
θ′ / πF1/N2 interface
τx
τy
τz
-0.12-0.08-0.040.000.04
0 0.5 1 1.5 2
θ′ / πN2/F2 interface
FIG. 3. (Color online) Angular dependence of the Cartesian STT
components in the units of ¯ hI/|e|a c t i n go nF 1/N2and N 2/F1interfaces
when ˆS0=ˆS1=ˆezandˆS2is rotated from ˆezin the layer’s plane by
an angle θ/prime.
components of STT reveal a standard angular dependence at
both interfaces. The amplitude of STT at the internal interfacesof CFL is comparable to that acting at the N
1/F1interface in
the case of noncollinear configuration of ˆS0andˆS1, when ˆS2
is fixed in the direction antiparallel to ˆS0.
When ˆS1is noncollinear to ˆS0, the spin accumulation
in the N 1layer increases and consequently the amplitude
of STT at F 1/N2and N 2/F2decreases. In turn, when ˆS1is
antiparallel to ˆS0, the STT inside the CFL structure is reduced
by more than a factor of 2. Nevertheless, the STT actingat the internal interfaces of the studied CFL layers mighthave a significant effect on their current-induced dynamicsand switching process, provided the magnetic configurationof CFL might deviate remarkably from its initial antiparallelconfiguration.
B. Synthetic antiferromagnet
First, we examine the dynamics of the SyAF free layer.
From symmetry we have HRKKY 1 =HRKKY 2 ≡HRKKY , and
we have set HRKKY=2 kOe, which corresponds to JRKKY∼
−0.6m J/m2. We have performed a number of independent
numerical simulations modeling SyAF dynamics induced byconstant current and a constant in-plane external magneticfield. The latter is assumed to be smaller than the critical fieldfor transition to the spin-flop phase of SyAF. Accordingly, eachsimulation started from an initial state close to ˆS
1=− ˆS2=
−ˆez. To have a nonzero initial STT for ˆS1, both spins of the
SyAF have been tilted by 1◦in the layer plane so that they
remained collinear.
From the results of numerical simulations we have con-
structed a map of time-averaged resistance, shown in Fig. 4(a).
The resistance has been averaged in a time interval of 30 nsfollowing an initial 50 ns equilibration time of the dynamics.The diagram shows only that part of the resistance, whichdepends on magnetic configuration, and hence varies withCFL dynamics.
27The constant part of resistance, due to bulk
and interfacial resistances of the studied structure, has beencalculated to be as large as R
sp=19.74 f/Omega1m2.
For the assumed initial configuration, the magnetic dynam-
ics has been observed only for a negative current density.When the current is small, no dynamics is observed sincethe spin motion is damped into the closest collinear state(ˆS
1=− ˆS2=− ˆez,m a r k e da s ↓↑) of high resistance. After
exceeding a certain threshold value of the current density, 0 1 2 3 4 5
-I / (108 Acm-2)-400-200 0 200 400Happ [Oe]
0.420.440.460.480.500.520.540.56
R [fΩm2](a)➞
➞
➞➞➞➞
-1-0.5 0 0.5 1
S1z
S2zHapp < H0
(b)
0 0.5 1 1.5 2
m
(c)
0.440.480.520.56
234567R [fΩm2]
time [ns](d)
(e) (i)
-0.8-0.400.40.8-1-0.5 00.5 1-1-0.500.51
Sz
Sx SySz
Happ > H0
(f)
(g)
234567
time [ns](h)
-0.2
0
0.2-1-0.5 00.5 1-1-0.500.51
Sz
Sx
SySz
FIG. 4. (Color online) (a) Averaged resistance of Cu-
IrMn(10)/Py(8)/Cu(8)/Co(2)/Cu(1)/Co(2)-Cu spin valve pillar with aSAF free layer as a function of current density and applied magnetic
field. Examples of switching processes at I=−1.0×10
8Ac m−2
andHapp=−400 Oe (b)–(e) and Happ=400 Oe (f)–(i). (b) and (f)
show the dynamics of zcomponents of both spin moments, (c) and
(g) present the overall magnetization of the free layer, (d) and (h)
show the corresponding variation of pillar resistance, and (e) and (i)show the spin trajectories of ˆS
1solid (red) line and ˆS2dashed (black)
line in the time interval from 0 to 10 ns, where switching takes place.
there is a drop in the averaged resistance, which indicates the
current-induced dynamics of the SyAF free layer. Figures 4(b)
and4(f)show that this drop is associated with switching of the
whole SyAF structure into an opposite state ( ˆS1=− ˆS2=ˆez,
marked as ↑↓).
From Fig. 4(a) it follows that the threshold current for
the onset of the dynamics markedly depends on the appliedfield and reaches a maximum at a certain value of H
app,
Happ=H0. Furthermore, it appears that the mechanisms of
the switching process for Happ<H 0andHapp>H 0are
qualitatively different. To distinguish these two mechanisms,we present in Figs. 4(b)–4(i) the basic characteristics of
switching, calculated for I=−1.0×10
8Ac m−2and for
fieldsHapp=−400 Oe, which is below H0[Figs. 4(b)–4(e)],
andHapp=400 Oe, which lies above H0[Figs. 4(f)–4(i)].
104422-4CURRENT-INDUCED DYNAMICS OF COMPOSITE FREE ... PHYSICAL REVIEW B 83, 104422 (2011)
Figures 4(b) and 4(f) present the time evolution of the z
components of both spins. To better understand the SyAFdynamics, in Figs. 4(c) and4(g) we plotted the amplitude
of overall SyAF magnetization, defined as m=|ˆS
1+ˆS2|.
This parameter vanishes for antiparallel alignment of bothspins of CFL, but becomes nonzero when the configurationdeviates from the antiparallel one. Magnetization of SyAF isalso a measure of the CFL coupling to external magnetic field.Furthermore, Figs. 4(d) and4(h) show the corresponding time
variation of the resistance, R, which might be directly extracted
from experimental measurements as well. In addition, inFigs. 4(e) and 4(i) we show the trajectories of ˆS
1and ˆS2
in real space taken from the time interval from t=0t o
10 ns. In addition, from Fig. 4(a) it has been found that
the point where the threshold current reaches its maximumis located at H
0/similarequalH02
z, which indicates its relation to the
magnetostatic interaction of F 2and fixed polarizer. This also
has been confirmed by analogical simulations disregardingthe magnetostatic coupling between magnetic layers, whichresulted in a similar diagram, but with H
0=0 (not shown).
This fact significantly facilitates understanding the mechanismof SyAF switching.
The initial configuration assumed above was −ˆS
1=ˆS2/similarequal
ˆS0with ˆS0=ˆez(↓↑). When the magnitude of the current
density is large enough and I<0, the orientation of ˆS1
becomes unstable and ˆS1starts to precess with a small angle
around −ˆez. Initial precession of ˆS1induces precession of
ˆS2—mainly via the RKKY coupling. Generally, the response
to the exchange field is slower than current-induced dynamics.Therefore, a difference in the precession phase of ˆS
2and
ˆS1appears, and the configuration of SyAF deviates from the
initial antiparallel one. This, in turn, enhances the STT actingon F
2, which tends to switch ˆS2. Its amplitude, however,
is small in comparison to the strong RKKY coupling. Afurther scenario of the dynamics depends then on the externalmagnetic field. When H
app<H 0[Figs. 4(b)–4(e)] the Zeeman
energy of ˆS2has a maximum in the initial state and the
external magnetic field tends to switch ˆS2to the opposite
orientation. Competition between the torques acting on SyAFresults in out-of-plane precessions of both spins. After severalprecessions ˆS
1reaches the opposite static state, which is
stable due to STT. In turn, ˆS2is only slightly affected by
STT, and its dynamics is damped in the external magneticand RKKY exchange fields. In contrast, when H
app>H 0
[Figs. 4(f)–4(i)], the Zeeman energy of F 2has a local minimum
in the initial state, which stabilizes ˆS2. Therefore, in a certain
range of current density, SyAF does not switch but remains inself-sustained coherent in-plane precessions [boundary areabetween ↓↑and↑↓(red) in the upper part of Fig. 4(a)].
For a sufficient current density, the SyAF structure becomesdestabilized and the precessional angle increases until the spinspass the ( x,y) plane. Consequently, the precessional angle
decreases and spins of the SyAF are stabilized in the oppositestate ( ↑↓). Moreover, as shown in Fig. 4(c), the switching
process for H
app<H 0is connected with a high distortion of
the SyAF configuration, where min a certain point reaches
its maximum value (corresponding to a parallel orientationof both spins). Contrary, the mremains small for H
app>H 0
[Fig. 4(g)], and the effective magnetic moment of the free layer
stays smaller than magnetic moment of a single layer. Thismight play an important role in applications of spin-torque
devices based on CFLs.
The two switching mechanisms described above dominate
the current-induced dynamics when the current density is closeto the dynamics threshold. For higher current densities, thenonlinearities in SyAF dynamics become more pronounced,which results in a bistable behavior of the dynamics, especiallyforH
app<H 0andI/greaterorsimilar108Ac m−2. In that region, the number
of out-of-plane precessions before SyAF switching increaseswith the current density. However, their precessional angleincreases in time and consequently ˆS
1might reach an out-of-
plane static point slightly tilted away from the ˆexdirection
while ˆS2=ˆezremains in the layers’ plane. The out-of-plane
static states (marked as ←↑) have a small resistance and appear
as dark (red) spots in the diagram shown in Fig. 4(a).
In addition, from the analysis of the dispersion of pillar re-
sistance (not shown) one finds that, except for a narrow regionclose to the dynamics threshold with persistent in-plane pre-cessions, no significant steady-state dynamics of the SyAF el-ement appears. As will be shown below, such a behavior mightbe observed when CFL becomes asymmetric (SyF free layer).
C. Synthetic ferrimagnet
Let us study now the spin valve with SyF as a free layer,
assuming d1=4 nm and d2=2 nm. Accordingly, HRKKY 2
remains at 2 kOe while HRKKY 1 is reduced to 1 kOe. As in the
case of SyAF, from the averaged time-dependent part of thepillar resistance, we have constructed a diagram presentingcurrent-induced dynamics [see Fig. 5(a)]. The static part of
resistance is now R
sp=19.80 f/Omega1m2.
The diagram has some features similar to those studied
in the previous section. However, the maximum criticalcurrent is shifted toward negative values of H
app,e v e ni f
the magnetostatic interaction between magnetic layers isneglected. This asymmetry is caused by the difference inexchange and demagnetization fields acting on layers F
1and
F2. Moreover, this difference leads to more complex dynamics
of the CFL’s spins than that in the case of SyAF.
Generally, there are several dynamic regimes to be dis-
tinguished. The first one is the region of switching fromthe↓↑configuration to the opposite one, ↑↓, which is
located at the largest values of H
appin the diagram. The
mechanism of the switching is similar to that of SyAF shownin Figs. 4(f)–4(i), where CFL changes its configuration just
via in-plane precessional states with a small value of m
(weak distortion of the antiparallel alignment of ˆS
1and ˆS2).
Furthermore, the darker area above H0indicates one of the
possible self-sustained dynamic regimes of SyF, i.e., the in-plane precessions (IPP); see Figs. 5(b)–5(e). This precessional
regime starts directly after the SyF switching, and ˆS
1and
ˆS2precess around ˆezand−ˆez, respectively. Due to different
effective fields in F 1and F 2, and energy gains due to STT,
the spins precess with different precessional angles [Fig. 5(e)]
and consequently different frequencies. Because of the stronginterlayer coupling and spin transfer between the layers, theamplitudes of their precessions are periodically modulated intime. This modulation appears also in the time dependenceof the pillar resistance. Conversely, below H
0the dynamics
is dominated by large-angle out-of-plane precessions (OPPs)
104422-5P. BAL ´AˇZ AND J. BARNA ´S PHYSICAL REVIEW B 83, 104422 (2011)
0 1 2 3 4 5
-I / (108 Acm-2)-400-200 0 200 400Happ [Oe]
0.460.480.500.520.540.560.580.60
R [fΩm2](a)➞
➞
➞➞
IPP
OPP
-1-0.5 0 0.5 1
S1z
S2zIPP
(b)
0 0.5 1 1.5 2
m
(c)
0.480.520.560.60
02468 1 0R [fΩm2]
time [ns](d)
(e) (i)
-0.4-0.200.20.4-0.8-0.400.40.8-1-0.500.51
Sz
SxSySz-1-0.500.51
OPP
(f)
00.511.52
(g)
0.440.480.520.560.60
4 8 12 16 20
time [ns](h)
SxSy-1-0.500.51
Sz
-1-0.500.51-1-0.500.51Sz
FIG. 5. (Color online) (a) Averaged resistance of Cu-
IrMn(10)/Py(8)/Cu(8)/Co(4)/Cu(1)/Co(2)-Cu spin valve pillar with a
SyF free layer, presented as a function of current density and appliedmagnetic field. Examples of current-induced dynamics for I=
−3×10
8Am−1andHapp=200 Oe (b)–(e) and Happ=−400 Oe
(f)–(i). (b) and (f) show the dynamics of zcomponents of ˆS1andˆS2,
(c) and (g) present the overall magnetization of the free layer, (d) and
(h) show the corresponding variation of pillar resistance, and (e) and
(i) show spin trajectories of ˆS1solid (red) line and ˆS2dashed (black)
line taken from a time interval as large as 30 ns after 100 ns of initial
equilibration.
of both spins, as shown in Figs. 5(f)–5(i). This dynamic state
is connected with a strong distortion of the antiparallel CFLconfiguration, i.e., large value of m, and a large variation of
the resistance. From Fig. 5(i)one can see that trajectories of
ˆS
1andˆS2are rather complicated, including both IPP and OPP
regimes with dominant OPP.
D. Power spectral density
From the analysis of current-induced dynamics we found
that self-sustained dynamics in structures with a SyF free layeris much richer than that in systems with a SyAF free layer[see Figs. 5(b)–5(i)]. Therefore, in this section we restrict
ourselves to dynamic regimes of the SyF free layer only. Morespecifically, we shall examine the power spectral density (PSD)as a function of current density and external magnetic field. 2 3 4 5
-I / (108 Acm-2) 10 20 30 40 50frequency [GHz](a)
1 2 3 4 5
-I / (108 Acm-2) 30 40 50 60
10-610-510-410-310-210-1100
PSD [pW/MHz](b)
-1-0.500.51
S1z
(c)
-1-0.500.51
2468 1 0S2z
time [ns](d)
(g)(h)0.440.480.520.56
R [fΩm2]
(e)
0.460.470.480.49
4 8 12 16 20R [fΩm2]
time [ns](f)
-0.8-0.400.40.8-1-0.500.51
-1-0.500.51
Sz
SxSySz
-1-0.6-0.20.2
-0.8-0.400.40.8-1-0.500.51
Sz
SxSySz
FIG. 6. (Color online) PSD calculated for the spin valve with a
SyF free layer at Teff=5Ka n d Happ=−400 Oe (a) and 200 Oe (b).
(c) and (d) show the steady time evolution of the spins’ zcomponents
in a time window of 10 ns after equilibration at Happ=−400 Oe and
I=−2.8×108Ac m−2. (e) and (f) show the steady time evolution
of the time-dependent part of the spin valve resistance in a timewindow of 20 ns after equilibration at H
app=−400 Oe and I=
−3.6×108Ac m−2(both ˆS1and ˆS2precess out of the layer plane)
andI=−3.8×108Ac m−2(ˆS2performs out-of-plane precessions
while ˆS1precesses in the layer’s plane), respectively. (g) and (h)
depict trajectories of ˆS1solid (red) line and ˆS2dashed (black) line
corresponding to resistance oscillations (e) and (f), respectively.
In the simulation we started from I=0 and changed
the current density in steps /Delta1I=106Ac m−2at a fixed
applied field. As before, to protect the SyF dynamics fromcollapsing into a collinear static state, we assumed smallthermal fluctuations corresponding to T
eff=5 K. At each step
we simulated the dynamics of the coupled CFL’s spins andcalculated PSD. As in Ref. 29, we assumed that the input
current is split between a load with resistance R
Land a pillar
with resistance Rsp+R(t). Hence, the voltage on the pillar has
been calculated as U(t)=IR(t)/[1+Rsp/(RLS)], where we
assumed RL=50/Omega1, andSis the cross section of the pillar
(ellipsoid with the major and minor axes equal to 130 and60 nm, respectively). Then, at a given I, we calculated the
voltage in the frequency domain, U(f), using fast Fourier
transformation over the period t
FFT=50 ns following an
equilibration time of teq=30 ns. The PSD has been defined
as PSD( f)=2U2(f)/(RL/Delta1f), where /Delta1f=1/tFFT.
Figures 6(a) and6(b) show the PSD calculated at Happ=
−400 and 200 Oe, respectively. The former case corresponds
to the part of the diagram in Fig. 5(a), which includes OPP
modes, while in the latter case we observed IPP only. Let us
104422-6CURRENT-INDUCED DYNAMICS OF COMPOSITE FREE ... PHYSICAL REVIEW B 83, 104422 (2011)
analyze first the situation in Fig. 6(a). When the current passes
through the corresponding threshold value, both spins startprecessing in the layers’ plane, similarly as shown in Fig. 5(b).
Apart from the main peak in the PSD at f/similarequal40 GHz, two
additional minor peaks close to f/similarequal20 GHz are visible. We
attribute them to the oscillations of precessional amplitudesof both spins. With an increasing amplitude of the currentdensity, the precessional angles of both spins increase andtheir precessional frequencies slightly decrease. Moreover,with increasing current the frequencies of the minor peaksbecome increasingly closer, until they finally coincide. At thispoint the PSD becomes widely distributed along the wholerange of observed frequencies, which is evidence of noisyvariation of the resistance. An example of spin dynamics in thisregion is shown in Figs. 6(c)and6(d), which have been taken
in a time window as large as 10 ns after the equilibration periodforH
app=−400 Oe and I=−2.8×108Ac m−2[within the
broad feature of PSD in Fig. 6(a)]. First, the figures show that
ˆS2starts to perform out-of-plane precessions as a result of the
competition between STT and RKKY coupling. Second, onecan note thermally activated random transitions of ˆS
1between
the OPP and IPP modes. These random transitions modify OPPprecessions of ˆS
2as well. The simultaneous dynamics of both
spins causes a chaotic variation of spin valve resistance andbroadens the PSD. The quasichaotic feature of the spin dynam-ics in this range of current densities can be seen also on the spintrajectories, which cover almost the whole sphere (not shown).
A further increase in current density leads to stabilization of
the OPP mode of ˆS
1. Hence the spin valve resistance becomes
more periodic [see Fig. 6(e)] and PSD again reveals a narrow
peak. Since both spins perform rather complicated dynamicswhen including IPP but dominated by the OPP regime [seeFig. 6(g)], we observe a blueshift in the PSD with current,
which is connected with a decrease in the precessional angles.However, at a certain value of Iwe notice an abrupt drop in the
peak’s frequency. At this current density the STT acting on theleft-hand interface of layer F
1starts to dominate the dynamics
ofˆS1and enables only small-angle IPPs along the ˆS0direction,
which modifies the trajectory of ˆS2.ˆS2still remains in the OPP
regime [see Fig. 6(h)] and hence the blueshift with current ap-
pears. The fact that the IPP of ˆS1still influences the dynamics
of the whole SyF is also shown in Fig. 6(f), which presents
the dynamic part of the spin valve resistance at I=−3.8×
108Ac m−2andHapp=−400 Oe. As a result of the IPPs of
ˆS1, the amplitude of the resistance varies periodically. In addi-
tion, a comparison of Figs. 6(e)and6(f)shows that the simul-
taneous OPPs of both spins lead to a stronger variation of theresistance than in the case when the layers are in the IPP state.
Contrary to this, at H
app=200 Oe one observes only IPP
modes of both spins similar to those shown in Fig. 5(e).T h e
in-plane precessional angle increases with current density andhence the peak frequency in PSD decreases and becomesbroader. In real systems, however, one might expect narrowerpeaks than those obtained in the macrospin simulations, asobserved in standard spin valves with a simple free layer.
30,31
IV . CRITICAL CURRENTS
First, we derive some approximate expressions for the
critical current density needed to induce the dynamics ofCFL, derived from a linearized LLG equation. In metallic
structures, the out-of-plane torque components are generallymuch smaller than the in-plane ones, and therefore willbe omitted in the analytical considerations of this section
(b
(0)
1,b(2)
1,b(1)
2→0).
The coupled LLG equations in spherical coordinates can be
then written as
d˜S
dt=1
1+α2M·˜v, (6)
where ˜S=(θ1,φ1,θ2,φ2)Tis a four-dimensional column vector
which describes spin orientation in both layers constitutingthe CFL, and ˜v=(v
1θ,v1φ,v2θ,v2φ)Tstands for the torque
components, viθ=/Gamma1i·ˆeiθandviφ=/Gamma1i·ˆeiφ, with ˆeiφ=
(ˆez׈Si)/sinθiand ˆeiθ=(ˆSi׈eiφ)/sinθidenoting unit
vectors in local spherical coordinates associated with ˆSi.I n
turn, the 4 ×4m a t r i x Mtakes the form
M=⎛
⎜⎜⎜⎝1 α 00
−α/sinθ11/sinθ1 00
001 α
00 −α/sinθ21/sinθ2⎞
⎟⎟⎟⎠.(7)
The static points of the CFL dynamics have to satisfy viθ=0
andviφ=0 for both i=1 and i=2. These conditions
are obeyed in all collinear configurations, i.e., θi=0,π.
Additionally, four trivial static points can be found in theout-of-plane configurations with θ
i=π/2 andφi=0,π.
Following Ref. 23, we linearize Eq. ( 6) by expanding ˜vinto
a series around the static points, which leads to
d˜S
dt=1
1+α2M·J·˜δv, (8)
where Jis a Jacobian matrix of ∂˜vi/∂˜Sjcomponents. The
matrix product M·Jdefines here the dynamic matrix D=
M·J. This matrix allows one to study the stability of the CFL’s
spins in their static points. If Tr {D}is negative, the static point
is stable, otherwise it is unstable. Hence, the condition for thecritical current is
32Tr{D}=0.
To obtain threshold current for the dynamics onset of
individual spins in the CFL, we assume first that one of thespins is fixed in its initial position, and investigate the stabilityof the second spin. The dynamic matrix
Dthen reduces to
a2×2 matrix. Considering the initial position of SyAF with
ˆS1=− ˆS2=− ˆez(i.e.,θ1=πandθ2=0), marked as ↓↑, and
polarizer ˆS0=ˆez, the stability condition leads to the following
critical currents I↓↑
c1andI↓↑
c2forˆS1andˆS2, respectively:
I↓↑
c1=−αμ0Msd1
a(0)
1+a(2)
1/bracketleftbig
−H1↓↑
ext+Hani−HRKKY 1 +Hd
1/bracketrightbig
,(9)
with H1↓↑
ext=Happ−H01
z−H21
z , and
I↓↑
c2=−αμ0Msd2
a(1)
2/bracketleftbig
H2↓↑
ext+Hani−HRKKY 2 +Hd
2/bracketrightbig
,(10)
104422-7P. BAL ´AˇZ AND J. BARNA ´S PHYSICAL REVIEW B 83, 104422 (2011)
withH2↓↑
ext=Happ−H02
z−H12
z. In both of the above expres-
sionsa(0)
1,a(2)
1, anda(1)
2are taken in the considered static point,
while the demagnetization field for the ith layer is given by
Hd
i=Hd
ix+Hd
iy
2−Hd
iz. (11)
Analogically, one can derive similar formulas for critical
currents in the opposite ( ↑↓) magnetic configuration of the
CFL.
Now we relax the assumption that one of the spins is
fixed, and consider both spins of the CFL as free. Then, wecalculate the trace of the whole 4 ×4 matrix, which leads to
the following expression for critical current destabilizing thewhole CFL:
I
↓↑
c CFL=−αμ0Msd1d2
d2/parenleftbig
a(0)
1+a(2)
1/parenrightbig
+d1a(1)
2/bracketleftbig
H↓↑
ext+2Hani
−HRKKY 1 −HRKKY 2 +Hd
1+Hd
2/bracketrightbig
, (12)
where H↓↑
ext=H01
z−H02
z+H21
z+H12
z. Since the spins of
CFL are antiparallel in the considered static point, I↓↑
c CFL is
independent of the external magnetic field. The above equationdescribes the critical current at which the CFL is destabilizedas a rigid structure (unaffected by external magnetic field alongthezaxis).
Numerical calculations presented below show that the
critical current is usually smaller than that given by Eq. ( 12).
Apparently, as shown by numerical simulations, there is aphase shift in the initial precessions of ˆS
1andˆS2. Such a phase
shift slightly perturbs the initial antiparallel configuration andmight reduce the critical current for the onset of the dynamics.
A similar formula also holds for the opposite configuration
(↑↓), where the critical current is given by
I↑↓
c CFL=αμ0Msd1d2
d2/parenleftbig
a(0)
1−a(2)
1/parenrightbig
−d1a(1)
2/bracketleftbig
−H↑↓
ext+2Hani
−HRKKY 1 −HRKKY 2 +Hd
1+Hd
2/bracketrightbig
, (13)
withH↑↓
ext=H01
z−H02
z−H21
z−H12
z.
Now we discuss the theoretical results on critical currents in
the context of those following from numerical simulations. Letus consider first the critical currents for individual spins of theSyAF free layer, assuming that the second spin remains stablein its initial position, Eqs. ( 9) and ( 10). The corresponding
results obtained from the formula derived above are presentedin Table I, where we have omitted a weak dependence on
H
app. For the studied structure with a SyAF free layer, I↓↑
c1is
negative while I↓↑
c2is positive. From our analysis, it follows
that the current density at which the dynamics appears in
the simulations [Fig. 4(a)] is higher than that given by I↓↑
c1.
However, we checked numerically that the critical value I↓↑
c1
agrees with the critical current obtained from simulations when
assuming ˆS1as free and fixing ˆS2along ˆez.
Following the above discussion of the CFL dynamics, one
can understand the shift of the threshold current as follows.Initially, when the current density exceeds I↓↑
c1,ˆS1becomes
destabilized. Then, ˆS2responses to the initial dynamics of
ˆS1with a similar coherent precession. However, ˆS2should
still be stable in its initial position at this current density andTABLE I. Critical current densities in units of 108Ac m−2,
calculated according to Eqs. ( 9), (10), and ( 12) for both SyAF and
SyF free layers.
SyAF SyF
↓↑ ↑↓ ↓↑ ↑↓
Ic1 −0.31 0.43 −0.54 0.63
Ic2 0.98 −0.46 2.33 −0.78
IcC F L −0.86 0.87 −2.37 −9.18
common precessions of the two coupled spin moments damp
the initial dynamics. Accordingly, SyAF ends up in the closeststatic state ( ↓↑). However, as the current density increases, the
initial precessions of ˆS
1become more pronounced, which in
turn means that the initial antiparallel configuration becomesdistorted and ˆS
2becomes destabilized. This results in a
coupled dynamics of both spins and finally leads to switchingof the SyAF structure.
On the other hand, we have also calculated the critical
current for the whole SyAF structure according to Eq. ( 12), and
for the given structure we got I↓↑
c CFL, shown in Fig. 4(a)by the
dashed vertical line (see also Table I). Equation ( 12) describes
the stability of the whole CFL, and since the interlayer coupling
is strong, I↓↑
c CFL corresponds to the current density at which both
spins become destabilized, simultaneously preserving theirantiparallel orientation. As can be seen in Fig. 4(a),t h i si s
the maximum threshold current density for current-induceddynamics. Because the rigid structure consisting of twoantiparallel spins is not influenced by an external homogeneous
magnetic field, there is no dependence of I
↓↑
c CFL onHapp.
Nevertheless, from our numerical simulation, it follows thatthe threshold current for the SyAF dynamics, I
thr, obeys the
condition |I↓↑
c1|<|Ithr|<|I↓↑
c CFL|, provided that |I↓↑
c1|<|I↓↑
c2|
or (as in our case) I↓↑
c2has a different sign.
When the SyAF is in the ↑↓configuration, the spin
accumulation and spin current are different from those in the↓↑configuration (at the same voltage). This in turn leads to
different spin torques, which is the reason why the criticalcurrents destabilizing the ↑↓state are different from those
for↓↑, as shown in Table I. From the critical currents one
can expect a relatively symmetric hysteresis with an applied
current in the structures with SyAF. In contrast, I
↑↓
c CFL for
the SyF is negative, similarly as I↓↑
c CFL, but it is significantly
larger, which indicates a lack of hysteresis. To compare theswitching of the SyAF and SyF free layers from the ↓↑to
↑↓configurations with the opposite ones ( ↑↓to↓↑), we have
simulated the dynamics of the corresponding CFLs assumingH
app=0 and varying current density. The simulations have
been performed in the quasistatic regime, i.e., for each valueof current density the spin dynamics was first equilibrated for50 ns, and then averaged values of spin components and pillarresistance were calculated from the data taken for the next30 ns of the dynamics. In order to prevent the system fromcollapsing into a static state with zero torque, we have includeda thermal stochastic field corresponding to T
eff=5 K [see
Eq. ( 3)]. Starting from I=0 and going first toward negative
currents, we have constructed the current dependence of the
104422-8CURRENT-INDUCED DYNAMICS OF COMPOSITE FREE ... PHYSICAL REVIEW B 83, 104422 (2011)
0.48 0.5 0.52 0.54
R [fΩm2]
(a)SyAF SyF
↑↓↓↑
-1 0 1
S1z
(b)
-1 0 1
-1 -0.5 0 0.5 1S2z
I / (108 Acm-2)(c) 0.5 0.52 0.54 0.56 0.58
(d)↑↓↓↑
-1 0 1
(e)
-1 0 1
-2 -1 0 1 2
I / (108 Acm-2)(f)
0.48 0.5 0.52 0.54
-1 -0.5 0 0.5 1R [fΩm2]
I / (108 Acm-2)(g) 0.5 0.52 0.54 0.56 0.58
-2 -1 0 1 2 3
I / (108 Acm-2)(h)
FIG. 7. (Color online) Hysteresis loops of the resistance for the
studied pillars with (a) SyAF and (d) SyF free layers. (b) and (c) depict
the spin dynamics of ˆS1andˆS2in SyAF, respectively, corresponding
to resistance loop (a). (e) and (f) show the dynamics of ˆS1and ˆS2
in SyF, respectively, corresponding to resistance loop (d). The initial
point of each hysteresis loop is marked with a dot. The arrows indicatethe direction of the current change. (g) and (h) correspond to the
upper parts of (a) and (d), in which, however, the effects due to the
magnetostatic field of the reference layer to the CFL spins have beenomitted.
averaged resistance and related zcomponents of both spins, as
shown in Fig. 7.
For both SyAF [Figs. 7(a)–7(c)] and SyF [Figs. 7(d)–7(f)]
free layers, one can see a relatively symmetric hysteresis withthe current density. In both cases direct switching from the ↓↑
to↑↓state occurs at a current density comparable to I↓↑
c CFL.I n
contrast, in the case of the SyF free layer, the second transition(↑↓to↓↑) appears at a current density which is very different
from that predicted by the linearized LLG model. Moreover,in both cases, switching from the ↑↓to↓↑state does not
appear directly, but through some precessional states. Moreprecisely, as the positive current density increases, both spinsstart precessing in the layers’ plane prior to switching. Thein-plane precessions are connected with a significant drop inthe resistance and with a reduction of the s
zcomponents. The
range of the IPP regime is particularly large in the case of SyF.From the analysis of the spins’ trajectories one may concludethat the angle of the IPPs increases with increasing currentdensity, and after exceeding a certain threshold angle CFLswitches to the ↓↑configuration.
The other factor giving rise to the the difference in switching
from↑↓to↓↑and from ↓↑to↑↓follows from the fact that the
magnetostatic interaction of the CFL’s layers with the polarizeris different in the ↓↑and↑↓states. To prove this we have
constructed analogical hysteresis loops for SyAF and SyF freelayers disregarding magnetostatic interaction with the F
0layer;see Figs. 7(g) and7(h). For both SyAF and SyF free layers
we observe now a large decrease in Rfor both switchings.
This implies that both switchings are realized via in-planeprecessions, in contrast to the case when F
0influences the CFL
dynamics via the corresponding magnetostatic field. While thehysteresis loop for SyAF remains symmetric, the one for SyFbecomes highly asymmetric. The asymmetry of the SyF loop isdue to a significant asymmetry of STT in the ↑↓and↓↑states,
which was previously shaded by the magnetostatic couplingwith the layer F
0.
V . DISCUSSION AND CONCLUSIONS
We have studied current-induced dynamics of SyAF and
SyF composite free layers. By means of numerical simulationswe identified a variety of dynamical regimes. The mostsignificant difference between the dynamics of SyAF andSyF free layers concerns the evidence of the self-sustaineddynamics of both CFL spins. While in the case of SyAFonly coupled in-plane precessions in a narrow window ofexternal parameters ( H
appandI) are observed, the SyF free
layer reveals a more complex and richer dynamics, with thepossibility of coupled out-of-plane precessions which mightbe interesting from an application point of view. Furthermore,as shown by numerical simulations, both SyAF and SyF areswitchable back and forth without the need of an externalmagnetic field. For the SyAF element two possible ways ofswitching have been identified. Since they lead to differentswitching times, their identification might be crucial for theoptimization of switching in real devices with SyAF freelayers. However, one has to note that the diagrams shownin Figs. 4and5may be changed when magnetization in CFL
becomes nonhomogeneous.
A disadvantage of the studied structures is their relatively
low efficiency of switching, i.e., high amplitude of criticalcurrent and long switching time. In order to show moresophisticated ways of tuning the CFL devices, we haveanalyzed critical currents derived from the linearized LLGequation. Formula ( 12) has been identified as the maximum
value of critical current at which the dynamics of the CFLstructure should be observed. This formula reveals some basicdependence of critical current on spin valve parameters, andtherefore might be useful as an initial tool for its tuning.However, in some cases nonlinear effects in the CFL dynamicsmight completely change the process of CFL switching, asshown by the presented numerical simulations. But the effectsof nonlinear dynamics go beyond the simple approach of alinearized LLG equation, and their study requires more so-phisticated nontrivial methods and/or numerical simulations.
ACKNOWLEDGMENTS
This work was supported by the Polish Ministry of Science
and Higher Education as a research project in the years2010–2011, and partly by the EU through the Marie CurieTraining Network SPINSWITCH (MRTN-CT-2006-035327).The authors thank M. Gmitra for helpful discussions. One ofus (P.B.) also thanks L. L ´opez D ´ıaz, E. Jaromirska, U. Ebels,
and D. Gusakova for valuable suggestions.
104422-9P. BAL ´AˇZ AND J. BARNA ´S PHYSICAL REVIEW B 83, 104422 (2011)
APPENDIX: TRANSFORMATIONS OF SPIN CURRENT
The torque acting on the left-hand interface of F 1is calcu-
lated from the xandycomponents of j/prime
1=T(θ1,φ1)·j1, where
j1is the spin current vector in the N 1layer (written in a global
frame; shown in Fig. 1), and T(θ1,φ1)=Rx(−θ1)Rz(φ1−
π/2), where Rq(α) is the matrix of rotation by angle αalong the
axisqin the counterclockwise direction when looking toward
the origin of the coordinate system. Hence the j/prime
1components
can be written as
j/prime
1x=j1xsinφ1−j1ycosφ1, (A1a)
j/prime
1y=(j1xcosφ1+j1ysinφ1) cosθ1−j1zsinθ1,(A1b)
j/prime
1z=(j1xcosφ1+j1ysinφ1)s i nθ1+j1zcosθ1,(A1c)
where ( θ1,φ1) are the spherical coordinates of ˆS1in the global
frame. Similarly, we define the torques’ amplitudes on the left-hand interface of F
2from the components of the transformed
spin current vector j/prime/prime/prime
2=T(θ2,φ2).j2. In this case, however, j2
is not written in the global frame, but in the local coordination
system coordinate system connected with ˆS1. To rotate the
local coordinate system of ˆS1to the local coordinate system of
ˆS2, we need to know the spherical angles θ2andφ2of vector
ˆS2in the local coordinate system of ˆS1. This might be done by
transforming first the ˆS2vector to the local coordinate systemofˆS1asˆS/prime
2=T(θ1,φ1)·ˆS2and calculate its angles θ2andφ2.
Then we can calculate the components of j/prime/prime/prime
2similarly as for
the left-hand interface,
j/prime/prime/prime
2x=j2xsinφ2−j2ycosφ2, (A2a)
j/prime/prime/prime
2y=(j2xcosφ2+j2ysinφ2) cosθ2−j2zsinθ2,(A2b)
j/prime/prime/prime
2z=(j2xcosφ2+j2ysinφ2)s i nθ2+j2zcosθ2,(A2c)
The equations in N 2, which is an adjacent nonmagnetic
interface from the right-hand side of F 1, are written in the local
coordinate system of ˆS1. To apply the definition of a(1)
2andb(1)
2
we need to rotate the local coordinate system so that its yaxis
will lie in the layer given by vectors ˆS1andˆS2. This might be
done by a single rotation of the local coordinate system arounditszaxis by an angle φ
2−π/2,j/prime/prime
2=Rz(φ2−π/2)·j2, where
j/prime/prime
2x=j2xsinφ2−j2ycosφ2, (A3a)
j/prime/prime
2y=j2xcosφ2+j2ysinφ2, (A3b)
j/prime/prime
2z=j2z. (A3c)
Note that angle φ2is calculated for vector ˆS2transformed into
a coordinate system of ˆS1as in previous case.
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PhysRevB.83.174424.pdf | PHYSICAL REVIEW B 83, 174424 (2011)
Fractional locking of spin-torque oscillator by injected ac current
Dong Li,1Yan Zhou,2Changsong Zhou,1,*and Bambi Hu3
1Department of Physics, Centre for Nonlinear Studies and The Beijing-Hong Kong-Singapore Joint Centre for Nonlinear and Complex
Systems (Hong Kong), Hong Kong Baptist University, Kowloon Tong, Hong Kong
2Department of Information Technology, Hong Kong Institute of Technology, Mid-levels west, Hong Kong
3Department of Physics, University of Houston, Houston, Texas 77204-5005, USA
(Received 4 January 2011; revised manuscript received 21 March 2011; published 11 May 2011)
Fractional synchronization is one of the most interesting collective behaviors in coupled or driving-response
oscillators system, very important for both a deep understanding of a particular oscillator and for its applications.We numerically investigate the fractional synchronization of a spin-torque oscillator by injected ac current.Multiple p:qlocking regions are found, which display some sophisticated overlaps. The system can be analyzed
as a perturbed heteroclinic cycle rather than a phase oscillator. Both the modulations on the output frequencyand power are mainly due to the modulation by the external signals on the distance between the dynamical orbitand the saddle point in phase space. By using this dynamical picture, we can well understand all the numericalresults, including the variation of the locking region with the amplitude |J
a|or frequency fof the injected
signal, the influence by noise, and the difference among the output powers of coexisting locking attractors.These understandings are significant for both potential applications in electronic communications and a deepinvestigation into this novel device.
DOI: 10.1103/PhysRevB.83.174424 PACS number(s): 75 .40.Gb, 85 .75.Bb, 05 .45.Xt
I. INTRODUCTION
The spin-torque oscillator (STO)1currently is receiving a
rapidly growing interest thanks to its significant advantages,such as its extremely small footprint (without the need ofa large inductor), ultrawide-band-frequency operation, andeasy on-chip integration, which make it very promisingfor broadband high-quality microwave generator.
2It is of
significance to study the interaction between a STO and anexternal stimuli both for a deep understanding of the dynamicalcharacteristics of a STO device and for potential applications.For example, for the purpose of utilizing that STO in mostof the existing communication technology, it is imperativethat it be readily modulated by an external stimuli since apure microwave resonance of the STO does not carry anyinformation.
3When the external frequency fis close to the
intrinsic (free-evolving) STO frequency F, it is possible to
get a 1 : 1 phase locking, where the locking ratios p:q=
f:˜F=1 : 1, and ˜Fis the oscillation frequency of the STO
under external forces. This effect has been studied both exper-imentally and theoretically for the purpose of understandingand realization of mutual synchronization of two or moreSTOs.
4
Understanding the response of a STO to a wider range
of injected frequencies can be obtained by investigating thefractional synchronization, which means p:qis a rational
number. Urazhdin et al.
5experimentally demonstrated that
the STO can be fractionally locked to a microwave magneticfield and pointed out that the nontrivial observation was dueto the complex nonlinear characteristics of STO. Microwavemagnetic field and microwave current are the two externalstimuli that are usually used to interact with STOs. However,it will be much more convenient to modulate the STO with anexternal microwave current instead of a microwave magneticfield since the incorporation of a large magnetic field sourcefor the generation of a microwave field will outweigh anyadvantages of STO-based nanosized devices.
6In this paper,we will study the fractional synchronization of the STO with
a wide range of injected ac currents.5
Previously, such a driven STO has usually been analyzed by
phase oscillator model, where the synchronization is usually
associated with a 1 : 1 locking when the driving frequency isclose to the free-evolving frequency.
4,7But the phase oscillator
model cannot be used to explain some important nonlinearcharacteristics.
8Therefore, it is not expected to be suitable
to analyze most of the phenomena relating to p:qfractional
locking, since the appearance of p:qlocking usually is as-
sociated with some highly nonlinear characteristics. The STO
is a nonlinear oscillatory system with some saddle-connectionstructures, and its dynamics is more suitably analyzed as aperturbed heteroclinic cycle.
8In this type of dynamical system,
there is a good degree of flexibility of locking in a wide
range of both subharmonics and superharmonics, which comes
from the sensitivity of its dynamical state near the heteroclinic
orbit, especially near the saddle points.9This is the theoretical
foundation basis on which we analyze the p:qfractional
locking of STO.
Three problems are of special importance in studying
locking behavior. First, how do these p:qlocking regions
change with the parameters of the driving signals? They
can highly reflect the nonlinear characteristics of a particularsystem.
5,10Second, how do these regions change if noise
effect is taken into consideration? It is important becausenoise plays a unique role in such a dynamical system witha saddle-connection structures
9,11and noise is inevitable in
the experiments.12Third, what is the output power of these
locking attractors? The output power is of importance for itsapplications.
2
Our studies in this paper will be focused on the afore-
mentioned three problems. Multiple p:qlocking regions are
found, and their rich behaviors are shown. The STO systemhas a great degree of flexibility of locking to a wide rangeof injected frequencies than that of a typical driven phase
174424-1 1098-0121/2011/83(17)/174424(8) ©2011 American Physical SocietyDONG LI, Y AN ZHOU, CHANGSONG ZHOU, AND BAMBI HU PHYSICAL REVIEW B 83, 174424 (2011)
oscillator. Different p:qfractional locking regions can have
complicated overlaps, and multiple p:qlocking attractors can
coexist at the same system parameters. Noise can destroy theattracting basins of the locking attractor having the smallestdistance to its bifurcation point in parameter space or the onehaving the smallest attracting basin. Noise can also makethe STO lock to a slower injected frequency. The outputpower is different among the coexisting locking attractors.These nontrivial features must be taken into considerationwhen developing STOs into applications. Importantly, all theobservations can be well understood by the nonlinearity ofthe perturbed heteroclinic cycle structure, i.e., the results ofthe modulation on the frequency or on the output powerindeed comes from the modulation on the distance between thedynamical orbit and the saddle point in the phase space, andthe larger the distance, the slower the frequency. Through thesedetailed studies of fractional locking, the complex nonlinearcharacteristics of this nontrivial STO system can therefore bewell understood.
II. MODEL
A macrospin approximation treats the magnetization of a
sample as a single macroscopic spin and has been extensivelyused to capture some features of magnetic materials qualita-tively as well as for studying the fundamental aspects of thespin-torque-induced magnetization precession and switching,albeit with some limitations, such as are typically used forstudying nanopillar with lateral sizes below 30 nm where thedominant spin wave is a zero-order coherent spin wave mode;and it becomes invalid for the cases where the large-amplitude,higher-order spin wave modes excitations become importantsuch as magnetic nanocontacts, vortex oscillators, and mostof spin-torque-driven domain-wall motions. In this paper weutilize a macrospin approximation for studying the qualitativefeatures of microwave-current-driven fractional locking of themostly commonly investigated in-plane spin-torque nanopillardevice injected with ac current [Fig. 1(a)]. The unit vector of
the free-layer magnetization mis described by the Landau–
Lifshitz–Gilbert–Slonczewski (LLGS) equation,
13
dm
dt=− |γ|m×Heff+αm×dm
dt+|γ|βJm×(m×M),
(1)
where γis the gyromagnetic ratio, αis the Gilbert damping
parameter, and βcontains material parameters and funda-
mental constants.14The electrical current Jis defined as
positive when electrons flow from the fixed layer to the freelayer. The effective field H
effcarries the contribution of an
external applied magnetic field Ha, an anisotropy (easy axis)
fieldHkalong the xaxis, and a demagnetization (easy plane
anisotropy) field μ0Hdz=4πMs, where Msis the saturation
magnetization of the free-layer material. Thus we get Heff=
Haˆex+(Hkmxˆex−Hdzmzˆez)/|m|. In most experiments, due
to the utilization of a synthetic antiferromagnetic stucture suchas a pinned layer, the stray field acting on the free layer canbe significantly compensated. In the framework of macrospinsimulation employed in the current study, the stray field actingon the free (sensing) layer is assumed to be zero.FIG. 1. (Color online) (a) Schematic of the in-plane STO investi-
gated in this paper. The free-layer magnetization mis separated from
the fixed layer Mby a nonmagnetic layer. In the spherical coordinate
system (b), the three possible oscillatory states in a free-evolving
STO are shown respectively in (c) a attracting heteroclinic cycle, (d)
global oscillation, and (e) local oscillation. The bold lines are theattractors. Their trajectories in the three-dimensional configuration
space are shown respectively in (f) a homoclinic orbit, (g) out-of-plane
oscillation, and (h) in-plane oscillation. Lin (d) indicates the distance
between the orbit and saddle. ˆLin (g) demonstrate this distance in
the configuration space.
In spherical coordinate system, we can express Eq. ( 1)a s
dθ
dt=γ
1+α2{Ucosθcosφ+α(Hdz+Hkcos2φ)
×sinθcosθ−Vsinφ−Hksinφcosφsinθ}, (2)
dφ
dt=γ
1+α2/braceleftbigg1
sinθ[−Usinφ−(Hdz+Hkcos2φ)s i nθ
×cosθ−Vcosφcosθ−αHksinφcosφsinθ]/bracerightbigg
,(3)
where U=αHa−β(Jd+Ja) and V=Ha+αβ(Jd+Ja).
Jdis the dc current and Ja=|Ja|cos 2πf t represents the
injected ac current with the amplitude |Ja|and the injected
frequency f. The values of some parameters used in the
calculation are as follows: |γ|=1.885×1011Hz/T,α=
10−2,Ha=0.2T ,β=10/3,Hdz=1.6T ,Hk=0.05 T,
andJd=10 mA, so that the free-evolving frequency F
approximates to 21 .7 GHz.
We call it a free-evolving state when |Ja|=0. In the pa-
rameter region where the STO can itself sustain an oscillation,the equilibrium state /Pi1
(1)thatmis antiparallel to Mmust
be a saddle point in the dynamical phase space, whereas theother equilibrium state /Pi1
(2)thatmis parallel to Mmust be an
unstable focus. There may be a homoclinic orbit (a heterocliniccycle in spherical coordinate system) connecting the saddle,but it can just happen at a particular subset with zero measurein the parameter space. The heteroclinic cycle in spherical
174424-2FRACTIONAL LOCKING OF SPIN-TORQUE OSCILLATOR ... PHYSICAL REVIEW B 83, 174424 (2011)
coordinate [Fig. 1(b)] is shown in Fig. 1(c), and its trajectory
in the three-dimensional configuration space is shown inFig. 1(f). The dynamics of the system with parameters
deviating from that for the heteroclinic cycle can be dealt withas aperturbed heteroclinic cycle . The asymptotic stable states
can be classified into two cases: (i) global oscillation [Figs. 1(d)
and 1(g)] which means the free layer mrotates around the
current J, and (ii) local oscillation (LO) [Figs. 1(e) and1(h)]
which means mjust vibrates near a particular direction.
8Such
three types of oscillation have also been numerically and/oranalytically given in others’ work.
15In this paper, we will focus
on the physically more relevant global oscillatory state exceptfor special notes. Such a state has a free-evolving frequencyFdepending on the distance Lbetween the orbit and the
saddle point,
8as shown in Fig. 1(d). While the free-evolving
state studied in this paper is always a global oscillatorystate, the orbit could be driven across the saddle point andbecomes a local oscillatory one when the injected current islarge.
III. FRACTIONAL SYNCHRONIZATION
In the presence of an injected current, the system is driven
to a new orbit with a different distance ˜Lfrom the saddle,
and the frequency is modulated to ˜Fmainly due to ˜L. When
the injected ac current Jais small, it influences the system as
another perturbation. The case of small Jahas been studied in
Ref. 8, showing that the 1 : 1 locking region is proportional
to the injected |Ja|. Here, we consider a wider range of
driving frequencies and stronger currents; the synchronizationregions are shown in Fig. 2. In the case of a wider range of
driving frequencies, several fractional locking regions could beobserved even when |J
a|is small. For example, in Fig. 2(below
the dashed line), the regions of locking ratios p:q=1:2 ,
1 : 1, 2 : 1, and 3 : 1 are obvious and well separated. In thefollowing, we investigate these fractional locking regions andfocus on the three aforementioned problems.
A.p:qlocking regions
Before investigating how the p:qlocking regions change
with system parameters, we show that it is relatively easierto fractionally lock this system and get larger locking regionsthan typical driven phase oscillators. The reason is that thedynamical orbit in this type of system is very sensitive toexternal perturbation near the saddle points and easier tobe driven to the target orbit of the synchronized frequency.
9
Typically, an oscillator which could be fractionally locked to a
driving signal, when simplified to the form of phase oscillator,would take the following form:
dφ/dt =2πF+μ/summationdisplay
p,qgp,qsin (2πqft−pφ), (4)
where Fandfare the free-evolving and driving frequencies,
respectively, μis the driving strength, and gp,qis the weight
of the p:qdriving component. Usually, gp,qis bigger with
smaller pandq, so that the smaller pandqlocking attractor
is more stable and its locking region is usually larger.
When the other p:qcomponents could be ignored com-
pared with 1 : 1, this phase oscillator could be simplified as
dφ/dt =2πF+μsin (2πf t−φ), (5)
whose locking region is
2π|F−f|/lessorequalslantμ. (6)
If we regard the driven STO as a phase oscillator, the 1 : 1
driving strength has the same order asβγ
1+α2|Ja|.8,16The 1 : 1
locking region given by Eq. ( 6) (dashed line in Fig. 3,l o w e r
panel) is much smaller than the 1 : 1 locking region in Fig. 2
at the same injected amplitude |Ja|.
Here, our aim is to show a simple comparison, so we
preserve three terms of p:q=1 : 1, 2 : 1, and 3 : 1 and
assume that g1,1=g2,1=g3,1=1 (in physical case, usually
g1,1>g 2,1>g 3,1).μis still assigned the value asβγ
1+α2|Ja|.
In Fig. 3, we show the locking region of this simplified driven
phase oscillator:
dφ/dt =2πF+μ[sin (2 πf t−φ)
+sin (2πf t−2φ)+sin (2πf t−3φ)]. (7)
Two significant differences are observed between the real
driven STO system (Fig. 2) and the driven phase oscillator
system (Fig. 3). First, this driven STO system shows a much
larger locking region of each fractional locking attractor, whencomparing Fig. 2with the lower panel of Fig. 3, both having
t h es a m es c a l eo f |J
a|. To get a similar size of locking region in
the driven phase oscillators, the driving current |Ja|needs to be
enlarged by 2–3 orders of magnitude, as seen in upper panel ofFig. 3. Second, there could be many p:qlocking regions
in the real STO system whereas the number of fractionallocking regions in the driven phase oscillator depends on
FIG. 2. (Color online) Probabilities of synchronization from different initial conditions in 1 : 3, 1 : 2, 1 : 1, 2 : 1, and 3 : 1 regions. Black
indicates the 100% synchronization regions. We use different color scales to help distinguish different locking regions. In each region, strips ofthe lighter color indicate smaller synchronization probabilities. Some other locking regions, such as 3 : 2, 4 : 3, etc., are also observed, but not
shown in the figure for the sake of clarity). |J
a|=2 mA is on the dashed line. The probability in this figure and also other places in this paper
represents the ratio of the phase volume of an attracting basin to the whole phase space.
174424-3DONG LI, Y AN ZHOU, CHANGSONG ZHOU, AND BAMBI HU PHYSICAL REVIEW B 83, 174424 (2011)
FIG. 3. (Color online) Fractional locking regions of the phase
oscillator in Eq. ( 7). The lower panel has the same scale of |Ja|
as that of Fig. 2, but the locking regions are much smaller. To get
a similar size of locking region to Fig. 2, the injected current |Ja|
needs to be enlarged greatly, as shown in the upper panel. The dashedlines delimit the 1 : 1 locking region of the driven phase oscillator,
dφ/dt =2πF+β|J
a|sin (2πf t−φ).
the form of the coupling term [in the case of Eq. ( 5), only
1 : 1 is found; in the case of Eq. ( 7), 2 : 1 and 3 : 1 locking
emerge]. This comparison shows that the degree of flexibilityof fractional synchronization of the driven STO system is quitehigh, consistent with the expectation based on the perturbedheteroclinic cycle structure. Several typical representations ofthe locking dynamics of the driven STO system are shown inFig. 4.
In a typical oscillator which can be well described by
a phase oscillator, increasing J
aof the driving signal will
generally enlarge the locking region and make an lockingattractor more stable, which can be beneficial for many
FIG. 4. (Color online) Time evolution of cos φ(solid lines) and
the injected signal cos (2 πf t) (dashed lines) of several typical locking
examples: (a) 1 : 3 ( f=7.2 GHz), (b) 1 : 2 ( f=10.8 GHz), (c) 1 : 1
(f=21.6 GHz), (d) 2 : 1 ( f=45.0 GHz), (e) 3 : 1 ( f=66.0 GHz),
(f) 4 : 3 ( f=30.0 GHz), and (g) 2 : 1 local oscillation ( f=
30.0 GHz). |Ja|=10 mA, and other parameters are the same as
in Fig. 2. LO stands for local oscillation.applications. However, this is not always the case in the driven
STO system.
Comparing Fig. 2and Fig. 3, we can see that when
different p:qlocking regions meet, they may have some
complicated overlaps. It is totally different from the p:q
locking in the driven phase oscillator, where the fractionallocking regions are separated by obvious boundaries. Thisdifference has significant implications in applications, becausethe overlapping of locking regions means that the attractormay not become more stable but rather could shift to anotherunder some particular initial conditions when |J
a|is increased.
Here, multiple p:qlocking attractors can coexist for the
same set of system parameters, for example the coexistenceof 4 : 3 locking attractor and 2 : 1 locking attractor with[2 : 1(LO)], shown in Figs. 4(f) and 4(g). The problem happens
when an expected 100% synchronization region is pierced bythe locking regions of other attractors. For example, in theenvelope of the 100% synchronization region of 1 : 1 lockingin Fig. 2, synchronization may be expected to be achieved from
any initial conditions, and then this synchronization regioncould be robustly employed in applications. However, thisregion is in fact pierced by other regions, e.g., 2 : 1, 3 : 1locking, so the 1 : 1 synchronization is not always achievable.An example is shown in Fig. 5. When f=24.2 GHz and
|J
a|=3 mA, 1 : 1 locking will be always achieved from any
initial condition because it is the only attractor. But whenincreasing to |J
a|=5 mA, the synchronization is invaded by
2 : 1 locking. From some particular initial conditions, 2 : 1locking is achieved. When |J
a|becomes larger, the overlaps of
the coexisting multiple locking attractors and even some newlyemergent ones will make the asymptotical dynamics dependstrongly on initial conditions.
The sophisticated overlapping of different locking regions
is a result of the saddle-node bifurcation of synchronizationin the perturbed heteroclinic cycle system.
16W h e nan e w
locking attractor emerges, an unstable orbit emerges at thesame parameter point, becoming the boundary of the attractingbasin. So there is no need for the other attractors to lose
FIG. 5. (Color online) Time series of cos φof different locking
attractors with the identical injected frequency f=24.2 GHz.
(a) 1 : 1 locking when |Ja|=3 mA (unfilled squares), (b) 1 : 1
locking when |Ja|=5 mA (filled squares), and (c) 2 : 1 locking
when |Ja|=5 mA (diamonds) compared with the driving signal
cos 2πf t (solid line). (d) The dynamical orbits of these three attractors
in phase space {θ,φ}. The filled circles and stars are respectively
the saddle point /Pi1(1)and unstable focus /Pi1(2). The slower locking
attractor (diamonds) shows an obviously shorter distance from the
saddle point.
174424-4FRACTIONAL LOCKING OF SPIN-TORQUE OSCILLATOR ... PHYSICAL REVIEW B 83, 174424 (2011)
stability at the same time and multiple attractors can coexist
as the overlap of the locking regions. On the other hand, adriven phase oscillator model in Eq. ( 4) is not relevant to
explain this phenomenon, because the synchronization anddesynchronization in phase oscillators are usually associatedwith supercritical Hopf bifurcation. When the synchronizationattractor becomes stable, the other attractors must disappear,so that there are clear boundaries between locking regions.
According to our calculations within the framework of the
perturbed heteroclinic cycle structure, the STO can demon-strate fractional locking to an ac current, which is similarto its fractional locking to an ac magnetic field, observed inexperiments.
5However, compared with the fractional locking
by an ac field,5our studies show that the STO will exhibit
different locking characteristics by an ac current, e.g., theoverlapping of the locking regions, which has not beenreported in the experiments by the ac magnetic field. Anotherdifference refers to the size of the synchronization regions.As shown in Fig. 2,1 : 1 ,2 : 1 ,a n d3 : 1h a v es i m i l a r
synchronization regimes, different from the case of the ac fieldp: 1 phase locking, where the sizes of the synchronization
regions are significantly different for even and odd p.
It should also be noticed that we simulate the probability in
Fig.2and elsewhere by using uniform distribution of the initial
conditions, so that the exact meaning of probability in fact
reflects the ratio of the phase volume of an attracting basin tothe whole phase space. The probabilities of these attractors inexperiments is equivalent to the probabilities in this work with
a weighting factor, which originates from the initial conditions’distribution affected by a variety of stochastic factors in reality,including, but not limited to, the temperature.
B. Noise effect
What the effect of noise is on these p:qlocking phe-
nomena of the STO is another important problem. The greatdegree of flexibility of STO locking to a wide range is dueto its sensitivity to the perturbation near saddle points.
9Noise
thus usually plays an important role in such a system.11And
noise is inevitable in experiments. In the driven STO system,the influence of noise is more complex and interesting. It caninfluence both the locking frequency and the attracting basinsof the coexisting locking attractors.
Let us first study the impact of noise on the locking
frequency. Usually noise tends to drive the orbit far awayfrom the saddle points in a pure heteroclinic cycle system, soas to speed up the oscillations.
11Therefore it is often expected
that the system tends to lock with a higher driving frequencywhen noise strength is increased. But in this system, thereis already a perturbation induced by the system parameters,which makes the system have a higher opportunity of beingdriven close to the saddle in the presence of noise. As a result,the STO can be locked to a smaller driving frequency withsome noise. But this phenomenon of noise-induced slowingdown is not easily observed in a 1 : 1 locking region, becausethis locking region is usually too wide where the variationinduced by noise is easily ignored. Thanks to the fractionalsynchronization states, we can demonstrate this nontrivialphenomenon obviously in a thinner locking region. As shownin the 1 : 2 region in Fig. 6(a), increasing Gaussian white
noise can make the STO obviously lock to a smaller drivingFIG. 6. (Color online) Probabilities of synchronization of (a)
1 : 2, (b) 1 : 1, and (c) 2 : 1 regions while noise added as /angbracketleftHa(t)/angbracketright=
0.2T,/angbracketleftHa(t)Ha(s)/angbracketright=2Dδ(t−s).|Ja|=2mA and the other param-
eters are the same as in Fig. 2.
frequency. The variation of locking frequency induced by
noise is a typical phenomenon of synchronization in such adynamical system with a saddle-connected structure, but theslowing-down phenomenon induced by noise is nontrivial. Inthese systems, the modulation by noise on the distance betweenthe dynamical orbit and the saddle point results in a modulationon the frequency, one of the mechanisms underlying anotherwell-known phenomenon named stochastic resonance.
17In
this way, noise can sometimes contribute to the locking of aSTO to a different frequency. This effect is especially obviouswhen the locking region is small [comparing Fig. 6(a) with
Figs. 6(b) and6(c)]. It is therefore very important to consider
the effect of noise in potential applications of STOs, especiallyin the case where the locked or modulated frequency is usedto encode information.
The effect of noise on attracting basins is easier to compre-
hend. In the region of coexistence of multiple attractors, noisetends to destroy the basin of the locking attractor that has thesmallest distance to its bifurcation point in parameter space,or the one with the smallest attracting basin. We demonstratethe meanings of the smallest distance to its bifurcation point
andsmallest attracting basin schematically in Fig. 7, where
initial conditions refer to all the state variables, and ωcould
be any system parameter, e.g., the injected frequency fin our
STO system. Along with the increasing ω, one can see the
emergence of D and A and the disappearance of B, A, and Cin order. At ω
1andω2, A and B have the smallest distance
to their bifurcation points S1andS2, respectively. D has the
smallest attracting basin at most region of the parameter ω.
In the driven STO system, by increasing the driving
frequency f, different p:qlocking attractors can emerge
and disappear in a way similar to that of Fig. 7. We show one
of such examples in Fig. 8. Figures 8(a) and8(b) respectively
show the probabilities of getting each locking attractor withthe uniform distribution of initial conditions in the absenceand in the presence of noise, when the amplitude of the drivingsignal is fixed as |J
a|=10 mA; Figs. 8(c),8(e),8(g), and 8(h)
show the distributions of those attracting basins at f=29.1
GHz, f=30.0 GHz, f=30.3 GHz, and f=15.9 GHz;
and Figs. 8(d) and 8(f) show two realizations of simulation
in the presence of noise at f=29.1 GHz and f=30.0 GHz
to demonstrate the change of the distributions of attractingbasins and the smearing of the basins’ boundaries.
Noise is absent at first. When ffalls within the region
between about 29 .1 GHz and 30 .0 GHz (1 .38–1.43 times
ofF), the coexistent locking attractors are 1 : 1, 4 : 3, 3 : 2,
and 2 : 1(LO) [Fig. 8(a)]. Similar to other fractional locking
problems, the locking attractors with small pandqusually
174424-5DONG LI, Y AN ZHOU, CHANGSONG ZHOU, AND BAMBI HU PHYSICAL REVIEW B 83, 174424 (2011)
FIG. 7. (Color online) Schematic drawing of the bifurcation
process versus ωin a dynamical system with the coexistence of
multiple attractors, where ωcould be any system parameter, e.g. the
injected frequency fin our STO system. A, B, C, and D indicate
the attracting basins of four p:qlocking attractors. S1indicates the
bifurcation point of the emergence of A; S2indicates the bifurcation
point of the disappearance of B. At ω1andω2,Aa n dBh a v et h e
smallest distance to their bifurcation point, respectively. D has the
smallest attracting basin in most regions of the parameter ω.
exist in a wider region of system parameters, and they
are usually more stable (having large basins),10e.g., C in
Fig. 7and the 1 : 1 locking in Fig. 8. When fincreases to
30.3 GHz, the desynchronization attractor appears [Fig. 8(g)].
The output frequency of the 1 : 1 locking has the largestdifference from the free-evolving frequency F. However, the
1 : 1 locking still has a longer distance to its bifurcation pointof disappearance than 4 : 3 locking. The attracting basin of thedesynchronization attractor does not invade the basin of the1 : 1, but the basin of 4 : 3. With further increasing of f,4:3
locking will disappear completely at about 30 .6 GHz. The
similar invasion happens to 3 : 2 locking when fdecreases
below 28 .8 GHz. These observations show clearly that 1 : 1
locking appears to be more stable, whereas 4 : 3 is least stableatf=30.0 GHz and 3 : 2 is least stable at f=29.1 GHz.
The next question is, when noise is taken into consideration,
which basin will be invaded first? The answer is that noise tendsto invade the basin of 4 : 3 at f=30.0 GHz or the basin of 3 : 2
atf=29.1 GHz. It always invades the one having the smallest
distance to its bifurcation point, because the existence of anattractor is sensitive to external perturbation when the systemparameters are so close to the bifurcation point. Thereforethe probabilities of achieving 4 : 3 locking at f=30.0 GHz
or 3 : 2 at f=29.1 GHz significantly decrease, as shown in
Fig.8(b). We show a realization of simulation at f=29.1 GHz
with noise in Fig. 8(d), where the basin of 3 : 2 locking disap-
pears completely due to noise. A similar phenomenon happensto the 4 : 3 locking at f=30.0 GHz, shown in Fig. 8(f).
In other ranges of system parameters, the coexistent
attractors are different; for example, we show in Fig. 8(h)
that, at f=15.9 GHz, the coexistent attractors turn out to
be 1 : 1, 1 : 1(LO) and desynchronization state (DS), but thechange of probabilities under noise effect is always similar.
Noise also tends to destroy the smallest attracting basin.
In Fig. 7, D has the smallest basin and so does the 2 : 1
locking attractor of local oscillation in Fig. 8(a). Comparing
Fig.
8(f)with Fig. 8(e), one can easily see that 2 : 1(LO) is noFIG. 8. (Color online) Attracting basins for the coexisting multi-
ple attractors when |Ja|=10 mA. (a) In the absence of noise, when
fis between about 29 .1 GHz and 30 .0 GHz (the vertical dashed
lines), locking attractors of 1 : 1, 4 : 3, 3 : 2 obviously coexist. [2 : 1
(LO) also exists, but its probability is too small.] (b) In the presence
of noise of /angbracketleftHa(t)/angbracketright=0.2T ,/angbracketleftHa(t)Ha(s)/angbracketright=0.01δ(t−s)T2,t h e
probabilities of these attractors significantly change: the 3 : 2’sturn out to be negligible at about f=29.1 GHz, the 4 : 3’s turn
out to be negligible at about f=30.0 GHz, and the 2 : 1(LO)s
completely disappear for the whole region. (c) The distribution ofattracting basins at f=29.1 GHz, and (d) one of its realizations
of simulation in the presence of noise demonstrates the change of
the distribution and the smearing of the basins’ boundaries. (e) Theattracting basins at f=30.0 GHz and (f) one of their realizations
in the presence of noise. (g) The attracting basins at f=30.3 GHz.
(h) An example of the distribution of attracting basins far from theaforementioned parameter region, while f=15.9 GHz. DS stands
for the desynchronization state.
longer present under the noise effect. This change can also be
observed by comparing Fig. 8(b) with Fig. 8(a).I nF i g . 8(b),
the probability of 2 : 1(LO) is zero, whereas in Fig. 8(a),i t
is not zero. But this comparison is not clear enough since theprobability of 2 : 1(LO) is quite tiny in Fig. 8(a).
174424-6FRACTIONAL LOCKING OF SPIN-TORQUE OSCILLATOR ... PHYSICAL REVIEW B 83, 174424 (2011)
Now let us get back to discussing Figs. 6(b) and 6(c).
Note that 100% synchronization state is most significante inapplications because it is independent of initial conditions.An interesting question is whether noise can contributeto increasing the 100% synchronization state if the basinsof other attractors are very small. The answer is yes. InFig. 6(b) and Fig. 6(c), it is seen that, when the probability
of synchronization is quite close to 100%, increasing noisecan enhance it to 100% and make the 100% region widerand wider until noise strength is too large and it destroyssynchronization again. On the other hand, when probabilitiesof synchronization are low, noise will always destroy thesynchronization state.
These effects of noise on the attracting basins resulted
from the particular bifurcation process as demonstrated inFig. 7. The saddle-node bifurcation of synchronization in this
perturbed heteroclinic cycle system is therefore crucial. All thenontrivial effects of noise originate from the role of noise tomodulate the dynamical orbits near the saddle points in phasespace in such a system with a perturbed heteroclinic cyclestructure. Thus, a driven phase oscillator model is not relevantto explain these effects.
C. Output power
Besides all aforementioned dynamical behaviors, the
output power is another important issue, since it is tied toapplications of the system. The emitted microwave powerspectra of the STO depends on a wide range of materialparameters. Here we study how the output power is influencedby external driving signals. We have performed the Fourier
FIG. 9. (Color online) (a) Fourier transformation amplitudes of
the cosine function of the relative angle between mandMof
different attractors and (b) the positions of their orbits in phase
space {θ,φ}. Parameters are the same as in Fig. 8(e), except for
that in the free-evolving state |Ja|=0 and in the desynchronization
statef=30.3 GHz. The dashed lines in (a) demonstrate the com-
parison among the output powers of the coexisting synchronization
state.transformations of sin θcosφ, the cosine function of the
relative angle between mandM, which is proportional with
the STO output signal, to reflect the microwave power. Theperturbed heteroclinic cycle structure can help us easily knowthe difference among the output powers of the coexistinglocking attractors. The faster attractor oscillates farther awayfrom the saddle point, usually with a smaller amplitude ofoscillation,
8leading to a smaller output power. Figure 9(a)
shows the simulation results. The dashed line demonstratesthe comparison we analyzed (which can be simply markedas 3 : 2 >4:3>1 : 1). The positions of these attractors in
phase space {θ,φ}are shown in Fig. 9(b). When q/negationslash=1, the
distances between an orbit and the saddle point /Pi1
(1)have
a little difference each time it gets close to the saddle point/Pi1
(1)since one p:qattractor gets back to its original position
after it passes over the saddle point for qtimes (rotates q
cycles in configuration space). However, one can still easilynotice the significant difference among the distances betweeneach orbit and the saddle points. The significant differenceamong the distances induces different locking frequencies,and oscillatory amplitudes, leading to different output power.
IV . DISCUSSION
To gain a deeper understanding of how the STO device
responses to a wide range of injected frequencies, we studythe fractional synchronization of STO by an injected ac current.Multiple p:qlocking regions are observed. Our studies focus
on three important problems: how do the locking regionschange with driving parameters, how does noise affect thep:qlocking phenomenon, and what is the output power of
thesep:qlocking attractors? First, we found that the system
has a great degree of flexibility of locking to a wide rangeof driving frequencies. The locking regions can have somesophisticated overlaps, where multiple p:qattractors can
coexist at the same system parameters. Even some 100%synchronization regions can be merged by other lockingregions. Second, noise plays a nontrivial role. It can makethe STO lock to relatively slower frequencies, and it can alsodestroy the attracting basin of the locking attractor having thesmallest distance to its bifurcation point, or the one having thesmallest attracting basin. Finally, we showed that the outputpower of the coexistent locking attractors depends on theoscillating frequencies.
All these novel dynamical behaviors were well explained
by the perturbed heteroclinic cycle structures. Our studies aresignificant both for understanding the nonlinear characteristicsof the STO system and for potential applications.
Our work can also help understand better about the
dynamical behavior of the LLGS equation and thus shedlight on a broad range of magnetism problems which can bedescribed by this equation.
18
ACKNOWLEDGMENTS
This work is support by Hong Kong Baptist University and
conducted using the resources of the High Performance ClusterComputing Centre, Hong Kong Baptist University, which re-ceives funding from Research Grant Council, University GrantCommittee of the HKSAR, and Hong Kong Baptist University.
174424-7DONG LI, Y AN ZHOU, CHANGSONG ZHOU, AND BAMBI HU PHYSICAL REVIEW B 83, 174424 (2011)
*cszhou@hkbu.edu.hk
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174424-8 |
PhysRevB.91.064421.pdf | PHYSICAL REVIEW B 91, 064421 (2015)
Nuclear magnetic resonance study of thin CihFeAIo.s Sio.5 Heusler films with varying thickness
A. Alfonsov,1 ’* B. Peters,2 F. Y. Yang,2 B. Buchner,1 ,3 and S. Wurmehl1 ,3 ,3
1 Leibniz Institute for Solid State and Materials Research IFW Dresden, D-01171 Dresden, Germany
2 Department o f Physics, The Ohio State University, Columbus, Ohio 43210, USA
3 Institute for Solid State Physics, Technische Universitdt Dresden, D-01062 Dresden, Germany
(Received 13 August 2013; revised manuscript received 5 February 2015; published 20 February 2015)
Type, degree, and evolution of structural order are important aspects for understanding and controlling the
properties of highly spin-polarized Heusler compounds, in particular, with respect to the optimal film growth
procedure. In this work, we compare the structural order and the local magnetic properties revealed by nuclear
magnetic resonance (NMR) spectroscopy with the macroscopic properties of thin Co2FeAlo.5Sio .5 Heusler films
with varying thickness. A detailed analysis of the measured NMR spectra presented in this paper enables us to
find a very high degree of L2r type ordering up to 81% concomitantly with excess Fe of 8%-13% at the expense
of A 1 and Si. We show that the formation of certain types of order depends not only on the thermodynamic phase
diagrams as in bulk samples, but also that the kinetic control may contribute to the phase formation in thin films.
It is an exciting finding that Co2FeAl05Si 0.5 can form an almost ideal L2, structure in films, though with a
considerable amount of Fe-Al/Si off stoichiometry. Moreover, the very good quality of the films as demonstrated
by our NMR study suggests that the technique of off-axis sputtering used to grow the films sets the stage for the
optimized performance of Co2FeAl0. 5S i0.5 in spintronic devices.
DOI: 10.1103/PhysRevB.91.064421 PACS number(s): 75.30.-m , 71.20.Be, 61.05.Qr, 76.60.Jx
I. INTRODUCTION
Spintronics is considered a potential follow-up technology
to purely charge-based electronics. In spintronic devices, both
charge and spin of electrons are used as information carriers,
leading to faster switching at lower energy consumption com
pared to charge-based electronics. Half-metallic ferromagnets
(HMFs) are the optimal materials to be implemented in
spintronic devices [1-5], as their conduction electrons are
expected to be 100% spin polarized. Heusler compounds with
L2]-type structure represent an especially favorable family
of predicted HMF compounds and seem to offer all the
necessary ingredients for their implementation in spintronic
devices, qualities such as high spin polarization [ 1,3,5,6], high
Curie temperatures [7,8], and a low Gilbert damping constant
[9], However, the observation of the required key spintronic
properties in Heusler compounds crucially depends on the type
and degree of structural ordering [4,5,10].
NMR spectroscopy allows one to probe the local envi
ronments of 59Co nuclei in Co-based Heusler bulk and film
samples, and thus enables characterization of local order and
quantification of different structural contributions concomi
tantly with an off-stoichiometric composition [10-18]. Such a
local probe of structure and composition is very useful since
compounds comprising elements from the same periodic row
(e.g., Co and Fe) have very similar scattering factors for x rays,
and thus x-ray diffraction (XRD) only may not be sufficient to
resolve the structural ordering unambiguously, particularly if
both disorder and deviations from the 2:1:1 stoichiometry are
present [19].
In addition to information on the chemical, crystallographic
environments, the NMR technique is useful to determine
the magnetic state of a ferro- or ferrimagnetic material. The
*a.alfonsov@ifw-dresden.de
3 s. wurmehl@ifw-dresden.derestoring field (//re st) is an effective magnetic field originating
from a resistance to magnetic oscillations and therefore is
proportional to the square root of the optimal power (i.e., the
power producing the maximum spin-echo intensity) of the
applied rf pulses during an NMR experiment. //rcst derived in
NMR experiments provides a measure of magnetic stiffness
or magnetic anisotropy on a local scale, compared with
the macroscopic domain wall stiffness contributing to the
coercive fields from superconducting quantum interference
device (SQUID) magnetometry [11,13]. The advantage of
NMR is that we can measure at a given frequency and can
thus relate the magnetic stiffness to a specific local magnetic
environment (e.g., phase or structure).
A particular interesting Heusler compound to be mentioned
in the context of HMF is C02FeAlo.5Sio.5- Band-structure
calculations predict a high stability of the minority band gap
in this compound [3,20], a prediction which is experimentally
supported [ 2 1]. Co 2FeAlo. 5Sio.s has been implemented in
thin films and magnetic tunnel junctions [22-30], Recently,
we have epitaxially grown Q^FeAl o.sSi 0.5 films on lattice-
matched MgAl 20 4 (0 0 1) substrates by an off-axis sputtering
technique, yielding films with an exceptionally high quality
[31]. In this work we characterize the local crystallographic
and magnetic structure of these films using NMR. We were
able to relate the macroscopic physical properties of these
Co2FeAl o.sSi 0.5 films to the local ordering.
II. EXPERIMENTAL DETAILS
Epitaxial Q^FeAl o.sSi 0.5 films were grown on MgAl 20 4
(001) substrates by off-axis sputtering in a UHV system
with a base pressure as low as 7 x 10“ 1 1 Torr using ul-
trapure Ar (99.999 9%) as sputtering gas. Optimal-quality
Co2FeAlo. 5Sio .5 epitaxial films were obtained at an Ar
pressure of 4.5 mTorr, a substrate temperature of 600 °C,
and dc sputtering at a constant current of 12 mA, which
results in a deposition rate of 5.6 A/min. The Co 2FeAl o.sSi 0.5
1098-0121/2015/91 (6)/064421 (7) 064421-1 ©2015 American Physical Society
ALFONSOV, PETERS, YANG, BUCHNER, AND WURMEHL
20 (deg)
65.0 65.5 66.0 66.5 67.0
FIG. I. (a) High-resolution 6/26 XRD scan of a 45-nm
Co2 FeAl o ,5Si o.5 (CFAS) film grown on MgAL04 (001) substrates,
(b) XRD rocking curve of the (004) peaks of the Co2FeAl 0 5Si 0.5 film
gives a FWHM of 0.004 3°.
epitaxial films were characterized by a Bruker D8 Discover
high-resolution triple-axis x-ray diffractometer. Details about
growth and characterization are found elsewhere [31].
The NMR experiments were performed at 5 K in an
automated, coherent, phase-sensitive, and frequency-tuned
spin-echo spectrometer (NMR Service, Erfurt, Germany). We
used a manganin coil wrapped around the sample to apply and
pick up the rf pulses. This coil is implemented in an LC circuit
with three capacitors. The NMR spectra were recorded at 5 K
in the frequency (v) range from 104 to 254 MHz in steps of
0.5 MHz in zero magnetic field. All NMR spectra shown here
were corrected for the enhancement factor as well as for the v2
dependence, resulting in relative spin-echo intensities which
are proportional to the number of nuclei with a given NMR
resonance frequency [11,13],
III. RESULTS AND DISCUSSION
Figure 1 shows the 6/26 scan of a 45-nm-thick
Co2FeAl 0.5Si 0.5 epitaxial film on MgAl20 4 (001). The
clear Laue oscillations near the Co2FeAl o.sSi 0 .5 (004) peak
demonstrate the high crystalline uniformity as well as smooth
surface and sharp interface with the substrate. Figure 1(b)
presents a rocking curve of the (400) peak with a FWHM of
0.004 3°, which is at the instrumental resolution limit of our
high-resolution XRD system, revealing exceptional crystalline
quality.
In order to further characterize the structural quality of
our films, we measured the 59Co NMR spectra for different
thin-film samples with varying thickness (20, 45, 84, 120, and
200 nm). Figure 2 exemplarily shows the normalized 59Co
NMR spectra of films with thickness t = 20, 84, and 200 nm
in comparison with that of a Co2FeAl 0.5Si 0.5 bulk sample
(data taken from Ref. [32]). All spectra share the main line
around 163 MHz with one shoulder on the low-frequency side
and two pronounced satellites on the high-frequency side with
spacing of about ~33 MHz between them.PHYSICAL REVIEW B 91, 064421 (2015)
l.O ----.---- -------- 1 -------------. ------------ -- -r-A feT T I
100 150 200 250
frequency (MHz)
FIG. 2. (Color online) Normalized 5 9 Co NMR spectra of
Co2FeAl o.jSi 0.5 thin films with thicknesses of t = 20, 84, and 200 nm
in comparison with the NMR data of a Co2FeAl0 .5Sio .5 bulk sample
[32], Note that missing data points in the middle of the spectra are
due to the increased spectrometer noise for this frequency.
The observation of low- and high-frequency satellite lines
with a spacing of about 33 MHz suggests a contribution from
62-type ordering of the films, in line with the interpretation
of the NMR data for Co2FeAlo.5Sio.5 and Co2FeAl bulk
samples [15,32], Partial 62-type ordering of the films is
consistent with the ternary thermodynamic Co-Fe-Al phase
diagram at 650°C (Ref. [33]) and with experimental results
for the Co2FeAlo.5Sio.5 compound from Umetsu et al. [34].
Neglecting other contributions to the high-frequency satellite,
its higher intensity in the films may be understood in terms of
a higher degree of 62-type contributions. This interpretation,
however, is in strong contrast to the significantly smaller NMR
echo intensity at ~ 130 MHz in films compared to the bulk
sample. In fact, the NMR spectra of the film samples do
not exhibit a clear satellite but rather a shoulder, on the low-
frequency side, which complicates the qualitative comparison
of the spectra. Taking into account both observations, the
larger high-frequency satellites and the poorly resolved low-
frequency satellite in the films compared to the bulk sample,
it seems natural to interpret this observation as a deviation
from the 2:1:0.5:0.5 stoichiometry, and more specifically, to
assume that the films are more Fe-rich and Al/Si-poor than
the expected 2:1:0.5:0.5 stoichiometry (compare Refs. [10],
[16], and [32]). The formation of Fe-rich environments may
also be responsible for the slightly higher than expected
magnetic saturation moment as, according to the Slater-
Pauling rule, the expected value for magnetic moment in the
case of Co2FeAl0.5Sio,5 compound is 5.5 /aB/f.u., whereas
the measured one for the 45-nm film is about 5.6 /zB/f.u. (see
Ref. [31]).
Thereby, already a qualitative analysis of the thin-film NMR
spectra suggests a contribution from both L2{ and 62 types of
order, as well as a presence of an Fe to Al/Si off stoichiometry.
Kozakai et al. [33] report that 62 is the thermodynamic stable
phase at 600 °C in Co2FeAl, whereas Umetsu et al. report that
the L2r type phase is thermodynamically stable below 1125 K
and Co2FeAl05Sio.5 undergoes a transition to 62-type order
064421-2
NUCLEAR MAGNETIC RESONANCE STUDY OF THIN Co ... PHYSICAL REVIEW B 91, 064421 (2015)
at 1125 K [34], Please note that even for the bulk sample
annealed below the ordering temperature no full L2\ order is
realized [32,34], In the present case of a thin film, both 62
and the higher-ordered L 2r type phases are found, suggesting
additional influence of, e.g., the substrate, strain, and/or kinetic
contributions upon cooling.
In order to perform a detailed quantitative analysis of all the
contributions to the NMR spectra, we fitted the NMR spectra of
all samples using a sum of Gaussian lines. The corresponding
parameters of these lines, such as resonance frequency,
linewidth, and intensity, were constrained according to a model
similar to the one described in detail in Ref. [32].
For L2i -type order only one NMR line is expected, while
52-type order yields several NMR lines [13,15]. Hence, in the
presence of both L2\-and 62-type order and off stoichiometry,
the relative area of the NMR spectra can be represented as
a sum of several lines originating in different structural and
compositional contributions. The spacing between adjacent
resonance lines, A 62, may be assumed to be a constant
while their relative contribution to the NMR spectrum is
given by the amount of random mixing of Fe and Al/Si on
one crystallographic site (52-type structure), as well as by
the Fe-to-Al/Si ratio. The off stoichiometry between Fe and
Al/Si contributes to NMR lines on the high-frequency side
only due to the extra Fe at the Al/Si sites in the first Co
shell. From the relative areas of these lines, the amount of
off stoichiometry and L2i/52-type order in the films can be
quantified. Due to the random mixing of A 1 and Si on one (L2i
plus off-stoichiometry) or two (52 plus off-stoichiometry)
crystallographic sites, each NMR line further broadens or
splits into a set of sublines with equal spacing A ^ between
them. This splitting originates in the small difference in the
hyperfine field seen by Co nuclei depending on which atom,
either A1 or Si, is located in the first coordination shell [20,32].
Compounds with Si have one extra valence electron with
respect to the compounds with Al. This extra valence electron
increases the magnetic moment of the compound, which in
turn changes the transferred contributions to the hyperfine
field and concomitantly the resonance frequency [20,21,34],
Hence, each specific configuration with particular Al and Si
neighbors in the first shell of Co arising from the random
distribution expected for a quaternary compound will have a
different resonance frequency. For details see Supplemental
Material Ref. [35] and Refs. [21] and [32]. The relative
contributions of the Gaussian lines in the fit can be compared
to the probabilities calculated from a random atom model [32],
which is mathematically expressed in the form of a binomial
distribution function:
P(n,m,l,k,x,u,y,CB 2,C L 2 l)
n\(N — n — m)\m\
(1 _ x )N - {m+k)x m+ky k(\ - y ) (Ar- n)- *
+ Cl2,--------- —--------- (1 — u)L~lulyk( 1 — y)(L~l)~kS „ 4' 1 \{L - 1 - k)\k \
with S nAif n ^ 4
if n < 4.The first term in Eq. (1) represents the 5 2 contributions
with a random distribution of Fe and Al/Si, where Cb2 is the
degree of 52-type order. This random distribution involves
both the 4 a and 4b Wyckoff positions of the respective L2|
lattice, which correspond to the 1 b position in the 52 notation.
In Eq. (1), x represents the Fe to (Al+Si) stoichiometry,
enabling us to calculate the probability of finding Fe atoms
on the Z (Al and Si) sites, and, hence, to quantify the Fe-
Al,Si off stoichiometry; y denotes the Al to Si stoichiometry
(AlvSi 1— y). For stoichiometric Co 2FeAlo.sSio .5 films with
complete 62-type order, x — 0.5 while x > 0.5 indicates
off stoichiometry with Fe excess. Here, N = 8 is the number
of possible sites for atoms in the first Co shell, while n, m,
and k are the corresponding numbers of Fe, Si, and Al atoms,
respectively, in the first Co shell (note n + m + k = N).
The second term in Eq. (1) represents the contribution
from L 2 r type order, u is the amount of Fe to (Al + Si) off
stoichiometry (u = 0 for stoichiometric composition), L = 4
is the number of possible sites for Fe atoms on the Al/Si sites
in the first Co shell, and / and k are the numbers of Fe and
Si/Al atoms in the first shell, respectively. Since both x and
u represent the off stoichiometry, there is a relation between
these two parameters x = 0.5 u + 0.5. The coefficients Cb2
and Ci2, represent the relative contribution from 59Co nuclei
with a 6 2 and L2\ first shell environment, respectively, and
Cb2 + Ci 2, = 1. There are two ways to realize the presence
of both L2\ and 6 2 in a given sample: Case (i) deals with
large 62-type domains within a L2i matrix, where the number
of Co nuclei located at the interfaces between both phases
is negligible compared to the number of Co nuclei within a
certain phase region in line with the recent report on Co 2MnSi
films by Miyajima et al. [36]. In that case, the coefficients
obtained from our binomial model immediately give the ratio
between L2i and 52 phases. In the second case (ii) both L2i
and 6 2 phases are so finely dispersed that the number of
Co nuclei at the interfaces is not negligible anymore. In that
case, the Co nuclei at the interface experience surroundings
similar to that of B2, and therefore the overall degree of
order is even underestimated by our model. Moreover, in this
case the distribution is no longer described by Eq. (1) (see
Supplemental Material [35] for details). Since our binomial
model [Eq. (1)] well fits the measured NMR data (see below),
scenario (i) seems to be valid in the present case, which is also
in line with the recent report on Co 2MnSi films by Miyajima
et al. [36].
Figure 3 exemplarily shows the fitting result of the NMR
spectrum for the 84-nm Co 2FeAlo. 5Sio.5 films where the
respective fitting parameters are NMR resonance frequencies,
the spacing between lines A 62, y, u, Cb2, AAl/Si, and
the linewidths of individual Gaussian lines. The residual fit
mismatch for all spectra does not exceed 15%, which is quite
good for such a rather simple model. The fit yields the average
spacing between the main line and the high-frequency satellites
of 33 MHz, which is slightly larger than in the corresponding
bulk samples (31 MHz) [32], The spacing AAl/Si between
lines due to the mixing of Al and Si is found to be about 7
MHz, which is very similar to the bulk sample. In addition,
the fit yields the Al-to-Si ratio of 0.5(±0.01):0.5(±0.01), as
expected from the nominal composition. In general, Al and Si
may not be homogeneously distributed in the Co 2FeAl l-^Si*
064421-3
ALFONSOV, PETERS, YANG, BUCHNER, AND WURMEHL PHYSICAL REVIEW B 91, 064421 (2015)
120 140 160 180 200 220 240
frequency (MHz)
FIG. 3. (Color online) Normalized 59Co NMR spectrum of an 84-
nm-thick Co2FeAI o.sSi 0 .5 film, shown together with a fitted curve
(solid line). Analysis of the data gives a degree of L2, order of 81 %.
series. We have seen such an inhomogeneous distribution
by NMR in the Co2Mn i_^Fe vSi series, where Fe in the
the Fe-rich samples is not entirely randomly distributed.
Obviously, such a preferential order will not follow the random
atom model as described in Eq. (1) (also see Ref. [37]). Such
an inhomogeneity is likely not present in the Co2FeAl 0 5Si 0 .5
films for two reasons: (i) for the corresponding bulk system
Al and Si are fairly homogeneously distributed [32], and
(ii) we found no deviations from our random atom model
hinting on such an inhomogeneous distribution of Al and
Si, with the exception that the relatively large mismatch of
the fit and the measured data at frequencies near ~140 and
~215 MHz may be related to the additional contributions from
Co2FeSi and CoAl or fee Co impurities, as suggested in Ref.
[32] for the bulk sample.
Our results confirm a quite high degree of order for all film
thicknesses (Fig. 4). The highest degree of L2\ order is found
to be as high as 81% for the 84-nm film. In order to further
0 )
TJ
< UQ .
■ S '
70
film thickness (nm)
FIG. 4. (Color online) L2r type order contribution (red open
circles) and NMR linewidth (black squares) as a function of film
thickness.NX
cr
(1)
Dt164.0
163.5
163.0 -
162.5
162.0
50 100 150
film thickness (nm)200<D5o
CL
Q .O
FIG. 5. (Color online) Thickness dependence of NMR resonance
frequency (blue squares, left side) and square root of the optimal
power (red circles, right side) for the main line (~ 163 MHz) of the
59Co NMR spectrum.
validate our analysis, we compare the trend in NMR linewidth
for all films as a function of thickness. Figure 4 shows that the
linewidth decreases with increasing film thickness, indicating
an improvement of ordering in thicker films and/or release of
strain. (Please note that the linewidth axis is inverted to allow
for a more direct comparison between evolution of linewidth
and degree of order.) Generally, the dependence of the NMR
linewidth reflects the evolution of L 2i ordering, as expected.
Interestingly, the 84-nm film sticks out, demonstrating the
smallest linewidth along with the highest degree of order of
about 81%. We will come back to the peculiarities of the
81 -nm-thick film at a later point.
In order to further shed light on the relation between
structural quality and film thickness, we analyzed the thickness
dependence of the square root of the optimal power (Fig. 5, red
circles, right side), since the measurement of optimal power
(i.e., the power producing the maximum spin-echo intensity)
of the applied rf pulses allows us to indirectly investigate the
magnetic stiffness or magnetic anisotropy on a local scale via
monitoring the restoring field [11,13]; specifically, the square
root of the optimal power is proportional to the restoring field.
The analysis of the local restoring field is interesting for the
investigation of the quality of thin films with respect to their
thickness as explained in the following: Typically, there is a
critical thickness for films with an epitaxial relation between
film and substrate. While films below a certain thickness show
uniform full strain—either tensile or compressive, depending
on the ratio between the lattice constants—films above the
critical thickness release strain. The critical thickness may
depend on several parameters, such as the ratio of lattice
constants between the film and substrate and the elastic
properties of the film material [38]. The release of strain in
films with their thickness exceeding the critical value may
lead to dislocations, defects, and disorder accompanied by a
change in magnetic anisotropy [38]; we may monitorthis effect
by measuring the restoring field by NMR. In the present case
of C^FeAlo.sSio.s films, we find that the restoring field of the
200-nm film reaches the value of the bulk sample consistent
with a lull release of strain and negligible magnetic anisotropy
consistent with a cubic system. Interestingly, there is a clear
064421-4
NUCLEAR MAGNETIC RESONANCE STUDY OF THIN Co ...
transition for the optimal power at thicknesses between 84
and 120 nm (open circles in Fig. 5). This transition for the
optimal power at thicknesses between 84 and 120 nm may be
related to the fact that the C^FeAlo.sSio.s films are mostly
strained at thicknesses below 100 nm and start to relax above
100 nm, as observed by XRD [31]. In the following, let
us combine the information on thickness dependence of the
linewidth, amount of L2\ order, and local magnetic anisotropy
to understand the evolution of film quality in films with
different thickness. The C^FeAlo.sSio.s films under 100 nm
thick are fully strained with a tetragonal distortion and remain,
hence, structurally uniform, while above 100 nm the films start
to relax, which leads to a lower quality of thicker films. Since
for Co 2FeAlo. 5Sio .5 the critical thickness is about 100 nm,
the best structural quality with the highest L2i ordering is
observed in the largest available thickness below 100 nm, i.e.,
an 84-nm Q^FeAlo.sSio.s film.
In general, the resonance frequencies of the films are higher
than in the bulk sample and closer to the average value
(165 MHz) between highly ordered Co 2FeSi (139 MHz) and
62-ordered Co 2FeAl (190 MHz). Three factors may contribute
to the evolution of resonance frequencies: (i) strain, and
hence the frequency may scale with the film thickness, (ii)
stoichiometry, and (iii) degree of order, (ii) and (iii) are both
based on the fact that the stoichiometry, particularly the Fe
stoichiometry, and order are both closely linked to the magnetic
moment of local neighbors and, hence, in turn to the local
hyperfine field and frequency via the transferred fields.
Since our analysis of the local magnetic anisotropy revealed
a relation between strain and thickness in our Co 2FeAl 0.5 Si 0.5
films, we study the impact of strain on the NMR resonance
frequencies using their evolution as a function of film thickness
(Fig. 5). The resonance frequencies are more or less constant
for films thinner than 84 nm and significantly increase with
increasing film thickness. Interestingly, a matching inverse
trend between the local restoring field and film thickness,
or, in other words, a similar transition between resonance
frequencies and optimal rf power at thicknesses between 84
film thickness (nm)
FIG. 6. Fe/(A1+Si) off stoichiometry as a function of film
thickness.PHYSICAL REVIEW B 91, 064421 (2015)
and 120 nm is observed, confirming that the release of strain
contributes to the evolution of resonance frequencies.
Besides 62-type ordering, we also observe Fe excess
at the expense of A 1 and Si. We were able to quantify
this off stoichiometry by fitting the data with Eq. (1); as
a result, we obtain about 8%-13% excess Fe in the films,
indicating that the film composition differs from that of the
target. This may be understood as follows: In the off-axis
sputtering geometry, the substrate is positioned at an angle
of =55° with respect to the normal direction of the sputter
target. This arrangement is crucial in minimizing the energetic
bombardment damage of the sputtered atoms on the film. Due
to this angled deposition, sometimes there is a difference in
the stoichiometry of the arriving atoms at the substrate as com
pared to the target composition. Film compositions different
from the corresponding target when using on-axis sputtering
were already reported previously, as, e.g., stoichiometric
Co2MnSi films are obtained from stoichiometry adjusted
targets [39,40].
For further analysis of the contribution of Fe stoichiometry
on the resonance frequencies, we plotted the relation between
resonance frequency (MHz)
resonance frequency (MHz)
FIG. 7. Fe/(A1+Si) off stoichiometry (a), L2\ ordering (b), and
their ratio (c) of the Co2FeAl o.sSi 0.5 films as a function of resonance
frequency of the main NMR line.
064421-5
ALFONSOV, PETERS, YANG, BUCHNER, AND WURMEHL
the Fe to Al/Si off stoichiometry and the corresponding
resonance frequency of the main NMR line [Fig. 6(a)], The
NMR resonance frequency monotonously increases with a
decreasing amount of off stoichiometry. A lower level of off
stoichiometry implies a lower macroscopic magnetic moment
of the sample, which in turn, due to a negative hyperfine
constant of Co [21,41], yields a higher resonance frequency
consistent with our observations [Fig. 6(a)],
Interestingly, the Fe stoichiometry scales also with the film
thickness (see Fig. 7), with the thinnest film being the exception
from the trend. This observation may also be related to the thick
films being more similar to the bulk samples.
The binomial analysis shows much larger contributions
from L2i order in the present films (70%-81 %) than in the bulk
sample (59%, see Ref. [32]). Hence, the shift of the resonance
frequencies towards the mean frequency value between highly
ordered Co 2FeSi and B2-ordered CoiFeAl may relate, at least
partially, to the higher order in the films compared to the bulk.
This working hypothesis is confirmed by the dependence of the
L2| order as a function of resonance frequency [see Fig. 6(b)],
where a higher degree of L2\ order yields a higher frequency,
with the 84-nm film being the only exception. Please note that
a similar shift of the resonance line of Co2FeAl 0.5Si 0.5 films
in response to the degree of order has been shown by Inomata
et al. but is not commented [10]. Since our films always
have a higher degree of L2i-type order than the bulk, we
may conclude that the transformation to the higher-ordered
L2\ -type phase depends rather on kinetic than thermodynamic
control. This competition between thermodynamic and kinetic
control has a strong dependence on the film thickness, since
the ordering depends not only on the thermal history of a
given sample and hence on the substrate temperature (which
is constant and is 600 °C in all films), the cooling rate, but
also on the defect concentration and the length of the meanPHYSICAL REVIEW B 91, 064421 (2015)
free path, viz. the diffusion length of atoms during the ordering
process.
Additionally, if we plot the ratio between L2\ order and
Fe to Al/Si off stoichiometry [see Fig. 6(c)] as the function of
resonance frequency, we clearly see a monotonous shift of the
NMR frequency towards the mean value between Co2FeSi and
Co2FeAl, which further proves the scenario of the interplay
between strain, stoichiometry, and structural order.
IV. SUMMARY
We presented a detailed NMR analysis of the structural
and local magnetic properties of Co2FeAl0. 5Si0.5 films
with varying thickness. Our findings are classified into two
categories, (i) We confirm an off-axis sputtering growth
technique to yield Heusler films of high quality, which
may open the way to enhance the performance of Heusler
compounds in spintronic devices in general, if this technique
is established. We prove the quality of the films by detailed
NMR analysis of the film properties, (ii) We use the NMR
technique to disentangle different contributions to the film
quality, namely, film thickness, its impact on strain and local
anisotropy, stoichiometry, and degree of order.
ACKNOWLEDGMENTS
This work is supported by a Materials World Network grant
from the National Science Foundation (DMR-1107637) and
from Deutsche Forschungsgemeinschaft DFG (WU595/5-1).
Partial support is provided by the NanoSystems Laboratory
at the Ohio State University. S.W. gratefully acknowledges
funding by DFG in the Emmy Noether Program (Project
No. WU595/3-1). We thank P. Woodward and W. Loser for
discussion and C.G.F. Blum for help with the preparation of
the sputter targets.
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064421-7
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PhysRevB.81.125444.pdf | Response of nanoparticle structure to different types of surface environments:
Wide-angle x-ray scattering and molecular dynamics simulations
Hengzhong Zhang,1,*Bin Chen,1Yang Ren,2Glenn A. Waychunas,3and Jillian F. Banfield1,3
1Department of Earth and Planetary Science, University of California, Berkeley, California 94720, USA
2Advanced Photon Source, Argonne National Laboratory, Argonne, Illinois 60439, USA
3Earth Sciences Division, Lawrence Berkeley National Laboratory, Berkeley, California 94720, USA
/H20849Received 25 August 2009; revised manuscript received 22 February 2010; published 31 March 2010 /H20850
The structure of nanoparticles is nonstationary and changes in response to the surface environment where the
nanoparticles are situated. Nanoparticle-environment interaction determines the nature of the structure change,an important consideration for evaluating subsequent environmental impact. In this work, we used ZnS nano-particles to interact with surface environments that contain different inorganic salts, water, and organic mol-ecules. From analysis of the pair-distribution function /H20849PDF /H20850derived from wide-angle x-ray scattering experi-
ments, we found that a stronger surface interaction results in a thicker crystalline core and a thinner distortedshell, corresponding to PDF curves having larger peaks and more peaks at longer radial distances. Plane-waveelectronic calculations were used to quantify the interaction strength. An analogous atomic view of thenanoparticle-environmental interactions and structures was provided by molecular dynamics simulations. Theextent of response of the nanoparticle structure to various surface environments is used as a measure of theinteraction strength between them.
DOI: 10.1103/PhysRevB.81.125444 PACS number /H20849s/H20850: 61.46.Df, 61.05.cf, 02.70.Ns
I. INTRODUCTION
When coupled with surface ligands, nanoparticles can be
used to target cancer-specific receptors and other maliciouscells.
1–3Functionalized nanoparticles can be used as sensors
for detection of deoxyribonucleic acid targets and explosivematerials.
4–6Realization of these nanotechnologies relies on
detailed understanding of the nanoparticle structure as wellas the interactions between nanoparticles and the surround-ing molecules/ions. These interactions include several typesof electrostatic interactions /H20849ionic and dipole interactions /H20850,
covalent bonding, hydrogen bonding, and van der Waalsforces. Though atomic force microscopy can measure theforces between nanoparticles and solid surfaces/substrates,
7,8
it is difficult to characterize the details of the interactions
between nanoparticles and surface molecules and ions. Inparticular, the manner in which the nanoparticle structureresponds to the surface environments is yet to be explored. Inthis work, we used atomic pair-distribution function /H20849PDF /H20850
analysis to study the structural changes in ZnS nanoparticlesdue to interactions with different surface species. Molecularsimulations were carried out to validate the experimental re-sults and to provide an atomic view of the interaction pro-cesses. The approach developed in this work may be used toanalyze interaction strengths and effects in nanoparticles thatare difficult to measure using other methods. Both the newapproach and the acquired knowledge will be advantageousin the development of highly specific nanomaterials for ap-plications in nanomaterial-environment interactions, such asmedical/cosmetic products and environmental remediationmechanisms that utilize nanoparticles.
9,10
II. EXPERIMENTAL
A. Sample preparation
ZnS /H20849sphalerite /H20850nanoparticles with an average diameter
of/H110113 nm were synthesized in anhydrous methanol. A sus-pension of 0.09 M ZnS nanoparticles in methanol was pre-
pared by reacting anhydrous zinc chloride /H20849ZnCl 2/H20850and so-
dium sulfide /H20849Na2S/H20850in anhydrous methanol, followed by
purification and redispersion in methanol.11For interactions
with ZnS nanoparticles, ionic salts /H20849sodium chloride NaCl,
calcium chloride CaCl 2, and sodium sulfate Na 2SO4/H20850and
molecules having different structures /H20849water H 2O, methanol
CH 3OH, thiophenol C 6H6S, and chlorobenzene C 6H5Cl/H20850
were used as the surface species.
Specific concentrations of different surface species were
added to the as-synthesized nano-ZnS suspensions, produc-ing methanol suspensions of 0.07 M ZnS+13.9 MH
2O, 0.06 M ZnS+3.3 M C 6H5Cl, 0.06 M ZnS+3.3 M
C6H6S, 0.09 M ZnS+0.03 M NaCl, 0.09 M ZnS
+0.015 M CaCl 2, and 0.09 M ZnS+0.015 M Na 2SO4.
The new suspensions equilibrated for /H1101124 h before per-
forming wide-angle x-ray scattering /H20849WAXS /H20850measurements.
B. X-ray diffraction
X-ray diffraction /H20849XRD /H20850was used to identify the phase of
the synthesized ZnS and to estimate the crystallite size. XRDspecimens were prepared by dispersing a thin layer of thenano-ZnS sample in methanol on to a low-scattering back-ground silicon plate which were then allowed to dry natu-rally. The plate was loaded immediately into the sampleholder of an x-ray diffractometer /H20849PANalytical X’Pert PRO /H20850
operated at 40 kV and 40 mA with a Co K
/H9251radiation x-ray
source /H20849wavelength 1.7903 Å /H20850. The XRD pattern was col-
lected at room temperature in the 2 /H9258range of 20° –80° with
a scanning rate of 1 ° /min.
C. Wide angle x-ray scattering
WAXS measurements were performed at room tempera-
ture at the high-energy beamline station 11-ID-C, AdvancedPHYSICAL REVIEW B 81, 125444 /H208492010 /H20850
1098-0121/2010/81 /H2084912/H20850/125444 /H208496/H20850 ©2010 The American Physical Society 125444-1Photon Source, Argonne National Laboratory /H20849USA /H20850, with an
x-ray wavelength of 0.10770 Å and a sample-to-camera dis-tance of /H11011272 mm. The exact distance was calibrated using
a CeO
2standard. Small volumes of the ZnS suspensions
/H20849containing different concentrations of surface species /H20850were
encapsulated in 1.5 mm diameter quartz capillary tubes.These tubes were then put into a capillary tube sample holderfor the WAXS experiments. WAXS patterns were acquired atroom temperature, with a q/H20849scattering vector /H20850range of
0.3–30 Å
−1, and a step size of 0.01 Å−1. The WAXS signal
was captured by an image plate detector. The WAXS patternsof several identical capillary tubes filled with methanol andvarious surface species /H20849without ZnS nanoparticles /H20850were ac-
quired for background subtraction from the sample patterns.
III. COMPUTATIONAL
A. Electronic structure calculations
To gain insight into the nature of the interactions /H20849such as
binding energy, bond length, and electron sharing /H20850,w ed i d
first-principle calculations of the interactions between onemolecular unit of surface species and a bulk ZnS /H20849100 /H20850sur-
face. The electronic-structure calculations were carried outusing the
CPMD package,12employing a plane-wave basis
/H20849energy cutoff=80 AU /H20850 with Troullier-Martins
pseudopotentials13and a local-density approximation ex-
change correlation using the high accuracy Padéapproximation.
14A periodic slab of ZnS /H20849/H1101111/H1100311
/H1100311 Å3, 32 ZnS molecular units /H20850with a CPMD geometri-
cally optimized /H20849100 /H20850surface was used as the basis for inter-
action with one molecular unit of NaCl, Na 2SO4,H 2O,
C6H6S, C 6H5Cl, and CH 3OH, respectively. Initial setup for a
surface species interacting with the ZnS /H20849100 /H20850surface for the
CPMD electronic calculation was obtained from a classical
molecular dynamics /H20849MD /H20850simulation performed using the
Forcite module of MATERIALS STUDIO 4.0 .15In a CPMD geo-
metric optimization, atoms of the interacting surface specieswere allowed to move in any direction. The coordinates ofatoms of the surface species interacting with the ZnS surfacewere optimized and the energy of the system was minimizedusing standard criteria /H20851convergence of both orbital /H20849energy
and gradient /H20850and geometry to within certain preset
variations /H20852.
12
B. Molecular dynamics simulations
In order to correlate the ZnS nanoparticle structure and
the strength of the interaction with surface species, we per-formed MD simulations of three representative systems,nano-ZnS in vacuum /H20849to approximate methanol, see Sec.
IV E below /H20850, nano-ZnS interacting with water, and nano-ZnS
interacting with Na
+/Cl−. MD simulations o fa3n mZ n S
/H20849sphalerite /H20850particle in vacuum and with adsorption of differ-
ent numbers of water molecules have been done previously.16
MD simulation of adsorption of Na+/Cl−ions ont oa3n m
ZnS nanoparticle was performed using the code DL_POLY
/H20849Ref. 17/H20850in this work. A shell model with Buckingham-type
interatomic potential functions was used to describe the ZnSstructure.
18Using the shell model, a Zn or S atom is treatedas a core and a massless /H20849or, very light /H20850shell that are con-
nected by a spring, accounting for ionic polarity inducedunder a local electric field. The Zn and S atoms have theelectrical charges of +2 and −2, respectively. The short-rangevan der Walls interaction between two atoms iandjtakes a
Buckingham form,
u
ij/H20849short range /H20850=Aijexp/H20873−Rij
/H9267ij/H20874−Cij
Rij6, /H208491/H20850
where uijis the interaction potential, Rijthe distance between
atoms iand j, and Aij,/H9267ij, and Cijare three model param-
eters. An angle-bending form of three-body interactions isconsidered for nearest S-Zn-S atoms,
u
ijk=1
2kijk/H20849/H9258−/H9258ijk/H208502, /H208492/H20850
where uijkis the interaction potential, kijka model parameter,
/H9258the angle formed by atoms i/H20849S/H20850,j/H20849Zn, center /H20850andk/H20849S/H20850,
and/H9258ijkthe equilibrium value of the angle /H20849109.4° /H20850.
The interatomic interactions in NaCl were described by
the Born-Huggins-Mayer potential functions, which has thesame form as Eq. /H208491/H20850but with an additional term of
−D
ij//H20849Rij/H208508/H20849Dijis a model parameter /H20850.19For detailed values
of the model parameters for ZnS and NaCl, the readers arereferred to Refs. 18and19. Suitable potential functions for
the interaction between ZnS and NaCl are not available fromthe literature. Thus, we developed interatomic potential func-tions for the NaCl-ZnS system as described below /H20849Sec.
IV D /H20850.
In the MD simulation, 24 Na
+/Cl−ions /H20849to simulate the
low concentration of NaCl due to the low solubility inmethanol in the experiment /H20850were placed over the surface
/H20849with a initial distance of /H110113 Å between them /H20850o fa3n m
ZnS nanoparticle constructed from the bulk structure ofsphalerite. The MD simulation was carried out at 300 K for aMD time of 20 ps with a step of 10
−5ps first and then for
another 60 ps with a step of 10−4ps. Potential-energy evo-
lution showed that after /H1101145 ps, the system has converged
to a steady state.
IV. RESULTS AND DISCUSSION
A. Sample characterization
Inspection of the XRD pattern /H20849Fig. 1/H20850shows that the
as-synthesized ZnS is nanosphalerite with very broad diffrac-tion peaks. The XRD line profile was analyzed using a nu-merical method
20for separation of the overlapping sphalerite
/H20849111 /H20850,/H20849200 /H20850,/H20849220 /H20850, and /H20849311 /H20850peaks which show significant
broadening at the nanoscale size. The Scherrer size21of the
nano-ZnS was estimated to be /H110111.5 nm in diameter using
the full width at the half maximum of the /H20849111 /H20850peak /H20849with a
Scherrer constant of 0.90 /H20850. This size corresponds to the crys-
talline core of the ZnS nanoparticles while the physical di-ameter determined by transmission electron microscopy andUV-vis spectroscopy was /H110113 nm.
11These values show that
the as-synthesized ZnS nanoparticles are highly distortedcore-shell structures with a weakly diffracting surface layer/H110110.75 nm in thickness.ZHANG et al. PHYSICAL REVIEW B 81, 125444 /H208492010 /H20850
125444-2B. PDF analysis
PDF analysis has been used to study structures of nano-
materials, including metals /H20849e.g., nano-Au /H20850, semiconductors
/H20849e.g., nano-CdSe /H20850, metal sulfides /H20849e.g., nano-MoS 2/H20850, and
metal oxides /H20849e.g., nano-TiO 2/H20850, as reviewed in Refs. 22–24.
However, systematic study of environmental response ofnanoparticle structure using PDF analysis was not reportedpreviously.
In this work, the PDFs of ZnS nanoparticles upon inter-
action with various surface species were derived from theWAXS data. First, structure factors of the nanoparticles werederived from the WAXS patterns after data reduction.
25
Then, the PDFs, or G/H20849r/H20850functions, were obtained through
Fourier transform of the structure factors S/H20849q/H20850,25
G/H20849r/H20850=2
/H9266/H20885
0/H11009
q/H20851S/H20849q/H20850−1/H20852sin/H20849qr/H20850dq. /H208493/H20850
PDF patterns reflect the atomic correlations in a material.
The theoretical PDF of a bulk crystalline material consists ofa series of peaks extending to arbitrarily large radial distance.Experimental PDF peaks are damped with increasing radialdistance because of limited experimental resolution /H20849for
beamline 11-ID-C at APS, this is at a radial distance of/H110117n m /H20850or because the particles themselves have dimen-
sions smaller than the resolution limit. For our ZnS nanopar-ticles interacting with various surface ligands, we observedenhanced damping at radial distances smaller than the nano-particle diameter /H20849Fig.2/H20850, which indicates that the outer parts
of the nanoparticles have less-crystalline character than thecores. This must be due to structural distortion of the tetra-hedral coordination of Zn or S atoms near the surface.
11,26As
there is a correspondence between different ligand type andthe degree of PDF damping, we theorize that the structuraldistortion /H20849Fig.2/H20850is specific to the surface ligand and hence
the nanoparticle environment. We now quantify how theligand-surface interaction induces this structural disorder.The PDF curves in Fig. 2can be classified into three
groups. In group I, there are PDF patterns characterized by afew small peaks at r/H11021/H110118 Å. The relative magnitude of the
second broad peak /H20849r/H110113.74–3.77 Å /H20850is lower than or com-
parable to that of the first peak /H20849r/H110112.33 Å, the average Zn-S
bond length /H20850. This is the case for nano-ZnS in methanol and
methanol+chlorobenzene. In group II, the PDF peaks arelarger and more numerous than in group one /H20849rextends to
/H1101114 Å /H20850. The relative magnitude of the second broad peak
/H20849r/H110113.76–3.80 Å /H20850is higher than that of the first peak
/H20849r/H110112.33 Å /H20850. In this category are patterns from nano-ZnS in
methanol+water and methanol+thiophenol. In group III, thePDF patterns contain many medium to large PDF peaks atr/H11021/H1101110 Å /H20849beyond which the minor peaks are noises from
data reduction /H20850. This group includes nano-ZnS in methanol
+dilute inorganic salts /H20849NaCl, CaCl
2, and Na 2SO4/H20850. The rela-
tive magnitude of the second broad peak /H20849r
/H110113.72–3.76 Å /H20850varied from almost comparable to higher
than that of the first peak /H20849r/H110112.33 Å /H20850. Compared to group I,
the peaks in /H110115.5–7.5 Å are more significant in this group
even though the salt concentrations are much lower thanthose of methanol and chlorobenzene in group I.
The unequal structural responses /H20849as shown by the PDF
curves in Fig. 2/H20850of the ZnS nanoparticles to different surface
species are expected to be determined by the interactionstrength between the nanoparticles and the surface species.Results from the plane-wave electronic structure calculations/H20849below /H20850are used to determine the binding strength of the
surface species and to correlate these with the different in-duced PDF characters.
C. Nature of surface binding by plane-wave electronic
calculations
Table Isummarizes results from the electronic-structure
calculations. Results show that surface species interact withZnS /H20849100 /H20850surfaces mainly via interactions between their
high-electronegativity atoms /H20849O, Cl, and S /H20850and the Zn atoms111
200
0100200300400500600700
30 40 50 60 70
2θθθθ(degree)Intensity ( CPS)
fitted220 311
FIG. 1. XRD pattern /H20849dots /H20850of nano-ZnS synthesized in metha-
nol. Overlapping sphalerite /H20849111 /H20850,/H20849200 /H20850,/H20849220 /H20850, and /H20849311 /H20850peaks
were separated /H20849lines /H20850using a numerical decomposition method
/H20849Ref. 20/H20850for estimation of the crystalline core size.2 4 6 8 10 12 14
r(Å)G
D: + 3. 3 M C 6H6S
C: + 13. 9 M H 2OG: + 0. 03 M NaCl
F: + 0. 015 M CaCl 2
E: + 0. 015 M Na 2SO4
B: + 3. 3 M C 6H5Cl
A: in CH 3OHIIIIII
FIG. 2. Atomic pair-distribution function /H20849G/H20850of/H110113 nm ZnS
nanoparticles /H208490.06–0.09 M ZnS /H20850suspended in methanol /H20849A/H20850and
methanol plus various surface species /H20849B–G /H20850. Group I represents
surface species with weak interactions with nanoparticles, group IIwith enhanced interactions, and group III with strong interactions.RESPONSE OF NANOPARTICLE STRUCTURE TO … PHYSICAL REVIEW B 81, 125444 /H208492010 /H20850
125444-3on the ZnS surface /H20849Fig. 3/H20850. The equilibrium distance be-
tween the interacting atoms is one indication of the strengthof the interaction between the surface species and the ZnSsurface. A shorter distance usually corresponds to a strongerinteraction as the latter usually corresponds to a higher de-gree of electron sharing and hence a shortening of the inter-nucleus distance. The binding energy represents the energyreleased when a surface species is adsorbed on the ZnS sur-face. In general, the higher the binding energy, the greaterthe structural interaction between the surface species and theZnS surface.
Table Ishows that ionic salts, water and thiophenol, and
methanol have binding energies of /H11011125–135 kJ /mol,
67–90 kJ/mol, and 37 kJ/mol, respectively. These ranges cor-respond to the different sets of PDF profiles we measured/H20849Fig.2/H20850. For the ionic salts we expect strong binding and thus
most surface Zn species is bonded with strengths similar tothe underlying Zn-S bonding. A crystal-chemical analysis,e.g., using the Pauling bond valence principle, would holdthat these Zn ions are largely valence satisfied. In contrast,for methanol we have weak surface binding, leading to un-satisfied valence contributions on the uppermost Zn ions,which creates structure distortion due to changes in the Zn-Sbonding network. For chlorobenzene, though the binding en-
ergy is close to those of water and thiophenol, the equilib-rium distance between the interacting atoms/H20849Cl-Zn:2.869 Å /H20850is longer than those of the latter two
/H20849O-Zn:2.140 Å; S-Zn:2.446 Å /H20850. This would decrease the
electron sharing between the ZnS surface and chlorobenzeneand thus lead to an effect similar to that of methanol on thestructure of ZnS. Finally, water and thiophenol represent anintermediate case, with intermediate strength binding, andintermediate size structural distortion. The effects of thesestrained/distorted surface layers propagate into the nanopar-ticle interior, causing remarkably distinct PDF characteris-tics. Molecular dynamics simulations of representative sys-tems provide more details of these structural changes/H20849below /H20850.
D. Development of ZnS-NaCl interatomic potential functions
For MD simulation of the interaction between ZnS-NaCl,
we developed a set of potential functions by fitting to theinteraction energies calculated using the electronic code
CPMD /H20849see Sec. III A and Fig. 4/H20850. We found that the Morse
potential function /H20851Eq. /H208494/H20850/H20852describes well the pairwise
atomic interactions in the ZnS-NaCl system,
E/H20849r/H20850=a⌊/H208531 − exp /H20851−b/H20849r−c/H20850/H20852/H208542−1 ⌋, /H208494/H20850
where Eis the interaction energy, ris the interatomic dis-
tance, and a,b, and care adjustable model parameters. Pa-
rameter crepresents the equilibrium distance between the
atoms in a diatomic cluster.
The calculations used the interaction geometry shown in
Fig.4/H20849a/H20850. For the NaCl-ZnS interaction, there are four atomic
pairs /H20849Na-S, Na-Zn, S-Cl, and Zn-Cl /H20850and hence there are
4/H110033=12 Morse potential parameters. Simultaneous deter-
mination of the 12 parameters could not be achieved from asingle fitting of the Morse potential functions to the calcu-lated interaction energies due to the many number of un-known parameters. Thus, as a first step, the three Morse po-tential parameters /H20849a,b, and c/H20850were derived for an isolated
diatomic cluster /H20849Na-S, Na-Zn, S-Cl, or Zn-Cl /H20850by fitting Eq.TABLE I. First-principle calculated binding energies of surface
species interacting with ZnS /H20849100 /H20850surface.
Surface
speciesMajor interacting
atomic pairaInteratomic distance
/H20849Å/H20850Binding energy
/H20849kJ/mol species /H20850
Na2SO4 O-Zn 2.083 134.7
NaCl Cl-Zn 2.332 124.7C
6H6S S-Zn 2.446 89.8
H2O O-Zn 2.140 66.7
C6H5Cl Cl-Zn 2.869 78.5
CH3OH O-Zn 2.963 36.8
aThe atomic pair with the shortest distance between the atoms of the
surface species and the ZnS /H20849100 /H20850surface.
S ZnClNaO
H SNaO
SHCCl CH HC ONaCl Na2SO4 H2O
C6H6SC6H5Cl CH3OHSS
SSSZnZn
Zn ZnZn2.332ÅZnS(100)2.083Å2.140Å
2.446Å 2.869Å2.963ÅZnS(100)
FIG. 3. /H20849Color online /H20850Optimized configurations of surface spe-
cies interacting with a ZnS /H20849100 /H20850surface. Dotted networks are the
charge-density isosurfaces of the valence electrons at density valueswhen the isosurfaces of the major interacting atoms /H20849shown in ball-
and-stick model /H20850begin to overlap.
z
∆z=0
ZnS(100)Cl Na
S
Zn2.73Å1.89Å2.56Å
-2024681012
- 1 0123 4
∆∆∆∆z(Å)Interaction energy (eV)CPMD
fitted
(b) (a)
FIG. 4. /H20849Color online /H20850Interaction between a ZnS /H20849100 /H20850surface
and a NaCl cluster. /H20849a/H20850Structure setup for the calculation of the
interaction energy. /H20849b/H20850The interaction energy as a function of the
ZnS /H20849100 /H20850-NaCl separation. Circles are from CPMD electronic cal-
culations and diamonds from fitting using Morse potential functions/H20851refer Eq. /H208494/H20850and Table II/H20850.ZHANG et al. PHYSICAL REVIEW B 81, 125444 /H208492010 /H20850
125444-4/H208494/H20850to the interaction energy of the diatomic cluster /H20849calcu-
lated using CPMD separately /H20850as a function of the atomic
separation. Here, the interaction energy is the energy changeby bringing two ions /H20849e.g., Na
+and Cl−/H20850from infinitely far
away to a designated distance. The obtained parameters arelisted in Table II.
We then used the following method to get the Morse po-
tential parameters for the ZnS-NaCl system. As a first ap-proximation, it was assumed that the three parameters /H20849a,b,
andc/H20850of the ZnS-NaCl system are proportional to the cor-
responding ones, respectively, of the diatomic clusters. Theproportional coefficients then were optimized such that thedifferences between the interaction energies calculated fromthe Morse potential functions and the energies calculated us-ing
CPMD became minimal for the ZnS /H20849100 /H20850-NaCl cluster
system /H20851Fig.4/H20849b/H20850/H20852. Here, the interaction energy is the energy
change by bringing a NaCl cluster to the ZnS /H20849100 /H20850surface
from infinitely far away to a designated distance. The derivedparameters are listed in Table II. One notes that the equilib-
rium distances care similar in both the diatomic cluster and
the ZnS-NaCl system. The derived parameters /H20849Table II/H20850
were used for the MD simulation of the interaction betweenNaCl an da3n mZ n S particle.
E. Insight from molecular dynamics simulations
Because the binding energy of methanol on a ZnS surface
is low /H20849Table I/H20850, the interaction between methanol and ZnS
nanoparticles is weak. The weak interaction can be approxi-mated by the MD simulation of a 3 nm ZnS particle invacuum.
16The binding energy of water on a ZnS surface islarger than that of methanol /H20849Table I/H20850. Hence, the interaction
between water and ZnS nanoparticles is stronger and can bestudied with MD simulations using sufficient water mol-ecules /H20849e.g., 362 H
2O/H20850to saturate sorption sites o na3n m
ZnS particle.16The MD simulation of the stronger interaction
o fa3n mZ n S particle with 24 Na+/Cl−ions was similarly
performed in this work /H20849see Sec. III B /H20850.
Figure 5shows /H20849a/H20850snapshots of the MD structures of a 3
nm ZnS particle in vacuum, /H20849b/H20850after adsorption of 362 H 2O
molecules, and /H20849c/H20850after adsorption of 24 Na+/Cl−ions. Fig-
ure6shows the comparisons between the PDF curves calcu-
lated from the MD structures /H20849Fig. 5/H20850with those from the
WAXS determinations /H20849Fig.2/H20850. Results show that the calcu-
lated PDF are in good agreement with the experimental PDF.This indicates that the MD simulations can generate atomicstructures that are consistent with the WAXS experiments.
Figure 5/H20849a/H20850shows that the 3 nm ZnS nanoparticle in
vacuum has a highly distorted shell and a small crystallinecore /H20849/H110111.6 nm in diameter /H20850. The core size is close to that
/H20849/H110111.5 nm /H20850estimated from XRD determination for the as-
synthesized ZnS nanoparticles in methanol. In contrast, the 3nm ZnS nanoparticle after adsorption of water molecules/H20851Fig.5/H20849b/H20850/H20852is more crystalline due to the strong binding of
water molecules /H20849energy change due to adsorption of water isTABLE II. Morse potential parameters.
Atomic pairFor diatomic cluster For ZnS /H20849100 /H20850-NaCl cluster
a
/H20849eV/H20850b
/H20849Å−1/H20850c
/H20849Å/H20850a
/H20849eV/H20850b
/H20849Å−1/H20850c
/H20849Å/H20850
Na-S 2.0444 1.2145 2.3899 0.4197 1.7098 2.4820
Na-Zn 0.2443 1.2617 2.9917 0.0502 1.7764 3.1071S-Cl 4.7858 1.4652 2.0511 0.9826 2.0627 2.1301Zn-Cl 3.8863 1.2503 2.2823 0.7979 1.7602 2.3703
(a)( c) (b)
FIG. 5. /H20849Color /H20850Snapshots of the equilibrated structures of a 3
nm ZnS /H20849sphalerite /H20850particle in molecular dynamics simulations. /H20849a/H20850
MD in vacuum. /H20849b/H20850MD of nano-ZnS with adsorption of 362 H 2O
molecules. /H20849c/H20850MD of nano-ZnS with adsorption of 24 Na+and 24
Cl−ions. Zn: gray; S: dark yellow; O: red; H: light gray; Na: blue;
and Cl: green.2 4 6 8 10 12 14
r(Å)G
B: + 13. 9 M H 2OC: + 0. 03 M NaCl
A: in CH 3OH
FIG. 6. Comparisons between experimental /H20849thin lines /H20850and cal-
culated PDF /H20849thick lines /H20850of/H110113 nm ZnS nanoparticles suspended
in methanol /H20849A/H20850, methanol plus water /H20849B/H20850, and methanol plus NaCl
/H20849C/H20850. The experimental data are from WAXS determinations and the
calculated data are from molecular dynamics simulations.RESPONSE OF NANOPARTICLE STRUCTURE TO … PHYSICAL REVIEW B 81, 125444 /H208492010 /H20850
125444-5182 kJ/mol H 2O/H20850and the full coverage of the surface by
water molecules. The average Zn-O bond length is 1.988 Å.The 3 nm ZnS nanoparticle after adsorption of 24 Na
+/Cl−
ions /H20851Fig.5/H20849c/H20850/H20852is also more crystalline than that in vacuum
due to the even stronger binding of the ions on the ZnSnanoparticle /H20849energy change due to adsorption of NaCl is
346 kJ/mol NaCl /H20850despite the low number of bound ions. The
average Zn-Cl bond length is 2.353 Å and the average Na-Sbond length is 2.600 Å.
The MD simulation results show that stronger surface
binding and more surface coverage by surface species canlargely compensate for the disruption of the periodic struc-ture of the ZnS nanoparticles at the surfaces. This results in amore crystalline nanostructure and hence more well definedand larger R peaks in the PDF.
V. CONCLUSIONS
In this study, we demonstrate that the distortion and core-
shell structures of nanoparticles in various chemical environ-ments are determined largely by surface interactions, andthat the structural responses to different surroundings can be
analyzed by PDFs obtained using high-energy WAXS meth-ods. More and larger PDF peaks at longer radial distancesare indicative of stronger surface interactions, as confirmedby first-principle calculations and molecular dynamics simu-lations. PDF analysis is a sensitive probe of these structuralchanges, and hence is a general method for the identificationand characterization of nanoparticle-surface environment in-teractions.
ACKNOWLEDGMENTS
We thank B. Gilbert for helpful discussions. Use of the
Advanced Photon Source is supported by the U.S. Depart-ment of Energy, Office of Science, under Contract No. DE-AC02-06CH11357. Computations were carried out in theGeochemistry Computer Cluster, Lawrence Berkeley Na-tional Laboratory. Financial support was provided by theU.S. Department of Energy /H20849Grant No. DE-FG03-
01ER15218 /H20850and the National Science Foundation /H20849Grant
No. EAR-0123967 /H20850.
*Corresponding author; heng@eps.berkeley.edu
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125444-6 |
PhysRevB.93.054411.pdf | PHYSICAL REVIEW B 93, 054411 (2016)
Two-body problem of core-region coupled magnetic vortex stacks
Max H ¨anze,1,*Christian F. Adolff,1Sven Velten,1Markus Weigand,2and Guido Meier3,4
1Institut f ¨ur Angewandte Physik und Zentrum f ¨ur Mikrostrukturforschung, Universit ¨at Hamburg, 20355 Hamburg, Germany
2Max-Planck-Institute for Intelligent Systems, Stuttgart, Germany
3The Hamburg Centre for Ultrafast Imaging, Luruper Chaussee 149, 22761 Hamburg, Germany
4Max-Planck Institute for the Structure and Dynamics of Matter, Luruper Chaussee 149, 22761 Hamburg, Germany
(Received 4 August 2015; revised manuscript received 26 January 2016; published 9 February 2016)
The dynamics of all four combinations of possible polarity and circularity states in a stack of two vortices
is investigated by time-resolved scanning transmission x-ray microscopy. The vortex stacks are excited byunidirectional magnetic fields leading to a collective oscillation. Four different modes are observed that dependon the relative polarizations and circularities of the stacks. They are excited to a driven oscillation. We observe arepulsive and attractive interaction of the vortex cores depending on their relative polarizations. The nonlinearityof this core interaction results in different trajectories that describe a two-body problem.
DOI: 10.1103/PhysRevB.93.054411
I. INTRODUCTION
Magnetic structures found in thin ferromagnetic layers
[1,2], such as magnetic bubbles [ 3], domain walls [ 4],
skyrmions [ 5], and vortices [ 6], have been studied intensively
over the past few decades. Their characteristic magnetizationstructures result from the minimization of different energycontributions. For instance, the formation of magnetic bubblesoriginates from a uniaxial anisotropy determined by the ferro-magnetic layer. Magnetic skyrmions are commonly stabilizedin the presence of external magnetic fields and an asymmetryin the boundary layers that leads to the Dzyaloshinskii-Moriyainteraction [ 5]. Magnetic vortices emerge when the geometry
of the ferromagnet is confined to dimensions on the micrometerscale [ 7], e.g., in micron-sized disks. Here, stray fields at the
edges of the structures are minimized. The magnetic vortexconstitutes a magnetization circulating in the plane aroundthe center position of the disk where it points out of plane.The sense of circulation ccan be either clockwise or counter-
clockwise ( c=±1), whereas the out-of-plane component of
the center region points either up or down (polarization p=
±1). Due to the four possible states, vortices are promising
candidates for applications in potential storage devices [ 8,9].
In order to realize a storage device with a high storage densityone needs to incorporate many vortices in a finite volume.Since neighboring vortices couple due to stray fields emergingat the surfaces of the ferromagnetic elements [ 10], the motions
of closely packed vortices are strongly influenced by theirsurrounding ferromagnetic structures [ 11,12]. The interaction
between laterally arranged elements has been studied forpairs [ 13,14], chains [ 15], and two-dimensional arrangements
[16–18] of vortices. In laterally coupled arrangements it has
been shown recently that memorylike writing processes arepossible based on the excitation of the gyrotropic mode [ 19],
where bits are stored as polarization patterns. The gyrotropicmode corresponds to a gyration of the vortex core aroundthe center of the disk and can be compared to the oscillationof a harmonic oscillator [ 20]. Even for closely packed two-
dimensional arrays of vortices, the storage density is expected
*max.haenze@physnet.uni-hamburg.deto be below that of conventional storage devices [ 21]. We
introduce an additional dimension to the collective gyrationsof vortices known from spin-torque oscillators [ 22]. Stacking
the vortices allows for a strongly increased packing densityand has thus stimulated recent studies [ 23–30]. While for
two-dimensional arrangements the minimization of the strayfields at the side surfaces creates the vortices and mediatestheir interaction, we observe a second coupling mechanism forthree-dimensional stacks that has been investigated theoreti-cally [ 26,31,32]. Due to core coupling the collective motions
in an elementary stack of two vortices become a two-bodyproblem.
Here, we study the vortex core motions emerging in a stack
of magnetic vortices depicted in Fig. 1using time-resolved
scanning transmission x-ray microscopy. In the first step weexcite the vortices by a short magnetic field pulse leading toa collective motion of the core regions. Both vortex cores areimaged along their damped oscillation. We observe a strongdependence of the resonance frequency and the trajectoriesof the gyration on the relative circulations and polaritieswithin the stack. In the second step we excite the differentnondegenerate states close to their resonance frequency.Stationary trajectories are observed that are comparable tomotions of the gravitational two-body problem. This effectoriginates in the proximity of the vortex core regions withinthe stack. Calculations elucidate their functional dependence.
II. SAMPLE PREPARATION AND METHODS
Figure 1(a) depicts schematics of the measurement setup
and x-ray measurements of the investigated stack of vortices.Magnetic contrast is provided via the x-ray magnetic circulardichroism (XMCD) at the Ni L
3-absorption edge (852.7 eV).
The spatial resolution with the zone plate used in the presentexperiment is 25 nm. The maximum temporal resolutionis 40 ps. Stacks of polycrystalline permalloy (Ni
80Fe20)
disks separated by an interlayer of silicon are prepared withelectron-beam lithography, in situ thermal evaporation of
permalloy/silicon/permalloy layers, and liftoff processing ona 100-nm-thick silicon nitride membrane. The disks have adiameter of 1 μm and a thickness of 40 nm. The silicon
spacer has a thickness of 20 nm. A coplanar waveguide is
2469-9950/2016/93(5)/054411(6) 054411-1 ©2016 American Physical SocietyH¨ANZE, ADOLFF, VELTEN, WEIGAND, AND MEIER PHYSICAL REVIEW B 93, 054411 (2016)
100 nm
200 nm(a) (b)
j
H
detectorx-ray photons
c1c2 = 1 c1c2 = -1(c)1μm
FIG. 1. (a) Schematics of the measurement setup along with scanning electron micrographs of the investigated ferromagnetic
microstructures. The subset depicts micrographs of the vortex stacks with in-plane magnetic contrast using scanning transmission x-raymicroscopy. The stray fields emerging (b) at the side surfaces and (c) the center regions of the ferromagnets are obtained from micromagnetic
simulations.
deposited on top of the stacks via thermal evaporation of
250 nm of copper and a protection layer of 5 nm of gold.A sinusoidal current is driven through the signal line of thecoplanar waveguide, leading to an alternating magnetic fieldon the order of several tenths of a millitesla acting in the planeof the ferromagnetic elements. The provided in-plane magneticcontrast of the microscope yields the relative configuration ofthe circulations. Here, the sample is tilted by 60
◦relative to the
incident x-ray beam. As shown in the inset we observe bothpossible combinations ( c
1c2=1 and c1c2=−1), indicating
that the silicon spacer decreases interlayer exchange couplingbetween the vortices. For interlayer exchange-coupled vorticesonly one state would occur [ 33]. Stray fields at the side
surfaces of the disks emerge when the vortices are deflected
from their equilibrium position indicated in Fig. 1(b).I n
addition, the vortex core regions exhibit a coupling due tothe out-of-plane component of the magnetization [Fig. 1(c)].
Both interaction effects are crucial to understand the collectivebehavior in a stack of vortices. Here, only the stray fieldsfor equal circulations ( c
1c2=1) of the vortices are depicted.
They have been obtained from micromagnetic simulations ofthe investigated structures as described in the last part of thiswork.
III. EXPERIMENTS
In principle two coupled oscillators have two eigenmodes
that describe all possible motions of the system. For stacksof magnetic vortices both modes have been observed inspin-torque oscillators [ 22]. In the experiments the dynamic
behavior of a stack of vortices is investigated using a shortmagnetic field pulse (1 ns, 3 mT) pointing in the ydirection.
The field pulse allows for the excitation of only one of thetwo modes [ 17]. The different circularities and polarities in
the stacks then yield different frequencies and motions of the
one excited mode. Due to symmetry considerations there are
four possible nondegenerate states. All four combinations ofthe relative circulations and polarizations are imaged usingout-of-plane magnetic contrast. Here, the sample is tilted by90
◦relative to the incident x-ray beam. The trajectories of the
core regions are shown in Fig. 2(a)and can be found as a movie
in the Supplemental Material [ 34]. While for static magnetic
fields the deflection depends only on the circularity, the initialdeflection due to a nanosecond magnetic field pulse dependson the handedness ( cp=±1) of the isolated magnetic vortex
[35]. Subsequent to the initial deflection the vortex performs
a damped gyration around the center of the disk, where thesense of gyration is determined by the polarity pof the
core. Isolated vortices with a positive polarity ( p=1) gyrate
counterclockwise, while vortices with a negative core polaritygyrate ( p=−1) clockwise. The oscillation frequency of the
isolated vortex is 240 MHz for the investigated structures. Inthe stack the external field pulse individually deflects bothvortices depending on their handedness. Thus, two identical
vortex states ( p
1p2=1,c1c2=1) are deflected in identical
directions and gyrate on equal trajectories after the fieldpulse. Due to the additive contrast of the two structures, thedifferent vortex cores cannot be distinguished in this case.Changing the circularity of one of the vortices results inopposite initial deflections yielding different trajectories ofthe vortex cores. The two vortex cores have the same senseof gyration. They gyrate around a common barycenter untilthey reach their equilibrium position and merge into a singleblack dot due to their direct superposition. This motion hasalso been described theoretically [ 23,31]. For both circularity
combinations the frequency of gyration is approximately410 MHz. It is comparable to the frequency of an isolated
disk with the combined thickness of the stacked vortices. The
frequencies have been obtained by the sum of the Fouriertransforms of the two vortex core motions in the stack. Theyare depicted in Fig. 2(b). In the next step, the relative polarities
of the vortex stacks are changed from equal ( p
1p2=1) to
opposite ( p1p2=−1) polarizations using self-organized state
formation [ 19,36,37]. Thereby, the remaining nondegenerate
states of opposite polarization are accessible. Two isolatedvortices with opposite polarizations have a different sense ofgyration that is also observed within the stack. The collectivemotions have a lower frequency of about 175 MHz compared
054411-2TWO-BODY PROBLEM OF CORE-REGION COUPLED . . . PHYSICAL REVIEW B 93, 054411 (2016)p1p2 = 1 p1p2 = -1
c1c2 = - 1 c1c2 = 1(a)
(b)
100 nm
0101
500 300 100
frequency (MHz)xyFFT mag. (arb. u.)12p p = 1 p1p2 = -1
c1c2 = 1 c1c2 = -1
12p p = 1 p1p2 = -1
FIG. 2. (a) Collective trajectories of the vortex cores within the
stack, indicated by red and blue lines. The out-of-plane component
of each magnetic vortex is either black ( p=−1) or white ( p=1).
It is obtained from the out-of-plane measurements. The vortices areexcited by a short magnetic field pulse pointing in the ydirection.
The motions depend on the indicated combination of the relative
circulations and polarizations. (b) Sum of the Fourier transform ofthe two vortex core motions subsequent to a short magnetic field
pulse. The relative circulations are indicated by dashed ( c
1c2=1)
and solid ( c1c2=−1) lines. The relative polarizations are depicted
in black ( p1p2=1) and gray ( p1p2=−1).
to the resonance frequency of the isolated disks (240 MHz).
When the vortex cores approach each other, we observe aslight evasion that is attributed to the repulsion of the coreregions. The two different relative polarities ( p
1p2=±1)
have a strong influence on the resonances of the oscillations.The relative circulations yield slight variations. For the caseof opposite polarities and equal circularities ( p
1p2=−1,
c1c2=1) a splitting of the resonances can be observed. It
could be attributed to a change in the oscillation regime fromlarge to small vortex core trajectories. This mode splitting canbe observed for a critical core distance of about 50 nm in the
movie (at 52 ns) in the Supplemental Material [ 34]. Since the
distance between the cores decreases over time, the influenceof the core interaction increases. Further measurements of thesteady-state motions elucidate this dependence.
The vortex stacks are excited near resonance by a sinusoidal
magnetic field. Two different frequencies of 175 and 410 MHzfor the two relative polarizations ( p
1p2=±1) are used.
Figure 3(a) illustrates the motions of the vortex cores for all(b)(a)
100 nmp1p2 = 1 p1p2 = -1
c1c2 = - 1 c1c2 = 1p1p2 = -1 reduced amplitudestrong amplitude
FIG. 3. (a) Stationary trajectories of all nondegenerate-state
combinations in a stack of vortices, indicated by red and blue lines.The vortices are excited by a sinusoidal magnetic field pointing in
theydirection. Stacks with p
1p2=1 are excited with a frequency of
410 MHz and a field amplitude of 0.4 mT; a frequency of 175 MHzis used for p
1p2=−1 with an amplitude of 0.5 mT for c1c2=1a n d
0.8 mT for c1c2=−1. (b) When the amplitude of the excitation is
reduced by about 40% the type of the trajectory changes for one ofthe two relative circulations.
four state combinations. The vortices oscillate on constant
trajectories that resemble possible motions of the gravitationaltwo-body problem. V ortices with the same polarities gyrateon circular trajectories around a common barycenter. Forequal circularities ( c
1c2=1) the vortices gyrate on the same
trajectory, whereas a phase shift of 180◦emerges for the case of
opposite circularities ( c1c2=−1). In both cases the interaction
is mediated by coupled in-plane dipoles rotating in the samedirection. For equal circularities the attractive force of the twocores is zero since they gyrate on the same lateral positions.For opposite circularities the interaction of the cores can alsobe neglected. This is due to the large interdistance ( ∼100 nm)
of the cores.
V ortices with opposite polarities gyrate in an opposite sense.
Here, the relative phase and thereby the crossing point of thecores depend on the relative circulation. One of the cores isconstrained to a lower radius. This asymmetry could be pro-voked by the Oersted field that slightly varies in its amplitudefor the two disks. Then, the intrinsic repulsion of the coresstrengthens this effect. However, as the oscillation radii areconstant for the case of identical polarizations the asymmetry
054411-3H¨ANZE, ADOLFF, VELTEN, WEIGAND, AND MEIER PHYSICAL REVIEW B 93, 054411 (2016)
of the Oersted field is rather small. The amplitude of the
excitation has been adjusted to maintain large-trajectory radii.By reducing the amplitude of the excitation the type of gyrationchanges for vortices with different polarities [Fig. 3(b)].
We observe a gyration of the vortices around individualbarycenters for the case of equal circularities ( c
1c2=1). Note
that the barycenter is defined as the center of the core trajectoryduring one oscillation period of an individual disk. The vorticesare repelled by the core interaction. This behavior cannot beobserved for the case of opposite circularities ( c
1c2=−1).
Slight oscillations of the barycenters could not be observeddue to the stroboscopic measurement method that integratesover millions of oscillation periods.
IV . THEORETICAL MODEL AND DISCUSSION
The strong frequency splitting of the two polarity states
can be understood within the model presented in Ref. [ 23].
Within this model the splitting between the two polaritystates sums up to 310 MHz for the investigated structures.This value is larger than the experimental splitting reportedin Fig. 2, which can be explained by the overestimation of
the rigid vortex approach [ 38]. Still, the observed repulsion
of the vortex cores has to be taken into account [ 26,31,32].
Therefore, we performed calculations where the interactionof the vortex cores is modeled by an additional potential.We calculate the total energies of two deflected magneticvortices using the Thiele approach [ 39], which considers the
magnetic vortex as a rigid particle. Figure 4(a)depicts the stray
fields of two magnetic dipoles, the vortex cores, in a stack ofmagnetic vortices. The energy of these dipoles is modeledby the assumption of two interacting point dipoles. It can beexpressed as a function of their lateral deflection in oppositedirections /Delta1r. The amplitude of the dipole moment is derived
from the actual size of the magnetic vortex core. Here, weassume that all magnetic moments in a cylindrical shape witha radius r
cand the thickness tof the disks point into the same
out-of-plane direction. The energy is given by
Ecore=−μ0πM2
sp1p2r4
ct2
4[/Delta1r2+(t+/Delta1z)2]3
2/parenleftbigg3(t+/Delta1z)2
/Delta1r2+(t+/Delta1z)2−1/parenrightbigg
,
(1)
where ( t+/Delta1z) is the distance between the vertical centers
of the two disks, Msis the saturation magnetization of
permalloy, and /Delta1zis the thickness of the silicon spacer.
The core interaction is repulsive for opposite ( p1p2=−1)
and attractive for equal polarities ( p1p2=1). Reasonable
values of rc=12 nm [ 6] andMs=800 kA /m are assumed.
The energy contribution of the confinement of the disks ismodeled by a harmonic potential [ 20,38] with a curvature
κ=1.72×10
−3kg/s2and corresponds to a frequency of
ω0/(2π)=240 MHz. For vortices the interaction of the stray
fields at the side surfaces of the disks is also describedby a harmonic potential when equally deflected in oppositedirections. The coupling coefficient η=1.45×10
−3kg/s2is
obtained in analogy to Ref. [ 10] from numerical integration of
the magnetostatic energy between the side surfaces. The strayfield energy depends on the relative circulations of the disksas depicted in Fig. 4(b). The sum of all energy contributions∆r∆z(a) (b)
(c) (d)
60
40
20
0
40 30 20 10
∆z (nm)∆req (nm)Esum (10-18 J)8
6
4
2
0
-2
120 80 40 0
∆r (nm)
c1c2=1 c1c2=-1
FIG. 4. Stray fields emerging (a) in the core regions and (b) at
the side surfaces of vortices that are equally deflected in oppositedirections. The stray fields have been calculated using dipoles
indicated by black and white arrows. (c) Energy contributions as a
function of the lateral distance of the vortex cores /Delta1r within the Thiele
approach. All four nondegenerate combinations of the circulations
(dashed: c
1c2=1, solid: c1c2=−1) and the polarizations (black:
p1p2=1, gray: p1p2=−1) are shown. (d) Resulting equilibrium
position for opposite polarities as a function of the thickness /Delta1zof
the silicon spacer. Micromagnetic simulations depicted by dots and
crosses are in agreement with the calculations.
Esumreads
Esum=Ecore(p1p2,/Delta1r)+(κ−c1c2η)/Delta1r2
4. (2)
Figure 4(c) depicts the total energy Esumfor all four possible
nondegenerate state combinations. For large deflections /Delta1r
the energy contribution of the stray fields at the side surfacesdominates. For the case of equal circularities and oppositepolarities ( c
1c2=1,p1p2=−1) the minimum energy, i.e.,
the equilibrium deflection /Delta1req, is obtained for /Delta1r=30 nm.
All other state combinations reach their equilibrium positionat/Delta1r=0. This behavior explains the collective oscillations
observed in Fig. 3(b). Depending on the circularity, the two
vortices oscillate around different or equal barycenters. Forthe case of equal circularities the distance between the twobarycenters is approximately /Delta1r≈50 nm, whereas for the
case of opposite circularities the two vortices gyrate aroundthe same barycenter. These values are in good agreement withthe analytical model. Slight variations can be explained by themeasurement method that yields only the superposed contrastof both vortex cores. The energy between the vortex corescan also be calculated using the model of magnetic surfacecharges that emerge at the top and bottom surfaces of thedisks. The proceeding is described in Ref. [ 26] and yields
similar results. To gain insight into the strength of the observeddipolar coupling we performed further calculations to predictthe limits of strong and weak core interactions. Figure 4(d)
054411-4TWO-BODY PROBLEM OF CORE-REGION COUPLED . . . PHYSICAL REVIEW B 93, 054411 (2016)
illustrates the dependence of the equilibrium deflection on the
thickness of the silicon spacer. The analytical calculations areconfirmed by micromagnetic simulations [ 40]. The dimensions
of the simulated stacks are identical to the experiments. Theequilibrium deflection is obtained by a relaxation of the systeminto its energetic minimum. Therefore, we use a cell size of4×4×4 nm, a saturation magnetization of M
s=800 kA /m,
an exchange stiffness constant of A ex=1.3×10−11J/m, and
a Gilbert damping constant of α=0.01. In agreement with
Ref. [ 32] the case of equal circularities provokes a larger static
displacement of the cores. Depending on the geometry of thedisks, the displacement is expected to emerge for the case ofdifferent circularities as well.
V . CONCLUSION
We conclude that the collective magnetic excitation in
a stack of vortices is dominated by the relative polaritiesof the vortex cores. A strongly increased splitting of theresonance frequencies compared to laterally coupled structuresis observed. The proximity of the disks results in a couplingof the vortex cores. This coupling yields a displacementof the equilibrium positions for vortex stacks with equal
circulations and opposite polarities. Its nonlinear influenceleads to different types of steady-state motions observed byscanning transmission x-ray microscopy that yield a two-bodyproblem. The access to the third dimension in stacked vorticesovercomes the limitations concerning the storage density inpotential memory devices.
ACKNOWLEDGMENTS
We thank U. Merkt for fruitful discussions and M. V olkmannfor superb technical assistance. We acknowledge the support ofthe Max Planck Institute for Intelligent Systems (formerly MPIfor Metals Research), Department Sch ¨utz, and the MAXY-
MUS team, particularly, M. Bechtel and E. Goering. We thankthe Helmholtz-Zentrum Berlin f ¨ur Materialien und Energie for
the allocation of synchrotron radiation beam time. Financial
support of the Deutsche Forschungsgemeinschaft via the
Sonderforschungsbereich 668 and the Graduiertenkolleg 1286is gratefully acknowledged. This work has been supportedby the excellence cluster “The Hamburg Centre for UltrafastImaging (CUI): Structure, Dynamics and Control of Matter atthe Atomic Scale” of the Deutsche Forschungsgemeinschaft.
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054411-6 |
PhysRevB.100.224411.pdf | PHYSICAL REVIEW B 100, 224411 (2019)
Theory for shift current of bosons: Photogalvanic spin current in
ferrimagnetic and antiferromagnetic insulators
Hiroaki Ishizuka1and Masahiro Sato2
1Department of Applied Physics, The University of Tokyo, Bunkyo, Tokyo 113-8656, Japan
2Department of Physics, Ibaraki University, Mito, Ibaraki 310-8512, Japan
(Received 5 July 2019; published 12 December 2019)
We theoretically study the optical generation of dc spin current (i.e., a spin-current solar cell) in ordered
antiferromagnetic and ferrimagnetic insulators, motivated by a recent study on the laser-driven spinon spincurrent in noncentrosymmetric quantum spin chains [H. Ishizuka and M. Sato, P h y s .R e v .L e t t . 122,197702
(2019 )]. Using a nonlinear response theory for magnons, we analyze the dc spin current generated by a linearly
polarized electromagnetic wave (typically, terahertz or gigahertz waves). Considering noncentrosymmetrictwo-sublattice magnets as an example, we find a finite dc spin-current conductivity at T=0, where no thermally
excited magnons exist; this is in contrast to the case of the spinon spin current, in which the optical transition ofthe Fermi degenerate spinons plays an essential role. We find that the dc spin-current conductivity is insensitiveto the Gilbert damping, i.e., it may be viewed as a shift current carried by bosonic particles (magnons). Ourestimate shows that an electric-field intensity of E∼10
4–106V/cm is sufficient for an observable spin current.
Our theory indicates that the linearly polarized electromagnetic wave generally produces a dc spin current innoncentrosymmetric magnetic insulators.
DOI: 10.1103/PhysRevB.100.224411
I. INTRODUCTION
Materials subject to an intense incident light show rich be-
haviors which are studied in the context of nonlinear responseand nonequilibrium phenomena. An example of such is elec-
tric shift current in noncentrosymmetric semiconductors and
ferroelectrics [ 1–7], where a nontrivial shift of electron po-
sition during its optical transition produces a macroscopicelectric current. Recent studies revealed that the shift cur-rent exhibits strikingly different behaviors from the ordinaryphotocurrent; the shift current shows unique light-positiondependence when it is excited locally [ 8–10], and propagates
faster than the Fermi velocity of electrons [ 10–12]. On the
other hand, in correlated materials, lower-energy excitationsoften emerge due to the interaction effect; a typical example ismagnetic excitations in Mott insulators. The optical transitionof these emergent particles may produce nontrivial phenom-ena, especially, transport phenomena, related to the nonlinearresponse of the emergent excitations.
Several recent studies in optospintronics and magneto-
optics [ 13–15] imply that the intensity and coherence of cur-
rently available electromagnetic waves are sufficient for thecontrol of magnetic excitations or magnetism. Typical resultsare the following: magnetization switching by a circularlypolarized laser in ferrimagnets [ 16–19], laser-driven demag-
netization [ 20–22], the spin pumping by gigahertz (GHz) or
terahertz (THz) waves [ 23,24], focused-laser-driven magnon
propagation [ 25,26], intense THz-laser-driven magnetic res-
onance [ 27,28], spin control by THz-laser-driven electron
transitions [ 29], dichroisms driven by THz vortex beams [ 30],
angular-momentum transfer between photons and magnons incavities [ 31–35], an ultrafast detection of spin Seebeck effect
[36], a phonon-mediated spin dynamics with THz laser [ 37],etc. Moreover, recent theoretical works have proposed several
ways of optical control of magnetism: GHz /THz-wave-driven
inverse Faraday effect [ 38,39], Floquet engineering of mag-
netic states such as chirality ordered states [ 40,41] and a
spin-liquid state [ 42], generation of magnetic defects with
laser-driven heat [ 43,44], applications of topological light
waves to magnetism [ 44–47], control of exchange couplings
in Mott insulators with high- [ 48] and low-frequency [ 49]
waves, optical control of spin chirality in multiferroic mate-rials [ 50], rectification of dc spin currents in magnetic insu-
lators with electromagnetic waves [
51–53]. These studies are
partly supported by recent developments in THz laser science[54,55] which realized high-intensity light beams with the
photon energy comparable to those of magnetic excitations.Despite these developments, the optical control of the currentcarried by magnetic excitations is limited to some theoreticalproposals.
Among the proposals, a recent theory proposes a mecha-
nism for producing a dc spin current in quantum spin chainswithout the angular-momentum transfer [ 52]; it is distinct
from the known mechanisms in which the angular momentumof photons is transferred to the magnet [ 23,24,51,53,56]. The
mechanism in Ref. [ 52] is analogous to that of the shift-
current photogalvanic effect [ 2]. The close relation between
two phenomena are clear from the Jordan-Wigner fermionrepresentation of spin chain; the ground state of the spin chainis a band insulator of Jordan-Wigner fermions, and the pho-togalvanic response is related to the optical transition of thefermions by the linearly polarized GHz /THz light. However,
the relation of this mechanism to the fermion excitations castsdoubt on the generality because the low-energy excitationsof the ordered magnets are usually magnons, i.e., bosonicexcitations.
2469-9950/2019/100(22)/224411(12) 224411-1 ©2019 American Physical SocietyHIROAKI ISHIZUKA AND MASAHIRO SATO PHYSICAL REVIEW B 100, 224411 (2019)
In this work, we theoretically show that a dc spin current
similar to that of the spin chain [ 52] also appears in ordered
antiferromagnetic (AFM) and ferrimagnetic (FRM) insulatorsby applying a linearly polarized electromagnetic wave. Thesymmetry argument in Sec. IIIshows that the creation of
dc spin current with linearly polarized waves is possibleonly if both site- and bond-center inversion symmetries arebroken. AFM and FRM insulators violate the bond-centerinversion symmetry and thereby they naturally satisfy halfof the required symmetry condition. The staggered momentis an advantage of considering AFM /FRM insulators for
generating a dc spin current. As an example, we considertwo-sublattice models with Néel-type ground state. Bosonicparticles describe the low-energy excitations of these models,i.e., magnons; the ground state is the zero-magnon state. Thisground state is very different from that of noncentrosymmetricS=
1
2spin chains [ 52] which are described by a Fermi degen-
erated state of spinons. Despite the difference, our calculationusing a nonlinear response theory finds a finite photogalvanicspin current similar to that of the spinons. We discuss that it isrelated to the zero-point fluctuation of the quantum magnets.Our theory also indicates that the magnon spin current is shift-current like, i.e., it is insensitive to the magnon lifetime as inthe spinon case [ 3,57,58]. This mechanism allows generation
of spin current using a linearly polarized electromagneticwave and ordinary AFM or FRM insulators.
The remaining part of the paper is organized as follows.
In Sec. II, we introduce the nonlinear response theory for
two-species magnons, which we will use in the followingsections. The main results of this paper are in Secs. IIIandIV.
Section IIIfocuses on the photoinduced spin current in AFM
and FRM insulators with a strong one dimensionality, whilewe study the three-dimensional (3D) magnets in Sec. IV.
Effective experimental setups and signatures for investigatingthe proposed mechanism are discussed in Sec. V. Section VI
is devoted to the summary and discussions.
II. NONLINEAR RESPONSE THEORY
We calculate the nonlinear response coefficients for the
photoinduced spin current by extending the linear responsetheory to the quadratic order in the perturbation. A similarmethod for fermions is used to calculate the photogalvaniccurrent in semiconductors [ 57,58] and the spin current of
spinons [ 52]. The derivation of the formula is summarized in
Appendix A. We here summarize the outline of the derivation.
We also discuss the physical implications.
We consider a two-sublattice AFM /FRM insulator with
two species of magnons. The effective Hamiltonian for themagnons is
H=/summationdisplay
kεα(k)α†
kαk+εβ(k)βkβ†
k, (1)
where αk(α†
k) andβk(β†
k) are the boson annihilators (creators)
for the magnons with the momentum k=(kx,ky,kz) and
εa(k)(a=α,β) is the energy of the magnons in the a=
α,β branch with momentum k. We here consider a generalperturbation (spin-electromagnetic-wave coupling)
H/prime=−/summationdisplay
μ,k/integraldisplaydω
2π/Gamma1μ
ωeiωtψ†
k/parenleftBigg/parenleftbig
Bμ
k/parenrightbig
αα/parenleftbig
Bμ
k/parenrightbig
αβ/parenleftbig
Bμ
k/parenrightbig
βα/parenleftbig
Bμ
k/parenrightbig
ββ/parenrightBigg
ψk
+H.c., (2)
and spin-current operator
J=/summationdisplay
kψ†
k/parenleftbigg
(Jk)αα (Jk)αβ
(Jk)βα (Jk)ββ/parenrightbigg
ψk. (3)
Here, ωis the frequency of ac light, /Gamma1μ
ωis the spin-light
coupling constant for the μdirection, and ψk=(αk,β†
−k)T.
The nonlinear conductivity is defined by
/angbracketleftJ/angbracketright(/Omega1)=/summationdisplay
μ,ν/integraldisplay
dωσμν(/Omega1;ω,/Omega1−ω)/Gamma1μ
ω/Gamma1ν
/Omega1−ω, (4)
where /angbracketleftJ/angbracketright(/Omega1)≡/integraltext
dt/angbracketleftJ/angbracketright(t)e−i/Omega1tis the Fourier transform of
the expectation value of the spin current /angbracketleftJ/angbracketright(t). For the
two-sublattice model, the formula for nonlinear spin currentconductivity reads as
σ
μν(/Omega1;ω,/Omega1−ω)
=1
2π/summationdisplay
k,ai=α,βsgn(a3)/bracketleftbig
˜ρk,a1sgn(a2)−sgn(a1)˜ρk,a2/bracketrightbig/parenleftbig
Bμ
k/parenrightbig
a1a2
ω−˜εa2(k)+˜εa1(k)−i/(2τk)
×/bracketleftbigg/parenleftbig
Bν
k/parenrightbig
a2a3(Jk)a3a1
/Omega1+˜εa1(k)−˜εa3(k)−i/(2τk)
−(Jk)a2a3/parenleftbig
Bν
k/parenrightbig
a3a1
/Omega1+˜εa3(k)−˜εa2(k)−i/(2τk)/bracketrightbigg
, (5)
where
˜εa(k)=sgn(a)εa(k), (6)
sgn(a)=/braceleftbigg
1( a=α),
−1( a=β),(7)
˜ρk,a=/braceleftbigg/angbracketleftα†
kαk/angbracketright0 (a=α),
/angbracketleftβ−kβ†
−k/angbracketright0(a=β).(8)
The relaxation time of magnons τkwas introduced in Eq. ( 5),
and/angbracketleft.../angbracketright0is the expectation value of ...in the equilibrium
state of the Hamiltonian in Eq. ( 1). The conductivity for dc
spin current corresponds to the /Omega1=0 case, σμν(0;ω,−ω).
In the rest of this work, we focus on the case Bμ
k=Bν
k=
Bkbecause we are interested in the response to a linearly
polarized light. Hence, we abbreviate the subscripts in thenonlinear conductivity σ
μν(0;ω,−ω)=σ(0;ω,−ω).
We note that the conductivity in Eq. ( 5) remains nonzero at
T=0. The substitutions of ˜ ρk,α=0 and ˜ ρk,β=1i nE q .( 5)
224411-2THEORY FOR SHIFT CURRENT OF BOSONS: … PHYSICAL REVIEW B 100, 224411 (2019)
reduce the formula to
σ(0;ω,−ω)=/summationdisplay
k−1
π/bracketleftbigg(1+i2τkω)|(Bk)βα|2[(Ak)αα+(Ak)ββ]
(ω−i/2τk)2−[εα(k)+εβ(k)]2/bracketrightbigg
+1
2π(Bk)βα(Ak)αβ[(Bk)ββ+(Bk)αα]
[ω−i/2τk−εα(k)−εβ(k)][εα(k)+εβ(k)+i/2τk]
+1
2π(Bk)αβ(Ak)βα[(Bk)ββ+(Bk)αα]
[ω−i/2τk+εα(k)+εβ(k)][εα(k)+εβ(k)−i/2τk]. (9)
Here, Ais an observable; it is the spin-current operator in the
rest of this paper. Because of ˜ ρk,β=1, the terms involving
the off-diagonal component of Bkremain at T=0. In other
words, the two-magnon creation /annihilation process plays a
crucial role as shown in Fig. 1(d). We focus on the T=0
case in the rest of this paper as this process is dominant in thelow-temperature limit.
From a different viewpoint, Eq. ( 9) implies the zero-point
fluctuation plays a key role in the photogalvanic response ofmagnons. In our formalism, the zero-point fluctuation is mani-fested in the Bogoliubov transformation of Holstein-Primakovbosons. This transformation creates β
kβ†
kandα†
kβ†
−kterms
which contribute to the photogalvanic response in the groundstate. ˜ ρ
k,β=1 is another consequence of the Bogoliubov
transformation. The importance of the zero-point fluctuationresembles the spinon spin current [ 52], in which the Fermi
degeneracy of spinons represents the quantum fluctuation of
(a) (b)ω ω
001234
0E
π −π −π π(c) (d)
kkαk, βkαk+ β−k
αkαk+ β−k
βk
ω
FIG. 1. Schematic pictures of the noncentrosymmetric magnets.
A quasi-one-dimensional magnet consisting of weakly coupled spin
chains (a) and a three-dimensional magnet with two-sublattice order
(b). Each sublattice (blue and orange) has a different environment,e.g., different gfactors, uniaxial anisotropy, etc., and with the bond
dimerization (shown by the thick bond). The two-sublattice order and
bond dimerization, respectively, break the inversion symmetry on thebond center and sites. Magnetic excitation and nonlinear spin-current
conductivity of the spin chain. The magnon band dispersions of the
model in Eq. ( 11a)f o r( c ) h
+=0a n d( d ) h+=1
100. Parameters h±
are defined in Eq. ( 17). When h+=0, two magnon dispersions are
degenerate. The GHz /THz light produces two magnons, one on each
branch as schematically shown in (d).spins. A crucial difference in the current case is the absence of
Fermi degeneracy. However, in the case of the AFMs /FRMs,
the condensate of Holstein-Primakov bosons plays a simi-lar role to the Fermi degeneracy. The pair-creation processrepresented by α
†
kβ†
kgenerates photogalvanic response of
the magnons which is manifested in the denominator ofEq. ( 9); the sum of eigenenergies, ε
α(k)+εβ(k), represents
creation /annihilation of a magnon pair. These features imply
that the zero-point fluctuation is necessary for the shift-currentresponse at T=0.
The first term in Eq. ( 9) vanishes when the ground state has
a certain symmetry. For example, collinear magnetic orderswith the moments parallel to S
zaxis are often symmetric with
respect to G=TMs
x, which is the product of time-reversal
operation ( T) and the mirror operation for the spin degrees of
freedom about the xaxis ( Ms
x). In this case, the real part of
σ(0;ω,−ω) reads as
Re[σ(0;ω,−ω)]
=−1
π/summationdisplay
kRe/braceleftbigg(Bk)βα(Ak)αβ[(Bk)ββ+(Bk)αα]
ω2−[εα(k)+εβ(k)+i/2τk]2/bracerightbigg
.(10)
The conductivities for the models considered in the following
sections are calculated using this formula.
III. SPATIALLY ANISOTROPIC MAGNET
In this section, we apply the above formula to a spin
chain with AFM or FRM order, which corresponds to aquasi-one-dimensional (quasi-1D) magnetic compound with anegligible interchain interaction. The spins are coupled to theelectromagnetic wave through the Zeeman coupling. To makethe problem theoretically well defined, we consider a modelwhich conserves the spin angular momentum S
z; the model
has an easy axis and the applied ac magnetic field is parallelto the ordered moments. The conservation of S
zallows us
to unambiguously define the spin-current operator from thecontinuity equation. This setup is in contrast to those of usualmagnetic resonances and spin pumping [ 23,24], in which the
ac field is perpendicular to the magnetic moment. We usethe standard spin-wave approximation to describe magneticexcitations (magnons).
A. Model
We consider an ordered noncentrosymmetric spin chain
with a two-sublattice unit cell [Fig. 1(a)], whose Hamiltonian
is given by
Htot=H0+H(ω)
Z, (11a)
H0≡/summationdisplay
ry,rzH1D(ry,rz), (11b)
224411-3HIROAKI ISHIZUKA AND MASAHIRO SATO PHYSICAL REVIEW B 100, 224411 (2019)
H1D(ry,rz)≡/summationdisplay
rxJ(1+δ)SA(r)·SB(r)
+J(1−δ)SA(r+ˆx)·SB(r)
−(D+Ds)/bracketleftbig
Sz
A(r)/bracketrightbig2−(D−Ds)/bracketleftbig
Sz
B(r)/bracketrightbig2
−B/bracketleftbig
gASz
A(r)+gBSz
B(r)/bracketrightbig
, (11c)
H(ω)
Z=− (Bωeiωt+H.c.)/summationdisplay
rgASz
A(r)+gBSz
B(r),
(11d)
where H1Dis the spin-chain Hamiltonian with the staggered
nearest-neighbor exchange interaction (i.e., dimerization)along the xdirection, H
0is the bundle of all the chains, and
H(ω)
Zis the Zeeman coupling between the spins and the exter-
nal electromagnetic wave. Here, Sa(r)≡(Sx
a(r),Sy
a(r),Sz
a(r))
(a=A,B)i st h es p i n - Saoperator on the asublattice of
the unit cell at position r=(rx,ry,rz). Symbols ˆ x,ˆy, and ˆ z
stand for the unit vectors along the x,y, and zdirections,
respectively. The parameters in the Hamiltonian H1Dare as
follows: J>0 is the antiferromagnetic exchange interaction
along the spin-chain ( x) direction, δis the dimerization, D>0
(Ds) is the uniform easy-axis (staggered) anisotropy, gA(gB)
is the gfactor for the spins on A(B) sublattice, and his
the external static magnetic field along the Szaxis. In the
spin-light coupling H(ω)
Z,|Bω|and arg( Bω) are, respectively,
the magnitude and the phase of the ac magnetic field of thelinearly polarized electromagnetic wave. We assume |D
s|<
D, and|δ|<1.
When SA/negationslash=SB, the ground state of the model in Eq. ( 11c)i s
a FRM-ordered state with magnetization |SA−SB|per a unit
cell [ 59,60]. The ground state is Néel ordered when SA=SB.
The classical ground state of H0has a collinear order with
spins pointing along the Szaxis because of the easy-axis
anisotropy D[Fig. 1(a)]. The anisotropy also produces the
spin gap in the excitation spectrum [Figs. 2(a) and1(b)]. We
discuss the effect of the gap and its relation to the frequencydependence of the nonlinear spin conductivity in the nextsection.
Here, we define the spin current for S
z. Since the model H0
conserves the zcomponent of total spin angular momentum,
the spin current for Szcan be defined from the continuity equa-
tions∂tSz
A=Jz
x(rx−1,B;rx,A)−Jz
z(rx,A;rx,B) and∂tSz
B=
Jz
x(rx,A;rx,B)−Jz
z(rx,B;rx+1,A), in which Jα
β(r,a;r/prime,b)
is the local spin- Sαcurrent operator between two neighboring
sites ( r,a) and ( r/prime,b) and it flows along the βdirection.
The above continuity equation is obtained from Heisenbergequation of motion for local spins. With these procedures, wefind the uniform current operator for H
1Dreads as
Jz
x=J
2N/summationdisplay
r(1+δ)/braceleftbig
Sx
B(r)Sy
A(r)−Sy
B(r)Sx
A(r)/bracerightbig
+(1−δ)/braceleftbig
Sx
A(r+ˆx)Sy
B(r)−Sy
A(r+ˆx)Sx
B(r)/bracerightbig
,(12)
where Nis the total number of unit cells.
B. Linear spin-wave approximation
We here study the shift current of magnons using linear
spin-wave approximation. Hereafter, we assume that in the(a)
σ(0;ω,−ω ) (a.u.)
ω/J(b)-0.15-0.10-0.050.000.05
10-410-310-210-1100101
0 1 2 3 4σ(ω)
α=5x10-3
α=1x10-2
α=1x10-10.01 0.10 1
0.0010.0100.1001
J┴=0
J┴=1/4
J┴=1δω|σ(0;ω,−ω )| (a.u.)
FIG. 2. Frequency dependence of the nonlinear spin-current con-
ductivity σ(0;ω,−ω). (a) Analytic result for the small Gilbert
damping limit α→0 and (b) numerical results for a finite α.T h e
inset in (a) is the δω≡ω−ωc1for different J⊥. The calculations
are done using a chain with N=2048–32 768 unit cells. All results
are for J=1,δ=1/4,SA=SB=1,gA=1,gB=1/2,h−=0, and
B+=1/100 unless noted explicitly.
ground state of H1D, the spins on the Asublattice point up
while those on Bsublattice are down [see Fig. 1(a)]. The in-
teraction between the low-energy excitations of H0(magnons)
are negligible when the temperature is sufficiently lower thanthe magnetic transition temperature. Therefore, we neglectthe interaction between the magnons, i.e., we study the spincurrent within the linear spin-wave approximation.
Using the Holstein-Primakov bosons, the spin operators are
given by
S
z
A=SA−ˆnA(r), (13a)
S+
A(r)=/radicalbig
2SA/parenleftbigg
1−ˆnA(r)
2SA/parenrightbigg1
2
a(r), (13b)
S−
A=/radicalbig
2SAa†(r)/parenleftbigg
1−ˆnA(r)
2SA/parenrightbigg1
2
(13c)
for the Asublattice, and
Sz
B=ˆnB(r)−SB, (14a)
S+
B(r)=/radicalbig
2SBb†(r)/parenleftbigg
1−ˆnB(r)
2SB/parenrightbigg1
2
, (14b)
S−
B=/radicalbig
2SB/parenleftbigg
1−ˆnB(r)
2SB/parenrightbigg1
2
b(r) (14c)
224411-4THEORY FOR SHIFT CURRENT OF BOSONS: … PHYSICAL REVIEW B 100, 224411 (2019)
for the Bsublattice. Up to the linear order in SAandSB,H0
reads as
H0∼/summationdisplay
k/parenleftbiggak
b†
−k/parenrightbigg†/parenleftBigg
h0
k+hz
khx
k−ihy
k
hx
k+ihy
kh0
k−hz
k/parenrightBigg/parenleftbiggak
b†
−k/parenrightbigg
+const, (15)
where the wave number along the chain ( x) direction is
simply represented by k,ak≡(1/√
N)/summationtext
ra(r)eik·r,bk≡
(1/√
N)/summationtext
rb(r)eik·(r+ˆx/2)are the Fourier transformation of
Holstein-Primakov bosons. The matrix elements of themagnon Hamiltonian ( 15) are calculated as
h
0
k=B++J(SA+SB), (16a)
hx
k=2J√
SASBcos(k/2), (16b)
hy
k=− 2Jδ√
SASBsin(k/2), (16c)
hz
k=B−−J(SA−SB), (16d)
where
B+=D(SA+SB−1)+Ds(SA−SB)+B
2(gA−gB),(17a)
B−=D(SA−SB)+Ds(SA+SB−1)+B
2(gA+gB).(17b)
We note that, in general, the magnon Hamiltonian for two-
sublattice ordered system has a 4 ×4 matrix form, but that of
the present system can be reduced to a 2 ×2 form as shown
in Eq. ( 15).
The quadratic Hamiltonian ( 15) is diagonalized by the
Bogoliubov transformation:
ak=cosh/Theta1kαk+sinh/Theta1kβ†
−k, (18)
b†
−k=sinh/Theta1kei/Phi1kαk+cosh/Theta1kei/Phi1kβ†
−k, (19)
where αk(α†
k) andβk(β†
k) are bosonic annihilation (creation)
operators. By choosing
ei/Phi1k=hx
k+ihy
k/radicalBig/parenleftbig
hx
k/parenrightbig2+/parenleftbig
hy
k/parenrightbig2(20a)
and
cosh(2 /Theta1k)=h0
k/radicalBig/parenleftbig
h0
k/parenrightbig2−/parenleftbig
hx
k/parenrightbig2−/parenleftbig
hy
k/parenrightbig2, (20b)
sinh(2 /Theta1k)=−/radicalBig/parenleftbig
hx
k/parenrightbig2+/parenleftbig
hy
k/parenrightbig2
/radicalBig/parenleftbig
h0
k/parenrightbig2−/parenleftbig
hx
k/parenrightbig2−/parenleftbig
hy
k/parenrightbig2, (20c)the Hamiltonian becomes
H0=/summationdisplay
kεα(k)α†
kαk+εβ(k)β†
−kβ−k, (21)
where
εα(k)=hz
k+/radicalBig/parenleftbig
h0
k/parenrightbig2−/parenleftbig
hx
k/parenrightbig2−/parenleftbig
hy
k/parenrightbig2, (22a)
εβ(k)=−hz
k+/radicalBig/parenleftbig
h0
k/parenrightbig2−/parenleftbig
hx
k/parenrightbig2−/parenleftbig
hy
k/parenrightbig2. (22b)
Here, we ignored the constant term in H0. We note that the
dispersions εα,β(k) and the phases ( /Theta1k,/Phi1 k) are all indepen-
dent of kyandkzbecause we now consider the 1D model H0.
Using the same transformation, we find
H(ω)
Z=B/summationdisplay
k(gAcosh2/Theta1k−gBsinh2/Theta1k)α†
kαk
+(gAsinh2/Theta1k−gBcosh2/Theta1k)β−kβ†
−k
+gA−gB
2sinh(2 /Theta1k)(α†
kβ†
−k+β−kαk)
+const (23)
and
Jz
x=J√
SASB/summationdisplay
ksinh(2 /Theta1k)/parenleftbigg
sink
2cos/Phi1k+δcosk
2sin/Phi1k/parenrightbigg
×(α†
kαk+β−kβ†
−k)
+/bracketleftbigg/braceleftbigg
cosh(2 /Theta1k)/parenleftbigg
cos/Phi1ksink
2−δsin/Phi1kcosk
2/parenrightbigg
+i/parenleftbigg
sin/Phi1ksink
2+δcos/Phi1kcosk
2/parenrightbigg/bracerightbigg
α†
kβ†
−k+H.c./bracketrightbigg
.
(24)
C. Spin-current conductivity
Combining the magnon representation of ( αk,βk) with the
formula ( 10), we compute the nonlinear dc spin-current con-
ductivity for the model Htotunder the application of GHz wave
or THz laser. We first study the nonlinear conductivity in theclean limit with infinite relaxation time τ
k→∞ . The analytic
solution for the conductivity Re[ σ(0;ω,−ω)] obtained from
Eq. ( 10) reads as
Re[σ(0;ω,−ω)]=(gA−gB)2δ[B++J(SA+SB)](ω2−4[B++J(SA+SB)]2−2J2SASB(1+δ2))
8π(1−δ2)ω2/radicalBig
4J4S2
AS2
B(1−δ2)2−{(ω/4)2+2J2SASB(1+δ2)−]B++J(SASB)]2}2, (25)
whenω∈[ωc1,ωc2] and zero otherwise. Here,
ωc1≡εα(0)+εβ(0)
=2/radicalbig
[B++J(SA+SB)]2−4J2SASB (26)corresponds to the energy for the band bottom of the pair
excitation and
ωc2≡εα(π)+εβ(π)
=2/radicalbig
[B++J(SA+SB)]2−4δ2J2SASB (27)
224411-5HIROAKI ISHIZUKA AND MASAHIRO SATO PHYSICAL REVIEW B 100, 224411 (2019)
is that for the top of the pair excitation [see Figs. 1(c) and
(d)]. The frequency dependence of the conductivity is shownin Fig. 2(a).
One finds from Eq. ( 25) that the spin-current generation
disappears in the case g
A=gB. However, this comes from
our simple setup. If we consider a larger-sublattice magnetor noncollinear-ordered one, a finite spin current is expectedeven in g
A=gB. In addition, in our previous study [ 52], we
show that other types of spin-light couplings such as inverseDyzaloshinskii-Moriya and magnetostriction couplings pro-duce a spin current in a 1D quantum spin chain.
Equation ( 25) is an odd function of δ. This reflects the
fact that the inversion-symmetry breaking is necessary forthe spin current. H
0has two inversion centers when δ=0,
Ds=0,gA=gB, and SA=SB: one at the center of the bond
and the other on the site. The inversion center on the siteis broken by the dimerization δ. To see the dependence of
σ(0;ω,−ω) on the model parameters, we explicitly write the
nonlinear conductivity as a function of the parameters, i.e.,σ(0;ω,−ω)=σ(ω;δ,g
A−gB,Ds,m), where m=/angbracketleftSz
r∈A/angbracketright−
/angbracketleftSz
r∈B/angbracketrightis the order parameter of the AFM or FRM insula-
tors. A symmetry argument on the transport coefficient findsσ(ω;δ,g
A−gB,Ds,m)=−σ(ω;−δ,gA−gB,Ds,m)f o rt h e
site-center inversion operation. This result is identical to thespinon case in Ref. [ 52].
On the other hand, the magnetic order changes the param-
eter dependence of σ(0;ω,−ω), which is related to the bond-
center inversion operation. The inversion operation about thecenter of the bonds is broken by the Néel ordering D
s/negationslash=
0o r gA/negationslash=gB. Therefore, the symmetry operation indicates
σ(ω;δ,gA−gB,Ds,m)=−σ(ω;δ,−gA+gB,−Ds,−m). In
addition, the translation operation about half a unit cellswitches Aand Bsublattices and m→− m;σ(ω;δ,g
A−
gB,Ds,m)=−σ(ω;δ,gA−gB,Ds,m). Hence, the conduc-
tivity in the ordered phase is an even function of gA−gBand
Ds. This is a different behavior from the spinon case, in which
the conductivity is an odd function of the staggered magneticfield (corresponds to g
A−gBin our case).
The conductivity diverges when ωapproaches ωc1.T h e
asymptotic form reads as
Re[σ(0;ω,−ω)]≈−(gA−gB)2J2δSASB[B++J(SA+SB)]
8πJ{[B++J(SA+SB)]2−4J2SASB}5
4
×1/radicalbig
(1−δ2)SASBδω, (28)
where δω≡ω−ωc1. A similar feature is also found in the
spinon case, in which the divergence is related to the sin-gularity of the density of states [ 52]. On the other hand, the
asymptotic form around ω=ω
c2reads as
Re[σ(0;ω,−ω)]≈(gA−gB)2J2δSASB[B++J(SA+SB)]
8πJ{[B++J(SA+SB)]2−4J2δ2SASB}5
4
×1/radicalbig
(1−δ2)SASB|δω|. (29)
The sign of the conductivity is the opposite of that in the
lower-frequency regime. This is in contrast to the spinon case[52], in which the sign of the nonlinear conductivity remains
the same for all frequencies ω∈[ω
c1,ωc2].D. Relaxation-time dependence
We next study the damping (relaxation-time) dependence
of the spin current. Different mechanisms of the photogal-vanic effect are classified by their relaxation-time dependence[2,3,57,58]: it is called shift current when σ(0;ω,−ω)∝τ
0
while is injection current when σ(0;ω,−ω)∝τ. In bosonic
systems, a slight difference appears in the momentum de-pendence of the single-particle relaxation time [ 61]; it is
inversely proportional to the momentum for the Goldstonemodes. Therefore, we assume the momentum dependence ofdamping term as τ
k=1/(α0εβ(k))so that the momentum
dependence is consistent with the field-theoretic requirement(α
0is the damping factor). Physically, the assumed form of τk
corresponds to the phenomenological Gilbert damping.
We substitute τk=1/(α0εβ(k))in Eq. ( 10) in order
to estimate the relaxation-time dependence of the spin-current conductivity. Figure 2(b) shows the α
0dependence
ofσ(0;ω,−ω). Our numerical result shows σ(0;ω,−ω)i s
insensitive to the damping. A slight difference, however,appears in the high-frequency region, where the smearing dueto the damping is more distinct than that in the low-frequency
region. This behavior is related to the momentum dependence
ofτ
k, which is inversely proportional to the energy of the
magnon. The insensitivity shows the spin current is a shift-current type photoinduced current [ 2]; this is a similar feature
to the spinon case [ 52].
IV . THREE-DIMENSIONAL MAGNETIC INSULATORS
In this section, we consider a three-dimensional (3D)
magnet which consists of coupled spin chains H1Dwith a
non-negligible interchain interaction [see Fig. 1(b)]. We par-
ticularly focus on the limit in which ωis close to the band gap
of two-magnon excitations. The procedure of the calculationis the same as the 1D case in the previous section. The staticpart of the Hamiltonian reads as
H
(3D)
0≡/summationdisplay
rJ(1+δ)SA(r)·SB(r)
+J(1−δ)SA(r+ˆx)·SB(r)
−(D+Ds)/bracketleftbig
Sz
A(r)/bracketrightbig2−(D−Ds)/bracketleftbig
Sz
B(r)/bracketrightbig2
−J⊥[SA(r)·SA(r+ˆy)+SA(r)·SA(r+ˆz)
+SB(r)·SB(r+ˆy)+SB(r)·SB(r+ˆz)]
−B/bracketleftbig
gASz
A(r)+gBSz
B(r)/bracketrightbig
. (30)
The spin chains are parallel to the xdirection, while the yandz
directions are perpendicular to the chains. The ferromagneticcoupling J
⊥>0 denotes the strength of the interchain ex-
change interaction. We study this model within the linear spin-wave approximation using Holstein-Primakov transformationin Sec. III B . Focusing on the lower edge of the magnon
dispersion, we first expand the matrix elements h
a
kof the
magnon Hamiltonian [see Eq. ( 16)] up to second order in k:
h0
k/similarequalB++J(SA+SB)+J⊥(SA+SB)
2/parenleftbig
k2
y+k2
z/parenrightbig
,(31a)
hx
k/similarequalJ√
SASB/parenleftbigg
2−1
4k2
x/parenrightbigg
, (31b)
224411-6THEORY FOR SHIFT CURRENT OF BOSONS: … PHYSICAL REVIEW B 100, 224411 (2019)
FIG. 3. Schematic figure of the magnon dispersion for the 3D
model in Eq. ( 30). We set ky=0. The blue and orange planes are
the dispersions of two magnon branches and the green transparentplane is that of two-magnon excitation. The plot is for J=1,J
⊥=1,
δ=1/4,SA=1,SB=1,h+=1/100, and h−=1/10.
hy
k/similarequal−J√
SASBδkx, (31c)
hz
k/similarequalB−+J(SA−SB)+J⊥(SA−SB)
2/parenleftbig
k2
y+k2
z/parenrightbig
.(31d)
We note that the magnon dispersions depend on both in-
trachain and interchain wave numbers differently from the1D case. The dispersion around the /Gamma1point k=0is shown
in Fig. 3. Using the momentum gradient of the low-energy
Hamiltonian with h0,x,y,z
k, we can define the spin-current oper-
ator; this approximation is essentially equivalent to expandingthe lattice spin-current operator in Eq. ( 24) up to the linear
order in k:
J
z
z=J√
SASB/summationdisplay
ksinh(2 /Theta1k)/parenleftbiggkx
2cos/Phi1k+δsin/Phi1k/parenrightbigg
×(α†
kαk+β−kβ†
−k)
+/braceleftbigg
cosh(2 /Theta1k)/parenleftbigg
cos/Phi1kkx
2−δsin/Phi1k/parenrightbigg
+i/parenleftbiggkx
2sin/Phi1k+δcos/Phi1k/parenrightbigg/bracerightbigg
α†
kβ†
−k+H.c. (32)
These equations correspond to the k·pexpansion of the
lattice model. Therefore, it should be a good approximationfor the lattice model when ωis close to the gap for two-
magnon excitations.
The spin-current conductivity is calculated using the for-
mula of Eq. ( 10). A calculation similar to the 1D model
considered in Sec. IIIgives
Re[σ(0;ω,−ω)]
=−J
2δSASB(gA−gB)2
(4π)22J⊥ω2(SA+SB)/parenleftbig
8kx−k3
x/parenrightbig
kx=KX, (33)where
KX=/bracketleftbigg
8(1−δ2)
−4/radicalBigg
[B++J(SA+SB)]2−(ω/2)2
J2SASB+δ2(δ2−2)/bracketrightbigg1
2
.
(34)
When ωis close to the lower edge, i.e.,
ω∼ωc1≡2/radicalbig
[B++J(SA+SB)]2−4J2SASB, (35)
KXbecomes
KX≈/radicalBigg
2/radicalbig
[B++J(SA+SB)]2−4J2SASBδω
(1−δ2)J2SASB, (36)
where δω=ω−ωc1. Therefore, the asymptotic form of
Re[σABB(0;ω,−ω)] is
Re[σ(0;ω,−ω)]≈−(gA−gB)2δ√SASB
16π2√
1−δ2(SA+SB)
×J√
δω
J⊥{[B++J(SA+SB)]2−4J2SASB}3
4.
(37)
Unlike the 1D case, in which the conductivity diverges
at the band edge ωc1, the 3D result in Eq. ( 37) decreases
proportionally to√
δωwhen approaching ωc1. The result is
plotted in the inset of Fig. 2(a) with the results for the 1D
limit. This difference is a consequence of the difference inthe density of states: it diverges in the 1D model while it isproportional to√
δωin the present 3D case.
The approximation we used in this section is accurate when
ωis close to the magnon gap at the /Gamma1point in the Brillouin
zone. In our model, the band bottom for the two-magnonexcitations are at the /Gamma1point, and the bandwidth of two-
magnon excitation along the xandydirections is in the order
ofJ
⊥and that for zdirection is in the order of J. Therefore, our
approximation is accurate when δω/lessmuchJ,J⊥. This condition
is manifested in J⊥in the denominator of Eq. ( 37), which
implies the divergence of Re[ σ(0;ω,−ω)] at J⊥→0. When
J⊥is very small, we expect Re[ σ(0;ω,−ω)] to behave like
that of the 1D case. On the other hand, Re[ σ(0;ω,−ω)]
looks like Eq. ( 37) when J⊥is sufficiently large, e.g., when
J⊥∼J. Therefore, the 1D result and the result in this section
correspond to the two limits of the 3D magnet.
V . EXPERIMENTAL OBSERV ATION
In this section, we discuss experimental methods for de-
tecting signatures of a directional spin current in our mecha-nism.
A. Setup
We here discuss experimental setups for the observation
of the spin current generated by linearly polarized light. Themechanism studied here produces a directional flow of thespin current, which is a distinct feature from the spin pumping
224411-7HIROAKI ISHIZUKA AND MASAHIRO SATO PHYSICAL REVIEW B 100, 224411 (2019)
FIG. 4. Schematic figure of the experimental setups for measur-
ing photoinduced spin current: all-optical setup [(a) and (b)] and
two-terminal setup (c). (a) The all-optical setup irradiates the isolated
magnet using GHz /THz light. The optically induced spin current
accumulates the angular momentum at the end of the magnet which
is depicted by the clouds; it produces the asymmetric distribution
of the angular momentum in the magnet. (b) A similar observationby attaching a thin layer of a soft ferromagnet at the two ends. The
photogalvanic spin current is injected to or absorbed from the soft
ferromagnets. (c) The two-terminal setup observes the directionalflow of spin current using the inverse spin Hall effect. The optically
induced spin current flows along a certain direction of the system.
Therefore, inverse spin Hall voltage of the two leads has the samesign. These setups are different from that of spin pumping of (d),
in which a transverse ac field is applied to the magnet and the spin
current is diffusively expanded.
[23,24]. Therefore, the observation of the directional flow
should provide an evidence for our mechanism. In addition,our theory in the previous sections corresponds to the case inwhich the ac magnetic field is parallel to the magnetization.Therefore, the angle dependence of the photocurrent providesinformation on the origin of the spin current. We discusstwo different mechanisms: first one is an all-optical setupusing Kerr rotation or Faraday effect, and the second is atwo-terminal setup using inverse spin Hall effect.
Observation of the spatial distribution of angular momen-
tum in the open-circuit setup provides a direct evidence forthe optically generated spin current [see Fig. 4(a)]. In an
isolated magnet, the spin current produced by a GHz /THz
light flows along a direction defined by the magnetic orderand the crystal symmetry. Therefore, if the system becomesclose enough to a laser-driven nonequilibrium steady state, theangular momentum accumulates at the two ends in an open-circuit setup in Fig. 4(a); positive angular momentum on one
end and negative on the other end. The angular-momentumdistribution is antisymmetric along the direction of the spincurrent. This distribution is strikingly different from the spin-pumping case in which the distribution is symmetric and itsdifference from the equilibrium state is larger at the focal areaof the laser than at the ends.An all-optical setup using Kerr rotation or Faraday effect
would be a useful setup for the observation of such a spatialdistribution. Measurement of magnetic moments and its spa-tial distribution using the optical probe is a commonly usedtechnique for observing the spin current. For instance, thismethod is used to observe the spin Hall effect [ 62]. Similarly,
observing the magnetization of soft magnet layers attachedto the two ends is another possible setup for the experiment[Fig. 4(b)].
The observation of spin current in a two-terminal setup
in Fig. 4(c) also enables us to see the directional flow of
spin current and to distinguish it from the spin-pumpingeffect. This setup consists of a noncentrosymmetric magneticinsulator which is sandwiched between two metallic leads;the two leads detect spin current via inverse spin Hall effect[63–65]. In the photogalvanic mechanism, the spin current in
the two leads flows toward the same direction. Therefore, theinverse spin Hall voltage of the two leads has the same sign.In contrast, in the spin pumping, the spin current diffusivelyflows outward from the magnet; the inverse spin Hall voltageis positive on one side and negative on the other. Therefore,the relative sign of the inverse spin Hall voltage of the twoleads can make a distinction between the spin pump and ourmechanism.
Finally, we shortly comment on heating effect of applied
electromagnetic waves. When we try to detect the photo-galvanic spin current with the above setups, spin pumpingmight also occur due to the heating effect of the appliedlaser. For such a case, extracting the asymmetric part of theangular-momentum distribution or inverse spin Hall voltageis important to detect an evidence for our mechanism.
B. Required intensity of ac field
We next estimate the required ac electromagnetic field
for generating an observable spin current. We here assumea spin current of J
s=10−16J/cm2is observable. This es-
timate is based on a Boltzmann theory calculation for spinSeebeck effect in a ferromagnet [ 52,74]. The details of the
estimate are briefly explained in Appendix B.W eu s et h e
following parameters as a typical value for 1D insulating mag-nets: J=100k
BJ,δ=0.1,SA=SB=1,gA−gB=0.1μB
J/T,B+=10kBJ, and a the light with a frequency which
is ¯hδω=6π¯h×1011Hz above the band gap. Here, ¯ his
the Planck constant. With these parameters, the conductivityfor the 1D AFM /FRM chain is Re[ σ(0;ω,−ω)]∼10
−14
J/(cm2T2). Therefore, the required magnitude of oscillating
magnetic field to produce a spin current of Js=10−16J/cm2
isB∼/radicalBig
Js
|Re[σ(0;ω,−ω)]|∼0.1 T. This corresponds to the elec-
tric field E=cB∼104–105V/cm under the assumption
ofc=108m/s which is a typical value of speed of
light in insulators. Similar estimate for the 3D magnetwith J=100k
BJ,J⊥=10kBJ,δ=0.1,SA=SB=1,gA−
gB=0.1μBJ/T,h+=10kBJ, andω=2π×1012Hz gives
Re[σ(0;ω,−ω)]∼10−11J/(cm2T2) and E=cB∼105–106
V/cm. The difference in the magnitude for 1D and 3D cases
is ascribed to the difference of the density of states; the 1Dsystem has a larger density of states due to the divergenceat the band edge. Our estimate predicts that the photogal-
224411-8THEORY FOR SHIFT CURRENT OF BOSONS: … PHYSICAL REVIEW B 100, 224411 (2019)
vanic spin current is experimentally observable by using a
moderate-intensity GHz /THz light.
C. Candidate material
We believe the photogalvanic spin current should be seen
generically in noncentrosymmetric magnets. In a recent work[52], the authors find three kinds of spin-light couplings
induce the spin current in a spin chain, and this work presentsphotogalvanic spin current in ordered magnets. These resultsimply the generation of photogalvanic spin current is a uni-versal phenomenon in noncentrosymmetric magnetic insu-lators. Various kinds of such noncentrosymmetric materialshave been synthesized or discovered [ 66]: a magnetoelectric
material Cr
2O3[67], ferrimagnetic diamond chains [ 68–70],
multiferroic materials [ 71,72], and a polar ladder magnet
BaFe 2Se3[73].
As we showed in the previous sections, a large density
of states for the magnon excitations is advantageous for alarge dc spin current. Therefore, quasi-1D noncentrosymmet-ric magnets such as the ferrimagnetic diamond chain andBaFe
2Se3would be promising candidates for studying the
spin current.
VI. SUMMARY AND DISCUSSION
To summarize, we studied the spin-current
generation through the shift-current mechanism inferrimagnetic /antiferromagnetic insulators. Our theory uses
a nonlinear response theory, which is a generalizationof the linear response theory. Based on this method,we find that the linearly polarized light produces themagnon current in noncentrosymmetric magnets withantiferromagnetic /ferrimagnetic order. The photogalvanic
spin current appears even at the zero temperature where nomagnon excitation exists; the current is related to excitingtwo magnons from the ground state, not to the opticaltransition of existing (thermally excited) magnons. Therelaxation-time dependence of the spin current indicates thatour photogalvanic effect is a “shift current,” i.e., the nonlinearconductivity is insensitive to the damping. Our theory clearlyshows that the shift-current mechanism, which is well knownin electron (fermion) systems, is also relevant to systemswith bosonic excitations, whose ground state is a vacuum ofbosons (zero-boson state).
Our result implies the zero-point quantum fluctuation is a
key for the shift-current type photocurrent. In the spinon spincurrent [ 52], the optical transition of a fermionic excitation
plays a crucial role for the photocurrent. In contrast to thesecases, the ground state of the ordered magnets is the zero-magnon state. Therefore, there is no optical transition of theexisting magnons. Despite the crucial difference, we find afinite photogalvanic spin current at the zero temperature. Themagnon photocurrent we found is ascribed to the opticaltransition of the “condensed” Holstein-Primakov bosons. Inthe antiferromagnets /ferrimagnets, the ground state is a con-
densate of Holstein-Primakov bosons, which is technicallyrepresented by the Bogoliubov transformation. The opticaltransition of the condensed Holstein-Primakov bosons allowsgeneration of the shift-current type photocurrent even at the
Photon−
Unit cellABAB−ℏ
+ℏ
FIG. 5. Schematic picture of the two-magnon excitation process.
The laser creates a pair of magnons with up and down spins,
respectively, β−kandαk. Blue and yellow waves, respectively, denote
typical density profiles of photoexcited magnons β−kandαk.T h e
center of mass of the magnons deviates from the center of the unit
cell owing to the noncentrosymmetry of the system.
zero temperature. On the other hand, we find that the non-
linear conductivity is zero at T=0 for the ferromagnetic
version of the model considered here. From this viewpoint,the two-magnon creation is similar to the particle-hole paircreation in semiconductors; the optical transition of fermionsfrom the valence band to the conduction band is equiva-lent to the pair creation (Fig. 5). As the condensation of
the Holstein-Primakov bosons is a manifestation of zero-point fluctuation, the zero-point fluctuation is the essence forthe shift-current type photogalvanic effects in the magneticinsulators.
Experimental setups for experimental observation of this
phenomenon include the two-terminal inverse-spin Hallmeasurements and magneto-optical Kerr effect. Our estimatesuggests that an GHz /THz light of E∼10
4–106V/cm is
sufficient for experimental observation; the response is rela-tively larger by tuning the frequency to the two-magnon ex-citations with larger density of states. The estimation impliesthis phenomenon is observable within the currently availableexperimental techniques.
ACKNOWLEDGMENTS
We thank R. Matsunaga and Y . Takahashi for fruitful dis-
cussions. We also thank W. Murata for providing Fig. 4.H . I .
was supported by JSPS KAKENHI Grants No. JP18H04222,No. JP19K14649, and No. JP18H03676, and CREST JSTGrant No. JPMJCR16F1. M.S. was supported by JSPS KAK-ENHI (Grant No. JP17K05513), and Grant-in-Aid for Sci-entific Research on Innovative Area “Nano Spin ConversionScience” (Grant No. 17H05174) and “Physical Properties ofQuantum Liquid Crystals” (Grant No. 19H05825).
224411-9HIROAKI ISHIZUKA AND MASAHIRO SATO PHYSICAL REVIEW B 100, 224411 (2019)
APPENDIX A: DERIV ATION OF KRAUT–VON BALTZ
FORMULA FOR BOSONS
Here, we shortly explain the derivation of the nonlinear
conductivity in two-band boson systems. We used the formulain Eq. ( A10) for the analytic calculations and Eq. ( A5)f o r
numerical results with a finite Gilbert damping.
We calculate the nonlinear response coefficients using
a formalism similar to the linear response theory. We as-sume a system with a time-dependent perturbation H
/prime=
−/summationtext
μˆBμFμ(t), where ˆBμis an operator and Fμ(t)i sa
time-dependent field; the Hamiltonian reads as H=H0+H/prime.
The expectation value of an observable ˆAreads as /angbracketleftˆA/angbracketright(t)=
Tr[ ˆρ(t)ˆA]/Z,where ρ(t) is the density matrix at time tand
Z≡Trρ(t). By expanding ρ(t) up to the second order in
Fμ(t), the Fourier transform of /angbracketleftA/angbracketright(t),/angbracketleftA/angbracketright(/Omega1), reads as
/angbracketleftA/angbracketright(/Omega1)=/summationdisplay
μ,ν/integraldisplay
dωσμν(/Omega1;ω,/Omega1−ω)Fμ(ω)Fν(/Omega1−ω),
(A1)
with the nonlinear conductivity
σμν(/Omega1;ω,/Omega1−ω)
=1
2π/summationdisplay
n,m,l(ρn−ρm)(Bμ)nm
ω−Em+En−i/(2τmn)
×/bracketleftbigg(Bν)mlAln
/Omega1+En−El−i/(2τmn)
−Aml(Bν)ln
/Omega1+El−Em−i/(2τmn)/bracketrightbigg
. (A2)Here, Enis the eigenenergy of the many-body eigenstate n,τmn
is the relaxation time, and Onm(O=A,Bμ,Bν)i st h em a t r i x
element of ˆOin the eigenstate basis of H0.
We here consider a periodic free-boson system in which all
matrices A,Bμ, and Bνhave the following form:
ˆO=/summationdisplay
k(α†
kβ−k)Ok/parenleftbiggαk
β†
−k/parenrightbigg
, (A3)
=/summationdisplay
k(α†
kβ−k)/parenleftbigg
(Ok)αα (Ok)αβ
(Ok)βα (Ok)ββ/parenrightbigg/parenleftbiggαk
β†
−k/parenrightbigg
,(A4)
where αk(α†
k) andβk(β†
k) are the annihilation (creation) op-
erators of the boson eigenstates with momentum k, and Ok=
Ak,Bμ
k,Bν
k. The theory for spin-wave excitations of many
antiferromagnetic models with a Néel-type order reduces tothe above form by using Holstein-Primakov and Bogoliubovtransformations.
For the two-band system, we can express Eq. ( A2)u s -
ing single-particle eigenstates. We note that A,B
μ, and Bν
for the two-band system above do not conserve the par-
ticle number. However, all operators are quadratic in theannihilation /creation operators and consist of only four terms:
α
†
kαk,β−kβ†
−k,β−kαk, andα†
kβ†
−k. Therefore, only few terms
out of the possible Wick decomposition remain nonzero,similar to that of the systems with conserved particle number.Using these features, we find
σ(/Omega1;ω,/Omega1−ω)=1
2π/summationdisplay
k,ai=α,βsgn(a3)/bracketleftbig
˜ρk,a1sgn(a2)−sgn(a1)˜ρk,a2/bracketrightbig/parenleftbig
Bμ
k/parenrightbig
a1a2
ω−˜εa2(k)+˜εa1(k)−i/(2τk)
×/bracketleftBigg /parenleftbig
Bν
k/parenrightbig
a2a3(Ak)a3a1
/Omega1+˜εa1(k)−˜εa3(k)−i/(2τk)−(Ak)a2a3/parenleftbig
Bν
k/parenrightbig
a3a1
/Omega1+˜εa3(k)−˜εa2(k)−i/(2τk)/bracketrightBigg
. (A5)
Here,
sgn(a)=/braceleftbigg
1( a=α),
−1( a=β),, (A6)
˜εa(k)=sgn(a)εa(k), (A7)
˜ρk,a=/braceleftbigg/angbracketleftα†
kαk/angbracketright0 (a=α),
/angbracketleftβ−kβ†
−k/angbracketright0(a=β),(A8)
and we assumed the relaxation time only depends on k. It is worth noting that the conductivity remains finite at T=0 despite
there are no excitations. Technically, this is a consequence of ˜ ρk,β, which is 1 at T=0. Physically, this is because the pair
creation /annihilation processes contribute to the spin current even at T=0.
We here focus on the T=0 limit. In this limit, ˜ ρk,α=0 and ˜ρk,β=1. Using these results, we obtain
σ(0;ω,−ω)=−1
π/summationdisplay
k,ai=α,β/bracketleftbigg(1+i2τω)|Bβα|2(Aαα+Aββ)
(ω−i/2τk)2−[εα(k)+εβ(k)]2/bracketrightbigg
+1
2π/summationdisplay
k,ai=α,β/braceleftbigg(Bk)βα(Ak)αβ[(Bk)ββ+(Bk)αα]
[ω−i/2τk−εα(k)−εβ(k)][εα(k)+εβ(k)+i/2τk]
+(Bk)αβ(Ak)βα[(Bk)ββ+(Bk)αα]
[ω−i/2τk+εα(k)+εβ(k)][εα(k)+εβ(k)−i/2τk]/bracerightbigg
. (A9)
224411-10THEORY FOR SHIFT CURRENT OF BOSONS: … PHYSICAL REVIEW B 100, 224411 (2019)
As we discussed in the main text, certain symmetries restrict the first term to be zero; this is the case for the models we consider
in the main text. Assuming the first term vanishes, we find
Re[σ(0;ω,−ω)]=−1
πRe/braceleftbigg(Bk)βα(Ak)αβ[(Bk)ββ+(Bk)αα]
ω2−[εα(k)+εβ(k)+i/2τ]2/bracerightbigg
. (A10)
We used this formula for the calculation of nonlinear conductivity in the main text.
APPENDIX B: BOLTZMANN THEORY FOR SPIN
SEEBECK EFFECT
The magnitude of spin current Js=10−16J/cm2is the esti-
mate for the spinon spin current produced by the spin Seebeckeffect in a recent experiment [ 74]. We here summarize the
method and result discussed in the Supplemental Material ofa recent work [ 52].
The spin current is estimated from the Seebeck effect of
magnons whose dispersion is given by
ε(k)=JSk
2+2DS+h (B1)
near the /Gamma1point of k=0. This magnon dispersion corre-
sponds to that of a ferromagnetic Heisenberg model with ex-change interaction J, uniaxial anisotropy D, and the magnetic
field hparallel to the anisotropy. The current is calculated
using the semiclassical Boltzmann theory, in which the currentreads as
J
s(r)=¯h/integraldisplaydk
(2π)3vzfk(r). (B2)
Here, fk(r) is the density of magnons with momentum kat
position randvz≡∂kzε(k) is the group velocity of magnons.
fk(r) is calculated from the Boltzmann equation with temper-
ature gradient
vk·∇rfk(r)=−fk(r)−f(0)
k(r)
τk, (B3)where f(0)
k(r) is the density at the equilibrium. Here, the
relaxation-time approximation is used to simplify the calcu-lation of collision integral on the right-hand side. The spincurrent induced by the spin Seebeck effect is estimated bysubstituting the solution of f
k(r)i nE q .( B3) into the current
formula in Eq. ( B2)
In the Boltzmann theory, the spin current by the spin
Seebeck effect reads as
Js(r)∼3(6π2)2
3J2
HS2
2αkBaT(r)/Delta1T
T(r)F/parenleftbiggJHSa2/Lambda12
2kBT(r),2DS+h
2kBT(r)/parenrightbigg
,(B4)
where /Lambda1=(6π2)1/3/ais the cutoff for magnon dispersion
and
F(a,b)=/integraldisplay1
0x4csch2(ax2+b)dx. (B5)
Using a set of typical parameters S=1,JH=100kBJ,
D=0J ,h=μBJ,a=4×10−10m,α=10−2,T=100 K,
/Delta1T=3×104K/m, we find Js∼10−12J/cm2for the fer-
romagnet. We assume this value as the typical spin-currentdensity in the insulating ferromagnets.
A recent experiment on quasi-one-dimensional magnets
observed a spin current which is 10
−4of what is typically
observed in a ferromagnetic phase [ 74]. Therefore, we assume
Js∼10−16J/cm2as the experimental resolution for the spin
current.
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224411-12 |
PhysRevB.76.224430.pdf | Microwave photovoltage and photoresistance effects in ferromagnetic microstrips
N. Mecking,1,2,*Y . S. Gui,1and C.-M. Hu†
1Department of Physics and Astronomy, University of Manitoba, Winnipeg, Canada R3T 2N2
2Institut für angewandte Physik und Zentrum für Mikrostrukturforschung, Universität Hamburg,
Jungiusstraße 11, 20355 Hamburg, Germany
/H20849Received 23 August 2007; revised manuscript received 4 November 2007; published 27 December 2007 /H20850
We investigate the dc electric response induced by ferromagnetic resonance in ferromagnetic Permalloy
/H20849Ni80Fe20/H20850microstrips. The resulting magnetization precession alters the angle of the magnetization with
respect to both dc and rf current. Consequently the time averaged anisotropic magnetoresistance /H20849AMR /H20850
changes /H20849photoresistance /H20850. At the same time the time-dependent AMR oscillation rectifies a part of the rf
current and induces a dc voltage /H20849photovoltage /H20850. A phenomenological approach to magnetoresistance is used to
describe the distinct characteristics of the photoresistance and photovoltage with a consistent formalism, whichis found in excellent agreement with experiments performed on in-plane magnetized ferromagnetic microstrips.Application of the microwave photovoltage effect for rf magnetic field sensing is discussed.
DOI: 10.1103/PhysRevB.76.224430 PACS number /H20849s/H20850: 76.50. /H11001g, 75.30.Gw, 07.57.Kp
I. INTRODUCTION
The fact that macroscopic mutual actions exist between
electricity and magnetism has been known for centuries asdescribed in many textbooks of electromagnetism.
1Now, this
subject is transforming onto the microscopic level, as re-vealed in various spin-charge coupling effects studied in thenew discipline of spintronics. Among them, striking phenom-ena are the dc charge transport effects induced by spin pre-cession in ferromagnetic metals, which feature both aca-demic interest and technical significance.
2,3Experiments
have been performed independently by a number of groupson devices with different configurations.
4–16Most works
were motivated by the study of spin torque,17,18which de-
scribes the impact of a spin-polarized charge current on themagnetic moment. In this context, Tulapurkar et al. made the
first spin-torque diode,
4and Sankey et al. detected the spin-
torque-driven ferromagnetic resonance /H20849FMR /H20850electrically.5
Both measured the vertical transport across nanostructured
magnetic multilayers. Along a parallel path, a number ofworks
19–21have been devoted to study the effect of spin
pumping. One of the interesting predictions is that injectionof a spin current from a moving magnetization into a normalmetal induces a dc voltage across the interface. To detectsuch a dc effect induced by spin pumping,
20experiments
have been performed by measuring lateral transport in hybriddevices under rf excitation.
6–8
From a quite different perspective, Gui et al. set out to
explore the general impacts of the high frequency responseon the dc transport in ferromagnetic metals,
9based on the
consideration that similar links in semiconductors have beenextensively applied for electrical detection of both spin andcharge excitations.
22Guiet al. detected, subsequently, pho-
toresistance induced by bolometric effect,9as well as
photocurrent,10photovoltage,11and photoresistance12caused
by the spin-rectification effect. A spin dynamo10was thereby
realized for generating dc current via the spin precession, andthe device was applied for a comprehensive electrical studyof the characteristics of quantized spin excitations in micro-structured ferromagnets.
11The spin-rectification effect wasindependently investigated by both Costache et al.13and
Yamaguchi et al.14and seems to be also responsible for the
dc effects detected earlier by Oh et al.15A method for dis-
tinguishing the photoresistance induced by either spin pre-cession or bolometric effect was recently established,
12
which is based on the nice work performed by Goennenweinet al. ,
16who determined the response time of the bolometric
effect in ferromagnetic metals.
While most of these studies, understandably, tend to em-
phasize the different nature of dc effects investigated in dif-ferent devices, it is perhaps more intriguing to ask the ques-tions of whether the seemingly diverse but obviously relatedphenomena could be described by a unified phenomenologi-cal formalism and whether they might arise from a similarmicroscopic origin. From a historical perspective, these twoquestions reflect exactly the spirit of two classic papers
23,24
published by Juretscheke and Silsbee et al. , respectively,
which have been often ignored but have shed light on the dceffects of spin dynamics in ferromagnets. In the approachdeveloped by Juretscheke, photovoltage induced by FMR inferromagnetic films was described based on a phenomeno-logical depiction of magnetoresistive effects.
23While in the
microscopic model developed by Silsbee et al. based on the
combination of Bloch and diffusion equations, a coherentpicture was established for the spin transport across the in-terface between ferromagnets and normal conductors underrf excitation.
24
The goal of this paper is to provide a consistent view for
describing photocurrent, photovoltage, and photoresistanceof ferromagnets based on a phenomenological approach tomagnetoresistance. We compare the theoretical results withexperiments performed on ferromagnetic microstrips in de-tail. The paper is organized in the following way: In Sec. II,a theoretical description of the photocurrent, photovoltage,and photoresistance in thin ferromagnetic films under FMRexcitation is presented. Sections II A–II D establish the for-malism for the microwave photovoltage /H20849PV /H20850and photore-
sistance /H20849PR /H20850based on the phenomenological approach to
magnetoresistance. These arise from the nonlinear couplingof microwave spin excitations /H20849resulting in magnetization M
precession /H20850with charge currents by means of the anisotropicPHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
1098-0121/2007/76 /H2084922/H20850/224430 /H2084914/H20850 ©2007 The American Physical Society 224430-1magnetoresistance /H20849AMR /H20850. Section II E compares our model
with the phenomenological approach developed by Ju-retscheke. Section II F provides a discussion concerning themicrowave photovoltage and photoresistance based on othermagnetoresistance effects /H20851like anomalous Hall effect
/H20849AHE /H20850, giant magnetoresistance /H20849GMR /H20850, and tunneling mag-
netoresistance /H20849TMR /H20850/H20852.
Experimental results on microwave photovoltage and
photoresistance measured in ferromagnetic microstrips arepresented in Secs. III and IV , respectively. We focus in par-ticular on their characteristic different line shapes, which canbe well explained by our model. In Sec. V conclusions andan outlook are given.
II. MICROWA VE PHOTOVOLTAGE AND
PHOTORESISTANCE BASED ON
PHENOMENOLOGICAL AMR
A. AMR coupling of spin and charge
The AMR coupling of spin and charge in ferromagnetic
films results in microwave photovoltage and photoresistance.The photovoltage can be understood regarding Ohms law/H20851current I/H20849t/H20850and voltage U/H20849t/H20850/H20852
U/H20849t/H20850=R/H20849t/H20850·I/H20849t/H20850. /H208491/H20850
We consider a time-dependent resistance R/H20849t/H20850=R
0
+R1cos /H20849/H9275t−/H9274/H20850which oscillates at the microwave frequency
/H9275=2/H9266fdue to the AMR oscillation arising from magnetiza-
tion precession. /H9274is the oscillations phase shift with respect
to the phase of the rf current I/H20849t/H20850. For the sake of generality
/H9274will be kept as a parameter in this work and will be dis-
cussed in detail in Sec. III C. I/H20849t/H20850takes the form I/H20849t/H20850
=I1cos /H20849/H9275t/H20850and is induced by the microwaves. It follows that
U/H20849t/H20850consists of time-dependent terms with the frequency /H9275,
2/H9275and a constant term /H20849time independent /H20850which corre-
sponds to the time average voltage and is equal to the pho-tovoltage: U
MW=/H20855R1I1cos /H20849/H9275t−/H9274/H20850cos /H20849/H9275t/H20850/H20856=/H20849R1I1cos/H9274/H20850/2
/H20849/H20855 /H20856denotes time-averaging /H20850. A demonstrative picture of the
microwave photovoltage mechanism can be seen in Fig. 1.
The second effect we investigate which is also based on
AMR spin-charge coupling is the microwave photoresistance/H9004R
MW. This has been reported recently13with the equilib-rium magnetization M0of a ferromagnetic stripe aligned to a
dc current I0. Microwave induced precession then misaligns
the dynamic magnetization Mwith respect to I0and thus
makes the AMR drop measurably. In this work, we presentresults which also show that if M
0lies perpendicular to I0
the opposite effect takes place: Microwave induced preces-
sion causes Mto leave its perpendicular position which in-
creases the AMR /H20849see Fig. 2/H20850.
After this qualitative introduction we want to go ahead
with a quantitative description of the AMR induced micro-wave photovoltage and photoresistance. Therefore, we definean orthogonal coordinate system /H20849x,y,z/H20850/H20849see Fig. 3/H20850. The y
axis lies normal to the film plane and the zaxis is aligned
with the magnetic field Hand hence with the magnetization
Mwhich is always aligned with Hin our measurements
because of the sample being always magnetized to satura-tion.
Geometrically our samples are thin films patterned to
stripe shape, so that d/lessmuchw/lessmuchl, where d,w, and lare the
thickness, width, and length of the sample. We apply Hal-
ways in the ferromagnetic film plane. For calculations basedon the stripes geometry the coordinates x
/H11032andz/H11032are defined.
These lie in the film plane. x/H11032is perpendicular and z/H11032parallel
to the stripe. The following coordinate transformationapplies: /H20849x,y,z/H20850=/H20851x
/H11032cos /H20849/H92510/H20850−z/H11032sin /H20849/H92510/H20850,y,z/H11032cos /H20849/H92510/H20850
+x/H11032sin /H20849/H92510/H20850/H20852where /H92510is the angle between Hand the stripe.
FIG. 1. /H20849Color online /H20850Mechanism of the AMR-induced micro-
wave photovoltage: Mprecesses /H20849period P/H20850in phase with the rf
current I./H20849a/H20850Mlying almost perpendicular to Iresults in low AMR.
/H20849b/H20850Mlying almost parallel to Iresults in high AMR. The time
average voltage Ubecomes nonzero.
FIG. 2. /H20849Color online /H20850Mechanism of the AMR-induced photo-
resistance. /H20849a/H20850Without microwaves /H20849MW /H20850Mlies perpendicular to
the dc current Iand the AMR is minimal /H20849b/H20850With microwaves M
precesses and is not perpendicular to Ianymore. Consequently the
AMR increases /H20849higher voltage drop U/H20850.
FIG. 3. /H20849Color online /H20850/H20849x,y,z/H20850and /H20849x/H11032,y,z/H11032/H20850coordinate systems
in front of a layout of our Permalloy film stripe /H20849200
/H110032400/H9262m2/H20850with two contacts and six side junctions.MECKING, GUI, AND HU PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-2For the microwave photovoltage and photoresistance the
longitudinal resistance R/H20849t/H20850=R0+RAcos2/H9258/H20849t/H20850of the film
stripe matters. It consists of the minimal longitudinal resis-
tance R0and the additional resistance RAcos2/H9258/H20849t/H20850from
AMR. /H9258/H20849t/H20850is the angle between the z/H11032-axis /H20849parallel to the
stripe /H20850and M.Mmoves on a sphere with the radius M0,
which is the saturation magnetization of our sample. /H9258/H20849t/H20850can
be decomposed into the angle /H9251/H20849t/H20850in the ferromagnetic film
plane and the out-of-plane angle /H9252/H20849t/H20850/H20849see Fig. 4/H20850. Conse-
quently,
cos/H9258/H20849t/H20850= cos/H9251/H20849t/H20850cos/H9252/H20849t/H20850. /H208492/H20850
Precession of the magnetization then yields oscillation of
/H9251/H20849t/H20850,/H9252/H20849t/H20850, and/H9258/H20849t/H20850. In our geometry the equilibrium magne-
tization M0encloses the in-plane angle /H92510with the stripe.
Hence in time average /H20855/H9252/H20849t/H20850/H20856=0 and /H20855/H9251/H20849t/H20850/H20856=/H92510. In general
the magnetization precession is elliptical. Its principle axis
lie along the xandyaxis and correspond to the amplitudes
/H92511and/H92521of the in- and out-of-plane angles /H92511tand/H92521tof the
rf magnetization: /H9251/H20849t/H20850=/H92510+/H92511t/H20849t/H20850=/H92510+/H92511cos /H20849/H9275t−/H9274/H20850and
/H9252/H20849t/H20850=/H92521t/H20849t/H20850=−/H92521sin /H20849/H9275t−/H9274/H20850/H20851see Fig. 4/H20852. Using Eq. /H208492/H20850we
approximate cos2/H9258/H20849t/H20850to second order in /H92511tand/H92521t:
cos2/H9258/H20849t/H20850/H11015 /H20841cos2/H9258/H20841/H92511t=/H92521t=0+/H92511t/H20879dcos2/H9258
d/H92511t/H20879
/H92511t=/H92521t=0+0
+/H92511t2
2/H20879d2cos2/H9258
d/H92511t2/H20879
/H92511t=/H92521t=0+/H92521t2
2/H20879d2cos2/H9258
d/H92521t2/H20879
/H92511t=/H92521t=0.
/H208493/H20850
The first order in /H92521tvanishes because it is proportional to
/H20849sin/H9252/H20850/H20841/H92521=0=0. It follows that
cos2/H9258/H20849t/H20850/H11015cos2/H92510−/H92511sin 2/H92510cos /H20849/H9275t−/H9274/H20850
−/H925112cos 2/H92510cos2/H20849/H9275t−/H9274/H20850
−/H925212cos2/H92510sin2/H20849/H9275t−/H9274/H20850. /H208494/H20850
This equation is now used to calculate the longitudinal
stripe voltage. To consider the general case an externallyapplied dc current I
0and a microwave induced rf current I1
are included in I/H20849t/H20850=I0+I1cos /H20849/H9275t/H20850. It follows from Eq. /H208491/H20850
thatU/H20849t/H20850=/H20851R0+RAcos2/H9258/H20849t/H20850/H20852/H20851I0+I1cos /H20849/H9275t/H20850/H20852. /H208495/H20850
Consequently U/H20849t/H20850can be written as U/H20849t/H20850=U0
+U1cos /H20849/H9275t−/H92741/H20850+U2cos /H208492/H9275t−/H92742/H20850+U3cos /H208493/H9275t−/H92743/H20850. For
the photovoltage and photoresistance only the constant term
U0, which is equivalent to the time average voltage /H20855U/H20849t/H20850/H20856,
matters. Combining Eqs. /H208494/H20850and /H208495/H20850,w efi n d
U0=I0/H20849R0+RAcos2/H92510/H20850−I1RA/H92511sin 2/H92510cos /H20849/H9274/H20850/2
−I0/H20849/H925112cos 2/H92510+/H925212cos2/H92510/H20850RA/2. /H208496/H20850
Note that /H20855sin2/H20849/H9275t−/H9274/H20850/H20856=/H20855cos2/H20849/H9275t−/H9274/H20850/H20856=1/2 and
/H20855cos/H9275tcos /H20849/H9275t−/H9274/H20850/H20856=cos /H20849/H9274/H20850/2. The first term in Eq. /H208496/H20850is
independent of the rf quantities I1,/H92511and/H92521and represents
the static voltage drop of I0. The second term is the micro-
wave photovoltage UMW. It shows no impact from the dc
current I0. The third term represents the microwave photore-
sistance /H9004RMW. It is proportional to I0and depends on the
microwave quantities /H92511and/H92521. It can be seen now that the
rf resistance amplitude R1used in the beginning of this para-
graph corresponds to R1=RA/H92511sin 2/H92510.
To analyze the magnetization’s angle oscillation ampli-
tudes /H92511and/H92521it is necessary to express them by means of
the corresponding rf magnetization Re /H20849me−i/H9275t/H20850.mis the
complex rf magnetization amplitude. Its phase is defined
with respect to I1, so that Re /H20849mxe−i/H9275t/H20850is in phase with
I1cos/H9275tat the FMR. Because M=M0+m,m=/H20849mx,my,0/H20850
can /H20849in first order approximation /H20850only lie perpendicular to
M0because MandM0have the same length /H20849M0/H20850. Hence
/H20841mx/H20841/M0=sin/H92511/H11015/H92511 and /H20841my/H20841/M0=sin/H92521/H11015/H92521 for
/H92511,/H92521/lessmuch90°.
The microwave photovoltage and photoresistance appear
whenever magnetization precession is excited. This means ifthe microwaves are in resonance with the FMR, with stand-ing exchange spin waves perpendicular to the film
10,11,25or
with magnetostatic modes.11In this article we will analyze
the FMR induced microwave photoresistance and photovolt-age.
B. Magnetization dynamics
To understand the impact of the applied rf magnetic field
Re/H20849he−i/H9275t/H20850on the microwave photovoltage and photoresis-
tance the effective susceptibilities /H9273xx,/H9273xy, and /H9273yy, which
link me−i/H9275tinside the sample with the complex external rf
magnetic field he−i/H9275t=/H20849hx,hy,hz/H20850e−i/H9275toutside the sample,
have to be calculated. Here /H9274is encoded in the complex
phase of m.
The susceptibility inside the sample /H20849magnetic field
hine−i/H9275t=/H20849hxin,hyin,hzin/H20850e−i/H9275t/H20850is determined by the Polder
tensor26/H9273ˆ/H20849received from solving the Landau-Liftshitz-
Gilbert equation28/H20850:
m=/H9273ˆhin=/H20898/H9273Li/H9273T0
−i/H9273T/H9273L0
00 0 /H20899hin, /H208497/H20850
with
FIG. 4. /H20849Color online /H20850Sketch of the magnetization precession.
The magnetic field Hencloses the angle /H92510with the current I. The
magnetization oscillation toward Ihas the amplitude /H92511and that
perpendicular to I:/H92521.MICROWA VE PHOTOVOLTAGE AND PHOTORESISTANCE … PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-3/H9273L=/H9275M/H9275r
/H9275r2−/H92752,/H9273T=/H9275/H9275 M
/H9275r2−/H92752,
where /H9275M=/H9253M0with the gyromagnetic ratio /H9253/H11015/H92620/H11003e/m
=2/H9266/H92620/H1100328 GHz /T/H20849electron charge eand mass me/H20850and
/H9275r=/H9253Hwithout damping. Approximation of our sample as a
two-dimensional film results in the boundary conditions thath
xand byare continuous at the film surface meaning hx
=hxinandby=/H92620hy=/H92620/H20851/H208491+/H9273L/H20850hyin−i/H9273Thxin/H20852. Hence
m=/H20898/H9273xx i/H9273xy0
−i/H9273xy/H9273yy0
00 0 /H20899h, /H208498/H20850
with
/H9273xx=/H9275r/H9275M+/H9275M2
/H9275r/H20849/H9275r+/H9275M/H20850−/H92752,
/H9273xy=/H9275/H9275 M
/H9275r/H20849/H9275r+/H9275M/H20850−/H92752,
/H9273yy=/H9275r/H9275M
/H9275r/H20849/H9275r+/H9275M/H20850−/H92752.
/H9273xxis identical to the susceptibility describing the propaga-
tion of microwaves in an unlimited ferromagnetic medium inV oigt geometry
29/H20849propagation perpendicular to M0/H20850./H9273xx,
/H9273xy, and /H9273yyhave the same denominator, which becomes
resonant /H20849maximal /H20850when /H9275=/H20881/H9275r2+/H9275r/H9275M. This is in accor-
dance with the FMR frequency of the Kittel formula for in-plane magnetized infinite ferromagnetic films.
30
This relatively simple behavior is due to the assumption
thathinis constant within the film stripe. This assumption is
only valid if the skin depth1/H9254of the microwaves in the
sample is much larger than the sample thickness. During ourmeasurements we fix the microwave frequency fand sweep
the magnetic field H. Consequently we find the FMR mag-
netic field H
0with
/H92752=/H92532/H20849H02+H0M0/H20850/H20849 9/H20850
and
H0=/H20881M02/4+/H92752//H92532−M0/2. /H2084910/H20850
Now we introduce Gilbert damping27/H9251Gby setting /H9275r
ª/H92750−i/H9251G/H9275with now /H92750=/H9253Hinstead of /H9275r=/H9253H. We sepa-
rate the real and imaginary part of /H9273xx,/H9273xy, and/H9273yy:
/H9273xx=/H20849/H9275r/H9275M+/H9275M2/H20850F,
/H9273xy=/H9275/H9275 MF,
/H9273yy=/H9275r/H9275MF, /H2084911/H20850
withF=/H92750/H20849/H92750+/H9275M/H20850−/H9251G2/H92752−/H92752+i/H9251G/H9275/H208492/H92750+/H9275M/H20850
/H20851/H92750/H20849/H92750+/H9275M/H20850−/H9251G2/H92752−/H92752/H208522+/H9251G2/H92752/H208492/H92750+/H9275M/H208502
/H11015/H20849H+H0+M0/H20850/H20849H−H0/H20850+i/H208492H+M0/H20850/H9251G/H9275//H9253
/H20849H+H0+M0/H208502/H20849H−H0/H208502+/H208492H+M0/H208502/H9251G2/H92752//H92532.
The approximation was done by neglecting the /H9251G2/H92752cor-
rection to the resonance frequency /H92752=/H92750/H20849/H92750+/H9275M/H20850−/H9251G2/H92752
/H11015/H92750/H20849/H92750+/H9275M/H20850which is possible if /H9251G/lessmuch1. Hence
/H9273xx,xy,yy/H11015Axx,xy,yy/H9004H/H20849H−H0/H20850+i/H9004H2
/H20849H−H0/H208502+/H9004H2, /H2084912/H20850
with/H9004H=/H20851/H208492H+M0/H20850//H20849H+H0+M0/H20850/H20852/H9251G/H9275//H9253. This can be ap-
proximated as /H9004H/H11015/H9251G/H9275//H9253if/H20841H−H0/H20841/lessmuchH0.Axx,Axy, and
Ayydetermine the scalar amplitude of /H9273xx,/H9273xy, and/H9273yy.
To analyze the FMR line shape in the following, we will
call the Lorentz line shape which is proportional to/H9004H//H20851/H20849H−H
0/H208502−/H9004H2/H20852symmetric Lorentz line shape and the
line shape proportional to /H20849H−H0/H20850//H20851/H20849H−H0/H208502−/H9004H2/H20852anti-
symmetric Lorentz line shape. A linear combination of both
will be called asymmetric Lorentz line shape. /H20841H−H0/H20841/lessmuchH0
allows us to approximate
Axx/H11015/H9253/H20849H0M0+M02/H20850
/H9251G/H9275/H208492H0+M0/H20850,
Axy/H11015M0
/H9251G/H208492H0+M0/H20850,
Ayy/H11015/H9253H0M0
/H9251G/H9275/H208492H0+M0/H20850. /H2084913/H20850
These are scalars which are independent of the dc mag-
netic field Hand hence characteristic for the sample at fixed
frequency. Indeed the assumption of Gilbert damping is notessential for the derivation of Eq. /H2084913/H20850. In the event of a
different kind of damping, /H9004Hcan also be directly input into
Eq. /H2084913/H20850replacing
/H9251G/H9275. However, because of the common-
ness of Gilbert damping, its usage here can provide a betterfeeling for the usual frequency dependence of A
xx,xy,yy. Going
ahead, Eq. /H208498/H20850becomes
m/H11015/H9004H/H20849H−H0/H20850+i/H9004H2
/H20849H−H0/H208502+/H9004H2/H20898Axx iAxy0
−iAxyAyy0
00 0 /H20899h. /H2084914/H20850
TheH-field dependencies has Lorentz line shape with an-
tisymmetric /H20849dispersive /H20850real and symmetric /H20849absorptive /H20850
imaginary part, the amplitudes Axx,±iAxy, and Ayy, respec-
tively, and the width /H9004H. Note that AxxAyy/H11015Axy2for
/H20841H−H0/H20841/lessmuchH0. Consequently, the susceptibility amplitude
tensor can be simplified to
/H20898Axx iAxy0
−iAxyAyy0
00 0 /H20899h/H11015/H20898/H20881Axx
−i/H20881Ayy
0/H20899/H20900/H20898/H20881Axx
i/H20881Ayy
0/H20899h/H20901
and Eq. /H2084914/H20850becomesMECKING, GUI, AND HU PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-4m=/H9253M0
/H9251G/H9275/H208492H0+M0/H20850/H9004H/H20849H−H0/H20850+i/H9004H2
/H20849H−H0/H208502+/H9004H2/H20898/H208811+M0/H0
−i
0/H20899
/H11003/H20900/H20898/H208811+M0/H0
i
0/H20899h/H20901. /H2084915/H20850
It is visible that the ellipticity of mis independent of the
exciting magnetic field h. Only the amplitude and phase of
mare defined by h. The reason is the weak Gilbert damping
/H9251Gfor which much energy needs to be stored in the magne-
tization precession to have a compensating dissipation.Hence little energy input and impact from happears.
From Eq. /H2084915/H20850follows that m
xandmyhave cardinally the
ratio
mx/my=i/H208811+M0/H0. /H2084916/H20850
Therefore, myvanishes for /H9275→0 and mx=imyfor/H9275→/H11009.
This means that the precession of Mis elliptical and becom-
ing more circular for high frequencies and more linear /H20849along
thexaxis /H20850for low frequencies. This description applies for
the case of an in-plane magnetized ferromagnetic film. How-ever, in the case that the sample has circular symmetry withrespect to the magnetization direction /H20849e.g., in a perpendicu-
lar magnetized disk or infinite film
10,11/H20850:/H92511=/H92521. This is the
same as in the case that /H9275→/H11009. Only in these cases the mag-
netization precession can be described in terms of one pre-cession cone angle.
13Otherwise, distinct attention has to be
paid to /H92511and/H92521/H20849see III B /H20850. Additionally, it can be seen in
Eq. /H2084915/H20850thatmy/mxis also the ratio of the coupling strength
ofmtohyandhx, respectively.
C. Microwave photoresistance
The microwave photoresistance /H9004RMWcan be deduced
from Eq. /H208496/H20850. First the microwave photovoltage is excluded
by setting the rf current I1=0. Then we only regard the mi-
crowave power dependent terms which depend on /H92511and/H92521:
/H9004RMW=/H20849/H20841U0/H20841I1=0−/H20841U0/H20841I1=0,/H92511=0,/H92521=0/H20850/I0
=RA/H20849−/H925112cos 2/H92510−/H925212cos2/H92510/H20850/2. /H2084917/H20850
If the magnetization lies parallel or antiparallel to the dc
current vector I0along the stripe /H20849/H92510=0° or /H92510=180° /H20850the
AMR is maximal. In this case magnetization oscillation /H20849/H92511
and/H92521/H20850reduces /H20849−cos 2 /H92510=−1 /H20850the AMR by /H9004RMW=− /H20849/H925112
+/H925212/H20850RA/2/H20849negative photoresistance /H20850. In contrast, if the mag-
netization lies perpendicular to I0/H20849/H92510=90°, see Fig. 2/H20850the
resistance is minimal. In this case magnetization oscillationcorresponding to
/H92511will increase /H20849−cos 2 /H92510=+1 /H20850the AMR
/H20849positive photoresistance /H20850by/H9004RMW=+/H925112RA/2/H20851oscillations
corresponding to /H92521leave /H9258/H20849t/H20850constant in this case and do
not change the AMR /H20852.
The next step is to calculate /H92511and/H92521. The dc magnetic
field dependence of /H92511=/H20841mx/H20841/M0=/H20841/H9273xxhx+i/H9273xyhy/H20841/M0and
/H92521=/H20841my/H20841/M0=/H20841−i/H9273xyhx+/H9273yyhy/H20841/M0is proportional to that of
/H20841/H9273xx/H20841,/H20841/H9273xy/H20841, and /H20841/H9273yy/H20841given in Eq. /H2084912/H20850/H20849imaginary symmetricand real antisymmetric Lorentz line shape /H20850. Squaring this
results in symmetric Lorentz line shape:
/H925112/H11008/H925212/H11008/H20879/H9004H/H20849H−H0/H20850+i/H9004H2
/H20849H−H0/H208502+/H9004H2/H208792
=/H9004H2
/H20849H−H0/H208502+/H9004H2.
Hence
/H925112=/H20841Axxhx+iAxyhy/H208412
M02/H9004H2
/H20849H−H0/H208502+/H9004H2,
/H925212=/H20841Ayyhy−iAxyhx/H208412
M02/H9004H2
/H20849H−H0/H208502+/H9004H2. /H2084918/H20850
Using Eqs. /H2084915/H20850and /H2084918/H20850, Eq. /H2084917/H20850transforms to
/H9004RMW=RA
/H20849/H9251G/H9275//H9253/H208502/H208492H0+M0/H208502/H20851−/H20849H0+M0/H20850cos 2/H92510
−H0cos2/H92510/H20852/H9004H2
/H20849H−H0/H208502+/H9004H2
/H11003/H20841hx/H20881H0+M0+ihy/H20881H0/H208412. /H2084919/H20850
The strength of the microwave photoresistance is propor-
tional to 1 //H9251G2. Weak damping /H20849small /H9251G/H20850is therefore critical
for a signal strength sufficient for detection. The magneticfield dependence shows symmetric Lorentz line shape.
The dependence of /H9004R
MWon/H92510in Eq. /H2084919/H20850reveals a sign
change and hence vanishing of the photoresistance at
cos2/H92510=1
2/H208731−H0
3H0+2M0/H20874. /H2084920/H20850
This means that the angle at which the photoresistance van-
ishes shifts from /H92510= ±45° and /H92510= ±135° /H20849for/H9275→0/H20850to
/H92510= ±54.7° and /H92510= ±125.3° respectively /H20849for/H9275→/H11009/H20850when
increasing /H9275. The reason for this frequency dependence is
the frequency dependence of the ellipcity of mdescribed at
the end of Sec. II B.
D. Microwave photovoltage
The most obvious difference in appearance between the
microwave photoresistance discussed in Sec. II C and themicrowave photovoltage discussed in this paragraph is thatthe photoresistance is proportional to the square of the rf
magnetization /H20851see Eq. /H2084917/H20850,
/H925112/H11015/H20841mx/H208412/M02and /H925212
/H11015/H20841my/H208412/M02/H20852while the photovoltage UMWis proportional to
the product of the rf magnetization and the rf current. Con-sequently, the photovoltage has a very different line shape:While the rf magnetization depends with Lorentz line shapeonH/H20851see Eq. /H2084912/H20850/H20852,I
1is independent of H. The line shape is
hence determined by the phase difference /H9274between the rf
magnetization component Re /H20849mxe−i/H9275t/H20850and the rf current
I1cos/H9275t. This effect does not play a role in the case of
photoresistance because there only one phase matters namelythat of the rf magnetization. In contrast in photovoltage mea-surements a linear combination of symmetric and antisym-metric Lorentz line shapes is found. This will be discussed indetail in the following.MICROWA VE PHOTOVOLTAGE AND PHOTORESISTANCE … PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-5To isolate the microwave photovoltage in Eq. /H208496/H20850the dc
current I0is set to 0:
UMW=/H20841U0/H20841I0=0=−I1/H92511RAsin 2/H92510cos/H9274
2. /H2084921/H20850
From Eq. /H208498/H20850we follow with
/H92511cos/H9274=R e /H20849mx/H20850=R e /H20849/H9273xxhx+i/H9273xyhy/H20850. /H2084922/H20850
We split hx=hxr+ihxiandhy=hyr+ihyiinto real /H20849hxr,hyr/H20850and
imaginary /H20849hxi,hyi/H20850part. This enables us to isolate the real part
in Eq. /H2084921/H20850using Eq. /H2084914/H20850:
UMW=I1RAsin 2/H92510
2M0/H20877/H20849Axyhyr+Axxhxi/H20850/H9004H2
/H20849H−H0/H208502+/H9004H2
+/H20849Axyhyi−Axxhxr/H20850/H9004H/H20849H−H0/H20850
/H20849H−H0/H208502+/H9004H2/H20878. /H2084923/H20850
Conclusively in contrast to the microwave photoresistance
/H20851/H9004RMW/H110081//H9251G2, see Eq. /H2084919/H20850/H20852the photovoltage is only pro-
portional to 1 //H9251G/H11008Axx,xy,yy. Thus good damping is less im-
portant for its detection.31
To understand the measurement results it will be neces-
sary to transform the coordinate system of Eq. /H2084923/H20850to
/H20849x/H11032,y,z/H11032/H20850. In this coordinate system the rf magnetic field his
constant during rotation as described in Eq. /H2084933/H20850.
To better understand the photovoltage line shape we have
a closer look on /H9274: When sweeping Hthe rf magnetization
phase is shifted by /H9274mwith respect to the resonance case
/H20849H=H0/H20850. The rf current has a constant phase /H9274Iwhich is
defined with respect to the magnetization’s phase at reso-
nance. The impact of the dc magnetic field Hon the rf cur-
rent /H20849I1,/H9274I/H20850via the FMR is believed to be negligible:
cos/H9274= cos /H20849/H9274m−/H9274I/H20850= cos/H9274mcos/H9274I+ sin/H9274msin/H9274I.
/H2084924/H20850
/H9274is determined by the /H20849complex /H20850phase of /H9273xx,/H9273xy, and/H9273yy
with respect to the resonance case /H20851Re/H20849/H9273xy,yy/H20850=0 at H=H0/H20852
during magnetic field sweep /H20851asymmetric Lorentz line shape;
see Eq. /H2084912/H20850/H20852:
tan/H9274m=Im/H20873/H9004H/H20849H−H0/H20850+i/H9004H2
/H20849H−H0/H208502+/H9004H2/i/H20874
Re/H20873/H9004H/H20849H−H0/H20850+i/H9004H2
/H20849H−H0/H208502+/H9004H2/i/H20874=H0−H
/H9004H. /H2084925/H20850
It should be noted that according to the Landau-Liftshitz
equation28happlies a torque on the magnetization and hence
excites mttransversal. That is why at resonance mxshows a
phase shift of 90° with respect to hx. Consequently in Eq.
/H2084925/H20850division by iis necessary /H20849/H9273xxand/H9273xybecome imagi-
nary at resonance /H20850.
Equation /H2084925/H20850means that in case that the applied micro-
wave frequency is higher than the FMR frequency /H20849H0
/H11022H/H20850/H9274m/H110220/H20849note that mt=me−i/H9275t/H20850,mtis delayed with re-
spect to the resonant case. The other way around /H20849H0/H11021H/H20850
the FMR frequency is higher than that of the applied micro-
wave field and mtis running ahead compared to the reso-
nance case. Using Eq. /H2084925/H20850we findcos/H9274m=/H9004H
/H20881/H20849H−H0/H208502+/H9004H2. /H2084926/H20850
Inserting Eqs. /H2084918/H20850and /H2084924/H20850–/H2084926/H20850into Eq. /H2084921/H20850gives
UMW=−RAI1sin 2/H92510
2/H20841Axxhx+iAxyhy/H20841
M0/H20873/H9004H2cos/H9274I
/H20849H−H0/H208502+/H9004H2
−/H20849H−H0/H20850/H9004Hsin/H9274I
/H20849H−H0/H208502+/H9004H2/H20874. /H2084927/H20850
The dependence on Htakes the form of a linear combi-
nation of symmetric and antisymmetric Lorentz line shapewith the ratio 1:tan
/H9274I. The symmetric line shape contribu-
tion /H20849/H11008/H9004H/H20850arises from the rf current contribution that is in
phase with the rf magnetization at FMR and the antisymmet-
ric from that out-of-phase. This gives a nice impression ofthe phase
/H9274Iof the rf current determining the line shape of
the FMR.
E. Vectorial description of the photovoltage
To complete the discussion of the microwave photovolt-
age we want to return to the approach used by Juretschke23
to demonstrate that it is consistent with the descriptionabove. In Sec. II A we started with Ohm’s law /H20851scalar equa-
tion /H208491/H20850/H20852. There we integrate an angle- and time-dependent
resistance. Here we want to start with the vectorial notationof Ohm’s law used in Juretschke’s publication /H20851Eq. /H208491/H20850/H20849Ref.
23/H20850/H20852. This integrates AMR and anomalous Hall effect AHE.
/H9267
is the resistivity of the sample and /H9004/H9267that additionally aris-
ing from AMR. RHis the anomalous Hall effect constant:
E=/H9267J+/H20849/H9004/H9267M2/H20850/H20849J·M/H20850M−RHJ/H11003M. /H2084928/H20850
We split M=M0+mtand the current density J=J0+jtinto
their dc /H20849M0and J0/H20850and rf contributions /H20851mt=Re /H20849me−i/H9275t/H20850
andjt=jcos/H9275t/H20852. Constance of /H20841M/H20841allows mt=/H20849mxt,myt,0/H20850in
first order approximation only to lie perpendicular to M0
=/H208490,0, M0/H20850. To select the photovoltage we set J0=0 and ap-
proximate equation /H2084928/H20850to second order in jtand mt. The
terms of zeroth order in both jtandmtrepresent the sample
resistance without microwave exposure and are not discussedhere. The terms of first order in either j
tormt/H20849but not both /H20850
have zero time average and do not contribute to the micro-wave induced dc electric field E
MW. Only the terms that are
simultaneously of first order in jtandmtcontribute to EMW
/H20851compare Eq. /H208494/H20850from Juretschke23/H20852:
EMW=/H9004/H9267
M02/H20855/H20849jtmt/H20850M0+/H20849jtM0/H20850mt/H20856−RH/H20855jt/H11003mt/H20856./H2084929/H20850
The/H9004/H9267dependent term represents the photovoltage con-
tribution arising from AMR and the RHdependent term that
arising from AHE. Note that a second order of mtappears
when applying a dc current J0/HS110050. It represents the photore-
sistance discussed in Sec. II C. However, it we will not bediscussed here.
In the following we will calculate the photovoltage in our
Permalloy film stripe considering its geometry which fixes
the current direction. j
t=jz/H11032tz/H11032along the stripe /H20849z/H11032is the unitMECKING, GUI, AND HU PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-6vector along the Permalloy stripe /H20850. The small dimensions
perpendicular to the stripe /H20849/lessmuchL/H20850will prevent the formation
of a perpendicular rf current. A similar approximation of a
metal grating forming a linear polarizer has been consideredpreviously.
9The photovoltage UMWis also measured along
the stripe /H20849length vector L=z/H11032/H110032.4 mm /H20850. When fluctuations
ofEMWalong the stripe are neglected considering the large
microwave wavelength, /H9261/H1101520 mm/greatermuch2.4 mm= L,w efi n d
UMWby multiplying EMWwith L:
UMW=/H20885
0L
EMWdz/H11032/H11015EMW·L
=/H9004/H9267L
M02/H20855jz/H11032t/H20849z/H11032mt/H20850/H20849M0z/H11032/H20850+jz/H11032t/H20849z/H11032M0/H20850/H20849mtz/H11032/H20850/H20856−0
=/H9004/H9267L
M0/H20855jz/H11032tmxt/H20856sin /H208492/H92510/H20850. /H2084930/H20850
This is equivalent to Eq. /H2084921/H20850which can be verified by
replacing /H9004/H9267jz/H11032tL=RAI1cos /H20849/H9275t/H20850and mxt=/H92511M0cos /H20849/H9275t−/H9274/H20850.
Time averaging results in the additional factor cos /H20849/H9274/H20850/2.
As discussed in Sec. II F the contribution belonging to the
anomalous Hall effect has no impact in this geometry be-cause it can only generate a photovoltage perpendicular tothe rf current, i.e., perpendicular to the stripe.
Comparing our results to those of Juretschke and
Egan,
23,31we note that an equation similar to Eq. /H2084930/H20850has
been derived in the formula for ey0in Eq. /H2084931/H20850in Juretsch-
ke’s publication.23There the photovoltage is measured par-
allel to the rf current as done in our stripe. However, it has tobe noted that the coordinate system is defined differently.The major difference compared to our system is that we usea stripe shaped film to lithographically define the direction ofthe rf current I
1, while the direction of his left arbitrary. In
contrast to that, Juretschke and Egan23,31define the direction
of the rf magnetic field and rf current by means of theirmicrowave setup. In Eq. /H2084931/H20850/H20849e
y0/H20850from Juretschke23this
results in the additional factor cos /H9258/H20849which is equivalent to
cos/H92510in our work /H20850compared to Eq. /H2084930/H20850. This arises from
the definition of hfixed parallel to the rf current /H20851compare
Eq. /H2084933/H20850/H20852.
F. Other magnetoresistive effects that couple spin
and charge current
In this section we present other magnetoresistive effects
which can generate photovoltage and photoresistance like theAMR. This selection gives a broader view on the range ofeffects for which the photovoltage and photoresistance canbe discussed in terms of the analysis presented in this work.In principle every magnetoresistive effect can modulate thesample resistance and thus rectify some of the rf current tophotovoltage.
One magnetoresistive effect is the anomalous Hall effect
AHE in ferromagnetic metals that was /H20849together with the
AMR /H20850the basis for the discussion of Juretschke.
23There a
current with perpendicular magnetization generates a voltageperpendicular to both. Under microwave exposure this alter-nates with the microwave frequency but in an asymmetricway due to the modulated AHE arising from magnetization
precession. The asymmetric voltage has a dc contribution/H20849photovoltage /H20850,
31which can be measured using a two-
dimensional ferromagnetic film with the magnetization nei-ther parallel nor perpendicular to it. The photovoltage in-duced by AHE appears in the film plane perpendicular to therf current and is small
25for Permalloy /H20849Ni80Fe20/H20850. Also a
photoresistive effect which alters the AHE can be expected if
the magnetization lies out-of-plane.
Other examples for magnetoresistive effects are GMR and
TMR structures which exhibit a photovoltage mechanismsimilar to that in AMR films. The difference is that there thedirection of the ferromagnetic layer magnetization with re-spect to the current does not matter. Effectively instead thedirection of the magnetization Mof one ferromagnetic layer
with respect to that of another layer is decisive /H20849see Fig. 5/H20850.
Exciting the FMR in one layer yields again oscillation of thesample resistance R/H20849t/H20850and thus gives the corresponding rf
voltage U/H20849t/H20850a nonzero time average /H20849photovoltage /H20850.
4,32This
is usually stronger than that from AMR films due to the
generally higher relative strength of GMR and TMR com-pared to AMR.
It should be noted that in current studies of the microwave
photovoltages effect in multilayer structures, the focus is oninterfacial spin transfer effects.
4–8,19–21,32It remains an in-
triguing question whether interfacial spin transfer effects andthe effect revealed in our approach based on phenomenologi-cal magnetoresistance might be unified by a consistent mi-croscopic model, as Silsbee et al. have demonstrated for de-
scribing both bulk and interfacial spin transport under rfexcitation.
24
Multilayer structures also provide a nice example that
photovoltage generation can also be reversed when the oscil-lating magnetoresistance, transforms a dc current into an rfvoltage,
33instead of transforming an rf current into a dc
voltage /H20849photovoltage /H20850. This gives a new kind of microwave
source and seems—although weaker—also possible in AMRand AHE samples.
It can be reasoned that like microwave photovoltage the
microwave photoresistance can also be based on GMR orTMR instead of AMR: When aligning the two magnetiza-
FIG. 5. /H20849Color online /H20850Microwave photovoltage in a GMR/TMR
heterostructure /H20851ferromagnetic /H20849M/H20850/nonferromagnetic/ferromag-
netic /H20849Mf/H20850/H20852: The dynamic magnetization Mprecesses /H20849period P/H20850in
phase with the current I./H20849a/H20850Mlies almost perpendicular to Mf:
High GMR/TMR. /H20849b/H20850Mlies almost parallel to Mf: Low
GMR /TMR ⇒nonzero time average of the voltage U.MICROWA VE PHOTOVOLTAGE AND PHOTORESISTANCE … PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-7tions of both ferromagnetic layers in a GMR or TMR struc-
ture microwave induced precession of one magnetization isexpected to increase the GMR/TMR because of the arisingmisalignment with the other magnetization. With the magne-tizations initially antiparallel the opposite effect, a micro-wave induced resistance decrease, is expected. Further workdemonstrating these effects would be interesting.
III. PHOTOVOLTAGE MEASUREMENTS
A. Measurement setup
The sample we use to investigate the microwave photo-
voltage consists of a thin /H20849d=49 nm /H20850Permalloy
/H20849Ni 80% ,Fe 20% /H20850film stripe /H20849200/H9262m wide and 2400 /H9262m
long /H20850with 300 /H11003300/H9262m2bond pads at both ends /H20849see Fig.
3/H20850. These are connected via gold bonding wires and coaxial
cables to a lock-in amplifier. For auxiliary measurements/H20849e.g., Hall effect /H20850six additional junctions are attached along
the stripe /H20849see Fig. 3/H20850.
The resistance of the film stripe is R
0+RA=85.0 /H9024for
parallel and R0=83.6 /H9024for perpendicular magnetization.
Hence the conductance is /H9268=1//H9267=2.9/H11003106/H9024−1m−1and
the relative AMR is /H9004/H9267//H9267=1.7%. The absolute AMR is RA
=1.4/H9024. This is in good agreement with previous
publications.9–11
The film is deposited on a 0.5 mm thick GaAs single crys-
tal substrate, and patterned using photolithography and liftoff techniques. The substrate is mounted on a 1 mm polyeth-ylene print circuit board which is glued to a brass plate hold-ing it in between the poles of an electromagnet. This pro-vides the dc magnetic field B=
/H92620H /H20849maximal /H110151T /H20850. The
sample is fixed 1 mm behind the end of a WR62 /H2084915.8
/H110037.9 mm /H20850hollow brass waveguide which is mounted nor-
mal to the Permalloy film plane. The stripe is fixed along the
narrow waveguide dimension. In the Kuband
/H2084912.4–18 GHz /H20850, that we use in our measurements, the WR62
waveguide only transmits the TE 01mode.1The stripe was
fixed with respect to the waveguide but was left rotatablewith respect to H. This allows the stripe to be parallel or
perpendicular to H, but keeps the magnetic field always in
the film plane. A high precision angle readout was installedto indicate
/H92510./H20849See Fig. 6/H20850.
The waveguide is connected to an HP83624B microwave
generator by a coaxial cable supplying frequencies of up to20 GHz and a power of 200 mW. The power is howeverlater significantly reduced by losses occurring within the co-axial cable, during the transfer to the hollow waveguide andby reflections at the end of the waveguide. Microwave pho-tovoltage measurements are performed sweeping the mag-netic field while fixing the microwave frequency. The sampleis kept at room temperature.
To avoid external disturbances the photovoltage was de-
tected using a lock-in technique: A low frequency /H2084927.8 Hz /H20850
square wave signal is modulated on the microwave CW out-
put. The lock-in amplifier, connected to the Permalloy stripe,is triggered to the modulation frequency to measure the re-sulting square wave photovoltage across the sample. Insteadof the photovoltage also the photocurrent can be measured.
10Its strength I0can be found when setting U0=0 in Eq. /H208496/H20850
/H20849instead of I0=0 /H20850.
B. Ferromagnetic resonance
The measured photovoltage almost vanishes during most
of the magnetic field sweep but shows one pronounced reso-nance of several
/H9262V . The strength and line shape of this
resonance are strongly depending on /H92510and will be dis-
cussed in Sec. III C. A line shape dependence of the photo-voltage on the microwave frequency is also found. The pho-tovoltage with respect to the strength of the externalmagnetic field Hand the microwave frequency f=
/H9275/2/H9266can
be seen in a gray scale plot in Fig. 7, in which the resonance
can be identified with the FMR by the corresponding fits/H20849dashed line /H20850because the Kittel equation /H208499/H20850/H20849Ref. 30/H20850for
ferromagnetic planes /H20849our Permalloy film /H20850applies. The mag-
netic parameters found are
/H92620M0/H110151.02 T and /H9253/H110152/H9266/H92620
/H1100328.8 GHz /T. They are in good agreement with previous
publications.9,10
The exact position of the FMR is obscured by its strongly
varying line shape. We overcome this problem by the pro-
FIG. 6. /H20849Color online /H20850Sketch of the measurement geometry. A
1 mm thick polyethylene plate is glued on a brass holder. On top ofthe polyethylene a GaAs substrate is glued. On the substrate thePermalloy /H20849Py/H20850stripe is defined. This is electrically wired to a volt-
age amplifier for photovoltage measurements. For photoresistancemeasurements an additional current source is connected parallel tothe voltage amplifier, which is not shown explicitly here.
FIG. 7. /H20849Color online /H20850Gray scale plot of the measured fre-
quency and magnetic field dependence of the microwave photovolt-age at
/H92510=47°. The dashed line shows the calculated FMR fre-
quency /H20851see Eq. /H208499/H20850/H20852. The photovoltage intensity is strongly
frequency dependent because of the frequency dependent wave-guide transmission.MECKING, GUI, AND HU PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-8ductive line shape analysis in Sec. III C. It is found that H0is
slightly dependent on /H92510. This can be attributed to a small
demagnetization field perpendicular to the stripes but withinthe film plane arising from the finite stripe dimensions in thisdirection. So, when M
0lies perpendicular to the stripe, H0
slightly increases compared to the value fulfilling the Kittel
equation for a plane /H20851see Eq. /H208499/H20850/H20852. In the parallel and perpen-
dicular case we use the approximation of our film stripe as anellipsoid, where we can use the corresponding Kittelequation
30/H20849demagnetization factors Nx,Ny, and Nzwith re-
spect to the dc magnetic field /H20850:
/H9275=/H9253/H20881/H20851H0+/H20849Nx−Nz/H20850M0/H20852/H20851H0+/H20849Ny−Nz/H20850M0/H20852. /H2084931/H20850
The difference of the resonance field between the case
that M0lies in the film plane parallel to the stripe and per-
pendicular is 1.6 mT /H208490.7% /H20850atf=15 GHz. From this we can
calculate the small demagnetization factor Nx/H11032=0.085% per-
pendicular to the Permalloy stripe within the film plane using
Eq. /H2084931/H20850. From the sum rule34follows: Ny=1− Nx/H11032−Nz/H11032=1
−0.085%−0=99.915%. Nz/H11032/H20849parallel to the stripe /H20850can be
assumed to be negligibly small. This matches roughly with
the dimension of the height to width ratio /H2084949 nm:200 /H9262m/H20850
of the sample. For the stripe presented in Sec. IV similar but
stronger demagnetization effects are found.
Now we will have a closer look on the magnetic proper-
ties of the investigated film. Again at f=15 GHz we find
using Eq. /H2084910/H20850:H0=0.219 T. Using asymmetric Lorentz line
shape fitting as described in Sec. III C we get /H9251G=0.0072.
Consequently, Axx=231.1, Axy=97.1, and Ayy=40.8 accord-
ing to Eq. /H2084913/H20850.
Because of /H9251G=0.0072 the magnetization precession does
impressive n/H1101522 turns before being damped to 1 /eof its
initial amplitude /H20849n=1/2/H9266/H9251G/H20850. Therefore the ellipcity of m
is almost independent of h/H20849see Sec. II B /H20850. It can be calcu-
lated from Eq. /H2084916/H20850thatmx/my=2.38 iat/H9275/2/H9266=15 GHz.
To check the validity of our approximation /H20849d/lessmuch/H9254, see
Sec. II B /H20850we will now regard the skin depth /H9254atf
=15 GHz in our sample /H20849d=49 nm /H20850. For/H9262=/H92620/H20849away from
the FMR /H20850we find /H9254=/H208812//H9275/H9262/H9267=2.4/H9262m. Hence /H9254/greatermuchd. This
is in accordance with our approximation that his almost
constant within the Permalloy film /H20849see II B /H20850. However, in
the vicinity of the FMR: /H20841/H9262/H20841/greatermuch/H92620and for the same fre-
quency and conditions as above: /H9262L=/H208491+/H9273L/H20850/H92620=133 i/H92620at
the FMR. Thus we approximate /H9254FMR=/H208812//H9275/H20841/H9262L/H20841/H9267
=210 nm. Hence /H9254FMRis still significantly larger than dand
our approximation is still valid.
Finally we can summerize that for samples with weak
damping /H20849/H9251G/lessmuch/H9275//H9275M/H20850like ours the approximation H/H11015H0
gives results with impressive precision /H20849see Fig. 8/H20850because
its discrepancies are limited to the unimportant magneticfield ranges with /H20841
/H9273xx/H20841,/H20841/H9273xy/H20841, and /H20841/H9273yy/H20841/lessmuch1, which are far
away from the FMR.
C. Asymmetric Lorentz line shape
Although in Sec. III B the frequency dependence of the
FMR field is verified with the gray scale plot in Fig. 7,i ti s
still desirable to receive a more accurate picture of the cor-responding line shape which is found to be strongly angulardependent /H20849see Fig. 8/H20850.I nE q . /H2084927/H20850it is shown that the mag-
netic field dependence of U
MWexhibits asymmetric Lorentz
line shape around H=H0. Hence UMWtakes the form
UMW=UMWSYM+UMWANT
=U0SYM /H9004H2
/H20849H−H0/H208502+/H9004H2+U0ANT/H9004H/H20849H−H0/H20850
/H20849H−H0/H208502+/H9004H2.
/H2084932/H20850
This is used to fit the magnetic field dependence of the
photovoltage in Fig. 8. For clearness the symmetric /H20849absorp-
tive /H20850and antisymmetric /H20849dispersive /H20850contributions are shown
separately in Fig. 9. A small constant background is found
and added to the antisymmetric contribution. The back-ground could possibly arise from other weak nonresonantphotovoltage mechanisms.
The fits agree in an unambiguous manner with the mea-
sured results. Hence they can be used to determine the Gil-bert damping parameter with high accuracy:
/H9251G/H11015/H9253/H9004H//H9275
/H11015/H208490.72% ±0.015% /H20850. However, if the magnetization lies par-
allel or perpendicular to the stripe the photovoltage vanishes
/H20851see Eq. /H2084921/H20850/H20852. Hence we can only verify /H9251Gwhen the mag-
netization is neither close to being parallel nor perpendicularto our stripe.
The corresponding
/H9251G=1//H9275/H9270in the Nickel sample of
Egan and Juretschke,31can be estimated using the ferromag-
netic relaxation time /H9270from their Table II. It lies in between
/H9251G=0.12 and 0.18, so being more than 16 times higher than
the value in our sample. This makes the line shape approxi-mation of Sec. II D invalid for their case. Consequently, a
FIG. 8. /H20849Color online /H20850Fitting /H20849black line /H20850of the microwave
photovoltage signal /H20849dots /H20850for different angles /H92510atf=15 GHz. The
black horizontal bars indicate zero signal.MICROWA VE PHOTOVOLTAGE AND PHOTORESISTANCE … PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-9much more elaborated line shape analysis23appears neces-
sary.
In Fig. 8the photovoltage along the stripe is presented at
four different angles /H92510. The signal to noise ratio is about
1000 because of the carefully designed measurement system,where the noise is suppressed to less than 5 nV. Because ofthis good sensitivity we can verify the matching of ourtheory from Sec. II with the measurement results in greatdetail. /H20849See Fig. 10./H20850
In the following we want to investigate the angular depen-
dence in detail. Therefore, we transform the coordinate sys-tem of Eq. /H2084923/H20850according to the transformation presented inSec. II A. Doing so we can separate the contributions from
h
x/H11032,hy, and hz/H11032:
UMW=RAI1sin /H208492/H92510/H20850
2M0/H20877/H20851Axyhyr+Axx/H20849hx/H11032icos/H92510
−hz/H11032isin/H92510/H20850/H20852/H9004H2
/H20849H−H0/H208502+/H9004H2+/H20851Axyhyi
+Axx/H20849hz/H11032rsin/H92510−hx/H11032rcos/H92510/H20850/H20852/H9004H/H20849H−H0/H20850
/H20849H−H0/H208502+/H9004H2/H20878.
/H2084933/H20850
hx/H11032,hy, and hz/H11032are fixed with respect to the hollow brass
waveguide and its microwave configuration and do not
change when /H92510is varied.
We find that the angular dependence of the line shape in
Eq. /H2084933/H20850exhibits two aspects: An overall factor sin /H208492/H92510/H20850and
individual factors /H20849sin/H92510, cos/H92510, and 1 /H20850for the terms be-
longing to the different spatial components of h. The overall
factor sin /H208492/H92510/H20850arises from the AMR photovoltage mecha-
nism and results in vanishing of the photovoltage signal at
/H92510=0°, 90°, 180°, and 270°. This means if M0lies either
parallel, antiparallel, or perpendicular to the stripe axis. Thisis illustrated in Fig. 11and is clearly observed in our mea-
surements /H20849see Fig. 10/H20850. We take this as a strong support for
the photovoltage being really AMR based.
Another support comes from the similarity with the planar
Hall effect.
35The planar Hall effect generates a voltage UPHE
perpendicular to the current in ferromagnetic samples /H20849width
W/H20850when the magnetization M0lies in the current-voltage
plane. It arises as well from AMR and vanishes when M0lies
either parallel or perpendicular to the current axis.
The similarity arises because of the AMR only generating
a transversal resistance when the current is not lying alongthe principle axis of its resistance matrix /H20849parallel or perpen-
FIG. 9. /H20849Color online /H20850Symmetric and antisymmetric contribu-
tions to the asymmetric Lorentz line shape fit from Fig. 8/H20849black /H20850.A
small constant background is found and added to the antisymmetriccontribution.
FIG. 10. /H20849Color online /H20850Bars show the angular dependence of
the amplitude of the symmetric /H20849U0SYM, thin bars /H20850and antisymmet-
ric /H20849U0ANT, thick bars /H20850contribution to the microwave photovoltage
atf=15.0 GHz. Note that both the symmetric and antisymmetric
contribution vanish for /H92510=0°, 90°, 180°, and 270°. The lines rep-
resent the corresponding fits by means of Eq. /H2084934/H20850. The inlet shows
the geometry of the investigated Permalloy stripe and the coordi-nate systems from Fig. 3/H20849note: z
/H20648H/H20850.
(a)
(b)
FIG. 11. /H20849Color online /H20850When the magnetic field Hlies parallel
or perpendicular to the stripe, the time average voltage vanishes. /H20849a/H20850
Hlies perpendicular to I: Precession of the magnetization Mleaves
/H20849after half a period P/2/H20850the angle /H9258between the axis of MandI
unchanged. Hence the AMR /H20849and so voltage U/H20850is also unchanged.
The photovoltage vanishes. /H20849b/H20850His parallel to I:/H9258and the AMR
stay constant during the precession of Mand the time average of I
is zero. This means that only when His neither parallel nor perpen-
dicular to the stripe a photovoltage is generated.MECKING, GUI, AND HU PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-10dicular to the magnetization /H20850. This is the same geometrical
restriction as shown above for the microwave photovoltage/H20851see Eq. /H2084921/H20850and Fig. 11/H20852.
We want to emphasize the importance that in any of these
microwave photovoltage experiments, due to the unusuallystrong angle dependence, it is important to pay attention tothe exact angle adjustment of the sample with respect to thedc magnetic field Hwhen measuring under high symmetry
conditions /H20849Hparallel or perpendicular to the stripe /H20850to avoid
involuntary signal changes due to small misalignments. Asfound in 90° out-of-plane configuration
10already a misalign-
ment as small as a tenth of a degree can yield a tremendousphotovoltage change in the vicinity of the FMR.
Finally we want to come back to the individual angular
dependencies of the photovoltage contributions arising fromthe different external magnetic field components. In additionto the sin /H208492
/H92510/H20850proportional dependence of UMWonmx, also
the strength with which mxis excited by hdepends on /H92510.
This is displayed in Fig. 12and reflected by the three terms
in Eq. /H2084933/H20850depending on hx/H11032,hy, and hz/H11032with cos /H92510,1 ,a n d
sin/H92510factors, respectively. Hence the symmetric U0SYMand
antisymmetric U0ANTLorentz line shape contribution to UMW
are fitted in Fig. 10with
U0SYM=/H20851Uz/H11032Ssin /H20849/H92510/H20850+Ux/H11032Scos /H20849/H92510/H20850+UyS/H20852sin /H208492/H92510/H20850,
U0ANT=/H20851Uz/H11032Asin /H20849/H92510/H20850+Ux/H11032Acos /H20849/H92510/H20850+UyA/H20852sin /H208492/H92510/H20850./H2084934/H20850
From Uz/H11032S,Ux/H11032S, and UyAthe dynamic magnetic field com-
ponents hz/H11032i,hx/H11032i,hyiwhich are 90° out-of-phase with respect
to the rf current I1can be determined using Eq. /H2084933/H20850and
from Uz/H11032A,Ux/H11032A, and UySwe find hz/H11032r,hx/H11032r, and hyrwhich are in
phase with I1.
In principle I1can be separately deduced using the bolo-
metric effect12as discussed in Sec. IV A. However, for the
sample used here our usage of multiple stipes does not allowus to address the bolometric heating to one single stripe.Consequently the strength of I
1is unknown so that we can
not determine h, but only hI1.Besides, considering the special dynamic magnetic field
configuration in our rectangular hollow waveguide no rfmagnetic field component h
z/H11032is expected to be generated
along the waveguides narrow dimension /H20849z/H11032axis /H20850by the
TE01mode1/H20849which is the microwave configuration of our
waveguide /H20850. It follows that the sin /H20849/H92510/H20850terms in Eq. /H2084934/H20850
vanishes. This results in the additional symmetry UMW /H20849/H92510/H20850
=−UMW /H20849−/H92510/H20850, which is clearly observed in our measure-
ments /H20849see Fig. 10/H20850. This symmetry was broken when we
used a round waveguide.
The vanishing of hz/H11032in our waveguide will allow us to
plot the direction of htwo-dimensional /H20849instead of three-
dimensional /H20850in Fig. 13. A small deviation from the symme-
tryUMW /H20849/H92510/H20850=−UMW /H20849−/H92510/H20850is however found and arises from
a small hz/H11032component /H20849see Table I/H20850which is not displayed in
Fig. 13. It might arise from the fact that the rf microwave
magnetic field hat the waveguide end already deviates from
the TE 01mode.
TABLE I. Determination of the rf magnetic field hat the
200/H9262m wide stripe at 1 mm distance from the waveguide end by
means of Eq. /H2084933/H20850.Ux/H11032,y,z/H11032S,Ux/H11032,y,z/H11032A: Measured amplitudes of the
contributions to the symmetric and antisymmetric Lorentz line
shape of UMW /H20851see Eq. /H2084934/H20850/H20852with the angular dependence belong-
ing to x/H11032,y, and z/H11032, respectively /H20849taken from the fitting in Fig. 10/H20850.
Axx,xy: Corresponding amplitudes of /H9273xx,xy.hx/H11032,y,z/H11032r,hx/H11032,y,z/H11032i:r fm a g -
netic field strength calculated from Ux/H11032,y,z/H11032S,Ux/H11032,y,z/H11032A/H20849in-phase and
90° out-of-phase contribution with respect to the current /H20850.
Ux/H11032,y,z/H11032SUx/H11032,y,z/H11032AAxx Axy I1hx/H11032,y,z/H11032rI1hx/H11032,y,z/H11032i
/H20849/H9262V/H20850/H20849 mA/H9262T//H92620/H20850
x/H11032 +2.60 +2.55 231.1 −15.7 +16.4
y +0.95 +0.30 97.1 +14.0 +4.4
z/H11032 +0.12 0.00 231.1 0.0 −0.7
FIG. 12. /H20849Color online /H20850Angular dependent coupling of the mag-
netization Mto the dynamic magnetic field h=/H20849hx/H11032,hy,hz/H11032/H20850. Only
the components of hperpendicular to M0can excite precession of
Mand therefore generate a dynamic m.hyis always exciting m.
The excitation strength of hx/H11032andhz/H11032is angular dependent /H20851com-
pare Eq. /H2084933/H20850/H20852. Here the two symmetry cases are shown: M /H20849a/H20850
perpendicular /H20849only hz/H11032andhycan excite M/H20850and /H20849b/H20850parallel /H20849only
hx/H11032andhycan excite M/H20850to the stripe.
FIG. 13. /H20849Color online /H20850Direction and ellipticity of the rf mag-
netic field hdisplayed by showing the path I1·hpasses during one
cycle. This is shown at the location of the three stripes /H20849these lie
normal to the picture on top of the gray GaAs substrate; the200
/H9262m wide stripe to the right /H20850for two sample positions. I1·hwas
determined by means of Eq. /H2084933/H20850. The upper right path corresponds
to the I1·hfrom Table I. The hatched edges indicate metal surfaces
reflecting microwaves. Within the waveguide the rf magnetic field h
corresponding to the TE 10mode is displayed in the background.MICROWA VE PHOTOVOLTAGE AND PHOTORESISTANCE … PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-11D. Determination of the rf magnetic field direction
Using the different angular dependencies of the three
symmetric and three antisymmetric terms in Eq. /H2084933/H20850hI1can
be determined. We make the assumption that the stripe itselfdoes not influence the rf magnetic field configuration, what isat least the case when further reducing its dimensions. Thusthe film stripe becomes a kind of detector for the rf magneticfield h.
To test this an array of 36 additional 50
/H9262m wide and
20/H9262m distant Permalloy stripes of the same height and
length as the 200 /H9262m wide stripe described above /H20849see Sec.
III A /H20850was patterned beside this one. The 50 /H9262m wide stripes
were connected with each other at alternating ends to form along meandering stripe.
9Four stripes were elongated on both
ends to 300 /H11003300/H9262m2Permalloy contact pads. For the outer
two stripes and the single 200 /H9262m stripe hI1is calculated
from the measured photovoltage using Eq. /H2084923/H20850. Table I
shows the measured voltage and the corresponding hI1for
the 200 /H9262m stripe at 1 mm distance from the waveguide. hI1
for all three stripes is displayed in Fig. 13, while positioning
the sample at two distances /H208491 and 3.5 mm, respectively /H20850
from the waveguide end. For comparison the rf magneticfield hconfiguration of the TE
01mode is displayed in the
background. From other measurements we can estimate thatI
1lies somewhere in the 1 mA range.
It is worth noting that possible inhomogeneities of the rf
magnetic field hwithin the Permalloy stripes will be aver-
aged because UMWis linear in h. Determining the sign of the
rf magnetic field components from the photovoltage contri-butions signs exhibits a certain complexity because a lot ofattention has to be paid to the chosen time evolution /H20849e
i/H9275tor
e−i/H9275t/H20850and coordinate system /H20849right hand or left hand /H20850. How-
ever, the sign only reflects the phase difference with respectto the rf current. The rf current is admittedly not identical fordifferent stripe positions. Consequently the comparison ofthe rf magnetization phase at different stripe locations is ob-scured.
It is a specially interesting point concerning microwave
photovoltage that the phase of the individual components ofthe rf magnetic field with respect to the rf current, and there-fore also with respect to each other can be determined. Thephase information is encoded in the line shape, which is aparticular feature of the microwave photovoltage describedin this work.
At this point only determining hI
1is possible because I1is
unknown. However, in Sec. IV A, an approach to determineI
1using the bolometric effect is presented. Using this ap-
proach the bolometric photoresistance is the perfect supple-ment for the photovoltage. It delivers unknown I
1with al-
most no additional setup.
IV . PHOTORESISTANCE MEASUREMENTS
The principle difficulties when detecting the AMR in-
duced photoresistance are to increase the microwave powerfor a sufficient signal strength and to reduce the photovoltagesignal, which is in general much stronger and superimposeswith the photoresistance. We overcome the microwavepower problem by using high initial microwave power/H20849316 mW /H20850and a coplanar waveguide /H20849CPW /H20850,
10which emits
the microwaves as close as possible to the Permalloy film
stripe /H208490.137/H1100320/H110032450/H9262m3/H20850with which we detect the
photoresistance. Its resistance is found to be R=880 /H9024and
the AMR RA=15/H9024. Its magnetic properties /H20849/H9253,M0/H20850are al-
most identical to that of the sample investigated in Sec. III.We use again lock-in technique like in III A with now anadditional dc current from a battery to measure resistanceinstead of voltage. The strong microwave power results instrong rf currents within the sample which give a speciallystrong photovoltage signal /H20851see Eq. /H2084927/H20850/H20852. To achieve a suf-
ficiently strong photoresistance signal the dc current I
0and rf
current I1have to be increased to the maximal value that
does not harm the sample /H20849a few mA, hence I0/H11015I1/H20850.
Ignoring the trigonometric factors sin 2 /H92510, cos 2 /H92510, and
cos/H9274as well as the photoresistance term depending on /H92521
/H20849that is always smaller than /H92511/H20850the photovoltage signal
/H20851UMW=/H92511sin /H208492/H92510/H20850cos/H9274RAI1/2, Eq. /H2084921/H20850/H20852and the photore-
sistance signal /H20851/H9004RMWI0/H11015−/H925112cos /H208492/H92510/H20850RAI0/2, Eq. /H2084917/H20850/H20852be-
come almost identical. But the major difference is that the
photoresistance is multiplied by /H925112and the photovoltage
only by /H92511.A s/H92511is particularly small /H20849/H110211°/H20850in our experi-
ments, this means that /H9004RMWI0is much smaller than UMW.
However, suppressing UMWis possible because it vanishes
for/H92510=0°, 90°, 180°, 270° /H20851see Eq. /H2084921/H20850/H20852. A very precise
tuning of /H92510with an accuracy below 0.1° is necessary to
suppress UMWbelow /H9004RMWI0. Fortunately in contrast to
/H20841UMW /H20841,/H20841/H9004RMW /H20841is maximal for /H92510=0°, 90°, 180°, 270°. In
the following, we will first discuss the bolometric photore-sistance arising from microwave heating of the sample andafterwards the AMR induced photoresistance that is dis-cussed above.
A. Bolometric (nonresonant)
The AMR-induced /H9004RMWis not the only photoresistive
effect present in our Permalloy film stripe. Also nonresonantheating by the microwave rf current I
1results in a /H20849bolomet-
ric/H20850photoresistance. The major difference compared to the
AMR-based photoresistance is that the bolometric photore-sistance is almost independent of the applied dc magneticfield Hand that its reaction time to microwave exposure is
much longer /H20849in the order of ms /H20850than that of the AMR-based
photoresistance /H208491/
/H9251G/H9275, in the order of ns /H20850.12The nonreso-
nant bolometric photoresistance is found with a typicalstrength of /H20849/H9004R/R/H20850/P=0.2 ppm /mW /H20849see Fig. 14/H20850.
The bolometric heating power P
bolarises from resistive
dissipation of the rf current I1in the sample /H20849Pbol=/H20855RI2/H20856
=RI02+RI12/2/H20850. This can hence be used to determine I1, which
is otherwise an unknown in Eq. /H2084927/H20850.I1can be determined
for example by finding the corresponding dc current I0with
the same bolometric resistance change. However, especiallyin the sample we use the thermal conductivity of the GaAscrystal on which our Permalloy stripes were deposited is sohigh /H2084955 W /mK /H20850that the different stripes are strongly ther-
mally coupled. Thus we cannot address the bolometric signal
of one stripe solely to the rf current of the same stripe. Thiseffect was verified comparing the resistance changes fromone stripe while applying a dc current through an otherstripe. Hence determination of /H20841I
1/H20841by means of Eq. /H2084927/H20850isMECKING, GUI, AND HU PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-12only possible when using a substrate material with low heat
conductance /H20849e.g., glass /H20850or by not depositing more than one
stripe.
B. AMR based (resonant)
In contrast to the nonresonant bolometric photoresistance
in Sec. IV A, the typically 50 times weaker resonant AMR-based photoresistance is very hard to detect. After visualizingit by using the CPW and turning the sample into a highsymmetry position /H20849parallel or perpendicular to H/H20850it is still
necessary to regard the difference of the photoresistancemeasured with the same current strength but with reversedcurrent sign instead of measuring with only one current di-rection. This eliminates the remaining still significant photo-voltage signal, which depends on the absolute currentstrength possibly due to bolometric AMR change.
Measurement results are presented in Fig. 14for f
=3.8 GHz. There it can be seen that /H20849as deduced in Sec.
II C /H20850, if the stripe lies parallel to the magnetization, the AMR
is maximal and the resistance decreases when the FMR isexcited /H20849negative photoresistance /H20850. In contrast in the perpen-
dicular case the AMR is minimal and we measure a resis-tance increase /H20849positive photoresistance /H20850. This behavior is
schematically explained in Fig. 15. The curves in Fig. 14
show the photoresistance at the FMR with symmetric Lor-entz line shape as predicted in Sec. II C.
Using Eq. /H208499/H20850we calculate
/H92620H0=16.6 mT. However, a
deviation of H0is found in both, parallel /H20849/H92620H0=11.1 mT /H20850
and perpendicular /H20849/H92620H0=25.3 mT /H20850, configuration. This is
due to demagnetization which gives rise to an FMR shift
with respect to the result from the infinite film approximation/H20851compare Eq. /H2084931/H20850/H20852.N
x=0.7% can be assumed because of
this shift.Using Eq. /H2084916/H20850we find that for our conditions mx/my
=7.9 i. Consequently, we can neglect the contribution from
/H92521=/H20841my/H20841/M0in Eq. /H2084917/H20850and find /H20841mx/H20841=13 mT using
/H9004RMW=/H20849/H9004R/R/H20850R=1.23 m /H9024 /H20849from Fig. 14/H20850and thus /H92511
=/H208812/H9004RMW/RA=0.73° and /H92521=/H92511//H20841mx/my/H20841=0.09°. The
smallness of /H92521is the reason for the resonant photoresistance
strength being almost identical for M /H20648IandM/H11036I/H20849although
the sign is reversed /H20850. We must expect /H20841mx/H20841,/H92511, and/H92521to be
even a little bit larger due to our lock-in measurement tech-nique only detecting the sinusoidal contribution to the squarewave signal from the microwaves.
The photoresistive decrease is in accordance with that
found by Costache et al.
13There the magnetization is aligned
with the current /H20849/H92510=0 /H20850. Thus applying an rf magnetic field
decreases the AMR from RAtoRAcos2/H9258c. This is used to
determine the precession cone angle /H9258cby assuming /H9258c=/H92511
=/H92521.
The height to width ratio of the strip is 35 nm to 300 nm.
Because of the magnetization lying along the stripe,13the
magnetization precession strongly deviates from being circu-lar. Using the corresponding parameters
/H92620M0=1.06 T, /H9253
=2/H9266/H92620/H1100328 GHz /T, and /H9275/2/H9266=10.5 GHz /H20850, we find from
Eq. /H2084916/H20850that the ratio of the amplitudes is mx/my=3.15 i.
This indicates strongly elliptical precession and suggests thatdistinguishing
/H92511and/H92521would provide a refined description
compared to that using the cone angle /H9258c, as discussed in
Sec. II C.
V . CONCLUSIONS
We have presented a comprehensive study of dc electric
effects induced by ferromagnetic resonance in Py micro-strips. A theoretical model based on a phenomenological ap-proach to magnetoresistance is developed and compared with
FIG. 14. /H20849Color online /H20850Photoresistance /H9004RMWmeasurement
/H20849stripe resistance R/H20850. The curves show the difference between the
signals /H9004Uwith I0= +5 mA and I0=−5 mA at P=316 mW: /H9004R
=/H20851/H9004U/H20849I0=+5 m A /H20850−/H9004U/H20849I0=−5 mA /H20850/H20852/10 mA. The subtraction
suppresses the photovoltage dependence on absolute /H20841I0/H20841/H20849for ex-
ample from bolometric AMR change /H20850. For both curves the dc mag-
netic field H/H20849and so M/H20850was applied within the film plane, but for
/H20849a/H20850parallel to the stripe /H20849and hence to the dc current I0/H20850and for /H20849b/H20850
perpendicular. A nonresonant background of about 70 ppm frombolometric photoresistance is found. It is decreases by about1.2 ppm when the sample is turned from parallel to perpendicularconfiguration. This is caused by the 1.7% AMR which changes R
and the bolometric signal proportionally. The FMR signal has al-most Lorentz line shape and its position is significantly changingwhen the sample is turned from parallel to perpendicular position/H20849see Sec. IV B /H20850.
FIG. 15. /H20849Color online /H20850Demonstration of the angular depen-
dence of the microwave photovoltage: Without microwaves /H20851/H20849a/H20850,
/H20849c/H20850/H20852the AMR is /H20849a/H20850minimal in perpendicular configuration of M
andIand /H20849c/H20850maximal in parallel configuration. When the micro-
waves are switched on the resistance /H20849b/H20850increases in parallel con-
figuration and /H20849d/H20850decreases in perpendicular configuration.MICROWA VE PHOTOVOLTAGE AND PHOTORESISTANCE … PHYSICAL REVIEW B 76, 224430 /H208492007 /H20850
224430-13experiments. These provide a consistent description of both
photovoltage and photoresistance effects.
We demonstrate that the microwave photoresistance is
proportional to the square of magnetization precession am-plitude. In the special case of circular magnetization preces-sion, the photoresistance measures its cone angle. In the gen-eral case of arbitrary sample geometry and ellipticalprecession, we refine the cone angle concept by defining twodifferent angles, which provide a precise description of themicrowave photoresistance /H20849and photovoltage /H20850induced by
elliptical magnetization precession. We show that the micro-wave photoresistance can be either positive or negative, de-
pending on the direction of the dc magnetic field.
In contrast to the microwave photoresistance, we find that
the microwave photovoltage is proportional to the product ofthe in-plane magnetization precession component with the rfcurrent. Consequently, it is sensitive to the magnetic fielddependent phase difference between the rf current and the rfmagnetization. This results in a characteristic asymmetricphotovoltage line shape, which crosses zero when the rf cur-rent and the in-plane component of the rf magnetization areexactly 90° out of phase. Therefore, the microwave photo-voltage provides a powerful insight into the phase of magne-
tization precession, which is usually difficult to obtain.
We demonstrate that the asymmetric photovoltage line
shape is strongly dependent on the dc magnetic field direc-tion, which can be explained by the directional dependenceof the magnetization precession excitation. By using themodel developed in this work, and by combining such asensitive geometrical dependence of the microwave photo-voltage with the bolometric photoresistance which indepen-dently measures the rf current, we are now in a position todetect and determine the external rf magnetic field vector,which is of long standing interest with significant potentialapplications.
ACKNOWLEDGMENTS
We thank G. Roy, X. Zhou, and G. Mollard for technical
assistance and D. Heitmann, U. Merkt, and the DFG for theloan of equipment. N.M. is supported by the DAAD. Thiswork has been funded by NSERC and URGP grants toC.-M.H.
*nmecking@physnet.uni-hamburg.de
†hu@physics.umanitoba.ca
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224430-14 |
PhysRevB.80.134401.pdf | Influence of three-dimensional dynamics on the training effect
in ferromagnet-antiferromagnet bilayers
Paolo Biagioni, *Antonio Montano,†and Marco Finazzi
LNESS, Dipartimento di Fisica, Politecnico di Milano, Piazza Leonardo da Vinci 32, 20133 Milano, Italy
/H20849Received 10 April 2009; revised manuscript received 19 July 2009; published 1 October 2009 /H20850
Training effect in exchange-bias systems consists of a variation in coercivity and symmetry between the first
reversal after field cooling and the following loops. It has been shown, in the frame of a two-dimensionalcoherent-rotation approach, that training might be explained in terms of an initial noncollinear arrangement ofthe antiferromagnetic spins after field cooling, which relaxes to a collinear arrangement during the first reversal/H20851A. Hoffmann, Phys. Rev. Lett. 93, 097203 /H208492004 /H20850/H20852. In this paper, we extend the model to three dimensions,
by numerically solving the Landau-Lifshitz-Gilbert equation describing the precession motion of magneticmoments. We are thus able to discuss the validity of Hoffmann’s model within a three-dimensional approach,with parameter values similar to those in the original publication, and to enlighten the role of out-of-planeanisotropies and Gilbert damping in determining the occurrence of training. Moreover, when realistic valuesare considered for the magnetocrystalline anisotropy of the system, we find that no training is reproducedwithin our extended model, suggesting that symmetry-driven irreversibilities might not be as relevant aspreviously believed for training effect.
DOI: 10.1103/PhysRevB.80.134401 PACS number /H20849s/H20850: 75.40.Mg, 75.60.Ej, 75.60.Jk, 75.70.Cn
I. INTRODUCTION
Magnetization reversal in bilayer systems constituted by a
ferromagnet /H20849FM /H20850and an antiferromagnet /H20849AFM /H20850is often
characterized by a shift and by enhanced coercivity in thehysteresis loop. This effect, known as exchange bias /H20849EB/H20850,
finds fundamental applications in the field of magnetic-datastorage and has originated a large debate and a flourishing ofpublications in the attempt to give it a firm description.
1
While it is now widely recognized, both experimentally
and theoretically, that EB mechanisms must be described at amicroscopic level by taking the detailed spin structure at theinterface and inside the AFM into account,
2–9some peculiar
features of magnetization reversal have been proposed to de-pend mainly on the average exchange and anisotropy ener-gies, which are well described even within the frame of mac-roscopic coherent-rotation models.
An important example is given by the training effect /H20849TE/H20850,
resulting in a different coercivity and a change in symmetrybetween the first reversal after field cooling and the follow-ing loops.
10–19It has been suggested that two mechanisms
can contribute to this phenomenon: on the one hand, in somepolycrystalline samples, TE seems to be connected with thedomain microstructure in the EB system and with thermallyactivated depinning of AFM spins, as corroborated by ex-perimental and numerical results.
15,19On the other hand, ex-
periments reveal that in some systems TE can be indepen-dent on the crystalline quality of the film.
13Hoffmann has
shown20that this observation might be related to the aniso-
tropy symmetry properties of the magnetic films and inter-preted in terms of a difference in the arrangement of themacroscopic magnetic moments in the AFM between the ini-tial condition right after field cooling /H20849noncollinear arrange-
ment /H20850and all the following configurations /H20849collinear arrange-
ment /H20850: while the first loop begins with the system in its
minimum-energy configuration, which could be reached bysurmounting energy barriers during field cooling, all the fol-lowing loops lead to a metastable configuration, which modi-
fies the symmetry and coercivity of reversal in the FM layer.This mechanism is fully determined by exchange and aniso-tropy energies in the system, within a macroscopic descrip-tion of magnetic moments, and has been reproduced by mini-
mizing the total energy of the system as a function of theapplied field. However, two approximations represent a pos-sible limit to the application of such a model:
20/H20849i/H20850the system
is treated by assuming an infinite in-plane anisotropy, fullyconfining the moments in the plane of the film and /H20849ii/H20850the
values chosen for the in-plane magnetocrystalline anistropyof the AFM, when compared with the exchange energies, areroughly two to three orders of magnitude larger than those inrealistic EB systems.
One of the most intriguing aspects of hysteresis-loop
simulation in EB systems are the very different results thatare sometimes obtained when minimization algorithms arecompared with calculations where the full Landau-Lifshitz-Gilbert /H20849LLG /H20850equation is solved to describe precession of
the magnetic moments. A remarkable example is given in apaper by Schulthess and Butler,
21who showed how Koon’s
model for FM-AFM interfaces22is not a good description for
EB when moment precession, rather than energy minimiza-tion, is taken into account. There is a fundamental reason forthis: EB reversal dynamics, as also evident in Hoffmann’smodel for TE, develops in an energy landscape which showsmany local energy minima. In this situation, the transientdynamics of magnetic moments, i.e., their path toward equi-librium, can largely influence the final local energy minimumwhere the system falls. Different paths lead to a differentability of overcoming energy barriers and therefore to differ-ent final steady states.
23The simulation of a magnetic mo-
ment preceding around an effective field therefore allows thesystem to reach new final states, which could not be reachedby means of simple in-plane rotation.
In the frame of this discussion, an important issue is to
extend Hoffmann’s model for symmetry-driven TE, wherePHYSICAL REVIEW B 80, 134401 /H208492009 /H20850
1098-0121/2009/80 /H2084913/H20850/134401 /H208497/H20850 ©2009 The American Physical Society 134401-1the interplay between local and global minima plays a key
role, to a three-dimensional /H208493D/H20850description for the evolu-
tion of the FM-AFM system by means of LLG equations. Arecent paper by Saha and Victora
24already applies LLG dy-
namics to a polycrystalline FM-AFM bilayer composed ofnoninteracting, randomly oriented grains. Their paper high-lights the role of micromagnetic domain evolution on EB andTE. However, the presence of many grains while making thesystem more realistic, partially conceals the role of aniso-tropy in the TE. Indeed, for some parameter values, they findtraining even in the case of uniaxial magnetocrystalline an-isotropy in the AFM, at variance with Hoffmann’s model,probably due to the many degrees of freedom made availableby the randomly oriented grains.
In this work we simulate the behavior of an FM-AFM
bilayer by solving the LLG equation. In the first part of thepaper, we show that the LLG equation can indeed reproduceTE within a three-dimensional extension of Hoffmann’smacroscopic model, when an initial in-plane noncollinear ar-rangement of the AFM moments is considered and as long asparameter values similar to those in the original manuscriptare chosen. In doing this, we also enlighten some differenceswhich emerge in the magnetic-moment configurations. Inparticular, the presence of a finite out-of-plane anisotropyopens a new channel for AFM spin relaxation by out-of-plane reorientation, which turns out to be strictly connectedwith the occurrence of training. To further enlighten the keyrole of the precession motion, we also show how changes inthe Gilbert damping constant can as well rule the occurrenceof training, by determining different paths towardequilibrium.
In the second part of the paper, we choose the system
parameters, particularly the magnetocrystalline anisotropy inthe AFM, in order to better adhere to the properties of real-istic EB bilayers. In doing so we find that, although noncol-linear initial conditions can still be obtained, they now pos-sess a large out-of-plane component. When hysteresis loopsare then simulated by solving the LLG equations, no trainingis observed anymore, a hint that symmetry-driven effectsmight be responsible for TE only in the limit of very largemagnetocrystalline anisotropy.
II. MODEL
The system under study is an FM/AFM bilayer, modeled
following Ref. 20in the frame of a coherent-rotation ap-
proach as an ensemble of three magnetic moments MF,
MAF1, and MAF2, the first one describing the FM layer and
the other two for the two sublattices representing the AFMlayer /H20849see Fig. 1/H20850. The total energy of the system can be
written as the sum of Zeeman, anisotropy, and exchange/H20849AFM exchange and interface exchange /H20850contributions
E
tot=EZeeman +Eanisotropy +Eexchange . /H208491/H20850
The temporal evolution of each magnetic moment Miis de-
scribed by the LLG equation25–27dMi
dt=−/H9253Mi/H11003Hi+/H9251
/H20841Mi/H20841Mi/H11003dMi
dt, /H208492/H20850
where /H9253is the gyromagnetic ratio of the electron spin, /H9251is
the Gilbert damping constant, and Hiis the effective field
acting on the ith magnetic moment, defined as
Hi=−/H11509Etot
/H11509Mi. /H208493/H20850
A normalized LLG equation can then be written by substi-
tuting mi=Mi//H20841Mi/H20841and/H9270=/H9253t. Hence the system dynamics is
fully determined once the damping constant /H9251and the total
energy Etotare provided. The latter can be written by consid-
ering the following expressions:
EZeeman =−/H20858
iH0·Mi; /H208494a/H20850
Eanisotropy =/H20858
i/H20841Mi/H20841/H20875−1
2k1,i/H20849mi,x4+mi,y4+mi,z4/H20850
+k2,imi,y2+k3,imi,z2/H20876; /H208494b/H20850
Eexchange =−/H20858
i/HS11005jJi,jMi·Mj, /H208494c/H20850
where H0is the external applied field, k1,i/H110220 and k2,i/H110210 are
anisotropy constants describing cubic and uniaxial magneto-crystalline anisotropy, respectively, k
3,i/H110220 describes in-
plane anisotropy due to both shape anisotropy /H20849for the FM /H20850
and interface anisotropy associated to the removal of inver-sion symmetry in a layered structure /H20849for both FM and AFM
moments /H20850, and finally J
i,jis the exchange coupling constant
between the ith and the jth magnetic moment. The exchange
coupling energy contains the AFM exchange coupling/H20849J
AF1,AF2 /H110210/H20850and the interface exchange coupling of the FM
layer with the first /H20849JF,AF1/H110220/H20850and the second /H20849JF,AF2/H110220/H20850
AFM sublattice. As the effect of a finite temperature is notincluded in the model, results must be interpreted as a zero-temperature limit.
In order to implement a numerical solution for the LLG
equation, a suitable constraint must be imposed to numeri-
z
xy/CID2F
/CID1F
mAF1
mAF2mF
FIG. 1. /H20849Color online /H20850Sketch of the simulated FM-AFM system
with the polar coordinate system used throughout the paper.BIAGIONI, MONTANO, AND FINAZZI PHYSICAL REVIEW B 80, 134401 /H208492009 /H20850
134401-2cally ensure conservation of the magnitude of magnetic mo-
ments during their evolution. A natural choice is to rewritethe normalized LLG equation in polar coordinates, whichautomatically guarantees /H20841m/H20841=1. The vectorial LLG equation
/H20849three equations, three unknowns for each moment /H20850is thus
replaced by the following system /H20849two equations, two un-
knowns for each moment, see Fig. 1/H20850:
d
/H9277
d/H9270+/H9251d/H9272
d/H9270sin/H9277=−hxsin/H9272+hycos/H9272; /H208495a/H20850
−/H9251d/H9277
d/H9270+d/H9272
d/H9270sin/H9277=hzsin/H9277−/H20849hxcos/H9272+hysin/H9272/H20850cos/H9277.
/H208495b/H20850
This finally yields a system of six nonlinear, strongly inter-
twined ordinary differential equations, which is solved bymeans of a multistep adaptive algorithm based on numericaldifferentiation formulas of order 5.
28
In order to provide the numerical code with suitable initial
conditions, mimicking the state of the system after field cool-ing, we find the absolute minimum-energy configuration, fora given set of parameters, by means of a global search heu-ristic method, namely, a genetic algorithm, because of theoccurrence of many local minima.
29,30After each iteration, a
fast deterministic algorithm is used to refine the search be-fore fitness evaluation.
III. SIMULATIONS FOR LARGE
MAGNETOCRYSTALLINE ANISOTROPY
In this section we simulate the FM-AFM system under
study with parameter values in the range of those used byHoffmann.
20As a suitable initial condition for each loop
simulation, the minimum-energy configuration of the mag-netic moments for a given set of parameters must be calcu-lated, in order to reproduce the state of the system after fieldcooling. Such an initial condition has already been derivedby Hoffmann in the two-dimensional limit of very largeAFM cubic magnetocrystalline anisotropy /H20849AFM moments
always aligned along an easy axis /H20850and no FM magnetocrys-
talline anisotropy /H20849FM moment always aligned with the ap-
plied field /H20850.
20His results show the occurrence of three differ-
ent regimes as a function of magnitude and direction of theapplied field, namely, parallel, antiparallel, and noncollinear/H20849perpendicular /H20850in-plane arrangements of the two AFM mo-
ments M
AF1and MAF2. It is also shown that if the cubic
anisotropy term is replaced by a uniaxial term in the AFMthen the noncollinear phase disappears. It seems to be im-plicit in the paper that whenever the system is found in thenoncollinear phase after field cooling then its evolution ischaracterized by training in the FM hysteresis loop.
We first test our genetic algorithm within a two-
dimensional energy description /H20849i.e., fixing
/H9277=90° in our
model /H20850in order to reproduce the phase-diagram analytically
calculated by Hoffmann but with finite anisotropy values. Weuse J
F,AF1 =JF,AF2 =−0.4 JAF1,AF2 ,k1,F=−0.1 JAF1,AF2 MF,
k1,AF1 =k1,AF2 =−0.4 JAF1,AF2 MF, no uniaxial anisotropy /H20849k2,i
=0/H20850, and in-plane anisotropy only for the FM layer /H20849k3,F=−JAF1,AF2 MF,k3,AF1 =k3,AF2 =0/H20850. We indeed reproduce the
trend already obtained by Hoffmann, just with slightlyshifted boundaries between different phases /H20849see Fig. 2/H20850.W e
also find, in agreement with Ref. 20that the presence of
uniaxial anisotropy prevents the stabilization of a noncol-linear AFM configuration /H20849not shown /H20850.
We then include the
/H9277degree of freedom in our descrip-
tion and maintain the same parameters as above. In doingthis, we find again that three phases are present /H20849see Fig. 3/H20850,
however the antiparallel phase now corresponds to a con-figuration where the two AFM moments have their main pro-jections along the out-of-plane anisotropy axis with just asmall canting /H20849/H1102130° with respect to the polar axis /H20850. This
out-of-plane configuration can be attributed to the inherentin-plane frustration determined by the competition between0 5 10 15 20 25 30 35 40 450.51.01.52.02.53.03.54.0
|(+)/ |
JH JF,AF 0 AF1,AF2
Field azimuth (degrees )
FIG. 2. Results from two-dimensional energy minimization with
the genetic algorithm /H20849gray-scale boxes /H20850and comparison with Hoff-
mann’s analytical model /H20849solid line /H20850. The arrows represent the ar-
rangement of the two AFM sublattices. Each box is the result of onesimulation with parameter values corresponding to the center of thebox. White, gray, and black boxes correspond to in-plane noncol-linear, parallel, and antiparallel arrangements, respectively.
0 5 10 15 20 25 30 35 40 450.51.01.52.02.53.03.54.0
|(+)/ |
JH JF,AF 0 AF1,AF2
Field azimuth (degrees )
FIG. 3. Results from three-dimensional energy minimization
with the genetic algorithm. The arrows represent the arrangement ofthe two AFM sublattices. Each box is the result of one simulationwith parameter values corresponding to the center of the box.White, gray, and black boxes correspond to in-plane noncollinear,in-plane parallel, and out-of-plane antiparallel arrangements, re-spectively. In the out-of-plane antiparallel arrangement, a smallcanting is present, as described in the text.INFLUENCE OF THREE-DIMENSIONAL DYNAMICS ON … PHYSICAL REVIEW B 80, 134401 /H208492009 /H20850
134401-3AFM exchange coupling and interface exchange coupling,
which is relaxed in the out-of-plane arrangement. Also thetwo in-plane parallel and antiparallel phases show a small
canting with respect to the anisotropy axes.
Within our extension of Hoffmann’s model to three di-
mensions, we simulate training by first applying the minimi-zation genetic algorithm to find the system energy minimum,in order to describe the configuration of magnetic momentsafter field cooling. We then cover the whole hysteresis looptwice /H20849from negative fields to positive fields and back /H20850in
order to evaluate the occurrence of training. For each fieldvalue, the LLG equations are solved numerically by takingthe configuration obtained at the end of the previous step asinitial condition and finally obtaining the new steady-statearrangement. The typical integration time for each step, cho-sen in order to fully reach a steady state, is
/H9270/H1122910 000, while
we use /H9251=0.1 as a damping constant. This damping value
will be modified later on in order to discuss its influence onthe simulation results.
Representative hysteresis loops are shown in Fig. 4, cal-
culated starting from an initial condition of noncollinear ar-rangement for the two AFM sublattices /H20849white area of the
phase diagram in Fig. 3/H20850. We indeed find that, for parameter
values similar to those presented by Hoffmann in his ex-amples, TE is well reproduced /H20849see panel m
F/H20648in Fig. 4/H20850. All
the situations where we have occurrence of training do notqualitatively differ from this one. Loops are simulated withthe same set of parameters used for Fig. 3. The field is ap-
plied in the plane of the sample with a
/H9272=20° tilt with re-
spect to the cubic anisotropy axis. In the figure we show thethree components for each of the three magnetic momentsinvolved in the simulations, namely, the two components inthe plane of the sample /H20849parallel and perpendicular to the
applied field, respectively /H20850and the one perpendicular to the
sample surface. By looking at the out-of-plane component ofthe two AFM moments /H20849see panels m
AF1zandmAF2zin Fig.
4/H20850, it is clearly seen that during the first half loop they lay inthe plane of the sample, while their main projection is along
the surface normal during the whole following evolution.This relaxation from an in-plane to an out-of-plane arrange-ment takes place during the first FM reversal and can beattributed to the already mentioned in-plane frustration deter-mined by the interplay between AFM and interface ex-change.
Such an out-of-plane relaxation is a peculiar feature
emerging from our model and it appears to be strictly con-nected with the occurrence of training. In order to prove this,we show in Fig. 5simulation results obtained with the same
parameters and same initial conditions as in Fig. 4but with
an in-plane anisotropy term added to the two AFM sublat-tices /H20849k
3,AF1 =k3,AF2 =−JAF1,AF2 MF/H20850, preferentially confining
them in the sample plane. It is clearly seen that now theevolution of the AFM moments is fully confined in the planeof the sample /H20849see panels m
AF1zandmAF2zin Fig. 5/H20850and that
this is accompanied by no training /H20849see panel mF/H20648in Fig. 5/H20850.
Such a behavior highlights that not only the symmetry of thein-plane anisotropy but also its out-of-plane component
0.02 0.04 0.06 0.08 0.1 0.12 0.14 0.16 0.18 0.20.30.40.5
Dampin g/c97KJ1,AF/|AF FM|Training
No training
FIG. 6. Graph showing the occurrence of training for a FM-
AFM bilayer as a function of the damping coefficient /H9251and for
three different values of the AFM cubic anisotropy constantsk
1,AF1 =k1,AF2. All other simulation parameters are the same as those
used for the simulation shown in Fig. 4.-1.0-0.50.00.51.0mF/CID2/CID2
mFmFzmF/CID3
mAF1
mAF2-1.0-0.50.00.51.0
-1.0-0.50.00.51.0
H0 AF1,AF2/J-0.3 -0.15 0 0.15 0.3
H0/JAF1,AF2-0.3 -0.15 0 0.15 0.3
H0/JAF1,AF2-0.3 -0.15 0 0.15 0.3mAF1 /CID2/CID2
mAF2 /CID2/CID2mAF2 /CID3mAF1 /CID3
mAF2 zmAF1 z1st loop
2nd loop
FIG. 4. /H20849Color online /H20850Results from LLG simulations of TE. For
each magnetic moment the three components are shown, namely,the in-plane component parallel /H20849
/H20648/H20850to the applied field, the in-plane
component perpendicular /H20849/H11036/H20850to the applied field, and the out-of-
plane /H20849z/H20850component. The hysteresis loop is covered twice.-1.0-0.50.00.51.0mF/CID2/CID2
mFmFzmF/CID3
mAF1
mAF2-1.0-0.50.00.51.0
-1.0-0.50.00.51.0
H0 AF1 ,AF2 /J-0.3 -0.15 0 0.15 0.3
H0/JAF1 ,AF2-0.3 -0.15 0 0.15 0.3
H0/JAF1 ,AF2-0.3 -0.15 0 0.15 0.3mAF1 /CID2/CID2
mAF2 /CID2/CID2
mAF2 /CID3mAF1 /CID3
mAF2 zmAF1 z1st loop
2nd loop
FIG. 5. /H20849Color online /H20850Results from LLG simulations with in-
plane anisotropy for the AFM layers. All other parameters are thesame as in Fig. 4. For each magnetic moment the three components
are shown, namely, the in-plane component parallel /H20849
/H20648/H20850to the ap-
plied field, the in-plane component perpendicular /H20849/H11036/H20850to the ap-
plied field, and the out-of-plane /H20849z/H20850component. The hysteresis loop
is covered twice.BIAGIONI, MONTANO, AND FINAZZI PHYSICAL REVIEW B 80, 134401 /H208492009 /H20850
134401-4might play a significant role in determining the occurrence of
training.
It should then be stressed that, within our approach based
on LLG equations, an in-plane noncollinear arrangement ofthe two AFM magnetic moments after field cooling is a nec-essary but not sufficient condition for the occurrence of train-ing. We indeed find that for several combinations of param-eter values, for which we can find a cooling field leading toan initial AFM noncollinear arrangement, nontrained loopsare nevertheless obtained. This can be attributed to the pecu-liar spiral-like path of the transient moment dynamics, lead-ing to a different ability of overcoming energy barriers com-pared with simulations based on energy minimization. Thisfinding is in full analogy with the analysis by Schulthess andButler
21about Koon’s model for FM-AFM interfaces,22
where the introduction of LLG equations extended the origi-nal results showing new possible regimes.
As already pointed out, in such complex systems, such as
FM-AFM interfaces, where the interplay between local andglobal minima plays an important role in the system dynam-ics, different transient spatial paths can lead to very different
final steady states. This is also true when the evolution ischanged by modification in the damping constant
/H9251. A larger
damping value shrinks the spiral-like evolution of the mag-netic moments and therefore makes again different final-energy minima available. This is clearly shown in Fig. 6,
where we analyze the occurrence of training as a function ofthe damping constant
/H9251for three different values of the AFM
cubic anisotropy constants k1,AF1 =k1,AF2. As a lower value
for/H9251determines a longer characteristic evolution time for
the system, we increase the value of /H9270accordingly, in order
to ensure that a steady-state configuration is always reached.All other simulation parameters are the same as the onesused for the simulation in Fig. 4. The relevance of this find-
ing is evident when considering that many common factorscan influence the damping constant, for example, the size ofa magnetic device,
31impurities,32–34or its operating
temperature.35,36It should also be pointed out that, in FM/
AFM LLG simulations, care is often taken in order to ensurethat the results are independent of the value of the damping
FIG. 7. /H20849Color online /H20850Results from three-dimensional energy minimization with the genetic algorithm, for a system with realistic
magnetocrystalline anisotropy /H20849see text /H20850:/H20849a/H20850azimuthal angle /H20841/H92721−/H92722/H20841between the two in-plane projections of the AFM moments and /H20849b/H20850
average polar tilt /H20841/H92771−/H92772/H20841/2 of the two AFM moments. The arrows nearby the color bar are a sketch of the AFM moment geometry.INFLUENCE OF THREE-DIMENSIONAL DYNAMICS ON … PHYSICAL REVIEW B 80, 134401 /H208492009 /H20850
134401-5parameter.21,24While this might be the case for a single FM
structure, our findings show that in the dynamics of a FM/AFM bilayer the damping constant might play a relevant rolein determining the local minimum reached during the rever-sal dynamics.
IV . SIMULATIONS FOR SMALL MAGNETOCRYSTALLINE
ANISOTROPY
As briefly discussed in the introduction, the parameter
values used in Hoffmann’s model, where all exchange andanisotropy energies are of the same order of magnitude,might be a poor description for many experimentally rel-evant systems showing EB and TE. If we restrict ourselvesto the case of CoO/Co bilayers, as in Ref. 20, the
magnetocrystalline anisotropy constant takes a value ofabout 2 /H1100310
5erg /cm3,37corresponding to roughly
2/H1100310−6eV /atom once the lattice parameter of CoO is
taken into account. On the other side, typical valuesfor the exchange integrals are 2 /H1100310
−4eV /atom and
2/H1100310−3eV /atom for the nearest-neighbor 90° exchange
and the second-neighbor 180° exchange, respectively.38
Therefore, in a realistic model the exchange energy shouldbe two to three orders of magnitude larger than the magne-tocrystalline anisotropy. As for the AFM coupling at the in-terface between the FM layer and the two AFM sublattices, ithas been evaluated, assuming Heisenberg exchange acrossthe interface, to be on the order of 1 meV /nm
2.39In order to
be used in our model, where all the spins of each sublatticeare represented by a single magnetic moment, such a valueshould be scaled down by the number of atomic layers con-stituting the film, which might be of some tens to some hun-dreds. Therefore, the interface exchange energy is also ex-pected to be two to three orders of magnitude lower than theAFM exchange coupling.
According to the discussion above, we run new simula-
tions for the initial conditions after field cooling, by means ofthe genetic algorithm. All parameter values are the same asbefore, except for the AFM magnetocrystalline anisotropyand the interface exchange coupling, which are set tok
1,AF1 =k1,AF2 =−0.01 JAF1,AF2 MF and JF,AF1 =JF,AF2
=−0.01 JAF1,AF2 , respectively.
The results are shown in Fig. 7. Due to the low magneto-
crystalline anisotropy, the phase diagram now shows a num-ber of configurations where the AFM moments are notaligned close to any of the anisotropy axes. Therefore, tobetter convey the complex 3D arrangement, we plot both theangle /H20841
/H92721−/H92722/H20841between the in-plane components of the two
AFM moments /H20851panel /H20849a/H20850/H20852and the angle /H20841/H92771−/H92772/H20841/2/H20851panel
/H20849b/H20850/H20852, which for AFM moments laying on opposite sides withrespect to the equatorial plane /H20849which is the case with our set
of parameters /H20850provides the average polar tilt of the AFM
moments with respect to such a plane.
A close inspection of the results from energy minimiza-
tion reveals that many noncollinear situations are again ob-tained but mostly with moment orientation not aligned withany of the anisotropy axes. We have extensively analyzed thehysteresis loops simulated with LLG equations starting fromsuch initial conditions and found that no sign of TE is everobtained. This result is a hint that, for realistic systems wherethe magnetocrystalline anisotropy is much lower than theAFM exchange, symmetry-driven contributions to TE mightbe less relevant than previously believed.
V . CONCLUSIONS
In conclusion, we have extended Hoffmann’s model for
symmetry-driven TE in FM-AFM bilayers to three dimen-sions, by numerically solving the LLG precession equationfor the magnetic moments. For the same parameter values asthose used by Hoffmann, we verify that even within ourextended three-dimensional model the occurrence of trainingis strictly connected with the configuration of AFM magneticmoments after field cooling. Some peculiar new features ofthe training dynamics anyway emerge in our analysis. Firstof all, the transition during the first FM reversal is accompa-nied by an out-of-plane relaxation of the two AFM moments,driven by the inherent in-plane frustration between interfaceand AFM exchange. This enlightens that the out-of-planeanisotropy can play a key role in the occurrence of training.Moreover, an initial noncollinear AFM arrangement is a nec-essary but not sufficient condition for training, whose dy-namics strongly depend also on other system parameters. Inparticular, when realistic values are chosen for the exchangeand anisotropy energies, TE is not reproduced anymorewithin our model, suggesting that symmetry-driven irrevers-ibilities might not be as relevant as previously believed forTE in realistic systems where the magnetocrystalline aniso-tropy is much lower than the AFM exchange.
All such considerations confirm that the behavior of FM-
AFM interfaces can be very complex even within a coherent-rotation approach based only on three magnetic momentsand that therefore not only the symmetry-driven initial stateafter field cooling plays a role for TE but also the dynamicsof the magnetic moments as governed by anistropy, interfacecoupling, and damping.
ACKNOWLEDGMENTS
We warmly acknowledge L. Duò for discussions and for
his continuous support.
*paolo.biagioni@polimi.it
†Present address: Edison s.p.a., Foro Buonaparte 31, 20121 Milano,
Italy.
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134401-7 |
PhysRevLett.104.146802.pdf | Inverse Spin-Galvanic Effect in the Interface between a Topological Insulator and a Ferromagnet
Ion Garate1,2and M. Franz1
1Department of Physics and Astronomy, The University of British Columbia, Vancouver, BC V6T 1Z1, Canada
2Canadian Institute for Advanced Research, Toronto, Ontario M5G 1Z8, Canada
(Received 2 November 2009; published 9 April 2010)
When a ferromagnet is deposited on the surface of a topological insulator the topologically protected
surface state develops a gap and becomes a two-dimensional quantum Hall liquid. We demonstrate that
the Hall current in such a liquid, induced by an external electric field, can have a dramatic effect on the
magnetization dynamics of the ferromagnet by changing the effective anisotropy field. This change isdissipationless and may be substantial even in weakly spin-orbit coupled ferromagnets. We study thepossibility of dissipationless current-induced magnetization reversal in monolayer-thin, insulating ferro-magnets with a soft perpendicular anisotropy and discuss possible applications of this effect.
DOI: 10.1103/PhysRevLett.104.146802 PACS numbers: 73.43. /C0f, 75.30.Gw, 75.70. /C0i, 72.15.Gd
Introduction.— Understanding the electric-field control
of magnetization and harnessing its technological potential
are among the most important objectives of spintronics.
Current-induced spin torques can reverse the magnetiza-tion of conducting ferromagnets (FM) and move magneticdomain walls [ 1]. However, the Joule heating generated by
transport currents remains a handicap from a practicalviewpoint. An electric field can also reorient the magneti-zation of insulating compounds with broken inversionsymmetry via the magnetoelectric coupling [ 2]. While
they overcome the issue with Joule heating, these multi-
ferroic materials are fewer and more difficult to engineerthan common metallic ferromagnets. Recently, a novelmagnetoelectric effect has been discovered [ 3] in topologi-
cal insulators that are coated with ferromagnetic films.Topological insulators (TIs) are bulk insulators with ananomalous band structure that supports topologically ro-bust gapless states at the surfaces [ 4]. These materials are
predicted to display a variety of unconventional spintronics
effects [ 5]. One unique feature is the universal quantized
topological magnetoelectric effect [ 3], described by
M
top¼/C0C1e2
2/C25E: (1)
HereMtopis the induced magnetization, C1is a half-
integer topological invariant that depends solely on the
sign of the time-reversal-symmetry-breaking perturbation,Eis the applied electric field, and C
1e2=2/C25/C17/C27His the
Hall conductance ( @/C171throughout). Unfortunately, the
prospects for manipulating the magnetization of real ferro-magnets via Eq. ( 1) are limited because below the thresh-
old Hall current density ( j
H<1A=m, see Ref. [ 6]) the
topological magnetic field Btop¼/C220Mtop&10/C06Tis
very small compared to typical coercive fields ( *0:01 T)
in a ferromagnet.
In this Letter we unveil a qualitatively new contribution
to the topological magnetoelectric effect, which stems
from the current-induced spin polarization of the TI sur-
face states. Unlike Eq. ( 1), this effect depends on materialparameters and is not related to Ampere’s law; instead it is
the topological counterpart of the inverse spin-galvanic
effect (ISGE) [ 7], which has only recently been exploited
in conducting ferromagnets with spin-orbit interaction [ 8].
The topological variant of ISGE is unique in that it isquantized, topologically protected, and occurs in insulatingferromagnets without spin-orbit interaction. In ultrathin(thickness &1n m ) ferromagnetic insulators deposited on
a surface of TI (Fig. 1) the topological ISGE produce
torques that may be comparable to the coercive field,
thus opening an unprecedented avenue for current-induced
control of magnetization without Joule heating.
Functional integral formalism.— We begin by reviewing
the equation of motion for the magnetization M/C17M^/C10of
a classical ferromagnet (in units of 1=volume). At low en-
ergies the magnitude Mis approximately constant and the
only dynamical variable is the direction ^/C10¼ð/C10
x;/C10y;/C10zÞ.
FIG. 1. Corbino-disk-shaped TI coated with an ultrathin ferro-
magnet. (a) Top view: In the absence of electric fields, the
magnetization of the ferromagnet points outside the page (dottedcircles). When a voltage difference is applied between the inner
and outer circles, a dissipationless Hall current flows at the
interface between the two materials (solid arrows). This currentmagnetizes the surface states of the TI (inverse spin-galvanic
effect) along the radial direction (dashed arrows), thus exerting a
spin torque on the magnetization of the ferromagnet. (b) Crosssectional view: The shaded region is the TI, whereas the un-shaded region is the ferromagnetic film. H
FMis the anisotropy
field in electric equilibrium. HCS;1is a topological magnetic field
proportional to (and parallel to) the applied electric field.PRL 104, 146802 (2010) PHYSICAL REVIEW LETTERSweek ending
9 APRIL 2010
0031-9007 =10=104(14) =146802(4) 146802-1 /C2112010 The American Physical SocietyThe time dependence of ^/C10may be determined using the
functional integral approach [ 9], which is built on the
partition function
Z¼Z0Z
D^/C10ðx;tÞe/C0SFM½^/C10/C138: (2)
Z0is the partition function corresponding to the equilib-
rium magnetic configuration ^/C10¼^/C10eq.SFM¼SB/C0Eis
the action for small (quadratic) spin fluctuations, where
SB¼MRdxdt^/C10/C1ð^/C10eq/C2_^/C10Þis the Berry phase and
E½^/C10/C138¼Rdxdt^/C10/C31/C01^/C10is the micromagnetic energy func-
tional. /C31is the spin-spin response function. The semiclas-
sical equation of motion can be derived from
/C14SFM=/C14^/C10¼0,
_^/C10¼^/C10eq/C2/C18
/C01
M/C14E
/C14^/C10/C19
: (3)
A gradient expansion [ 10]o f /C31yields the venerable
Landau-Lifshitz-Gilbert-Slonczewski equation for magne-tization dynamics in the presence of damping and transportcurrents,
_^/C10¼^/C10
eq/C2H/C0/C11^/C10eq/C2_^/C10/C0vs/C1r^/C10
/C0/C12^/C10eq/C2vs/C1r^/C10þ/C1/C1/C1 : (4)
His an effective magnetic field (in energy units) that
includes the anisotropy field, the exchange field, as wellas external magnetic fields. Hdetermines the easy axis
along which the magnetization of a single-domain ferro-magnet points in equilibrium. v
sis the adiabatic spin trans-
fer velocity and is proportional to the transport current. /C11
and/C12characterize dissipative processes in which energy is
transferred from magnetic to nonmagnetic (e.g., lattice)
degrees of freedom.
Topological effective magnetic field.— We now address
the magnetization dynamics of an insulating ferromagnetsitting on top of a TI. The low-energy effectiveHamiltonian for the surface states of the TI is [ 3,4]
H¼v
F/C28/C1ð/C25/C2^zÞ/C0/C1/C28/C1^/C10; (5)
where vFis the Fermi velocity, /C28i(i2fx; y; z g) are Pauli
matrices denoting real spin of the surface states, /C25¼
/C0ir/C0eA,Ais the electromagnetic vector potential, ^z
is the unit vector normal to the interface between the TI andthe ferromagnet, and /C1is the exchange coupling between
the surface states and the local moments of the ferromagnet(/C1>0for ferromagnetic coupling). We consider a ferro-
magnet with perpendicular anisotropy ( /C10
eq¼^z) so that in
equilibrium a gap opens in the energy spectrum of the
surface states.
The partition function for this composite system is
Z¼Z0Z
D^/C10ðx;tÞe/C0SFM½^/C10/C138Z
D2/C9ðx;tÞe/C0STI½/C22/C9;/C9;^/C10/C138;(6)
where SFMis the ferromagnetic action discussed above andSTI¼Z
d2xdt/C22/C9½@0/C0/C22/C0H/C138/C9 (7)
is the action for the surface states. /C9is a fermionic spinor,
@0¼@t/C0eA0,/C22is the chemical potential (located in the
gap), and A0is the electrostatic potential. After rotating the
spins by an angle /C25=2around ^z, Eq. ( 7) may be rewritten as
STI¼Rd2xdt/C22c½@0/C0/C22/C0~H/C138cwith
~H¼vF/C28xð/C25x/C0eaxÞþvF/C28yð/C25y/C0eayÞ/C0/C10z/C1/C28z;(8)
wherecis the rotated fermion field. In this new basis, a/C17
/C1=ðevFÞð^/C10/C2^zÞappears as an additional contribution to
the effective vector potential. /C10z/C1acts as a mass term.
These massive Dirac fermions may be integrated out in the
standard manner [ 11], whereby Z¼RD^/C10ðx;tÞe/C0Seff½^/C10/C138.
To second order in ^/C10the effective action is Seff’SFMþ
SCSþSEB, where
SCS¼e2
2/C25C1Z
d2xdt/C15/C22/C23/C21A/C22@/C23A/C21; (9)
~A¼ðA0;Axþax;AyþayÞis the effective vector poten-
tial and /C22¼t; x; y . The Chern-Simons (CS) action ( 9)
arises in ( 2þ1)-dimensional systems with broken time
reversal symmetry and nontrivial topology. The topology
of the band structure is encoded in the Thouless, Kohmoto,
Nightingale, den Nijs (TKNN) [ 12] invariant C1. For fer-
mions described by a single Dirac Hamiltonian ( 8), we
have [ 13]
C1¼/C01
2sgnð/C10z/C1Þ: (10)
SEBis quadratic in spatial and temporal derivatives of
A/C22and encodes the ordinary dielectric or diamagnetic
response of the gapped surface state. Herein we focus on
SCS, which is first order in the derivatives of A/C22(and ^/C10),
and thus outweighs SEBin the description of ^/C10ðx;tÞat long
length and time scales. It also produces the effective mag-
netic field that underlies the inverse spin-galvanic effectwhich is central to this study.
The semiclassical magnetization dynamics follows from
/C14S
eff=/C14^/C10¼0,
_^/C10¼^/C10eq/C2ðHFMþHCSÞþ/C1/C1/C1 ; (11)
where HFM¼/C0/C14SFM=ðM/C14^/C10Þis the effective magnetic
field that collects the anisotropy or exchange fields of theisolated ferromagnet and
H
CS¼/C01
M2D/C14SCS
/C14^/C10¼/C0/C27H
M2D/C1
evF/C20
Eþ/C1
evFð^z/C2_^/C10Þ/C21
(12)
is an additional (topological) contribution to the magnetic
field that results from the exchange coupling between theferromagnet and the TI. M
2Dis the areal magnetization at
the interface (in units of 1=area). HCSdepends on materialPRL 104, 146802 (2010) PHYSICAL REVIEW LETTERSweek ending
9 APRIL 2010
146802-2parameters ( vF,/C1,M2D) and is proportional to the Hall
conductivity /C27H¼C1e2=2/C25. Because the exchange cou-
pling between the surface states and the localized moments
of the ferromagnet is local in space, the influence of HCS
weakens as the thickness of the ferromagnetic film
increases.
HCS;1/C17/C0/C1=ðevFM2DÞ/C27HEcan be interpreted as an
electric-field induced change of magnetic anisotropy. The
underlying cause of this effect is that the electric field spin
polarizes the surface states along a direction ( E=E) which
is misaligned with the equilibrium easy axis ( ^z). We illus-
trate this point by computing the magnetization induced bya static and uniform electric field:
/C14
EMi
2D/C17/C31ij
M;EEj; (13)
where
/C31ij
M;E¼lim
!!0e
i!1
AX
kX
n;n0/C28i
n;n0vj
n0;nfk;n/C0fk;n0
Ek;n0/C0Ek;nþ!(14)
is the linear magnetoelectric response function [Fig. 2(a)].
n; n0are the band indices of the surface states, Ek;nare the
band energies, fk;nare the Fermi distributions, /C28i
n;n0¼
hn;kj/C28ijn0;ki, and Ais the area of the interface. From
Eq. ( 5), the velocity operator is related to the spin operator
viav¼@H=@k¼/C0vF/C28/C2^z, which allows us to use the
TKNN formula for conductivity [ 12] and write
/C31ij
M;E¼/C0/C27H
evF/C14ij; (15)
where /C14ijis the Kronecker delta and we have used the fact
that the longitudinal conductivity is zero. Hence, Hi
CS;1¼
ð/C1=M 2DÞ/C14EMi
2D. This result is reminiscent of the current-
induced effective field in single-domain metallic ferromag-
nets that belong to the gyrotropic crystal class [ 14]. Some
significant differences between Ref. [ 14] and the present
work are that HCS;1(i) does not depend on the strength of
spin-orbit interactions in the ferromagnet or at the interface
[Eq. ( 5) involves vFrather than a ‘‘spin-orbit velocity’’],(ii) reverses sign when /C10z!/C0 /C10zand vanishes when
/C10z¼0, and (iii) exerts a dissipationless torque provided
that the ferromagnet is insulating.
HCS;2/C17/C0 ð /C27H=M 2DÞð/C1=ev FÞ2^z/C2@t^/C10is associated
with the change in the spin response function under a
magnetic field [Fig. 2(b)]:
/C31ij
M;BðqÞ¼/C1
AX
kX
n;n0/C28i
n;n0/C28j
n0;nfk;n/C0fkþq;n0
Ekþq;n0/C0Ek;nþ!;(16)
where q¼ð!;qÞis the energy-momentum of the magnon
and/C28i
n;n0¼hn;kj/C28ijn0;kþqi.A tq¼0we get /C31ij
M;B¼
ð/C1=ev FÞ2ð/C0i!Þ/C27H/C15ij, where /C15xy¼/C0/C15yx¼1and/C15xx¼
/C15yy¼0. Thus, Hi
CS;2¼ð/C1=M2DÞ/C31ij
M;B/C10jsimply increases
(if/C1>0) or decreases (if /C1<0) the Berry phase of the
isolated ferromagnet [ 15], thereby renormalizing the pa-
rameters entering Eq. ( 4).
When the magnetization of the ferromagnet is uniform,
Eq. (12) captures the entire current-induced spin torque for
weak electric fields. In the presence of inhomogeneousmagnetic textures, one must add the ordinary spin transfer
torque. The microscopic theory for v
s/C1r^/C10amounts to
evaluating the change of the xyspin-spin response function
[10] under an electric field [Fig. 2(c)]. Starting from
/C31xy
M;BðqÞ, perturbing the matrix elements of the spin opera-
tors to first order in E[16] and expanding the resulting
expression to first order in q, we find (numerically) that
vs/C1q//C10zðExqx/C0EyqyÞ. Furthermore, for realistic pa-
rameters the torque exerted by HCSis found to dominate
overvs/C1qby an ample margin even when jqj/C24nm/C01
(note that HCSdoes not vary as ^/C10is slightly tilted away
from ^z).
Current-induced magnetization switching.— As ex-
plained above, HCS;1modifies the anisotropy field of
the ferromagnet in the presence of a Hall current jH¼
/C27H^z/C2E:
Han¼K
M2D/C10z^zþ/C1
evFM2D^z/C2jH; (17)
where Kis the anisotropy energy per unit area for the
magnetic ultrathin film in electric equilibrium. When E¼
0the magnetization of the ferromagnet points along ^z.
After turning on the electric field, the magnetization beginsto precess around H
anand (assisted by the damping)
equilibrates along the modified easy axis. For instance, in
a Corbino disk geometry depicted in Fig. 1the electric field
produces a crown-shaped magnetization. Provided thatquantum coherence is preserved, this configuration hosts[17] a circulating spin-current proportional to Mð/C30Þ/C2
Mð/C30þ/C14/C30Þ//C10
zðjH/C2^zÞþOðE2Þ, which is radially po-
larized and persistent (dissipationless). /C30is the azimuthal
angle around the disk.
IfjH*evFK=/C1,^/C10reaches the interface ( /C10z¼0)i n
the course of the precession. At that moment, according to
Eq. ( 10),C1¼0and hence @t^/C10¼0; yet this is an un-
stable fixed point and an infinitesimal in-plane magnetic
FIG. 2. Feynman diagrams for (a) the electric-field-induced
magnetization (inverse spin-galvanic effect), (b) the xycompo-
nent of the spin-spin response function, (c) the xycomponent of
the spin-spin response function in the presence of an electric
current (it yields the adiabatic spin transfer torque vs/C1r^/C10). The
solid straight lines are propagators for massive Dirac quasipar-
ticles (quasiholes). The solid wavy lines are magnons that coupleto the spin operator, and the dashed straight lines are photons that
couple to the velocity operator.PRL 104, 146802 (2010) PHYSICAL REVIEW LETTERSweek ending
9 APRIL 2010
146802-3field suffices to kick the magnetization towards /C10z<0.
Once this occurs the electric field may be turned off and the
magnetization will equilibrate towards /C0^z. Thus a 180/C14
magnetization switching may be completed by combining
a dissipationless Hall charge current with a very small
magnetic field. Nevertheless, achieving jH*evFK=/C1in
real materials presents challenges. First, jH(E) cannot be
larger than /C241A=m(0:5m V =nm) because otherwise the
dissipationless quantum Hall effect will break down [ 6].
Second, we require relatively small coercive fields:
Hcoer¼K=M 2D&0:02 T. While such a soft perpendicu-
lar anisotropy is inadequate for the magnetic recordingindustry, it may find applications in magnetic random
access memories and magnetic field sensors [ 18]. Third,
the thickness of the ferromagnet needs to be comparable tothe penetration depth of the Dirac fermions into the ferro-
magnetic insulator ( &1n m ). While ultrathin films are
commonplace in metallic ferromagnets [ 19], insulating
ferromagnets such as EuO or EuS present additional ex-
perimental difficulties (but see Ref. [ 20] for recent
progress). Alternatively, one could electrically manipulate
the spin textures caused by magnetic impurities placed on
the surface of the TI [ 21,22]. Using /C1¼JM
2D,jH¼
1A=m,vF¼5/C2105m=s, and Hcoer¼0:01 T, we esti-
mate J*50 meV nm2as the condition for magnetization
switching. Hence J=a2*0:2e V , where a’0:5n m is a
typical lattice constant for the topological insulator. J=a2’
0:2e V is an a priori reasonable value [ 21] for the exchange
integral between the localized moments of the ferromag-netic insulator and the surface states of the TI. For stronger
perpendicular anisotropies (say, H
coer*0:05 T) the ex-
change integral would need to be of the order of a few
eV, and at such strong coupling the surface states of the TIwould be altered in a way not captured by Eq. ( 5). From the
precession frequency !
prec’/C22BHan=@’1 GHz we infer
switching times of the order of a nanosecond.
There has been some recent work along the lines of the
above discussion, albeit in topologically trivial materials[23]. There are two salient differences between Ref. [ 23]
and the present work. (i) The microscopic origin of the
change in magnetic anisotropy: in our case it is the current-induced spin-polarization of massive Dirac fermions (the
topological inverse spin-galvanic effect), whereas Ref. [ 23]
concentrates on the electrical manipulation of the atomicpositions and distortions of the charge distribution.
(ii) Symmetry of the anisotropy mechanism: in our case
it is odd under time reversal (because j
His odd), whereas
in Ref. [ 23] it is even under time reversal (because Eand
charge density are even).
Conclusions.— When a ferromagnetic film with perpen-
dicular anisotropy is placed on top of a topological insu-lator, a quantum Hall current induces a spin torque which
substantially modifies the magnetic easy axis. The origin of
this new torque can be traced to a topological variant of the
inverse spin-galvanic effect. In Corbino disk geometries
this effect may be exploited to generate crown-shapedmagnetic textures and to switch the magnetization of a
ferromagnet by 180
/C14without Joule heating.
We thank I. Affleck, J. Folk, A. H. MacDonald, and G.
Sawatzky for helpful comments and questions. This re-
search has been supported by NSERC and CIfAR. I. G.thanks CIfAR for financial support.
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146802-4 |
PhysRevB.80.144427.pdf | Gilbert damping and current-induced torques on a domain wall: A simple theory based on
itinerant 3 delectrons only
L. Berger
Physics Department, Carnegie Mellon University, Pittsburgh, Pennsylvania 15213, USA
/H20849Received 23 April 2009; revised manuscript received 11 September 2009; published 30 October 2009 /H20850
Many electronic theories of Gilbert damping in ferromagnetic metals are based on the s-dexchange model,
where localized 3 dmagnetic spins are exchanged-coupled to itinerant 4 selectrons, which provide the needed
spin relaxation. Recently, Tserkovnyak et al. have obtained Gilbert damping from itinerant 3 delectrons alone,
which have their own spin relaxation. We show that simple semiclassical equations of motion for precessingitinerant 3 dspins predict exactly the same formula
/H9251=1 //H20849/H9275d/H9270srd/H20850for the Gilbert damping constant as the full
Green’s function quantum treatment by Tserkovnyak et al. Here,/H9275dis the precession frequency of 3 dspins in
thed-dmutual exchange field, and /H9270srdthe 3 dspin-relaxation time. A correct form for the spin-relaxation torque
is crucial for success: The spins relax toward an instantaneous direction which is that of the vector sum ofexternal field and d-dexchange field. Remarkably, d-dexchange torques disappear completely from the
equations of motion for the total 3 dmagnetization, and exchange plays only an indirect role through the spin
relaxation. This purely 3 dmodel is simpler than the traditional s-dmodel. We also present a theory of
current-induced torques on a domain wall, based on the 3 dmodel. We find equivalents to the so-called
adiabatic and nonadiabatic torques. They are given by formulas similar to those holding for the s-dexchange
model.
DOI: 10.1103/PhysRevB.80.144427 PACS number /H20849s/H20850: 75.60.Ch, 85.75. /H11002d, 75.75. /H11001a, 75.47. /H11002m
I. INTRODUCTION
Damping of the motion of magnetic spins in ferromagnets
is of the kind described by Gilbert, where the damping rate isproportional to the spin precession frequency. Many elec-tronic theories for metallic ferromagnets are based on the s-d
exchange model,
1where localized 3 dmagnetic spins Sare
coupled to itinerant 4 selectron spins sby an interaction E
=−2JsdS·s, where Jsd/H112290.1–0.2 eV.
Because of the momentum gap existing2between spin-up
and spin-down Fermi surfaces, no damping is obtained at T
=0 unless spin relaxation,3connected with a combination of
spin-orbit interaction and electron scattering, is introducedfor the 4 selectrons. It is represented by a spin-relaxation
time
/H9270srs/H1122910−12–10−13s. One exception is the theory of
Mills et al. ,4who showed that spin orbit can be replaced here
bys-dexchange itself.
Using s-dexchange and coupled semiclassical equations
of motion for Sands, Turov5derived the value of the ferro-
magnetic resonance linewidth. It is directly related to thedimensionless Gilbert damping parameter
/H9251. In the limit
/H9275s/H9270srs/H112711, this reduces to
/H9251=s
/H20849S+s/H20850/H20849/H9275s/H9270srs/H20850. /H208491/H20850
Here, Sandsare the magnitudes of Sands, with units of
atom−1. The quantity /H9275s=2JsdS//H6036would represent the spre-
cession frequency in the s-dexchange field set up by S,i f
that field had a constant direction.
Later, Heinrich et al.6treated this problem with a Green’s
function formalism. Remarkably, this quantum treatmentyields exactly the same expression for
/H9251/H20851Eq. /H208491/H20850/H20852as the
simple equations of Turov5for the classical precession of S
ands.Recently, Tserkovnyak et al.7obtained Gilbert damping
from itinerant 3 delectrons alone, assumed to have their own
spin-relaxation time /H9270srd.This purely 3 dmodel leads to
/H9251=1
/H9275d/H9270srd, /H208492/H20850
where /H9275dwould be the 3 d-spin precession frequency in the
Stoner exchange field generated by all the other 3 ditinerant
spins, if that field had a fixed direction.
The purpose of the present paper is to show that a simple
classical equation of motion for a precessing 3 dspin predicts
exactly the same formula for /H9251/H20851Eq. /H208492/H20850/H20852as the full quantum
treatment by Tserkovnyak et al.7which uses Keldysh
Green’s functions combined with the Boltzmann equation.The present approach also provides a clear physical picture/H20851Fig. 1/H20849b/H20850/H20852of processes involved in Gilbert damping.
Actually, the fact that the present model uses only one
kind of electron is more important than the exact dors
nature of such electrons.
II.S-DEXCHANGE MODEL
The equations of motion for the localized 3 dmagnetic
spinSand the itinerant 4 sconduction-electron spin s/H20851Fig.
1/H20849a/H20850/H20852are5
/H6036ds
dt=−g/H92620/H9262Bs/H11003/H20849H+Hsd/H20850−/H6036/H20849s−s0/H20850
/H9270srs
/H6036dS
dt=−g/H92620/H9262BS/H11003/H20849H+Hds/H20850. /H208493/H20850
Here, His the external static field, Hsd=−2JsdS/g/H92620/H9262B
the exchange field exerted by Sons,/H92620the vacuum perme-PHYSICAL REVIEW B 80, 144427 /H208492009 /H20850
1098-0121/2009/80 /H2084914/H20850/144427 /H208495/H20850 ©2009 The American Physical Society 144427-1ability in the SI system of units /H20849Systeme International /H20850, and
Hds=−2Jsds/g/H92620/H9262Bthe field exerted by sonS. Also, /H9262Bis
the Bohr magneton. The g-factor gis assumed for simplicity
to have the same value for Sand for s.
In Eqs. /H208493/H20850,s0is the instantaneous direction toward which
sis relaxing. As discussed a long time ago by Hasegawa,8
this direction should be antiparallel to the total field H
+Hsdacting on s/H20851Fig. 1/H20849a/H20850/H20852
s0=−sH+Hsd
/H20841H+Hsd/H20841. /H208494/H20850
This choice of s0represents the instantaneous direction
where the total Zeeman energy of swould be minimum. It is
a logical choice since, during spin relaxation, the Zeemanenergy is lost to the lattice through emission of phonons.
Choices which differ from Eq. /H208494/H20850would lead
5,8to shifts
in the Sprecession frequency, away from the usual value;
such shifts are not observed in actual resonance experiments.Note also that Walker
9has derived Eq. /H208494/H20850on the basis of
Fermi-liquid theory.
We introduce coordinates x,y, and z, with zantiparallel to
H/H20851Fig.1/H20849a/H20850/H20852, and look for solutions of Eqs. /H208493/H20850and /H208494/H20850of the
form s+/H20849t/H20850=s+/H208490/H20850e−/H20849/H9003+i/H9275/H20850t,S+/H20849t/H20850=S+/H208490/H20850e−/H20849/H9003+i/H9275/H20850t, where s+=sx
+isy. We assume H/H11270Hsd,Hdsand /H20841s+/H20841/H11270s,/H20841S+/H20841/H11270S. We intro-
duce the quantity /H9275s=2JsdS//H6036. It would represent the spre-
cession frequency around Hsdif the latter had a fixed direc-
tion. We obtain in the limit /H9275s/H9270srs/H112711
/H9275/H11229g/H92620/H9262BH
/H6036;/H9003/H11229s/H9275
/H20849s+S/H20850/H9275s/H9270srs. /H208495/H20850
Then, the Gilbert damping parameter, defined as /H9251=/H9003//H9275,
is given by Eq. /H208491/H20850in agreement with Refs. 5and6. Inter-estingly, starting with a Bloch-type spin-relaxation term in
the equations of motion /H20851Eqs. /H208493/H20850/H20852, we arrived nevertheless
/H20851Eq. /H208495/H20850/H20852to a Gilbert form for the damping rate /H9003, i.e., with
/H9003/H11008/H9275. The Hterm in Eq. /H208494/H20850is responsible for this.
III. ITINERANT D-DMODEL
In this model, we consider only itinerant 3 delectrons, in
Bloch waves with various wave vectors and spin states, la-beled with the index n=1,2,3,.... Paired spin-up and spin-
down electrons of same wave vector give zero total spin, andcan be ignored. Only the remaining unpaired spin-up statesmatter. Since they all have different wave vectors, they canhave nonorthogonal spin parts while still being orthogonaland obeying the exclusion principle. This makes possible aclassical picture of individual precessing 3 dspins, pointing
in different directions, with increased exchange energy.
As mentioned before, the fact that only one kind of elec-
tron appears in the model is more important than the exact d
orsnature of such electrons. Actually, the two kinds of states
are significantly mixed through s-dhybridization. This ques-
tion will be discussed in more detail in Sec. VI.
As in the last section, we write a classical equation of
motion for the spin s
n/H20851Fig.1/H20849b/H20850/H20852of an individual 3 delectron
/H6036dsn
dt=−g/H92620/H9262Bsn/H11003/H20849H+Hdd/H20850−/H6036sn−s0
/H9270srd. /H208496/H20850
Here, Hddis the d-d/H20849Stoner /H20850exchange field /H20851Fig. 1/H20849b/H20850/H20852
acting on sn, generated by all other itinerant 3 delectrons, and
/H9270srd/H1122910−13–10−14s the 3 dspin-relaxation time. Also, Sis
the total spin of 3 delectrons in the system, with S=/H9018nsn.
The total exchange energy is −2 Jdd/H9018n/H11022m/H9018msn·sm. Then, Hdd
is given by Hdd=−JddS/g/H92620/H9262B. For simplicity, we assume
thed-dexchange integral Jddto have the same value between
all pairs of 3 dstates. Band-structure calculations are
consistent10with Jdd/H112290.5 eV.
Similarly to the last section, and for the same reasons, sn
relaxes /H20851see Fig. 1/H20849b/H20850/H20852toward the direction
s0=−sH+Hdd
/H20841H+Hdd/H20841. /H208497/H20850
The remarks about 1 //H9270srsmade in that section also apply
to 1 //H9270srd. The mechanism of spin relaxation of Ref. 3works
for 3 delectrons, since these are now assumed itinerant. We
sum Eq. /H208496/H20850over n, to obtain an equation of motion for the
total 3 dspinS
/H6036dS
dt=−g/H92620/H9262BS/H11003H−/H6036
/H9270srd/H20849S−S0/H20850, /H208498/H20850
where S0=−S/H20849H+Hdd/H20850//H20849/H20841H+Hdd/H20841/H20850. We see that exchange
torques have disappeared from Eq. /H208498/H20850. The reason is that
these are internal to the 3 d-electron system, not external as in
the case of the s-dexchange model of last section. Exchange
appears only indirectly, through S0in the spin-relaxation
term. We define the quantity /H9275d=g/H92620/H9262BHdd//H6036. It would rep-
resent the snprecession frequency around Hddif the latter
had a fixed direction. Similarly, we define /H9275=g/H92620/H9262BH//H6036andso
sdHdsH
H
Hddos
snz z
Hs
a) b)S
SS0
FIG. 1. /H20849a/H208504sconduction-electron spin sand 3 dmagnetic-
electron spin Sprecessing around the magnetic field H. The s-d
exchange field Hsdis antiparallel to Sand acts on s; and vice versa
forHds. The vector s0is antiparallel to the total field H+Hsdacting
ons, and is the direction toward which sis relaxing. /H20849b/H208503dindi-
vidual spin snand total 3 dspinS=/H9018nsnprecessing around the mag-
netic field H. The d-dmutual exchange field Hddis antiparallel to S
and acts on sn. The vector s0is antiparallel to H+Hddand is the
direction toward which snis relaxing.L. BERGER PHYSICAL REVIEW B 80, 144427 /H208492009 /H20850
144427-2S+=Sx+iSy, with zantiparallel to H/H20851Fig.1/H20849b/H20850/H20852. After assum-
ingH/H11270Hdd,/H20841s+/H20841/H11270s,/H20841S+/H20841/H11270S, Eq. /H208498/H20850gives
dS+
dt=−i/H9275S+−/H9275
/H9275d/H9270srdS+
dSz
dt/H112290.
To first order in the precession amplitude /H20841S+/H20841, the modu-
lus of Sis constant. Again, we look for a solution of the form
S+/H20849t/H20850=S+/H208490/H20850e−/H20849/H9003+i/H9275/H20850t, and find immediately
/H9003=/H9275
/H9275d/H9270srd. /H208499/H20850
Then,/H9251=/H9003//H9275is given by Eq. /H208492/H20850in agreement with Ref.
7. Again, and for the same reasons, /H9003is of the Gilbert form.
Even when taking into account s-dhybridization, we have
/H9275s/H11021/H9275dbut/H9270srs/H11022/H9270srd. Thus, the dimensionless parameters
/H9275srs/H9270srsin Eq. /H208491/H20850and/H9275srd/H9270srdin Eq. /H208492/H20850may have comparable
values /H1122910–100.
IV. CURRENT-INDUCED TORQUES ON A DOMAIN
WALL, IN THE 3 dMODEL
We consider a tail-to-tail wall in a nanowire /H20851Fig. 2/H20849a/H20850/H20852.
The spatial coordinate Xruns along the length of the nano-
wire. The total 3 dspinSat location Xmakes an angle /H9258/H20849X,t/H20850
with the − Xaxis. As an approximation,11we assume that the
vector Sin the wall is everywhere contained in a plane P
parallel to the Xdirection, which makes an angle /H9274with thesubstrate plane /H20851Fig.2/H20849b/H20850/H20852. In a static wall at zero current, we
have/H9274=0. The sign convention for /H9274is such that it increases
when Sturns toward the − xdirection. We introduce local
spin coordinates x,y, and zwith zparallel to Sandxnormal
toXand to plane P/H20851Fig. 2/H20849a/H20850/H20852.
When /H9274differs from zero, the canted magnetization
creates11in the wall a demagnetizing field HD. If the nano-
wire thickness is much less than the width, this field is nor-mal to the substrate plane. The component of H
Dalong the
normal to plane PisHDx=−HDcos/H9274=−Msin/H9258sin/H9274cos/H9274.
The torque exerted by HDxon the total 3 dspinSis in plane P
and is
/H9270y=/H20849/H92620Ms2/2/H20850sin/H208492/H9274/H20850sin/H9258. /H2084910/H20850
The usual energy eigenstates of an itinerant electron are
plane waves where the spin direction is the same at all loca-tions. However, more general “spiral states” have beenintroduced
12to represent itinerant electrons in domain walls.
As long as the wall width is much larger than an electronwavelength, the spatial variation in the direction of Sis slow
and there is no difference with the usual theory of domainwalls based on localized electrons. The structure of a simpletransverse wall is given
13by/H9258=f/H20849X−vwt/H20850//H9004/H20850where vwand
/H9004are the wall speed in the laboratory frame and the wall
width, and f /H20849u/H20850is a certain function.
In earlier sections, there was no electric current. We intro-
duce now the current density j↑carried by spin-up 3 delec-
trons, as seen from the laboratory frame. The existence ofsuch a 3 dcurrent will be discussed further in Sec. VI.
The effect on Sof torque
/H9270yis evaluated in the simplest
manner14in a moving frame where the electron gas is at rest
and, therefore, the spin current vanishes and causes no addi-tional torque. The torque itself is the same in all frames. Inthe case of spin-up electrons, the speed of that moving frame
is
ve↑=−j↑/ne↑e, where ne↑is the spin-up electron density. In
that frame, the spin-up parts of /H9270yandSare related by
/H9270y↑=/H6036Sz↑/H11509/H9258//H11509t=−/H6036Sz↑/H20849f/H11032//H9004/H20850/H20849vw−ve↑/H20850, /H2084911/H20850
where f/H11032/H20849u/H20850=df /du, and where vw−ve↑is the apparent speed
of the wall as seen from the moving frame.
It is also possible to derive Eq. /H2084911/H20850in the laboratory
frame. In that frame, the apparent wall speed is vw, not vw
−ve↑. Also, the current density j↑present in that frame gener-
ates a 3 dspin current js↑, leading to an extra term − divjs↑in
Eq. /H2084911/H20850. These two changes cancel each other, so that we
obtain the same Eq. /H2084911/H20850as before.
By working in the moving frame, we have shown that the
case with current can be reduced to the case without current,by a simple change in frame. Also, we have avoided theintroduction of the spin current.
We also write a expression similar to Eq. /H2084911/H20850for the
contribution
/H9270y↓of spin-down electrons. Because of the exclu-
sion principle and of orthogonality, the spins S↑andS↓of
spin-up and spin-down electrons stay closely antiparallel. By
equating /H9270y↑+/H9270y↓to/H9270yof Eq. /H2084910/H20850, and using the fact13that
f/H11032=sin/H9258for a uniaxial anisotropy, we obtain finally
/H208491/2/H20850sin/H208492/H9274/H20850=− /H20851vw−/H20849P/Pn/H20850ve/H20852//H9275D/H9004z
y
ddnadXSS S
S
H
HM
zx
Msubstrate planeS
S
HH
ddX
X
Da)
b)0plane P ψθ
FIG. 2. /H20849a/H20850Simple tail-to-tail domain wall in a nanowire. The X
axis runs along the length of the nanowire. The total 3 dspinS
makes an angle /H9258/H20849X,t/H20850with the − Xaxis. The plane of the picture is
plane Pwhich contains all the spins Sand makes an angle /H9274with
the plane of the substrate. Local spin coordinates x,y, and zhave
thezaxis parallel to S, and xnormal to plane Pand to the Xaxis.
/H20849b/H20850View of the same domain wall, with the plane of the picture
normal to the Xaxis. Plane P, which contains the spins S,i sa ta n
angle/H9274to the plane of the substrate. The vector S0is antiparallel to
the total field Hdd+HDand is the direction toward which Sis
relaxing.GILBERT DAMPING AND CURRENT-INDUCED TORQUES … PHYSICAL REVIEW B 80, 144427 /H208492009 /H20850
144427-3P=j↑−j↓
j↑+j↓;Pn=ne↑−ne↓
ne↑+ne↓
ve=−j/nee;/H9275D=g/H92620/H9262BMs//H6036. /H2084912/H20850
Here,/H9262Bis the Bohr magneton, and all carriers are as-
sumed electronlike. And veis the average electron drift
speed. Also, ne=ne↑+ne↓and j=j↑+j↓. Note that /H9258has
dropped out of the expression for /H9274, thus justifying our as-
sumption of a constant /H9274.
The demagnetizing-field torque /H9270yof Eq. /H2084910/H20850and, de-
pending on the frame, the − divjsterm are the only external
torques along y acting on the 3 dspins Sof the wall. The
−divjsterm plays the same role in our 3 dmodel as the so-
called adiabatic torque in the s-dexchange model.15,17In the
latter theory, that torque had the nature of an s-dexchange
torque.
By Eq. /H2084912/H20850, the maximum stable value of /H9274is/H9266/4, and
the corresponding critical value of the current density is15
j/H9274=/H11006/H92620Ms2e/H9004
P/H6036. /H2084913/H20850
Field HDalso has a component in the plane P, which has
the same effect on Sas an additional anisotropy with easy
axis along X. This tends to reduce the wall width below the
value/H9004holding at /H9274=0. This effect varies like /H92742at small /H9274,
and we will ignore it.
V. NONADIABATIC TORQUE
As before /H20851Eq. /H208497/H20850/H20852, each 3 dspinsnrelaxes toward the
instantaneous direction of the total field acting on it. Here,this field is H
dd+HD/H20851Fig. 2/H20849b/H20850/H20852. After summing over nand
assuming /H20841/H9274/H20841/H112701 rad and HD/H11270Hdd,Sis found to relax to-
ward S0=−Sz/H20849Hdd+HD/H20850/Hdd. The spin-relaxation torque act-
ing on Sis
/H9270x=/H6036/H20849S0/H20850x
/H9270srd=−/H6036SHDx
Hdd/H9270srd=/H6036S/H9275D/H9274sin/H9258
/H9275d/H9270srd. /H2084914/H20850
This spin-relaxation torque plays the same role in the
present 3 dtheory as the so-called nonadiabatic torque in
theories16,17based on the s-dexchange model. Contributions
to/H9270xfrom interatomic-exchange and anisotropy torques can-
cel each other as long as the wall has the structure discussedin the last section. We substitute
/H9274from Eq. /H2084912/H20850into Eq.
/H2084914/H20850. Also, torque /H9270xis equivalent to the torque
/H92620MsHnadXsin/H9258of a fictitious field Hnadalong the easy axis
X. From all this, we obtain finally
HnadX=−/H6036ne/H20849Pnvw−Pve/H20850
2/H92620Ms/H9004/H20849/H9270srd/H9275d/H20850, /H2084915/H20850
where /H9258has dropped out. The term in vwrepresents Gilbert
damping. The positive sign of its coefficient Pn/H20851Eq. /H2084912/H20850/H20852is
required by the second law.
In real magnetic materials, it is important to take into
account domain-wall pinning, caused by lattice defects. It ischaracterized
13by the coercivity Hc. The wall will movewhenever HnadX=/H11006Hc. Combining this condition with Eq.
/H2084915/H20850, we obtain
vw=P
Pn/H20849ve/H11007vec/H20850;vec=2/H92620Ms/H9004/H20849/H9270srd/H9275d/H20850
Pn/H6036neHc. /H2084916/H20850
Because of the existence of the coercivity, a minimum
electron drift speed vecis needed before wall motion can
start /H20851Eq. /H2084916/H20850and Fig. 3/H20852. For 3 delectrons, P/Pnis on the
order of unity. Then, Eq. /H2084916/H20850shows that vwis on the order of
the electron drift speed ve, whenever /H20841ve/H20841exceeds the critical
value vec/H20851Fig. 3/H20852.
VI. APPLICABILITY OF 3 dMODEL
The equilibrium physical and magnetic properties of Ni,
Co, and Fe depend primarily10on the 3 dband. By them-
selves, 3 delectrons are already itinerant, with a bandwidth18
of several electron volts. As shown by Hodges et al.19for Ni,
the addition of the 4 sband causes only minor changes in the
structure and bandwidth of that 3 dband. Despite significant
hybridization of 3 dand 4 sstates, 3 delectrons retain distinct
physical properties, such as high density of states and lowvelocity. These electrons are the basis of the present d-d
model.
This model applies best to the problem of Gilbert damp-
ing /H20849Sec. III/H20850in transition-metal materials. The best example
is that of Permalloy thin films, studied experimentally
20by
Ingvarsson. For Ni and Co, it has to be complemented by theKambersky Fermi surface breathing mechanism
21of damp-
ing, which depends in opposite fashion on electron relaxationtime.
On the other hand, band-structure calculations for ferro-
magnetic Ni
19,22all show that the spin-up Fermi level is lo-
cated above the top of the 3 dband, in a region with the low
density of states and high electron velocity characteristic of4selectrons. The spin-up Fermi surface of Ni even has
23
necks similar to those of Cu. This is confirmed by ordinary
Hall effect data24for Ni, Ni-Fe, Ni-Fe-Cu, and Ni-Co, which
show that a small number /H112290.3 el. /at. of carriers carry most
of the current. Also by deviations from Matthiessen rule,25(P/P)v
v vw
e ec vecn
FIG. 3. Normalized wall speed vwversus average electron drift
speed ve, according to Eqs. /H2084916/H20850. Here, PandPnare the current-
polarization and electron-density polarization factors. These are de-fined in Eqs. /H2084912/H20850.L. BERGER PHYSICAL REVIEW B 80, 144427 /H208492009 /H20850
144427-4which indicate a large ratio 3–20 of spin-up to spin-down
conductivities. Again, despite s-dhybridization, it is these
distinct properties which justify giving the name 4 sto these
spin-up electrons at the Fermi level. They are responsible formost of the electrical conductivity.
It appears, therefore, that the s-dexchange model /H20849Sec. II/H20850
would be more reasonable
15,17for the problem of current-
induced torques on domain walls, in many materials. Oneexception is iron-rich Fe-Mn, Fe-Cr, Fe-V , and Fe-Ti, wheredeviations from Matthiessen rule
25show conduction by spin-
down 3 dcarriers to be dominant. Hall effect data for Fe-Cr
/H20849Ref. 26/H20850show these carriers to be holelike. There, our
purely 3 dmodel may apply even for current-induced torques
/H20849Sec. IV/H20850.
VII. CONCLUSIONS AND FINAL REMARKS
The model based on 3 ditinerant electrons only, used by
Tserkovnyak et al.7for their original derivation of Eq. /H208492/H20850is
conceptually simpler than the s-dexchange model, which
uses two different kinds of electrons. Also, it is less plaguedby uncertainties arising from s-dhybridization.
Our present treatment of Gilbert damping in this model
achieves maximum mathematical simplicity, as well as maxi-mum physical clarity and insight /H20851Fig. 1/H20849b/H20850/H20852, through the useof a semiclassical equation /H20851our Eq. /H208496/H20850/H20852for the precession of
a3dspins
n. This method was pioneered by Turov5in con-
nection with the s-dexchange model, but has almost been
forgotten since.
Further simplification happens because we do not try, like
Tserkovnyak et al. , to rederive known results about spin re-
laxation /H20849see Refs. 3and8/H20850. Instead, we just focus on the
Gilbert damping part of the problem.
The most important and least trivial ingredient for our
calculation is the choice8of the direction s0toward which the
spins relax /H20851Eq. /H208494/H20850and /H208497/H20850/H20852, also made by Turov for the s-d
exchange model.
In the case of current-induced torques on a domain wall,
the formulas obtained for the angle /H9274/H20851Eq. /H2084912/H20850/H20852and for the
fictitious field Hnad/H20851Eq. /H2084915/H20850/H20852are the same as they would be
in a similar theory14,15,17based on s-dexchange, even though
exchange plays a much less explicit role in the equations. Ofcourse, the values of parameters such as P,P
nandnemay be
somewhat different. Our results are consistent with those ofTserkovnyak et al. ;
7for example, the dimensionless coeffi-
cient/H9252, used by these authors to describe the intensity of the
nonadiabatic torque, can be shown in the 3 dmodel to be
equal to the Gilbert constant /H9251, itself given by our Eq. /H208492/H20850.
On the other hand, /H9252/H11022/H9251holds in the s-dexchange model.
1S. V . V onsovskii, Zh. Eksp. Teor. Fiz. 16, 981 /H208491946 /H20850.
2E. A. Turov, Izv. Akad. Nauk SSSR, Ser. Fiz. 19, 474 /H208491955 /H20850.I n
this paper, damping disappears exponentially at low temperaturebecause of the momentum gap.
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Physics , edited by F. Rado and D. Suhl /H20849Academic, New York,
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4D. L. Mills, A. Fert, and I. A. Campbell, Phys. Rev. B 4, 196
/H208491971 /H20850.
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6B. Heinrich, D. Freitova, and V . Kambersky, Phys. Status Solidi
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8H. Hasegawa, Prog. Theor. Phys. 21, 483 /H208491959 /H20850. See Eqs.
/H208492.12 /H20850,/H208494.7/H20850, and /H208495.4/H20850–/H208495.5/H20850and Fig. 1.
9M. B. Walker, Phys. Rev. B 3,3 0 /H208491971 /H20850. See Eq. /H208493.21 /H20850.
10C. Herring, in Magnetism , edited by G. T. Rado and H. Suhl
/H20849Academic Press, New York, 1966 /H20850, V ol. 4, pp. 144 and
162–164.
11A. P. Malozemoff and J. C. Slonczewski, Magnetic Domain
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12C. Herring, Phys. Rev. 85, 1003 /H208491952 /H20850;87,6 0 /H208491952 /H20850.
13S. Chikazumi, Physics of Magnetism , 1st ed. /H20849Wiley, New York,
1964 /H20850, pp. 18 and 191.
14L. Berger, Phys. Rev. B 75, 174401 /H208492007 /H20850.
15L. Berger, J. Appl. Phys. 49, 2156 /H208491978 /H20850; Phys. Rev. B 33,
1572 /H208491986 /H20850.
16L. Berger, J. Appl. Phys. 55, 1954 /H208491984 /H20850; Phys. Rev. B 73,
014407 /H208492006 /H20850.
17S. F. Zhang and Z. Li, Phys. Rev. Lett. 93, 127204 /H208492004 /H20850.
18G. C. Fletcher, Proc. Phys. Soc., London, Sect. A 65, 192
/H208491952 /H20850.
19L. Hodges, H. Ehrenreich, and N. D. Lang, Phys. Rev. 152, 505
/H208491966 /H20850. See Figs. 1 and 12.
20S. Ingvarsson, L. Ritchie, X. Y . Liu, G. Xiao, J. C. Slonczewski,
P. L. Trouilloud, and R. H. Koch, Phys. Rev. B 66, 214416
/H208492002 /H20850.
21V . Kambersky, Can. J. Phys. 48, 2906 /H208491970 /H20850.
22C. S. Wang and J. Callaway, Phys. Rev. B 9, 4897 /H208491974 /H20850;J .W .
D. Connolly, Phys. Rev. 159, 415 /H208491967 /H20850; S. Wakoh and J. Ya-
mashita, J. Phys. Soc. Jpn. 19, 1342 /H208491964 /H20850.
23A. V . Gold, J. Appl. Phys. 39, 768 /H208491968 /H20850. See Fig. 2.
24E. M. Pugh, Phys. Rev. 97, 647 /H208491955 /H20850; E. R. Sanford, A. C.
Ehrlich, and E. M. Pugh, ibid. 123, 1947 /H208491961 /H20850; A. C. Ehrlich,
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25A. Fert and I. A. Campbell, J. Phys. F: Met. Phys. 6, 849 /H208491976 /H20850.
26G. C. Carter and E. M. Pugh, Phys. Rev. 152, 498 /H208491966 /H20850.GILBERT DAMPING AND CURRENT-INDUCED TORQUES … PHYSICAL REVIEW B 80, 144427 /H208492009 /H20850
144427-5 |
PhysRevB.75.174430.pdf | Reliability of Sharrocks equation for exchange spring bilayers
D. Suess, *S. Eder, J. Lee, R. Dittrich, and J. Fidler
Institute of Solid State Physics, Vienna University of Technology, Vienna, A-1040 Austria
J. W. Harrell
MINT Center and Department of Physics and Astronomy, University of Alabama, Tuscaloosa, Alabama 35487–0209, USA
T. Schrefl and G. Hrkac
Department of Engineering Materials, The University of Sheffield, Sheffield, S-10 2TN United Kingdom
M. Schabes, N. Supper, and A. Berger
San Jose Research Center, Hitachi Global Storage Technologies, San Jose, California 95135, USA
/H20849Received 19 January 2007; published 22 May 2007 /H20850
A Monte Carlo approach and a modified nudged elastic band method are used to study the dynamic
coercivity of interacting particle arrays in particular perpendicular recording media and exchange spring bi-layers. Monte Carlo simulations are performed to study the effect of the interactions on the dynamic coercivityof interacting particle arrays. It is shown that the interactions in magnetic recording media only slightlyinfluence the dynamic coercivity. The reliability of energy barrier measurements based upon Sharrock’s equa-tion for frequency-dependent coercivity data is investigated using a modified nudged elastic band method. It isshown that the extrapolated energy barrier at zero field may deviate from the correct one by up to 18% if theconventional exponent n=1.5 is assumed. Our micromagnetic simulations furthermore indicate that the accu-
racy of the extrapolated energy barrier can be improved by about a factor of 3 upon measuring the dynamiccoercivity at an angle of 45° and using the exponent nas an additional fit parameter.
DOI: 10.1103/PhysRevB.75.174430 PACS number /H20849s/H20850: 74.25.Ha
I. INTRODUCTION
With increasing areal density in magnetic recording, new
concepts have to be introduced in order to obtain a highthermal stability and a good writeability and, at the sametime, a good signal-to-noise ratio. For example, a break-through technology in longitudinal recording was introducedwith the concept of antiferromagnetic coupled /H20849AFC /H20850
media.
1,2Recently, perpendicular recording was introduced
into products, which allows a further increase in areal den-sity. With increasing areal density the grains in the recordingmedia have to be decreased in diameter. However, in themost simple picture where the thermal stability depends onthe volume of one grain, a minimum volume is required toobtain the required thermal stability. In future perpendicularrecording media it will be a trade-off between areal densityand thermal stability. Therefore it is important to be able tomeasure the thermal stability of advanced magnetic record-ing media with high accuracy. The lifetime of stored infor-mation /H20849thermal stability /H20850in granular recording media is ob-
viously connected to the stability of the magnetization statesin each grain, which can be estimated by the Arrhenius-Néelformula
/H9270=/H92700e/H9004E/kBT. /H208491/H20850
Here, /H9004Eis the energy barrier which separates the two mag-
netic lowest-energy states in a recording media grain. /H92700is
the inverse of the attempt frequency. A commonly usedmethod to determine this energy barrier as well as the short-time coercive field /H20849switching field /H20850H
0of longitudinal re-
cording media was proposed by Sharrock.3More recently,the validity of Sharrock’s equation for more complex mag-
netic recording materials, such as AFC media was investi-gated by Margulies et al.
4
In this paper the validity of Sharrock’s equation for the
case of perpendicular recording media and, more specifically,for the case of exchange spring media is investigated. Ex-change spring media consist of strongly-exchange-coupledhard and soft layers. Exchange spring magnets were initiallyintroduced by Coehoorn et al.
5and Kneller and Harwig6for
permanent magnet applications. The optimal tuning of thefraction of the soft magnetic phase and the hard magneticphase allowed the design of materials with a high remanenceand at the same time a high coercive field.
7Experiments on
exchange spring films, in particular on a bilayer structureconsisting of a soft magnetic NiFe layer, coupled to a CoSmlayer, were done by Mibu et al.
8and Fullerton et al.9for the
scope of a high-energy product for hard magnetic materials.
Recently, the compositions of hard and soft magnetic lay-
ers were introduced theoretically10,11to reduce the write field
requirements in magnetic recording. Experimental work on
exchange spring media was done by Wang et al.12and Sup-
peret al.13The influence of the interface coupling on the
coercive field and the compression of the domain wall at thehard-soft interfaces can be found in Refs. 14–17.
In a multilayer structure with continuously increasing an-
isotropy from layer to layer it was shown theoretically thatthe coercive field can be decreased to an arbitrarily smallvalue while keeping the energy barrier /H20849thermal stability /H20850
constant.
18
Studies of exchange spring structures show that extremely
hard magnetic films can be written with a limited head fieldif they are coupled to softer magnetic layers. InterestinglyPHYSICAL REVIEW B 75, 174430 /H208492007 /H20850
1098-0121/2007/75 /H2084917/H20850/174430 /H2084911/H20850 ©2007 The American Physical Society 174430-1the scope of exchange spring media /H20849ESM /H20850in magnetic re-
cording is opposite to the scope of exchange spring magnetsfor permanent magnets. In magnetic recording ESM shoulddrastically decrease the coercive field, while it should bemaintained high in permanent magnet applications.
The paper is structured as following. In Sec. II the basic
concept of measuring the thermal stability using Sharrock’sequation is given. In Sec. III micromagnetic models are dis-cussed that allow one to simulate magnetic structures at finitetemperature. In particular the introduction of a Monte Carlomethod is given that allows one to simulate the hysteresisloop of recording media at finite temperature. Furthermore,Sec. III deals with the nudged elastic band method, whichallows for the calculation of energy barriers of magneticstructures.
In Sec. IV validation of Sharrock’s equation is investi-
gated for perpendicular recording media and exchange springmedia. First, the effect of the interactions field is investigatedusing the Monte Carlo method introduced in the previoussection. Finally, energy barrier calculations on a single grainof various exchange spring media are performed.
II. BACKGROUND OF SHARROCK’s EQUATION
Let us start with a quick review of Sharrock’s equation. In
the following it is assumed that each grain of the recordingsystem can be described by a two-level system. One levelcorresponds to the state with magnetization up; the otherlevel corresponds to the state with magnetization down. Oneis interested in the average lifetime of the state with magne-tization pointing up. The occupation probabilities of the twoenergy levels P
1andP2satisfy the normalization condition
P1+P2=1 and the master equationdP1
dt=−w12P1+w21P1,
where w12is the transition rate from the up state to the down
state and w21the transition rate from the down to the up
state. w12is the inverse of the average lifetime of the up
state, w12=1
/H9270. The magnetization as a function of time, which
depends on the occupation probability P1and P2, can be
written as
M/H20849t/H20850=Ms/H20849P1−P2/H20850=Ms/H208492P1−1 /H20850. /H208492/H20850
For sufficiently large downward fields the up state has a
much larger energy than the down state. In this limit w21is
much smaller than w12and can be set to zero. Under this
assumption, it follows that P1=e−w12t.
For macroscopic particle assemblies, such as recording
media, in an accurate approach the energy barrier has to bereplaced by a distribution of energy barriers, which results inthe fact that the decay of the magnetization no longer followsan exponential decay. Instead, one finds that for a distribu-tion of energy barriers the magnetization decreases accordingto a logarithmic law as a function of time.
19
In the following the simple case of only one energy bar-
rier height is investigated. The average life time /H9270can be
extracted by substituting the equation for P1into the equa-
tion for M/H20849t/H20850and calculating the time t0, when M/H20849t0/H20850=0. It
follows that t0=/H9270ln/H208492/H20850. Therefore, applying a field and mea-
suring the time t0until the magnetization becomes zero al-lows one to determine /H9270, which depends on the system, par-
ticularly on the energy barrier separating the state up fromthe state down. From the measurement of the time
/H9270the
energy barrier can be extracted using Eq. /H208491/H20850. However, the
energy barrier of recording media at zero field cannot beextracted from
/H9270, because the average lifetime /H9270for media is
usually several years and cannot be accessed experimentally.A way to enhance the decay of the magnetization is to applyan external field that opposes the magnetization. From thedecay of the magnetization at finite fields one tries to esti-mate the thermal stability at zero field. For Stoner-Wohlfarthparticles the energy barrier at finite opposing field is con-nected to the energy barrier at zero field by the relation
/H9004E=/H9004E
0/H208731−H
H0/H20849/H9258/H20850/H20874n
, /H208493/H20850
where H0/H20849/H9258/H20850is the Stoner-Wohlfarth switching field, when
the external field is applied at an angle /H9258with respect to the
anisotropy axis. Upon applying the external field exactly par-allel to the easy axis, the exponent nis found to be 2. How-
ever, the exponent will deviate significantly if
/H9258/H110220. Victora
expressed the energy barrier as a series expansion as /H9004E
=C1/H208491−H/H0/H208503/2+O/H208495/2 /H20850.20Harrell investigated in detail
the exponent nas a function of the external field Hand the
angle between the external field and the easy axis of singledomain particles.
21He found that for an angle /H9258=15.9° the
exponent nis very close to 1.5 for all external field values.
For/H9258=1° the exponent depends on the external field and
decreases from 1.85 to 1.62 as the external field increasesfrom zero to the coercive field. For
/H9258=45° the value of the
exponent nis between 1.4 and 1.5. For the analysis of ex-
periments, different values of the exponent nare used, such
asn=2 /H20849Ref. 22/H20850andn=3/2 /H20849Ref. 23/H20850.
Substituting the Arrhenius-Néel formula into Eq. /H208493/H20850leads
to Sharrock’s equation
Hc,dyn=H0/H208771−/H20875kBT
/H9004E0ln/H20873t0
ln/H208492/H20850/H92700/H20874/H208761/n/H20878. /H208494/H20850
Therefore applying different external fields Hc,dynand mea-
suring for every field the time t0until the magnetization be-
comes zero allows one to determine /H9004E0andH0. This pro-
cedure is usually called measuring the time dependence ofthe coercivity.
III. MICROMAGNETIC THEORY
A. Energy barriers
In magnetic storage applications thermal switching events
determine the long-term stability of the stored information.The main difficulty in the computation of transition pro-cesses is caused by the disparity of the time scales. If thethermal energy k
BTis comparable to the energy barrier /H9004E
separating two local energy minima, direct simulations of theescape over the energy barrier using Langevin equation arepossible.
24,25However, this is usually not the case in magnet
recording applications where kBT/H11270/H9004E. Due to the granular-
ity in magnetic recording simulations, it is a good approxi-mation that switching occurs grain by grain. Therefore, theSUESS et al. PHYSICAL REVIEW B 75, 174430 /H208492007 /H20850
174430-2thermal stability can be estimated if the energy barrier of
each grain is known.
Henkelman and Jónsson proposed the nudged elastic band
method to calculate minimum-energy paths.26A path of the
nudged elastic band method is represented by a sequence ofimages. One image represents one magnetization state of themagnetic system. An initial path is assumed which connectsthe initial magnetization state M
/H20849i/H20850with the final magnetiza-
tion state M/H20849f/H20850.
In the work of Henkelman and Jónsson chemical pro-
cesses are simulated. Therefore the coordinates of thenudged elastic band method denote the position of particles.In contrast to space coordinates, the magnetization in micro-magnetics has to fulfill the constraint that the magnitude re-main constant with time. Therefore it is not possible to di-rectly use the formulation of the nudged elastic band methodas proposed by Henkelman and Jónsson. Dittrich et al. suc-
cessfully applied the nudged elastic band to micromagneticsusing polar coordinates in order to fulfill the constraint of aconstant magnetization.
27However, convergence problems
can occur because of the problem of a good definition of thedifference vector between two magnetization states in polarcoordinates. The difference vector is required in the nudgedelastic band method in order to relax the initial path towardsthe minimum-energy path.
In order to avoid this problem the magnetization of the
nudged elastic band method is represented by Cartesian co-ordinates in the following. A modified relaxation procedurein the nudged elastic band method is proposed. Every imageconsists of Mdiscretization points /H20849e.g., node points of the
finite-element mesh or cells of a finite-difference scheme /H20850.
On each discretization point the magnetic polarization is
described by a three-dimensional vector. The magnetizationof the image iand the discretization point kis given by
J
i,k=/H20849Jx,Jy,Jz/H20850. /H208495/H20850
The optimal path can be found by solving the following par-
tial differential equation for the magnetization Ji,kon every
node point on each image:
/H11509Ji,k
/H11509t=−/H20841/H9253/H20841
JsJi,k/H11003/H20851Ji,k/H11003Di,k/H20849J/H20850/H20852. /H208496/H20850
The three-dimensional vector Di,kcan be regarded as an ef-
fective field. The right-hand side of Eq. /H208496/H20850has the same
form as the damping term of the Landau-Lifshitz-Gilbertequation. As a consequence Eq. /H208496/H20850conserves the magnitude
of the magnetization in time. The vector D
iis composed of
three-dimensional vectors Di,kon every discretization point
of each image i,
Di=/H20849Di,1,Di,2, ..., Di,M/H20850. /H208497/H20850
This vector, which governs the relaxation of the images to-
wards the minimum-energy path, is calculated using Eq. /H208498/H20850,
Di=/H20853Heff,i/H20849Ji/H20850−/H20849Heff,i/H20849Ji/H20850·ti/H20850ti/H20854+Fi. /H208498/H20850
The effective field is the negative functional derivative of the
total Gibbs’ energy density of the image i,Heff,i=−/H9254/H9255Gibb
/H9254J=2A
JS/H9004Ji+2Ku
JS2/H20849Ji·u/H20850u+HS+Hext.
/H208499/H20850
The first term denotes the exchange energy contribution with
Aas the exchange constant. The second term is the aniso-
tropy term with Kuas the magnetocrystalline anisotropy con-
stant and uthe unitary direction vector of the easy magneti-
zation axis. HSandHextare the stray field and the external
field, respectively.
Care has to be taken when calculating the local tangent ti
at an image i. The single use of either a forward-difference
approximation, backward-difference approximation, or acentral-difference approximation develops kinks in thepath.
26The kinks prevent the string from converging to the
minimum-energy path. The optimal choice of the appropriatedifference approximation depends on the energy differencebetween successive images. In a first approach, forward dif-ferences climbing up a hill, backward differences goingdown a hill, and central differences at energy minima andmaxima are used. The tangent t
ican be calculated using
ti=Ji+1−Ji
/H20648Ji+1−Ji/H20648ifE/H20849Ji−1/H20850/H11021E/H20849Ji/H20850/H11021E/H20849Ji+1/H20850, /H2084910/H20850
ti=Ji−Ji−1
/H20648Ji−Ji−1/H20648ifE/H20849Ji−1/H20850/H11022E/H20849Ji/H20850/H11022E/H20849Ji+1/H20850, /H2084911/H20850
ti=Ji+1−Ji−1
/H20648Ji+1−Ji−1/H20648ifE/H20849Ji−1/H20850/H11021E/H20849Ji/H20850/H11022E/H20849Ji+1/H20850
or if E/H20849Ji−1/H20850/H11022E/H20849Ji/H20850/H11021E/H20849Ji+1/H20850. /H2084912/H20850
This prevents the formation of kinks. A detailed analysis of
this topic and the motivation for this choice of the tangentcan be found in the work of Henkelman and Jónsson.
26The
norm which is used in all expressions is the L2norm.
The last term of Eq. /H208498/H20850denotes the spring force. It pre-
vents the images from moving towards the end points andlocal minima of the path, giving a low resolution near saddlepoints and a high resolution near energy minima. This prob-lem is known as “sliding-down” and can be solved by intro-ducing spring forces between the images which make themstay equally spaced in the L
2norm:
Fi=k
/H92620/H20849/H20648Ji+1−Ji/H20648−/H20648Ji−Ji−1/H20648/H20850/H9270i
/H20648/H9270i/H20648. /H2084913/H20850
The direction of the spring force is given by the difference of
the magnetization state of two images,
/H9270k+=Jk+1−Jk, /H2084914/H20850
/H9270k−=Jk−Jk−1, /H2084915/H20850
/H9270k=/H9270k+ifE/H20849Jk−1/H20850/H11021E/H20849Jk/H20850/H11021E/H20849Jk+1/H20850, /H2084916/H20850RELIABILITY OF SHARROCKS EQUATION FOR … PHYSICAL REVIEW B 75, 174430 /H208492007 /H20850
174430-3/H9270k=/H9270k−ifE/H20849Jk−1/H20850/H11022E/H20849Jk/H20850/H11022E/H20849Jk+1/H20850. /H2084917/H20850
One problem is the choice of the strength of the spring con-
stant k. The optimal value for kdepends on the number of
images used, on the number of finite elements, and on thesize of the model. It is difficult to give a general rule for thevalue of the spring constant. It should be strong enough toprevent images from falling down into the energy minima,but not too strong as to dominate by orders of magnitude inEq. /H208498/H20850. Fortunately, the absolute value of kis usually not
very critical and can be varied over several orders of magni-tude without losing speed within the time integrationscheme.
B. Monte Carlo simulations
The nudged elastic band method is a powerful tool to
estimate the thermal stability for systems with small numbersof energy minima and saddle points. However, for calcula-tion of the magnetization decay of a granular recording me-dia the sole application of the nudged elastic band methoddoes not provide the magnetization as a function of time orfield. For these systems a better approach is the use of MonteCarlo methods. Bortz et al. investigated activated reversal
processes of Ising spin systems with Monte Carlo methods.
28
Charap et al. used Monte Carlo methods in order to estimate
the areal density limit of longitudinal recording.29The time
increment in the Monte Carlo method was adjusted accord-ing to the average time between successful reversals. There-fore the method could describe magnetization reversal pro-cesses of any time span of interest. However, the methodused by Charap et al. is not suitable to calculate hysteresis
loops with different field sweep rates. Chantrell et al. used a
Monte Carlo method to model the low-field susceptibility ofa cobalt granular system.
30Standard Monte Carlo steps are
performed in order to achieve a correct thermodynamic de-scription of the magnetization states close to an energy mini-mum. In order to model thermal activations over larger en-ergy barriers the Arrhenius-Néel model is applied. For eachgrain of the recording media the probability of switchingwithin the measuring time t
m/H20849time step of the Monte Carlo
method /H20850is given by
Pr=1− e−tm//H9270, /H2084918/H20850
where /H9270is the relaxation time given by Eq. /H208491/H20850. The Monte
Carlo simulations performed in this paper are based on thework by Chantrell et al. A granular microstructure was con-
structed using Voronoi tessellations. The equilibrium magne-tization state is described with one magnetic polarizationvector. For every magnetization state the finite-elementmethod is used to calculate the effective field on every grainof the media. The effective field contains the demagnetizingfield of the neighboring grains, the exchange field, and theexternal field. For the Monte Carlo method one grain iof the
media is chosen at random. The switching probability withinthe time step t
mwas calculated according to Eq. /H2084918/H20850.O n
average all grains are chosen one time within the time tm.I n
the following simulations the time step tmwas chosen suffi-
ciently small that the results do not depend on tm. The energybarrier in Eq. /H2084918/H20850depends on the effective field acting on
grain i. In order to calculated the energy barrier two different
approached are used. In the first approach we followed thework of Chantrell et al.
30The energy barrier is calculated
using the Pfeiffer approximation.31In the second approach
the energy barriers for the system were precomputed usingthe nudged elastic band method. In order to calculate theenergy barriers for an arbitrary grain iof the media the fol-
lowing procedure was applied. A finite-element model wasconstructed to model a standard grain with a basal plane of1n m/H110031 nm and a thickness that equals the film thickness.
The obtained energy barrier was multiplied by the area of thebasal plane of the grain i. In order to save computational
time in a preprocessing step a table was constructed thatcontains the energy barrier for discrete values of the effectivefield and the angle
/H9258between the external field and the easy
axis. For every field value and angle /H9258the energy barrier was
calculated using the nudged elastic band method as describedin the previous section. Figure 1compares the precomputed
energy barriers using the nudged elastic band method withthe Pfeiffer approximation for a grain with a rectangularbasal plane with an edge length of 1 nm. The film thicknessis 20 nm, the anisotropy constant K
1=3/H11003105J/m3, and the
exchange constant A=10−11J/m. The magnetic polarization
Js=0.5 T. The demagnetizing field of the grain which leads
to a shape anisotropy was not taken into account. For theprecomputed barriers the external field was discretized be-tween zero and the switching field using 20 mesh points. Theangle
/H9258was discretized between 0 and 90° using 14 discreti-
zation points. Figure 1shows that the Pfeiffer approximation
is well suited to estimate the energy barriers even for a grainwith a thickness of 20 nm.
For the Monte Carlo simulation a second-order interpola-
tion scheme was used to evaluate the energy barrier for anyarbitrary point E/H20849H,
/H9258/H20850. This method allows for the calcula-
tion of the thermal stability of recording structures where the
thermally activated reversal mechanism occurs via a forma-tion of a nucleation. This is particularly important for ex-change spring media.
IV . MICROMAGNETIC RESULTS
A. Monte Carlo simulations of single-phase media
Sharrock’s equation /H20851Eq. /H208494/H20850/H20852was derived under the as-
sumption that no interaction fields act on the media. How-ever, if the time-dependent coercivity is measured for agranular recording media, this assumption may not be justi-fied. The internal field that acts on one grain changes duringthe measurement. At the beginning of the measurement allgrains point up. The full demagnetizing field adds to theexternal field. At M
z=0 the demagnetizing field is zero /H20849at
least within the mean-field approximation /H20850, leading to zero
demagnetizing field. However, the field Hc,dynin Eq. /H208494/H20850is
assumed to be constant. If the external field is applied at afinite angle with respect to the film normal, apart from themagnitude of the internal field, also the angle of the internalfield changes during the measurement. A similar problemoccurs if the intrinsic hysteresis loop of a tilted recordingmedium is measured. The internal field angle /H20849sum of theSUESS et al. PHYSICAL REVIEW B 75, 174430 /H208492007 /H20850
174430-4external field, the exchange field, and the demagnetizing
field /H20850changes along the hysteresis loop even if the angle of
the applied field is kept constant. This problem was dis-cussed by Richter who suggested an iterative procedure tocompensate for the error.
32Recently, the iterative procedure
was used to measure intrinsic hysteresis loops of perpendicu-lar recording media at different angles between the easy axisand the film normal.
33
In order to investigate the influence of the interaction field
on the dynamic coercivity, Monte Carlo simulations as de-scribed in Sec. III are performed. A recording media with20/H1100320 grains is simulated. The grain diameter is 6.5 nm and
the film thickness is 20 nm. The magnetic polarization is0.5 T and the exchange constant is A=10
−11J/m. The aniso-
tropy constant is K1=3/H11003105J/m3. No distribution of the
easy axis is assumed in order to clearly separate the effect ofthe interaction field on the dynamic coercivity. The externalfield is applied at an angle of 15.9° with respect to the easyaxis. In a first set of simulations the exchange field and thestray field were not taken into account. The dashed lines inFig.2show the remanent hysteresis loops for different wait-
ing times tat a temperature of T=300 K. The remanent hys-
teresis loops are obtained by first saturating the sample. Anexternal field His applied for a time t. After the time tthe
field is removed and the remanence is measured. This is donefor different fields Hin order to obtain the remanent hyster-
esis loop. The different dashed curves in Fig. 2denote simu-
lations for different waiting times t.
The numerically obtained values of the dynamic coerciv-
ity are plotted as a function of ln /H20849
/H9260t/H20850in Fig. 3.tis the
waiting time and /H9260=1/ /H20851/H92700ln/H208492/H20850/H20852, where /H92700=10−9s. The
curves in Fig. 3are fitted using Eq. /H208493/H20850in order to determine
the energy barrier /H9004E0andH0. Equivalently the energy bar-
rier/H9004E0andH0can be obtained by fitting H(ln/H20849/H9260,t/H20850)data to
Sharrock’s equation. Equation /H208493/H20850is the inverse function of
Sharrock’s equation.
For the simulations neglecting the demagnetizing field
and the exchange field the dynamic coercivities /H20849circles inFig.3/H20850agree very well with the values obtained from Shar-
rock’s equation /H20849solid line in Fig. 3/H20850./H9004E0andH0in Shar-
rock’s equation were calculated using the micromagnetic in-put parameters. The differences between the analyticallyobtained dynamic coercive fields /H20849from Sharrock’s equation /H20850
and the numerical values were smaller than 10
−3T
/H20849/H110210.4% /H20850for all simulations.
The numerical obtained curves of Fig. 3were fitted with
Sharrock’s equation in order to obtain the energy barrier /H9004E
andH0. The exponent nin Eq. /H2084919/H20850was assumed to be n
=1.55 which follows from the Pfeiffer approximation. Asexpected for zero interactions, the fitted values of /H9004EandH
0
agree very well with the calculated ones. The fitted values
are/H9004E0,fitt=48.32 kBT300and/H92620H0,fitt=0.918 T. The Stoner-
FIG. 1. /H20849Color online /H20850Energy barrier as a function of the external field and the angle /H9258between the easy axis and the external field. The
grain has a rectangular basal plane with edge length of 1 nm. The film thickness is 20 nm. Left image: the energy barrier was calculatedusing the nudged elastic band method. The barrier is calculated for 20 different values of the external field and 14 values of the angle
/H9258. Right
image: the Pfeiffer approximation is used to estimate the energy barrier.
FIG. 2. Remanent hysteresis loops obtained by Monte Carlo
simulations. The temperature T=300 K. No intergranular exchange
field is assumed in the calculations. The waiting time is t=1 s,
10−1s, 10−2s,...,10−9s for the curves a,b,c,..., h, respectively.
The angle between the easy axis and the external field is 15.9°.Dashed lines a-h: the stray field of neighboring grains is not taken
into account. Solid lines A-H: same as a-hbut the demagnetizing
field is taken into account.RELIABILITY OF SHARROCKS EQUATION FOR … PHYSICAL REVIEW B 75, 174430 /H208492007 /H20850
174430-5Wohlfarth theory gives for the micromagnetic input param-
eters/H9004E0,SW=48.7 kBT300and/H92620H0,SW=0.914 T.
In order to investigate the influence of the stray field in-
teractions, the simulations were repeated taking the demag-netizing field into account. The self-demagnetizing field ofone grain of the recording media that leads to a shape aniso-tropy was not taken into account in order to be able to com-pare the results directly with the simulations where the de-magnetizing field was neglected. The demagnetizing fieldleads to a small reduction of the dynamic coercive field asshown in Fig. 2/H20849solid lines /H20850and Fig. 3/H20849dashed line /H20850. This is
in contrast to a simple mean-field theory where at coercivityno mean field acts on the grains. Again Sharrock’s equationwas used to fit the numerical obtained values of the dynamiccoercivity leading to /H9004E
0,fitt=46.47 kBT300and/H92620H0,fitt
=0.88 T.
Finally, simulations were performed taking into account
the demagnetizing field and an exchange field between thegrains with a mean exchange field of 0.16 T. Interestingly,the dynamic coercive field increases as the exchange inter-actions are introduced leading to /H9004E
0,fitt=48.8 kBT300and
/H92620H0,fitt=0.9 T as shown in Fig. 3/H20849dotted line /H20850.
In all previous simulations the energy barriers in the
Monte Carlo simulations where calculated using the Pfeifferapproximation. Simulations with precomputed energy barri-ers using the nudged elastic band method are shown by thedotted dashed line in Fig. 3. The simulations show that for
single-phase media and a film thickness of 20 nm the resultsonly slightly deviate from the simulations using the Pfeifferapproximation /H20849dotted line /H20850.
B. Energy barriers of bilayers with a perfectly soft layer
In the last section it was shown that an extrapolation using
Sharrock’s equation leads to values of H0and/H9004E0,fittthat are
not significantly influenced by the interaction fields. This canbe understood by the following argument. The state of the
film where the values of H0and/H9004E0,fittare measured /H20849fitted /H20850
is the demagnetized state. Therefore, 50% of the grains arepointing up and the other 50% are pointing down, leading tozero mean field in first order. The measured /H9004E
0,fittalso has
a physical meaning for magnetic recording. It approximatesthe energy barrier of a grain at the transition. At the transitionit is justified to assume that no demagnetizing field and noexchange field /H20849this is only true in the limit for weak ex-
change /H20850act on the grain.
However, usually the most unstable grains in magnetic
recording are the grains close to the center of a bit. Here, alarge demagnetizing field acts on the grains. In order to es-timate the thermal stability of a grain at the center of a bit,care has to be taken because the extrapolated value of /H9004E
0,fitt
does not take demagnetizing fields into account. The influ-
ence of neighboring grains /H20849demagnetizing field and ex-
change field /H20850on the energy barrier in a saturated film is
investigated in Ref. 17. It is shown that the influence of the
demagnetizing field and the exchange field can be treatedwith a mean-field approach. /H9004E
0,fittonly corresponds to the
energy barrier of a grain in the demagnetized film if theexponent nof the energy barrier as a function of the external
field is known in detail. In order to calculate the exponent n
for exchange spring media the energy barrier is calculatednumerically using the nudged elastic band method. The ex-change constant and the magnetic polarization are the sameas in the last section. In contrast to the last section only onegrain of the exchange spring media is modeled. This effec-tive mean field can be added to the external field. The graindiameter of Fig. 4shows the energy barrier as a function of
the external field for exchange spring media with differentsoft layer thicknesses. If not stated otherwise, in all the simu-lations the following parameters are used. The magnetic po-larization in the hard layer and the soft layer is J
s=0.5 T.
The exchange constant A=1/H1100310−11J/m. The anisotropy in
the hard layer is K1=1/H11003106J/m3.
In Fig. 4the external field is applied at an angle /H9258=0.5°
with respect to the easy axis. In the limit of an infinitely thicksoft and an infinitely thick hard magnetic layer an analyticexpression for the energy barrier as a function of an appliedfield /H20849
/H9258=0 /H20850was derived by Loxley and Stamps.34The pre-
dictions of the analytical formula are compared with values
obtained from the nudged elastic band method for a soft-layer thickness of 36 nm and an angle
/H9258of 0.5°. As shown in
Fig.4the agreement is excellent, especially for values of the
external field larger than about 0.5 times the dynamic coer-cive field. For large field values the external field stronglypushes the domain wall against the hard-soft interface, lead-ing to a small width of the domain wall at the saddle point,which is the state along the minimum-energy path with thelargest energy. In terms of the domain wall width, the exter-nal field can be thought of an effective anisotropy in theorder of J
sH. For smaller field values, the width of the do-
main wall at the saddle point is larger than the thickness ofthe soft magnetic layer, leading to deviations from the ana-lytical formula due to the finite soft-layer thickness.
Since Eq. /H208493/H20850was derived for single-domain particles, it is
not obvious at all if it can be used for exchange spring mediawhere highly nonuniform states are formed during reversal.
FIG. 3. /H20849Color online /H20850Compilation of the dynamic coercivity
obtained from the waiting time experiments of Fig. 2. The tempera-
ture is T=300 K. Instead of the waiting time tthe logarithm ln /H20849/H9260t/H20850
is used as the yaxis. The constant /H9260=1/ /H20851/H92700ln/H208492/H20850/H20852. The effect of
interaction fields /H20849stray field and exchange field /H20850on the dynamic
coercivity is investigated.SUESS et al. PHYSICAL REVIEW B 75, 174430 /H208492007 /H20850
174430-6In order to check whether Eq. /H208493/H20850is valid or not, the expo-
nent nis calculated as a function of the external field for
various exchange spring media. Similar to experimentswhere the external field is applied perpendicular to the filmplane, the exponent nis calculated for an angle
/H9258of 0.5°.
The exponent nis locally fitted in a field range of about
0.1 T /H20849five data points /H20850. For the fit the numerically calculated
values for /H9004EandH0/H20849/H9258/H20850are used.Figure 5shows that nstrongly depends on the value of the
external field. It is interesting to note that even the single-phase media without a soft layer show a nonconstant expo-nent n. This is different to the Stoner-Wohlfarth theory where
the exponent ndoes not exceed a value of 2 /H20849Ref. 21/H20850. The
reason is that in the investigation the hard-layer thickness is18 nm. Slightly inhomogeneous states are formed that leadto different results from the Stoner-Wohlfarth theory. Micro-magnetic simulations of a sample with a thickness of 10 nmlead to very similar results as reported by Harrell.
21
The numerical results for a soft layer thickness ts
=36 nm very well agree with the analytical results. The ana-
lytical formula34shows that in the limit of zero external field
ngoes towards infinity. Even for larger values of Hthe ex-
ponent nis significantly larger than 1.5. This indicates that
an experimental fit with n=1.5 leads to significantly wrong
results and that the energy barrier as a function of the exter-
TABLE I. Compilation of the error of the extrapolated energy barrier /H9004E=Efitted−Erealand the extrapo-
lated H0using Sharrock’s equation for different soft-layer thicknesses ts. The thickness of the hard layer is
18 nm. /H9258=0.5°. nglobal is determined by fitting the exponent nwith Sharrock’s equation in the whole field
range /H208490/H11021H/H11021H0/H20850. In all other columns Sharrock’s equation is fitted in the range 5 kBT300/H11021/H9004E/H20849H/H20850
/H1102120kBT300. The columns “fit n” determine the error of H0and/H9004Eifnis used as a free fit parameter. The
columns n=1.5 denote the error if nis set constant to 1.5 which is done in most experimental measurements.
In the columns n=nglobal,H0and/H9004Eare determined from the fits using nglobal of the second columns. In the
last row the standard deviation is calculated of the six lines above.
ts/H20849nm /H20850 nglobalError /H92620H0/H20849T/H20850 Error /H9004E/H20849kBT300/H20850
Fitnn =1.5 n=nglobal Fitnn =1.5 n=nglobal
0 1.90 −0.01 − 0.01 0.21 −15.97 − 15.97 −7.19
3 1.87 0.02 − 0.01 0.08 −9.39 − 11.72 −4.80
5 1.51 −0.04 0.03 0.01 −9.74 2.68 −0.61
7 1.47 −0.02 − 0.03 −0.05 10.93 6.91 3.98
9 1.62 0.05 − 0.05 −0.03 15.58 − 5.26 0.28
11 1.78 0.07 − 0.06 0.02 3.61 − 14.61 −2.99
Standard deviation 0.04 0.03 0.09 12.72 9.47 3.96
FIG. 4. Energy barrier of exchange spring media for different
soft-layer thicknesses as a function of the external field strength.The grain diameter is 6 nm; the hard-layer thickness is 18 nm. Theanisotropy constant in the hard layer is K
1,hard=1/H11003106J/m3. The
numbers in the plot /H208490–36 /H20850denote the soft-layer thickness in nm.
The solid lines are fitted to numerically calculated energy barriersusing E
0,H0, and nas fit parameters. The angle between the easy
axis and the external field is /H9258=0.5°. The dotted line shows the
results of the analytical formula that is valid for /H9258=0° and infinite
thick layer thicknesses. Exchanging the xaxis and the yaxis in the
above plot gives a curve which is usually called “time dependenceof the remanent coercivity.”
FIG. 5. Field dependence of the fitting parameter n./H9258=0.5°. The
hard-layer thickness th=18 nm. The numbers next to the curves
denote the soft-layer thickness.RELIABILITY OF SHARROCKS EQUATION FOR … PHYSICAL REVIEW B 75, 174430 /H208492007 /H20850
174430-7nal field can hardly be described by Eq. /H208493/H20850using a constant
value of n.
In the following, the error is estimated that occurs by the
determination of the energy barrier /H9004E0and H0by fitting
H(ln/H20849/H9260,t/H20850)data to Sharrock’s equation. Equivalently, /H9004E0
andH0can be determined by fitting /H9004E/H20849H/H20850with Eq. /H208493/H20850. The
range used of the fit is 5 kBT300/H11021/H9004E/H20849H/H20850/H1102120kBT300. The per-
formance of the fit using Sharrock’s equation is measured by
comparing the extrapolated energy barrier at zero field aswell as the extrapolated H
0with the numerically calculated
energy barrier and switching field. In Table Ithe perfor-
mances of different fits using Sharrock’s equation are com-piled. The actual energy barrier at zero field is 85 k
BT300. The
external field is applied at an angle of 0.5° off the film nor-mal. For a constant value of n=1.5 the extrapolated energy
barriers show significant errors. For zero soft-layer thicknessthe energy barrier is underestimated by 18%. For a soft-layerthickness of 7 nm the energy barrier is overestimated by 8%.For the case of a large soft-layer thickness of 36 nm thelargest error of an underestimation of about 40% occurs. Us-
ing the exponent nas an additional fit parameter the extrapo-
lated energy barrier is even more inexact. Calculating thestandard deviation of the error of the energy barrier for allinvestigated soft-layer thicknesses leads to
/H9268=12.72 kBT300
and/H9268=9.47 kBT300for using nas an additional fit parameter
and a constant nof 1.5, respectively. In contrast to the energy
barrier the extrapolation to determine H0is very good. The
standard deviation of H0is just 0.03 T.
To summarize, E0cannot be extrapolated accurately for
perpendicular recording media and exchange spring mediafrom the dynamic coercivity /H20849pulse duration is assumed to
change from 10
−7s to about 1 s /H20850if the field angle is close to
the easy axis and a constant exponent nis assumed. This is
an important fact because fitting the /H9004E/H20849H/H20850loops of Fig. 4
with Eq. /H208493/H20850in the whole range from 0 /H11021/H9004E/H20849H/H20850/H1102185kBT300
and using E0,H0, and nas free fit parameters leads to fits that
do not seem too bad /H20849solid lines in Fig. 4/H20850. Only for small
energy barriers /H9004E/H20849H/H20850/H110155kBT300can clear misfits be ob-
served.
In the following a method is presented that allows one to
increase the accuracy of the measurement of the energy bar-rier of perpendicular recording media and exchange springmedia. The origin of the wrong extrapolation of Sharrock’sequation for exchange spring media can be found in the fielddependence of the exponent n. The idea is to measure the
energy barrier as a function of the applied field in such a way
that/H9004E/H20849H/H20850can be well described by Eq. /H208493/H20850. This can be
realized as will be shown later by applying the field at a large
angle of 45° with respect to the film normal.
In Fig. 6the simulated energy barriers as a function of the
external field are fitted with Eq. /H208493/H20850. The field angle is 45°
with respect to the easy axis. For soft-layer thicknesses of0–9 nm the fits are very good for the whole field range. The
/H92732values of the fits are 0.3, 0.02, 0.38, and 2 for soft-layer
thickness of 3, 5, 7, and 9 nm, respectively. For very largesoft-layer thicknesses the field dependence of the energy bar-rier can hardly be described with a simple power law. Asshown in Fig. 6fort
s=36 nm the fit is very bad, leading to a
/H92732value of 170.
In order to investigate the quality of the fit in more detail
the exponent nis plotted as a function of the field strength H.
FIG. 6. Same as Fig. 4except that the external field is applied at
an angle of /H9258=45°.
FIG. 7. Field dependence of the fitting parameter n./H9258=45°. The
hard-layer thickness th=18 nm. The numbers next to the curves
denote the soft-layer thickness.
FIG. 8. Same as Fig. 3. However, th=10 nm.SUESS et al. PHYSICAL REVIEW B 75, 174430 /H208492007 /H20850
174430-8Figure 7shows that for this field angle the exponent nonly
weakly depends on the strength of the external field for soft-layer thicknesses relevant for practical media in the rangefrom 3 nm to 11 nm. Due to the insensitivity of nonH, the
energy barrier as a function of the external field can be ex-cellently fitted with Eq. /H208493/H20850.
This insensitivity of the exponent nonHfor
/H9258=45° also
remains if other parameters of the exchange spring mediasuch as the hard-layer thickness are changed as shown in Fig.8. The thickness of the hard layer is 10 nm. The simulation
for zero soft-layer thickness shows an exponent nthat is in
very good agreement with the Stoner-Wohlfarth theory. Ingeneral for different soft-layer thicknesses the exponent nis
not 1.5 but varies from about 1.4 to about 2 depending on theactual sample. Since nmainly depends on the design of the
particular exchange spring media, one can expect that ncan
be determined by using nas a free fit parameter in Sharrock’s
equation of using nas a fit parameter. If the accuracy of the
vibrating sample magnetometer /H20849VSM /H20850measurement is not
sufficient to use nas a free fit parameter, it might be possible
to determine a global nby fitting results obtained using a
contact tester, which can span many decades of time. ForVSM measurements, modelers would need to suggest to ex-perimentalists an appropriate nto use. The improved accu-
racy using nas a free fit parameter in the simulation could be
confirmed as summarized in Table II. Measuring the rema-
nent coercivity in a field range of 5 k
BT300/H11021/H9004E/H20849H/H20850
/H1102120kBT300at an angle 45° and using nas a free fit parameterdrastically increases the quality of the extrapolated energy
barrier. The standard deviation of the error decreases to about
/H9268=2.8 kBT300.
Table IIIcompiles the standard deviations of the error of
the energy barrier and H0for the different measurements and
different hard-layer thicknesses. For both th=18 nm and th
=10 nm, the standard deviation of the error of /H9004E0is about 3
times smaller than for the measurement with /H9258=0.5° and a
constant value of n=1.5. Using nas a free fit parameter
increases the quality of the fit only if nweakly depends
onH, which is the case if the field is applied at an angle
/H9258=45°.
C. Exchange spring media with finite K1in the soft layer
In the previous sections the energy barrier was investi-
gated for exchange spring media where the soft magneticlayer was perfectly soft. However, the assumption of a finitevalue of the anisotropy in the soft layer is more realistic. Theshape anisotropy alone contributes considerably to the aniso-tropy of a granular grain with a large aspect ratio. Interest-ingly, a finite anisotropy in the soft layer is not only morerealistic but also beneficial for magnetic recording because itfurther decreases the coercive field.
35In Fig. 9,/H9004E/H20849H/H20850is
investigated for bilayers with a finite value of the anisotropy
in the soft layer /H20849K1,soft=2/H11003105J/m3/H20850. The anisotropy in the
hard layer is K1,hard=1/H11003106J/m3. The hard layer thickness
is 18 nm. The numbers in Fig. 9denote the soft-layer thick-TABLE II. Same as Table Iexcept that /H9258=45°.
ts/H20849nm /H20850 nglobalError /H92620H0/H20849T/H20850 Error /H9004E/H20849kBT300/H20850
Fitnn =1.5 n=nglobal Fitnn =1.5 n=nglobal
0 1.39 − 0.02 0.08 0.01 − 6.17 8.17 −0.62
3 1.47 − 0.01 0.00 0.00 − 0.31 1.76 0.15
5 1.54 0.00 −0.01 0.00 − 0.48 −2.33 0.06
7 1.68 0.01 −0.02 0.02 − 3.07 −7.77 −1.66
9 1.85 0.02 −0.02 0.05 − 6.55 −12.14 −2.87
11 2.04 0.03 −0.02 0.07 − 9.93 −15.54 −5.45
Standard deviation 0.02 0.04 0.03 3.80 8.89 2.15
TABLE III. Compilation of the standard deviations of the error in H0and/H9004Efor different exchange
spring media. The standard deviation is calculated from data of six different soft-layer thicknesses as shownin Tables IandII.t
his the hard-layer thickness of the bilayer.
th/H20849nm /H20850 /H9258Error /H92620H0/H20849T/H20850 Error /H9004E/H20849kBT300/H20850
Fitnn =1.5 n=nglobal Fitnn =1.5 n=nglobal
10 0.5 0.06 0.11 0.04 9.98 9.24 2.68
10 5.0 0.04 0.03 0.03 6.09 6.30 1.74
10 45.0 0.02 0.02 0.04 3.86 6.78 2.39
18 0.5 0.04 0.03 0.09 12.72 9.47 3.96
18 5.0 0.04 0.06 0.07 8.94 6.55 2.28
18 45.0 0.02 0.04 0.03 3.80 8.89 2.15RELIABILITY OF SHARROCKS EQUATION FOR … PHYSICAL REVIEW B 75, 174430 /H208492007 /H20850
174430-9nesses. It is interesting to note that for a soft-layer thickness
of 11 nm, H0for/H9258=0.5° is similar to H0for/H9258=45°. This is
in contrast to the Stoner-Wohlfarth theory, which predicts aminimum of H
0at/H9258=45°. This effect is also in contrast to
the predictions of a pure pinning behavior, where the coer-cive field follows H
0/H110081/cos /H20849/H9258/H20850according to Kondorsky.36
The observed angular dependence of H0is summarized in
the inset of Fig. 10. The angular dependence can be under-
stood if one keeps in mind that the reversal process in ex-change spring media occurs in two steps. In a first step anucleation is formed into the soft layer. This nucleationprocess shows an angular dependence similar to the pre-diction of the Stoner-Wohlfarth theory, H
N/H11008/H20851sin2/3/H20849/H9258/H20850
+cos2/3/H20849/H9258/H20850/H20852−3/2.
In a second step the domain wall that was nucleated
propagates towards the soft-hard interface. The angular de-pendence of the /H20849pinning /H20850field to push the domain wall in
the hard layer follows HP/H110081/cos /H20849/H9258/H20850. The switching field H0
is determined by H0=max /H20849HN,HP/H20850. Since the nucleation
field and the pinning field show a different angular depen-
dence, it may depend on the angle /H9258if the switching field is
determined by HNor by HP. In the investigated sample the
angular dependence of H0/H20849/H9258/H20850follows a Stoner-Wohlfarth-
like behavior for small angles /H9258. For larger angles the nucle-
ation field becomes smaller than the pinning field. Hence forlarge angles the switching field H
0/H20849/H9258/H20850is determined by HP,
leading to pinninglike behavior H0/H110081/cos /H20849/H9258/H20850. In Fig. 11the
exponent nis calculated by fitting /H9004E/H20849H/H20850data to Eq. /H208493/H20850.
Similar to the results for a perfectly soft layer, the exponent
nstrongly depends on the applied field strength for /H9258=0.5°.
Even values of nlarger than 2 are observed. Similar to the
results of the last section, the exponent nbecomes less de-
pendent on Hif the external field is applied at an angle /H9258
=45° /H20849see Fig. 12/H20850. Values close to n=3/2 are observed. To
find a physical argument that explains why for a variety ofsamples the exponent nbecomes almost constant if the angle
is applied at 45° will be a task of future research.
FIG. 9. Energy barrier of exchange spring media for different
soft-layer thicknesses and different angles /H9258between the external
field and the easy axis. The anisotropy constant in the hard layerand in the soft layer is K
1,hard=1/H11003106J/m3and K1,soft=2
/H11003105J/m3, respectively. The numbers in the figure denote the soft-
layer thicknesses.
FIG. 10. Hysteresis loops of a bilayer with an 18-nm-thick hard
layer and an 11-nm-thick soft layer /H20849K1,hard=106J/m3,K1,soft=2
/H11003105J/m3/H20850. The angle /H9258between the external field and the easy
axis is varied. The inset shows the angular dependence of H0as a
function /H9258.
FIG. 11. Same as Fig. 5/H20849/H9258=0.5°, th=18 nm /H20850. However, the
anisotropy in the soft layer is K1=2/H11003105J/m3.
FIG. 12. Same as Fig. 11except that /H9258=45°.SUESS et al. PHYSICAL REVIEW B 75, 174430 /H208492007 /H20850
174430-10V . CONCLUSION AND OUTLOOK
Monte Carlo simulations of dynamic coercivity simula-
tions have shown that the interaction fields such as the ex-change field and the strayfield do not significantly change thedynamic coercivity. Although Sharrock’s equation was de-rived without taking interaction fields into account, it is wellsuited to describe interacting grains of magnetic structures.
The analysis of the paper shows that the accuracy of mea-
surements of energy barriers of exchange spring media canbe improved by changing the experimental conditions. Wepropose that the external field is applied at 45° with respectto the film normal. For measurements under 45° the expo-
nent nis almost constant which is in contrast to measurement
parallel to the film normal. This makes it possible to use nas
an additional fit parameter along with the fitted energy bar-rier at zero field /H9004E
0and the fitted H0.
ACKNOWLEDGMENTS
The financial support of the Austrian Science Fund
P19350 is acknowledged. I would like to thank P. Visscherfor helpful discussions.
*Electronic address: dieter.suess@tuwien.ac.at
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174430-11 |
PhysRevLett.97.117601.pdf | Origin of Increase of Damping in Transition Metals with Rare-Earth-Metal Impurities
A. Rebei *and J. Hohlfeld
Seagate Research Center, Pittsburgh, Pennsylvania 15222, USA
(Received 18 May 2006; published 11 September 2006)
The damping due to rare-earth-metal impurities in transition metals is discussed in the low concen-
tration limit. It is shown that all established damping mechanisms based on spin-orbit and/or spin-spininteractions cannot explain experimental observations even qualitatively. We introduce a different
relaxation channel due to the coupling of the orbital moments of the rare-earth-metal impurities and
the conduction pelectrons that leads to good agreement with experiment. Using an itinerant picture for
the host ions, i.e., write their magnetization in terms of the electronic degrees of freedom, is key to the
success of our model.
DOI: 10.1103/PhysRevLett.97.117601 PACS numbers: 76.30.Kg, 72.25.Rb, 76.60.Es
Magnetization dynamics has become one of the most
important issues of modern magnetism. This developmentis driven by the technological demand to tailor magneticresponses on ever smaller length and shorter time scales.The importance of this issue manifests itself in a com-pletely new area of research, spintronics, and a huge lit-
erature that cannot be cited here. Selected highlights
include precessional switching by tailored field pulses[1,2], spin-torque [ 3,4], and laser-induced magnetization
dynamics [ 5,6].
In general, magnetization dynamics is described via the
Landau-Lifshitz-Gilbert equation (LLG) [ 7] including ad-
ditional terms to incorporate spin-torque effects [ 8]o r
those due to pulsed optical excitations [ 9]. All these de-
scriptions account for energy dissipation via a phenome-
nological damping parameter /.0011which governs the time
needed for a nonequilibrium magnetic state to return toequilibrium. Recently it has even been suggested that /.0011
determines the magnetic response to ultrafast thermal ag-itations [ 10].
Technological applications call for the ability to tailor /.0011
[11]. The most systematic experimental investigation on
this topic was published by Bailey et al. [12] who studied
the effect of rare-earth-metal doping on the damping inpermalloy. Most rare-earth-metal ions induced a large in-crease of/.0011, but neither Eu nor Gd altered the damping of
permalloy (cf. Fig. 2). Since Gd
3/.0135andEu2/.0135have no
orbital momentum, this points immediately to the impor-tance of the angular momentum in the damping process.Bailey et al. determined damping by reproducing their data
via the LLG equation using /.0011as a fit parameter. This
widely used procedure points to a fundamental problemof this phenomenological approach. Though the LLGequation describes data well, a more microscopic approachis needed to understand the origin of damping.
It was Elliott [ 13] who first studied damping in semi-
conductors due to spin-orbit coupling. Later Kambersky[14] argued that the Elliot-Yafet mechanism should be also
operable in magnetic conductors. Korenman and Prange
[15] developed a more microscopic treatment and foundthat spin-orbit coupling should be important at low tem-
perature in transition metals. Recent measurements ofdamping in magnetic multilayers at room temperature[16] suggest that the s-dinteraction might also be at the
origin of damping [ 17,18]. However, all of the present
models fail to reproduce the data of Ref. [ 12].
In this Letter, we explain the increase of damping in
rare-earth-metal-doped transition metals via a novel orbit-orbit coupling between the conduction electrons and theimpurities. The well-known s-finteraction [ 19] gives rise
to a/.0133g
J/.02551/.01342dependence of the damping that is in contra-
diction to experimental observations [ 12]. In contrast, the
orbit-orbit coupling considered here reproduces the mea-sured/.0133g
J/.02552/.01344dependence of the damping. Both depen-
dencies on the Lande gfactorgJfollow directly from the
fact that the rare-earth-metal ions are in their ground state.Hence, their angular momentum L
f, spin Sf, and total
angular momentum Jfare related by the Wigner Eckard
theorem: Lf/.0136/.01332/.0255gJ/.0134JfandSf/.0136/.0133gJ/.02551/.0134Jf. Deriving
the magnetic moments of the transition-metal ions from theelectronic degrees of freedom is essential to capture thecorrect behavior of damping as a function of J
f. For the
uniform mode, the damping due to orbit-orbit coupling is
of Gilbert form in the low frequency limit.
Taking the wave functions of the d-,f-, and conduction
electrons orthogonal, the Hamiltonian for the rare-earth-metal-doped transition metal in an external field His
H/.0136He/.0135Hf/.0135Hd: (1)
This approximation should be valid for the heavy rare-
earth metals but probably fails for elements like cerium
where valence fluctuations are important. The conductionelectron Hamiltonian H
eis the usual one, He/.0136P
k;/.0027/.0015k;/.0027ak;/.0027yak;/.0027, whereay
k;/.0027andak;/.0027are the creation
and annihilation operators of a conduction electron with
momentum kand spin/.0027./.0015k;/.0027is the energy of the con-
duction electrons including a Zeeman term.
Hfis the Kondo Hamiltonian [ 20] of the localized rare-
earth-metal momentPRL 97,117601 (2006)PHYSICAL REVIEW LETTERSweek ending
15 SEPTEMBER 2006
0031-9007=06=97(11)=117601(4) 117601-1 ©2006 The American Physical Society Hf/.0136/.0255Se/.0001Sf/.0135/.0021Le/.0001Lf/.0255/.0022f/.0001H: (2)
Se=fandLe=fare the spin and angular momentum of
conduction and felectrons, respectively. Le=fare taken
with respect to the position of the impurity. The spin-spin
term is the well-known s-fcoupling used by de Gennes to
reproduce the Curie temperatures in rare-earth metals with/.0255being of the order 0.1 eV [ 19]. The last term is again a
Zeeman term. The middle term is the essential orbit-orbitinteraction needed in our discussion. To get a nonzeroorbit-orbit term due to a single impurity at the center, it
is essential to include higher terms of the partial wave
expansion for the wave functions of the conduction elec-trons:
k/.0133r/.0134/.01364/.0025/.0129/.0129/.0129
VpP1
l/.01360Pm/.0136l
m/.0136/.0255lilf/.0133r/.0134jl/.0133kr/.0134Ylm/.0133/.0018k;/.0030k/.0134/.0002
Y/.0003
lm/.0133/.0018;/.0030/.0134. The first nontrivial contribution for l/.01361is [20]
HLL/.0136i/.01332/.0255gJ/.0134X
k;k0/.0021/.0133k;k0/.0134^k/.0002^k0/.0001Jfay
kak0;(3)
where the orbit-orbit coupling /.0021will be assumed to be a
function of the relative angles of the kvectors and is
almost everywhere zero except for kclose to the Fermi
levelkF. The magnitude of /.0021is not known but is expected
to be of the same order as the spin-spin coupling constant /.0255
[21,22]. The crystalline electric field effect in transition
metals is less than 0.1 meV which is small and hence thespin-orbit term S
e/.0001Lfis neglected. At room temperature
all the rare-earth-metal ions studied in Ref. [ 12] are in their
ground state making the term Sf/.0001Lfineffective as damp-
ing mechanism. This follows immediately from the
Wigner-Eckart theorem.
The Hamiltonian for the host transition-metal ions is
based on the Anderson Hamiltonian with explicit spinrotational invariance in the absence of a Zeeman term[15,23,24]. It is
Hd/.0136/.0015ddy/.0027d/.0027/.0135X
kVkd/.0133ay
k;/.0027d/.0027/.0135dy/.0027ak;/.0027/.0134/.0135U
8/.00262
/.0255U
2Sd/.0001Sd/.0255/.0022d/.0001H; (4)
where Sdis the spin operator of the local delectrons while
their orbital angular momentum is assumed quenched. /.0026is
the charge density operator of the delectrons. In transition-
metal ions such as Ni, Vkd/.00251:0–10:0e V is comparable to
the Coulomb potential U. The hybridization term between
the conduction and delectrons is essential to establish a
spin-independent orbit-orbit coupling between the dand
thefions. The degree of localization of the magnetic
moments increases with decreasing Vkd[25] and controls
the extent to which rare-earth-metal impurities enhancedamping.
The orbit-orbit coupling [cf. Eq. ( 3)] gives no contribu-
tion forGd
3/.0135/.01334f7/.0134as observed in the experiment [ 12]. As
for the element Eu, it is believed from measurements of theparamagnetic susceptibilities that the ionic state isEu
2/.0135/.01334f7/.0134and notEu3/.0135/.01334f6/.0134[19,26]. If this is the casethen clearly this is a state with Lf/.01360and it is the same as
that ofGd3/.0135. Yb is also present in a double-ionized state
[27] and therefore doping with Yb2/.0135/.01334f14/.0134should not
increase damping. This result remains to be confirmed byexperiment. For Eu there is an additional reason why its
angular momentum is quenched. The first excited state of
this latter element lies only about 400 K above the groundstate [ 27] and this can lift the degeneracy of the ground
state. The average orbital angular momentum will there-fore be zero even though L
2remains a good quantum
number [ 28]. Hence our Hamiltonian from the outset re-
produces the experimental results for Eu and Gd andpredicts that doping with Yb should not change the damp-
ing. We next address the remaining rare-earth elements.
First, we outline the steps to derive the damping due to
the orbit-orbit coupling term. We are only interested in thedamping of the dmoments of the transition metal; there-
fore, it is advantageous to adopt a functional integralapproach. Since our system is near equilibrium and farfrom the Curie point, we use the spin wave approximationand expand the spin operators of the fmoments in terms of
Boson operators f
/.0006, wheref/.0006/.0136Sy
f/.0006iSx
f. We keep only
the first nontrivial terms. The integration of the conduction
electrons is carried out exactly. Afterward we integrate theimpurity variables, fandf
y, also exactly but keep only
quartic terms in dandd/.0135. The remaining effective action
has now only the fields danddyand from their equations
of motion the spin propagator hm/.0255/.0133/.0028/.0134m/.0135/.0133/.00280/.0134iof thed
moments,m/.0006/.0136Sx
d/.0006iSy
d, can be determined. We use a
Stratonovich-Hubbard transformation to write this effec-
tive Lagrangian in terms of m/.0006. Then a stationary phase
approximation of the functional generator allows us to
determine the desired propagator and hence the damping.We finally compare the functional form of this result to thatof LLG and discuss why the electronic (itinerant) picture ofthe host transition-metal ions is essential.
The fundamental quantity in our calculation is the gen-
erating functional
Z/.0137/.0017/.0003;/.0017/.0138/.0136Tre/.0255R/.0012
0d/.0028fH/.0255/.0017/.0003/.0133/.0028/.0134m/.0255/.0133/.0028/.0134/.0255/.0017/.0133/.0028/.0134m/.0135/.0133/.0028/.0134g; (5)
where/.0017and/.0017/.0003are external sources and /.0012is inverse
temperature. The propagator, i.e., the connected two--
point Green’s function, of the volume mode of thetransition-metal ions is found by functional differentia-tions with respect to the external sources /.0017
/.0003and/.0017,
hm/.0135/.0133/.0028/.0134m/.0255/.0133/.00280/.0134ic/.0136/.00142lnZ/.0137/.0017/.0003;/.0017/.0138=/.0014/.0017/.0133/.0028/.0134/.0014/.0017/.0003/.0133/.00280/.0134. It is cal-
culated within a double random phase approximation(RPA2) method. The true single particle propagator of
thedbands is first found within a RPA in the presence of
an effective field due to the conduction electrons and the
impurities. In turn, the effect of the fimpurities on the
conduction electrons is calculated within RPA. The result-ing effective Lagrangian is now written in terms of monly
L/.0136/.02551
2mijKijklmkl/.0255Tr ln/.0137G/.02551
d/.0135Km/.0138; (6)
whereG/.02551
d/.0133/.00271;/.00272/.0134/.0136@/.0028/.0255/.0022/.0015d/.0135V2Gc/.0135TrkfGfGcBGcAgPRL 97,117601 (2006)PHYSICAL REVIEW LETTERSweek ending
15 SEPTEMBER 2006
117601-2is the propagator of the delectrons in the presence of the conduction electrons and the rare-earth-metal impurity ( /.0027i/.01361,2
for spin-up and spin-down, respectively). The quadratic term in mrepresents effective anisotropy and spin-charge
interactions and is given by
K/.00271/.00272/.00273/.00274/.0136/.0255U
4/.0133/.0014/.00271/.00272/.0014/.00273/.00274/.02552/.00141/.00271/.00142/.00272/.00141/.00273/.00142/.00274/.0134/.025522V4Gf/.0133GcBGcAGc/.0134/.00271/.00272Gf/.0133GcBGcAGc/.0134/.00273/.00274/.0014/.00271/.00274/.0014/.00272/.00273
/.0255V4GcAGcGfGcBGc: (7)
Integrations over momentum and spin are implied in all these expressions. The different terms that appear in Kare as
follows:Gcis the Green’s function of the conduction electrons in the mean field approximation
G/.02551c/.0133k;/.00271;k0;/.00272;/.0028/.0134/.0136/.0133@/.0028/.0135/.0022"k/.00271/.0255/.0022F/.0134/.0014kk0/.0014/.00271/.00272/.0135i/.0021/.0133k;k0/.0134/.01332/.0255gJ/.0134hJz
fi/.0133k0xky/.0255k0ykx/.0134/.0014/.00271/.00272; (8)
which is off diagonal in momentum due to the orbit-orbit coupling. /.0022"k;/.0027now includes Zeeman terms due to the external
field and the zcomponent of the field due to impurity. The propagator Gfis that of the fions in the presence of both the
conduction electrons and the transition-metal ions, G/.02551
f/.0133/.0028/.0134/.0136@/.0028/.0135/.0022fH/.0135Trk;/.0027fGcAGcBg. TheAandBmatrices are
solely due to the presence of the impurity and represent the indirect coupling between the transition-metal ions and the f
ions
A/.0133k0;/.00271;k;/.00272/.0134/.0136B/.0133k;/.00271;k0;/.00272/.0134/.0003/.0136/.02550/.0027/.0135/.00271/.00272/.0255i/.00210/.0001/.0135
k0k; (9)
where we have set /.02550/.0136/.0255/.0129/.0129/.0129/.0129/.0129/.0129
2Jfp
4/.0133gJ/.02551/.0134,/.00210/.0136/.0021/.0129/.0129/.0129/.0129/.0129/.0129
2Jfp
2/.01332/.0255gJ/.0134, and/.0001/.0006
kk0/.0136/.0133^k0/.0002^k/.0134/.0006. In the trace log term of the effective
Lagrangian, the first nontrivial contribution is of order V4and is given by Fig. 1. The diagram with a single insertion of an f
propagator does not contribute due to the antisymmetry of the orbit-orbit coupling in the momentum space. Varying theeffective action with respect to m
ijgives four equations which can be averaged and differentiated with respect to the
external sources to get the mpropagators. We are only interested in C/.01331221/.0134/.0136hm12m21iwhich is given by
fG/.02551
d11/.0135K11ijhmijigC/.01331221/.0134/.0135K11ijC/.0133ij21/.0134hm12i/.0136/.0255 hm22i/.0255K21ijC/.0133ij21/.0134hm22i/.0255K21ijhmijiC/.01331221/.0134: (10)
In the absence of impurities, these equations are to lowest order the time-dependent generalization of the Hartree-Fock
equations derived by Anderson [ 23]. Using the RPA2 method, we solve for C/.01331221/.0134
C1221/.0133!l/.0134/.0136X
nm11/.0133!n/.0134m22/.0133!n/.0135!l/.0134/.0030/.0020
1/.0135X
n;mK2112/.0133!m/.0134m11/.0133!n/.0135!m/.0134m22/.0133!n/.0135!m/.0135!l/.0134/.0021
; (11)
where!l/.0136/.01332l/.01351/.0134/.0025=/.0012 for integerl. If we ignore the
impurity interaction and replace the average values of the
mijby the Anderson solution, we recover the RPA result
for the propagator of the magnetization. To include theimpurities, we evaluate the dpropagators, m
ij, within RPA.
In the low frequency limit, !/.0028/.0001/.0028!c, we find that the
(retarded) propagator CRof the theory is proportional to
/.0133!/.0255!0/.0135i/.0011!/.0134/.02551. Here,/.0001/.02551is the lifetime of the virtual
dstates [ 23],!cdenotes the frequency of the conduction
electrons, and !0is the ferromagnetic resonance frequency
of the transition metal. This low frequency limit for thedamping is similar to that of the LLG result [ 15]. The
damping/.0011in the spin-conserving channel is proportional
toJ
f/.0133Jf/.01351/.0134/.0137/.0133gJ/.02552/.0134jVj/.01384and is given by
/.0011/.0136cj/.0021Vj4Jf/.0133Jf/.01351/.0134/.01332/.0255gJ/.01344
/.0002/.0020U/.0001E
25/.00253/.0133E/.0255/.0001E/.01342/.0133E/.0135/.0001E/.01342/.0133nmkF/.01342
18!4c/.0135Q/.0133!f/.0134/.0021
:
(12)
Herenis the density of conduction electrons, cis the
concentration of the fimpurities, and E/.0006/.0001Eis the
energy of the up-down dstates. These latter energies can
be determined self-consistently as in the Anderson solution[23] and hence their form is not expected to dependstrongly on the atomic number of the rare-earth-metal
impurity at low concentrations. The explicit form of the
functionQis not needed here but it represents contribu-
tions beyond the ‘‘mean’’ field approximation of the f
impurities and is given by Fig. 1. In Fig. 2, we show that
the leading coefficient of the damping due to non-spin-flipscattering (solid curve) is in very good agreement with the
experimental results of Bailey et al. [12].
Finally we point out the reasons behind insisting on
using the itinerant electrons explicitly instead of the sim-
plers-dexchange interaction which accounts well for
damping in permalloy [ 16]. Using a localized-type
Hamiltonian for the dmoments
d d
d dVV
VVff
cc
FIG. 1. The first diagram that is contributing to the damping of
thedelectrons due to the fimpurities through the conduction
electrons.PRL 97,117601 (2006)PHYSICAL REVIEW LETTERSweek ending
15 SEPTEMBER 2006
117601-3 Hd/.0136/.0255JSe/.0001Sd/.0255/.0022d/.0001Sd (13)
instead of Eq. ( 4), leads to a damping which differs sig-
nificantly from experiment (dashed curve in Fig. 2). This
localized moment Hamiltonian, however, appears to de-scribe well damping in insulators such as heavy rare-earth-metal-doped garnets [ 29]. In garnets, the hybridization
coupling is smaller than in metals. Hence our result alsoexplains why the damping in rare-earth-metal-doped gar-nets is not as strong as in the rare-earth-metal-doped tran-sition metals. The experimental measurements (triangles)
clearly show that at room temperature non-spin-flip scat-
tering is more important than spin-flip scattering whichonly becomes important close to the critical temperature.Again, the data are well reproduced by the orbit-orbitcoupling and the relatively large increase in damping isdue to the large virtual mixing parameter V
kd. In contrast,
thes-fcoupling (squares in Fig. 2) is in conflict with
experiment.
In summary, we have shown that the damping in rare-
earth-metal-doped transition metals is mainly due to anorbit-orbit coupling between the conduction electrons andthe impurity ions. For near equilibrium conditions and inthe low frequency regime this leads to damping for theuniform mode that is of Gilbert form. The orbit-orbitmechanism introduced here is much stronger than thespin-orbit based Elliott-Yafet-Kambersky mechanism
since the charge-spin coupling at the host ion is of the
order of 1–10 eV compared to 0.01 eV for spin-orbitcoupling. The predicted increase of damping is propor-tional toV
4which in transition-metal ions is of the same
order asUthe Coulomb potential. A localized model for
thedmoments based on the s-dexchange is unable to
account for the increase in damping in these doped systemsas a function of the orbital moment of the rare-earth-metal
impurities. An additional test of this damping theory would
be to measure the effect of a single rare-earth element onthe damping in various transition metals. Such experimentswill provide further insight into the dependence of damp-ing onVand will improve our understanding of the itin-
erant versus localized pictures of magnetism.
We acknowledge fruitful discussions with P. Asselin,
W. Bailey, O. Heinonen, P. Jones, O. Myarosov, and
Y . Tserkovnyak.
*Electronic address: arebei@mailaps.org
[1] Th. Gerrits, H. A. M. van den Berg, J. Hohlfeld, L. Ba ¨r,
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FIG. 2. Comparison of the normalized leading factor in the
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15 SEPTEMBER 2006
117601-4 |
PhysRevB.85.184409.pdf | PHYSICAL REVIEW B 85, 184409 (2012)
Harmonic transition-state theory of thermal spin transitions
Pavel F. Bessarab,1,2Valery M. Uzdin,2,3and Hannes J ´onsson1
1Science Institute and Faculty of Science, VR-III, University of Iceland, 107 Reykjav ´ık, Iceland
2Department of Physics, St. Petersburg State University, St. Petersburg, 198504, Russia
3St. Petersburg State University of Information Technologies, Mechanics and Optics, St. Petersburg, 197101, Russia
(Received 14 November 2011; revised manuscript received 17 February 2012; published 9 May 2012)
A rate theory for thermally activated transitions in spin systems is presented. It is based on a transition-state
approximation derived from Landau-Lifshitz equations of motion and quadratic expansion of the energy surfaceat minima and first order saddle points. While the flux out of the initial state vanishes at first order saddle points,the integrated flux over the hyperplanar transition state is nonzero and gives a rate estimate in good agreementwith direct dynamical simulations of test systems over a range in damping constant. The preexponential factorobtained for transitions in model systems representing nanoclusters with 3 to 139 transition metal adatoms is onthe order of 10
11to 1013s−1, similar to that of atomic rearrangements.
DOI: 10.1103/PhysRevB.85.184409 PACS number(s): 05 .20.Dd, 75 .10.−b
I. INTRODUCTION
Metastable magnetic states have been studied experimen-
tally in small systems of various kinds, in particular, molec-ular magnets
1and supported2–4and free-standing5transition
metal clusters. The stability of such states with respect tothermal fluctuations is an important issue in many contexts,for example, when assessing the limit to which magneticrecording devices can be miniaturized. Although the systemsmentioned above are quite different, they are all characterizedby two or more magnetic states which correspond to differentorientations and/or different values of the magnetic moments.
A preparation of a system in a particular magnetic state
can be destroyed by thermally activated transitions to otherstates. For long-lived magnetic states, the separation intime scale between fast precession of magnetic momentsand slow transitions between states make direct dynamicalsimulation of spin dynamics
6impractical. This, however,
opens the possibility for the use of a statistical approachfor estimating spin transition rates as well as determiningthe transition mechanism. Statistical approaches have beenpresented previously for a single macrospin,
7,8but we are
not aware of a previous presentation of a statistical ratetheory for systems with multiple spins. Even in small clusters,transitions can involve nucleation and propagation of a domainwall rather than coherent rotation of magnetic moments.
2,3A
macrospin approximation would in such cases give the wrongactivation barrier height and a poor estimate of the rate. Inthis paper, a method for finding the mechanism and rate ofthermal spin transitions is developed by adapting transitionstate theory (TST)
9to multiple spin degrees of freedom. It
gives an Arrhenius law for the transition rate, which can beevaluated using only the input that would be needed for a directsimulation of the spin dynamics—a simulation that would,however, be impossibly long in the cases of interest.
II. THEORY
TST9has been used extensively for estimating the rate of
thermally activated atomic rearrangements such as chemicalreactions and diffusion.
10The separation of time scale
mentioned above makes it possible to estimate the rate fromthe probability of finding the system in the most restrictive andleast likely region separating the initial state from possible
final states—the transition state. Given a transition statedividing surface, f(x)=0, where xrepresents all dynamical
variables in the system, the reaction rate constant, k
TST, can
be estimated for spin systems in a way that is analogous toatomic systems
11as
kTST=1
C/integraldisplay
Re−E(x)/kBTδ[f(x)]v⊥(x)
(1)
×H[v⊥(x)]J(x)/productdisplay
idxi,
where Rdenotes the region associated with the initial state
up to and including the dividing surface, J(x) is a Jacobian
determinant, Eis the energy of the system, v⊥(x)=∇f(x)·˙x
is a projection of the velocity onto the normal of the dividingsurface, and Cis a normalization constant given by
C=/integraldisplay
Re−E(x)/kBTJ(x)/productdisplay
idxi.
A central approximation is that a trajectory only crosses the
dividing surface once,12and this is taken into account by
inserting a Heaviside step function Hinto Eq. (1).F o rs p i n
systems, the relevant variables are taken to be spherical anglesθ
iandφidefining the direction of the ith magnetic moment.
The set of variables for a system of spins is denoted as x≡
{θ,φ}≡{θ1,θ2,..., θ N,φ1,φ2,..., φ N}. The magnitude of the
magnetic moments Mii sa s s u m e dt ob eaf u n c t i o no ft h ea n -
gles,Mi(θ,φ), i.e., an adiabatic approximation is invoked. The
Jacobian determinant is then J(θ,φ)≡/producttext
iM2
i(θ,φ)s i nθi.
The normal projection of the velocity, v⊥(θ,φ), needs to be
estimated at each point on the dividing surface. The equationof motion is taken to be the Landau-Lifshitz equation (seeRef. 13)
dM
i
dt=γMi×∂E
∂Mi, (2)
where γis a gyromagnetic ratio. In the adiabatic limit, this
equation can be split into two equations:
˙φi=γ
Misinθi∂E
∂θiand ˙θi=−γ
Misinθi∂E
∂φi.(3)
184409-1 1098-0121/2012/85(18)/184409(4) ©2012 American Physical SocietyBESSARAB, UZDIN, AND J ´ONSSON PHYSICAL REVIEW B 85, 184409 (2012)
FIG. 1. Comparison of the rate of transitions in a spin trimer
obtained directly from dynamics given by the Landau-Lifschitz-Gilbert equation of motion as a function of the damping constant
αatT=23 K (solid line) and a harmonic TST estimate (dotted line).
Inset: the energy surface near a first order saddle point, representation
of a hyperplanar transition state dividing surface (thick line) and the
spin velocity (arrows).
The length of the velocity vector is proportional to the
magnitude of the energy gradient but the velocity and gradientvectors are perpendicular.
The TST expression for the rate constant can be simplified
by introducing quadratic approximations to the energy surfacearound the critical points to give a harmonic TST (HTST)approximation. The transition state dividing surface is thenchosen to be a hyperplane going through a first order saddlepoint on the energy ridge separating the initial state fromproduct states (see Fig. 1). The hyperplane normal is chosen to
point in the direction of the unstable mode, the eigenvector ofthe Hessian matrix along which the saddle point is a maximum.If second order saddle points on the ridge are high enoughabove first order saddle points, then each first order saddlepoint corresponds to a specific transition mechanism and acertain product state. For each possible final state, one or moreminimum energy paths (MEP) can be found. Following anMEP means advancing each degree of freedom of the system insuch a way that the energy is minimal with respect to all degreesof freedom perpendicular to the path. The nudged elastic band(NEB) method
14can be used to find MEPs between a given
pair of initial and final states. A maximum along an MEPcorresponds to a first order saddle point on the energy surfaceand the highest one gives an estimate of the activation energy.
Unlike atomic systems, the velocity in spin systems is zero
at a saddle point because the gradient is zero. In the vicinityof the saddle point, the energy surface, E(θ,φ), can in general
be approximated as a parabolic function and the magnitudeof the energy gradient and, thereby, the velocity increasesas one moves away from the saddle point. Moreover, sincethe energy gradient lies within the dividing surface at pointson the dividing surface, the velocity is perpendicular to thedividing surface.
The expansion of the energy at the minimum ( β=m) and
at the saddle point ( β=s)i s
E
β(q)=Eβ(0)+1
2D/summationdisplay
j=1/epsilon1β,jq2
β,j, (4)where Dis twice the number of spins. The expansion is
in terms of normal mode coordinates, displacements alongeigenvectors of the Hessian matrix. The Landau-Lifshitzequations become linear with this quadratic approximation tothe energy surface. At the saddle point, one of the eigenvectors,the one corresponding to the unstable mode, is orthogonal tothe dividing surface. Labeling this mode as q
s,1, the velocity
v⊥(θ,φ)=˙qs,1can according to Eqs. (2)–(4)be written as a
linear combination of normal mode coordinates,
v⊥=D/summationdisplay
i=2aiqs,i. (5)
The direction of each eigenvector at the saddle point is chosen
so that ai>0 leads to a positive contribution to v⊥, i.e.,
pointing away from the initial state.
With these quadratic approximations to the energy surface,
the HTST expression for the rate constant becomes
kHTST=/integraltext
e−/summationtextD
j=2/epsilon1s,jq2
s,j/2kBT/summationtextD
i=2aiqidq2...dq D/integraltext
e−/summationtextD
j=1/epsilon1m,jq2
m,j/2kBTdq1...dq D
×Js
Jme−(Es−Em)/kBT, (6)
where Jβ≡J(θβ,φβ). The denominator is simply a product
of Gaussian integrals. The numerator is more complicatedbecause the integrals involved are carried out over the regionwhere v
⊥/greaterorequalslant0, i.e., over the half-plane a2q2+a3q3+···+
aDqD/greaterorequalslant0. After some algebra (which will be published
elsewhere) one obtains
kHTST=1
2πJs
Jm/radicaltp/radicalvertex/radicalvertex/radicalbtD/summationdisplay
j=2a2
j
/epsilon1s,j/producttextD
i=1√/epsilon1m,i/producttextD
i=2√/epsilon1s,ie−(Es−Em)/kBT,(7)
which agrees with an Arrhenius expression with an activation
energy Ea=Es−Emand a temperature independent preex-
ponential, ν.
The theory presented here is classical and makes use of
harmonic approximations to the energy surface. An extensionto full transition-state theory involving statistical samplingwithin the dividing surface as well as the inclusion of quantumtunneling by use of Feynman path integrals, analogous to whathas been formulated for particle systems (see, for example,Refs. 15and16), is an ongoing project.
III. APPLICATIONS
Below, this rate theory is applied to transitions in three
different systems. First, three spins are considered and HTSTresults compared with direct simulations of the dynamics.Then, the method is applied to a cluster of 139 Fe adatomson a W(110) surface. These first two systems are describedby a Heisenberg-type Hamiltonian. The third example is athree atom Fe cluster on a substrate described by a Alexander-Anderson Hamiltonian for itinerant electrons.
184409-2HARMONIC TRANSITION-STATE THEORY OF THERMAL ... PHYSICAL REVIEW B 85, 184409 (2012)
The Heisenberg-type Hamiltonian can be written in a
general form:
E=−/summationdisplay
nKn/summationdisplay
i(Mi·en)2−1
2J/summationdisplay
/angbracketlefti,j/angbracketrightMi·Mj
−D/summationdisplay
i/negationslash=j3(rij·Mi)(rij·Mj)−r2
ij(Mi·Mj)
r5
ij.(8)
The magnitude of the magnetic moments Miis independent
of angles. The first term represents anisotropy, Jdenotes the
exchange coupling, Dis dipolar coupling constant, and rij
is the vector between sites iandj. Exchange interaction
is only between nearest neighbors (indicated by the angularbrackets).
The HTST rate constant estimate, Eq. (7), was tested by
comparing it with the rate of transitions observed in a directsimulation of the dynamics of a multidimensional systeminvolving three spins which are coupled through the exchangeinteraction. Parameters of the Hamiltonian [Eq. (8)]w e r e
chosen to include easy-axis K
⊥and easy-plane K/bardblanisotropies
which could result from the interaction with a substrate. Asa result, minima and saddle points are formed on the energysurface. Parameter values and temperature were chosen so as tomake the transitions frequent enough to obtain good statisticsin dynamics simulations spanning a long time interval butinfrequent enough for the system to be able to thermalize atthe bath temperature in between transitions. The parameterswereM=2.7μ
B,K⊥M2=5m e V , K/bardblM2=−10 meV, and
JM2=15 meV. Two equivalent minima exist on the energy
surface: at θi=π/2 and φi={π/2,3π/2}. There are two
equivalent saddle points between the minima: at θi=π/2
andφi={0,π}. The activation energy was found to be Es−
Em=15 meV. The dynamics of the spins were calculated
numerically from the Landau-Lifshitz-Gilbert equations wheredissipation and random force terms are included to couplethe spins to a thermal heat bath.
17,18Long simulations were
performed, spanning 10−5s and 109steps at a temperature
of 23 K. This gave satisfactory statistics in the counting oftransitions. The dynamical simulations were carried out forvarious values of the damping constant, α, as shown in Fig. 1.
The agreement with the HTST estimate is good, within a factorof 2, for a wide range in the damping constant. While theparameters and temperature have been chosen here to make itpossible to obtain the transition rate from direct simulation ofthe spin dynamics, the usefulness of the rate theory presentedhere becomes clear when the temperature is lowered, theactivation energy barrier increased, and/or the number of spinsincreased. Then, the direct calculation become difficult, oreven impossible, while the evaluation of the rate expressionremains relatively straightforward.
To demonstrate the methodology presented here on a more
challenging system, we applied it to a larger, rectangular islandof 139 Fe atoms (see Fig. 2). The parameters in Eq. (8)
were chosen to mimic roughly Fe on W(110) substrate:
2,19
dipole-dipole interactions were included as well as anisotropy
in the [1 ¯10] direction (which is perpendicular to the long axis
of the cluster) resulting from the interaction with the sub-strate. The parameter values were KM
2=0.55 meV, JM2=
12.8m e V ,2andD/J=10−3.19Two degenerate states with-3.50-3.48-3.46-3.44
0 10 20 30 40 50
FIG. 2. Minimum energy path (solid line) for a magnetic transi-
tion in a rectangular shaped 139 Fe atom island on W(110) surface.A relaxation starting from a straight line interpolation (dotted line)
representing a uniform rotation of the spins between spin up and spin
down states revealed an intermediate metastable state, as shown bythe insets. The discretization points used in the NEB calculation are
shown with filled circles but the minimum for the metastable state and
a saddle point obtained by subsequent optimization are marked withX.Insets: noncollinear spin configurations at various points along the
path.
spins parallel to the anisotropy axis represent the most stable
states. A NEB calculation starting from a uniform rotationrevealed a more complicated transition mechanism involvinga metastable intermediate state, as shown in Fig. 2.T h e
metastable state can be seen as the emergence of a new domain,
π π
θ2ππθ3
π π
θ2ππθ3
FIG. 3. Minimum energy path for a transition between a parallel
(P) and antiparallel (AP) state of a Fe trimer on a metal substrate
described with the Alexander-Anderson model. Spin configurations
corresponding to locations marked with X on the path are shown witharrows denoting magnitude and direction of the magnetic moments.
The direction of spin 1 is taken to be fixed but the relative angles, θ
2
andθ3, are variable. The energy is given in units of the d-level width,
/Gamma1, due to s-dhybridization. Inset: energy surface showing minima
corresponding to P and AP states, and the calculated minimum energy
path for the transition. Saddle point (SP) is also shown.
184409-3BESSARAB, UZDIN, AND J ´ONSSON PHYSICAL REVIEW B 85, 184409 (2012)
but the cluster is too small for it to form fully. The activation
energy for transitions out of the metastable state is 14 meVand the calculated preexponential, according to Eq. (7),i s
ν=7.4×10
12s−1. The lifetime of the intermediate state can
be estimated as τ(T)=1/kHTST.
Although the Landau-Lifshitz equation was first formulated
in order to describe the precessional motion of classicalmagnetization, it has proven to be an equation of motionalso for quantum systems.
13,20This expands the range of
applicability of the rate theory presented here. We demonstratethis on a triatomic Fe island described within the noncollinearAlexander-Anderson model (see Ref. 21) which captures the
main features of magnetic ordering in 3 dtransition metal
clusters on a metal surface. In particular, several differentmagnetic states close in energy have been found for supportedtrimers of Fe, Cr, and Mn.
21The question is how large an
energy barrier separates these states and how long their lifetimeis at a given temperature. While a triatomic island is too smallto support long-lived metastable states, we use this as anillustration of the methodology because the energy surfacecan be visualized easily.
The implementation of the model within a mean field
approximation and the parameter values used here to representFe trimer are given in Ref. 21. The interaction of d-electrons
with the itinerant s-andp-bands is included, but not spin-orbit
interaction so spin space and the real space are not connected.There is no energy barrier to uniform rotation of magneticmoments and only relative orientation of spins is relevant.
The quantization axis for the system is chosen to be alongthe magnetic moment of one of the trimer atoms, atom 1. Theconfiguration is then specified by only four degrees of freedom.There are two energy minima and both of them correspondto in-plane orientation of the spins. The global minimumrepresents a state with parallel (P) magnetic moments, buta metastable state with antiparallel (AP) moments also exists.Figure 3shows a contour graph of the energy as a function
of two angles θ
2andθ3, while for all atoms we set φi=0.
The minimum energy path between AP and P states turns outto lie in-plane and is also shown in Fig. 3. The activation
energy for leaving the metastable state is E
a=ESP−EAP=
0.007/Gamma1, where /Gamma1is the width of the d-level due to s-d
hybridization.21If/Gamma1=1 eV, the calculated preexponential
isν=2.4×1011s−1. A study of the effect of island size and
shape on such metastable states and the rate of transitionsbetween the states is ongoing and the results will be presentedat a later time.
ACKNOWLEDGMENTS
This work was supported by The Icelandic Research Fund,
Nordic Energy Research, and The University of IcelandScholarship Fund. We thank Professor Pieter Visscher for sev-eral constructive comments on the manuscript and ProfessorBj¨orgvin Hj ¨orvarsson for stimulating discussions.
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184409-4 |
PhysRevB.92.054434.pdf | PHYSICAL REVIEW B 92, 054434 (2015)
Influence of uniaxial anisotropy on domain wall motion driven by spin torque
P. Chureemart,1,*R. F. L. Evans,2I. D’Amico,2and R. W. Chantrell2
1Computational and Experimental Magnetism Group, Department of Physics, Mahasarakham University, Mahasarakham 44150, Thailand
2Department of Physics, University of York, York YO10 5DD, United Kingdom
(Received 19 April 2015; revised manuscript received 15 July 2015; published 25 August 2015)
Magnetization dynamics of a bilayer structure in the presence of a spin-transfer torque is studied using an
atomistic model coupled with a model of spin accumulation. The spin-transfer torque is decomposed into twocomponents: adiabatic and nonadiabatic torques, expressed in terms of the spin accumulation, which is introducedinto the atomistic model as an additional field. The evolution of the magnetization and the spin accumulationare calculated self-consistently. We introduce a spin-polarized current into a material containing a domain wallwhose width is varied by changing the anisotropy constant. It is found that the adiabatic spin torque tends todevelop in the direction of the magnetization whereas the nonadiabatic spin torque arising from the mistrackingof conduction electrons and local magnetization results in out-of-plane magnetization components. However, theadiabatic spin torque significantly dominates the dynamics of the magnetization. The total spin-transfer torqueacting on the magnetization increases with the anisotropy constant due to the increasing magnetization gradient.
DOI: 10.1103/PhysRevB.92.054434 PACS number(s): 75 .78.Fg,75.60.Ch,75.70.Kw,87.15.hj
I. INTRODUCTION
The ability to manipulate the magnetization in a domain
wall (DW) using a spin-polarized current has significant poten-tial for novel spintronic devices and has attracted considerableattention from both experimental and theoretical researcherssince its first introduction by Berger [ 1] and Slonczewski [ 2].
The spin-transfer torque resulting from the exchange in-teraction between the conduction electrons and the localmagnetization is an important phenomenon with potentialapplications as spin-torque oscillators for telecommunicationsapplications, in DW-based magnetic devices such as racetrackmemory [ 3,4], and in the switching of magnetic random access
memory (MRAM) elements [ 5,6]. It provides an exciting
technological advance, coupling fast speed, nonvolatility, andlow power requirements [ 7–9]. The physics of the spin-torque
phenomenon can be described in terms of a spin accumulation,which interacts with the local magnetic moments via aquantum mechanical exchange interaction. The mechanism
of spin-transfer torque in slowly varying magnetization, i.e., a
domain wall, can be theoretically described by consideringthe spin current carried by the conduction electrons intothe magnetic domain wall. The spin-transfer torque arisingfrom the s-dexchange interaction acts on the spin current to
adiabatically align it in the direction of the local magnetization.Simultaneously, a reaction torque proportional to the spincurrent density is created on the local magnetization withinthe DW. For sufficiently high spin current density, thespin injection causes the magnetization reorientation, resultingin the DW motion in the direction of conduction electron flow.
The spin-transfer torque can be decomposed into adiabatic
and nonadiabatic contributions. The former, known as theSlonczewski torque, accounts for the conduction electrons’following the direction of local magnetization whereas thelatter occurs with a rapid change in the magnetization, whichhas been explained by spin mistracking, momentum transfer, orspin-flip scattering [ 10]. In general, the nonadiabatic torque is
*phanwadeec@gmail.comassumed to be much weaker than the adiabatic torque [ 11,12].
The magnitudes of the adiabatic and nonadiabatic torquesstrongly depend on the DW width, which is determinedby the anisotropy constant and exchange interaction of thematerial. The DW width becomes a significant factor for thespin-torque efficiency due to the fact that for a material withhigh anisotropy the resulting strong magnetization gradientwithin the DW subsequently gives rise to a high DW velocity.Therefore, the materials with a large anisotropy, which inturn allow a low current density to initiate DW motion,are promising candidates for the application in spintronicdevices.
Spin torques are generally introduced into micromagnetic
models via adiabatic and nonadiabatic terms proportional,respectively, to coefficients μ
xandβx[11,13–15]. The
magnitudes of both coefficients are generally taken as (un-known) constants (i.e., spatially independent) in the usualformalism and their magnitude is still a matter of discussion.Interestingly, a recent study by Claudio-Gonzalez et al. [11]
has demonstrated that the magnitude of these coefficientsstrongly depends on the spatial variation of the magnetizationgradient giving rise to the nonuniform behavior throughoutthe layer. This results in the divergence of the coefficients atpositions with small gradient of magnetization. To avoid theconsequent nonphysical behavior of the empirical constantsμ
xandβxClaudio-Gonzalez et al. [11] evaluated an effective
nonadiabatic coefficient βdiffproviding the description of
nonadiabatic torque by averaging |∂M/∂x |2with a weight
function. In our recent work [ 16], the spin-torque coefficients
are calculated directly from the spin accumulation. The resultsshow that the dynamic micromagnetic approach based onadiabatic and nonadiabatic terms with constant coefficientsis valid only for systems with slow spatial variations of themagnetization.
In the present work, we calculate the spatial spin-transfer
torque within the DW directly from the spin accumulationbased on our recent work in Ref. [ 16] instead of calculating
from the conventional model [ 11,13–15] through the spin-
torque coefficients, which are unknown. Spin accumulationnaturally includes the effect of both adiabatic and nonadiabatic
1098-0121/2015/92(5)/054434(9) 054434-1 ©2015 American Physical SocietyCHUREEMART, EV ANS, D’AMICO, AND CHANTRELL PHYSICAL REVIEW B 92, 054434 (2015)
torques. This provides the new route of spin-torque calcula-
tion to get insight into the physical description behind themechanism of current-induced domain wall motion and avoidsvarious limitations of the conventional model in estimating theempirical constants, i.e., μ
xandβx. Using this approach we
have investigated the DW motion driven by the spin torqueusing the self-consistent solution of the spin accumulation andmagnetization coupled with atomistic model. We find that theDW displacement and initial DW velocity strongly depend onthe strength of the magnetocrystalline anisotropy and currentdensity, and that the adiabaticity of the spin torque is dependenton the domain wall width.
II. METHODOLOGY
To investigate the domain wall motion driven by injecting
spin-polarized current, the generalized spin accumulationmodel coupled with atomistic model is employed. Semian-alytical solution of spin accumulation is applied to a series oflayers representing the spatial variation of the magnetization ina domain wall to calculate the spin torque at any position of thesystem. Meanwhile, the atomistic model is used to investigatethe dynamics of magnetization caused by spin torque. Thesetwo models are detailed in the following.
A. Spin accumulation model
The spin-transfer torque originating from the spin accu-
mulation can be described via the s-dexchange interaction
model [ 13,16,17]. The s-dmodel has been used to present
a qualitative description of current-induced torque acting onspin moment. The exchange energy due to the interaction of thespin accumulation and the local spin moment is conventionallydescribed by the Hamiltonian given by
H
sd=−Jm·S, (1)
where mdenotes the spin accumulation. Sis the unit vector of
the local spin moment and Jis the exchange coupling strength
between the spin accumulation and the local spin moment. Toinvestigate the spin accumulation in the ferromagnet for anyarbitrary direction of the spin moment, the general solution ofthe spin accumulation based on a transfer matrix approach asdetailed in Ref. [ 16] will be employed.
In the rotated basis system ˆb
1,ˆb2, and ˆb3, the component
of spin accumulation is parallel and perpendicular to the localspin moment. The longitudinal component will be parallel to
ˆb
1and the two components of the transverse spin accumulation
along the directions ˆb2and ˆb3. The general solution of spin
accumulation can then be expressed in the following form
m/bardbl(x)=m/bardbl(0)e−x/λ sdlˆb1
m⊥,2(x)=2e−k1x[ucos(k2x)−vsin(k2x)]ˆb2
m⊥,3(x)=2e−k1x[usin(k2x)+vcos(k2x)]ˆb3, (2)
with ( k1±ik2)=/radicalBig
λ−2
trans±iλ−2
J, where λJ=√2/planckover2pi1D0/J.
Hereλsdlis the spin diffusion length, λtransis the transverse
damping and D0the diffusion constant. m/bardbl(0),u, andvare
constants, which can be obtained by imposing continuity ofthe spin current at the interface. The spin accumulation inthe rotated basis system can be expressed in the Cartesian
coordinate system by using a transformation matrix [ 16].
The effect of the spin torque can be considered as an addi-
tional effective field arising from the s-dexchange interaction
between the local spin moment and the spin accumulation,given by
H
ST=−∂Hsd
∂S=Jm. (3)
B. Atomistic spin model
We model the magnetization dynamics induced by the spin-
transfer torque using an atomistic spin model coupled with thespin accumulation. The energetics of the system are describedusing a classical spin Hamiltonian with the Heisenberg formof the exchange interaction [ 18] written as
H=−/summationdisplay
i/negationslash=jJijSi·Sj−ku/summationdisplay
i(Si·e)2−|μs|/summationdisplay
iSi·Happ,
(4)
where Jijis the nearest-neighbor exchange integral between
spin sites iandj,Siis the local normalized spin moment, Sj
is the normalized spin moment of the neighboring atom at site
j,kuis the uniaxial anisotropy constant, eis the unit vector of
the easy axis, and |μs|is the magnitude of the spin moment.
The parameters of the model are representative of Co witha simplified simple cubic discretization, with an interatomicexchange energy J
ij=11.2×10−21J/link and μs=1.44μB
at 0 K.
The demagnetizing field is calculated at the micromagnetic
level using the macrocell approach [ 18,19]. Each macrocell
contains a predefined number of atomic unit cells and the netmagnetization within the cell is determined by the average ofthe atomic spins in the cell. Macrocell moments ( k,l) then
interact using the dipole-dipole interaction including the self-demagnetizing term [ 18] given by
H
dip,k=μ0
4π/summationdisplay
l/negationslash=k/bracketleftbigg3(μl·ˆrkl)ˆrkl−μl
|rkl|3/bracketrightbigg
−μ0
3μkˆμk
V,(5)
where μl=μs/summationtextnatom
i=1Siis the vector of the magnetic moment
in the macrocell site l, which is found from the summation of
spin moments in the macrocell l,μ0is the permeability of free
space, Vis the volume of the macrocell, rklis the distance and
ˆrklthe corresponding unit vector between macrocell sites k
andl, andnatomis the number of atoms in each macrocell. The
self-interaction term in Eq. ( 5) neglects the configurational
anisotropy of the (cubic) macrocells. We approximate thedipole field as constant over the cell κcontaining spin i.T h e
effective local field acting on spin iis therefore given by
H
eff,i=−1
|μs|∂H
∂Si+Hdip,κ. (6)
The dynamics of the spin system under the action of
the spin-transfer torque can be modeled using the standardLandau-Lifshitz (LL) equation of motion with the inclusion ofan additional spin-torque field ( J
sdm)[13,20,21] as follows:
∂S
∂t=−γS×(Heff+Jsdm)+α
μsS×∂S
∂t. (7)
054434-2INFLUENCE OF UNIAXIAL ANISOTROPY ON DOMAIN . . . PHYSICAL REVIEW B 92, 054434 (2015)
For convenient numerical integration, we cast Eq. ( 7)
into the Landau-Lifshitz-Gilbert (LLG) form, giving the finalequation of motion
∂S
∂t=−γ
(1+λ2)S×(Heff+Jsdm)
−γλ
(1+λ2){S×[S×(Heff+Jsdm)]}, (8)
where γis the absolute gyromagnetic ratio, λ=0.1i st h e
intrinsic Gilbert damping constant applied at the atomic level,Sis the normalized spin moment, and H
effis the effective field
given by Eq. ( 6). The local effective field Heffleads to damped
precessional motion into the direction of the local effectivefield. Interestingly, the additional field due to the presence ofthe injected spin current Jmgives rise to the contribution of
adiabatic and nonadiabatic torques. This term describes thespin-torque effect on the spin motion and indicates that theadditional field due to the spin-transfer torque can be anothersource of precession and damping [ 22,23]. We note that all
simulations are done without thermal fluctuations, that is, atzero K using the
VA M P I R E software package [ 18].
C. Spin-torque calculation
To calculate the adiabatic (AST) and nonadiabatic spin
torques (NAST), let us consider the rotated basis system wherethe local spin moment in the current layer ( S)i sa l o n gt h e
ˆb
1direction whereas that in the previous layer is oriented
in the plane ˆb1ˆb2. The spin moment in the previous layer
can be rotated into the basis coordinate system as illustratedin Fig. 1,S
p=Sp/bardblˆb1+Sp⊥ˆb2, by using the transformation
matrix given by
[Sbasis]=[T]−1[Sglobal], (9)
and the transformation matrix is as follows
[T]=⎡
⎢⎢⎢⎣SxX/prime/prime+SyY/prime/prime
D2D3X/prime/prime
D2
2D3−SxSyY/prime/prime
D1D2D3SzY/prime/prime
D1D3
−SxY/prime/prime+SyX/prime/prime
D2D3Y/prime/prime
D2
2D3−SxSyX/prime/prime
D1D2D3SzX/prime/prime
D1D3
Sz
D1−SxSz
D1D2−Sy
D1⎤
⎥⎥⎥⎦(10)
FIG. 1. (Color online) Schematic representation of the spin-
transfer torque consisting of the adiabatic (AST) and nonadiabatic(NAST) torques in the rotated basis system.with
⎡
⎢⎣X/prime/prime
Y/prime/prime
Z/prime/prime⎤
⎥⎦=⎡
⎢⎢⎢⎣Sp,xD2
1−Sx(SySp,y+SzSp,z)
D1D2
SzSp,y−SySp,z
D1
SxSp,x+SySp,y+SzSp,z
D2⎤
⎥⎥⎥⎦, (11)
where [ S
basis] and [ Sglobal] are the spin moments in the basis
coordinate system and in the global coordinate system respec-tively. S
x,Sy, andSzare the x,y, andzcomponents of spin
moment in the current layer, respectively. D1=/radicalBig
S2y+S2z,
D2=/radicalBig
S2x+S2y+S2z, andD3=√
X/prime/prime2+Y/prime/prime2.
In the basis system as shown in Fig. 1, the adiabatic and
nonadiabatic torques can be determined from the total spintorque τ
STvia the s-dexchange interaction as follows
τST=S×Jsdm
=ˆb1×Jsd(m/bardblˆb1+m⊥,2ˆb2+m⊥,3ˆb3)
=−Jsdm⊥,3ˆb2+Jsdm⊥,2ˆb3. (12)
In general, the AST is the in-plane torque whereas the
NAST is introduced as the fieldlike torque or the out-of-planetorque. Therefore, the spin moments in the rotated basis systemas illustrated in Fig. 1results in the AST and NAST along the
directions of ˆb
2and ˆb3, respectively. As a consequence, the
AST and NAST in the rotated basis system are given by
τAST=−Jsdm⊥,3ˆb2
τNAST=Jsdm⊥,2ˆb3. (13)
The above equation shows that the AST and NAST can
be accessed directly via the spin accumulation. Subsequently,the dynamics of spin motion including the effect of the spin-transfer torque can be investigated by employing Eq. ( 8).
III. CURRENT-INDUCED DOMAIN WALL MOTION
In this work we investigate the dynamics of the magnetiza-
tion in a bilayer system consisting of two ferromagnets (FMs).The current-induced domain wall motion is studied by inject-ing a spin current perpendicular to the plane of the bilayer.In this computational study, the investigation is presented intwo sections. First, the effect of the spin-transfer torque onthe DW dynamics is studied, followed by an investigationof the time evolution of DW displacement and DW velocity.Furthermore, the effect of the current density ( j
e)i sa l s o
studied by injecting currents with different magnitudes. Thisallows the investigation of the critical current density which isthe minimum spin current required to move the domain wall.Second, the effect of the DW width on the time evolution ofthe DW displacement and DW velocity is considered.
A. Time evolution of magnetization and spin torque
The system consists of a bilayer structure with a pinned
layer (PL) providing a spin-polarized current (which is notmodeled explicitly) and a free layer (FL) with dimensionsof 60 nm ×30 nm ×1.5 nm. In order to calculate the spin
accumulation and spin torque the system is discretized intomacrocells 1 .5n m×1.5n m×1.5 nm in size.
054434-3CHUREEMART, EV ANS, D’AMICO, AND CHANTRELL PHYSICAL REVIEW B 92, 054434 (2015)
FIG. 2. (Color online) The the tail-to-tail domain wall contained
in the second ferromagnet of the bilayer system with the uniaxialanisotropy constant of k
u=2.52×106J/m3: The arrows indicate the
direction of magnetization. The magnetization along the ydirection
is represented by the blue coloring. In contrast, the red color showsthe orientation of magnetization in the −ydirection.
The magnetic moment in each macrocell is then calculated
by averaging over the spins within the cell. The pinned layeris not considered explicitly; its role is simply to provide aspin-polarized current through the layer under investigation.A domain wall is forced into the free layer by fixing anantiparallel magnetization configuration at the boundaries ofthe system as illustrated in Fig. 2. The DW profile is transverse
in thexyplane. The studied system is based on a material with
a uniaxial anisotropy constant of k
u=2.52×106J/m3≡
2.7×10−23J/atom with the ydirection as the easy axis and
a lattice constant of a=3.49˚A. The transport parameters
of Co used in spin accumulation calculation are takenfrom Ref. [ 21] as the following values, β=0.5,β
/prime=0.9,
D0=0.001 m2/s,λsdl=60 nm, and λJ=3n m .
We first investigate the effect of the spin-transfer torque
on the domain wall motion by introducing a current densityof 50 MA/cm
2into the bilayer system. The current-induced
domain wall motion can be observed through the componentsof magnetization. Figure 3shows the time evolution of the
magnetization after the application of the current induced bythe spin-torque. In the absence of the spin-transfer torque att=0 ns, the DW is situated centrally and the position of the
DW center is defined by the maximum magnetization of thexcomponent and zero of the ycomponent. In interpreting
the numerical results it is necessary to stress that the DWcan initially move freely but, due to the finite system size,after some time interacts with the strong pinning sites atthe boundaries, which are used to inject the DW into thesystem. The DW initially moves when the spin current isinjected above the critical value. The DW has a translationalmotion to the right, which is the direction of the injectedcurrent and it tends to stop moving at the equilibration timet=0.6 ns with a finite DW displacement, as expected given
its interaction with the boundary pinning sites. Specifically,a small out-of-plane or zcomponent develops during the
propagation time. Its appearance comes from the fact thatthe domain wall interacts with the strong pinning site. Thisis evidence of DW deformation due to interaction with thepinning site. The DW deformation and the occurrence of z
component exhibited in this study are in good agreement withthe recent experimental and theoretical studies [ 24–26].
We next consider the time variation of the spin-transfer
torque via self-consistent solution of the magnetization andspin accumulation, naturally including the adiabatic andnonadiabatic torques, to understand its dependence on the 0 0.01 0.02 0.03
0 5 10 15 20 25 30 35 40Mz
Layer number0.0 ns
0.2 ns
0.4 ns
0.6 ns-1-0.5 0 0.5 1My 0 0.2 0.4 0.6 0.8 1Mx
FIG. 3. (Color online) Schematic representation of the magneti-
zation component with time evolution from 0 ns to the equilibration
time of 0 .6 ns: The current density injected into the bilayer system
containing the DW is 50 MA/cm2.
magnetic structure and its time evolution. The xandy
components give the adiabatic torque, which tends to developtowards the direction of magnetization. On the other hand thezcomponent arises from the contribution of the nonadiabatic
torque, which acts out of the plane. The spin torque actingon the local magnetization due to the spin-polarized currentresults in the translation of the DW. As a consequence, thespatial spin torque at different times as illustrated in Fig. 4
reflects the spatial magnetization configuration of Fig. 3,
which is translated due to the spin torque. It is found thatthe motion ceases after 0.6 ns as the DW contacts with theboundary pinning sites. In addition, in this case the magnitudeof the adiabatic and nonadiabatic torques remain constant withtime and the domain wall width is not significantly affectedas the wall contacts the boundary pinning sites, suggesting thatthe spin current density of 50 MA/cm
2is not high enough to
distort the pinned DW.
B. DW displacement and velocity
We next consider the effect of the current density on the
domain wall motion. This leads to the investigation of thecritical spin current density ( j
e), required to initiate domain
wall motion and also spin-torque driven oscillations of themagnetization of the DW fixed at the strong boundary pinningsites. It is first noted that the calculation in this sectionobserved the domain wall motion in the bilayer system with theanisotropy constant of k
u=2.52×106J/m3giving rise to the
054434-4INFLUENCE OF UNIAXIAL ANISOTROPY ON DOMAIN . . . PHYSICAL REVIEW B 92, 054434 (2015)
-0.01 0 0.01
0 5 10 15 20 25 30 35 40STz [T]
Layer number0.0 ns
0.2 ns
0.4 ns
0.6 ns-0.03-0.02-0.01 0STy [T] -0.02-0.01 0 0.01 0.02STx [T]
FIG. 4. (Color online) The time evolution of the spatial spin-
transfer torque with je=50 MA/cm.2
domain wall width of approximately 6.86 nm. The application
of the spin-polarized current induces a displacement of theDW position with time, as shown in Fig. 5(top panel).
The DW displacement is monitored by observing the shiftof the DW center from the initial position at each time step.It can be seen that the DW displacement is time dependentand increases linearly in the first time period before reaching asteady state with finite displacement due to the interaction withthe boundary pinning sites [ 24,27,28]. The equilibration time
of DW displacement tends to decrease with increasing spincurrent density, consistent with the increased DW velocity.
To describe the behavior of the DW displacement with
different regimes of the current density, it is important toconsider the critical current density, which can be evaluatedthrough the initial DW velocity. The initial velocity iscalculated by determining the rate of change of the DWdisplacement in the first 0.1 ns as the DW shows uniformtranslational motion during that period. The relation betweenthe initial DW velocity as a function of the current density isplotted on a semilogarithmic scale in Fig. 5(bottom panel). It
is found that the critical current density is 0.5 MA/cm
2.T h i s
behavior is also found in the previous studies [ 26,29–33].
On increasing the current density above the critical value,
the domain wall moves uniformly without any precessionalong the direction of the injected spin current. This motioninduced by the spin current is due to the conservation ofthe angular momentum. At high spin current density, thedomain wall motion is accompanied by oscillatory behavior,which tends to be observed with a high current density over100 MA/cm
2. Interestingly, at extremely high values of current 0 4 8 12 16 20
0 0.5 1 1.5 2DW displacement [nm]
Time [ns]0.5 MA/cm2
10 MA/cm2
30 MA/cm2
50 MA/cm2
100 MA/cm2
500 MA/cm2
1000 MA/cm2
0 40 80 120 160 200
0.0001 0.001 0.01 0.1 1 10 100 1000DW velocity [m/s]
je [MA/cm2]je, critical
FIG. 5. (Color online) (Top) The time variation of domain wall
displacement with different current densities. (Bottom) The initial
DW velocity as a function of current density: The critical current den-sity, minimum current density required to move DW is 0 .5 MA/cm
2.
density je=1000 MA/cm2, the DW reaches the boundary
inning sites and the translational motion stops. At this point thedynamic behavior of the DW is becomes oscillatory, exhibitinga stable precessional state around a finite wall displacement[27]. At equilibrium, the DW displacement oscillates at a high
frequency of 300 GHz since the pinned DW essentially actsas a spin-torque oscillator. This also implies the appearanceof an out-of-plane component of magnetization resultingfrom the nonadiabatic torque, consistent with the previousstudies [ 34,35]. Our result with the current density of j
e=
1000 MA/cm2yielding the initial velocity at approximately
200 m/s is in good agreement with the analytical results ofthe one-dimensional (1D) Walker ansatz model in Ref. [ 36]
where the domain displacement at equilibrium is about 18 nm.However, the oscillatory behavior cannot be observed in 1Dmodel because the effect of nonadiabatic spin torque is nottaken into account.
In order to understand the origin of the oscillatory behavior,
the magnetization component at the initial DW center isinvestigated in its time evolution after the introduction ofthe spin-transfer torque. Figure 6clearly shows that the
spin-transfer torque causes the deformation of the DW leadingto precessional motion of the xandzcomponents. This is the
precession of the equilibrium magnetization about the effectivefield determined by the interaction with the pinning site. Thenonadiabatic torque driving the DW in the stable precessionalstate is strong enough to deform the N ´eel wall so as to have
a significant out-of-plane component, which results in theoscillatory behavior. The domain wall motion accompaniedby the precessions due to the nonadiabatic torque has beenconfirmed by recent studies [ 10,25,27,35,37]. Interestingly,
054434-5CHUREEMART, EV ANS, D’AMICO, AND CHANTRELL PHYSICAL REVIEW B 92, 054434 (2015)
0 0.2 0.4 0.6 0.8 1
0 0.05 0.1 0.15 0.2Mx, y, z
Time [ns]MxMyMz
FIG. 6. (Color online) The magnetization component of the ini-
tial DW center with time evolution after injecting the spin current
with the density of 1000 MA/cm2.
the observed oscillatory motion of the domain wall for large
current is similar to the behavior of domain walls at currentsabove the Walker threshold.
IV . CURRENT-INDUCED DW MOTION: EFFECT
OF THE DOMAIN WALL WIDTH
We now turn to the effect of the domain wall width on the
magnetization dynamics. This is investigated by introducinga spin-polarized current into a bilayer system containing adomain wall whose width is varied by changing the anisotropyconstant. The domain wall profile with different anisotropyconstants can be seen in Fig. 7. The magnetization is allowed
to vary continuously throughout, constrained by pinning sitesat the boundaries. The width of the domain wall is variedby increasing the uniaxial anisotropy constant to investigatethe influence of the magnetic anisotropy on the spin-transfer
-1-0.5 0 0.5 1
0 5 10 15 20 25 30 35 40My
Layer NumberKu2Ku4Ku6Ku10Ku 0 0.2 0.4 0.6 0.8 1Mx
FIG. 7. (Color online) The domain wall profile transverse in the
xyplane with various anisotropy constants: The uniaxial anisotropy
constant of cobalt is Ku=4.2×105J/m3. The distance between layer
is given in units of supercells, corresponding to five atomic spacings.torque on the domain wall. The anisotropy constant is varied
from the typical anisotropy value of cobalt ku=4.2×105J/m3
up to 10 times that value. The xandycomponents of
magnetization can be used to characterize the center of DWand the DW width. The zcomponent of the magnetization
is zero according to the usual properties of the N ´eel wall
for the thin sample. A detailed qualitative investigation ofthe current-induced DW motion with the effect of anisotropyconstant will be discussed in the following.
A. DW displacement and velocity
First, a spin current with the density of 50 MA/cm2is
injected into the bilayer system along the xdirection in order
to observe the manipulation of the magnetization within theDW with different anisotropy constants. The magnetizationconfiguration after the introduction of the spin current for 1 nsis illustrated in Fig. 8. It shows that the DW motion is initiated
after injecting the spin current into the system. The centerof the domain wall moves from the initial position along thedirection of the spin current. The system with high anisotropyis easily displaced due to a larger gradient of magnetizationwithin the DW giving rise to a high magnitude of spin torqueacting on it. Interestingly, the DW center position of the systemwith the anisotropy constant of k
uis unchanged. This implies
that the density of spin current injected to the system is below
0 0.01 0.02 0.03
0 5 10 15 20 25 30 35 40Mz
Layer numberKu6Ku8Ku10Ku-1-0.5 0 0.5 1My 0 0.2 0.4 0.6 0.8 1Mx
FIG. 8. (Color online) The component of magnetization in the
second FM with various anisotropy constants after the introductionof the spin current for 1 ns: The center of the DWs are displaced in the
direction of injected spin current. The system with high anisotropy
constant leading to a large gradient of magnetization within domainwall results in a large displacement of the DW.
054434-6INFLUENCE OF UNIAXIAL ANISOTROPY ON DOMAIN . . . PHYSICAL REVIEW B 92, 054434 (2015)
0 5 10 15 20
0 0.5 1 1.5 2 2.5 3DW displacement [nm]
Time [ns]Ku2Ku6Ku8Ku10Ku40Ku80Ku100Ku
0 10 20 30 40
4 6 8 10 12 14 16DW velocity [m/s]
δ [nm]
FIG. 9. (Color online) (top) The time-dependent variation of the
domain wall displacement and (bottom) the initial domain wall
velocity of different uniaxial anisotropy systems with the spin currentdensity of 50 MA/cm
2.
the critical value, which depends on the DW width [ 38–40]. In
addition, the out-of-plane component is likely to be large forhigh anisotropy.
Furthermore, it is also worthwhile to observe the dynamic
behavior of the DW motion via the DW displacement andthe initial DW velocity. As illustrated in Fig. 9(top panel),
the DW displacement is not noticeable for a very wide wall,specifically for uniaxial anisotropy constants of k
uand 2ku.
The DW exhibits transient oscillatory behavior back to itinitial position. Hence, higher spin current density is neededin order to initiate the translation of DW for these cases. Onthe other hand, displacement of the narrow DW tends to bemore easily initiated than the wide DW. This is because ofthe strong interaction between the spin current and the localmagnetization gradient within the DW giving rise to a largespin-transfer torque. For a low anisotropy, the linear responseof the DW displacement occurs in the first 0 .1 ns and then
reaches the equilibrium state after reaching the boundarypinning sites. For a high anisotropy, the DW displacementdeviates from linear behavior and the precessional motion isenhanced for several cycles in the first ns before reaching theequilibrium state. The deviation from the linear behavior inthe first period becomes stronger for higher anisotropy. In thecase of this spin current density, the stable precessional stateis not established as the current density is not high enough topush the DW against the boundary pinning sites.
Finally, we consider the initial DW velocity as a function
of the DW width. Clearly the initial DW velocity dependssensitively on the DW width as can be seen in Fig. 9(bottom
panel). The initial DW velocity decreases with increasing DWwidth as a result of the decreasing magnetization gradient. Thesimilar result has been shown in Ref. [ 41]. This relation can
be used to evaluate the critical DW width for each spin currentdensity. The current density of 50 MA/cm
2is able to move a
DW along the direction of the injected spin current in case ofthe DW width less than 11 .2n m .
B. Spin-transfer torque
We now consider the spin-transfer torque consisting of
adiabatic (AST) and nonadiabatic (NAST) components. Asmentioned before, the total spin-transfer torque is mainlycontributed by the AST resulting from the spin accumulationcomponent following the direction of the local magnetizationwhereas the out-of-plane torque comes from the NAST arisingfrom the electron mistracking. The strength of the spin-transfertorque on the DW can be represented by considering themaximum value occurring at any position over the DWregion given that its contribution is nonuniform throughoutthe DW. In addition, the degree of nonadiabatic torque orthe so-called nonadiabaticity ( D
NAST), which characterizes the
relative influence of the NAST on the DW compared with theAST, is also evaluated by the following equation,
D
NAST=|NAST max|
|AST max|. (14)
|NAST max|and|AST max|are the maximum value of adiabatic
and nonadiabatic torques within DW.
Clearly, as shown in Fig. 10, both adiabatic and nonadia-
batic torques tend to be more effective in narrow domain wallsdue to the large gradient of the magnetization. It can also beseen that the nonadiabaticity factor becomes more significantfor a small DW width. This is schematically shown in Fig. 10.
In contrast, the pure adiabatic torque is likely to dominate thetotal torque, with negligible nonadiabatic torque, for a largeDW width. This is consistent with previous studies [ 14,41,42].
The results also indicate that the nonadiabatic torque, whichis represented by the value of βused in the micromagnetic
approach is directly dependent on the DW width. In the case
0 0.005 0.01 0.015 0.02 0.025 0.03 0.035
0 0.05 0.1 0.15 0.2 0.25 0.3 0.2 0.25 0.3 0.35 0.4 0.45Magnitude of ST(T)
DNAST
δ/λsdl|ASTmax|
|NASTmax|
DNAS T
FIG. 10. (Color online) The thickness dependence of a maximum
of adiabatic spin torque (AST), nonadiabatic spin torque (NAST) and
the degree of nonadiabaticity ( DNAST): The spin diffusion length ( λsdl)
is 60 nm.
054434-7CHUREEMART, EV ANS, D’AMICO, AND CHANTRELL PHYSICAL REVIEW B 92, 054434 (2015)
ofδ/lessmuchλsdl, the nonadiabatic torque becomes significant to the
system.
V . CONCLUSION
In this work we have applied the modified formalism of
spin accumulation with an atomistic spin model to studythe dynamics of a DW in the presence of a spin-transfertorque. The model uses a transfer matrix approach to determinedirectly the equilibrium spin accumulation avoiding the needfor computationally expensive time stepping of the equationof motion. Domain wall dynamics under the influence of aspin-polarized current are studied by self-consistent calcula-tions of the spin accumulation and magnetization. The spinaccumulation is calculated in a rotated basis, which givesaccess to both the adiabatic and nonadiabatic contributions tothe spin torque, which arise naturally in the model. The total
spin torque contributed by adiabatic and nonadiabatic torques
at any position within the DW is considered. The resultsindicate that both torques are inversely proportional to domainwall width. Furthermore, it is found that the adiabatic torquedominates the total spin torque; meanwhile the nonadiabatictorque controls the out-of-plane component of spin torque. Thedependence of spin torque on the DW width is consistent withthe proportionality of the spin torque to the gradient of the
magnetization. However, it is important to note that the self-consistent solution of spin accumulation and magnetizationleads to a further contribution to the effect of the DW width.Specifically, we show that the adiabatic and nonadiabaticcomponents of the spin torque reduce with increasing DWwidth relative to the spin diffusion length, which becomes animportant characteristic length in the calculation of the spintorque. Both components decrease at different rates, with theresult that the nonadiabaticity factor, indicative of the relativestrength of the nonadiabatic torque, tends to decay to zero asthe DW width increases. Our results show that materials withhigh anisotropy such as FePt giving rise to narrow domainwall are more effective for data storage application involvingDW propagation, such as racetrack memories [ 43], due to the
enhancement of high spin-transfer torque. We also concludethat the spin torque is strongly dependent on the spin diffusionlength, which is an important factor in materials design.
ACKNOWLEDGMENT
P.C. would like to acknowledge financial support from
Mahasarakham University, Thailand.
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054434-9 |
PhysRevB.97.134421.pdf | PHYSICAL REVIEW B 97, 134421 (2018)
Thickness-dependent enhancement of damping in Co 2FeAl/β-Ta thin films
Serkan Akansel,1Ankit Kumar,1,*Nilamani Behera,1Sajid Husain,2Rimantas Brucas,1
Sujeet Chaudhary,2and Peter Svedlindh1
1Department of Engineering Sciences, Uppsala University, Box 534, SE-751 21 Uppsala, Sweden
2Thin Film Laboratory, Department of Physics, Indian Institute of Technology Delhi, New Delhi 110016, India
(Received 5 March 2018; revised manuscript received 6 April 2018; published 23 April 2018)
In the present work Co 2FeAl (CFA) thin films were deposited by ion beam sputtering on Si (100) substrates at
the optimized deposition temperature of 300 °C. A series of CFA films with different thicknesses ( tCFA), 8, 10, 12,
14, 16, 18, and 20 nm, were prepared and all samples were capped with a 5-nm-thick β-Ta layer. The thickness-
dependent static and dynamic properties of the films were studied by SQUID magnetometry, in-plane as wellas out-of-plane broadband vector network analyzer–ferromagnetic resonance (FMR) measurements, and angle-dependent cavity FMR measurements. The saturation magnetization and the coercive field were found to be weaklythickness dependent and lie in the range 900–950 kA /m and 0.53–0.87 kA /m, respectively. The effective damping
parameter ( α
eff) extracted from in-plane and out-of-plane FMR results reveals a1
tCFAdependence, the values for
the in-plane αeffbeing larger due to two-magnon scattering (TMS). The origin of the αeffthickness dependence
is spin pumping into the nonmagnetic β-Ta layer and in the case of the in-plane αeff, also a thickness-dependent
TMS contribution. From the out-of-plane FMR results, it was possible to disentangle the different contributionstoα
effand to the extract values for the intrinsic Gilbert damping ( αG) and the effective spin-mixing conductance
(g↑↓
eff)o ft h eC F A / β-Ta interface, yielding αG=(1.1±0.2)×10−3andg↑↓
eff=(2.90±0.10)×1019m−2.
DOI: 10.1103/PhysRevB.97.134421
I. INTRODUCTION
Half-metallic ferromagnetic materials having a small
Gilbert damping parameter ( α), which describes the relaxation
of the magnetization, are of immense interest for spin transfertorque devices since a low αvalue results in a low value for
the critical current density required to switch the magneti-zation [ 1,2]. Co-based Heusler alloys, e.g., Co
2FeAl (CFA),
have unique properties such as half-metallicity [ 3–5], large
magnetization, and high Curie temperature ( Tc=1000 K) [ 5].
Their use as electrode material in magnetic tunnel junctions,due to giant tunneling magnetoresistance (360%) at roomtemperature, has been reported [ 6,7].
Full Heusler alloys, X
2YZ, can exhibit three different
crystallographic phases—the fully ordered L21phase, the
partially ordered B2 phase, and the fully disordered A2 phase.
In the L21phase, the different types of atoms occupy their
assigned sites, while in the partially ordered phase the YandZ
atoms randomly share sites. For the A2 phase, all available sites
are occupied at random [ 8]. Unfortunately, crystallographic
disorder reduces half-metallicity and increases the value of theGilbert damping parameter. There exist a number of studieswhere postannealing has been utilized in order to obtain lowerdamping parameters. Damping parameters in the range from0.001 to 0.004 have been obtained by postannealing of CFAfilms deposited on MgO substrates [ 8–14].
In the case of CFA films deposited on Si substrates [ 8,15,16]
comparably few studies have been reported and the B2 phase is
rarely achieved [ 15]. However, using ion beam sputtering and
*ankit.kumar@angstrom.uu.seoptimizing the growth temperature, it has recently been shown
that the B2 phase can be obtained without any postannealing
process [ 17]. Besides obtaining the B2 phase, a record low
value for the damping parameter for CFA films deposited onSi was reported.
The objective of this work is to investigate the thickness
dependence of the magnetic relaxation for B2 phase Si/CFA/Ta
thin films. Spin transfer torque devices typically require ul-trathin magnetic electrode layers. One problem for devicesis that decreasing the thickness of the magnetic layer oftenresults in a concomitant increase of the magnetic dampingparameter due to effects such as surface anisotropy [ 18]. The
explanation for the increase of damping can be linked to theexcitation of both uniform and nonuniform precession modesof the magnetization and, if a nonmagnetic layer with largespin-orbit coupling is used together with the magnetic layer,spin pumping into the nonmagnetic layer also contributes[19,20]. Uniform modes give rise to intrinsic or Gilbert type
of relaxation, while nonuniform modes are known as extrinsicmodes which can be caused by magnetic inhomogeneity orsurface anisotropy fields. The nonuniform precession of themagnetic moments results in two-magnon scattering (TMS),where magnons are created. The TMS increases the linewidthof the ferromagnetic resonance (FMR) absorption as wellas the effective damping parameter of the material [ 21,22].
The influence of surface/interface anisotropy is expected toincrease by decreasing film thickness [ 23]. However, in out-
of-plane FMR measurements, TMS is avoided and hencethe effective damping parameter has a contribution from theintrinsic relaxation and can in addition exhibit a thickness-dependent spin-pumping contribution. The latter enhancementof the damping parameter has from theory been shown to
2469-9950/2018/97(13)/134421(8) 134421-1 ©2018 American Physical SocietySERKAN AKANSEL et al. PHYSICAL REVIEW B 97, 134421 (2018)
be large for a ferromagnetic layer in direct contact with a
nonmagnetic metal layer with large spin-orbit coupling (largespin-flip probability) [ 19,20]. Enhancement is thus expected
for heavier elements with panddelectrons in the conduction
band, while the enhancement will be absent for lighter elementsas well as for heavier elements with only selectrons in the
conduction band.
In this study CFA thin films capped with a high spin-orbit
coupling 4 dβ-Ta layer have been investigated in terms of
dynamic magnetization properties using both in-plane andout-of-plane FMR techniques to be able to distinguish betweenintrinsic and extrinsic contributions to the magnetic relaxation.Besides broadband FMR studies, angle-resolved cavity FMRmeasurements have also been utilized. The intrinsic dampingparameter and the enhancement of damping due to TMSand spin pumping can be disentangled by angle-resolved andbroadband FMR measurements, which is quite enlightening interms of understanding the fundamental dynamical propertiesof these promising materials for future spintronic applications.
II. SAMPLES AND METHODS
CFA thin films were deposited on Si(100)/SiO 2sub-
strates by utilizing an ion beam sputtering deposition sys-tem (Nordiko-3450). Prior to deposition substrates were heattreated in situ at 620 °C for 2 h to remove surface contamina-
tions. A base pressure of about 7 ×10
−7Torr was achieved
by using cryo and turbo pumps. The Ar gas pressure wasmaintained at 2 .4×10
−4Torr and the rf ion source was
operated at 75 W during deposition. The film depositiontechnique is explained in detail in our previous work [ 17].
Films were grown at 300 °C. A series of films was preparedwith the stacking Si/CFA( t
CFA)/Ta(5 nm). Nominal tCFAvalues
were 8, 10, 12, 14, 16, 18, and 20 nm. All films were coveredwith a 5-nm-thick capping layer of β-Ta. The β-Ta layers were
grown at room temperature and their quality was ascertainedby x-ray diffraction and resistivity measurements [ 23].
Film thickness and surface/interface roughnes were ob-
tained by x-ray reflectivity (XRR) measurements. The scanscovered the 2 θrange 0°–4°, and the XRR results were ana-
lyzed using the
PANALYTICAL X ’PERT REFLECTIVITY software
package (ver. 1.2 with segmented fit). Layer thicknesses,densities, and surface/interface roughness were obtained fromthis analysis.
Magnetic hysteresis loop measurements were performed
using a Magnetic Property Measurement System (MPMS,Quantum Design).
Dynamic magnetic properties were investigated both by
fixed frequency cavity and broadband ferromagnetic resonancemeasurements. In the X-band cavity FMR measurements the
frequency was kept constant at 9.8 GHz and an in-planemagnetic field was scanned during the measurement. The setupwas equipped with a goniometer making it possible to performangular-dependent in-plane as well as out-of-plane FMR mea-surements, providing information about in-plane anisotropyfields, and two-magnon scattering (TMS) contribution to therelaxation of the magnetization.
Besides cavity FMR measurements, the samples were inves-
tigated by broadband FMR measurements. In-plane broadbandFMR measurements were performed using a transmissiongeometry coplanar waveguide (CPW) where a lock-in am-
plifier detection technique was used. A pair of homemadeHelmholtz coils generating a low-frequency, low-amplitudemagnetic field (211.5 Hz and 0.25 mT magnetic field ampli-tude) was used to modulate the rf signal which was detectedby the lock-in amplifier. As in cavity FMR, each measurementwas performed varying the dc magnetic field while keeping themicrowave frequency constant. FMR spectra were recorded inthe frequency range from 5 to 20 GHz in steps of 1 GHz.
A setup enabling out-of-plane FMR measurements was also
utilized. Recording the FMR signal by applying the field outof plane with respect to the sample surface provides a TMS-free FMR signal. For out-of-plane measurements a broadbandvector network analyzer (VNA) was utilized. Two ports of theVNA were connected to a coplanar waveguide mounted in theair gap of an electromagnet.
III. RESULTS AND DISCUSSION
XRR measurements were performed to accurately de-
termine thickness and roughness of the different layers inthe Si/CFA( t
CFA)/Ta samples. Figure 1shows XRR spectra
(symbols) together with simulated spectra (solid lines) forsamples with different nominal CFA thickness. A three-layermodel CFA/Ta/Ta
2O5was used in the simulations, since
previous studies using x-ray photoelectron spectroscopy [ 17]
and transmission electron microscopy [ 24] have shown that
the top part of the Ta layer becomes oxidized, yielding Taand Ta
2O5layers with thicknesses of about 2.5 and 2.2 nm,
respectively. The results of the simulations are summarizedin Table I. The results of the simulations show that the CFA
thickness matches quite well with the nominal thickness andthat differences in interface roughness between samples aresmall.
Figure 2shows in-plane magnetization versus field curves
for samples with different CFA thickness; for sake of clarityresults are only shown for three samples. All samples exhibitrectangular hysteresis curves with small coercivity values; thecoercivity was found to be weakly CFA thickness dependent
FIG. 1. X-ray reflectivity spectra recorded for Si/CFA( tCFA)/
Ta/Ta 2O5thin films. Symbols correspond to experimental spectra and
solid lines represent simulated curves.
134421-2THICKNESS-DEPENDENT ENHANCEMENT OF DAMPING IN … PHYSICAL REVIEW B 97, 134421 (2018)
TABLE I. Thickness and roughness values ( σ) of the different layers in CFA/Ta/Ta 2O5films extracted from the simulation of the experimental
XRR data.
tCFA(nm) σ(nm)±0.06 tCFA(nm)±0.03 σ(nm)±0.06 tTa(nm)±0.03 σ(nm)±0.03 tTa2O5(nm)±0.06 σ(nm)±0.03
8 0.21 8.54 0.34 2.37 0.20 2.26 0.28
10 0.35 10.88 0.60 2.62 0.19 2.42 0.34
12 0.38 12.20 0.55 2.59 0.37 2.16 0.50
14 0.28 14.32 0.46 2.42 0.47 2.15 0.4116 0.20 16.03 0.55 2.50 0.45 2.19 0.31
20 0.22 20.22 0.43 2.45 0.31 2.25 0.13
and varied in the range 0.53–0.87 kA /m (0.65–1.10 mT). The
inset shows the magnetization curve for one sample ( tCFA=
20 nm) applying the magnetic field out of plane with respectto the film surface; all samples exhibit similar out-of-planemagnetization curves. The saturation magnetization is best de-termined from the saturation field; the saturation magnetizationdetermined in this way indicates a weakly CFA thickness-dependent value for the saturation magnetization ( μ
0Ms) with
values of about 1.10 T. These values are in good agreementwith previously determined values for CFA films deposited byion beam sputtering on Si substrates. The thickness-dependentsaturation magnetization clearly demonstrates the absence ofinterfacial dead layers in these samples.
The in-plane angle-dependent cavity FMR data were ana-
lyzed using the following equation [ 25]:
f=γμ
0
2π([Hrcos(φH−φM)+Hccos 4(φM−φC)
+Hucos 2(φM−φu)]{Hrcos(φH−φM)+Meff
+Hc
4[3+cos 4(φM−φC)]+Hucos2(φM−φu)})1/2,
(1)
FIG. 2. In-plane magnetization normalized with the saturation
magnetization versus field for CFA films with different thickness.
The inset shows the normalized out-of-plane magnetization versusfield for the CFA film with 20 nm thickness.where Hris the resonance field, fis the cavity microwave
frequency, and γ=gμB
¯his the gyromagnetic ratio. Here,
gis the Landé spectroscopic splitting factor, μBthe Bohr
magneton, and ¯ his the reduced Planck´s constant. With respect
to the [100] direction of the Si substrate, in-plane directionsof the magnetic field, magnetization, uniaxial, and cubicanisotropies are given by φ
H,φM,φuandφC, respectively.
Hu=2Ku
μ0MsandHc=2Kc
μ0Mscorrespond to the uniaxial and
cubic anisotropy fields, respectively, with KuandKcbeing the
uniaxial and cubic magnetic anisotropy constants, respectively.M
eff=Ms−H⊥
kis the effective magnetization, where H⊥
kis
the perpendicular anisotropy field of the film. Here Meff,Hc,
andHuare used as fitting parameters. Figure 3shows Hrversus
φHextracted from the angular-dependent FMR measurements
together with fits according to Eq. ( 1), clearly revealing a dom-
inant twofold uniaxial in-plane magnetic anisotropy. Usingg=2.10, a value which is in accord with values extracted from
broadband FMR measurements, μ
0Meffshows small variation
between samples taking values in the range 1.00–1.02 T. Theresults for the effective magnetization are close to the valuesextracted for the saturation magnetization (cf. inset in Fig. 2),
showing that the perpendicular anisotropy field is negligiblysmall for the samples studied here. The uniaxial anisotropyfieldμ
0Huexhibits a decreasing trend with increasing CFA
thickness, with values in the range 2.20–3.90 mT, while thecubic anisotropy field values are less than one-tenth of theuniaxial anisotropy field values.
FIG. 3. Resonance field μ0Hrversus magnetic field rotation
angle φHobtained from cavity FMR measurements. Symbols are
experimental data points and lines are fits to Eq. ( 1).
134421-3SERKAN AKANSEL et al. PHYSICAL REVIEW B 97, 134421 (2018)
The recorded FMR spectra linewidth have the following
different contributions:
μ0/Delta1H=μ0/Delta1Hinh+μ0/Delta1HG+sp+μ0/Delta1Hmosaic
+μ0/Delta1HTMS. (2)
In the following we will discuss all four contributions in the
linewidth. μ0/Delta1Hinhis the frequency-independent sample in-
homogeneity contribution, while μ0/Delta1HG+sp=4πα efff/γ/Phi1
is the Gilbert and spin-pumping damping contribution. Here,α
effand/Phi1are the effecive damping constant and a correc-
tion factor due to the field dragging effect. For the in-planeconfiguration /Phi1=cos(φ
M−φH) and for the out-of-plane,
/Phi1=cos(θM−θH), where φHis the magnetic field azimuthal
angle with respect to the in-plane crystallographic [100]direction, and θ
His the polar angle of the magnetic field.
φM(θM) is the azimuthal (polar) angle of sample magnetization.
This field dragging term enhances damping, but vanishesalong the easy and hard axes (its presence in our studiedsamples is minute and will not be discussed further). The thirdtermμ
0/Delta1Hmosaic=∂Hr
∂φH/Delta1φH+∂Hr
∂θH/Delta1θHis due to sample
mosaicity [ 14,26]. This contribution to the linewidth originates
from variation of crystallite orientations in the films, and fromthickness variations. These microscopic variations result inspatial variations of the anisotropy fields and consequentlyslight variations in the resonance field for different regions.
This contribution is present in our studied samples. The lasttermμ
0/Delta1HTMSis the two-magnon scattering (TMS) contri-
bution. The TMS is a process where the q=0 magnon scatters
into a degenerate magnon with wave vector /vectorq/negationslash=0. Arias
and Mills have formulated a theoretical model where latticegeometrical defects induce magnetic inhomogeneity and yieldtwo-magnon scattering [ 27]. Later Woltersdorf and Heinrich
formulated a model including both isotropic and anisotropicangle-dependent TMS contributions to the linewidth [ 28]. For
the in-plane configuration, which is discussed here, the TMSdepends on the in-plane direction of the applied magnetic fieldrelative to the principal in-plane crystallographic direction ofthe film. Angle-dependent TMS contributions appear when thescattering centers are anisotropic, e.g. self-assembled networksof misfit dislocations result in a fourfold angular dependencedue to effective channeling of scattered spin waves. Moreover,rectangular surface defects cause a (cos 2 φ
H)2angular depen-
dence. A slightly different symmetry of surface defects resultsin a/vectorqwave-vector-dependent (cos 2 ϕ)
4angular dependence,
where ϕ=φM+ψ;ψis the angle between the magnetization
vector and /vectorq. Therefore, combining the Arias and Mills,
and Woltersdorf and Heinrich models of TMS, the angular
dependence of TMS can be expressed as
μ0/Delta1HTMS∝/Gamma1
/Phi1sin−1/radicaltp/radicalvertex/radicalvertex/radicalbt/parenleftbigg/radicalBigg
ω2+/parenleftbiggω0
2/parenrightbigg2
−ω0
2/parenrightbigg/slashbigg/parenleftbigg/radicalBigg
ω2+/parenleftbiggω0
2/parenrightbigg2
+ω0
2/parenrightbigg/integraldisplay
w(ψ)(cos 2 φH)2(cos 2ϕ)4dψ, (3)
where /Gamma1is the intensity of the TMS, w(ψ) is a weighting
parameter along the path of the TMS scattering lobes /vectorq(ψ),
ω0=γμ 0Meff, andωis angular frequency.
The angle-dependent linewidth obtained from cavity FMR
measurements was fitted using Eqs. ( 2) and ( 3) to extract the
thickness-dependent TMS linewidth contribution, shown inFig. 4. Since broadband in-plane FMR results do not indicate
any field dragging effect, implying φ
M=φH, both /Delta1Hinh
and/Delta1HG+spcorrespond to isotropic contributions to the
linewidth and the exact value of both cannot be extracted fromthis analysis. However, the weighting-factor-dependent TMSintensity /Gamma1can be extracted from the fitting. /Gamma1increases from
2.6 to 4.5 mT, decreasing the CFA thickness from 20 to 8 nm,clearly indicating the presence of a thickness-dependent TMSlinewidth contribution in our studied samples.
In-plane broadband FMR measurements were performed
with the magnetic field applied along the easy axis of the films.Recorded FMR spectra were fitted to the expression [ 29]
dA
dH∝2(H−Hr)/Delta1H
2/bracketleftBig/parenleftbig/Delta1H
2/parenrightbig2+(H−Hr)2/bracketrightBig2−/bracketleftbig/parenleftbig/Delta1H
2/parenrightbig2−(H−Hr)2/bracketrightbig
/bracketleftbig/parenleftbig/Delta1H
2/parenrightbig2+(H−Hr)2/bracketrightbig2,
(4)
wheredA
dHis the magnetic field derivative of the microwave
absorption signal. The full width at half maximum linewidth/Delta1H and resonance field H
rwere used as fitting parameters.
Figure 5shows FMR spectra at different frequencies forthetCFA=16 nm sample and Fig. 6(a) shows /Delta1H versus
frequency for CFA samples with different thickness (leaving
out results for two samples for the sake of clarity). The insetin Fig. 5shows H
rversus frequency for the tCFA=16 nm
sample together with a fit of the experimental data to Eq. ( 1);
the results for other samples are very similar and plotting more
FIG. 4. Linewidth μ0/Delta1H versus magnetic field rotation angle φH
obtained from cavity FMR measurements. Symbols are experimental
data points and lines are fits to Eqs. ( 2)a n d( 3). The extracted TMS
contributions to the linewidth are 2.6, 3.8, and 4.5 mT for the 20-,14-, and 8-nm-thick CFA samples, respectively.
134421-4THICKNESS-DEPENDENT ENHANCEMENT OF DAMPING IN … PHYSICAL REVIEW B 97, 134421 (2018)
FIG. 5. In-plane FMR spectra for the 16-nm-thick CFA film.
Symbols are experimental data and solid lines are fits to Eq. ( 4). The
inset shows frequency versus resonance field for the same sample.
Symbols are experimental data and the solid line is a fit to Eq. ( 1).
than one curve in the graph it is very difficult to distinguish
one curve from the other by eye. Using gas a free parameter,
one obtains g=2.10, while μ0Mefftakes values in the range
1.00–1.05 T. The /Delta1H versus frequency data were fitted to the
expression [ 29]
μ0/Delta1H=4πα eff
γf+μ0/Delta1H 0, (5)
where αeffis the effective damping parameter, which for
the in-plane configuration, in addition to the intrinsic Gilbertdamping, contains both a TMS contribution and a con-tribution due to spin pumping into the Ta layer, and/Delta1H
0(=/Delta1Hinh+/Delta1Hmosaic) is a sum of the frequency-
independent inhomogeneity and mosaicity contributions tothe linewidth. Extracted α
effvalues versus CFA thickness are
shown in Fig. 6(b). The extracted values of αeffincrease with
decreasing CFA layer thickness, indicating a1
tCFAdependence.
The extracted μ0/Delta1H0values vary in the range 1.2–2.5 mT,
being smaller for tCFA<12 nm (1.2–1.6 mT).Broadband out-of-plane FMR measurements were per-
formed in the frequency range from 5 to 17 GHz. During thesemeasurements the VNA was utilized to record the frequencyand magnetic field dependence of the complex transmissionparameter S
21of the microwave signal. Typical results for the
real and imaginary parts of S21for the tCFA=20 nm sample
are given in Fig. 7. Recorded S21spectra were fitted to the
following set of equations [ 30]:
S21(H,t)=S0
21+Dt+χ(H)
˜χ0,
χ(H)=Meff(H−Meff)
(H−Meff)2−H2
eff−i/Delta1H (H−Meff).(6)
In these equations S0
21is the nonmagnetic contribution to
S21,χ(H) is the complex susceptibility of the magnetic film,
and ˜χ0is an imaginary function of the frequency and film
thickness. The term Dtaccounts for a linear drift of the
recorded S21signal and Heff=2πf/γ μ 0.
Meffand the Landé gfactor can be extracted by fitting the
Hrversus frequency results to the expression
μ0Hr=2πf
γ+μ0Meff. (7)
Typical results are shown in Fig. 8(a) for the tCFA=8- and
20-nm samples. Following the method outlined in Ref. [ 30],
μ0Meffandgincrease slightly and take values in the range
1.15–1.20 T and 2.07–2.13, respectively. Figure 8(b) shows
/Delta1H versus fextracted from out-of-plane FMR results, again
indicating an increase of αeffwith decreasing thickness of
the CFA layer. The damping parameter extracted in thisway includes the intrinsic Gilbert contribution ( α
G) and the
contribution due to spin pumping ( αsp);αeff=αG+αsp.H e r e
we have ignored the radiative and eddy current contributions tothe damping, which are expected to give a contribution /lessorsimilar3×
10
−4. The theoretical framework describing the relaxation
of injected spins in the nonmagnetic layers, including thebackflow of spin angular momentum from the nonmagneticlayers into the magnetic layer, was presented in Refs. [ 19,20].
The theory as derived is restricted to metals with a ratioof the spin-conserved to spin-flip scattering times (the spin-flip probability) /epsilon1=τ
el/τSF=(λel/λSD)2/3/greaterorsimilar10−3, where
λelandλSDare the mean free path and spin-diffusion length,
FIG. 6. (a) μ0/Delta1Hversus f(a) from in-plane FMR measurements for samples with different CFA thickness. Symbols correspond to
experimental data and lines are fits to Eq. ( 5). (b)αeffversus tCFA.
134421-5SERKAN AKANSEL et al. PHYSICAL REVIEW B 97, 134421 (2018)
FIG. 7. Out-of-plane FMR spectra for 8- and 20-nm-thick CFA films showing (a) real and (b) imaginary parts of S21. Symbols are
experimental data and lines are fits to Eq. ( 6).
respectively. For a nonmagnetic metal to be an efficient spin
sink, the requirement is /epsilon1/greaterorsimilar10−2[20]. Using values for
λelandλSDderived for ferromagnetic/ β-Ta bilayers ( λel=
0.5 nm and λSD=2.5n m ) [ 31], the value for the spin-flip
probability becomes /epsilon1=1.3×10−2indicating that the model
is applicable to ferromagnetic/ β-Ta bilayers and that β-Ta
acts as an efficient spin sink. In the simplest case, with onlyone interface, the extra contribution to the damping can beexpressed as
α
sp=gμBg↑↓
eff
4πMs1
tCFA, (8)
where g↑↓
effis the real part of interfacial mixing conductance
g↑↓in series with the nomal-metal resistance. For the samples
discussed here there are two interfaces, one between the CFAand Ta layers and one between the Ta and Ta
2O5layers.
This implies that g↑↓
effwill be a function of the conduc-
tance at both interfaces, since spin relaxation is expectedboth in the Ta and Ta
2O5layers. Figure 9(a) shows αeff
extracted from out-of-plane FMR measurements versus1
tCFAtogether with a fit of the experimental data to Eq. ( 8). UsingMs=915 kA /m(μ0Ms=1.15 T) and g=2.10, one obtains
g↑↓
eff=(2.90±0.1)×1019m−2, which is comparable to the
value obtained for a Pd/CoFe/Pd multilayer structure [ 32].
Using this value for the effective mixing conductance, it isnow possible to disentangle the two contributions to α
eff;
Fig. 9(b) shows αefftogether with αspandαGversus CFA
layer thickness. The extracted value for the intrinsic Gilbertisα
G=1.1±0.2×10−3, which is in good agreement with
previously determined values [ 17]. Moreover, assuming that
the spin current is reflected at the β-Ta/Ta2O5interface and
using the relation between the intrinsic and effective spin-
mixing conductance g↑↓
eff=g↑↓(1−e−2tTa/λSD), where tTais the
thickness of the β-Ta layer and the exponential term within the
brackets accounts for the backflow of spin angular momentum,one obtains g
↑↓≈3.35×1019m−2for the intrinsic spin-
mixing conductance.
The low Gilbert damping ( /lessorequalslant1×10−3) and high spin-
mixing conductance ( /greaterorequalslant1×1019m−2) observed for the
CFA/β-Ta bilayer system are key requirements for spin transfer
torque magnetization switching and spin logic devices. How-ever, efficient switching of magnetic memory and spin logicdevices also requires a large interface transparency ( T). The
FIG. 8. fversus Hr(a) and μ0/Delta1Hversus f(b) from out-of-plane FMR measurements for samples with different CFA thickness. Symbols
correspond to experimental data and lines are fits to Eqs. ( 7)a n d( 5). Since error in Hris negligible, no error bars are shown in (a).
134421-6THICKNESS-DEPENDENT ENHANCEMENT OF DAMPING IN … PHYSICAL REVIEW B 97, 134421 (2018)
FIG. 9. (a) αeffversus1
tCFAusing data extracted from out-of-plane FMR measurements. Squares correspond to the experimental data and
solid line fit to Eq. ( 8). (b)αeff, spin-pumping contribution αspto damping and intrinsic Gilbert damping αGversus tCFA.
interface transparency in the CFA/ β-Ta bilayer system controls
the flow of spin angular momentum across the interface anddepends on the microscopic intrinsic and extrinsic interfacialfactors, such as band structure mismatch, Fermi velocity, andinterface imperfections, and can be expressed as [ 33]
T=g
↑↓
efftanh/parenleftbigtCFA
2λSD/parenrightbig
g↑↓
effcoth/parenleftbigtTa
λSD/parenrightbig
+σTah
λSD2e2, (9)
where σTa(=5×105/Omega1−1m−1) is the conductivity of the β-Ta
layer. The estimated value of the transparency for the CFA/ β-
Ta interface is ∼68%. This Tvalue is even higher than for
FM/Pt interfaces [ 33], clearly indicating the significance of
using the CFA/ β-Ta structure in innovative spin transfer torque
devices.
IV . CONCLUSIONS
The effects of Co 2FeAl thickness covering the range 8–
20 nm on the static and dynamic properties of Si/ Co 2FeAl/β-
Ta multilayers have been investigated. It was found that staticproperties like the saturation magnetization and coercivitywere weakly thickness dependent, with values covering therange 900–950 kA /m and 0.53–0.87 kA /m, respectively. The
in-plane uniaxial anisotropy field was determined from angle-dependent cavity FMR measurements, indicating a decreasingtrend with increasing CFA thickness, with values covering therange 2.20–3.90 mT. Both in-plane and out-of-plane broadbandFMR measurements show that the effective damping parameter
increases with decreasing thickness, indicating an enhance-ment of damping due to spin pumping into the nonmagneticcap layer. The in-plane damping parameter is also affected byspin relaxation due to two-magnon scattering, resulting in alarger effective damping parameter as compared to the out-of-plane damping parameter. The out-of-plane effective dampingparameter, being free from spin relaxation due to two-magnonscattering, was further analyzed to extract information aboutthe effective spin-mixing conductance of the multilayer as wellas to disentangle the contributions to the effective damping
parameter, yielding g
↑↓
eff=(2.90±0.10)×1019andαG=
(1.1±0.2)×10−3. The high value of g↑↓
efffor the CFA/ β-Ta
structure, at par with that of FM/Pt bilayers, in conjunctionwith∼68% interface transparency and low Gilbert damping
(/lessorequalslant1.1×10
−3) of CFA clearly makes the CFA/ β-Ta structure
a promising building block for spin transfer torque devices.
ACKNOWLEDGMENTS
This work is supported by the Knut and Alice Wallen-
berg (KAW) Foundation, Grant No. KAW 2012.0031. S.H.acknowledges the Department of Science and TechnologyIndia for providing the the INSPIRE Fellowship (Grant No.IF140093) grant.
S.A. and A.K. contributed equally to this work.
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134421-8 |
Physics.14.92.pdf | VIEWPOINT
ANewDriftinSpin-Based
Electronics
Asymmetry-breakingmechanismallowsresearcherstoproduceand
observeadirectedcurrentofmagnonsinamagneticinsulator,opening
newpossibilitiesinmagnon-basedelectronics.
ByArabindaHaldar andAnjanBarman
Demandforminiaturized,energy-efficient,andultrafast
information-processingdevicescontinuestorise,but
manufacturersareapproachingthefundamentallimits
oftheprevailingtechnology,whichisbasedoncomplementary
metal-oxidesemiconductors(CMOS).Oneofthemainbarriers
toprogressisJouleheating: asCMOScomponentsbecome
fasterandsmaller,theysuffermorefromtheheatthatbuildsup
becauseoftheflowofelectroniccharge. Researchershave
proposedcircumventingthisproblembydoingawaywith
movingchargesaltogether. Instead,informationprocessing
couldbeaccomplishedbymanipulating
“magnons”—quasiparticlesofelectron-spinexcitations—ina
magneticmedium. Now,RichardSchlitzattheSwissFederal
InstituteofTechnology(ETH),Zurich,andcolleagueshave
takenanimportantsteptowardsuchatechnologybyshowing
thatamagnondriftcurrentcanbeinducedtoflowina
magneticheterostructure[ 1].
Justasphononsrepresentthecoherentpropagationoflattice
vibrations,magnonsrepresentthecollectiveprecessionof
electrons’magneticmoments. Inbothcases,these
quasiparticlesmovethroughamaterialeventhoughthe
excitationsthatsustainthemremainfixedwithinthelattice.
Thepossibilityofon-chipdataprocessingbasedonmagnonsis
stimulatinganewfrontierinphysicscalled“magnonics,”where
amagnoncurrentreplacesthespinorchargecurrentusedin
spintronicorelectronicdevices,respectively[ 2,3]. Thisisnota
straightforwardreplacement,however. Whereasanelectron
driftcurrentisthephysicalmotionofcharge,amagnoncurrent
representsonlythepropagationofthephaseofcollectivespin
precession. Thisdifferencemeansthattheinteractionofmagnonswithamagneticfieldisnotanalogoustothe
interactionofelectronswithanelectricfield. Ratherthan
drivingmagnonsthroughacircuit,amagneticfieldonlycauses
achangeintheirfrequency. Instead,magnondriftcurrents
mustbemanipulatedbymechanismsthatresultfrombreaking
theinversionsymmetryofthemagneticmedium.
OnesuchmechanismistheDzyaloshinskii-Moriyainteraction
(DMI),whichcanoccuratthecontactbetweenaferromagnetic
layerandanonmagneticlayerwithlargespin-orbitcoupling.
ThisinterfacialDMI(iDMI)isanantisymmetric,three-site
exchangeinteraction,wherethespinsoftwoferromagnetic
atomsinteractviaanonmagneticatombelongingtothe
nonmagneticlayerattheothersideoftheinterface. Asaresult,
theDMIvectorliesintheplaneoftheinterface,producingan
asymmetricmagnondispersionthatcanbedirectlyprobed
usinganopticalmagnon-spectroscopytechnique[ 4]. However,
thisprobingtechniquecannotdifferentiate“pure”magnondrift
currentsinducedbytheiDMIfromdiffusivemagnoncurrents
drivenbymagnonchemicalpotential. Asaresult,clean
observationsofmagnondriftcurrentshavenotbeenreported.
Inanewstudy,Schlitzandhiscolleaguesproposeatheoryof
magnontransportinwhichthedriftcurrentcontributionis
addedtothediffusivemagnoncurrentbyincludingan
additionalasymmetrictermintheequationthatdescribesthe
system. Theeffectofthisadditionaltermistocreatean
anisotropyinthemagnonvelocity,whichtheteamusedasa
wayofdisentanglingthetwocontributionsexperimentally.
Theysputter-depositedaY 3Fe5O12(YIG)thinfilmona
(111)-orientedGd 3Ga5O12(GGG)substrate. YIGisapopular
physics.aps.org | ©2021AmericanPhysicalSociety | June23,2021 | Physics14,92 | DOI:10.1103/Physics.14.92 Page1VIEWPOINT
Figure1: Schematicshowingtheexperimentalsetupusedto
measurethemagnondriftcurrent. Acurrent(I)flowinginthe
centralplatinum(Pt)wiregeneratesaspincurrentintheYIGlayer
viathespinHalleffect. Dzyaloshinskii-Moriyainteractionatthe
YIG-GGGinterfaceproducesanasymmetryinthepropagation
velocityofdriftmagnoncurrent(V DMI),whichcanbecontrolledby
aligningthemagnetizationvector( M).Theasymmetryisrevealed
asanunequalresistancemeasuredbythetwodetectorwireson
eithersideofthecurrent-carryingwire.
Credit: A.Barman/S.N.BoseNationalCentreforBasicSciences;
A.Haldar/IndianInstituteofTechnologyHyderabad;adaptedby
APS/AlanStonebraker
ferrimagneticoxideforsuchstudies,asitallowslong-range
spin-wavepropagation,whiletheYIG-GGGinterfacehasbeen
showntogenerateiDMI[ 5]. Wheretheteam’ssetupdeviated
frompriorexperimentsisintheirinnovativenonlocal
measurementtechnique. Usually,suchnonlocalelectrical
measurementsofamaterialaremadeusingtwophysically
separatedcontactpads. Currentissentintothematerial
throughoneofthecontactpads,andthematerial’sresistanceis
calculatedbymeasuringthevoltageattheothercontactpad.
Asthevoltageismeasuredawayfromthecurrent-carrying
contactpad,thecalculatedresistancecarriesinformationon
thetransportpropertiesofthematerialuponwhichthecontact
padsarefabricated. Theproblemisthatthenonlocal
resistance,asdescribedbyasimplifiedmagnontransport
model,arisesbecauseofthecombinationofbothdiffusionand
driftmagnoncurrentinthematerial. Assuch,thereisnowayto
teasethetwoeffectsapartinexperiments.Toavoidthelimitationsofthisconventionaltwo-contact
approach,Schlitzandhiscolleaguesfabricatedthreeequally
spaced,parallelplatinumwiresontopoftheYIGfilm(Fig. 1). By
drivinganoscillatingcurrentinthecentralwire,theyinduceda
magnoncurrentinthelowerYIGlayerthroughthespinHall
effect(SHE).TheSHEgeneratesapurespincurrentasaresultof
theflowofchargecurrentinmaterialswithlargespin-orbit
coupling,suchasplatinumandotherheavymetals. Itsinverse
effect—knownasISHE—isthegenerationofavoltageduetothe
conversionofspincurrenttochargecurrent. Intheabsenceofa
magnondriftcurrent,thediffusivemagnoncurrentwould
generateanequalvoltageateachwire,withthesizeofthe
voltagedependentonthemagnetic-fieldstrengthand
orientation. Butadriftcurrentwouldproduceavoltage
asymmetry. Indeed,theteamfoundthattheISHE-induced
voltageateachwirewasdifferentandthatthesevoltagesvaried
asymmetricallyasthemagnetic-fieldorientationwaschanged.
Fromthisasymmetry,theresearcherswereabletocalculatethe
driftcurrentcontributioninisolation.
Schlitzandcolleagues’cleardemonstrationofamagnondrift
currentisaproof-of-principleofanimportantphenomenonin
magnonics. Assuch,theresultopensupnewpossibilities,such
asimprovedmagnon-basedlogicandcommunicationdevices.
Agoalforthefuturewillbetofindmaterialcombinationsthat
generateastrongerDMIeffectthantheYIG-GGGinterface,
whichwouldenhancethemagnondriftcurrent. Suchmaterials
mustalsoexhibitlowlevelsofGilbertdamping—a
phenomenonthatcausesspinexcitationstodissipate—toallow
forsignificantmagnonpropagation. ButDMImightnotbethe
onlygameintown: Othermechanismsofinversionsymmetry
breaking—suchasanasymmetricornonuniformfield[ 6]and
theRashbaeffect[ 7]—canalsobeutilizedtorealizelarge
magnondriftcurrents,andwelookforwardtothe
demonstrationofsuchideas.
ArabindaHaldar: DepartmentofPhysics,IndianInstituteof
TechnologyHyderabad,Telangana,India
AnjanBarman: DepartmentofCondensedMatterPhysicsand
MaterialSciences,S.N.BoseNationalCentreforBasicSciences,
Kolkata,India
REFERENCES
1.R.Schlitz etal.,“Controlofnonlocalmagnonspintransportvia
physics.aps.org | ©2021AmericanPhysicalSociety | June23,2021 | Physics14,92 | DOI:10.1103/Physics.14.92 Page2VIEWPOINT
magnondriftcurrents,” Phys.Rev.Lett. 126,257201(2021).
2.A.V.Chumak etal.,“Magnonspintronics,” Nat.Phys. 11,453
(2015).
3.ABarman etal.,“The2021magnonicsroadmap,” J.Phys.
Condens.Matter (2021).
4.H.T.Nembach etal.,“LinearrelationbetweenHeisenberg
exchangeandinterfacialDzyaloshinskii–Moriyainteractionin
metalfilms,” Nat.Phys. 11,825(2015).5.H.Wangetal.,“Chiralspin-wavevelocitiesinducedbyall-garnet
interfacialDzyaloshinskii-Moriyainteractioninultrathinyttrium
irongarnetfilms,” Phys.Rev.Lett. 124,027203(2020).
6.J.H.Kwon etal.,“Giantnonreciprocalemissionofspinwavesin
Ta/Pybilayers,” Sci.Adv2,e1501892 (2016).
7.K.-W.Kim etal.,“Predictionofgiantspinmotiveforcedueto
Rashbaspin-orbitcoupling,” Phys.Rev.Lett. 108,217202
(2012).
physics.aps.org | ©2021AmericanPhysicalSociety | June23,2021 | Physics14,92 | DOI:10.1103/Physics.14.92 Page3 |
PhysRevB.101.205407.pdf | PHYSICAL REVIEW B 101, 205407 (2020)
Editors’ Suggestion
Spin caloritronics in a CrBr 3-based magnetic van der Waals heterostructure
Tian Liu ,*,†Julian Peiro ,†Dennis K. de Wal , Johannes C. Leutenantsmeyer,
Marcos H. D. Guimarães , and Bart J. van Wees
Zernike Institute for Advanced Materials, Nijenborgh 4, 9747 AG Groningen, The Netherlands
(Received 3 March 2020; revised manuscript received 11 April 2020; accepted 14 April 2020;
published 6 May 2020)
The recently reported magnetic ordering in insulating two-dimensional (2D) materials, such as chromium tri-
iodide (CrI 3) and chromium tribromide (CrBr 3), opens new possibilities for the fabrication of magnetoelectronic
devices based on 2D systems. Inevitably, the magnetization and spin dynamics in 2D magnets are strongly linkedto Joule heating. Therefore, understanding the coupling between spin, charge, and heat, i.e., spin caloritroniceffects, is crucial. However, spin caloritronics in 2D ferromagnets remains mostly unexplored, due to theirinstability in air. Here we develop a fabrication method that integrates spin-active contacts with 2D magnetsthrough hBN encapsulation, allowing us to explore the spin caloritronic effects in these materials. The angulardependence of the thermal spin signal of the CrBr
3/Pt system is studied, for different conditions of magnetic
field and heating current. We highlight the presence of a significant magnetic proximity effect from CrBr 3on
Pt revealed by an anomalous Nernst effect in Pt, and suggest the contribution of the spin Seebeck effect fromCrBr
3. These results pave the way for future magnonic devices using air-sensitive 2D magnetic insulators.
DOI: 10.1103/PhysRevB.101.205407
I. INTRODUCTION
The search for magnetism in 2D systems has been a
nontrivial topic for decades. Recently, 2D magnetism wasdemonstrated in an insulating material CrI
3[1], which shows
antiferromagnetic exchange between the layers, resulting inzero (nonzero) net magnetization for even (odd) number oflayers. It has been shown that CrBr
3exhibits ferromagnetism
when exfoliated down to a few layers [ 2] and monolayers [ 3]
while preserving its magnetic order.
This discovery offers us a platform to explore magnonics
in 2D systems. Magnonics refers to spintronics based onmagnons, which are quantized spin waves, i.e., collectiveexcitations of ordered electron spins in magnetic materials[4–6]. Magnonic spin transport has been extensively studied
in various ways in 3D magnetic insulators, e.g., spin pumping[7], Spin Seebeck effect (SSE) [ 8], and electrical injection
and detection of magnons [ 9]. The outstanding magnon trans-
port properties of the ferrimagnetic insulator yttrium irongarnet (YIG) and the robustness and fast dynamic of AFMmaterials like iron oxide [ 10] and nickel oxide [ 11]t r i g -
gered the development of the first magnon transport deviceprototypes for application using these materials [ 9,12,13].
The predicted novel physical phenomena [ 14–18] hosted by
low-dimensional magnon systems represent a strong potentialfor 2D magnonics. Thermally excited magnon transport wasreported recently in an AFM vdW 2D material MnPS
3[19].
However, magnonics in 2D van der Waals magnetic systemsstill remains mostly unexplored, especially for 2D ferromag-netic (FM) systems.
*tian.liu@rug.nl
†These authors contributed equally to this work.One of the difficulties to study such phenomena is the easy
degradation in air of the magnetic 2D materials, bringing extratechnical challenges for integrating magnonic circuits withthese materials. Here, we introduce a technique of bottommetallic contacts on an air-sensitive material CrBr
3, aiming at
preliminary study of magnonics in 2D ferromagnetic materi-als. We select CrBr
3as a medium for 2D magnonics study [ 20]
as its FM order is independent on the number of layers andthus it simplifies the device fabrication. The Curie temperatureof CrBr
3is about Tc=37 K [ 20] in bulk, reducing to 27 K
for monolayers [ 3]. CrBr 3presents perpendicular magnetic
anisotropy (PMA) [ 2] with an out-of-plane coercive field of
4 mT and an in-plane saturation field of 400 mT for a fewlayers [ 3]. The saturation magnetization of about 271 kA /mi s
reported nearly equal for in-plane and out-of-plane orientationin bulk and differs by less than 20% for three-layer CrBr
3
[2,21].
II. DEVICE GEOMETRY AND MEASUREMENTS
In this work we employ nonlocal angular-dependent
magnetoresistance (nlADMR) measurements on a hBN-encapsulated CrBr
3flake contacted by Pt strips. ADMR mea-
surements have been widely used to characterize the spin Hallmagnetoresistance (SMR) in local geometries [ 22]o rt h es p i n
Seebeck effect (SSE) in nonlocal geometry [ 9] and identify
them out of other caloritronics effects [ 23–26]. We fabricated
a device where Pt strips (5.5 nm thick) are deposited into apreetched 16.6-nm-thick hBN flake on top of a silicon oxidesubstrate. A 6.5-nm-thick top hBN flake is used to pick up andfully cover a 7-nm-thick CrBr
3flake (about 10 layers) [ 27]. A
schematic of the device and nonlocal measurement geometryis shown in Fig. 1(a).
2469-9950/2020/101(20)/205407(8) 205407-1 ©2020 American Physical SocietyTIAN LIU et al. PHYSICAL REVIEW B 101, 205407 (2020)
FIG. 1. (a) Schematic of the device and the circuit for the nonlocal measurements. A 7-nm-thick CrBr 3flake placed on top of 5.5-nm-high
Pt strips is fully encapsulated by two layers hBN. The x,ydirections are defined to be in-plane (Pt strips parallel to the yaxis), where
the magnetic field is rotated over the azimuthal angle ϕ(IP) and polar angle theta (OOP). (b), (d) Principle of generation and detection
of respectively electrically and thermally generated magnons. (c), (e) Measured corresponding first (c) and second (e) order harmonic NL
resistances with 20 μA are fitted with the cos2(ϕ)a n dc o s ( ϕ) function, respectively. The small red arrows in (b) and (d) indicate spin
polarization direction. For (e) the sign of the fitted cosine for the ISHE from the SSE agrees with this spin polarization and therefore with
the standard definition of the spin Hall angle [ 28]. For the measurement in (e), the offset R2ω
0=16.3±0.8V/A2. The error bars represent the
standard deviation from the fits.
In this system, a gradient of temperature is created by
the Joule heating from a remote Pt heater which generatesa magnon-mediated spin flow due to the magnon densitydependence on the temperature [ 29], i.e., the SSE. At the
interface between a magnet and a nonmagnetic material, atransfer of magnon spin ( +¯h) from the CrBr
3to the Pt is
possible by spin flip of a −¯h/2s p i nt oa +¯h/2 spin in the
Pt. The spin current generated this way in the Pt contactconverts into a charge current by inverse spin Hall effect(ISHE) and can be measured as a voltage difference. In thegeometry defined in Fig. 1, the ADMR is then sensitive
to the xcomponent of the magnetization of CrBr
3,Mx.I n
the in-plane ADMR configuration [Figs. 1(a) and1(d)], the
orientation of the magnetization with regard to the detectioncontact drives the angular dependence; therefore, a cos( ϕ)
dependence is expected.
All data shown in the main text was measured on a pair
formed of a 310-nm-wide injector and a 520-nm-wide detec-tor, spaced by 500 nm edge to edge, and at a base temperatureof 5 K under a reference magnetic field of 4 T, unless specif-ically mentioned. We separate different harmonics by usingstandard low frequency (6 Hz to 13 Hz) lock-in techniques.The voltage response is composed of different orders that areexpanded as V(t)=R
1I(t)+R2I(t)2+··· [9], where Riis
theith-order response [ 30] to the applied ac current I(t). As
the electrical magnon injection scales linearly with current, itsresponse is expected in the first harmonic signal. The thermalinjection depends quadratically on the applied current and theresponse appears in the second harmonic signal.
First and second harmonic responses of the nonlocal signal
have been measured simultaneously all along this study. Thefirst order angular dependence is expected to obey the relationR
1ω=V/I=R1ω
0+R1ω
nlcos2(ϕ)[9], where R1ω
0is an offset
resistance and R1ω
nlis the magnitude of the first harmonicsignal. However, we do not observe the expected cos2(ϕ)
modulation in the first harmonic signal, as the fitted firstorder resistance R
1ω
nlis only detected in the order of 0.01 m /Omega1
which is comparable to the standard deviation. An example ofmeasured first harmonic signal can be found in Fig. 1(c).Y e t ,
this value is at least three orders smaller than the R
1ω
nlreported
for the Pt /YIG system [ 9]). The measurements are carried out
over a wide range of applied currents and magnetic fields,and with the maximum lock-in detection sensitivity. A typicalmeasurement of first harmonic nonlocal signal is shown inFig. 1(c), for a current of 20 μA at 5 K. In contrast, the
nonlocal second harmonic signals exhibit a clear sinusoidalbehavior [Fig. 1(e)] under an in-plane rotating magnetic field.
The magnitudes of nonlocal signals were fitted with
R
2ω=V
I2=R2ω
0+R2ω
nlcos(ϕ), (1)
where R2ω
0is the offset resistance for the second harmonic
signal. A nonzero offset R2ω
0is always present, possibly from
unintended Seebeck contribution in the detector [ 31].R2ω
nlis
the magnitude of the second harmonic signal. For the corre-sponding second harmonic measured in Fig. 1(e), we extract
an amplitude R
2ω
nl=−36±1V / A2, which is comparable to
the magnitude of room-temperature nonlocal SSE measuredon bulk Pt /YIG samples [ 9] with equal angular dependence.
If we compare to the typical top contact geometry used todetect SSE from YIG [ 9], the same SSE detected here in
bottom contact geometry should produce a spin current inthe opposite direction. Therefore, the ISHE induced in Pt isreversed compared to the top Pt on YIG; hence we expect anopposite sign of the signal. The negative sign observed herewould correspond to the positive sign measured in [ 9] and,
if attributed to SSE, reveals a transfer of magnon spin fromCrBr
3to the Pt top surface. However, at this point, we cannot
205407-2SPIN CALORITRONICS IN A CrBr 3-BASED … PHYSICAL REVIEW B 101, 205407 (2020)
FIG. 2. Dependence of second harmonic signals on applied cur-
rent through the injector. (a) Top panel: low bias signals with cos( ϕ)
fitting measured at 20 μA, with a fitted amplitude ( −29±1V/A2);
bottom panel: high bias signals with cos( ϕ) fitting measured at
140μA, with a fitted amplitude (0 .64±0.03 V/A2). (b) Bias
dependence of R2ω
nl. Bias dependence shown in these graphs were
measured at 5 K under a magnetic field of 4 T. The inner figure
presents the zoom-in data of R2ω
nl, for the applied current from 100
μA to 300 μA.
rule out other effects like proximity induced anomalous
Nernst effect (pANE) in Pt [ 32]. We discuss relevant effects
later [see Fig. 4(c), rotation of out-of-plane magnetic field].
The current dependence of R2ω
nlis plotted in Fig. 2,f o ra
contact pair with distance of 950 nm center to center (edgeto edge distance of 500 nm). R
2ω
nldepends on the applied
current nonlinearly, and a sign reversal of R2ω
nloccurs between
40 and 100 μA. For data measured at 60 μA and 80 μA,
an angular modulation of the second harmonic signal is stillobserved but it is not described by a simple cosine function(see Supplemental Material [ 33]). An example of the negative
R
2ω
nlat low current is shown in Fig. 2(a) (top panel), and
an example of the positive R2ω
nlat high current is plotted inFig. 2(a) (bottom panel). The absolute amplitude |R2ω
nl|in
general decreases with increasing current at the heater, asplotted in Fig. 2(b). Its value for positive amplitude at high
current is one to two orders of magnitude lower than itsvalue for negative amplitude at low current, depending on theapplied current.
To get better insight of the role of the complex temperature
distribution in our device for this nonlinear behavior, weemploy a two-dimensional finite element model (FEM) sim-ulating a geometry of the x-zplane. Indeed the full hBN en-
capsulation of the CrBr
3flake in this device brings inevitable
additional heat conduction paths resulting in strong current-dependent thermal gradients in both xandzdirections ( ∂
xT
and∂zT, respectively). As κCrBr 3, the thermal conductivity of
CrBr 3, is unknown, we ran the computation for different ther-
mal conductance ratios ηKso that κCrBr 3(T)=ηKκhBN(T),
withκhBNthe thermal conduction of hBN, and taking into
account the highly temperature dependent thermal conductionof the materials (see Supplemental Material VII [ 33]). This
modeling reveals a strong dependence of the temperatureprofile as a function of the heating current. It qualitativelysupports that the main contribution of the thermal gradientin the Pt detector is in xdirection ( ∂
xT). Yet there also is a
non-negligible thermal gradient in zdirection ( ∂zT), in the
CrBr 3as well as in the Pt detector, allowing for SSE and
possible unintended effects occurring in the Pt detector thatwill be discussed below.
The in-plane magnetic field dependence on the second
order nlADMR amplitude R
2ω
nlis plotted in Fig. 3(a).W e
apply a range of fields from 0 T to 7 T for the in-planerotation measurements at 5 K. At low current (20 μA), we
observe a linear increase of |R
2ω
nl|from 0 T to 3 T. After
4 T, the magnitude tends to saturate showing only a slightdecay [Figs. 3(a) and3(c)]. At high current (160 μA), we
also observe a linear increase of R
2ω
nlfrom 0 T to 4 T, but
(a)
(b)(d) (c)
-180 -90 0 90911911911911R2ω(V/A2)
ϕ(deg)7T
4T
1T
0T20μΑ 160μΑ
-180 -90 0 90-1000100
ϕ(deg)-1000100-1000100-1000100
0T1T4T7TR2ω(V/A2)
02 0 4 0 6 0050
Temperature (K)|R2ω
nl(V/A2)|20μΑ
01
4T
160μΑ
R2ω
nl(V/A2)0246050
5K
20μΑ
R2ω
nl(V/A2)
Magnetic field (T)|R2ω
nl(V/A2)|
01
160μΑ
FIG. 3. (a) Magnetic field dependence of R2ω
nlwith both low current (20 μA) and high current (160 μA). The fitted cosine amplitude
increases with magnetic field until 3 T in both cases. Examples of measured signals are shown in (c) for low bias and in (d) for high bias, with
the fitted cosine curves in solid line. (b) The low bias and the high bias signals measured at three different temperatures: 5 K, 10 K, and 60 K.
The thermal spin signal measured at 10 K is smaller than 5 K for both low bias and high bias cases.
205407-3TIAN LIU et al. PHYSICAL REVIEW B 101, 205407 (2020)
(b) (d) (e) (f)zCrBr3
PtSSE
CrBr3
PtCrBr3
PtANEz ANEx
MPtMPt
x(a)
V
+- +
-V
++
--
Sum(c)
FIG. 4. (a) Schematics of the main effects contributing to the detected signal in OOP-nlADMR, ϕ=0◦,θ∈[−180◦,180◦]. (b) Second
harmonic nlADMR for the forward (blue) and the reverse (red) configurations measured with applied current of 20 μA. (c) Sum
(R2ω
NL,For+R2ω
NL,Rev )/2 (green) and difference ( R2ω
NL,For−R2ω
NL,Rev )/2 (purple) of the traces in (b), highlighting contributions that are fitted with
cos(θ)a n ds i n ( θ) functions, respectively. (d) Second harmonic nlADMR shown for 40, 100, and 280 μA for an external magnetic field of 4 T
r o t a t i n gi nt h e x-zplane. (e) The current dependence of pANEx(red) and SSE +pANEzsignals (blue) for the forward configuration. In insets
of (e) are given the ratio ξ=−(RSSE+RpANE z)/RpANE x(bottom inset). (f) Current dependence of the calculated SSE resistance for a range of
γ=∂zT/∂xT.
with magnitudes about 50 times smaller than |R2ω
nl|for low
current. After 4 T, the magnitude still increases but at a
lower rate [Figs. 3(a) and3(d)]. The lower magnitude at high
current is consistent with the reduction of the magnetizationexpected for a temperature increase due to Joule heating. Theorigin of the magnetic field dependence remains unclear. Asthe saturation of the magnetization of trilayer CrBr
3in its
hard plane is reported to occur at 400 mT [ 2], the linear
increases cannot be simply explained by the saturation of themagnetization as from an isolated CrBr
3layer and reveals the
contribution of additional field dependent effects.
The second order nlADMR is also measured at three
different temperatures, 5 K, 10 K, and 60 K, and the fittedamplitudes of R
2ω
nlare shown in Fig. 3(b) for low (20 μA) and
high current (160 μA) measured under 4 T. Compared with
the signal at 5 K, the fitted cosine amplitude at 10 K decreasesfor both low and high bias. Far above T
cat 60 K, a very small
but nonzero value of R2ω
nlis observed in our measurements
(0.08±0.03 V/A2at 160 μA and −3±2V/A2at 20μA).
We attribute this small nonzero value to an artifact from themeasurement setup (see Supplemental Material [ 33]).
We present hereafter a series of out-of-plane nlADMR
(OOP-nlADMR) measurements, i.e., fixing ϕ=0
◦and vary-
ingθby rotating the magnetic field in the x-zplane, as
defined on Fig. 1. Some examples and the current dependence
of this OOP-nlADMR are summarized in Fig. 4. The first
observation, with Figs. 4(b) and 4(d) as examples, is that
all OOP-nlADMR signals exhibit a nonzero angular phaseshift varying with the heating current. We investigated the
origin of this phase considering the various effects that couldadd to the SSE signal. Nernst, Seebeck, and spin Nernstmagnetoresistance (SNMR) [ 25,34] effects are discarded as
major contributions, either due to the probing geometry ortheir angular dependence; a detailed description is given in theSupplemental Material [ 33]. However, the anomalous Nernst
effect (ANE), which has already been reported as a possibleeffect, arising from a proximity induced ferromagnetism intothe Pt [ 24,32,35–38], cannot be ruled out.
Considering a proximity ANE (pANE) in Pt, a transverse
pANE voltage /Delta1V
pANE reads
/Delta1VpANE
LPt=| ∇ V|y=|− SpANE(m×[−∇T])|y, (2)
where SpANE is the pANE coefficient, mis the unit vector of
direction of the magnetization, and LPtis the y-axis length
of the contact area of Pt with CrBr 3. As the magnetization
of CrBr 3is expected to saturate for fields beyond 1 T in
the hard plane [ 2,21], we also assume the proximity induced
magnetization parallel to the magnetic field at 4 T. Then, twocontributions of the pANE are distinguished [Fig. 4(a)]: the
pANE signal caused by the IP gradient ∂
xT, pANEx, which
varies as sin( θ), and the pANE signal caused by the OOP
gradient ∂zT, pANEz, which varies as cos( θ).
The pANE induced by the temperature gradient along x
(pANEx) can be isolated from the other signals by changing
the heat flow direction. By interchanging the heater and
205407-4SPIN CALORITRONICS IN A CrBr 3-BASED … PHYSICAL REVIEW B 101, 205407 (2020)
detector contacts, the heat flow direction along the xaxis
(∝∂xT) is reversed, but the heat flow direction along the z
axis (∝∂zT) remains the same. Hence the pANEzcontribution
will stay unchanged, while the pANExwill reverse its sign.
In Fig. 4(b), we provide a normalized second order nlADMR
R2ω
N=R2ωAPt/LPt, with APtthe Pt electrode cross section, at
20μA and 4 T, for the configuration forward defined in Fig. 1,
and the nlADMR from a reversed geometry where heater anddetector are interchanged. As the width and length of the twoelectrodes are different, as well as their interface with CrBr
3
possibly, the heating power injected will differ by a smallfactor. Therefore, our comparison remains only qualitative.Nevertheless, the amplitudes and offsets are alike and the twotraces differ mainly by the apparent opposite phase shift.
If both pANE
xand pANEzcontributions are significant
in our system, the difference between the forward geometry[Fig. 4(b)] signal and the reverse geometry [Fig. 4(b)] signal
will reveal the sin( θ) behavior, and the sum of these two
signals will reveal the cos( θ) behavior. As a result, we obtain
the respective traces shown in Fig. 4(c). The good agreement
of the fittings on both curves is a confirmation that the pANEis present in the Pt detector.
Based on this observation, we extracted the two contri-
butions for every ADMR at different current and at a con-stant magnetic field of 4 T, by fitting the expression R
2ω=
R2ω
0+RSSE+pANE zcosθ+RpANE xsinθ. The measurements at
40, 100, and 280 μAa r es h o w ni nF i g . 4(c), and the fitted
sinusoidal curve presents the phase shift in each case. Thecurrent dependence of the extracted amplitudes is providedin Fig. 4(d).T h e R
SSE+pANE zand RpANE xcontributions both
follow a similar decreasing trend with applied current. WhileR
SSE+pANE zdominates at 20 and 40 μA,RpANE xbecomes close
to twice RSSE+pANE zat higher current. The variation of the
amplitude of RSSE+pANE zat low currents follows the variation
of the signal for IP field rotation in Fig. 2(b); however, the sign
reversal for the derived RSSE+pANE zdoes not occur in the OOP
configuration.
To elucidate the contribution of the spin Seebeck,
we introduce the ratio ξ=− RSSE+pANE z/RpANE x=
−(RSSE+RpANE z)/RpANE xof the two contributions [inset
of Fig. 4(e)], the ratio δ=Sz
pANE/Sx
pANE to account for
any difference between the IP ( Sx
pANE) and OOP ( Sz
pANE)
proximity anomalous Nernst coefficients, as well as the ratioγ=∂
zT/∂xTof the temperature gradients in Pt. As a result,
the SSE contribution to the measured signal simply reads(demonstration in the Supplemental Material [ 33])
R
SSE=RpANE x(δγ−ξ). (3)
Based upon the fact that the saturated magnetization of CrBr 3
has been reported to be of the same magnitude when oriented
IP or OOP, we assume δ≈1, i.e., Sz
pANE≈Sx
pANE. Following
this assumption, the estimated ratio of the two contributionsγlays between −0.20 and 0.15, according to our FEM
simulation based on thermal conduction properties of CrBr
3
and hBN layers (i.e., the ratio ηK=κCrBr 3/κhBN) (see details
in the Supplemental Material [ 33]). Even using δγ=±0.5
accounting for the possible underestimation of ∂zTdue to
the omission of a small heat leakage via the Pt /Au contacts
leads on SiO 2, we extract a significant SSE contribution to(b) (a)
FIG. 5. (a) SSE angular dependence shown for 1, 4, and 7 T,
with current fixed to 20 μA at 5 K. (b) Magnetic field dependence
of pANExand SSE +pANEzsignal amplitude for the forward con-
figuration. In the inset of (b) the ratio ξ=−(RSSE+RpANE z)/RpANE x
is given. See the Supplemental Material [ 33] for the data extraction
in detail.
the nlADMR signal at low heating current, as plotted in
Fig. 4(f). We provide the magnetic field dependence of the
OOP-nlADMR in Fig. 5. Figure 5(a) shows examples of
the evolution of the OOP-nlADMR for 1, 4, and 7 T, fora current fixed to 20 μA. The same operation to separate
pANE
z+SSE from pANExis applied to this measurement
set and the amplitude variation of each component is shown inFig.5(b) for magnetic fields from 0 to 7 T. The pANE
z+SSE
variation is comparable to the one measured in in-plane rota-tion configuration [Fig. 3(a), blue curve], except that we do
not observe the high field saturation decrease. The dependenceof the pANE
xtrace follows a similar increase until 2 T, but
shows a slight decrease for 3 and 4 T and increases again toreach the same value as pANE
z+SSE at 7 T. This behavior
is captured into the ξratio that shows a peak above 1.5 for
3 and 4 T and a value remaining around 1 for other fieldstrengths. As the temperature profile is fixed, the differencebetween SSE +pANE
zand pANExmust be strongly linked
to the magnetic properties of the CrBr 3/Pt structure.
III. DISCUSSION
By analyzing the OOP-nlADMR, we show that pANEx
presents a different angular dependence than SSE and pANEz
allowing one to separate the two contributions. Despite the
lack of insight on the mechanism inducing the magnetizationin Pt, this assumption is based on the fact that the magneticmoments emerging on the Pt atoms are imprinted by themoments of CrBr
3. Yet the saturated magnetization of CrBr 3
has been measured to differ by less than 20% between theorientation along the easy axis and the orientation in the hardplane. Therefore, the induced magnetization in Pt is expectedto behave accordingly, leading to a comparable anomalousNernst coefficient depending on the magnetization value butweakly on its orientation.
A pANE contribution to the ADMR has been identified in
Pt/YIG systems as well, but the pANE
zrepresents at most
205407-5TIAN LIU et al. PHYSICAL REVIEW B 101, 205407 (2020)
5% of the voltage signal, the left 95% being attributed to
SSE induced ISHE [ 32]. Because of the significant magnetic
exchange field already noticed in CrBr 3[3,39]a sw e l la s
the strong temperature gradients involved (beyond two ordersof magnitude higher than in [ 32]), in our CrBr
3/Pt system,
the pANE cannot be neglected and the SSE signal is at bestcomparable with the pANE
z.
In the Pt /YIG system, the magnon SSE signal decreases
with the magnetic field [ 40]. In Fig. 3(a), we notice that,
after 3 T, the fitted amplitude of the low current curve doesnot change with magnetic field, but R
2ω
nlof the high current
curve increases linearly with magnetic field. In other words,R
2ω
nlat low current tends to decrease where SSE contributes
most, compared to the amplitude at high current where theSSE contributes less. Hence our measurements, with supportof a temperature distribution simulation, suggest that the highamplitude signal observed at low current is dominated by SSEfrom CrBr
3.
According to the expected angular dependence of the SSE
and ANE, the SSE +pANEzsignal should appear in both IP-
nlADMR and OOP-nlADMR, while pANExshould be only
detected in OOP-nlADMR. Therefore, the same current de-pendence of SSE +pANE
zin both configurations is expected.
According to the FEM simulation, a reversal of ∂zToccurs at
sufficiently high current, simultaneously in CrBr 3and Pt at
the detection interface (see the Supplemental Material [ 33]).
This leads to a reversal of the SSE +pANEz, most likely
dominated by ANE in the high current range. However, thesign reversal is only observed in the IP measurements [inFig. 2(b)], not showing in the OOP measurements after the
separation [in Fig. 4(e)]. As the IP and OOP measurements
were performed with different cool-down processes, the ther-mal conductivity is possibly changed at the interface. Thisimplies that the sign reversal current is possibly shifted toa much higher value and therefore not observed in the OOPmeasurements.
Furthermore, we also suggest that a quantitative discrim-
ination between pANE and SSE is possible. We provide anindicative estimation of the magnitude of the SSE based onthe assumption that the pANE coefficient is equal for ANE
x
and ANE z. By far, we are limited by the current knowledge
on the material properties of the 2D magnet. However, if thethermal conduction profiles and the magnetization dynamicsare characterized concretely, a more accurate separation of thetwo spin-caloritronic effects can be realized.
Nevertheless, the magnetic field dependence of pANE
x
and SSE +pANEzand the difference between them bring
new questions. The ANE scales with the magnetization viathe coefficient S
pANE. The nonmonotonic field dependence of
pANExsuggests a complex evolution of the induced magne-
tization in Pt, due to either the presence of magnetic domainsor any additional interaction at the interface.IV . CONCLUSIONS
To conclude, we demonstrate the relevance of the full hBN
encapsulation and the bottom contacting design to enablethe integration of air-reactive materials such as CrBr
3,f o r
studying spin-caloritronic effects in 2D magnets. By usingsecond order nlADMR measurement on such an encapsulatedCrBr
3/Pt device, we reveal, by detecting the presence of
a proximity ANE voltage, a significant proximity inducedmagnetism from CrBr
3into the adjacent Pt contacts. With
reasonable assumptions, we conjecture about the presenceof a weak SSE, dominating the signal in the low currentregime, while the pANE prevails for currents above 60 μA.
The nontrivial magnetic field dependence of the separatedeffects leaves open questions as for the current understand-ing of magnetic effects at the interface of heavy metal and2D magnets. The encapsulation shows itself as an eleganttechnique to address these questions in deeper investigationsof air-degradable 2D materials, and opens the way to futuremagnon transport studies.
V . METHODS
CrBr 3and hBN crystals are provided by a commercial
company HQgraphene. CrBr 3is an air sensitive material.
To study magnonics with CrBr 3in a nonlocal geometry,
we encapsulate a 7-nm-thin chromium tribromide flake andplatinum (Pt) strips into two hexagonal boron nitride (hBN)layers (top layer and bottom layer). The stacking of van derWaals materials was performed in a glove box filled with inertgas argon by using standard PC /PDMS dry transfer method.
Pt strips were first grown on bottom hBN. After that CrBr
3
with a top hBN thin layer was transferred on top of the Ptstrips. See the Supplemental Material [ 33] for more details in
fabrication process.
ACKNOWLEDGMENTS
The authors thank Prof. J. Ye and P. Wan for granting us ac-
cess to their transfer system in an Ar glove box. We thank J. G.Holstein, H. de Vries, H. Adema, and T. J. Schouten for tech-nical assistance. We acknowledge fruitful discussions with G.R. Hoogeboom, A. A. Kaverzin, and J. Liu. This project hasreceived funding from the Dutch Foundation for FundamentalResearch on Matter (FOM, now known as NWO-I) as a part ofthe Netherlands Organization for Scientific Research (NWO),the European Union’s Horizon 2020 research and innovationprogramme under Grants Agreement No. 696656 and No.785219 (Graphene Flagship Core 1 and Core 2), and ZernikeInstitute for Advanced Materials. M.H.D.G. acknowledgessupport from NWO VENI 15093.
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205407-8 |
PhysRevB.84.094401.pdf | PHYSICAL REVIEW B 84, 094401 (2011)
Parametric excitation of eigenmodes in microscopic magnetic dots
Henning Ulrichs,*Vladislav E. Demidov, and Sergej O. Demokritov
Institute for Applied Physics and Center for Nonlinear Science, University of Muenster, Corrensstrasse 2-4, 48149 Muenster, Germany
Sergei Urazhdin
Department of Physics, West Virginia University, Morgantown, WV 26506, USA
(Received 22 June 2011; published 2 September 2011)
We utilize time- and space-resolved Brillouin light scattering spectroscopy to study the parametric excitation
of spin-wave eigenmodes in microscopic Permalloy dots. We show that the fundamental center eigenmode hasthe smallest excitation threshold. With the increase of the pumping power above this threshold, higher-orderdipole-dominated eigenmodes with both even and odd spatial symmetry also become excited. At microwavepower levels far above the threshold, the multimode excitation regime is suppressed due to the parametricexcitation of short-wavelength exchange-dominated spin-wave modes. Our results provide important insight intothe physics of parametric processes in microscopic magnetic systems.
DOI: 10.1103/PhysRevB.84.094401 PACS number(s): 75 .40.Gb, 85 .75.−d, 75.30.Ds, 75 .75.−c
I. INTRODUCTION
Parametric processes in magnetic systems were observed
by Bloembergen and Damon1and theoretically explained by
Anderson and Suhl2more than 50 years ago. Since then,
they have been intensively studied in the context of appliedphysics as well as basic research.
3–15Parametric processes can
be utilized for amplification and manipulation of spin-wavepulses,
7–9parametric stimulation and recovery of microwave
signals,10and wave-front reversal.11They also can be used
as a powerful experimental tool in studies of spin-wavesolitons and two-dimensional bullets,
7,8,12,13as well as magnon
Bose-Einstein condensates.14,15
One of the main parameters governing the efficiency of
parametric excitation is dynamic damping.16Monocrystalline
yittrium iron garnet (YIG) films are characterized by extremelylow magnetic damping (Gilbert damping parameter α<10
−4)
and thus have become the material of choice for studiesof parametric excitation and amplification of magnetizationoscillations and waves. As a consequence of the low dampingin YIG, moderate microwave pumping levels are sufficient forparametric excitation, enabling studies of strongly nonequi-librium states such as parametrically driven magnon gas instrongly nonlinear regimes.
17
As a material for technical applications, YIG has several
drawbacks. High-quality YIG films can be grown only onspecial substrates, such as gallium gadolinium garnet, whichmakes the fabrication process incompatible with conventionalsilicon-based semiconductor technology. Additionally, thismaterial is difficult to structure, and it also exhibits astrong dependence of the magnetic properties on temper-ature due to the relatively low Curie point. In contrast,polycrystalline transition-metal ferromagnetic films can beeasily grown by sputtering or evaporation on a variety ofsubstrates, including silicon, and they can be structured ona submicrometer scale by standard lithography techniques.Among these materials, Ni
80Fe20=Permalloy (Py) is most
widely used for basic research and applied studies dueto its low crystalline anisotropy and small damping ( α<
10
−2). Py has been utilized as a working medium in spin-torque nano-oscillators,18–21magnonic crystals,22–26domain
wall motion–based memory devices,27and spin-wave logic
circuits.28
Magnetic damping in Py is relatively small compared to
other metallic ferromagnets, but it is still much larger thanin YIG, resulting in a significantly higher threshold powerrequired for parametric excitation. For instance, parametricexcitation of spin waves in Permalloy films has been achievedonly with microwave power levels of at least a few Watts.
29,30
This problem can be overcome by reducing the dimensions
of the magnetic samples to nanometer scale and concentratingthe pumping energy into a smaller volume, thus producing alarge local microwave field sufficient for parametric excitationusing moderate driving power.
31,32
In this paper, we report an experimental investigation of
the parametric excitation of spin-wave modes in an elliptical
Py dot with submicrometer dimensions fabricated on top of
a microscopic microwave transmission line. To analyze thespectral and spatial characteristics of the excited modes, weutilized time- and space-resolved microfocus Brillouin lightscattering (BLS) spectroscopy.
33The parametric excitation
threshold power of about 1 mW was significantly smallerthan in the extended Py films, enabling us to investigate
parametric excitation processes far above the threshold.
We show that above the threshold, many different dipole-dominated eigenmodes can be excited. At large paramet-ric pumping power, short-wavelength exchange-dominatedspin-wave modes also become excited. The transfer of theparametric pumping energy into the short-wavelength part ofthe mode spectrum results in a decreased excitation efficiency
of the dipole-dominated modes. This redistribution of energy
does not significantly affect the excitation of the lowest-frequency modes of the dot. Consequently, the fundamentalcenter and the edge modes can be efficiently excited bythe parametric pumping both at small and at large pumpingpower levels. These results are important for the devel-opment of integrated magnetic devices utilizing parametric
processes for excitation and amplification of magnetization
oscillations.
094401-1 1098-0121/2011/84(9)/094401(6) ©2011 American Physical SocietyULRICHS, DEMIDOV , DEMOKRITOV , AND URAZHDIN PHYSICAL REVIEW B 84, 094401 (2011)
H
y
Microwave
pulses500 nm
xM
Microstrip linePy ellipse
h
FIG. 1. (Color online) Scanning electron micrograph of the sample.
II. SAMPLE AND MEASUREMENT SETUP
Figure 1shows a scanning electron micrograph of the
studied sample, which consists of a 10-nm-thick Py filmpatterned by electron-beam lithography and ion milling intoan elliptical dot with lateral dimensions of 1000 by 500 nm.The dot is fabricated directly on top of a 1- μm-wide and
160-nm-thick Au microstrip transmission line. A static mag-netic field of H=400–700 Oe was applied along the short
axis of the Py ellipse. The data presented here were obtained atH=700 Oe. To excite the magnetization dynamics, microwave
pulses with duration of 100 ns and a repetition period of 2 μs
were applied to the transmission line. The pulse power wasvaried between 0.1 mW and 50 mW. The microwave pulsescreated a dynamic magnetic field hparallel to the direction of
the static magnetization.
The detection of the magnetization dynamics was per-
formed by microfocus BLS technique described in detail inRef. 33. This technique combines the spectral and temporal
resolution of the conventional BLS
34with diffraction-limited
spatial resolution of about 250 nm determined by the size ofthe probing laser spot. The intensity of the scattered light at agiven frequency is proportional to the square of the dynamicmagnetization amplitude at this frequency, at the position ofthe probing spot.
The dynamic magnetic field hwas parallel to the static
magnetization in our experimental geometry. In this configura-tion, the microwave field cannot linearly excite magnetizationdynamics, since the corresponding component of the dynamicmagnetic susceptibility tensor is equal to zero.
16Instead,
the dynamics can be excited by a higher-order parametricexcitation process.
35In the quasiparticle picture, this process
can be understood as splitting of a microwave photon withfrequency f
Pand wave vector kP≈0 into two magnons with
frequency fP/2 and wave vectors that are equal in magnitude
and opposite in direction.16In accordance with this picture,
in our experiments, we detected magnetization oscillations athalf of the applied microwave pumping frequency f
P.
In confined sample geometries, quantization of the spin-
wave spectrum imposes limitations on the parametric excita-tion. Specifically, the dynamic magnetization response exhibitsresonant spectral behavior, with resonant frequencies equal tothose of the system’s eigenmodes. By utilizing the spectralsensitivity of the BLS technique to detect only the dynamicsignal at the frequency of a particular mode, one can selectivelymap out its spatial profile. Additionally, by synchronizingthe microwave pulses with the spectrometer clock, the timeFIG. 2. BLS spectra recorded at powers of parametric pumping
varying from 1 to 50 mW, as labeled. The horizontal scale is the
detection frequency, equal to half of the pumping frequency.
dependence of the magnetization response to the excitation
pulses can be recorded with resolution of 1 ns.
III. EXPERIMENTAL RESULTS AND ANALYSIS
A. Spectral characteristics of parametric excitation
Figure 2shows the BLS spectra recorded at different values
of the microwave pumping power Pbetween 1 and 50 mW,
providing a survey of the spectroscopic properties and power-dependent dynamical regimes of the system. To record thespectra, the laser spot was positioned at the center of the Pydot. The pumping frequency f
Pwas varied between 8 and
20 GHz, and the BLS intensity was simultaneously measuredatf
P/2.
Because of the threshold nature of the parametric
excitation, no dynamic magnetization was detected atP<1m W .A t P=1 mW, the spectrum exhibits a single
peak at f
0=7.1 GHz ( fp=14.2 GHz), corresponding to the
spin-wave eigenmode with the lowest parametric threshold[Fig. 2(a)]. At P>2 mW, a second peak appears at f
2=
8.5 GHz, as illustrated in Fig. 2(b) forP=2.5 mW. At P>
3.2 mW, a third peak appears at f1=7.7 GHz, as illustrated in
Fig. 2(c) forP=5 mW. At even larger power levels, several
additional peaks appeared in the spectra. For example, fourclosely spaced large peaks and an additional small peak atfrequency f
esignificantly below f0can be distinguished at
P=10 mW [Fig. 2(d)]. There is also a bump on the declining
slope of the peak at f0, suggesting that at least one additional
mode with frequency close to f0may be excited.
This simple trend is reversed at excitation powers above
10 mW. The BLS spectra now exhibit only two peaks atfrequencies f
0andfe[Figs. 2(e) and2(f)]. These two peaks
exhibit a nonlinear frequency shift with increasing P.I n
addition, they broaden and become noticeably asymmetric.The asymmetry is especially pronounced for the peak at f
0,
which clearly has a significantly steeper rising slope than thedeclining slope, characteristic for a nonlinear resonance.
36–38
B. Spatial characteristics of the parametrically excited modes
To identify the normal modes associated with the observed
spectral peaks, we performed spatially resolved measurements
094401-2PARAMETRIC EXCITATION OF EIGENMODES IN ... PHYSICAL REVIEW B 84, 094401 (2011)
FIG. 3. (Color online) Left: Pseudocolor-coded maps of the BLS
intensity. Right: One-dimensional cross sections of the maps along
the major axis of the Py ellipse, as marked by the dashed lines. Panels
(a)–(c) were acquired at the labeled frequency values correspondingto three different spectral peaks.
atP=10 mW, where the largest numbers of peaks are
observed. For each of the observed peaks, the excitationfrequency was fixed at twice its central frequency, and two-dimensional mapping of the BLS intensity was performed. Theprobing spot was scanned in x- and y-directions with a step size
of 50 nm across a 500 by 1000 nm rectangular area covering thePy dot. The left-side panels in Fig. 3show pseudocolor-coded
maps of the recorded BLS intensity. The right-side panels showone-dimensional cross sections of these maps along the majoraxis of the Py ellipse. It is important to note that the measuredtwo-dimensional maps and one-dimensional profiles representa result of convolution of the local dynamic magnetizationamplitude with the instrumental resolution function, resultingin a significant blurring of submicrometer spatial features.
Figure 3(a) shows that the mode at frequency f
0=7 GHz
has a half-sine profile along the major axis, and it does notexhibit any nodal lines. These characteristics indicate that itis the fundamental center mode of the Py dot.
39The profile
of the mode at frequency f1=7.7 GHz [Fig. 3(b)] has two
maxima on the long axis and a minimum at the center of thedot. This minimum is likely associated with the nodal lineof the eigenmode. The BLS intensity does not vanish at theminimum, likely due to the limited spatial resolution of ourtechnique.
The spatial profile of the mode at f
2=8.3 GHz [see
Fig. 3(c)] has a maximum at the center, similar to the
fundamental mode. In contrast to that mode, the profile issharper near the maximum, and it forms two broad shoulderswith small bumps near the edges. As mentioned previously,fine spatial features are blurred due to finite resolution ofthe setup. Therefore, based on our data, the mode with thefrequency f
2can be interpreted as a mode with two nodal
lines separating a central maximum from two side maximalocated on the major axis of the Py ellipse.
The limitations of the spatial resolution of our technique
prevented us from identifying the mode corresponding to thepeak at f
3. This higher-order mode likely has three nodallines. We also performed spatially resolved measurements at
fe=5.5 GHz, which revealed a typical spatial structure of
the so-called edge mode, with maxima of intensity close tothe edges of the dot on the axis parallel to the direction of thestatic field, and a vanishing intensity at the center of the dot.
We note that the mode observed at f
1=7.7 GHz [Fig. 3(b)]
is expected to have odd spatial symmetry, i.e., its amplitudeprofile is antisymmetric with respect to the minor axis ofthe dot. By symmetry, this mode cannot be directly excitedby the usual linear excitation mechanism with a spatiallyuniform dynamic magnetic field. The symmetry of the modeatf
2does not prohibit its linear excitation by a uniform
field, but the excitation efficiency would be significantlysmaller than for the fundamental mode at f
0.40In contrast,
the efficiency of parametric excitation for all these modes issimilar, as indicated by the similar amplitudes of the peaksin Fig. 2(d). Therefore, the parametric excitation mechanism
presents significant advantages compared to linear excitationfor the experimental studies of the eigenmode spectra in micro-and nanomagnets.
C. Dependence of the mode intensities on pumping power
We now analyze and interpret the dependencies of the
parametrically excited mode intensities on the pumping power.Figure 4shows these dependencies for the fundamental mode
(filled triangles), the higher-order mode at f
2(open triangles),
and the edge mode at fe(circles). Both of the center modes
exhibit similar nonmonotonic behavior above their excitationthresholds: The intensities first increase and then start todecrease with further increases in the pumping power. Theintensity of the fundamental mode reaches a minimum atP≈6 mW and then increases again. In contrast, the BLS peak
atf
2becomes indistinguishable from the background at P=
12 mW and does not recover at larger pumping powers. Similarbehaviors were also observed for the higher-order modes atfrequencies f
1andf3.
These data suggest the presence of a mechanism limiting
the energy flow from the parametric pumping to the observed
FIG. 4. (Color online) Dependence of the BLS peak intensity on
pumping power for the fundamental mode at f0(filled triangles), for
the higher-order mode at f2(open triangles), and for the edge mode
atfe(open circles).
094401-3ULRICHS, DEMIDOV , DEMOKRITOV , AND URAZHDIN PHYSICAL REVIEW B 84, 094401 (2011)
modes at large P. Although this mechanism influences all
the observed modes, its effect on the higher-order modesis stronger than on the fundamental mode, leading to theircomplete suppression.
To interpret these behaviors, we recall that because of the
intrinsic anisotropy of the magnetic eigenmode spectrum, thefrequencies of the modes only weakly depend on the numberof nodal lines perpendicular to the magnetization.
41As a
consequence, for each mode with nodal lines parallel to thestatic magnetization (see Fig. 3), there are, generally speaking,
many nearly degenerate modes with a finite number of nodallines perpendicular to the magnetization. For example, atfrequencies f
1–f3, there are a number of exchange-dominated
modes with very short effective wavelengths in the directionparallel to magnetization. These modes cannot be detected bythe BLS technique, which is sensitive predominantly to thelong-wavelength modes.
The exchange-dominated modes are generally character-
ized by stronger damping and weaker coupling to the pumpingfield, and consequently they have larger excitation thresholdscompared to the dipole-dominated modes.
41Therefore, only
the dipole-dominated modes are excited at small P, and, in
this regime, their intensity increases with P.A sPreaches the
threshold value for the excitation of the exchange-dominatedmodes, additional scattering channels become effective thatredistribute the energy among the modes. While the details ofthese processes are presently unknown, one can generally ex-pect that the increase in the amplitudes of exchange-dominatedmagnetization oscillations results in nonlinear scattering of thedipole-dominated oscillations into the short-wavelength partof the mode spectrum, creating additional nonlinear dampingchannels for the dipole-dominated modes. As a result, theflow of energy from the pumping to the dipole-dominatedmodes decreases, leading to a decrease of their intensity and, atsufficiently large pumping power, to the complete suppressionof the dipole-dominated modes.
This suppression mechanism is significantly less efficient
for the fundamental mode, since it has the lowest frequencyamong the center modes, and consequently there are noexchange-dominated modes at the same frequency. Neverthe-less, there are a number of modes with no nodal lines parallel tothe magnetization and several nodal lines perpendicular to themagnetization whose frequency is only slightly different fromthat of the fundamental mode. The onset of their parametricexcitation can be the origin of the decrease in the fundamentalpeak intensity at P>3m W .
These modes are dipole dominated and thus should be
detectable by the BLS measurements. Indeed, the broadeningof the fundamental peak at P>3 mW [compare Fig. 2(a)and
2(c)] and a bump on its declining slope [see Fig. 2(d)] can
be interpreted as a signature of their excitation. In addition,in the interval P=3–8 mW, spatially resolved measurements
revealed deviations of the spatial profile of the mode at f
0
from that shown in Fig. 3(a) forP=10 mW, which can
be associated with simultaneous excitation of several dipole-dominated modes with different spatial profiles. The largestdeviations were observed at P=6 mW, corresponding to the
minimum of the fundamental mode intensity. These deviationsare dramatically reduced at P>10 mW. Based on these data,
one can conclude that, in contrast to the competition betweenthe dipole-dominated and exchange-dominated modes, the
competition among the dipole-dominated modes results in thepredominant energy flow into the fundamental mode of the dotat large P.
Finally, the intensity of the edge mode (circles in Fig. 4)
increases monotonically with increasing P. This behavior is
consistent with the intensity-suppression mechanisms dis-cussed already: since the frequency of the edge mode liesfar below the frequencies of all the other modes of the system,its intensity is not affected by their parametric excitation.
D. Temporal characteristics of parametric excitation
In addition to the significance of parametric excitation
as a spectroscopic tool, it can be used to determine otherimportant dynamical parameters of the magnetic system. Thetime dependence of the excited mode amplitude at differentpumping powers provides information about the magneticdamping constant, the strength of the microwave pumpingfield, and its coupling to the magnetic system (see Sec. IVfor
details).
We performed time-resolved measurements of the fun-
damental mode intensity at pumping powers between thethreshold value of 1 mW and 50 mW, with temporal reso-lution of 1 ns. Figures 5(a) and5(b) show time traces for
P=1mW and 3.2 mW. These data demonstrate that just above
the parametric threshold, the rate of intensity growth is small,but it quickly increases with increasing P.
Plotting the time-dependent intensity of the fundamental
mode on the logarithmic scale, at P=1–4 mW, we observe a
well-defined initial exponential rise followed by saturation, asillustrated in Fig. 5(c)forP=3.2 mW. Fitting this exponential
dependence, we obtain a characteristic rise time constant τas a
function of the pumping power for P<4 mW. At larger powers,
P>4 mW, the intensity growth becomes too abrupt to make
a reliable estimate of τdue to the limited temporal resolution
FIG. 5. (Color online) (a) and (b) Time traces of the fundamental
mode intensity at the labeled values of pumping power; t=0
corresponds to the start of the pumping pulse. (c) Time dependence
of intensity on the logarithmic scale at P=3.2 mW. Line shows
the result of a fit by an exponential function. (d) The inverse of
amplitude rise time constant vs√
P∝h. Line is the best linear fit of
the data.
094401-4PARAMETRIC EXCITATION OF EIGENMODES IN ... PHYSICAL REVIEW B 84, 094401 (2011)
of our measurement. Analysis given in Sec. IVsuggests that
the inverse of the time constant τshould depend linearly on h,
which is proportional to the square root of the pumping power,
h=A√
P. Here, Ais a calibration parameter determined
by the sample geometry and the microwave losses in thetransmission line. As expected, the experimentally determined
values of 1 /τfollow a linear dependence on√
P[Fig. 5(d)].
IV. THEORY
Rigorous understanding of the nonlinear dynamical regimes
in microscopic structures requires a self-consistent theoryof parametric excitation taking into account the effects ofthe inhomogeneity of the internal demagnetizing field andthe magnetization in the sample, as well as the boundaryconditions governing spin-wave quantization. Nevertheless,the theory developed for extended magnetic films
41can still
be used to analyze the behavior of the studied system close tothe threshold of parametric excitation. According to Ref. 41,
the threshold amplitude of the dynamic magnetic field for theonset of parametric excitation is given by
h
th=ωr/V, (1)
where ωr=αω is the relaxation frequency, and V=
γ24πMs[P(k)(1+sin2(ϕ))−1]/(4ω) is a coefficient char-
acterizing the coupling of the pumping field to the planewave with frequency ωand wave vector koriented in the film
plane at an angle ϕwith respect to the direction of the static
magnetization: ϕ=tan
−1(ky/kx). Here, 4 πM sis the saturation
magnetization, and P(k)=1−(1−exp[−kd])/kd, where d
is the film thickness.
To account for the finite lateral dimensions of the dot, we
applied the standard spin-wave quantization scheme.42Within
this approach, the fundamental center mode of the dot isapproximated by a two-dimensional standing spin wave withthe components of the wave vector k
x=π/aandky=π/b,
where a=1000 nm and b=500 nm, which represent the
lateral sizes of the dot in the xandydirections, respectively.
In this approximation, the coupling coefficient is V=1.63×
107(Oe·s)−1.Above the threshold, the amplitude of the parametrically
excited mode is expected to grow exponentially with acharacteristic time constant (see Ch. 5.3 in Ref. 43)
τ=1/(hV−ω
r). (2)
In agreement with this result, the experimental values for
1/τscale linearly with h[Fig. 5(d)]. As follows from Eq. ( 2),
1/τis equal to the relaxation frequency ωrath=0 and
vanishes at h=hth. Fitting the experimental data of Fig. 5(d)
with a linear function and extrapolating to P=0, we obtain
ωr=0.36×109s−1, corresponding to the Gilbert damping
parameter α=0.008, which is in excellent agreement with
the known value for Py.44From the same fit, we also obtain
the threshold power Pth=0.6 mW, corresponding to exact
compensation of the magnetic relaxation by the parametricpumping. Finally, from the slope of the linear dependence, weobtain the calibration factor A=29 Oe/(mW)
1/2. This value is
in reasonable agreement with the estimate A=24 Oe/(mW)1/2
based on the nominal geometrical parameters of the microstrip
line.
V. CONCLUSIONS
In conclusion, we have demonstrated parametric excitation
of spin-wave modes in microscopic magnetic-film structuresat moderate microwave powers. Parametric processes canbe utilized for studies of the eigenmode spectra and otherdynamical characteristics in micro- and nanomagnets. Thelow threshold power for parametric excitation in microscopicsystems enables observation of complex nonlinear phenomenasuch as mode competition and nonlinear parametric reso-nance. Moreover, the low threshold power makes parametricprocesses in microscopic structures useful for technical ap-plications such as parametric amplification of spin waves inintegrated magnonic devices.
ACKNOWLEDGMENTS
We acknowledge support from Deutsche Forschungsge-
meinschaft, the European Project Master (No. NMP-FP7212257), National Science Foundation (NSF) Grant Nos.DMR-0747609 and ECCS-0967195, and the Research Cor-poration.
*henning.ulrichs@uni-muenster.de
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094401-6 |
PhysRevB.78.020404.pdf | Inhomogeneous Gilbert damping from impurities and electron-electron interactions
E. M. Hankiewicz,1,2,*G. Vignale,2and Y. Tserkovnyak3
1Department of Physics, Fordham University, Bronx, New York 10458, USA
2Department of Physics and Astronomy, University of Missouri, Columbia, Missouri 65211, USA
3Department of Physics and Astronomy, University of California, Los Angeles, California 90095, USA
/H20849Received 7 April 2008; revised manuscript received 3 June 2008; published 22 July 2008 /H20850
We present a unified theory of magnetic damping in itinerant electron ferromagnets at order q2including
electron-electron interactions and disorder scattering. We show that the Gilbert damping coefficient can beexpressed in terms of the spin conductivity, leading to a Matthiessen-type formula in which disorder andinteraction contributions are additive. In a weak ferromagnet regime, electron-electron interactions lead to astrong enhancement of the Gilbert damping.
DOI: 10.1103/PhysRevB.78.020404 PACS number /H20849s/H20850: 76.50. /H11001g, 75.45. /H11001j, 75.30.Ds
I. INTRODUCTION
In spite of much effort, a complete theoretical description
of the damping of ferromagnetic spin waves in itinerant elec-tron ferromagnets is not yet available.
1Recent measurements
of the dispersion and damping of spin-wave excitationsdriven by a direct spin-polarized current prove that the the-oretical picture is incomplete, particularly when it comes tocalculating the linewidth of these excitations.
2One of the
most important parameters of the theory is the so-called Gil-bert damping parameter
/H9251,3which controls the damping rate
and thermal noise and is often assumed to be independent ofthe wave vector of the excitations. This assumption is justi-fied for excitations of very long wavelength /H20849e.g., a homoge-
neous precession of the magnetization /H20850, where
/H9251can origi-
nate in a relatively weak spin-orbit /H20849SO/H20850interaction.4
However, it becomes dubious as the wave vector qof the
excitations grows. Indeed, both electron-electron /H20849e-e/H20850and
electron-impurity interactions can cause an inhomogeneous
magnetization to decay into spin-flipped electron-hole pairs,giving rise to a q
2contribution to the Gilbert damping. In
practice, the presence of this contribution means that theLandau-Lifshitz-Gilbert equation contains a term propor-tional to − m/H11003/H11612
2/H11509tm/H20849where mis the magnetization /H20850and
requires neither spin-orbit nor magnetic disorder scattering.In contrast, the homogeneous damping term is of the formm/H11003
/H11509tmand vanishes in the absence of SO or magnetic dis-
order scattering.
The influence of disorder on the linewidth of spin waves
in itinerant electron ferromagnets was discussed in Refs.5–7, and the role of e-einteractions in spin-wave damping
was studied in Refs. 8and9for spin-polarized liquid He
3
and in Refs. 10and11for two- and three-dimensional /H208493D/H20850
electron liquids, respectively. In this Rapid Communication,we present a unified semiphenomenological approach, whichenables us to calculate on equal footing the contributions ofdisorder and e-einteractions to the Gilbert damping param-
eter to order q
2. The main idea is to apply to the transverse
spin fluctuations of a ferromagnet the method first introducedby Mermin
12for treating the effect of disorder on the dynam-
ics of charge-density fluctuations in metals.13Following this
approach, we will show that the q2contribution to the damp-
ing in itinerant electron ferromagnets can be expressed interms of the transverse spin conductivity, which in turn sepa-
rates into a sum of disorder and e-eterms.
A major technical advantage of this approach is that the
ladder vertex corrections to the transverse spin conductivityvanish in the absence of SO interactions, making the dia-grammatic calculation of this quantity a straightforward task.Thus we are able to provide explicit analytic expressions forthe disorder and interaction contribution to the q
2Gilbert
damping to the lowest order in the strength of the interac-tions. This Rapid Communication connects and unifies dif-ferent approaches and gives a rather complete and simpletheory of q
2damping. In particular, we find that for weak
metallic ferromagnets the q2damping can be strongly en-
hanced by e-einteractions, resulting in a value comparable
to or larger than typical in the case of homogeneous damp-ing. Therefore, we believe that the inclusion of a dampingterm proportional to q
2in the phenomenological Landau-
Lifshitz equation of motion for the magnetization14is a po-
tentially important modification of the theory in stronglyinhomogeneous situations, such as current-driven nano-magnets
2and the ferromagnetic domain-wall motion.15,16
II. PHENOMENOLOGICAL APPROACH
In Ref. 12, Mermin constructed the density-density re-
sponse function of an electron gas in the presence of impu-rities through the use of a local drift-diffusion equation,whereby the gradient of the external potential is cancelled, inequilibrium, by an opposite gradient of the local chemicalpotential. In diagrammatic language, the effect of the localchemical potential corresponds to the inclusion of the vertexcorrection in the calculation of the density-density responsefunction. Here, we use a similar approach to obtain the trans-verse spin susceptibility of an itinerant electron ferromagnet,modeled as an electron gas whose equilibrium magnetizationis along the zaxis.
Before proceeding we need to clarify a delicate point. The
homogeneous electron gas is not spontaneously ferromag-netic at the densities that are relevant for ordinary magneticsystems.
13In order to produce the desired equilibrium mag-
netization, we must therefore impose a static fictitious fieldB
0. Physically, B0is the “exchange” field Bexplus any
external/applied magnetic field B0appwhich may be addition-PHYSICAL REVIEW B 78, 020404 /H20849R/H20850/H208492008 /H20850RAPID COMMUNICATIONS
1098-0121/2008/78 /H208492/H20850/020404 /H208494/H20850 ©2008 The American Physical Society 020404-1ally present. Therefore, in order to calculate the transverse
spin susceptibility we must take into account the fact that theexchange field associated with a uniform magnetization isparallel to the magnetization and changes direction when thelatter does. As a result, the actual susceptibility
/H9273ab/H20849q,/H9275/H20850
differs from the susceptibility calculated at constant B0,
which we denote by /H9273˜ab/H20849q,/H9275/H20850, according to the well-known
relation11
/H9273ab−1/H20849q,/H9275/H20850=/H9273˜ab−1/H20849q,/H9275/H20850−/H9275ex
M0/H9254ab. /H208491/H20850
Here, M0is the equilibrium magnetization /H20849assumed to point
along the zaxis /H20850and/H9275ex=/H9253Bex/H20849where /H9253is the gyromagnetic
ratio /H20850is the precession frequency associated with the ex-
change field. /H9254abis the Kronecker delta. The indices aandb
denote directions /H20849xory/H20850perpendicular to the equilibrium
magnetization and qand/H9275are the wave vector and the fre-
quency of the external perturbation. Here we focus solely on
the calculation of the response function /H9273˜because term
/H9275ex/H9254ab/M0does not contribute to Gilbert damping. We do
not include the effects of exchange and external fields on theorbital motion of the electrons.
The generalized continuity equation for the Fourier com-
ponent of the transverse spin density M
ain the direction a/H20849x
ory/H20850at wave vector qand frequency /H9275is
−i/H9275Ma/H20849q,/H9275/H20850=−i/H9253q·ja/H20849q,/H9275/H20850−/H92750/H9280abMb/H20849q,/H9275/H20850
+/H9253M0/H9280abBbapp/H20849q,/H9275/H20850, /H208492/H20850
where Baapp/H20849q,/H9275/H20850is the transverse external magnetic field
driving the magnetization and /H92750is the precessional fre-
quency associated with a static magnetic field B0/H20849including
exchange contribution /H20850in the zdirection. jais the ath com-
ponent of the transverse spin-current-density tensor and weset/H6036=1 throughout. The transverse Levi-Civita tensor
/H9280ab
has components /H9280xx=/H9280yy=0,/H9280xy=−/H9280yx=1, and the summation
over repeated indices is always implied.
The transverse spin current is proportional to the gradient
of the effective magnetic field, which plays the role analo-gous to the electrochemical potential, and the equation thatexpresses this proportionality is the analog of the drift-diffusion equation of the ordinary charge transport theory,
j
a/H20849q,/H9275/H20850=iq/H9268/H11036/H20875/H9253Baapp/H20849q,/H9275/H20850−Ma/H20849q,/H9275/H20850
/H9273˜/H11036/H20876, /H208493/H20850
where /H9268/H11036/H20849=/H9268xxor/H9268yy/H20850is the transverse dc /H20849i.e.,/H9275=0/H20850spin
conductivity and /H9273˜/H11036=M0//H92750is the static transverse spin sus-
ceptibility in the q→0 limit.17Just as in the ordinary drift-
diffusion theory, the first term on the right-hand side of Eq./H208493/H20850is a “drift current” and the second is a “diffusion current,”
with the two canceling out exactly in the static limit /H20849forq
→0/H20850, due to the relation M
a/H208490,0 /H20850=/H9253/H9273˜/H11036Baapp/H208490,0 /H20850. Combin-
ing Eqs. /H208492/H20850and /H208493/H20850gives the following equation for the
transverse magnetization dynamics:/H20873−i/H9275/H9254ab+/H9253/H9268/H11036q2
/H9273˜/H11036/H9254ab+/H92750/H9280ab/H20874Mb
=/H20849M0/H9280ab+/H9253/H9268/H11036q2/H9254ab/H20850/H9253Bbapp, /H208494/H20850
which is most easily solved by transforming to the circularly
polarized components M/H11006=Mx/H11006iMy, in which the Levi-
Civita tensor becomes diagonal, with eigenvalues /H11006i. Solv-
ing in the “+” channel, we get
M+=/H9253/H9273˜+−B+app=M0−i/H9253/H9268/H11036q2
/H92750−/H9275−i/H9253/H9268/H11036q2/H92750/M0/H9253B+app, /H208495/H20850
from which we obtain to the leading order in /H9275andq2
/H9273˜+−/H20849q,/H9275/H20850/H11229M0
/H92750/H208731+/H9275
/H92750/H20874+i/H9275/H9253/H9268/H11036q2
/H927502. /H208496/H20850
The higher-order terms in this expansion cannot be legiti-
mately retained within the accuracy of the present approxi-mation. We also disregard the q
2correction to the static sus-
ceptibility, since in making the Mermin ansatz /H208493/H20850we are
omitting the equilibrium spin currents responsible for thelatter. Equation /H208496/H20850, however, is perfectly adequate for our
purpose, since it allows us to identify the q
2contribution to
the Gilbert damping,
/H9251=/H927502
M0lim
/H9275→0Im/H9273˜+−/H20849q,/H9275/H20850
/H9275=/H9253/H9268/H11036q2
M0. /H208497/H20850
Therefore, the Gilbert damping can be calculated from the dc
transverse spin conductivity /H9268/H11036, which in turn can be com-
puted from the zero-frequency limit of the transverse spin-current–spin-current response function,
/H9268/H11036=−1
m/H115692Vlim
/H9275→0Im/H20855/H20855/H20858i=1NSˆiapˆia;/H20858i=1NSˆiapˆia/H20856/H20856/H9275
/H9275, /H208498/H20850
where Sˆiais the xorycomponent of the spin operator for the
ith electron, pˆiais the corresponding component of the mo-
mentum operator, m/H11569is the effective electron mass, Vis the
system volume, Nis the total electron number, and /H20855/H20855Aˆ;Bˆ/H20856/H20856/H9275
represents the retarded linear-response function for the ex-
pectation value of an observable Aˆunder the action of a field
that couples linearly to an observable Bˆ. Both disorder and
e-einteraction contributions can be systematically included
in the calculation of the spin-current–spin-current responsefunction. In the absence of spin-orbit and e-einteractions,
the ladder vertex corrections to the conductivity are absentand calculation of
/H9268/H11036reduces to the calculation of a single
bubble with Green’s functions,
G↑,↓/H20849p,/H9275/H20850=1
/H9275−/H9255p+/H9255F/H11006/H92750/2+i/2/H9270↑,↓, /H208499/H20850
where the scattering time /H9270sin general depends on the spin
band index s=↑,↓. In the Born approximation, the scattering
rate is proportional to the electron density of states, and wecan write
/H9270↑,↓=/H9270/H9263//H9263↑,↓, where /H9263sis the spin- sdensity of
states and /H9263=/H20849/H9263↑+/H9263↓/H20850/2./H9270parametrizes the strength of theHANKIEWICZ, VIGNALE, AND TSERKOVNYAK PHYSICAL REVIEW B 78, 020404 /H20849R/H20850/H208492008 /H20850RAPID COMMUNICATIONS
020404-2disorder scattering. A standard calculation then leads to the
following result:
/H9268/H11036dis=/H9271F↑2+/H9271F↓2
6/H20849/H9263↓−1+/H9263↑−1/H208501
/H927502/H9270. /H2084910/H20850
This, inserted in Eq. /H208497/H20850, gives a Gilbert damping param-
eter in full agreement with what we have also calculatedfrom a direct diagrammatic evaluation of the transverse spinsusceptibility, i.e., spin-density–spin-density correlationfunction. From now on, we shall simplify the notation byintroducing a transverse spin-relaxation time,
1
/H9270/H11036dis=4EF↑+EF↓
3n/H20849/H9263↓−1+/H9263↑−1/H208501
/H9270, /H2084911/H20850
where EFs=m/H11569/H9271Fs2/2 is the Fermi energy for spin- selectrons
andnis the total electron density. In this notation, the dc
transverse spin conductivity takes the form
/H9268/H11036dis=n
4m/H11569/H9275021
/H9270/H11036dis. /H2084912/H20850
III. ELECTRON-ELECTRON INTERACTIONS
One of the attractive features of the approach based on
Eq. /H208498/H20850is the ease with which e-einteractions can be in-
cluded. In the weak-coupling limit, the contributions of dis-order and e-einteractions to the transverse spin conductivity
are simply additive. We can see this by using twice the equa-tion of motion for the spin-current–spin-current responsefunction. This leads to an expression for the transverse spinconductivity /H20851Eq. /H208498/H20850/H20852in terms of the low-frequency spin-
force–spin-force response function,
/H9268/H11036=−1
m/H115692/H927502Vlim
/H9275→0Im/H20855/H20855/H20858iSˆiaFˆia;/H20858iSˆiaFˆia/H20856/H20856/H9275
/H9275./H2084913/H20850
Here, Fˆia=pˆ˙iais the time derivative of the momentum opera-
tor, i.e., the operator of the force on the ith electron. The total
force is the sum of electron-impurity and e-einteraction
forces. Each of them, separately, gives a contribution of or-der /H20841
vei/H208412and /H20841vee/H208412, where veiandveeare matrix elements of
the electron-impurity and e-einteractions, respectively, while
cross terms are of higher order, e.g., vee/H20841vei/H208412. Thus, the two
interactions give additive contributions to the conductivity.In Ref. 18, a phenomenological equation of motion was used
to find the spin current in a system with disorder and longi-tudinal spin-Coulomb drag coefficient. We can use a similarapproach to obtain transverse spin currents with transverse
spin-Coulomb drag coefficient 1 /
/H9270/H11036ee. In the circularly polar-
ized basis,
i/H20849/H9275/H11007/H92750/H20850j/H11006=−nE/H11006
4m/H11569+j/H11006
/H9270/H11036dis+j/H11006
/H9270/H11036ee, /H2084914/H20850
and correspondingly the spin conductivities are
/H9268/H11006=n
4m/H115691
−/H20849/H9275/H11007/H92750/H20850i+1 //H9270/H11036dis+1 //H9270/H11036ee. /H2084915/H20850
In the dc limit, this gives/H9268/H11036/H208490/H20850=/H9268++/H9268−
2=n
4m/H115691//H9270/H11036dis+1 //H9270/H11036ee
/H927502+/H208491//H9270/H11036dis+1 //H9270/H11036ee/H208502. /H2084916/H20850
Using Eq. /H2084916/H20850, an identification of the e-econtribution is
possible in a perturbative regime where 1 //H9270/H11036eeand 1 //H9270/H11036dis
/H11270/H92750, leading to the following formula:
/H9268/H11036=n
4m/H11569/H927502/H208731
/H9270/H11036dis+1
/H9270/H11036ee/H20874. /H2084917/H20850
Comparison with Eq. /H2084913/H20850enables us to immediately
identify the microscopic expressions for the two scatteringrates. For the disorder contribution, we recover what we al-ready knew, i.e., Eq. /H2084911/H20850. For the e-einteraction contribu-
tion, we obtain
1
/H9270/H11036ee=−4
nm/H11569Vlim
/H9275→0Im/H20855/H20855/H20858iSˆiaFˆ
iaC;/H20858iSˆiaFˆ
iaC/H20856/H20856/H9275
/H9275,/H2084918/H20850
where FCis just the Coulomb force, and the force-force cor-
relation function is evaluated in the absence of disorder. Thecorrelation function in Eq. /H2084918/H20850is proportional to the func-
tionF
+−/H20849/H9275/H20850which appeared in Ref. 11/H20851Eqs. /H2084918/H20850and /H2084919/H20850/H20852in
a direct calculation of the transverse spin susceptibility. Mak-ing use of the analytic result for ImF
+−/H20849/H9275/H20850presented in
Eqs. /H2084921/H20850and /H2084924/H20850of that paper we obtain
1
/H9270/H11036ee=/H9003/H20849p/H208508/H92510
27T2rs4m/H11569a/H115692kB2
/H208491+p/H208501/3, /H2084919/H20850
where Tis the temperature, p=/H20849n↑−n↓/H20850/nis the degree of
spin polarization, a/H11569is the effective Bohr radius, rsis the
dimensionless Wigner-Seitz radius, /H92510=/H208494/9/H9266/H208501/3, and
/H9003/H20849p/H20850—a dimensionless function of the polarization p—is de-
fined by Eq. /H2084923/H20850of Ref. 11. This result is valid to second
order in the Coulomb interaction. Collecting our results, wefinally obtain a full expression for the q
2Gilbert damping
parameter,
/H9251=/H9253nq2
4m/H11569M01//H9270/H11036dis+1 //H9270/H11036ee
/H927502+/H208491//H9270/H11036dis+1 //H9270/H11036ee/H208502. /H2084920/H20850
One of the salient features of Eq. /H2084920/H20850is that it scales as the
total scattering ratein the weak disorder and e-einteraction
limit, while it scales as the scattering time in the opposite
limit. The approximate formula for the Gilbert damping inthe more interesting weak-scattering/strong-ferromagnet re-gime is
/H9251=/H9253nq2
4m/H11569/H927502M0/H208731
/H9270/H11036dis+1
/H9270/H11036ee/H20874, /H2084921/H20850
while in the opposite limit, i.e., for /H92750/H112701//H9270/H11036dis,1 //H9270/H11036ee,
/H9251=/H9253nq2
4m/H11569M0/H208731
/H9270/H11036dis+1
/H9270/H11036ee/H20874−1
. /H2084922/H20850
Equation /H2084920/H20850agrees with the result of Singh and Tesanovic6
on the spin-wave linewidth as a function of the disorder
strength and /H92750. However, Eq. /H2084920/H20850also describes the influ-
ence of e-ecorrelations on the Gilbert damping. A compari-
son of the scattering rates originating from disorder and e-eINHOMOGENEOUS GILBERT DAMPING FROM IMPURITIES … PHYSICAL REVIEW B 78, 020404 /H20849R/H20850/H208492008 /H20850RAPID COMMUNICATIONS
020404-3interactions shows that the latter is important and can be
comparable or even greater than the disorder contribution forhigh-mobility and/or low-density 3D metallic samples. Fig-ure1shows the behavior of the Gilbert damping as a func-
tion of the disorder scattering rate. One can see that the e-e
scattering strongly enhances the Gilbert damping for smallpolarizations/weak ferromagnets /H20851see the red /H20849solid /H20850line /H20852.
This stems from the fact that 1 /
/H9270/H11036disis proportional to 1 //H9270and
independent of polarization for small polarizations, while
1//H9270/H11036eeis enhanced by a large prefactor /H9003/H20849p/H20850=2/H9261//H208491−/H92612/H20850
+/H208491/2/H20850ln/H20851/H208491+/H9261/H20850//H208491−/H9261/H20850/H20852, where /H9261=/H208491−p/H208501/3//H208491+p/H208501/3.O n
the other hand, for strong polarizations /H20849dotted and dash-
dotted lines in Fig. 1/H20850, the disorder dominates in a broad
range of 1 //H9270and the inhomogenous contribution to the Gil-
bert damping is rather small. Finally, we note that our calcu-lation of the e-einteraction contribution to the Gilbert damp-ing is valid under the assumption of /H6036
/H9275/H11270kBT/H20849which is
certainly the case if /H9275=0/H20850. More generally, as follows from
Eqs. /H2084921/H20850and /H2084922/H20850of Ref. 11, a finite frequency /H9275can be
included through the replacement /H208492/H9266kBT/H208502→/H208492/H9266kBT/H208502
+/H20849/H6036/H9275/H208502in Eq. /H2084919/H20850. Thus 1 //H9270/H11036eeis proportional to the scatter-
ing rate of quasiparticles near the Fermi level, and our damp-ing constant in the clean limit becomes qualitatively similarto the damping parameter obtained by Mineev
9for/H9275corre-
sponding to the spin-wave resonance condition in some ex-ternal magnetic field /H20849which in practice is much smaller than
the ferromagnetic exchange splitting
/H92750/H20850.
IV. SUMMARY
We have presented a unified theory of the Gilbert damp-
ing in itinerant electron ferromagnets at the order q2, includ-
inge-einteractions and disorder on equal footing. For the
inhomogeneous dynamics /H20849q/HS110050/H20850, these processes add to a
q=0 damping contribution that is governed by magnetic dis-
order and/or spin-orbit interactions. We have shown that thecalculation of the Gilbert damping can be formulated in thelanguage of the spin conductivity, which takes an intuitiveMatthiessen form with the disorder and interaction contribu-tions being simply additive. It is still a common practice,e.g., in the micromagnetic calculations of spin-wave disper-sions and linewidths, to use a Gilbert damping parameterindependent of q. However, such calculations are often at
odds with experiments on the quantitative side, particularlywhere the linewidth is concerned.
2We suggest that the inclu-
sion of the q2damping /H20849as well as the associated magnetic
noise /H20850may help in reconciling theoretical calculations with
experiments.
ACKNOWLEDGMENTS
This work was supported in part by the NSF under
Grants No. DMR-0313681 and No. DMR-0705460 as wellas Fordham Research Grant. Y.T. thanks A. Brataas andG. E. W. Bauer for useful discussions.
*hankiewicz@fordham.edu
1Y. Tserkovnyak, A. Brataas, G. E. Bauer, and B. I. Halperin,
Rev. Mod. Phys. 77, 1375 /H208492005 /H20850.
2I. N. Krivorotov, D. V. Berkov, N. L. Gorn, N. C. Emley, J. C.
Sankey, D. C. Ralph, and R. A. Buhrman, Phys. Rev. B 76,
024418 /H208492007 /H20850.
3T. L. Gilbert, IEEE Trans. Magn. 40, 3443 /H208492004 /H20850.
4E. M. Hankiewicz, G. Vignale, and Y. Tserkovnyak, Phys. Rev.
B75, 174434 /H208492007 /H20850.
5A. Singh, Phys. Rev. B 39, 505 /H208491989 /H20850.
6A. Singh and Z. Tesanovic, Phys. Rev. B 39, 7284 /H208491989 /H20850.
7V. L. Safonov and H. N. Bertram, Phys. Rev. B 61, R14893
/H208492000 /H20850.
8V. P. Silin, Sov. Phys. JETP 6, 945 /H208491958 /H20850.
9V. P. Mineev, Phys. Rev. B 69, 144429 /H208492004 /H20850.
10Y. Takahashi, K. Shizume, and N. Masuhara, Phys. Rev. B 60,
4856 /H208491999 /H20850.
11Z. Qian and G. Vignale, Phys. Rev. Lett. 88, 056404 /H208492002 /H20850.12N. D. Mermin, Phys. Rev. B 1, 2362 /H208491970 /H20850.
13G. F. Giuliani and G. Vignale, Quantum Theory of the Electron
Liquid /H20849Cambridge University Press, Cambridge, UK, 2005 /H20850.
14E. M. Lifshitz and L. P. Pitaevskii, Statistical Physics, Part 2 ,
Course of Theoretical Physics Vol. 9, 3rd ed. /H20849Pergamon, Ox-
ford, 1980 /H20850.
15Y. Tserkovnyak, A. Brataas, and G. E. Bauer, J. Magn. Magn.
Mater. 320, 1282 /H208492008 /H20850, and references therein.
16In ferromagnets which nonuniformities are beyond the linearized
spin waves, there is a nonlinear q2contribution to damping /H20851see
J. Foros, A. Brataas, Y. Tserkovnyak, and G. E. W. Bauer,arXiv:0803.2175 /H20849unpublished /H20850/H20852which has a different physical
origin, related to the longitudinal spin-current fluctuations.
17Although both /H9268/H11036and/H9273˜/H11036are in principle tensors in transverse
spin space, they are proportional to /H9254abin axially symmetric
systems; hence we use scalar notation.
18I. D’Amico and G. Vignale, Phys. Rev. B 62, 4853 /H208492000 /H20850.FIG. 1. /H20849Color online /H20850The Gilbert damping /H9251as a function of
the disorder scattering rate 1 //H9270. The red /H20849solid /H20850line shows the Gil-
bert damping for polarization p=0.1 in the presence of the e-eand
disorder scattering, while the dashed line does not include thee-escattering. The blue /H20849dotted /H20850and black /H20849dash-dotted /H20850lines
show Gilbert damping for p=0.5 and p=0.99, respectively. We
took q=0.1 k
F,T=54 K, /H92750=EF/H20851/H208491+p/H208502/3−/H208491−p/H208502/3/H20852,M0=/H9253pn /2,
m/H11569=me,n=1.4/H110031021cm−3,rs=5, and a/H11569=2a0.HANKIEWICZ, VIGNALE, AND TSERKOVNYAK PHYSICAL REVIEW B 78, 020404 /H20849R/H20850/H208492008 /H20850RAPID COMMUNICATIONS
020404-4 |
PhysRevB.87.174409.pdf | PHYSICAL REVIEW B 87, 174409 (2013)
Spin-transfer torques in helimagnets
Kjetil M. D. Hals and Arne Brataas
Department of Physics, Norwegian University of Science and Technology, NO-7491 Trondheim, Norway
(Received 24 March 2013; published 6 May 2013)
We theoretically investigate current-induced magnetization dynamics in chiral-lattice helimagnets. Spin-orbit
coupling in noncentrosymmetric crystals induces a reactive spin-transfer torque that has not been previouslyconsidered. We demonstrate how the torque is governed by the crystal symmetry and acts as an effectivemagnetic field along the current direction in cubic B20-type crystals. The effects of the new torque are computedfor current-induced dynamics of spin spirals and the Doppler shift of spin waves. In current-induced spin-spiralmotion, the new torque tilts the spiral structure. The spin waves of the spiral structure are initially displaced bythe new torque, while the dispersion relation is unaffected.
DOI: 10.1103/PhysRevB.87.174409 PACS number(s): 75 .78.−n, 75.60.Jk, 75.70.Tj, 75.70.Kw
I. INTRODUCTION
Current-induced magnetization dynamics continue to be a
very active research area due to potential applications in futureelectronic devices. In metallic ferromagnets, the magnetizationcan be manipulated via the spin-transfer torque (STT), whicharises due to a misalignment between the spin polarizationof the current and the local magnetization direction.
1,2Slon-
czewski and Berger were the first to predict the existence ofthe STT effect,
3,4which was later demonstrated in several
experiments.1,2The anticipated application potential of the
STT effect lies in the development of electromagnetic devicesthat utilize a current-induced torque instead of externalmagnetic fields to manipulate the magnetization.
2
The magnetization dynamics of an itinerant ferromagnet
is described by the Landau-Lifshitz-Gilbert (LLG) equationextended to include the current-induced torques:
2,5
˙m=−γm×Heff+αm×˙m+τ. (1)
Here, m=M/Ms(Ms=|M|) is the unit direction vector
of the magnetization M,Heff=−δF/δ Mis the effective
field found by varying the free energy F[M] with respect
to the magnetization, αis the Gilbert damping coefficient,
γis (minus) the gyromagnetic ratio, and τdescribes the
current-induced torques. In the absence of intrinsic spin-orbitcoupling (SOC), the torque becomes τ=τ
ex:2
τex=− (1−βm×)(vs·∇)m. (2)
In Eq. (2), the first term is the adiabatic torque, while the
second term (parametrized by β) is the nonadiabatic torque.
The vector vsis proportional to the current density Jand
its polarization P:vs=− ¯hPJ/2es0. Here, s0is the total
equilibrium spin density along −m, and eis the electron
charge. The torque in Eq. (2)treats the ferromagnet within
the exchange approximation, which assumes that the exchangeforces only depend on the relative orientation of the spins. Thisassumption is believed to be valid in metallic ferromagnets,including disordered systems in which impurities couple to thespin degree of freedom through random magnetic moments orspin-orbit coupling. In this case, impurity averaging restoresthe spin-rotational symmetry of the system. Recently, insystems with a broken spatial inversion symmetry, the intrinsicSOC in combination with an external electric field havebeen observed to induce an additional torque, such thatτ=τ
ex+τso.6–10In general, the SOC-induced torque τso
can be written as6,9,10
τso=−γm×Hso, (3)
where the SOC field Hsois proportional to the electric field and
its orientation is determined by the symmetry of the underlyingcrystal lattice and the direction of the external electric field.Therefore, in contrast to τ
ex, which vanishes in a homogeneous
ferromagnet, τsois finite even in this case. Several experiments
have demonstrated that the SOC torque plays an important rolein magnetization dynamics.
7,8The underlying physics of the
torque is that the SOC effectively acts as a magnetic field onthe spins of the itinerant quasiparticles when an electric fieldis applied to the system. The effective magnetic field inducesan out-of-equilibrium spin density that yields a torque on themagnetization.
6,7
In chiral magnets, the exchange interaction also contains
an anisotropic term known as the Dzyaloshinskii-Moriya(DM) interaction.
11,12The DM interaction arises due to the
characteristic crystalline asymmetry of the chiral magnet incombination with the SOC, and in cubic B20-type crystals, itleads to the formation of a spin spiral in the magnetic groundstate. We refer to these systems as helimagnets. Helimagnetshave recently attracted substantial interest because topologicalnontrivial spin structures, known as skyrmions, have beenobserved in such systems under the application of weakexternal magnetic fields.
13–19Current-induced responses of
the formed skyrmion lattice to current densities that areover five orders of magnitude smaller than those typicallyobserved in conventional ferromagnetic metals have recentlybeen observed experimentally.
20,21To understand this striking
feature of helimagnets, numerical simulations and a col-lective coordinate description have been applied to studythe current-induced dynamics of spin spirals and skyrmionlattices.
22–24However, an important aspect of helimagnets is
the absence of spatial inversion symmetry, which implies thatthe magnetization experiences a SOC-induced torque given byEq.(3).
In the present paper, we derive the form of the torque in
Eq.(3)for cubic noncentrosymmetric (B20-type) compounds.
An important example of such a system is the chiral itinerant-electron magnet MnSi, which was the first system in whicha two-dimensional lattice of skyrmions was observed. The
174409-1 1098-0121/2013/87(17)/174409(5) ©2013 American Physical SocietyKJETIL M. D. HALS AND ARNE BRATAAS PHYSICAL REVIEW B 87, 174409 (2013)
effects of the SOC torque are studied for two different cases:
current-induced spin-spiral dynamics and the Doppler shift ofmagnons that propagates along the spiral structure. We observethat for current-induced spin-spiral motion, the new torqueyields an enhanced tilting of the spiral structure, while thetorque does not affect the Doppler shift of spin waves exceptto induce an initial translation of the spiral structure. We alsobriefly discuss the effect of the SOC torque on the skyrmionlattice dynamics.
This paper is organized in the following manner. Section II
provides a derivation of the SOC torque in Eq. (3)for cubic
B20-type crystals. Section IIIdiscusses the effects of the SOC
torque on current-induced spin-spiral motion and the Dopplershift of spin waves that propagates along the spin spiral. Weconclude and summarize our results in Sec. IV.
II. DERIV ATION OF THE SOC TORQUE
In deriving the explicit form of the torque in Eq. (3),
we are guided by the Onsager reciprocity relations andNeumann’s principle. Consider a system described by theparameters {q
i|i=1,..., N }for which the rate of change ˙qiis
induced by the thermodynamic forces fi≡−∂F/∂q i, where
F(q1,..., q N) is the free energy. Onsager’s theorem states that
the response coefficients in the equations ˙qi=/summationtextN
j=1Lijfj
are related by Lij(H,m)=/epsilon1i/epsilon1jLji(−H,−m), where /epsilon1i=1
(/epsilon1i=− 1) ifqiis even (odd) under time reversal.25mand
Hrepresent any possible equilibrium magnetic order and an
external magnetic field, respectively. In the present paper, theresponses of the itinerant ferromagnet are described by thetime derivative of the unit vector along the magnetizationdirection, ˙m, and the charge current density J. The associated
thermodynamic forces are the effective field scaled with themagnetization, f
m=MsHeff, and the electric field, fq=E,
respectively, and the equations describing the dynamics in thelinear response regime are determined by
/parenleftbigg˙m
J/parenrightbigg
=/parenleftbiggL
mm Lmq
Lqm Lqq/parenrightbigg/parenleftbiggfm
fq/parenrightbigg
. (4)
The Onsager reciprocity relations imply that Lmiqj(m)=
−Lqjmi(−m). In addition to the symmetry requirements
imposed by the reciprocity relations, the symmetry of theunderlying lattice structure also decreases the number ofindependent tensor components. This fact is expressed byNeumann’s principle, which states that a tensor representingany physical property should be invariant with respect to everysymmetry operation of the crystal’s point group.
25
According to Eq. (4), the effect reciprocal to the adiabatic
and nonadiabatic torque in Eq. (2)is a charge current density
induced by a time-dependent magnetic texture. To the lowestorder in the texture gradients and the precession frequency, theinduced charge current density in the exchange approximationis
26
Jex
i=¯h
2eσP/parenleftbigg
m×∂m
∂ri−β∂m
∂ri/parenrightbigg
·˙m. (5)
Here, eis the electron charge, Pis the spin polarization
of the current, σis the conductivity, and riis component i
of the spatial vector. Because the exchange approximationneglects any coupling (via intrinsic SOC) of the spins to thecrystal structure, the above expression is fully spin-rotationally
symmetric and a textured magnetization, i.e., ∂m/∂r
i/negationslash=0, is
required to have a coupling between the momentum of theitinerant quasiparticles and the magnetization. If the effects ofintrinsic SOC are considered, additional terms are allowed bysymmetry in the phenomenological expansion for the pumpedcurrent. In particular, for inversion symmetry-breaking SOC,a homogenous magnetization pumps a charge current. To thelowest order in SOC and precession frequency, the expressionfor the pumped current then becomes
J
pump
i=ηij˙mj+Jex
i. (6)
The second-rank tensor ηijis an axial tensor because the
current is a polar vector while the magnetization is anaxial vector. η
ijis linear in the SOC coupling and vanishes
in systems with spatial inversion symmetry. According toNeumann’s principle, the particular form of η
ijis governed
by the crystal structure and is determined by the following setof equations produced by the generating matrices [ R
ij]o ft h e
crystal’s point group:25
ηij=|R|RinRjmηnm. (7)
Here,|R|is the determinant of the matrix [ Rij].
Let us now consider a cubic B20-type crystal. Its crystal
structure belongs to the noncentrosymmetric space groupP2
13, which has the cubic point group T. Common examples
of cubic B20-type chiral magnets are MnSi, FeGe, and(Fe,Co)Si. From the symmetry relations in Eq. (7), one then
finds that the tensor η
ijis proportional to the unit matrix:25
ηij=ηδij, (8)
where δijis the Kronecker delta. The tensor is isotropic
because the high symmetry of the cubic crystal reduces thenumber of independent tensor coefficients to the single param-eterη. Substituting this tensor into Eq. (6)and expressing the
time derivative of the magnetization in terms of the effectivefield by applying the first term on the right-hand side of Eq. (1),
one obtains the response matrix:
27
Lqimj=−γη
Ms/epsilon1ikjmk+Lex
qimj. (9)
Here,Lex
qimjare the response coefficients describing the process
reciprocal to the STT in Eq. (2), which have been previously
derived in Ref. 26. The term proportional to ηdescribes the
process reciprocal to the SOC-induced torque in Eq. (3).U s i n g
the Onsager reciprocity relations, we find that the SOC fieldtakes the following form:
H
so=ηsovs, (10)
where ηso=(2ηes 0)/(¯hσPM s). Thus, the torque induced by
the SOC in noncentrosymmetric cubic magnets acts as aneffective magnetic field along the current direction. Note thatthe torque is reactive because it does not break the time reversalsymmetry of the LLG equation.
III. RESULTS AND DISCUSSION
In the following, we investigate the effects of the SOC
torque on current-driven spin-spiral motion and the Dopplershift of spin waves. Additionally, a brief discussion of how we
174409-2SPIN-TRANSFER TORQUES IN HELIMAGNETS PHYSICAL REVIEW B 87, 174409 (2013)
expect the torque to affect the skyrmion crystal dynamics is
presented.
A. Spin-spiral motion
To the lowest order in the magnetic texture gradients,
the free energy density of a ferromagnet with broken spatialinversion symmetry can be written phenomenologically as:
28
F(m)=Jij
2∂m
∂ri·∂m
∂rj+Dijkmi∂mj
∂rk. (11)
Here, Jijis the spin stiffness describing the exchange inter-
action between neighboring magnetic moments, and the termproportional to D
ijkis the DM interaction. In Eq. (11) (and
in what follows), summation over repeated indices is implied.The explicit form of the tensors J
ijandDijkis determined by
the crystal symmetry.
In cubic B20-type ferromagnets, the free energy density
becomes
F(m)=J
2∂m
∂ri·∂m
∂ri+Dm·(∇×m). (12)
The free energy of the system, F[m]=/integraltext
drF, is minimized
by a helical magnetic order, where the wave vector of thespiral structure is determined by the ratio between the DMparameter and the spin stiffness, k=D/J .F o ra kvector
that points along the zaxis, the magnetic order of the ground
state is
m
0(z)=cos(kz)ˆx+sin(kz)ˆy, (13)
where ˆxand ˆyare the unit direction vectors along the xandy
axes, respectively.
The action functional S[m] and the dissipation functional
R[˙m] of the system are written as29,30
S[m]=/integraldisplay
dtdrAi(˙mi+vs·∇mi)+γ
MsF(m)−γm·Hso,
(14)
R[˙m]=/integraldisplay
dtdrα
2/parenleftbigg
˙m+β
αvs·∇m/parenrightbigg2
. (15)
Here, A(m) is the Berry phase vector potential of a magnetic
monopole, which satisfies /epsilon1ijk∂Ak/∂m j=mi[/epsilon1ijkis the Levi-
Civita tensor]. The LLG equation in Eq. (1), with τ=τex+
τso, is determined by
δS
δm=−δR
δ˙m. (16)
A previous study on spin-spiral motion demonstrated that
the response of the structure to an applied current (along z) can
be described by the tilting angle ξand drift velocity ˙ζof the
spiral structure.22To find an approximate solution of Eq. (16),
we therefore employ the following variational ansatz:
m(z,t)=cos[ξ(t)]m0[z−ζ(t)]+sin[ξ(t)]ˆz. (17)
Substitution of this ansatz into Eqs. (14) and (15) and
integration over the spatial coordinates yield an effective actionand dissipation functional for the variational parameters ξ(t)andζ(t):
S[ζ,ξ]=/integraldisplay
dt(˙ζ−v
s)ksinξ
+γ
Ms/parenleftbiggJ
2k2cos2ξ−Dkcos2ξ/parenrightbigg
−γH sosinξ,
(18)
R[˙ζ,˙ξ]=/integraldisplay
dtα
2/bracketleftBigg
˙ξ2+/parenleftbiggβ
αvsk−k˙ζ/parenrightbigg2/bracketrightBigg
. (19)
The equations of motion for the variational parameters are
δS[ζ,ξ]
δζ=−δR[˙ζ,˙ξ]
δ˙ζ,δS[ζ,ξ]
δξ=−δR[˙ζ,˙ξ]
δ˙ξ.(20)
We are interested in the steady-state regime in which ξ
approaches a constant value. In this regime, the drift velocityand the tilting angle are
˙ζ=β
αvs, (21)
sin(ξ)=Ms
γ1
Jk−2D/bracketleftbigg/parenleftbiggβ
α−1/parenrightbigg
vs−γ
kHso/bracketrightbigg
.(22)
The expression for the drift velocity ˙ζagrees with the
expression derived in Ref. 22. The SOC torque does not affect
the drift velocity because the SOC torque effectively actssimilarly to the adiabatic torque, as can be observed from theexpression for the action S[ζ,ξ]i nE q . (18). The adiabatic and
SOC torques initiate a spiral motion when a current is applied.However, the motion is damped due to the intrinsic pinningeffect caused by Gilbert damping in combination with theDM interaction. Thus, similar to what is observed for domainwalls in conventional ferromagnets, a nonadiabatic torque isrequired to obtain a steady-state spiral motion. An observableeffect of the SOC torque is the modification of the tilting angleobserved in Ref. 22by an amount of −M
sHso/(Jk2−2Dk).
B. Doppler shift of spin waves
In ferromagnets with a homogeneous magnetization, a
Doppler shift in the spin-wave dispersion relation under theapplication of a current has been observed.
31The frequency ω
of the spin wave is shifted by vs·q, where qis the wave vector
of the magnon: ω=(γJ/M s)q2+vs·q.
Theoretical works on Goldstone modes in helimagnets
with a spin spiral predict that these modes are much morecomplicated than those in homogeneous ferromagnets.
32We
refer to these Goldstone modes as helimagnons. The dispersionrelation of the helimagnons is highly anisotropic, with a linearwave-vector dependency parallel to the spin-spiral directionand a quadratic dependency in the transverse direction (in thelong wavelength limit). That is, the soft modes behave like an-tiferromagnetic magnons along the spiral, while ferromagneticbehavior is observed for modes propagating in the transverseplane. Thus far, no works have studied the effect of an appliedcurrent on the dispersion relation of helimagnons.
To derive an effective action for the Goldstone modes,
we describe the local fluctuations by ξandζin Eq. (17)
by allowing the parameters to be both position and timedependent: ξ=ξ(r,t) andζ=ζ(r,t). A similar parametriza-
tion was performed in Refs. 32and 33in the analysis of
174409-3KJETIL M. D. HALS AND ARNE BRATAAS PHYSICAL REVIEW B 87, 174409 (2013)
helimagnons. The parameter ζdescribes a local twist (around
thezaxis) of the spiral structure, while ξdescribes a local
tilting along the zaxis. In the analysis of the Doppler shift,
we neglect dissipation and disregard the dissipation function.Reference 33demonstrated that simple closed-form solutions
for the variational parameters can only be obtained for modespropagating along the spin-spiral direction. For simplicity, wetherefore restrict our study to Goldstone modes that propagatealong the zaxis. Expanding Eq. (14) to second order in ξ(z,t)
andζ(z,t), we obtain the effective action (the current is applied
along the zaxis):
S[ξ,ζ]=/integraldisplay
dtdzkξ/parenleftbigg
˙ζ+v
s∂ζ
∂z−vs/parenrightbigg
+γJ
2Ms/bracketleftBigg/parenleftbigg∂ξ
∂z/parenrightbigg2
+k2/parenleftbigg∂ζ
∂z/parenrightbigg2
+k2ξ2/bracketrightBigg
−γH soξ.
(23)
The equations of motion are obtained by varying the action
with respect to ξandζ, i.e.,δS/δζ =δS/δξ =0, which results
in two coupled equations for the variational parameters:
˙ζ(z,t)+vs∂ζ(z,t)
∂z
=−γJ
kMs/parenleftbigg
k2−∂2
∂z2/parenrightbigg
ξ(z,t)+vs+γ
kHso,(24)
˙ξ(z,t)+vs∂ξ(z,t)
∂z=−γJk
Ms∂2ζ(z,t)
∂z2. (25)
Let us first consider the homogenous part of the equations
and neglect the two last terms on the right-hand side in
Eq. (24). Substitution of a plane wave ansatz of the form
[ζ0ξ0]Texp(i(qz−ωt))into the equations yields the follow-
ing dispersion relation:
ω=γJ
Msq/radicalbig
k2+q2+vsq. (26)
We see that the STT results in a Doppler shift similar to what
is observed for spin waves in conventional ferromagnets. Inthe long wavelength limit, q→0, a linear dispersion relation
is obtained: ω=(γJ/M
s)kq+vsq. The SOC-induced torque
only appears as a source term in the nonhomogeneous equa-tions. The particular solution (PS) of the nonhomogeneousequations in Eqs. (24) and(25) is
/parenleftbiggζ(z,t)
ξ(z,t)/parenrightbigg
PS=/parenleftBigg
[vs+(γ/k)Hso]t
0/parenrightBigg
. (27)
This solution describes a displacement of the spiral structure
induced by the adiabatic and SOC torques. However, thiscurrent-driven spin-spiral motion is damped when dissipationis considered due to the intrinsic pinning effect. Thus, theSOC torque (together with the adiabatic torque) only causesan initial translation of the spin spiral.C. Skyrmion crystal dynamics
In helimagnetic thin-film systems, skyrmions have been
observed under the application of a weak external magneticfield Bperpendicular to the thin film. Each skyrmion has
a vortexlike magnetic configuration, where the magneticmoment at the core of the vortex is antiparallel to the appliedfield while the peripheral magnetic moments are parallel.From the peripheral moments to the core, the magneticmoments swirl up in a counterclockwise or clockwise manner.The formed skyrmions arrange themselves in a crystallinestructure, a two-dimensional skyrmion crystal.
Recent experiments have revealed current-driven skyrmion
crystal motion at ultralow current densities.
20T h em o t i o no fa
skyrmion lattice is only weakly affected by pinning, which is instark contrast to observations for current-induced domain walldynamics in conventional ferromagnets. A theoretical workhas indicated that the pinning-free motion arises because theskyrmion lattice rotates and deforms to avoid the impurities.
24
However, all analyses of current-driven skyrmion crystalmotion have disregarded the SOC torque.
Section IIshowed that the SOC torque acts as an effective
field along the current direction. For a current applied alongany direction in the thin film, the expected consequence ofthe SOC torque is therefore that this torque leads to a smallcorrection to the external magnetic field that stabilizes the two-dimensional skyrmion lattice such that the total field becomesH
T=B+Hso. The expected response of the skyrmion crystal
to this perturbation is a rotation of the two-dimensional(2D) lattice structure that aligns the core magnetic momentsantiparallel to H
T. To confirm our predictions, a more thorough
numerical simulation of the magnetic system is required,which is beyond the scope of the present paper.
IV . SUMMARY
In this paper, we performed a theoretical study of current-
induced torques in cubic noncentrosymmetric helimagnets. Wedemonstrated that due to the broken spatial inversion symme-try, the SOC induces a reactive magnetization torque. The spe-cific form of the SOC torque is determined by the symmetry ofthe underlying crystal lattice and acts as an effective magneticfield along the current direction in B20-type chiral magnets.
The consequences of the SOC torque are studied for
two different cases: current-induced spin-spiral motion andthe Doppler shift of helimagnons. During the current-drivenspin-spiral motion, the SOC torque yields an enhanced tiltingof the spin-spiral structure, while the velocity is not affected.The dispersion relation of a helimagnon that propagates alongthe axis of the spin spiral is not affected by the SOC torqueexcept to induce an initial translation of the spiral structure.
ACKNOWLEDGMENTS
This work was supported by EU-ICT-7 Contract No.
257159 “MACALO.”
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174409-5 |
PhysRevB.78.064429.pdf | Calculation of current-induced torque from spin continuity equation
Gen Tatara1and Peter Entel2
1Department of Physics, Tokyo Metropolitan University, Hachioji, Tokyo 192-0397, Japan
2Physics Department, University of Duisburg-Essen, 47048 Duisburg, Germany
/H20849Received 3 August 2008; published 29 August 2008 /H20850
Current-induced torque is formulated based on the spin continuity equation. The formulation does not rely
on the assumption of separation of local spin and charge degrees of freedom, in contrast to approaches basedon the s-dmodel or mean-field approximation of itinerant ferromagnetism. This method would be thus useful
for the estimation of torques in actual materials by first-principles calculations. As an example, the formalismis applied to the adiabatic limit of the s-dmodel in order to obtain the analytical expression for torques and the
corresponding
/H9252terms arising from spin relaxation due to spin-flip scattering and spin-orbit interaction.
DOI: 10.1103/PhysRevB.78.064429 PACS number /H20849s/H20850: 85.75. /H11002d, 72.10. /H11002d, 72.25. /H11002b
I. INTRODUCTION
Spin-transfer torque is a torque acting on local spins as a
result of an applied current. Such a torque has been discussedmostly based on s-dtype of exchange interaction
1–6after the
pioneering works by Berger7,8and Slonczewski.9Ins-d
models, the conduction electrons and localized spins are dis-criminated and therefore the transfer of spin angular momen-tum between those two degrees of freedom occurs. However,in reality, this separation of degrees of freedom is not alwaysso obvious; since in an itinerant picture, all electronic bandscontribute to both conduction and magnetism with differentweights. Thus, the formulation of spin torques based on thes-dpicture is an approximation and this is a serious problem
when one tries to evaluate current-induced torques in actualmaterials. For trustful estimates, formulations beyond thesimple s-dseparation is certainly required. Such formalism
can be combined with first-principles calculations withoutany artificial assumption and would be useful for realisticestimates of current-induced torques and of efficiency ofcurrent-induced switching. The aim of this paper is to de-velop a calculational scheme satisfying these requirementsbased on the spin continuity equation.
Theoretical determination of current-induced torques is
difficult even in the simplest case of s-dmodel when spin
relaxation and nonadiabaticity is present.
4,5,10–15So far, very
few studies on the effect of spin relaxation due to spin-flipscattering by magnetic impurities have been donemicroscopically.
4,5,12In the s-dformalism, the current-
induced torque is represented as the effective field due to thespin polarization of the conduction electron s. The torque is
therefore given as
/H9270/H20849sd/H20850=−JsdS/H11003s, where Sis the localized
/H20849d/H20850electron spin and Jsdis the exchange interaction constant.
Microscopic calculation using linear-response theory4,5re-
vealed, in agreement with phenomenolocigal result,2that
spin-flip interaction of conduction electrons with random im-purities induces a torque perpendicular to the spin-transfertorque /H20849called
/H9252terms16/H20850. The torque is written as
/H9270/H20849/H9252/H20850=−/H9252P
eS2/H20851S/H11003/H20849j·/H11612/H20850S/H20852, /H208491/H20850
where Pis the spin polarization of the current and jis the
current density. The coefficient /H9252was calculated by sum-ming over not a few Feynman diagrams, representing self-
energy and vertex corrections.4,5,15
The case of itinerant ferromagnetism was studied by
Tserkovnyak et al.10and Duine et al.12They introduced the
magnetization as a mean-field expectation value of itinerantelectron spin and, thus, the models considered were effec-tively the s-dmodel. Tserkovnyak et al. considered a kinetic
equation for the spin density with a consistency condition forthe magnetization, but the spin dephasing term was intro-duced phenomenologically. Duine et al. estimated the
torques by calculating the effective action for the magnetiza-tion fluctuation, which has been assumed to be of small am-plitude. Within the mean-field treatment, the torque in theitinerant case turned out to be exactly the same as that of thes-dmodel.
4,12
It has recently been noticed that the coefficient /H9252is very
important for the realization of highly efficient magnetizationswitching by the current.
2,15–17First, it affects the threshold
current and the intrinsic pinning threshold is replaced by anextrinsic one, which is usually lower than the intrinsic one.
Second, it results in a terminal speed of the wall
v/H11008/H9252
/H9251j,
which can exceed the pure spin-transfer speed limit if/H9252
/H9251is
large /H20849/H9251is Gilbert damping parameter /H20850. Third, the deforma-
tion of the wall depends on /H9252. When /H9252/H11011/H9251, deformation is
suppressed and weak dissipation may be expected.18Experi-
mental studies of the value of /H9252have recently been carried
out. Significant wall deformation observed in permalloy in-dicated that
/H9252/HS11005/H9251.18Thomas et al.19found for permalloy that
the observed wall speed corresponds to /H9252/H110118/H9251. Therefore,
determination of /H9252is of particular importance for device
applications.
In this paper, we will present a microscopic calculation
scheme different from the s-dformalism.7,8The idea is sim-
ply to use the continuity equation of spin and thus the for-mulation is not necessarily based on the s-dinteraction pic-
ture. The formalism turns out to be quite powerful, inparticular, for the determination of spin-relaxation effect
/H9252.
The continuity equation, which we consider, is essentiallythe kinetic equation discussed by Tserkovnyak et al. ,
10but all
observables have been microscopically defined and can becalculated using our formalism. For instance, spin dephasingtime introduced phenomenolocigally in Ref. 10is repre-
sented by the spin source term /H20849T/H20850defined by Green’s func-PHYSICAL REVIEW B 78, 064429 /H208492008 /H20850
1098-0121/2008/78 /H208496/H20850/064429 /H208496/H20850 ©2008 The American Physical Society 064429-1tion in our formalism. Microscopic details of this term Tturn
out to be essential in determining the spin-relaxation-inducedtorque.
Our scheme is applicable also to the s-dmodel or mean-
field approximation of itinerant ferromagnetism. We will useour formalism to obtain the analytical expression of thetorques arising from both spin-flip scattering and spin-orbitinteraction arising from the impurities in the s-dmodel in the
adiabatic limit. In the present formalism, the number of con-tributing diagrams is less than the number of diagrams usedin the s-dexchange formalism
4,5and thus the calculation is
easier.
II. FORMALISM
The spin density sof the total system is defined as the
expectation value of conduction-electron spin, summed overall bands nas
s
/H9251/H20849x,t/H20850/H11013/H20858
n/H20855cn†/H20849x,t/H20850/H9268/H9251cn/H20849x,t/H20850/H20856. /H208492/H20850
It satisfies the equation /H6036s˙/H9251=i/H20858n/H20849/H20855/H20851H,cn†/H20852/H9268/H9251cn/H20856
+/H20855cn†/H9268/H9251/H20851H,cn/H20852/H20856/H20850where His total Hamiltonian. We assume
that Hconsists of free and spin-relaxation parts HsrasH
=/H20848d3x/H20858n/H60362
2m/H20841/H11612cn/H208412+Hsr. Then the continuity equation is ob-
tained as
/H6036s˙/H9251=−1
e/H11612·js/H9251+T/H9251, /H208493/H20850
where erepresents the electron charge. Here the spin current
jsis defined by the free part as
js/H9262/H9251/H11013−ie/H6036
2m/H20858
n/H20855cn†/H20849x,t/H20850/H11612J/H9262/H9268/H9251cn/H20849x/H11032,t/H20850/H20856, /H208494/H20850
and the spin source /H20849or sink /H20850Tis a contribution arising from
spin relaxation and interaction, i.e.,
T/H9251/H11013i/H20858
n/H20849/H20855/H20851Hsr,cn†/H20852/H9268/H9251cn/H20856+/H20855cn†/H9268/H9251/H20851Hsr,cn/H20852/H20856/H20850. /H208495/H20850
The continuity /H20851Eq. /H208493/H20850/H20852is sufficient to calculate the torque
acting on the spin. Actually, the equation is equivalent to the
equation of motion of spin /H6036s˙=/H9270where /H9270represents the total
torque acting on the spin. The torque is thus simply given by
/H9270/H9251=−1
e/H11612·js/H9251+T/H9251. /H208496/H20850
Note that the continuity equation describes the time de-
pendence of the spin density and, therefore, the right-handside of Eqs. /H208493/H20850and /H208496/H20850is uniquely defined even in the pres-
ence of spin relaxation, where the spin current can be definedin several different ways /H20849see Ref. 20/H20850. In the context of spin
Hall effect, the continuity /H20851Eq. /H208493/H20850/H20852was used to obtain proper
definition of spin current and to explore transportproperties.
21–23Concerning the current-induced torques, Eq.
/H208496/H20850has been so far applied only in the absence of spin-
relaxation term, where the torque is given by the divergenceof the spin current.
24,25The main aim of this paper is to study
the spin-relaxation contribution T.Let us look explicitly at the continuity equation, in case of
spin relaxation, due to spin impurities and spin-orbit interac-tion H
sr=Hsf+Hso. Spin-flip interaction is described by
Hsf=vs/H20885d3x/H20858
nSimp/H20849x/H20850·/H20849cn†/H9268cn/H20850, /H208497/H20850
where vsis a constant, Simp/H20849x/H20850/H11013/H20858inimpSimpi/H9254/H20849x−Ri/H20850,Simpirep-
resents the impurity spin at x=Ri, and nimpdenotes the num-
ber of impurity spins. The spin-orbit interaction is written as
Hso=−i
2/H9261so/H20885d3x/H20858
ijkl/H9280ijk/H11612jVso/H20849l/H20850/H20849x/H20850/H20849cn†/H9268l/H11612Jkcn/H20850, /H208498/H20850
where the potential Vso/H20849l/H20850is here assumed to arise from random
impurities and depends on the spin direction /H20849l/H20850.
The spin-relaxation torque is given by a sum of contribu-
tions from spin-flip and spin-orbit interactions as T/H9251=Tsf/H9251
+Tso/H9251, where
Tsf/H9251/H20849x/H20850=2vs/H20858
/H9252/H9253/H9280/H9251/H9252/H9253/H20855Simp/H9252s/H9253/H20856i, /H208499/H20850
Tso/H9251/H20849x/H20850=−2 m/H9261so/H20858
/H9252/H9253/H9262/H9263/H9280/H9251/H9252/H9253/H9280/H9262/H9263/H9252/H20855/H11612/H9262Vso/H20849/H9253/H20850/H20849x/H20850jsv/H9253/H20856i. /H2084910/H20850
The average over random impurity spins and spin-orbit po-
tential is represented by /H20855/H20856i.
All the terms in the right-hand side of torque /H20851Eqs. /H208496/H20850,
/H208499/H20850, and /H2084910/H20850/H20852are written in terms of local spin density and
local spin current and so the torque acting on the spin iscalculated by estimating the spin density and the spin cur-rent. This representation of the spin torque applies to anyspin-relaxation processes and interaction and is directly cal-culable without assuming separation of spin and charge de-grees of freedom. Equations /H208496/H20850,/H208499/H20850, and /H2084910/H20850are thus suit-
able starting points for realistic estimates based on first-principles calculations. This is the essential point of thispaper /H20849although ab initio calculations, using the present for-
malism, still need to be undertaken /H20850.
III. APPLICATION TO THE s-dMODEL
In Secs. III A and III B of the paper, we will apply this
formulation to estimate the current-induced torques in theadiabatic limit /H20849i.e., slowly varying magnetization compared
to conduction-electron motion /H20850to show the validity and use-
fulness of our formalism. We will calculate the torque arisingfrom the spin relaxation due to both the spin-flip scatteringand the spin-orbit interaction. It is found that the torque isrepresented by the so-called
/H9252term in both cases and values
of corresponding /H9252are calculated. Our formulation is thus
useful for both analytical and numerical studies.
We will now consider the s-dmodel with only one con-
duction band. Please note that the assumption of separationofsand delectrons here is simply for analytical demonstra-
tion and is not a requirement for the present formulation. Thes-dinteraction between a localized spin Sand the conduction
electrons is given byGEN TATARA AND PETER ENTEL PHYSICAL REVIEW B 78, 064429 /H208492008 /H20850
064429-2Hex/H11013−Jsd/H20885d3xS/H20849x,t/H20850·/H20849c†/H9268c/H20850. /H2084911/H20850
We describe the adiabatic limit by the standard local gauge
transformation in the spin space, choosing the electron spin-quantization axis along S/H20849x,t/H20850at each point. A new electron
operator a/H11013/H20849a
+,a−/H20850t/H20849tdenotes transpose /H20850is defined as
c/H20849x,t/H20850/H11013U/H20849x,t/H20850a/H20849x,t/H20850where Ui sa2 /H110032 matrix, which we
further define as U/H20849x,t/H20850/H11013m·/H9268with mbeing a real three-
component unit vector m=/H20849sin/H9258
2cos/H9278,sin/H9258
2sin/H9278,cos/H9258
2/H20850. The
gauge field is written as A/H9262/H9251/H11013/H20849m/H11003/H11509/H9262m/H20850/H9251. Then the Hamil-
tonian of aelectrons is given by the free part /H20858k/H9268/H9280k/H9268ak/H9268†ak/H9268
/H20849/H9280k/H9268/H11013/H9280k−/H9268M,/H9268=/H11006represents the spin /H20850,HAdescribing the
interaction with the SU /H208492/H20850gauge field, and Hemas the inter-
action with the external electric field, which drives thecurrent.
1,15Here, we consider static local spins in the adia-
batic limit, where the momentum transferred by the gaugefield to conduction electrons is negligibly small /H20849compared to
k
F/H20850and take into account the gauge field only in linear order.
Then, the gauge interaction is given by15
HA=/H60362
m/H20858
q/H20858
/H9262k/H9262A/H9262/H9251/H20849−q/H20850ak†/H9268/H9251ak. /H2084912/H20850
The applied electric field is represented by the interaction,
Hem=/H20858
/H9262ie/H6036E/H9262
m/H90240ei/H90240t/H20858
k/H20851k/H9262ak†ak+/H20858
/H9251qA/H9262/H9251/H20849q/H20850ak†/H9268/H9251ak/H20852+O/H20849E2/H20850,
/H2084913/H20850
where /H90240is the frequency of the field chosen as /H90240→0a t
the end of calculation.
The spin-current part of the torque is calculated in the
adiabatic limit as
−/H11612·js/H9251/H11229−/H20849/H11612/H9262n/H20850js/H9262. /H2084914/H20850
Here, n/H11013S/Sand, therefore, this contribution corresponds
to the standard spin-transfer torque.
A. Torque from spin-flip scattering
Let us turn to the spin-relaxation part of the torque arising
from spin impurities, i.e., Eq. /H208499/H20850. The effect of spin relax-
ation on the spin-current part can be shown to be simply dueto modification of lifetime
/H9270. Here, we assume that the im-
purity spins are influenced by a strong s-dexchange field and
write Simp/H9251/H20849x/H20850=R/H9251/H9252/H20849x/H20850S˜
imp/H9252/H20849x/H20850, where S˜
imp/H9251represents impurity
spin in the rotated frame, and
R/H9251/H9252/H110132m/H9251m/H9252−/H9254/H9251/H9252, /H2084915/H20850
is a rotation matrix. Then the averaging is given by
/H20855S˜
imp/H9251/H20849x/H20850S˜
imp/H9252/H20849x/H11032/H20850/H20856i=1
3/H9254/H9251/H9252/H9254/H20849x-x/H11032/H20850nimpSimp2where nimpis the im-
purity spin concentration. Averaging taken with respect toS
impturns out to lead to—essentially—the same result as in
the case of S˜imp. The spin source term is written as
Tsf/H9251/H20849x/H20850=−2 ivs/H20858
/H9252/H9253F/H9251/H9252/H9253/H20849x/H20850/H20855S˜
imp/H9252/H20849x/H20850tr/H20851/H9268/H9253G˜
x,x/H11021/H20852/H20856i, /H2084916/H20850
whereF/H9251/H9252/H9253 /H11013/H20858
/H9262/H9263/H9280/H9251/H9262/H9263R/H9262/H9252R/H9263/H9253, /H2084917/H20850
and G˜
x,x/H11032/H11021/H11013i/H20855a†/H20849x/H11032/H20850a/H20849x/H20850/H20856is the lesser component of the
Green’s function defined on Keldysh contour in the complex
time. To the lowest /H20849second /H20850order in vs, we obtain after
averaging over spin impurities,
Tsf/H9251/H20849x/H20850=−i2
3nimpvs2Simp2/H20858
/H9252/H9253/H9254/H20858
/H9262/H9263F/H9251/H9252/H9253/H20849x/H20850tr/H20851/H9268/H9252G˜
x,x/H208490/H20850/H9268/H9253G˜
x,x/H208490/H20850/H20852/H11021
+O/H20849vs4/H20850, /H2084918/H20850
where G˜/H208490/H20850denotes Green’s functions without impurity spins
but including the gauge field Aand external electric field E.
Including these fields in linear order, we obtain
Tsf/H9251/H20849x/H20850=−2e
3mnimpvs2Simp2/H20858
/H9252/H9253/H9262/H9263F/H9251/H9252/H9253/H20849x/H20850E/H9262A/H9263/H9254/H20849x/H20850D/H9262/H9263/H9252/H9253/H9254,
/H2084919/H20850
where
D/H9262/H9263/H9252/H9253/H9254/H11013lim
/H90240→01
/H90240/H20885d/H9275
2/H9266/H20858
kk/H11032tr/H20875/H9268/H9252/H20873/H9254/H9262/H9263gk/H11032/H9275/H9268/H9253gk/H9275/H9268/H9254gk/H9275+/H90240
+k/H9262k/H9263
m/H20853gk/H11032/H9275/H9268/H9253gk/H9275gk/H9275+/H90240/H9268/H9254gk/H9275+/H90240
+gk/H11032/H9275/H9268/H9253gk/H9275/H9268/H9254gk/H9275gk/H9275+/H90240/H20854/H20874/H20876/H11021
+ c.c. /H2084920/H20850
Here, the Green’s function gk/H9275is the Fourier representation
of free Green’s function and /H20851/H20852/H11021denotes the lesser compo-
nent. They are diagonal in spin space, being defined ingauge-transformed space. Complex conjugates are denoted
by c.c. Figure 1shows the contributions to D
/H9262/H9263/H9252/H9253/H9254diagram-
matically. The lesser component is calculated in standardmanner in the limit of /H9024
0→0. The first two diagrams of Fig.
1are simplified by the use of partial integration over kusing
k/H9262
m/H20849gka/H208502=/H11509
/H11509k/H9262gka, etc. These contributions are obtained as
D/H9262/H9263/H9252/H9253/H9254/H208491−2 /H20850= lim
/H90240→0/H20885d/H9275
2/H9266/H20858
kk/H11032tr/H20875f/H11032/H20849/H9275/H20850k/H9262k/H9263
m/H20853/H9268/H9252gk/H11032/H9275r/H9268/H9253
+/H9268/H9253gk/H11032/H9275a/H9268/H9252/H20854/H20849/H20841gk/H9275r/H208412/H9268/H9254gk/H9275a+gk/H9275r/H9268/H9254/H20841gk/H9275a/H208412/H20850
+/H9254/H9262/H9263/H20875f/H20849/H9275/H20850
2/H20853/H20851/H9268/H9252/H20849gk/H11032/H9275a/H208502/H9268/H9253
−/H9268/H9253/H20849gk/H11032/H9275a/H208502/H9268/H9252/H20852gk/H9275a/H9268/H9254gk/H9275a− c.c. /H20854σβσγ
σδk/primeωkω
kωk,ω+Ω0Aδν
EµEµ
Aδνk,ω+Ω0k,ω+Ω0
FIG. 1. Diagrammatic representation of D/H9262/H9263/H9252/H9253/H9254. Double-dashed,
dotted, and wavy lines denote interaction with impurity spin, ap-plied electric field E, and gauge field A, respectively.CALCULATION OF CURRENT-INDUCED TORQUE FROM … PHYSICAL REVIEW B 78, 064429 /H208492008 /H20850
064429-3−1
/H90240/H20875f/H20873/H9275−/H90240
2/H20874/H20849/H9268/H9252gk/H11032/H9275a/H9268/H9253
+/H9268/H9253gk/H11032/H9275a/H9268/H9252/H20850gk/H9275a/H9268/H9254gk/H9275a−f/H20873/H9275+/H90240
2/H20874/H20849/H9268/H9252gk/H11032/H9275r/H9268/H9253
+/H9268/H9253gk/H11032/H9275r/H9268/H9252/H20850gk/H9275r/H9268/H9254gk/H9275r/H20876/H20876/H20876, /H2084921/H20850
where f/H20849/H9275/H20850/H11013/H20849 e/H9252/H9275+1/H20850−1. Similarly, the third contribution in
Fig.1is obtained as
D/H9262/H9263/H9252/H9253/H9254/H208493/H20850= lim
/H90240→0/H20885d/H9275
2/H9266/H20858
kk/H11032/H9254/H9262/H9263tr/H20875f/H11032/H20849/H9275/H20850/H20853/H9268/H9252gk/H11032r/H9268/H9253
+/H9268/H9253gk/H11032a/H9268/H9252/H20854gkr/H9268/H9254gka+/H20875−f/H20849/H9275/H20850
2/H20853/H20851/H9268/H9252/H20849gk/H11032/H9275a/H208502/H9268/H9253
−/H9268/H9253/H20849gk/H11032/H9275a/H208502/H9268/H9252/H20852gk/H9275a/H9268/H9254gk/H9275a− c.c. /H20849/H9268/H9252gk/H11032/H9275a/H9268/H9253
+/H9268/H9253gk/H11032/H9275a/H9268/H9252/H20850/H20851gk/H9275a/H9268/H9254/H20849gk/H9275a/H208502−/H20849gk/H9275a/H208502/H9268/H9254gk/H9275a/H20852− c.c. /H20854
+1
/H90240/H20875f/H20873/H9275−/H90240
2/H20874/H20849/H9268/H9252gk/H11032/H9275a/H9268/H9253+/H9268/H9253gk/H11032/H9275a/H9268/H9252/H20850gk/H9275a/H9268/H9254gk/H9275a
−f/H20873/H9275+/H90240
2/H20874/H20849/H9268/H9252gk/H11032/H9275r/H9268/H9253+/H9268/H9253gk/H11032/H9275r/H9268/H9252/H20850gk/H9275r/H9268/H9254gk/H9275r/H20876/H20876/H20876.
/H2084922/H20850
Noting that only antisymmetric part with respect to /H9252and/H9253
contribute to the torque, these contributions are summed to
be
D/H9262/H9263/H9252/H9253/H9254=−i/H20885d/H9275
2/H9266/H20858
kk/H11032f/H11032/H20849/H9275/H20850tr/H20877/H20851/H9268/H9252Im/H20849gk/H11032a/H20850/H9268/H9253−/H9268/H9253Im/H20849gk/H11032a/H20850/H9268/H9252/H20852
/H11003/H20875k/H9262k/H9263
m/H20849/H20841gkr/H208412/H9268/H9254gka+gkr/H9268/H9254/H20841gkr/H208412/H20850+/H9254/H9262/H9263/H20849gkr/H9268/H9254gka/H20850/H20876/H20878,/H2084923/H20850
where gkr/H11013gk,/H9275=0r, etc. We see that spin-flip processes con-
tribute as additional lifetimes as indicated by the imaginary
part of spin-scattered electron Green’s function Im gk/H11032a.
To estimate the trace in the spin space, we use general
identities, which hold for 2 /H110032 diagonal matrices B,C, and
D/H20849containing only /H9268zand the identity matrix /H20850,
tr/H20851/H20849/H9268/H9252B/H9268/H9253−/H9268/H9253B/H9268/H9252/H20850/H20849C/H9268/H9254D+D/H9268/H9254C/H20850/H20852
=2i/H20851/H20849/H9280/H9252/H9253/H9254−/H9280/H9252/H9253z/H9254/H9254z/H20850/H20851/H20849BC/H20850+D−+/H20849BC/H20850−D++/H20849BD/H20850+C−
+/H20849BD/H20850−C+/H20852+2/H9280/H9252/H9253z/H9254/H9254z/H20851B+/H20849CD/H20850−+B−/H20849CD/H20850+/H20852/H20852,
tr/H20851/H20849/H9268/H9252B/H9268/H9253−/H9268/H9253B/H9268/H9252/H20850/H20849C/H9268/H9254D−D/H9268/H9254C/H20850/H20852
=2/H20849/H9254/H9253z/H9254/H9252/H9254−/H9254/H9252z/H9254/H9253/H9254/H20850/H20851/H20849BC/H20850+D−−/H20849BC/H20850−D+−/H20849BD/H20850+C−
+/H20849BD/H20850−C+/H20852, /H2084924/H20850
where the components B/H11006are defined as B=/H20851B++B−+
/H20849B+−B−/H20850/H9268z/H20852/2, etc. The result for D/H9262/H9263/H9252/H9253/H9254is then obtained asD/H9262/H9263/H9252/H9253/H9254=/H9254/H9262/H9263/H20851a/H20849/H9280/H9252/H9253/H9254−/H9280/H9252/H9253z/H9254/H9254z/H20850+b/H20849/H9254/H9252/H9254/H9254/H9253z−/H9254/H9253/H9254/H9254/H9252z/H20850/H20852,
/H2084925/H20850
where the coefficients are given by
a=−1
2/H9266/H20858
kk/H11032/H20858
/H9268/H9268/H11032/H20875k2
3m/H20841gk/H9268r/H208412/H20849gk,−/H9268a+gk,−/H9268r/H20850
+/H20849gk/H9268rgk,−/H9268a+gk/H9268agk,−/H9268r/H20850/H20876/H20849Imgk/H11032/H9268/H11032a/H20850,
b=−1
2/H9266/H20858
kk/H11032/H20858
/H9268/H9268/H11032/H20849i/H9268/H20850gk/H9268agk,−/H9268r/H20849Imgk/H11032/H9268/H11032a/H20850. /H2084926/H20850
Using F/H9251/H9252/H9253=−/H9280/H9251/H9252/H9253−2/H20858/H9254m/H9254/H20849/H9280/H9251/H9253/H9254m/H9252−/H9280/H9251/H9252/H9254m/H9253/H20850and A/H9262
=1
2/H20849n/H11003/H11509/H9262n/H20850−A/H9262zn,15the torque due to spin flip is obtained
as
Tsf=−2e
3mvs2Simp2/H20858
/H9262E/H9262/H20851a/H20849n/H11003/H11509/H9262n/H20850−b/H11509/H9262n/H20852. /H2084927/H20850
The coefficients aand bare calculated as a=/H9266/H20849m/e2M/H20850
/H20849/H9268+−/H9268−/H20850/H20849/H9263++/H9263−/H20850and b=O/H20851a/H11003/H20849/H9280F/H9270/H20850−1/H20852/H112290, where /H9263/H11006and
/H9268/H9268=e2n/H9268/H9270/H9268/mare the spin-resolved conductivity and density
of states, respectively. Coefficient bis treated as zero within
the present approximation. Therefore, the torque induced bythe spin relaxation is simply a
/H9252term given by
Tsf=−/H9252sfP
e/H20851n/H11003/H20849j·/H11612/H20850n/H20852, /H2084928/H20850
where P/H11013/H20849/H9268+−/H9268−/H20850//H20849/H9268++/H9268−/H20850is the spin polarization of the
current and
/H9252sf=2/H9266
3Mnimpvs2Simp2/H20849/H9263++/H9263−/H20850. /H2084929/H20850
Defining the spin-flip lifetime /H20849/H9270sof Ref. 4/H20850as/H20849note that
Sz2+S/H110362of Ref. 4corresponds to2
3Simp2here /H20850/H9270sf−1
=/H208494/H9266/3/H20850nimpvs2Simp2/H20849/H9263++/H9263−/H20850,w efi n d /H9252sf=/H6036//H208492M/H9270sf/H20850, which
agrees with the results obtained in Refs. 4and5.
B. Torque from spin-orbit interaction
The torque from spin-orbit interaction /H20851Eq. /H2084910/H20850/H20852is calcu-
lated in a similar way. The spin-orbit interaction is written inthe rotated frame as
H
so=/H9261so/H20885d3x/H20858
ijkl/H9280ijk/H11612jVso/H20849i/H20850/H20849x/H20850Ril/H20849x/H20850/H20873−i
2a†/H9268l/H11612Jka+Akla†a/H20874.
/H2084930/H20850
The spin-orbit contributions to the spin current and the elec-
tron density in the rotated frame are obtained asGEN TATARA AND PETER ENTEL PHYSICAL REVIEW B 78, 064429 /H208492008 /H20850
064429-4js/H9263/H9267/H20849x/H20850=−i
2m/H9261so/H20858
ijkl/H9280ijk/H20849/H11612x−/H11612x/H11032/H20850/H9263/H20885d3x1/H11612jVso/H20849i/H20850/H20849x1/H20850Ril/H20849x1/H20850
/H11003tr/H20877/H9268/H9267G˜
x,x1/H11032/H208490/H20850/H20875−i
2/H20849/H11612/H6023x1−/H11612/H6024x1/H11032/H20850k/H9268l
+Akl/H20849x1/H20850/H20876G˜
x1,x/H11032/H208490/H20850/H20878
x/H11032→x,x1/H11032→x1/H11021
,
ne/H20849x/H20850=−i
2/H9261so/H20858
ijkl/H9280ijk,/H20885d3x1/H11612jVso/H20849i/H20850/H20849x1/H20850Ril/H20849x1/H20850/H20849/H11612/H6023x1
−/H11612/H6023x1/H11032/H20850ktr/H20851G˜
x,x1/H11032/H208490/H20850/H9268lG˜
x1,x/H11032/H208490/H20850/H20852x/H11032→x,x1/H11032→x1/H11021+O/H20849A/H20850./H2084931/H20850
The torque is then calculated as
Tso/H9251/H20849x/H20850=−i/H9261so2/H20858
/H9252/H9262/H9263/H9270/H20858
jklm/H9280/H9251/H9262/H9270/H9280lm/H9270/H9280/H9263jk
/H11003/H20885d3x1R/H9262/H9252/H20849x/H20850R/H9263/H9253/H20849x1/H20850/H20858
kk/H11032p/H20858
k1k1/H11032
/H11003plpje−ip·/H20849x−x1/H20850e−i/H20849k−k/H11032/H20850·xe−i/H20849k1−k1/H11032/H20850·x1/H20855Vso/H20849/H9252/H20850/H20849p/H20850Vso/H20849/H9270/H20850/H20849−p/H20850/H20856
/H11003/H208771
2/H20849k+k/H11032/H20850m/H20849k1+k1/H11032/H20850ktr/H20851/H9268/H9252G˜
k,k1/H208490/H20850/H9268/H9253G˜
k1/H11032,k/H11032/H208490/H20850/H20852/H11021
+/H20849k+k/H11032/H20850mAk/H9253/H20849x1/H20850tr/H20851/H9268/H9252G˜
k,k1/H208490/H20850G˜
k1/H11032,k/H11032/H208490/H20850/H20852/H11021
+/H20849k1+k1/H11032/H20850kAm/H9252/H20849x1/H20850tr/H20851G˜
k,k1/H208490/H20850/H9268/H9253G˜
k1/H11032,k/H11032/H208490/H20850/H20852/H11021/H20878. /H2084932/H20850
In the adiabatic limit, we consider Green’s functions are di-
agonal in wave vectors G˜
k,k/H11032/H208490/H20850=/H9254k,k/H11032G˜
k/H208490/H20850and the integration
over x1can be carried out, treating the slowly varying vari-
ables R/H20849x1/H20850and A/H20849x1/H20850as constants, resulting in
/H20848dx1e−i/H20849p−k+k/H11032/H20850·/H20849x−x1/H20850=V/H9254p,k−k/H11032. We therefore obtain
Tso/H9251/H20849x/H20850=−i/H9261so2/H20858
/H9252/H9262/H9263/H9270/H20858
jklm/H9280/H9251/H9262/H9270/H9280lm/H9270/H9280/H9263jkR/H9262/H9252/H20849x/H20850R/H9263/H9253/H20849x/H20850/H20858
kk/H11032
/H11003/H20849k−k/H11032/H20850l/H20849k−k/H11032/H20850j/H20855Vso/H20849/H9263/H20850/H20849k−k/H11032/H20850Vso/H20849/H9270/H20850/H20849−k+k/H11032/H20850/H20856
/H11003/H208751
2/H20849k+k/H11032/H20850m/H20849k1+k1/H11032/H20850ktr/H20851/H9268/H9252G˜
k/H208490/H20850/H9268/H9253G˜
k/H11032/H208490/H20850/H20852/H11021
+/H20849k+k/H11032/H20850mAk/H9253/H20849x/H20850tr/H20851/H9268/H9252G˜
k/H208490/H20850G˜
k/H11032/H208490/H20850/H20852/H11021
+/H20849k+k/H11032/H20850kAm/H9252/H20849x/H20850tr/H20851G˜
k/H208490/H20850/H9268/H9253G˜
k/H11032/H208490/H20850/H20852/H11021/H20876. /H2084933/H20850
We average over spin-orbit impurities so that the average
remains finite only when the spin polarizations are parallel.Impurity averaging is thus given as
/H20855V
so/H20849/H9263/H20850/H20849p/H20850Vso/H20849/H9270/H20850/H20849−p/H11032/H20850/H20856i=nso/H9254/H9263/H9270/H9254p,p/H11032. /H2084934/H20850
The result of the torque isTso/H9251/H20849x/H20850=−i1
2nso/H9261so2/H20858
/H9252/H9262/H9263/H9270/H9280/H9251/H9262/H9263R/H9262/H9252/H20849x/H20850R/H9263/H9253/H20849x/H20850/H11003/H20858
kk/H11032/H20851/H20849k/H11003k/H11032/H20850/H9270
/H11003/H20849k/H11003k/H11032/H20850/H9263tr/H20851/H9268/H9252G˜
k/H208490/H20850/H9268/H9253G˜
k/H11032/H208490/H20850/H20852/H11021+/H20849k/H11003k/H11032/H20850/H9270/H20851/H20849k−k/H11032/H20850
/H11003A/H9253/H20852/H9263tr/H20851/H9268/H9252G˜
k/H208490/H20850G˜
k/H11032/H208490/H20850/H20852/H11021+/H20849k/H11003k/H11032/H20850/H9263/H20851/H20849k−k/H11032/H20850
/H11003A/H9252/H20852/H9270tr/H20851G˜
k/H208490/H20850/H9268/H9253G˜
k/H11032/H208490/H20850/H20852/H11021/H20852/H9263=/H9270. /H2084935/H20850
The last two terms lead to vanishing contribution in the adia-
batic limit. In fact, these are already linear in Aand so G˜/H208490/H20850
does not contain spin-flip components, and thus /H9268zand G˜/H208490/H20850
commute each other. We therefore obtain
/H20851/H20849k−k/H11032/H20850A/H9253/H20852/H9263tr/H20851/H9268/H9252G˜
k/H208490/H20850G˜
k/H11032/H208490/H20850/H20852/H11021+/H20851/H20849k−k/H11032/H20850A/H9252/H20852/H9263
/H11003tr/H20851G˜
k/H208490/H20850/H9268/H9253G˜
k/H11032/H208490/H20850/H20852/H11021
=/H20853/H9254/H9252,z/H20851/H20849k−k/H11032/H20850/H11003A/H9253/H20852/H9263+/H9254/H9253,z/H20851/H20849k−k/H11032/H20850
/H11003A/H9252/H20852/H9263/H20854tr/H20851/H9268zG˜
k/H208490/H20850G˜
k/H11032/H208490/H20850/H20852/H11021. /H2084936/H20850
This contribution is symmetric with respect to /H9252and/H9253and
results in zero when multiplied by F/H9262/H9263/H9251/H9252/H9253, which is asymmetric
with respect to /H9252and/H9253.
The first term of Eq. /H2084935/H20850can be simplified by using the
rotational symmetry of electron, /H20855/H20849k/H11003k/H11032/H20850/H9270/H20849k/H11003k/H11032/H20850/H9270/H20856=1
3/H20855/H20849k
/H11003k/H11032/H20850·/H20849k/H11003k/H11032/H20850/H20856=1
3/H20855/H20851k2k/H110322−/H20849k·k/H11032/H208502/H20852/H20856 /H20849/H20855 /H20856 denotes the angular
average /H20850,a s
Tso/H9251/H20849x/H20850=−i1
6nso/H9261so2/H20858
/H9252/H9262/H9263/H9270/H20858
kk/H11032F/H9262/H9263/H9251/H9252/H9253/H20851k2k/H110322
−/H20849k·k/H11032/H208502/H20852tr/H20851/H9268/H9252G˜
k/H208490/H20850/H9268/H9253G˜
k/H11032/H208490/H20850/H20852/H11021. /H2084937/H20850
We therefore see that the expression is similar to that of
spin-flip impurity case /H20851Eq. /H2084918/H20850/H20852. Including the effect of
electric and gauge fields to linear order in both similarly tothe spin-flip impurity case, we obtain the torque as
T
so=−e
6mnso/H9261so2a/H11032/H20858
/H9262E/H9262/H20849n/H11003/H11509/H9262n/H20850, /H2084938/H20850
where coefficient is given as
a/H11032=−1
2/H9266/H20858
kk/H11032/H20858
/H9268/H9268/H11032/H20849k2k/H110322−/H20849k·k/H11032/H208502/H20850/H20875k2
3m/H20841gk/H9268r/H208412/H20849gk,−/H9268a+gk,−/H9268r/H20850
+/H20849gk/H9268rgk,−/H9268a+gk/H9268agk,−/H9268r/H20850/H20876/H20849Imgk/H11032/H9268/H11032a/H20850. /H2084939/H20850
The coefficient is calculated as a/H11032=/H92662m
3e2M/H20849/H9268+kF+2
−/H9268−kF−2/H20850/H20849/H9263+kF+2+/H9263−kF−2/H20850. Therefore, spin-orbit interaction
yields the /H9252term with coefficient given by
/H9252so=1
2M1
n+/H9270+−n−/H9270−/H20873n+/H9270+
/H9270+/H20849so/H20850−n−/H9270−
/H9270−/H20849so/H20850/H20874, /H2084940/H20850
whereCALCULATION OF CURRENT-INDUCED TORQUE FROM … PHYSICAL REVIEW B 78, 064429 /H208492008 /H20850
064429-51
/H9270/H11006/H20849so/H20850/H110132/H9266
9nso/H9261so2kF/H110062/H20849/H9263+kF+2+/H9263−kF−2/H20850, /H2084941/H20850
with/H9270/H11006/H20849so/H20850as the lifetime due to spin-orbit interaction.
The total current-induced torque in the adiabatic limit is
therefore given by Eqs. /H2084914/H20850,/H2084928/H20850,/H2084929/H20850, and /H2084940/H20850as
/H9270=−P
2e/H20849/H11612·j/H20850n−/H9252srP
e/H20851n/H11003/H20849j·/H11612/H20850n/H20852, /H2084942/H20850
with/H9252sr/H11013/H9252sf+/H9252so.
IV . SUMMARY
In summary, we demonstrated that the spin continuity
equation represents the current-induced torque acting on themagnetization and that it can be used for microscopic deter-mination of the torques. The present formalism does not as-sume separation of magnetization and conduction-electrondegrees of freedom and can directly be applied to itinerantelectron systems without mean-field approximation. In thispaper, the formalism was applied to the s-dmodel in the
presence of spin relaxation caused due to spin-flip scatteringand spin-orbit interaction with impurities. Both relaxationprocesses were shown to induce the so-called
/H9252torque term.Application of the formalism to realistic itinerant system
using first-principles calculations would be very interestingsince it would allow for quantitative estimations of current-induced switching. Of particular interest are the systems withenhanced spin-orbit interaction near surfaces and multilay-ers. Our formulation can be easily extended to describe thesesystems.
Further improvement of the present theory would be to
include effects caused by electron-electron correlation. If thecorrelation is represented within the mean-field approxima-tion by a local spin-dependent potential, the torque isstraightforwardly calculated similarly to the estimate of spin-flip scattering. Treatment beyond mean field would be animportant future work.
Note added in proof. Recently, we found that the spin-
transfer torque in the presence of spin-orbit interaction inferromagnetic semiconductors was studied in Ref. 26.
ACKNOWLEDGMENTS
The authors thank H. Akai, M. Ogura, and H. Kohno for
their valuable discussions. G.T. acknowledges Grant-in-Aidfor Scientific Research on Priority Areas for their financialsupport. P.E. thanks the SFB491 and the DFG for their finan-cial support.
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064429-6 |
PhysRevB.77.174410.pdf | Shape effects on magnetization state transitions in individual 160-nm diameter Permalloy disks
Zhigang Liu *and Richard D. Sydora
Department of Physics, University of Alberta, Edmonton, Alberta, Canada T6G 2G7
Mark R. Freeman
Department of Physics, University of Alberta, Edmonton, Alberta, Canada T6G 2G7
and National Institute for Nanotechnology, 11421 Saskatchewan Drive, Edmonton, Alberta, Canada T6G 2M9
/H20849Received 29 November 2007; revised manuscript received 4 March 2008; published 8 May 2008 /H20850
The spin dynamics in individual Permalloy nanodisks has been investigated by using time-resolved
magneto-optical Kerr effect microscopy. Transitions between the vortex and quasisingle domain states havebeen observed by sweeping the applied bias field, and the critical bias fields for triggering vortex annihilationand nucleation have been determined by associated frequency shifts of 5–10 GHz in ferromagnetic resonance.The shape of the nanodisks has to be taken into account in three-dimensional micromagnetic simulations toobtain consistent results for the critical fields when compared to the experiment.
DOI: 10.1103/PhysRevB.77.174410 PACS number /H20849s/H20850: 75.75. /H11001a, 75.40.Gb, 75.60.Ej, 76.50. /H11001g
In recent years, remarkable progress has been made in
exploring the equilibrium and dynamic properties of smallmagnetic elements, which is motivated by their applicationsin magnetic storage technology such as magnetoresistive ran-dom access memory.
1,2Many other applications in spintron-
ics, which rely on the spin degree of freedom in electronicdevices, are also based on nanoscale magnetic systems.
3The
demands for a high storage density, a fast processingspeed, and low energy consumption have brought togetherknowledge and techniques to spur the subfield ofnanomagnetism.
4,5
One of the most interesting and useful features of nano-
magnets is their different ground states under certain condi-tions, which can form a technical basis for encoding infor-mation. In general, the ground states result from thecompetition of all terms contributing to the Hamiltonian ofthe system that leads to a minimization of the total energy.The vortex and quasisingle domain states are the two mainconfigurations in a ferromagnetic nanodisk. The demagneti-zation field plays the key role in favoring the vortex configu-ration in low external fields, with the size of the vortex coredetermined by competition with the exchange interaction. By
using methods such as energy functional theory, variationaltheory, and micromagnetic simulation, a variety of analyticaland computational studies were reported to elucidate the dy-namics of the two states and the transitions between them.
6–8
However, a potential problem arises because most theories
and calculations have modeled the nanodisk as a perfect cyl-inder /H20849with a rectangular cross section from the side view /H20850,
while with current fabrication technologies, it is difficult toapproximate the samples in that way. In this paper, we showthat the shape of the nanodisks significantly affects thevortex-to-quasisingle domain state transitions.
Many experimental studies on nanomagnets measure the
total signals from a large number of elements in two-dimensional arrays, self-assembled composite, etc.
9–11Un-
certainties due to size and shape variation, and in some casesdipolar coupling within arrays, can give unclear informationconcerning the behavior of state transitions. Experiments onindividual nanomagnets below 200 nm have recently begunto be reported,
12–14which focused on either the vortex stateor the quasisingle domain state. In this work, we report on
observations for both of these states, which were measuredon individual Permalloy nanodisks with a diameter of about160 nm. Time-resolved magneto-optical Kerr effect micros-copy /H20849TRMOKE /H20850was used to monitor the small-angle per-
turbation response of the magnetization /H20849spin wave dynam-
ics/H20850in the nanodisks. A bias magnetic field was applied
parallel to the disk plane, and a short magnetic pulse wasused to excite the spin waves in the nanodisks. The resonantfrequency is a sensitive fingerprint of the equilibrium mag-netic configuration, providing insight into the details of hys-teresis in small structures complimentary to that obtained bymagnetic force microscopy, Lorentz microscopy, or electronholography.
The Permalloy disks were fabricated on sapphire sub-
strates by standard electron beam lithography /H20849EBL /H20850, metal-
lization, and lift-off procedures. Then, photolithography wasperformed to fabricate gold transmission lines near the Per-malloy disks for excitation. A micrograph of a sample isshown in Fig. 1/H20849a/H20850, wherein the pump-probe measurement
scheme is also sketched. The experimental details, includingthe fast pulse generation using a GaAs photoconductive
switch, are described in previous work
15–17and remain simi-
lar here. The pulse field has both in-plane and out-of-planecomponents since the disks with good signals have to bevery close to the transmission lines; the peak amplitude is inthe range of 10
3A/m, as can be estimated by sampling the
current with a fast oscilloscope and then calculating the fieldwith the Biot–Savart law. Scanning electron microscope/H20849SEM /H20850images of the nanodisks are shown in Figs. 1/H20849b/H20850and
1/H20849c/H20850. The tops of the disks are somewhat domed as a result of
shadowing during deposition through the double-layer resistopenings. The deposited thickness was measured as 30 nm ina witness film. In addition, there is an edge roughness on the10-nm scale that arises from the granularity of the film. Thedistance between neighboring disks is about 900 nm /H20849/H110225
disk diameters /H20850, allowing dipolar interactions to be ne-
glected, and the probing laser was focused on a single disk/H20849spot size of /H11021700 nm /H20850.
The time traces in Fig. 2show the characteristic time-
domain response of the out-of-plane component of magneti-PHYSICAL REVIEW B 77, 174410 /H208492008 /H20850
1098-0121/2008/77 /H2084917/H20850/174410 /H208495/H20850 ©2008 The American Physical Society 174410-1zation /H20849Mz/H20850to the pulsed excitation. The disk is in a single-
domain state when sufficiently saturated by strong bias fieldssuch as H
0=95.5 kA /m in Fig. 2/H20849a/H20850. It should be noted that
there is no extrinsic dephasing due to averaging the signalsfrom an ensemble of magnets. The decay time constant1.8/H110060.3 ns reasonably agrees with those measured in thin
films or bulk Permalloy. At very small bias fields /H20851H
0
=0.24 kA /m in Fig. 2/H20849b/H20850/H20852, the disk is always in a vortexstate, exhibiting much higher modal frequencies than the uni-
formly magnetized state. For intermediate bias fields, dis-torted versions of both the single domain and vortex statescan be stable, depending upon the magnetic history. Figures2/H20849c/H20850and2/H20849d/H20850show the measurements for H
0=39.8 kA /m.
In this case, the magnetization is only partially saturated toform a quasisingle domain or Cstate, as illustrated by the
schematic insets. The bending of the “ C” shape increases
with decreasing bias field until at the nucleation fieldstrength H
nu, the magnetization will close around a core and
generate a vortex state. At low bias fields, the vortex corestays near the center of the disk /H20851inset of Fig. 2/H20849b/H20850/H20852. The core
is pushed toward the edge by increasing H
0until it is ex-
pelled when it reaches the disk edge at the annihilation fieldstrength H
an.
These transitions are identifiable from the measured wave
forms and most conveniently by their frequencies, which areobtained by Fourier transformation. For the quasisingle do-main state, the relatively uniform oscillation is the only sig-nificant mode in the spectra /H20851see the insets of Figs. 2/H20849c/H20850and
2/H20849e/H20850/H20852, and the frequency f
0was given by Guslienko et al.18
by using a modified Kittel’s formula
f0=/H92530
2/H9266/H20881H02+H0Ms/H208511−3 F/H20849/H9252/H20850/H20852, /H208491/H20850
where Msis the saturation magnetization, /H92530is the gyromag-
netic ratio, and F/H20849/H9252/H20850is the effective demagnetizing factor for
a cylinder with /H9252equal to the thickness-to-radius ratio. For
the vortex state, the high-frequency dynamics19exhibits rela-
tively complicated profiles in the frequency domain, and f0is
chosen as the frequency of the primary mode /H20851with the high-
est spectral density; see the insets of Figs. 2/H20849b/H20850and2/H20849d/H20850/H20852; the
observed secondary modes will be discussed below.
The variation in f0as a function of H0are plotted as
squares in Fig. 3/H20849a/H20850. The quasisingle domain state frequen-
cies closely follow the modified Kittel’s formula /H20849gray curve /H20850
except for the low- H0region in which the C-shape configu-
ration leads to significantly lower frequencies than those pre-dicted by assuming an ideal uniform state. When H
0is low-
ered below 29 kA/m, there is a frequency jump of /H1101110 GHz
as a result of a single domain to vortex state transition /H20849vor-
tex nucleation /H20850. If the applied field amplitude is increased
while in the vortex state, the resonance frequency is main-tained at /H1101113 GHz, which is characteristic of Permalloy
disks at this aspect ratio,
20–22until H0is larger than
/H1101140 kA /m, whereupon f0drops to /H1101111 GHz. The lower
frequency is characteristic of a thinner disk and suggests thatthe vortex core is affected by the sloping disk edge. Anabrupt frequency drop of /H110115 GHz is observed when H
0in-
creases to /H1101168 kA /m and registers the vortex to quasisingle
domain transition /H20849vortex annihilation /H20850. The measured nucle-
ation and annihilation fields corresponded within 1 kA/m forrepeated bias field sweeps and had variations of /H110111.6 kA /m
for different disks.
In a single sweeping cycle, it was observed that a transi-
tion can be spontaneously triggered when the bias field wasfixed in the critical region. Figure 4/H20849a/H20850shows an example
when H
0was fixed at 67.4 kA/m. Before the moment re-
corded for the annihilation /H20851marked by the arrow in Fig.
FIG. 1. /H20849Color online /H20850/H20849a/H20850Micrograph of the sample showing the
gold transmission lines /H20849yellow /H20850and the Permalloy patterns /H20849light
green /H20850; the visible Permalloy structures are useful for alignment and
for locating the nanomagnets. The circuit connections forTRMOKE measurement are also sketched, with the photoconduc-tive switch /H20849PCS/H20850on one end of the transmission lines and a bias
voltage on the other end /H20849V=10–15 V /H20850./H20849b/H20850SEM image of the
Permalloy disks captured at a 45° tilted angle. /H20849c/H20850SEM top view of
one of the disks shown in /H20849b/H20850; its diameter is displayed by the
SEM
software, which reads “164.5 nm.”
FIG. 2. /H20851/H20849a/H20850–/H20849d/H20850/H20852Evolutions of Mzas a function of the pump-
probe optical delay time measured under different bias fields andground states /H20849quasisingle domain or vortex /H20850, as illustrated by the
cartoons in each panel. The power spectral densities /H20849PSD/H20850of the
time traces are shown by the insets, with the arrows marking thecharacteristic frequency f
0as the indicator for state transitions dis-
cussed in the text.LIU, SYDORA, AND FREEMAN PHYSICAL REVIEW B 77, 174410 /H208492008 /H20850
174410-24/H20849a/H20850/H20852, the vortex state was sustained for more than 10 min
/H20849each 12 ps delay time step in the pump-probe measurement
took abou t4si n real time /H20850. A similar behavior was also
observed for the vortex nucleation process when H0was
fixed at 29.1 kA/m /H20851Fig.4/H20849b/H20850/H20852; the quasisingle domain state
had survived for more than 10 min before the vortex ap-peared. These facts demonstrate that when measuring asingle nanomagnet, its magnetic properties /H20849not only f
0but
also the magnetization M, the susceptibility /H9273, and so on /H20850in
a single bias field sweep should show an effectively discon-tinuous change when a state transition occurs. In contrast, ifconventional hysteresis data /H20849Mas a function of H
0/H20850were
obtained by averaging over an array,9,23,24these state transi-
tions would appear to be gradually completed within a smallrange of H
0, mostly due to the variation of shape and size
within the array, and hence cannot grasp the details revealedin the present work. Similarly, in time-resolved measure-ments, the spontaneous switching events can only be ob-served by measuring individual nanomagnets; the transitionevents are stochastic among different disks and would pro-duce incoherent temporal data if many disks were collec-tively measured.To better understand the observed state transitions and
frequency data, micromagnetic simulations were performedbased on the Landau–Lifshitz–Gilbert equation.
25In the cal-
culations, Ms=8.2/H11003105A/m,/H92530=1.854 /H110031011s−1T−1,
and the exchange stiffness coefficient A=1.0/H1100310−11J/m. A
large Gilbert damping constant /H9251=1.8 was used for fast
ground state stabilization so that reasonable estimations forH
anand Hnucan be made. The sweep step for the bias field
was 0.8 kA/m near critical fields and was larger for unim-portant regions. Then, in accordance to our experimentalconditions, the excitation pulse was applied to the systemunder a finite temperature T=350 K /H20849an upper-limit estima-
tion, considering the laser heating /H20850and the relaxation dynam-
ics were simulated with the real damping constant
/H9251=0.008
to test the stability of corresponding states and find moreaccurate ranges for H
anand Hnu. The corrections due to these
perturbations were below 0.8 kA/m. The finite-element dis-cretization was done on a 64 /H1100364/H110038 rectangular grid,
26and
two shapes for the nanodisk were used /H20849see the inset of Fig.
3/H20850; a flat-topped cylinder similar to those adopted by the
aforementioned theoretical and computational work and amore realistic “domed” cylinder to qualitatively model theactual samples are shown in Figs. 1/H20849b/H20850and1/H20849c/H20850. For both
models, granular defects of 5–10 nm in size were randomlygenerated at the edges.
Simulation results for the f
0-H0curves are plotted in Fig.
3/H20849a/H20850/H20849circles for the domed cylinder model and triangles for
the flat cylinder model /H20850to compare to the measurements.
Despite small discrepancies in the frequencies, the main fea-tures are reproduced reasonably well, such as the low- H
0
deviation from the modified Kittel’s formula due to the C
state and the small frequency drop when H0/H1102247.8 kA /m.
Concerning the state transitions, the domed model fits theexperiments much better than the flat model. A significantdifference occurs for the vortex annihilation field; the flatcylinder model gives H
an/H1101587.5 kA /m, which reasonably
agrees with the results in Ref. 6, while the domed cylinder
(a)
(b)
FIG. 3. /H20849Color online /H20850Spin wave frequencies of the Permalloy
disk. The measured data are plotted by squares, and the simulatedresults obtained by using the domed cylinder model and the flatcylinder model are plotted as circles and triangles, respectively. /H20849a/H20850
Hysteresis behavior of the primary modal frequency /H20849f
0/H20850as a func-
tion of the bias field /H20849H0/H20850, with the arrows indicating the sweep
direction of the bias field. The representative magnetization statesare also sketched. The inset 3D cartoon shows the shapes of the twomodels. The gray curve is calculated based on Eq. /H208491/H20850/H20849for our
samples,
/H9252=0.375 and F/H20849/H9252/H20850/H110150.1537, see Ref. 18for details /H20850; the
gray dashed curve gives a reference calculation based on the un-modified Kittel’s formula, i.e., F/H20849
/H9252/H20850=0./H20849b/H20850Frequencies of the sec-
ondary modes in the vortex states. The insets show the simulatedmagnitude and phase distributions of the primary mode /H2085113.1 GHz,
see/H20849a/H20850/H20852and the secondary mode /H2084912.4 GHz /H20850when H
0=0. The color
bars /H20849not shown /H20850are scaled by the maximum and minimum of
individual maps.
FIG. 4. /H20849a/H20850The solid curve shows the temporal scan of Mzwith
an abrupt change in the precession behavior, indicating a vortex-to-quasisingle domain transition /H20849marked by the arrow /H20850; the dashed
curve shows an immediately followed scan to confirm the disk wasalready in the quasisingle domain state. The bias field was fixed at67.4 kA/m during the scans. /H20849b/H20850Similar consecutive scans for de-
tecting a quasisingle domain to vortex transition. The bias field wasfixed at 29.1 kA/m.SHAPE EFFECTS ON MAGNETIZATION STATE … PHYSICAL REVIEW B 77, 174410 /H208492008 /H20850
174410-3model leads to a much smaller Han/H1101566.9 kA /m, which is
very close to the measured value. The process can be easilyvisualized through the simulated spatial images, in which thevortex core can reach the round-corner surface at a relativelylow bias field. The upper portion of the core will then begeometrically destabilized by the curved shape, resulting inthe earlier annihilation.
It is also interesting to investigate the distributions of the
vortex-state modes, which, under a specific H
0, exhibit cer-
tain secondary peaks near the primary mode with compa-rable intensities. The measured and simulated results for thesecondary modes are plotted in Fig. 3/H20849b/H20850. These modes, to-
gether with the primary modes shown in Fig. 3/H20849a/H20850, appear to
fill in discrete frequency levels when the bias field increases.This type of mode distribution was intensively investigatedin larger disks wherein spatially resolved measurements werepossible.
20,21The high-frequency vortex state oscillations can
be quantized in radial and azimuthal directions by the num-
ber pair /H20849n,m/H20850, which indexes the orders of specific spin
wave modes. This picture does not cleanly map onto oursmall radius samples with imperfect circular symmetry,where a symmetrical, “uniform” oscillation /H208490, 0/H20850is no
longer an eigenmode of the disk. No radial nodes are foundin simulations, suggesting that n=0 under the present exci-
tation conditions. The multiple peaks in the range of 10–13GHz exhibit stationary phase as well as left- and right-phasecirculation patterns that can only approximately be identifiedwith different azimuthal indices m. The insets of Fig. 3/H20849b/H20850
present the simulated magnitude and phase distributions ofthe 13.1 GHz /H20849primary /H20850and the 12.4 GHz /H20849secondary /H20850modes
when H
0=0. The asymmetry of the structure selects particu-
lar nonuniform modes. The azimuthal distribution is not uni-form for the primary mode, although no nodes are visible. Inaddition, this mode is stationary after being reconstructed inthe time domain by using the method introduced in Ref. 21.
The secondary mode, however, shows a clear quantization/H20849m=4/H20850and is rotating counterclockwise.
When the bias field becomes strong enough
/H20849H
0/H1102245 kA /m/H20850, the primary mode shifts to lower frequen-
cies. This trend indicates an increasing influence of the thin-ner edge of the disk as the vortex is driven far off center. Thedeclining primary mode frequency is more accurately de-scribed by the domed cylinder model than the flat cylindermodel /H20851see the data between 45 and 65 kA/m in Fig. 3/H20849a/H20850/H20852.
For the uniform-to-vortex state transition with decreasing
field /H20849vortex nucleation /H20850, the simulations show that the criti-
cal bias field does nothave significant dependence on the
models with different shapes. The H
nuvalues determined by
both models are consistent with the measurements /H20851Fig.3/H20849a/H20850/H20852
and also agree with the results from other simulation work.6
The nucleation process simulated by the two models can becompared by using the images presented in Fig. 5/H20849for faster
execution, we used
/H9251=1.8 and T=0 K in these calculations,
so the evolution is not on real time scales /H20850. The bias field was
set slightly above the critical range to fully stabilize the qua-sisingle domain state /H20851Figs. 5/H20849a1/H20850and5/H20849b1/H20850/H20852so that a subse-
quent 0.8 kA/m step down can trigger the nucleation process.We found that in both models, the vortex core emerges fromthe bottom edge of the nanodisk /H20849although for the flat cylin-
der model, the bottom and top sides are symmetric in geom-etry/H20850, while the spins near the top of the nanodisk still remain
in quasisingle domain state /H20851Figs. 5/H20849a2/H20850and5/H20849b2/H20850/H20852. Note that
in these two cases, the spins in the nucleation volume precessout of the disk plane before forming a vortex core penetrat-ing the entire thickness. The shape at the top of the disk doesnot affect the early stage of vortex nucleation near the bot-tom, and the nucleation fields produced by the two modelsdiffer by just 1.6 kA/m, which is much smaller than thediscrepancy for the annihilation fields. After the nucleation,the vortex core moves from the edge to its equilibrium loca-tion near the disk center, and its height increases when pass-ing across the edge region /H20851Figs. 5/H20849b3/H20850and5/H20849b5/H20850/H20852.
To summarize, we have measured the time-resolved mag-
netic dynamics in individual Permalloy disks of 160 nm di-ameter. The fundamental mode frequencies of the nanodiskexhibit a distinct hysteresis behavior as a function of thein-plane bias field, and the critical fields for triggering thevortex annihilation and nucleation processes have been
(a1)
(a3)(a2)
(a5)(a4)(b1)
(b3)(b2)
(b5)(b4)
τ= 5.1 nsτ=0
τ= 5.3 nsτ= 5.2 ns
τ= 8.3 nsτ= 6.4 nsτ=0
τ= 6.7 nsτ= 6.6 ns
τ= 9.7 ns
min max
FIG. 5. /H20849Color online /H20850The evolution of magnetization configu-
ration in the vortex nucleation process as simulated by the flat cyl-inder model /H20851/H20849a1/H20850–/H20849a5/H20850/H20852and the domed cylinder model /H20851/H20849b1/H20850–/H20849b5/H20850/H20852.
The disks are stabilized into equilibrium with H
0=29.44 kA /m
/H20849a1/H20850and 27.85 kA/m /H20849b1/H20850, respectively. Then, the bias fields de-
crease to 28.65 and 27.06 kA/m, respectively, to trigger the nucle-ation, representative snapshots are recorded in /H20849a2/H20850–/H20849a5/H20850and/H20849b2/H20850–
/H20849b5/H20850. The
/H9270values are the “effective” time in the simulations with a
large damping constant /H9251=1.8, so these snapshots do not reflect the
real time points /H20849in real time, the evolutions would be much
slower /H20850. In each frame, the intensity of Mzat the top and bottom
layers of the 3D models are shown by the colored surfaces; thecolor bar shows a fixed minimum value /H20849−1, assigned for cells
outside the magnetic disk /H20850and different maximum values for dif-
ferent frames. The small cones between the two surfaces representthe spins in the 3D models that are within the vortex core /H20849the
criterion Mbeing at least 25° off the disk plane /H20850; the colors of these
cones are also scaled with M
z. For clarity, a zoom-in view of the
vortex core is presented aside /H20849b3/H20850.LIU, SYDORA, AND FREEMAN PHYSICAL REVIEW B 77, 174410 /H208492008 /H20850
174410-4determined. The realistic shape of the nanodisk has to be
considered in micromagnetic simulations to explain the mea-sured critical fields. By modifying the shape of the nanodisk,it would be possible to control the annihilation field over aconsiderable range while keeping the nucleation field un-changed, which could be a useful feature for applications.
The methods described in the present work can be applied
to more general nanomagnets, such as rings, squares, ormultilayer elements. Issues on the dynamic transition behav-ior and critical bias fields can be analogously addressed.
These investigations may benefit a variety of nanoscale tech-nologies such as magnetic quantum cellular automata
27that
utilize the magnetization state transitions to store and processinformation.
We thank Hue Nguyen for help with EBL fabrication in
the NanoFab of the University of Alberta. This work wassupported by NSERC, iCORE, CIFAR, and CRC.
*zliu2@ucsc.edu
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netism , edited by B. Heinrich and J. A. C. Bland /H20849Springer, New
York, 2005 /H20850.
2J. Åkerman, Science 308, 508 /H208492005 /H20850.
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2004 /H20850.
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Phys. Rev. B 71, 144407 /H208492005 /H20850.
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10V. V. Kruglyak, A. Barman, R. J. Hicken, J. R. Childress, and J.
A. Katine, J. Appl. Phys. 97, 10A706 /H208492005 /H20850.
11A. V. Jausovec, G. Xiong, and R. P. Cowburn, Appl. Phys. Lett.
88, 052501 /H208492006 /H20850.
12I. N. Krivorotov, N. C. Emley, J. C. Sankey, S. I. Kiselev, D. C.
Ralph, and R. A. Buhrman, Science 307, 228 /H208492005 /H20850.
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14V. S. Pribiag, I. N. Krivorotov, G. D. Fuchs, P. M. Braganca, O.
Ozatay, J. C. Sankey, D. C. Ralph, and R. A. Buhrman, Nat.Phys. 3, 498 /H208492007 /H20850.
15K. S. Buchanan, X. Zhu, A. Meldrum, and M. R. Freeman, Nano
Lett. 5, 383 /H208492005 /H20850.16X. Zhu, Z. Liu, V. Metlushko, P. Grütter, and M. R. Freeman,
Phys. Rev. B 71, 180408 /H20849R/H20850/H208492005 /H20850.
17Z. Liu, F. Giesen, X. Zhu, R. D. Sydora, and M. R. Freeman,
Phys. Rev. Lett. 98, 087201 /H208492007 /H20850.
18K. Yu. Guslienko and A. N. Slavin, J. Appl. Phys. 87, 6337
/H208492000 /H20850.
19The gyrotropic motion of the vortex core, with a low frequency
of/H110111 GHz, is also visible in some of our measurements, such
as, for example, in Fig. 2/H20849b/H20850.
20J. P. Park and P. A. Crowell, Phys. Rev. Lett. 95, 167201 /H208492005 /H20850.
21M. Buess, R. Höllinger, T. Haug, K. Perzlmaier, U. Krey, D.
Pescia, M. R. Scheinfein, D. Weiss, and C. H. Back, Phys. Rev.Lett. 93, 077207 /H208492004 /H20850.
22C. E. Zaspel, B. A. Ivanov, J. P. Park, and P. A. Crowell, Phys.
Rev. B 72, 024427 /H208492005 /H20850.
23R. P. Cowburn, J. Phys. D 33,R 1 /H208492000 /H20850.
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Shima, Y. Otani, and K. Fukamichi, Phys. Rev. B 65, 172419
/H208492002 /H20850.
25We used our own micromagnetics code /H20851Z. Liu, Ph.D. thesis,
University of Alberta, 2008 /H20852.This was benchmarked against M.
Scheinfein’s, LLG Micromagnetics Simulator™ /H20849http://
llgmicro.home.mindspring.com/ /H20850. The code has also been
checked by using OOMMF’s standard problem No. 4 /H20849http://
www.ctcms.nist.gov/~rdm/mumag.org.html /H20850.
26Test simulations were also performed with 32 /H1100332/H110038 and 64
/H1100364/H1100316 grid dimensions, and the results did not show a sig-
nificant difference.
27A. Imre, G. Csaba, L. Ji, A. Orlov, G. H. Bernstein, and W.
Porod, Science 311, 205 /H208492006 /H20850.SHAPE EFFECTS ON MAGNETIZATION STATE … PHYSICAL REVIEW B 77, 174410 /H208492008 /H20850
174410-5 |
PhysRevLett.108.074501.pdf | Turbulence in Noninteger Dimensions by Fractal Fourier Decimation
Uriel Frisch,1Anna Pomyalov,2Itamar Procaccia,2and Samriddhi Sankar Ray1
1UNS, CNRS, OCA, Laboratoire Lagrange, Boı ˆte Postale 4229, 06304 Nice Cedex 4, France
2Department of Chemical Physics, The Weizmann Institute of Science, Rehovot 76100, Israel
(Received 5 August 2011; published 13 February 2012)
Fractal decimation reduces the effective dimensionality Dof a flow by keeping only a (randomly
chosen) set of Fourier modes whose number in a ball of radius kis proportional to kDfor large k. At the
critical dimension Dc¼4=3there is an equilibrium Gibbs state with a k/C05=3spectrum, as in V. L’vov
et al. ,Phys. Rev. Lett. 89, 064501 (2002) . Spectral simulations of fractally decimated two-dimensional
turbulence show that the inverse cascade persists below D¼2with a rapidly rising Kolmogorov constant,
likely to diverge as ðD/C04=3Þ/C02=3.
DOI: 10.1103/PhysRevLett.108.074501 PACS numbers: 47.27.Gs, 05.20.Jj
In theoretical physics a number of results have been
obtained by extending the dimension dof space from
directly relevant values such as 1, 2, 3 to noninteger values.Dimensional regularization in field theory [ 1] and the
4/C0/C15expansion in critical phenomena [ 2] are well-known
instances. For this, one usually expands the solution in
terms of Feynman diagrams, each of which can be analyti-
cally continued to real or complex values of d. The same
kind of extension can be carried out for homogeneousisotropic turbulence but a severe difficulty appears thenford<2: the energy spectrum EðkÞcan become negative
in some band of wave numbers k, so that this kind
of extension lacks probabilistic realizability [ 3].
Nevertheless, in Ref. [ 4], henceforth cited as LPP, it is
argued that, should there exist an alternative realizable way
of doing the extension below dimension two in which thenonlinearity conserves energy and enstrophy, then an in-teresting phenomenon—to which we shall come back—should happen in dimension 4=3.
For diffusion and phase transitions there is a very differ-
ent way of switching to noninteger dimensions, namely, toreformulate the problem on a fractal of dimension D(here
a capital Dwill always be a fractal dimension) [ 5]. Are we
able to do this for hydrodynamics ? Implementing mass and
momentum conservation on a fractal is quite a challenge[6]. We discovered a new way of fractal decimation in
Fourier space, appropriate for hydrodynamics. Since,here, we are primarily interested in dimensions less thantwo, we shall do our decimation starting from the standardd¼2case.
The forced incompressible Navier-Stokes equations for
the velocity field can be written in abstract notation as
@
tu¼Bðu;uÞþfþ/C3u; (1)
Bðu;uÞ¼/C0 u/C1ruþrp; /C3¼/C23r2; (2)
where ustands for the velocity field uðx1;x2;tÞ,ffor the
force fðx1;x2;tÞ,pis the pressure and /C23the viscosity. The
velocity uis taken in the space of divergenceless velocityfields which are 2/C25periodic in x1andx2, such that
uðt¼0Þ¼u0. Now, we define a Fourier decimation op-
erator PDon this space of velocity fields:
Ifu¼X
k2Z2eik/C1x^uk;thenPDu¼X
k2Z2eik/C1x/C18k^uk:(3)
Here, /C18kare random numbers such that
/C18k¼/C261with probability hk
0with probability 1/C0hk;k/C17jkj:(4)
To obtain D-dimensional dynamics we choose
hk¼Cðk=k 0ÞD/C02; 0<D /C202; 0<C/C201;(5)
where k0is a reference wave number; here C¼k0¼1.
All the /C18kare chosen independently, except that /C18k¼/C18/C0k
to preserve Hermitian symmetry. Our fractal decimation
procedure removes at random—but in a time-frozen(quenched) way—many modes from the klattice, leaving
on average NðkÞ/k
Dactive modes in a disk of radius k.
The randomness in the choice of the decimation will becalled the disorder.
Observe that P
Dis a projector, that it commutes with
the viscous diffusion operator /C3and that it is self-adjoint
for the energy ( L2) norm, defined as usual as kuk2/C17
ð1=ð2/C25Þ2ÞRjuðxÞj2d2x, where the integral is over a 2/C25/C2
2/C25periodicity square. The conservation of energy (by
the nonlinear term) for sufficiently smooth solutions ofthe Navier-Stokes equation can be expressed asðu;Bðu;uÞÞ¼0, where ðu;wÞ/C17ð1=ð2/C25Þ
2ÞRuðxÞ/C1wðxÞd2x
is the L2scalar product.
The decimated Navier-Stokes equation , written for an
incompressible field v, takes the following form
@tv¼PDBðv;vÞþPDfþPD/C3v: (6)
The initial condition is v0/C17vðt¼0Þ¼PDu0. Thus, at
any later time PDv¼v. Energy is again conserved; indeed
ðv;PDBðv;vÞÞ¼0, as is seen by moving the self-adjoint
operator PDto the left hand side of the scalar product and
using PDv¼v. For enstrophy conservation, take the curlPRL 108, 074501 (2012) PHYSICAL REVIEW LETTERSweek ending
17 FEBRUARY 2012
0031-9007 =12=108(7) =074501(4) 074501-1 /C2112012 American Physical Societyof (1); the quadratically nonlinear term in the vorticity
equation is then Bvortð!; !Þ/C17/C0 u/C1r!, where uis ex-
pressed in terms of !by Biot–Savart. The relation
ð!; B vortð!; !ÞÞ¼0expresses enstrophy conservation. In
the decimated case, the proof of enstrophy conservation isidentical to that for energy conservation with Breplaced by
B
vort.
If, in addition to decimation, we apply a Galerkin trun-
cation which kills all the modes having wave numbersbeyond a threshold K
G, the surviving modes constitute a
dynamical system having a finite number of degrees of
freedom. Such truncated systems with no forcing and no
viscosity have been studied by Lee, Kraichnan and others[8]. Using suitable variables related to the real and imagi-
nary parts of the active modes, the dynamical equationsmay be written as _y
/C11¼P
/C12/C13A/C11/C12/C13y/C12y/C13.
For the purely Galerkin-truncated (not decimated) case
it is well known that the above dynamical system satisfies aLiouville theoremP
/C11@_y/C11=@y/C11¼0and thus conserves
volume in phase space. This in turn implies the existenceof (statistically) invariant Gibbs states for which the proba-
bility is a Gaussian, proportional to e
/C0ð/C11Eþ/C12/C10Þ, where
E¼P
kj^ukj2is the energy and /C10¼P
kk2j^ukj2is the ens-
trophy. Such Gibbs states , called by Kraichnan absolute
equilibria , play an important role in his theory of the two-
dimensional (2D) inverse energy cascade [ 9]. If we now
combine inviscid, unforced Galerkin truncation and deci-mation, it is easily checked that the Liouville theorem still
holds, provided the decimation preserves Hermitean sym-
metry. For such Gibbs states, and any active mode ( /C18
k¼
1), one easily checks that the mean square energy hjukj2i¼
C0=ð/C11þ/C12k2Þ, where C0>0does not depend on k. The
corresponding energy spectrum is the mean energy EðkÞof
modes having a wave number between kandkþ1.U pt o
fluctuations of the disorder, the number of active modes insuch a shell is Oðk
D/C01Þ. Thus,
EðkÞ¼kD/C01
/C11þ/C12k2; /C12> 0;/C11 > /C0/C12; (7)
where various positive constants have been absorbed into a
new definition of /C11and/C12. An instance is enstrophy
equipartition :/C11¼0(all the modes have the same ens-
trophy), for which the energy spectrum is EðkÞ/kD/C03.A s
observed in LPP, this equilibrium spectrum coincides with
the Kolmogorov 1941 k/C05=3spectrum at the critical dimen-
sionDc¼4=3. Note that such Gibbs states are only condi-
tionally Gaussian, for a given disorder. Otherwise, they arehighly intermittent, since a given high- kmode will be
active only in a small fraction of the disorder realizations.We also note that similar phenomena have been observedin shell models [ 10].
The form ( 7) of the D-dimensional absolute equilibria
also allows for the kind of Bose condensation in the gravest
modes (here, those with unit wave number) found by
Kraichnan for 2D turbulence. For this the ‘‘inversetemperature’’ /C11must be taken negative, close to its mini-
mum realizable value /C0/C12. The arguments used by
Kraichnan to predict an inverse Kolmogorov k
/C05=3energy
cascade for high-Reynolds number 2D turbulence withforcing near an intermediate wave number k
injcarry over
to the decimated case with D< 2. In particular the con-
servation of enstrophy blocks energy transfer to high wavenumbers. This in itself does not imply that the energy willcascade to wave numbers smaller than k
inj, producing a
k-independent energy flux: it might also linger around and
accumulate near kinj.
It is now our purpose to show that for 4=3<D /C202,
when the energy spectrum is prescribed to be EðkÞ¼k/C05=3
over the inertial range, there is a negative energy flux /C5E,
vanishing linearly with D/C04=3near the critical dimen-
sionDc¼4=3. For this we shall assume that a key feature
of the two-dimensional energy cascade carries over tolower dimensions, namely, the existence of scaling solu-tions with local (in Fourier space) dynamics, so that theenergy transfer is dominated by triads of wave numbers
with comparable magnitudes. Let us now decompose the
energy inertial range into bands of fixed relative width, sayone octave, delimited by the wave numbers 2
0,21,22, etc.
Because of locality there is much intraband dynamics but,of course, interband interactions are needed to obtain anenergy flux. Pure intraband dynamics (with no forcingand dissipation) would lead to thermalization. For dimen-sional reasons, thermalization and interband transfer have
the same time scale, namely, the eddy turnover time
k
/C03=2E/C01=2ðkÞ.
To get a handle on the combined intraband and interband
dynamics we perform a thermodynamic thought experi-
ment in which we artificially separate them in time. In the
first phase, starting from a k/C05=3spectrum we prevent the
various bands from interacting by introducing (impene-trable) interband barriers at their edges. In each band, themodes will then thermalize and achieve a Gibbs state with
a spectrum ( 7) in which /C11and/C12are determined by the
constraints that the total band energy and enstrophy be thesame as for the /C05=3spectrum. For example, in the first
band this gives the constraints ( n¼0for the energy and
n¼2for the enstrophy)
Z
2
1dkkn½kD/C01=ð/C11þ/C12k2Þ/C0k/C05=3/C138¼0; (8)
a system of two transcendental equations for the parame-
ters/C11and/C12, which we solved numerically. For D¼2, the
corresponding absolute equilibrium spectrum, obtained bysubstituting these values in ( 7), is shown in Fig. 1, together
with the /C05=3spectrum. The two spectra are very close to
each other. Specifically, in 2D the absolute equilibriumspectrum exceeds the /C05=3spectrum by about 10% at
any lower band edge and by about 5% at any upper band
edge. Of course, as we approach the critical dimension
D
c¼4=3the discrepancy goes to zero and can easily bePRL 108, 074501 (2012) PHYSICAL REVIEW LETTERSweek ending
17 FEBRUARY 2012
074501-2calculated perturbatively in D/C04=3. In the second phase
of our thought experiment, we consider two adjacentbands, e.g., [ 2
0,21] and [ 21,22] that have thermalized,
starting from the same k/C05=3spectrum and we remove the
interband barrier at 21. A new thermalization leads then to
an absolute equilibrium in the band [ 20,22], which again,
can be easily calculated. In 2D, before the removal, theenergy between 2
0and21was 0.555. After the new ther-
malization, this energy is found to have increased by
0.005 51. Thus energy has been transferred from the upperband [ 2
1,22] to the lower band [ 20,21]. Close to Dc¼4=3,
we can again apply elementary perturbation techniques andobtain for the upper-to-lower-band energy transfer0:009ðD/C04=3Þto leading order. Our thermodynamic
thought experiment thus suggests that the energy fluxvanishes linearly with D/C04=3, being negative above the
critical dimension, which implies an inverse cascade.Variants of this thought experiment involving more bandsgive similar results. In the K41 inertial range, the energy
spectrum and the energy flux /C5
Eare related by EðkÞ¼
CKolj/C5Ej2=3k/C05=3, where CKolis the Kolmogorov constant;
thus the Kolmogorov constant diverges as ðD/C04=3Þ/C02=3.
A closure calculation of eddy-damped quasinormalMarkovian (EDQNM) type also predicts a divergence
with a /C02=3exponent.
Kraichnan’s ideas about the inverse cascade in 2D got
growing support a few years later from direct numerical
simulations, which eventually achieved the resolution of
32 768
2modes [ 11]. As to our idea about the robustness of
the inverse cascade and the growth of the Kolmogorovconstant when lowering the dimension D, some support
can be already provided, using a D-dimensional decimated
variant of spectral direct numerical simulation: First onegenerates an instance of the disorder, that is the list ofactive and inactive Fourier modes; then, one applies stan-dard time marching algorithms and, at each time step, setsto zero all inactive modes. In addition to the well-knowndifficulties of simulating 2D turbulence (see, e.g., [ 11] and
references therein), there are new difficulties.A few words about the numerical implementation. We
integrate the decimated Navier-Stokes Eq. ( 6) in vorticity
representation. Instead of using as damping the viscous
operator /C3¼/C23/C1(where /C1/C17r
2is the Laplacian), we use
/C3/C17/C0/C23/C1þ2/C0/C22/C1/C02;/C23 > 0;/C22 > 0;(9)
whose Fourier symbol is /C0/C23k4/C0/C22k/C04. In other words,
we use hyperviscosity to avoid wasting resolution on theenstrophy cascade and large-scale friction to prevent anaccumulation of energy on the gravest modes and thusallow eventual convergence to a statistical steady state.The results reported here have a resolution of N¼3072
collocation points in the two coordinates. Time marching is
done by an Adams-Bashforth scheme combined with ex-
ponential time difference (ETD) [ 12] with a time step
between 5/C210
/C05and 10/C04, depending on dimension.
Energy injection at the rate "is done in a band of width
three around kinj¼319 by adding to the time rate of
change of the Fourier amplitude of the vorticity a term
proportional to the inverse of its complex conjugate [ 13].
This allows a k-independent and time-independent energy
injection. As Dis decreased the amplitude of this forcing is
increased to keep the total energy injection on active
modes fixed at "¼0:01. The damping parameters are
/C23¼10/C011and/C22¼0:1. Runs are done concurrently for
different values of Don a high-performance cluster at the
Weizmann Institute and take typically a few thousand
hours of CPU per run to achieve a statistical steady state.
Energy spectra are obtained by angular averages over
Fourier-space shells of unit width
EðKÞ/C171
2X
K/C20k<Kþ1j^vðkÞj2; (10)1.0 1.2 1.4 1.6 1.8 2.0k0.40.60.81.0Ek
FIG. 1 (color online). The k/C05=3spectrum (continuous) and the
associated 2D absolute equilibrium with the same energy and
enstrophy in the first octave (dashed).
0.5 1 1.5 2 2.5 3012
log10 kE(k)k5/3
1.6 1.8 200.511.5
DPlateauD=1.5
D=2
FIG. 2 (color online). Compensated steady-state spectra for
D¼2:0, 1.9, 1.8, 1.7, 1.6, 1.5 from bottom to top with spikes
at injection. The inset shows the dependence on Dof the plateau
of the compensated spectra, as an average over the interval
between vertical dashed lines (with standard deviation errorbars).PRL 108, 074501 (2012) PHYSICAL REVIEW LETTERSweek ending
17 FEBRUARY 2012
074501-3where the ^vðkÞare the Fourier coefficients of the solution
of the decimated Navier-Stokes Eq. ( 6). We also need the
energy flux /C5EðKÞthrough wave number Kdue to non-
linear transfer, defined as
/C5EðKÞ/C17X
k/C20K^v/C3ðkÞ/C1cNLðkÞ; (11)
where cNLðkÞdenotes the set of Fourier coefficients of the
nonlinear term PDBðv;vÞin the decimated Navier-Stokes
Eq. ( 6) and the asterisk denotes complex conjugation.
EðkÞand /C5EðKÞare mostly insensitive to the disorder
realization.
Figures 2and3(inset) show the steady-state compen-
sated energy spectra k5=3EðkÞand the energy fluxes /C5EðkÞ,
for various values of Dbetween 2 and 1.5, respectively.
Both are quite flat, over a significant range of kvalues,
evidence that D-dimensional forced turbulence, Fourier
decimated down from the two-dimensional case, preservesthe key feature of two-dimensional turbulence of having aninverse cascade that follows the /C05=3law. Note that the
inertial range (the flat region of the compensated energyspectrum) shrinks as the dimension Ddecreases. The
absolute value of the energy flux is about 80% of theenergy injection "forD¼2, but drops to less than 50%
forD¼1:5. Indeed, as the dimension Dis lowered, there
are fewer and fewer pairs of active modes in the forcing
band, capable through their beating interaction of drainingthe energy into the infrared direction; thus the energyinjection will be more and more balanced by direct dis-sipation near injection. Preventing this would require asubstantial lowering of the dissipation which in turn re-quires a substantial increase in the resolution at the high- k
end. Anyway, the fact that the flux j/C5
Ejbecomes substan-
tially lower than injection does not prevent us from calcu-lating the Kolmogorov constant, given (in terms of plateau
values) by C
Kol¼k5=3EðkÞ=ðj/C5EðkÞj2=3Þ. Figure 3shows
the variation of the Kolmogorov constant with dimension.When lowering the dimension from 2 to 1.5, a combined
effect of a rise in the compensated spectrum and a drop influx yields a monotonic growth of about a factor ten in the
Kolmogorov constant and a substantial growth of errors
due to fluctuations within the averaging interval. Probingthe conjectured divergence by moving closer to the criticalpoint D
c¼4=3would require much higher resolution. A
state-of-the-art 16 3842simulation of sufficient length
might shed light.
We finally observe that the fractal Fourier decimation
procedure—that allows numerical experimentation by
spectral simulation—can be started from any integer di-
mension and can be applied to a large class of problems incompressible and incompressible hydrodynamics andMHD. It is also applicable to other problems in nonlineardynamics and condensed matter physics, such as criticaldynamical phenomena [ 14], Kardar–Parisi–Zhang dynam-
ics [15], and nonlinear wave interactions [ 16].
We are grateful to E. Aurell, H. Chen, H. Frisch, B.
Khesin, V. L’vov, T. Matsumoto, S. Musacchio, S.
Nazarenko, R. Pandit, and W. Pauls for useful discussions.U. F. and S. S. R.’s work was supported by ANR OTARIEBLAN07-2_183172. A. P. and I. P.’s work was supportedby the Minerva Foundation, Munich, Germany.
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[16] V. E. Zakharov, V. S. L’vov, and G. Falkovich, Kolmogorov
Spectra of Turbulence (Springer-Verlag, Berlin, 1992).1.5 1.6 1.7 1.8 1.9 2103050
DCKol
11 . 522 . 5−1−0.50
log10 kΠE(K)/εD=1.5
D=2
FIG. 3 (color online). Dependence of the Kolmogorov con-
stant on D. The lowest value, at D¼2, is about 5. The inset
shows the energy flux normalized by the energy injection "for
the same values of Das in Fig. 2.PRL 108, 074501 (2012) PHYSICAL REVIEW LETTERSweek ending
17 FEBRUARY 2012
074501-4 |
PhysRevB.99.014431.pdf | PHYSICAL REVIEW B 99, 014431 (2019)
Ferromagnetic resonance and control of magnetic anisotropy by epitaxial strain in the
ferromagnetic semiconductor (Ga 0.8,Fe0.2)Sb at room temperature
Shobhit Goel,1,*Le Duc Anh,1,2,†Shinobu Ohya,1,2,3,‡and Masaaki Tanaka1,3,§
1Department of Electrical Engineering and Information Systems, The University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-8656, Japan
2Institute of Engineering Innovation, The University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-8656, Japan
3Center for Spintronics Research Network (CSRN), The University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-8656, Japan
(Received 2 July 2018; revised manuscript received 21 November 2018; published 25 January 2019)
We study the strain dependence of the magnetic anisotropy of room-temperature ferromagnetic semiconductor
(Ga 1-x,Fex)Sb (x=20%) thin films epitaxially grown on different buffer layers, using ferromagnetic resonance
measurements. We show that the magnetocrystalline anisotropy ( Ki)i n( G a 0.8,Fe0.2)Sb exhibits a dependence
on the epitaxial strain and changes its sign from negative (in-plane magnetization easy axis) to positive(perpendicular magnetization easy axis), when the strain is changed from tensile to compressive. Meanwhile,the shape anisotropy ( K
sh) is negative and dominant over Ki. Therefore, the effective magnetic anisotropy
(Keff=Ki+Ksh) is always negative, leading to the in-plane magnetic anisotropy in all the (Ga 0.8,Fe0.2)Sb
samples. This work demonstrates ferromagnetic resonance and strong shape anisotropy at room temperature inIII-V ferromagnetic semiconductors. We also observed very high Curie temperature ( T
C/greaterorsimilar400 K) in p-type
(Ga,Fe)Sb, which is the highest TCreported so far in III-V based ferromagnetic semiconductors.
DOI: 10.1103/PhysRevB.99.014431
I. INTRODUCTION
Ferromagnetic semiconductors (FMSs) have attracted
much attention since they exhibit both semiconducting andferromagnetic properties, which provide a straightforward ap-proach for integrating spin-dependent phenomena into semi-conductor devices. From FMS thin films, one can inject aspin-polarized current into a nonmagnetic semiconductor us-ing methods such as electrical spin injection [ 1–4] and spin
pumping [ 5], without suffering from severe problems such as
conductivity mismatch and interface roughness as seen in gen-eral ferromagnetic metal-semiconductor contacts [ 1,2]. This
good compatibility with conventional semiconductor technol-ogy is very important for the realization of semiconductorspintronic devices with nonvolatile functions and low powerdissipation [ 6–11]. Thus far, the mainstream studies of FMSs
are based on the Mn-doped III-V FMSs such as (Ga,Mn)As.These Mn-doped FMSs, however, maintain ferromagneticorder only at low temperature (the highest Curie temperatureT
Cis 200 K in (Ga,Mn)As [ 12]) and they have strong magne-
tocrystalline anisotropy, which results in a difficulty to controlthe magnetization by nanofabrication processing. Besides,Mn-doped FMSs are only p-type because Mn acts as an
acceptor in III-V semiconductors. These are severe drawbacksthat hinder the use of FMSs in practical spintronic devices.
Recently, we found that Fe-doped narrow-gap III-V FMSs
can be promising alternatives to overcome the problems ofthe Mn-based FMSs. By using Fe as the magnetic dopants,
*goel@cryst.t.u-tokyo.ac.jp
†anh@cryst.t.u-tokyo.ac.jp
‡ohya@cryst.t.u-tokyo.ac.jp
§masaaki@ee.t.u-tokyo.ac.jpone can grow both n-type FMSs ((In,Fe)As [ 13–15], (In,Fe)Sb
[16]) and p-type FMSs ((Al,Fe)Sb [ 17], (Ga,Fe)Sb [ 18,19])
because Fe atoms are in the isoelectronic Fe3+state and
do not supply carriers. The most notable feature in the Fe-doped FMSs is their very high T
C: Intrinsic room-temperature
ferromagnetism has been confirmed in (Ga 1-x,Fex)Sb thin
films with the Fe density x/greaterorequalslant23% [ 18], and in (In 1-x,Fex)Sb
thin films with x/greaterorequalslant16% [ 16]. Therefore, these new Fe-doped
FMSs are expected to be useful materials for spintronic deviceapplications at room temperature.
In this paper, we study the growth and magnetic anisotropy
(MA) of (Ga
1-x,Fex)Sb (x=0.2) thin films epitaxially grown
on different buffer layers and thus subjected to differentepitaxial strains. MA plays an important role in control-ling the magnetization of the ferromagnetic (FM) thin films,which is a fundamental operation of magnetic/spintronic de-vices. Understanding and controlling the MA, thus, are es-sential for device applications of (Ga,Fe)Sb. In the past, re-searchers successfully observed and controlled the MA of theMn-doped III-V FMSs, (Ga,Mn)As [ 20–28] and (In,Mn)As
[29–31] ferromagnetic thin films, by epitaxial strain. These
Mn-doped FMSs showed a perpendicular-magnetization easyaxis under tensile strain, and an in-plane-magnetization easyaxis under compressive strain. In this work, we have grown
(Ga
0.8,Fe0.2)Sb thin films on four different buffer layers
(AlSb, GaSb, In 0.5Ga0.5As, and GaAs) by molecular beam
epitaxy (MBE) to induce different epitaxial strains rangingfrom tensile to compressive, and examined its effect on theMA of these (Ga
0.8,Fe0.2)Sb thin films.
We performed ferromagnetic resonance (FMR) measure-
ments to investigate the MA fields of the (Ga 0.8,Fe0.2)Sb
thin films. FMR is not only one of the most efficient andpowerful techniques to observe the MA [ 32], but is also used
for spin pumping to inject spin angular momentum (spin
2469-9950/2019/99(1)/014431(7) 014431-1 ©2019 American Physical SocietyGOEL, ANH, OHYA, AND TANAKA PHYSICAL REVIEW B 99, 014431 (2019)
TABLE I. Epitaxial strain ( ε) estimated from XRD, saturation magnetization ( μ0Ms) measured by SQUID, effective magnetization
(μ0Meff), magnetocrystalline anisotropy field ( Hi), and gfactor obtained by the fitting to the FMR spectra of (Ga 0.8,Fe0.2) S bi ns a m p l e s
A–D with different buffer layers.
Sample Buffer ε(%) μ0MS(mT) μ0Meff(mT) Hi(Oe) gfactor
A AlSb −1.7 89.9 104 .3±0.5 −144±52 .08±0.03
B GaSb −0.1 77.9 90 .4±0.1 −125±12 .07±0.03
CI n 0.5Ga0.5As +0.23 59.8 37 .1±0.2 227 ±22 .1±0.03
D GaAs +3.84 66.3 32 .3±0.2 340 ±22 .11±0.03
current) from an FM material into nonmagnetic metals and
semiconductors. Therefore, observing FMR in the (Ga,Fe)Sbthin films, particularly at room temperature, is a fundamentaland important step to examine this material as a spin injectorin practical spin devices. Here, we measured the dependenceof the FMR resonance field on the external magnetic fielddirection and fitted a theoretical curve to the data to obtainthe MA fields of the (Ga,Fe)Sb thin films. We performedcareful analyses of the MA to separate the shape anisotropy(K
sh), which is due to the dipole-dipole interactions, and
the magnetocrystalline anisotropy ( Ki), which is due to the
spin-orbit interactions, and discussed the effect of epitaxialstrain on these two components.
II. SAMPLE GROWTH AND CHARACTERIZATIONS
We have grown a series of four samples A–D of p-type
FMS (Ga,Fe)Sb thin films on semi-insulating GaAs (001)substrates by low-temperature molecular beam epitaxy (LT-MBE), whose buffer layers and properties are given in Table I.
The schematic structure of our samples is shown in Fig. 1(a).
In samples A, B, and C, on a semi-insulating GaAs (001)substrate, we first grew a 100-nm-thick GaAs layer at asubstrate temperature T
S=550◦C to obtain an atomically
flat surface; next we grew a 10-nm-thick AlAs layer at thesame T
S. Then, we grew a thick buffer layer, which is a
300-nm-thick AlSb layer at TS=470◦C for sample A, a
300-nm-thick GaSb layer at TS=470◦C for sample B, and
a 500-nm-thick In 0.5Ga0.5As layer at TS=550◦Cf o rs a m p l e
C. For sample D, a 500-nm-thick GaAs buffer layer wasgrown directly on a semi-insulating GaAs (001) substrate atT
S=550◦C. Finally, we grew a 15-nm-thick (Ga 1-x,Fex)Sb
layer with a Fe concentration of x=20% at a growth rate of
0.5μm/h and an Sb beam equivalent pressure of 7 .8×10−5
Pa atTS=250◦C for all the samples. As shown in Fig. 1(b),
in situ reflection high-energy electron diffraction (RHEED)
patterns in the [ ¯110] direction of the (Ga,Fe)Sb thin films in all
four samples are bright and streaky, thereby indicating goodtwo-dimensional growth of a zinc-blende crystal structure.In this way, we obtained high-quality (Ga,Fe)Sb thin films,whose quality is better than that of our previous reports[18,19] because we optimized the MBE growth conditions:
The properties of (Ga,Fe)Sb depend on the Sb pressure duringthe MBE growth and we found that by keeping a higher Sb
4
pressure at 7 .8×10−5Pa in the MBE growth chamber before
Ga and Fe fluxes were supplied, we obtained high TC>300 K
in (Ga 1-x,Fex)Sb with a lower Fe concentration of x=20%
(this is an improvement from our previous reports [ 18,19]).We characterized the crystal structures and lattice constants
of all the (Ga,Fe)Sb thin films and buffer layers by x-raydiffraction (XRD). Figures 2(a)–2(d) show the XRD results
of samples A–D, respectively. All the samples show a sharpGaAs (004) peak. In samples A, B, and C, there is a broaderpeak which can be deconvoluted into two Gaussian peakscorresponding to the buffer layer and (Ga,Fe)Sb (004). Insample D, the (Ga,Fe)Sb (004) peak can be clearly seen. Fromthe peak positions, we estimated the intrinsic lattice constantsof (Ga,Fe)Sb ( a
GaFeSb ) and of the buffer layer ( abuffer) (see
Supplemental Material [ 33]). We define the epitaxial strain ε
asaGaFeSb−abuffer
aGaFeSb×100 (%). As listed in Table I, the estimated
FIG. 1. (a) Schematic illustration of the (001)-oriented sample
structure composed of (Ga 1-x,Fex)Sb grown on different buffer lay-
ers on a semi-insulating GaAs(001) substrate. (b) In situ reflection
high-energy electron diffraction (RHEED) patterns observed along
the [¯110] axis during the MBE growth of the 15-nm-thick (Ga,Fe)Sb
thin films on AlSb (sample A), GaSb (sample B), In 0.5Ga0.5As (sam-
ple C), and GaAs (sample D) buffer layers. (c) Sample alignment
and coordinate system used in the ferromagnetic resonance (FMR)
measurement system. A radio-frequency (rf) magnetic field hwas
applied along the [ ¯110] direction of the sample. θHandθMare the
angles of the magnetic field Hand the magnetization Mwith respect
to the [001] direction, respectively.
014431-2FERROMAGNETIC RESONANCE AND CONTROL OF … PHYSICAL REVIEW B 99, 014431 (2019)
FIG. 2. X-ray diffraction rocking curves of samples A–D. The
broad peak in sample A–C was fitted by the Gaussian curves cor-responding to the peaks of the (Ga,Fe)Sb thin film (red dotted line)
and of the buffer layers of (a) AlSb (yellow dotted line), (b) GaSb
(pink dotted line), and (c) In
0.5Ga0.5As (green dotted line). The sum
of the two curves is the fitting curve which is plotted by the violet
dashed line. (d) In sample D, the (Ga,Fe)Sb (004) peak (blue-violet
dashed line) can be clearly seen. For each sample, the epitaxial strain
(ε%) was estimated (see Supplemental Material [ 33]) and shown in
the figure.
values of εindicate that the (Ga,Fe)Sb films can have both
tensile and compressive strains when they are grown ondifferent buffer layers. Here, samples A ( ε=−1.7%, AlSb
buffer layer) and B ( ε=−0.1%, GaSb buffer layer) have
tensile strain, whereas samples C ( ε=0.23%, In
0.5Ga0.5As
buffer layer) and D ( ε=3.84%, GaAs buffer layer) have
compressive strain. These results demonstrate that we cansystematically vary the epitaxial strain of (Ga,Fe)Sb in awide range, from tensile to compressive, by growing it onappropriate buffer layers.
Next, we characterized the magnetic properties of all the
samples using magnetic circular dichroism (MCD) spec-troscopy and superconducting quantum interference device(SQUID) magnetometry. As shown in Figs. 3(a)–3(h),t h e
magnetic field dependences of MCD (MCD– Hcurves) show
clear hysteresis, and the Arrott plots indicate that T
Cis higher
than 320 K in all the samples. Here the MCD intensity wasmeasured at the E
1peak ( ∼2.1 eV). To estimate the exact
value of TC, we measured remanent magnetization versus
temperature ( M−T) curves up to 400 K (see Supplemental
Material [ 33]). It is shown that the remanent magnetization
is still present even at 400 K. We have also measured mag-netization hysteresis ( M−H) curves at 400 K, as shown in
Figs. 4(a)–4(d), in which we can see clear remanent magneti-
zation. Therefore, T
Cis higher than 400 K. These results prove
that the room-temperature ferromagnetism is obtained in allfour (Ga,Fe)Sb samples with the Fe concentration of 20%.
Figures 5(a)–5(d) show the magnetic field dependence of
the magnetization ( M−H)o f( G a
0.8,Fe0.2)Sb measured for
samples A–D at 50 K, with a magnetic field Happlied along
the in-plane [110] axis (solid circles) and the perpendicular[001] axis (open circles). In all the samples, Msaturates at
FIG. 3. (a)–(d) MCD- Hcurves at different temperatures, (e)–(h)
Arrott plots of (Ga 0.8,Fe0.2)Sb grown on different buffer layers. The
(Ga,Fe)Sb thin films in all the samples exhibit clear ferromagnetismwithT
C>320 K.
smaller HwhenH//[110] than when H//[001]. These results
show that the easy magnetization axes of the (Ga,Fe)Sb thinfilms lie in the in-plane direction in all four samples regardlessof the different epitaxial strains. We note that the same resultswere obtained from the M−Hcurves measured using SQUID
at room temperature. Also, we observed a tendency that thesaturation magnetization decreases with increasing ε, which
can be attributed to the degradation of the crystal quality ofthe films due to the buffer layer. The crystal-quality changeis observed in the linewidths in the ferromagnetic resonance(FMR) spectra, which is discussed in Sec. III.
III. EXPERIMENTAL SETUP OF
FERROMAGNETIC-RESONANCE (FMR)
MEASUREMENTS AND THEORETICAL MODEL
We used a Bruker electron paramagnetic resonance
(EPR) spectrometer for performing FMR measurements at9.066 GHz. As shown in Fig. 1(c), in our FMR measurements,
014431-3GOEL, ANH, OHYA, AND TANAKA PHYSICAL REVIEW B 99, 014431 (2019)
FIG. 4. (a)–(d) Magnetization hysteresis curves ( M-H) mea-
sured at 400 K for (Ga 0.8,Fe0.2)Sb grown on the (a) AlSb, (b) GaSb,
(c) In 0.5Ga0.5As, and (d) GaAs buffer layers when the magnetic field
was applied in the film plane along the [110] axis (red open circles).These characteristics show that the T
Cof these (Ga 0.8,Fe0.2)Sb is
higher than 400 K.
the microwave radio frequency (rf) magnetic field ( h)i s
applied along the [ ¯110] axis in the film plane and the direct-
current (dc) magnetic field His rotated from the [001] direc-
tion (perpendicular to the film plane) to the [110] direction (inthe film plane). Initially, we cut the sample into a (3 ×1)-mm-
size piece with edges along [ ¯110] (3 mm) and [110](1 mm).
Then, we put it on the center of a quartz sample rod and placedit inside the center of the microwave cavity that resonates inthe TE
011mode, where hand rf electric field ( e) are largest
and smallest, respectively. The FMR spectrum was thenmeasured by sweeping the magnitude of H. The magnetic
field derivative of the microwave absorption was obtained by
FIG. 5. Magnetization hysteresis curves ( M-H) measured at
50 K for (Ga 0.8,Fe0.2)Sb grown on the (a) AlSb, (b) GaSb, (c)
In0.5Ga0.5As, and (d) GaAs buffer layers when the magnetic field was
applied in the film plane along the [110] axis (red solid circles) and
perpendicular to the plane along the [001] axis (black open circles).superimposing an alternating-current (ac) modulation field
Hac(1 mT, 100 kHz) parallel to H. Figure 1(c) also shows
the coordinate system used for the FMR measurements. θH
andθMare the angles of HandMfrom the [001] direc-
tion, respectively. All the samples were measured under amicrowave power P=200 mW at 300 K. We note that the
raw FMR spectra of all the samples included backgroundsignals, which were separately detected by measuring theFMR spectra without samples and then subtracted from theraw data (see Supplemental Material [ 33]).
In the FMR experiments, the total magnetic moment M
precesses around the direction of the external magnetic fieldat the Larmor angular frequency ω. Microwave absorption
occurs when the microwave angular frequency coincides withω. This precessional motion of the magnetization is described
by the well-known Landau-Lifshitz-Gilbert (LLG) equationas shown in Eq. ( 1),
1
γ∂M
∂t=−[M×(H+Heff)]+α
(γM S)/bracketleftbigg
M×∂M
∂t/bracketrightbigg
,(1)
where the first term on the right side shows the precessional
motion of the magnetization and the second term representsdamping [ 37,38]. Here, γ=gμ
B/¯his the gyromagnetic ra-
tio, where g,μB, and ¯ hare the gfactor, Bohr magneton,
and reduced Planck’s constant, respectively, and α=G
γM Sis
the damping coefficient, where GandMSare the Gilbert
coefficient and saturation magnetization, respectively; Heff
represents the effective magnetic field which includes the
rf microwave magnetic field, the demagnetizing field (shapeanisotropy field), and the magnetocrystalline anisotropy field.To determine the FMR condition, we used the first term ofEq. ( 1). In our case, the free-energy density Eis expressed as
the summation of the magnetocrystalline anisotropy energy
(E
i), the shape anisotropy energy ( Esh), and the Zeeman
energy ( EZeeman ). In our model, we assumed that Eidepends
only on the out-of-plane magnetic field angle ( θH) because
the in-plane magnetic field angle ( φH) dependence of FMR
was almost isotropic in all the (Ga,Fe)Sb samples (data notshown). The following Eq. ( 2) shows the modified expression
forE:
E=E
eff+EZeeman
=−Keffcos2θM−MSμ0Hcos(θH−θM), (2)
where EiandEshare combined into the effective magnetic
anisotropy energy Eeff(=Ei+Esh). The corresponding effec-
tive magnetic anisotropy constants of Ei,Esh, andEeffare
denoted as Ki,Ksh, andKeff(=Ki+Ksh), respectively. Kshis
given in Eq. ( 3),
Ksh=−1
2μ0M2
S. (3)
From Eq. ( 2), the in-plane (perpendicular) magnetic
anisotropy corresponds to negative (positive) signs of Keff
[37,39]. The resonance field ( μ0HR) of the FMR spectrum is
determined by the resonance condition given by the Smith-Beljers relation [ 40,41] expressed as
/parenleftbiggω
γ/parenrightbigg2
=1
(MSsinθM)2/bracketleftBigg
∂2E
∂θ2
M∂2E
∂φ2
M−/parenleftbigg∂2E
∂θM∂φM/parenrightbigg2/bracketrightBigg
,(4)
014431-4FERROMAGNETIC RESONANCE AND CONTROL OF … PHYSICAL REVIEW B 99, 014431 (2019)
where φMis defined as the in-plane magnetization angle
(see Supplemental Material [ 33]). Here, θMandφMat the
resonance condition are determined by the two equationsof∂E/∂θ
M=0 and ∂E/∂φ M=0. However, in our case,
because the dependence of FMR on φMwas almost isotropic,
we used only ∂E/∂θ M=0. Using Eq. ( 2), this condition is
expressed as
sin(2θM)=(2μ0HR/μ0Meff)sin(θM−θH). (5)
Here, μ0Meffis the effective magnetic field which is
expressed as μ0Meff=μ0MS−Hi, where Hi=2Ki
MSis the
magnetocrystalline anisotropy field. From Eqs. ( 2) and ( 4),
we obtained the following fitting equation (see SupplementalMaterial [ 33]):
/parenleftbiggω
γ/parenrightbigg2
=[μ0HRcos(θH−θM)−μ0Meffcos2θM]
×[μ0HRcos(θH−θM)−μ0Meffcos2θM]. (6)
Equations ( 5) and ( 6) were simultaneously solved nu-
merically to obtain the theoretical value of μ0HRandθM,
where γ(orgfactor) and μ0Meffare fitting parameters.
Using the μ0MSvalues obtained from the SQUID measure-
ments, we first estimated Ksh(=−1
2μ0M2
s), and then esti-
mated Ki(=−MSHi
2,where Hi=μ0MS−μ0Meff).Finally,
Keff(=Ki+Ksh) was estimated for all the samples.
IV . RESULTS AND DISCUSSIONS
The FMR spectra of the (Ga,Fe)Sb layers in samples
A–D measured at room temperature (300 K) are shown inFigs. 6(a)–6(d), where the data obtained with H//[110] and
H//[001] are represented by open red circles and open black
squares, respectively. In all the samples for both magneticfield directions, we observed clear FMR signals from the(Ga,Fe)Sb thin films at room temperature. We note that theFMR signal at room temperature has never been reported forother III-V FMSs. The resonance field μ
0HRof the FMR
spectra measured with H//[110] is smaller than that with
H//[001] in all the samples, indicating that the easy magne-
tization axis is always in the film plane (in-plane magneticanisotropy). This result is consistent with the SQUID resultsshown in Sec. II. We also note that the linewidth of the FMR
spectra becomes broader from 31 mT (sample A) to 56 mT(sample D) for H//[001] as shown in Fig. 7(black solid
circles) when the strain is changed from tensile (sample A)to compressive (sample D). This increase in FMR linewidthis attributed to the degradation of the crystal quality of thefilms due to the buffer layer, which also causes the decreasein saturation magnetization as shown in Fig. 7(blue solid
squares). Next, we measured the FMR spectra for variousdirections of Hbetween the direction normal to the film
plane (H//[001]) and the in-plane direction ( H//[110]). The
detailed angular dependence of μ
0HRon the Hdirection
(θH) of all the samples is represented as the black solid cir-
cles in Figs. 6(e)–6(h).T h eμ0HRvalue decreased smoothly
with increasing θHfrom 0◦(H//[001]) to 90◦(H//[110]).
The change of μ0HRwhenHis rotated from [001] to
[110] monotonously decreases when one goes from sampleA (0.14 T) to sample D (0.05 T). This result reflects the
FIG. 6. (a)–(d) FMR spectra observed for (Ga 0.8,Fe0.2)Sb grown
on the (a) AlSb, (b) GaSb, (c) In 0.5Ga0.5As, and (d) GaAs buffer
layers at room temperature (300 K) when the magnetic field H
was applied along [110] (“red” circles) and [001] (“black” squares).(e)–(h) Resonance field μ
0HRas a function of the direction angle θH
ofμ0H.
different MA in these samples, likely due to the different
epitaxial strains. On the other hand, μ0HRremained almost
unchanged when we rotated Hin the film plane (data not
shown), indicating very weak in-plane magnetic anisotropyof the (Ga,Fe)Sb thin films. The fittings (black solid curves)
FIG. 7. FMR linewidth when the magnetic field is applied along
[001] (black solid circles) and the saturation magnetization (blue
solid squares) as a function of strain ( ε).
014431-5GOEL, ANH, OHYA, AND TANAKA PHYSICAL REVIEW B 99, 014431 (2019)
FIG. 8. Strain ( ε) dependence of the (a) magnetocrystalline anisotropy constant Ki, (b) shape anisotropy constant Ksh, and (c) effective
magnetic anisotropy constant Keffof (Ga,Fe)Sb thin films grown on different buffer layers.
reproduce the observed angular dependence of the FMR fields
quite well for all the samples, as shown in Figs. 6(e)–6(h).T h e
fitting parameters ( μ0Meffandgfactors) that were obtained
from the fitting to the experimental μ0HRdata are listed in
Table I.
In Table I, one can see that μ0Mefftends to decrease when
the strain is changed from tensile (sample A) to compressive(sample D). This means that μ
0Meffwhich carries information
of the magnetocrystalline anisotropy depends strongly on theepitaxial strain of the (Ga,Fe)Sb thin film. Figures 8(a)–
8(c) summarize the estimated values of magnetocrystalline
anisotropy constant K
i, shape anisotropy constant Ksh, and
effective magnetic anisotropy constant Keff(=Ki+Ksh), as
a function of ε. In all the samples, the magnitude of Kshis
one or two orders of magnitude larger than Ki, indicating the
dominance of the shape anisotropy in the MA properties of(Ga,Fe)Sb. The strong shape anisotropy is due to the largeμ
0MSof (Ga,Fe)Sb even at room temperature.
The magnetocrystalline anisotropy constant Ki, though
small, shows a systematic dependence on the strain ε.
As shown in Fig. 8(a), when the strain is changed from
tensile ( ε=−1.7%) to compressive ( ε=+3.84%), the
magnitude of Kiincreases and changes from negative
(in-plane anisotropy) to positive (perpendicular anisotropy).These results indicate that it is feasible to control themagnetocrystalline anisotropy of (Ga,Fe)Sb thin films byusing epitaxial strain. Meanwhile, K
shis always negative, as
shown in Fig. 8(b), making Keffalways negative (in-plane
magnetic anisotropy), as shown in Fig. 8(c). As a result, all the
(Ga,Fe)Sb thin films examined here have in-plane magneticanisotropy. These results of (Ga,Fe)Sb are contrasting to thoseof (Ga,Mn)As in the following two points: (i) In (Ga,Mn)As,K
iis large (magnetocrystalline field Hiis∼several 1000 Oe
[20]) and dominates MA, but (Ga,Fe)Sb shows small Hi∼
100−300 Oe (listed in Table I) and possesses a very large
Ksh. (ii) In (Ga,Mn)As, compressive (tensile) strain leads toin-plane (perpendicular) magnetic anisotropy, but in
(Ga,Fe)Sb tensile (compressive) strain leads to in-plane(perpendicular) magnetic anisotropy, and thus the strain effectis opposite. Therefore, in (Ga,Fe)Sb, the shape anisotropyshould be utilized to control the in-plane magnetic anisotropy.
V . CONCLUSION
We have successfully grown a series of (Ga,Fe)Sb thin
films with the Fe concentration of 20% on different bufferlayers, AlSb, GaSb, In
0.5Ga0.5As, and GaAs, which all exhibit
room-temperature ferromagnetism. The epitaxial strain εin
the (Ga,Fe)Sb layers was gradually varied over a wide rangefrom−1.7% (tensile strain) to +3.84% (compressive strain).
We observed clear FMR signals in (Ga,Fe)Sb at room temper-ature (FMR has never been observed in III-V based FMSs atroom temperature), and determined the magnetic anisotropyconstants. We found that the magnitude of K
iis weak and
shows a monotonous dependence on the strain. By changingthe strain from tensile to compressive, K
ichanged from nega-
tive (in-plane magnetic anisotropy) to positive (perpendicularmagnetic anisotropy). Meanwhile, K
shwas always negative
and is dominant over Ki, leading to negative Keff(in-plane
magnetization) in all the samples. This study suggests that theeasy magnetization axis of (Ga,Fe)Sb can be controlled bychanging the shape anisotropy.
ACKNOWLEDGMENTS
This work was partly supported by Grants-in-Aid for
Scientific Research by MEXT (Grants No. 18H03860, No.17H04922, and No. 16H02095), CREST of JST (Grant No.JPMJCR1777), the Spintronics Research Network of Japan(Spin-RNJ), Yazaki Memorial Foundation for Science &Technology, and the Murata Science Foundation.
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014431-7 |
PhysRevB.99.184407.pdf | PHYSICAL REVIEW B 99, 184407 (2019)
Local spin moments, valency, and long-range magnetic order in monocrystalline
and ultrathin films of Y 3Fe5O12garnet
Y. Y. C h i n ,1,2,*H.-J. Lin,2Y . -F. Liao,2W. C. Wang,2P. Wang,3D. Wu,3A. Singh,2H.-Y . Huang,2Y .-Y . Chu,2D. J. Huang,2
K.-D. Tsuei,2C. T. Chen,2A. Tanaka,4and A. Chainani2
1Department of Physics, National Chung Cheng University, Chiayi 62102, Taiwan
2National Synchrotron Radiation Research Center, Hsinchu 30076, Taiwan
3Department of Physics, National Laboratory of Solid State Microstructures, Nanjing University, Nanjing 210093, China
4Department of Quantum Matter, ADSM, Hiroshima University, Higashi-Hiroshima 739-8530, Japan
(Received 25 March 2019; published 9 May 2019)
We investigate and compare the electronic structure of a bulk single crystal of Y 3Fe5O12garnet [YIG,
a high- TC(=560 K) ferrimagnet] with that of an epitaxial ultrathin (3.3 nm) film of YIG with a reduced
ferrimagnetic temperature TC=380 K, using bulk-sensitive hard x-ray photoelectron spectroscopy (HAXPES),
x-ray absorption spectroscopy (XAS), and x-ray magnetic circular dichroism (XMCD). The Fe 2 pHAXPES
spectrum of the bulk single crystal exhibits a purely trivalent Fe3+state for octahedral and tetrahedral sites. The
Fe 3sspectrum shows a clear splitting which allows us to estimate the on-site Fe 3 s-3dexchange interaction
energy. The valence band HAXPES spectrum shows Fe 3 d,O2 p,a n dF e4 sderived features and a band
gap of ∼2.3 eV in the occupied density of states, consistent with the known optical band gap of ∼2.7e V .
FeL-edge XAS identifies the octahedral Fe3+and tetrahedral Fe3+site features. XMCD spectra at the Fe
L2,3edges show that bulk single-crystal YIG exhibits antiferromagnetic coupling between the octahedral- and
tetrahedral-site spins. The calculated Fe 2 pHAXPES, Fe L-edge XAS, and XMCD spectra using full multiplet
cluster calculations match well with the experimental results and confirm the full local spin moments. In contrast,HAXPES, XAS, and XMCD of the Pt /YIG (3.3 nm) ultrathin epitaxial film grown by a pulsed laser deposition
method show a finite Fe
2+contribution and a reduced Fe3+local spin moment. The Fe2+state is attributed to
a combination of oxygen deficiency and charge transfer effects from the Pt capping layer to the ultrathin film.However, the conserved XMCD spectral shape for the ultrathin film indicates that the 3.3-nm epitaxial film isgenuinely ferrimagnetic, in contrast to recent studies on films grown by radio-frequency magnetron sputteringwhich have shown a magnetic dead layer of ∼6 nm. The presence of Fe
2+and the reduced local spin moment
in the epitaxial ultrathin film lead to a reduced Curie temperature, quantitatively consistent with well-knownmean-field theory. The results establish a coupling of the local Fe spin moments, valency, and long-rangemagnetic ordering temperature in bulk single crystal and epitaxial ultrathin-film YIG.
DOI: 10.1103/PhysRevB.99.184407
I. INTRODUCTION
Spintronics, or spin-based electronics, relies upon repro-
ducible and robust transport of spin and charge for deviceoperation. However, recent studies have identified pure spincurrents which could efficiently transport spin angular mo-mentum without an accompanying charge current. This wouldlead to the absence of an Oersted field and lower Jouleheating losses [ 1–8] and promises new functionalities as
well as energy savings. In order to generate and manipulatepure spin currents, bilayers composed of a normal metal(NM)/ferromagnetic material with a nonmagnetic layer have
been extensively investigated, and fascinating phenomenasuch as spin pumping [ 3,4], the spin Seebeck effect (SSE)
[5], the spin Hall effect (SHE) [ 6,7], and the inverse spin
Hall effect [ 8] were recently reported. A pure spin current
could be generated by a thermal gradient in the SSE, whilea nonmagnetic metal with strong spin-orbit coupling, such
*yiyingchin@ccu.edu.twas Pt, could convert a charge current into a spin current inthe SHE. More interestingly, heterostructures with a ferro- orferrimagnetic insulator (FMI) layer have attracted significantattention because only magnetic excitations (spin currents) areexpected to propagate in the FMI layer, leading to a naturalseparation of spin current from charge current. The ferrimag-net Y
3Fe5O12with a TC=560 K is one such insulating oxide,
and consequently, the bilayer Pt /Y3Fe5O12has become a
prototype for investigating spin-current phenomena. Further-more, recent studies reported an unconventional Hall effectdepending on the magnetic field, implying the importance ofthe interface between Pt and Y
3Fe5O12[9–13].
Y3Fe5O12(YIG) is an extremely important material for
ultrahigh-frequency optical modulators, femtosecond photo-magnetic switching devices, and microwave applications. Italso shows giant magnetoelectric and magnetocapacitanceeffects and exhibits Bose-Einstein condensation of magnons[14,15]. YIG crystallizes in a cubic structure ( Ia3d) with
magnetically active Fe
3+ions in 16a octahedral (O h) sites
and 24d tetrahedral (T d) sites. It exhibits ferrimagnetic or-
der below TC=560 K with antiparallel Fe spins due to
2469-9950/2019/99(18)/184407(9) 184407-1 ©2019 American Physical SocietyY. Y. C H I N et al. PHYSICAL REVIEW B 99, 184407 (2019)
superexchange on the octahedral:tetrahedral sites in a 2:3
ratio with the magnetic easy axis along the 111 direction.Moreover, because it exhibits low magnetic damping and isa very good insulator (band gap of ∼2.7e V ) [ 16], YIG is a
favorite choice for generating pure spin currents via a thermalgradient. It was demonstrated that the dc magnetic momentcurrent in YIG could reach a value of 10
24μB/cm2[17].
Although bulk YIG shows only weak magnetic anisotropy,
a recent study indicated the presence of perpendicular mag-netic anisotropy in Pt /YIG thin films [ 18]. Moreover, the
deviation between the bulk magnetization and the longitudinalspin Seebeck effect was attributed to the near-surface uniaxialmagnetic anisotropy, which is intrinsic to YIG [ 18]. More
significantly, the threshold current for exciting spin wavesin Pt/YIG bilayer films is 2–3 orders of magnitude lower
than what is expected for bulk YIG. It was theoreticallyshown that the strong reduction in threshold current is dueto an easy-axis surface anisotropy, which also increases thepower of the spin wave excitation by at least 2 orders ofmagnitude [ 19]. However, in a recent study using polarized
neutron reflectometry, the authors concluded that the interfaceof Pt/YIG films can become nonmagnetic, and this will
have important repercussions for the inverse SHE [ 20]. It is
also known that the Curie temperature of YIG films can getreduced even for high-crystalline-quality epitaxial films [ 21].
Most importantly, in a recent study of epitaxial films grown byradio-frequency magnetron sputtering, the YIG films grownon Gd
3Ga5O12(GGG) (111) substrates showed a magnetic
dead layer of ∼6 nm at the interface [ 22]. Thus, it is extremely
important to carry out a spectroscopic characterization of theelectronic structure and its relation to the magnetic propertiesof YIG films in bilayers. Further, it is necessary to compareit with the electronic structure of bulk single-crystal YIGusing the same techniques. This would help us to identify thebest conditions required for developing high-quality films fordevice applications.
In this work, we study single-crystal YIG(111),
Pt/YIG(111), and Cu /YIG(111) epitaxial thin films using
hard x-ray photoelectron spectroscopy (HAXPES) andFeL
2,3x-ray absorption spectroscopy (XAS) and x-ray
magnetic circular dichroism (XMCD). HAXPES is ideallysuited for bulk sensitive core-level and occupied valenceband studies of electronic structure [ 23–25]. On the other
hand, XAS and XMCD are well suited to studying the site-and orbital-selective unoccupied density of states and fordetermining element-specific orbital and spin moments [ 26].
Our results show the presence of Fe
2+and reduced Fe spin
moments in the epitaxial ultrathin film compared to the pureFe
3+and the full spin moment seen in the bulk single crystal.
This causes a reduced Curie temperature compared to the bulksingle crystal but is quantitatively consistent with well-knownmean-field theory. The results indicate a direct coupling ofthe local Fe spin moments, valency, and long-range magneticordering temperature in the bulk single crystal as well as inepitaxial ultrathin-film YIG.
II. EXPERIMENTS
The YIG bulk single crystal was obtained commer-
cially. Pt /YIG(111) and Cu /YIG(111) ultrathin films wereFIG. 1. (a) The Fe 2 pHAXPES spectra of Y 3Fe5O12bulk single
crystal at room temperature. (b) The theoretical simulation of theHAXPES spectrum of YIG single crystal by the configuration-
interaction cluster calculations.
epitaxially grown on GGG(111) substrates using pulsed laser
deposition by applying a KrF excimer laser at a repetition of4 Hz and a laser fluence of 2.7 J /cm
2. The growth temperature
and oxygen pressure were 740◦C and 0.07 Torr, respec-
tively. Clear in situ reflection high-energy electron diffraction
(RHEED) patterns were observed during deposition, indi-cating the single crystallinity of the YIG films. The YIGthickness was estimated to be 3.3 nm for Pt /YIG and for
Cu/YIG epitaxial films from calibrated RHEED oscillations.
The film quality was further confirmed by x-ray diffraction.The YIG films were transferred into another vacuum chamberto deposit Pt /Cu films by dc magnetron sputtering. The thick-
ness of the Pt and Cu capping layer was 3 nm. The growthrates of the YIG films and the Pt /Cu capping layers were
also determined by x-ray reflectivity measurements, and thecharacterization procedures were reported in a recent study[27]. The Fe L
2,3XAS and XMCD experiments were carried
out at the BL11A beamline of the National SynchrotronRadiation Research Center in Taiwan. The Fe L
2,3XAS and
XMCD spectra were collected at room temperature in thetotal-electron yield mode with an energy resolution of betterthan 0.3 eV . Fe
2O3and NiO single crystals were measured
simultaneously in a separated chamber to calibrate the photonenergy with an accuracy better than 10 meV . HAXPES experi-ments ( hν=6500 eV) were performed at room temperature at
the Taiwan beamline BL12XU of SPring-8 in Hyogo, Japan.The overall energy resolution was 0.35 eV , estimated from afit to the Fermi edge of silver, which was also used to calibratethe binding energy.
III. RESULTS AND DISCUSSION
A. HAXPES Fe 2 presults of bulk single crystal
The Fe 2 pHAXPES spectrum of the YIG bulk single
crystal is presented in Fig. 1(a). The spectrum consists of the
2p3/2and 2 p1/2spectral features due to spin-orbit splitting.
The 2 p3/2main peak consists of two features, positioned at
binding energies (BEs) of 710.5 and 711.5 eV and a satellite
184407-2LOCAL SPIN MOMENTS, V ALENCY , AND LONG-RANGE … PHYSICAL REVIEW B 99, 184407 (2019)
TABLE I. The parameters (in eV) for simulating the Fe 2 p
HAXPES spectrum of the YIG bulk single crystal.
Udd Upd /Delta1 10 Dq Veg Vt2g
TdFe3+6.0 7.5 2.0 −0.4 2.82 1.72
OhFe3+6.0 7.5 2.0 0.9 1.27 2.38
feature at about 720 eV . Similarly, the 2 p1/2main peak con-
sists of two features, positioned at binding energies of 724.5and 725.5 eV and a satellite feature at about 733.5 eV . In orderto understand the origin of the spectral features, we carried outmodel configuration interaction cluster calculations [ 28,29]
for the Fe 2 pspectrum, including full atomic multiplets for
octahedral FeO
6and tetrahedral FeO 4clusters. The basis
states used for the calculations consist of a linear combinationof the d
5,d6L1, and d7L2states for Fe3+. The electronic
parameters for the calculations are the on-site Coulomb en-ergy U
dd, the charge transfer energy /Delta1, the Fe 3 d-O 2 p
hybridization strength V, the crystal field splitting 10 Dq, and
the Coulomb interaction in the presence of a 2 pcore hole
Upd. The parameters were optimized to give the best match
with the experimental data, and the results are shown alongwith the experimental spectrum. The bulk single-crystal Fe2pspectrum can be simulated nicely using a combination of
O
hand T dFe3+in a 2:3 ratio, consistent with the chemical
formula. The two features of the main peak are assigned to theoctahedral and tetrahedral Fe
3+sites, respectively. The elec-
tronic structure parameters obtained from the cluster calcula-tions are listed in Table I. It is understood that YIG is a typical
charge transfer insulator with a small charge transfer energy(/Delta1=2 eV), large on-site Coulomb energy ( U
dd=6 eV), and
strong hybridization ( Veg=2.82 eV and Vt2g=2.38 eV for T d
and O hsites, respectively) between the Fe 3 dand O 2 pligand
states. The charge transfer nature of YIG is consistent with
FIG. 2. (a) The Fe 3 sHAXPES spectra of Y 3Fe5O12bulk single
crystal at room temperature. (b) The simulation consists of four peaks
obtained from a fit to the HAXPES spectrum for estimating the Fe 3s
multiplet splitting, as explained in the text.FIG. 3. (a) The Y 3 pHAXPES spectra of Y 3Fe5O12single crys-
tal at room temperature. (b) The Y 3 dHAXPES spectra of Y 3Fe5O12
bulk single crystal at room temperature. The weak plasmon features
are marked by asterisks.
the known results of other trivalent Fe3+oxides, hematite
(α-Fe 2O3)[30] and maghemite ( γ-Fe 2O3)[31].
B. HAXPES Fe 3 sresults of bulk single crystal
In Fig. 2(a) we plot the Fe 3 sHAXPES spectrum of
bulk single-crystal YIG. The spectrum consists of two broadfeatures, a higher-intensity feature at about 94 eV and alower-intensity feature at 100 eV binding energy. The Fe3sspectrum thus exhibits the well-known multiplet splitting
due to 3 s-3dexchange interaction [ 32]. A closer look at the
higher-binding-energy feature at 100 eV shows that it consistsof two peaks, which can be assigned to the tetrahedral andoctahedral Fe sites. Hence, we have carried out a peak fittingto the Fe 3 sspectrum using four peaks (Td1, Oh1, Td2,
and Oh2) to accurately estimate the binding energies of thefeatures. The fitting results are overlaid on the experimentalspectrum. We obtain a splitting of ∼6.0 eV for the tetrahedral
Fe site and ∼7.0 eV for the octahedral site. While it is known
that the Fe 3 smultiplet splitting energy /Delta1E
3s=(2S+1)Jeff,
where Sis the net spin on the Fe site and Jeffis the effective
exchange integral between the 3 sand 3 dstates [ 32], the role
of the intrashell correlation effects [ 33], final-state screening
184407-3Y. Y. C H I N et al. PHYSICAL REVIEW B 99, 184407 (2019)
FIG. 4. The valence band HAXPES spectra of Y 3Fe5O12bulk
single crystal at room temperature for linear horizontal (H) and
vertical (V) polarizations of the incident x rays.
[34], and charge transfer screening [ 35] has been recognized.
More recently, a systematic study on a series of Fe compoundsshowed that charge transfer screening leads to a modificationof/Delta1E
3s[36]. It was shown that /Delta1E3sfollows a linear relation
versus (2 S+1) given by /Delta1E3s=A+(2S+1)Jeff, where A
is a constant. From a fit to the experimentally observed data,it was found that A=0.94 and J
eff=1.01 eV for a series of
Fe compounds. Using this relation with A=0.94, as we will
show later with the XMCD measurements and analysis, sinceS∼2μ
Bfor the tetrahedral and octahedral Fe3+sites in bulk
YIG, we could estimate that Jeff∼1.0 eV for tetrahedral Fe
sites and Jeff∼1.2 eV for the octahedral Fe sites.
C. HAXPES Y 3 pand 3 dresults of bulk single crystal
Figures 3(a) and 3(b) show the Y 3 pand Y 3 dcore-
level HAXPES spectra of bulk single-crystal YIG. The Y 3 p
spectrum exhibits a spin-orbit split 3 p3/2and 3 p1/2doublet at
binding energies of 301 and 313 eV , respectively, while theY3dspectrum exhibits a spin-orbit split doublet at binding
energies of 158 and 160 eV , respectively. The clean singlepeaks and the binding energies of the Y 3 pand Y 3 dspectra
are indicative of typical Y
3+states. We also note that the
spectra exhibit weak satellites at about 12 eV higher bindingenergies compared to the main peaks in both the Y 3 pand
3dspectra, and these are indicative of weak plasmon features.
In particular, since the splitting between the main peaks of the3p
3/2and 3 p1/2doublet is also 12 eV , the plasmon of the main
3p3/2feature is hidden in the main 3 p1/2feature, resulting in
a small deviation of the relative spectral intensities comparedto the expected ratio of 2:1 due to their degeneracies.
D. HAXPES valence band spectra of bulk single crystal
In Fig. 4, we plot the valence band HAXPES spectra
obtained for horizontal and vertical linearly polarized incidentx rays. The spectra show small differences for the horizontaland vertical polarization spectra. The spectra mainly consistFIG. 5. (a) The wide-scan Fe 2 pHAXPES data for bulk single-
crystal YIG and Pt /YIG (3.3 nm) epitaxial film at room temperature,
showing the Pt 4 score level overlapping the Fe 2 p1/2feature.
(b) The narrow-range Fe 2 p3/2HAXPES data for YIG bulk single
crystal, Cu /YIG (3.3 nm), and Pt /YIG (3.3 nm) epitaxial thin
films at room temperature, showing a weak feature at low binding
energy( ∼708 eV) attributed to Fe2+states.
of three broad features: the first feature is from about 2.3 to
about 4 eV BE, the second is between 4.0 and 7.0 eV , andthe third feature occurs between 7.0 and nearly 10.0 eV BE.The vertical polarization enhances the Fe 3 dstates, while the
horizontal polarization enhances the Fe 4 sstates. In addition,
based on known band structure calculations, the first featureis dominated by Fe 3 dstates, while the second feature is
due to mainly O 2 pstates mixed with the Fe 3 dstates. The
third feature consists of O 2 pstates mixed with Fe 4 sstates,
a st h eF e4 sstates are enhanced in the horizontal incident
polarization spectrum. The onset of the first feature is at2.3 eV BE and indicates that the band gap in the occupieddensity of states is close to the optical band gap of YIG, whichis approximately 2.7 eV [ 16]. This implies that the chemical
potential of the bulk YIG single crystal is pinned near thebottom of its conduction band.
E. Comparative HAXPES Fe 2 pspectra of bulk single crystal
and epitaxial thin films
Next, we discuss the comparison of the HAXPES Fe 2 p
spectra of the bulk single-crystal YIG, Cu /YIG, and Pt /YIG
184407-4LOCAL SPIN MOMENTS, V ALENCY , AND LONG-RANGE … PHYSICAL REVIEW B 99, 184407 (2019)
FIG. 6. (a) The Fe L2,3XAS data for YIG bulk single crystal
at room temperature. (b) The theoretical simulation of the XASspectrum of YIG bulk single crystal by the configuration-interaction
cluster calculations.
films, as shown in Fig. 5. Since the YIG films have a capping
layer of 3 nm Pt /Cu metal, we could use HAXPES to measure
the valency of Fe in the YIG films. However, since the Pt 4 s
core-level binding energy ( ∼722 eV) lies very close to the Fe
2p3/2feature (binding energy of 710–715 eV) and it actually
overlaps the Fe 2 p1/2feature [see Fig. 5(a)], we measured
and compared the HAXPES of Cu /YIG and Pt /YIG films to
identify the changes in the Fe 2 p3/2signal with bulk single-
crystal YIG. As shown in Fig. 5(b) on an expanded scale, the
presence of Fe2+in Cu/YIG and Pt /YIG epitaxial thin films
in the Fe 2 p3/2HAXPES spectra can be identified as a weak
feature with a chemical shift to low binding energy [ 37]. The
finite intensity observed between 708 and 710 eV indicatesthe existence of Fe
2+in the epitaxial thin films. Thus, as
seen in Fig. 5(b), the Fe 2 p3/2HAXPES of the Pt /YIG
3.3-nm epitaxial film shows a higher Fe2+content compared
to the Cu /YIG 3.3-nm epitaxial film. This is consistent with
a recent study which reported a charge transfer from the Ptcapping layer compared to negligible charge transfer from aCu capping layer in ultrathin Pt /YIG (1.6 nm) and Cu /YIG
(1.6 nm) bilayers [ 27]. We have also confirmed there is no
observable angular dependence of the spectra, indicating theabsence of surface effects. This is inferred from the fact thatFe 2 pspectra (not shown), measured with horizontal and
vertical polarization at grazing incidence as well as at a 45
◦
incidence angle, all show very similar spectral shapes. Thepresence of Fe
2+is expected to have an influence on the
magnetic properties of the Pt /YIG epitaxial thin films, and
to investigate this, we performed XAS and XMCD experi-ments on YIG bulk single crystal and Pt /YIG epitaxial thin
films.
F. Comparative Fe L2,3XAS spectra of bulk single crystal and
epitaxial thin films
The Fe L2,3XAS spectrum of bulk single-crystal YIG is
presented in Fig. 6(a). The Fe L2,3XAS spectra consist of
two main sets of features at ∼707–711 and ∼720–724 eVFIG. 7. (a) The Fe L2,3XAS spectra of Y 3Fe5O12bulk single
crystal and Pt /Y3Fe5O14epitaxial thin film at room temperature.
(b) The simulation of the XAS spectrum of Pt /YIG epitaxial thin
film by the configuration-interaction cluster calculations.
photon energies, which are the L3andL2edges derived from
Fe 2 pspin-orbit coupling. The energy positions of spectral
features and their multiplet structures are characteristic of thevalence state and the local symmetry of the Fe ion. We thenused the same electronic parameters obtained for the Fe 2 p
photoemission spectrum to also calculate the Fe L-edge XAS
spectrum using configuration interaction cluster calculations.We obtain a good match between the calculated and exper-imental spectra, as shown in Fig. 6. The main peak of the
L
3edge at 708.5 eV is dominated by tetrahedral Fe3+, while
the octahedral Fe3+states dominate the prepeak at 707.5 eV
and also contribute significantly to the main peak at the higherphoton energy of 709.5 eV .
In Fig. 7(a), we plot the Fe L-edge XAS spectrum of the
Pt/YIG epitaxial thin film compared with the YIG bulk single
crystal’s Fe L-edge XAS shown in Fig. 6. As seen in Fig. 7(a),
the Pt/YIG epitaxial thin-film spectrum shows higher spectral
weight at the low-energy shoulder ( ∼707 eV) in the Pt /YIG
epitaxial thin film compared to the YIG single crystal. Thisimplies the presence of Fe
2+ions in the YIG epitaxial thin
film, consistent with the Fe 2 pHAXPES spectrum shown
in Fig. 5(b). In order to confirm and determine the Fe2+
content in the Pt /YIG epitaxial thin film, we subtracted the
spectrum of the YIG bulk single crystal from that of theepitaxial thin film. The difference spectrum (blue line) is alsoshown in Fig. 7(a). We note that this spectral shape is different
from not only the spectrum of O
hFe2+in Fe-doped MgO
[38] but also that of T dFe2+in CaBaFe 4O7[39]. However,
it can be simulated by their combination and indicates thepresence of both O
hFe2+and T dFe2+in the Pt /YIG thin
film. We then carried out configuration-interaction clustercalculations to simulate the Fe L-edge XAS spectrum. The
best match to the experimental data is shown together withthe experimental spectrum. The calculations indicate that thePt/YIG 3.3-nm epitaxial film consists of ∼90% Fe
3+with O h
and T dcontributions in a 2:3 ratio, ∼6.9% T dFe2+(cyan line)
and∼3.1% O hFe2+(magenta line). The electronic structure
184407-5Y. Y. C H I N et al. PHYSICAL REVIEW B 99, 184407 (2019)
TABLE II. The parameters (in eV) for simulating the Fe L2,3
XAS and XMCD data of the YIG bulk single crystal and the epitaxial
thin film.
Udd Upd /Delta1 10 Dq Veg Vt2g Hex
YIG bulk single crystal
TdFe3+6.0 7.5 2.0 −0.4 2.82 1.72 0.04
OhFe3+6.0 7.5 2.0 0.9 1.27 2.38 0.04
Pt/YIG (3.3 nm)
TdFe3+6.0 7.5 2.0 −0.4 2.82 1.72 0.02
OhFe3+6.0 7.5 2.0 1.0 1.27 2.38 0.016
TdFe2+6.0 7.5 7.0 −0.4 2.82 1.72 0.007
OhFe2+6.0 7.5 7.0 0.6 1.27 2.38 0.007
parameters obtained from the cluster calculations are listed in
Table II.
G. Comparative HAXPES O 1 sspectra of bulk single crystal
and epitaxial thin films
Having confirmed the presence of Fe2+in the Pt /YIG films
compared to bulk single-crystal YIG, we analyzed the O 1 s
core-level HAXPES to check the origin of Fe2+in the film. As
seen in Fig. 8,t h eO1 score-level HAXPES of the bulk crystal
shows a narrow single peak at about 531 eV . In contrast, the O1sspectrum of the Pt /YIG film shows a broader main peak as
well as a broad satellite feature extending up to a higher BEof nearly 536 eV . Since it is known that oxygen adsorption(physisorption and chemisorption) on Pt can lead to satellitefeatures at higher BE than the main peak [ 40], we carried out
a fitting of the spectrum to accurately identify if the satelliteconsists of more than one feature. The best fit is obtained byusing two satellites at binding energies of 533.5 and 536.0 eV .It is known [ 41,42] that oxygen vacancies or defects result in
a satellite typically 2 eV higher BE from the main peak. In
FIG. 8. The O 1 sHAXPES spectrum of Y 3Fe5O12bulk single
crystal and Pt /Y3Fe5O14(3.3 nm) epitaxial thin film at room temper-
ature. The Pt 4 p3/2feature lies close to the O 1 sfeatures. We have
fitted the O 1 sfeatures of the Pt /Y3Fe5O14(3.3 nm) epitaxial thin
film using V oigt functions, as shown in order to estimate the energy
positions and peak widths of the features.FIG. 9. (a) The Fe L2,3XMCD curves of Y 3Fe5O12bulk single
crystal and Pt /Y3Fe5O12(3.3 nm) epitaxial thin film at T=300 K.
The theoretical simulations for the T=300 K XMCD curves of
(b) the YIG single crystal and (c) Pt /YIG (3.3 nm) epitaxial thin
film.
contrast, a satellite due to oxygen physisorbed on the Pt(111)
surface occurs at about 5 eV higher BE than the main peak[40]. We thus attribute the satellite at nearly 536.0 eV to
physisorbed oxygen and the 533.5 eV BE satellite to oxygenvacancies in the YIG film.
H. Comparative Fe L2,3XMCD results of bulk single crystal
and epitaxial thin films
TheT=300 K Fe L2,3XMCD data of the YIG bulk single
crystal and the Pt /YIG 3.3-nm epitaxial film are presented in
Fig. 9(a). The XMCD experiments were carried out at T=
300 K under a 1-T magnetic field. We also tried experimentsatT=30 K, but the strong insulating behavior of the YIG
bulk single crystal at T=30 K led to spectral distortions
due to charging. We first discuss the XMCD data of thebulk single-crystal YIG which show three features, S1–S3, aslabeled in Fig. 9(b). By comparing our results with known
XMCD curves of GaFeO
3with O hFe3+andγ-Fe 2O3with
both T dFe3+and O hFe3+[43] ,t h em a i nF e L3XMCD
184407-6LOCAL SPIN MOMENTS, V ALENCY , AND LONG-RANGE … PHYSICAL REVIEW B 99, 184407 (2019)
TABLE III. Fe 3 dspin moments (in units of μB) as determined
by XMCD sum rules and XMCD simulations.
Bulk single crystal Pt /YIG (3.3 nm)
TdFe3+1.97 1.46
OhFe3+−2.03 −1.30
TdFe2+−0.47
OhFe2+−0.48
Per Fe 0.37 0.27
XMCD sum rules 0.35 0.27
feature in Fig. 9(b) (labeled S2) of the YIG bulk single
crystal is attributed to the T dFe3+. In contrast, features S1
and S3 at lower and higher photon energies mainly comefrom O
hFe3+and are in the direction opposite that of the
TdFe3+contribution. Therefore, the XMCD signal indicates
an antiparallel alignment, i.e., an antiferromagnetic couplingof the T
dFe3+and O hFe3+magnetic moments, similar to
what was observed in γ-Fe 2O3and Fe 3O4[43,44].
Although the orbital and spin moments could be obtained
by employing the XMCD sum rules [ 45–47], theoretical cal-
culations are also necessary for explaining and quantifying theobserved behavior, particularly for systems with more thanone valence state and /or local symmetries. For the Pt /YIG
film, although it contains a finite amount of Fe
2+as under-
stood from the Fe L2,3XAS and Fe 2 pHAXPES spectra
discussed earlier, the line shape of the XMCD signal of theepitaxial thin film is quite similar to that of the YIG bulk singlecrystal, implying magnetic contributions from Fe
3+dominate
the XMCD signal. We note that in a recent study on a Pt /YIG
(1.6 nm) ultrathin film [ 27], it was shown that the spectral
shape deviates a little from that of thick YIG films (and ourbulk single-crystal data). In particular, it was shown that onlythe T
dFe3+site XMCD signal weakened, while the O hFe3+
site XMCD signal did not change. This was interpreted to
represent a preferential charge transfer from the Pt cappinglayer to the T
dFe site, resulting in T dFe2+. However, in the
present case, we find that for the Pt /YIG (3.3 nm) epitaxial
thin film, the spectral shape matches the bulk single-crystalXMCD signal but is uniformly weakened, and the reductionis larger than 10%, the concentration of Fe
2+in the film. This
indicates reduced spin moments for both the T dFe3+and
OhFe3+sites.
In order to quantify the magnetic dichroism of the YIG
bulk single crystal as well as the Pt /YIG 3.3-nm epitaxial
thin film, cluster calculations using the same parameters asthose for the XAS spectra were performed, and the results arepresented in Figs. 9(b) and9(c). As shown in Fig. 9(b), there
is nice agreement between the theoretical (magenta line) andexperimental XMCD (black line) spectra, and thus, we canquantify the magnetic moments of Fe ions for bulk single-crystal YIG. Moreover, the site-resolved calculations shownin the bottom part of Fig. 9(b) confirm that the magnetic
moments of T
dFe3+and O hFe3+are indeed aligned opposite
to each other. The estimated magnetic moments (listed inTable III) match very nicely with the spin moments calcu-
lated using the local spin-density approximation with on-siteCoulomb energy U[48,49].Further, as depicted in Fig. 9(c), our cluster calculations
for the Pt /YIG 3.3-nm epitaxial thin film also match nicely
with the experimental data. However, we needed to include theFe
2+contributions to get the best match, as was discussed for
the XAS data of Fig. 7. While the contribution from Fe2+is
quite small compared with that of Fe3+, it can be expected that
the Fe2+ions will disturb the magnetic interactions between
Fe3+ions. However, more surprisingly, we find that the spin
moments for the Fe3+ions are also significantly reduced in
the epitaxial thin film as listed in Table III. This not only
explains the reduction of the XMCD signal but would alsoimply a reduced Curie temperature in the Pt /YIG epitaxial
thin film. We measured the Curie temperature of the Pt /YIG
(3.3 nm) epitaxial film, and as shown in the SupplementalMaterial [ 50], we could fit the magnetization as a function of
temperature to a Bloch T
3/2law typical of ferrimagnets. We
could estimate TC=380 K for the Pt /YIG (3.3 nm) epitaxial
film. Thus, the magnetization results and the XMCD spectralshape of the ultrathin film indicate that the Pt /YIG (3.3 nm)
epitaxial film is genuinely ferrimagnetic. This is in contrast torecent studies on films grown by radio-frequency magnetronsputtering which have shown a magnetic dead layer of ∼6n m
[22]. In fact, as discussed above, even Pt /YIG (1.6 nm) bilayer
films grown by pulsed laser deposition were reported to beferrimagnetic at room temperature [ 27].
Based on mean-field theory, it is known that T
C=
μeff(CACB)1/2, where μeffis the effective spin moment and
CAandCBare Curie constants for the A and B sublattices
in a ferrimagnet [ 51]. This equation indicates that T Cis
directly proportional to μeff. Indeed, the ratio of TCfor the
epitaxial thin film compared to the bulk single crystal RTc∼
0.68 and is close to the ratio of the effective spin momentsestimated from the XMCD data: R
μ1=0.74±0.05 for the
TdFe3+site and Rμ2=0.64±0.05 for the O hFe3+site.
The small deviations for the ratio of effective moments forthe T
dFe3+and O hFe3+sites probably originates from
the preferential charge transfer as reported for the Pt /YIG
(1.6 nm) ultrathin film [ 27]. However, the nearly similar
XMCD signal for the present case of the Pt /YIG (3.3 nm)
epitaxial film suggests that the reduced spin moments on bothT
dFe3+and O hFe3+sites is dominated by the presence
of oxygen vacancies, leading to both T dFe2+and O hFe2+
sites. This can be expected to disturb and effectively weaken
the exchange interaction between the T dFe3+and O hFe3+
sites. Thus, the reduced TCdue to the presence of Fe2+is
attributed to a combination of oxygen deficiency and chargetransfer effects from the Pt capping layer to the ultrathinfilm.
IV . CONCLUSION
In conclusion, we have carried out HAXPES, XAS, and
XMCD of bulk single-crystal YIG compared to an epitaxialPt/YIG thin-film bilayer. The Fe 2 pHAXPES spectrum of
the bulk single crystal indicates a purely trivalent Fe
3+state.
The valence band HAXPES spectrum shows Fe 3 d,O2 p,
and Fe 4 sderived features and a band gap of ∼2.3e V i n t h e
occupied density of states, close to the known optical bandgap of 2.7 eV . Fe L-edge XAS was used to characterize the
octahedral Fe
3+and tetrahedral Fe3+site features. Fe L-edge
184407-7Y. Y. C H I N et al. PHYSICAL REVIEW B 99, 184407 (2019)
XMCD spectra showed that bulk single-crystal YIG exhibits
antiferromagnetic coupling between the octahedral and tetra-hedral sites. Moreover, the full multiplet cluster calculationsof the Fe 2 pHAXPES, Fe L-edge XAS, and XMCD spectra
matched well with the experimental results and confirmedthe full local spin moments. In contrast, HAXPES, XAS,and XMCD of the Pt /YIG (3.3 nm) ultrathin epitaxial film
grown by a pulsed laser deposition method showed a finiteFe
2+contribution and a reduced Fe3+local spin moment. The
Fe2+state is attributed to a combination of oxygen deficiency
and charge transfer effects from the Pt capping layer to theultrathin film. However, the conserved XMCD spectral shapefor the ultrathin film indicates that the 3.3-nm epitaxial filmis genuinely ferrimagnetic, in contrast to recent studies onfilms grown by radio-frequency magnetron sputtering whichconcluded a magnetic dead layer of ∼6 nm. The presence of
Fe
2+and the reduced local spin moment in the epitaxial ultra-
thin film lead to a reduced Curie temperature, quantitativelyconsistent with known mean-field theory. The results show
a coupling of the local Fe spin moments, valency, and long-range magnetic ordering temperature in bulk single-crystaland epitaxial ultrathin-film YIG.
ACKNOWLEDGMENTS
We thank Dr. Y . Tanaka for providing the single-crystal
YIG and for valuable discussions. The authors would liketo thank the Ministry of Science and Technology of theRepublic of China, for financially supporting this researchunder Contracts No. MOST 106-2112-M-213-003-MY3, No.106-2112-M-213-001-MY2, and No. 107-2112-M-194-001-MY3. The synchrotron radiation experiments were performedat the BL12XU of SPring-8 with the approval of the JapanSynchrotron Radiation Research Institute (JASRI) (ProposalsNo. 2016B4255 and No. 2017A4251).
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184407-9 |
PhysRevLett.108.017601.pdf | Spin-Wave Modes and Their Intense Excitation Effects in Skyrmion Crystals
Masahito Mochizuki1,2
1Department of Applied Physics, University of Tokyo, Tokyo 113-8656, Japan
2Multiferroics Project, ERATO, Japan Science and Technology Agency (JST), Tokyo 113-8656, Japan
(Received 31 August 2011; published 5 January 2012)
We theoretically study spin-wave modes and their intense excitations activated by microwave magnetic
fields in the Skyrmion-crystal phase of insulating magnets by numerically analyzing a two-dimensional
spin model using the Landau-Lifshitz-Gilbert equation. Two peaks of spin-wave resonances with
frequencies of /C241 GHz are found for in-plane ac magnetic field where distribution of the out-of-plane
spin components circulates around each Skyrmion core. Directions of the circulations are oppositebetween these two modes, and hence the spectra exhibit a salient dependence on the circular polarizationof irradiating microwave. A breathing-type mode is also found for an out-of-plane ac magnetic field. Byintensively exciting these collective modes, melting of the Skyrmion crystal accompanied by a redshift ofthe resonant frequency is achieved within nanoseconds.
DOI: 10.1103/PhysRevLett.108.017601 PACS numbers: 76.50.+g, 75.10.Hk, 75.70.Ak, 75.78. /C0n
Competing interactions in magnets often cause nontri-
vial spin textures such as ferromagnetic domains and mag-netic bubbles, which have attracted a great deal of interest
from the viewpoints of both fundamental science and
technical applications in the field of spintronics [ 1,2]. In
particular, response dynamics of such magnetic structuresunder external fields is an issue of vital importance becauseits understanding is crucial for their manipulations.
The skyrmion, a nontrivial swirling spin structure carry-
ing a topological quantum number, is one of the interesting
examples of such spin textures. It was originally proposedby Skyrme to account for baryons in nuclear physics in the1960s as a quasiparticle excitation with spins pointing inall directions to wrap a sphere [ 3,4], and was recently
realized experimentally in two-dimensional condensed
matter systems, e.g., quantum Hall ferromagnets [ 5,6],
ferromagnetic monolayers [ 7], and doped layered antifer-
romagnets [ 8].
The formation of Skyrmion crystal (SkX) was theoreti-
cally predicted in Dzyaloshinskii-Moriya (DM) ferromag-nets without inversion symmetry [ 9,10], and was indeed
observed in the Aphase of metallic chiral magnets MnSi
[11,12] and Fe
1/C0xCoxSi[13] by neutron-scattering experi-
ments as a triangular lattice of Skyrmions with spins anti-parallel to the applied magnetic field at the Skyrmioncenters and parallel at their peripheries. A recentMonte Carlo study found a greater stability of the SkXphase in thin films [ 14]. This prediction was confirmed by
the real-space observation of the Skyrmion triangular lattice
inFe
0:5Co0:5Sithin films using the Lorentz force micros-
copy in a wide temperature and magnetic-field range [ 15].
Typically the Skyrmion is 10–100 nm in size, which is
determined by the ratio of DM interaction and exchangecoupling and is much smaller than magnetic bubbles.
Moreover, recent experiments found that the Skyrmion is
stable even near or above room temperature [ 16], and canbe manipulated by much lower electric currents than fer-
romagnetic domain walls [ 17,18]. These properties, i.e.,
small size, high operational temperature, and low thresholdfield, are advantageous for technical application to high-
density data storage devices. Therefore, understanding of
the dynamics of Skyrmions and SkX under external fieldsis an important issue [ 19].
In this Letter, we theoretically study collective spin
dynamics in the SkX phase of insulating ferromagnetswith DM interaction by numerical simulations of theLandau-Lifshitz-Gilbert (LLG) equation under time-dependent ac magnetic fields. We find a couple of spin-
wave resonances with frequencies /C241 GHz for in-plane ac
magnetic field where the out-of-plane spin componentsrotate around each Skyrmion core. The directions of theserotations are opposite between the higher-lying and lower-lying modes, and their spectra show strong circular-polarization dependence. A breathing-type mode is alsofound for out-of-plane ac magnetic field. Furthermore, westudy intense excitation effects of these collective modes,
and find a redshift of the resonant frequency and melting of
the SkX within nanoseconds. These findings will lead to afast manipulation of Skyrmions in nanoscale using spin-wave resonances.
We start with a classical Heisenberg model on a two-
dimensional square lattice [ 14], which contains nearest-
neighbor ferromagnetic exchange, Zeeman coupling, andDM interaction as [ 20],
H¼/C0JX
hi;jiSi/C1Sj/C0½HþH0ðtÞ/C138 /C1X
iSi
þDX
iðSi/C2Siþ^x/C1^xþSi/C2Siþ^y/C1^yÞ;(1)
where H¼ð0;0;HzÞis a constant external magnetic field
normal to the plane, and H0ðtÞis an applied time-dependent
magnetic field. The norm of the spin vector is set to be unity.PRL 108, 017601 (2012) PHYSICAL REVIEW LETTERSweek ending
6 JANUARY 2012
0031-9007 =12=108(1) =017601(5) 017601-1 /C2112012 American Physical SocietyWe adopt J¼1as the energy unit and take D¼0:09. The
spin turn angle /C18in the helical structure is determined by the
ratio D=J astan/C18¼D=ðffiffiffi
2p
JÞ, which is derived from a
saddle point equation of the energy as a function of /C18. Our
parameter set gives /C18¼3:64/C14or the periodicity of /C2499
sites, which corresponds to the Skyrmion diameter of
/C2450 nm if we consider a typical lattice parameter of 5 A ˚.
We study collective spin excitations of this model by
numerically solving the LLG equation using the fourth-order Runge-Kutta method. The equation is given by
@Si
@t¼/C01
1þ/C112
G½Si/C2Heff
iþ/C11G
SSi/C2ðSi/C2Heff
iÞ/C138;(2)
where /C11Gis the dimensionless Gilbert-damping coeffi-
cient. We derive a local effective field Heff
iacting on the
ith spin Sifrom the Hamiltonian H asHeff
i¼
/C0@H=@Si. All the calculations are performed for systems
with N¼288/C2288 sites under the periodic boundary
condition. We fix /C11G¼0:04for simulations of the spectra
shown in Fig. 2, while /C11G¼0:004for others.
We first study phase diagram of the model ( 1)a tT¼0
as a function of Hz. Starting with spin configurations ob-
tained in the Monte Carlo thermalization at low T,w e
further relax them by sufficient time evolution in the LLG
equation, and compare their energies. As shown in Fig. 1(a),
helical (HL), SkX, and ferromagnetic (FM) phases appearsuccessively as Hzincreases where critical fields are Hz¼
1:875/C210/C03andHz¼6:3/C210/C03, respectively. Here
Hz¼1/C210/C03corresponds to /C243:4m T if we adopt a
typical value of J¼0:4 meV andS¼1spins (see also
Table I). In Fig. 1(b), we display spin configuration of the
SkX phase where the in-plane components of the spinvectors at sites ( i
x,iy) are described by arrows when
modðix;6Þ¼modðiy;6Þ¼0. Here distribution of the spin
z-axis components, Szi, is shown by a color map. One
Skyrmion is magnified in Fig. 1(c)with a color map of the
local scalar spin chiralities given by
Ci¼Si/C1ðSiþ^x/C2Siþ^yÞþSi/C1ðSi/C0^x/C2Si/C0^yÞ:(3)
The finite spin chirality is a source of the topological Hall
effect [ 21] observed in experiments [ 22–25].
We then study the microwave-absorption spectra due to
spin-wave resonances in the SkX phase. We trace spindynamics after applying a /C14-function pulse of magnetic
field at t¼0, which is given by H
0ðtÞ¼/C14ðtÞH!. The
absorption spectrum or the imaginary part of the dynamicalsusceptibility, Im/C31ð!Þ, is calculated from the Fourier
transformation of magnetization mðtÞ¼ð 1=NÞP
iSiðtÞ.
In Fig. 2(a), we show calculated spectra for several
values of Hzwhen H!is parallel to the xyplane. We
find two resonance peaks in the spectra, and both of theirfrequencies increase as H
zincreases as shown in the inset
of Fig. 2(a). Note that !¼0:01corresponds to /C241 GHz
forJ¼0:4 meV (¼96:7 GHz ). Thus these spin-wave
resonances are located in the frequency range 500 MHz–1.2 GHz or in the microwave regime. On the other hand,the calculated spectra for H
!parallel to the zaxis are
shown in Fig. 2(b), which have only one resonance peak.
The resonant frequency !Rdecreases as Hzincreases as
shown in the inset. Again these resonances are located inthe microwave frequency regime.
To identify each spin-wave mode, we trace the spin
dynamics by applying a stationary oscillating magnetic
FIG. 1 (color). (a) Phase diagram of the Hamiltonian ( 1)a t
T¼0where HL, SkX, and FM denote helical, Skyrmion-
crystal, and ferromagnetic phases, respectively. (b) Spin con-
figuration of the SkX phase with a color map of the spin z-axis
components SziatHz¼3:75/C210/C03. Spin vectors at sites
(ix,iy) projected onto the xyplane are shown by arrows for
modðix;6Þ¼modðiy;6Þ¼0. (c) One Skyrmion is magnified
with a color map of the scalar spin chiralities Ci.
TABLE I. Unit conversion table when J¼0:4 meV .
Magnetic field H 1/C210/C03J /C243:4m T
Frequency ! 0.01 J /C241 GHz
Time t 1000 J/C01/C2410 nsecFIG. 2 (color online). Imaginary parts of (a) in-plane and
(b) out-of-plane dynamical susceptibilities, Im/C31ð!Þ, in the
SkX phase for several values of Hz. The insets show resonant
frequencies !Ras functions of Hz.PRL 108, 017601 (2012) PHYSICAL REVIEW LETTERSweek ending
6 JANUARY 2012
017601-2field with resonant frequency !R. We first study the modes
activated by the in-plane ac magnetic field by setting
H0ðtÞ¼ð 0;H!ysin!Rt;0Þwith H!y¼0:5/C210/C03. The
frequency !Ris fixed at !R¼6:12/C210/C03for the
lower-energy mode, while at !R¼1:135/C210/C02for
the higher-energy mode. We find that for all of the modes,all the Skyrmions show uniformly the same motion so thatwe focus on one Skyrmion hereafter. In Figs. 3(a)and3(b),
we display calculated time evolutions of the spins. Thespins at sites ( i
x,iy) are represented by arrows when
modðix;6Þ¼modðiy;6Þ¼0together with distributions
of the Szicomponents in the left panels, while those of
the spin chiralities Ciin the right panels. Interestingly the
area of larger Szior that of larger jCijcirculates around
each Skyrmion core even though the applied ac field H0ðtÞ
is linearly polarized in the ydirection. We find that direc-
tions of their rotations are opposite, i.e., counterclockwise(CCW) with respect to the magnetic field Hkzfor the
lower-lying mode while clockwise (CW) for the higher-lying mode. These directions are independent of the sign ofDM constant Dor winding direction of the spins. Instead
they are determined by a sign of the applied field or by the
spin orientation at the Skyrmion core.
Because of these habits, the spin-wave excitations acti-
vated by the in-plane ac magnetic field strongly depend onthe circular polarization of the irradiating microwave. InFig.4, we show calculated time evolutions of the magne-
tization parallel to the yaxis,m
yðtÞ¼ð 1=NÞP
iSyiðtÞ, when
we irradiate linearly polarized, left-handed circularly po-
larized (LHP), and right-handed circularly polarized(RHP) in-plane microwaves with resonant frequency !
R¼
6:12/C210/C03, which corresponds to the lower-lying mode
atHz¼3:75/C210/C03. More concretely, we apply a time-
dependent magnetic field H0ðtÞ¼½H0xðtÞ;H0yðtÞ;0/C138where
FIG. 3 (color). Spin dynamics of each collective mode in the SkX phase calculated at Hz¼3:75/C210/C03. Spins at sites ( ix,iy) are
represented by arrows when modðix;6Þ¼modðiy;6Þ¼0with color maps of the Szicomponents in the left panels, while in the right
panels, distributions of the local spin chiralities Ciare displayed. Temporal waveforms of the applied ac magnetic fields, H!ysin!Rt
andH!zsin!Rt, are shown in the uppermost figures where inverted triangles indicate times at which we observe the spin configurations
shown here. (a) [(b)] Lower-energy [Higher-energy] rotational mode with !R¼6:12/C210/C03(!R¼1:135/C210/C02) activated by the
in-plane ac magnetic field. Distributions of the Szicomponents and the spin chiralities Cicirculate around the Skyrmion core in a
counterclockwise (clockwise) fashion. (c) Breathing mode with !R¼7:76/C210/C03activated by the out-of-plane ac magnetic field.PRL 108, 017601 (2012) PHYSICAL REVIEW LETTERSweek ending
6 JANUARY 2012
017601-3H0xðtÞ¼/C11H!xycos!RtandH0yðtÞ¼H!xysin!Rtwith/C11¼0
for the linearly polarized microwave and /C11¼1(/C01) for
the LHP (RHP) microwave. In the LHP (RHP) microwave,its magnetic-field component rotates in a CCW (CW) way.
Here we fix H
!xy¼0:5/C210/C03. We find that irradiation of
the LHP microwave significantly enhances the magnetiza-
tion oscillation as compared to the linearly polarized mi-
crowave, whereas the RHP microwave cannot activate
collective spin oscillations.
Next we discuss a spin-wave mode activated by the
out-of-plane ac magnetic field. We again trace spin dy-
namics by applying H0ðtÞ¼ð 0;0;H!zsin!RtÞwith!R¼
7:76/C210/C03andH!z¼0:5/C210/C03. We observe a breath-
ing mode where the area of each Skyrmion extends and
shrinks dynamically as shown in Fig. 3(c).
We finally study effects of the intense spin-wave exci-
tation. We apply in-plane LHP ( /C11¼1) and RHP ( /C11¼/C01)
microwaves of H0xðtÞ¼/C11H!xycos!t and H0yðtÞ¼
H!xysin!tto the SkX phase at Hz¼6:3/C210/C03. The
system is located on the phase boundary between the
SkX and FM phases. Here we take H!xy¼0:5/C210/C03,
which corresponds to /C241:7m T when J¼0:4 meV
andS¼1. The frequency !is fixed at 7:4/C210/C03. This
value is nearly equal to the resonant frequency !R¼
7:8/C210/C03of the lower-energy mode, but slightly
deviates from it in reality. Because the intense spin-wave
excitations necessarily change the spin structure fromits equilibrium configuration, and it results in redshifts of
the resonant frequencies, we chose !slightly smaller
than !
Rof the nearly equilibrium case in advance. In
fact, the redshift can be seen in Fig. 4. The magnetization
dynamics under the LHP microwave becomes slow as
compared to that under the linearly polarized microwave
when the oscillation amplitude becomes larger. One can
easily notice this fact from different maximum points
between these two oscillations. Indeed the oscillationfrequency in Fig. 4under the LHP microwave is
!/C246:1/C210
/C03for0<t< 2000 , while !/C245:7/C210/C03
for3000 <t< 5000 .
In Figs. 5(a) and5(b), we show snapshots of the spin
configurations at several times under the irradiating LHP
microwave. We observe melting of the SkX due to the
intensively excited rotational spin-wave modes. The melt-
ing occurs within t/C245000 –6000 . Here t¼1000 corre-
sponds to /C2410 nsec when J¼0:4 meV . Thus the melting
occurs within 50–60 nsec. We also find that the SkX
melting is difficult to achieve either by the RHP microwave
or even by the LHP microwave if its frequency is off
resonant. Note also that the spatial pattern in Fig. 5(c)
loses a periodicity of the original SkX, suggestive of a
chaotic aspect of the melting dynamics.
We finally compare the modes found in the SkX phase
with those in the vortex-state nanodisks clarified in
Refs. [ 26–29]. The twofold rotational modes and the
breathing mode found in the SkX resemble, respectively,the twofold translational modes expressed by the Bessel
functions with m¼/C6 1and the radial mode with m¼0in
the vortex-state nanodisks. In Ref. [ 28], Ivanov and Zaspel
theoretically showed that degeneracy of the translationalmodes with m¼/C6 1in the nanodisk is lifted under an
applied magnetic field normal to the disk. We consider thata similar mechanism works in the SkX case for the doublet
CW and CCW modes. There are also several differences.
The modes in nanodisks are mainly governed by the long-range dipolar interaction, resulting in their salient aspect-ratio dependence. Note that their frequencies go to zero inthe zero aspect-ratio limit. In contrast, the SkX and itsdynamics considered here are governed by the nearest-neighbor spin interactions described in the Hamiltonian
(1). The essential relevance of the DM interaction to the
SkX is indicated by several experimental findings [ 15]
such as its emergence only in chiral magnets, unique spin-0.800.8
my
time0 1000 2000 3000 4000circular (LHP)linear
circular (RHP)xyH’
LHP (CCW)
xyH’xyH’
linear
RHP (CW)
FIG. 4 (color online). Calculated time evolutions of magneti-
zation ( ky),myðtÞ¼ð 1=NÞP
iSyiðtÞ, in the SkX phase at Hz¼
3:75/C210/C03under linearly polarized, left-handed circularly
polarized (LHP), and right-handed circularly polarized (RHP)
in-pane ac magnetic fields with resonant frequency !R¼
6:12/C210/C03corresponding to the lower-lying mode.
FIG. 5 (color online). Melting of the SkX within nanoseconds
under irradiating LHP microwave, which excites the rotationalspin-wave modes intensively (see text). Color maps of the S
zi
components are displayed at (a) t¼0, (b) t¼4000 , and
(c)t¼7200 . Figures magnify a partial area with 220/C2220
sites for clarity, while the calculations are done for 288/C2288
sites with the periodic boundary condition. Temporal waveform
of the microwave is also shown where times corresponding tofigures (a), (b), and (c) are indicated by inverted triangles.PRL 108, 017601 (2012) PHYSICAL REVIEW LETTERSweek ending
6 JANUARY 2012
017601-4swirling directions of Skyrmions, and considerably small
size (10–100 nm) of Skyrmions compared to dipolar-force-induced magnetic bubbles. Thus we expect negligible
aspect-ratio dependence of the modes as well as weak
influences of the dipolar interaction. Our study focuseson thin films whose thickness is much smaller than theSkyrmion diameter because a greater stability of the SkXin thinner films has been confirmed [ 14,15]. In such a case,
the system can be regarded as ferromagnetically stackedtwo-dimensional layers, which guarantees the validity ofour results based on a two-dimensional model.
In summary, we have theoretically studied spin-wave
excitations in the SkX phase of insulating ferromagnetswith DM interaction. We have found a couple of rotationalmodes with /C241 GHz frequencies for in-plane ac magnetic
field. The rotations are in a CCW fashion for the lower-lying mode, while in a CW fashion for the higher-lyingmode. These habits give rise to strong dependence of thesespin-wave excitations on the circular polarization of the
irradiating microwave. A breathing mode has been found
for out-of-plane ac magnetic field. We have also observedthe melting of the SkX under the irradiating LHP micro-wave. These findings will open a route to manipulation ofthe Skyrmion as a nanoscale spin texture using spin-waveresonances.
The author is deeply grateful to N. Nagaosa for fruitful
discussion and insightful suggestions. The author also
thanks Y. Tokura, M. Kawasaki, X. Z. Yu, and S. Seki for
stimulating discussions. This work was supported byGrant-in-Aid (No. 22740214) and G-COE Program‘‘Physical Sciences Frontier’’ from MEXT Japan, byFunding Program for World-Leading Innovative R&D onScience and Technology (FIRST Program) on ‘‘QuantumScience on Strong Correlation’’ from JSPS, and byStrategic International Cooperative Program (Joint
Research Type) from JST.
Note added in proof .—Recently Petrova and
Tchernyshyov analytically derived rotational spin-wavemodes in the SkX phase [ 30]. Analysis of the neutron-
scattering data [ 31] based on our finding is an issue of
future interest.
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017601-5 |
PhysRevB.103.014433.pdf | PHYSICAL REVIEW B 103, 014433 (2021)
Current-induced spin-wave Doppler shift and attenuation in compensated ferrimagnets
Dong-Hyun Kim,1Se-Hyeok Oh,2Dong-Kyu Lee,3Se Kwon Kim,4and Kyung-Jin Lee3,4,5,*
1Department of Semiconductor Systems Engineering, Korea University, Seoul 02841, Korea
2Department of Nano-Semiconductor and Engineering, Korea University, Seoul 02841, Korea
3Department of Materials Science and Engineering, Korea University, Seoul 02841, Korea
4Department of Physics, Korea Advanced Institute of Science and Technology, Daejeon 34141, Korea
5KU-KIST Graduate School of Converging Science and Technology, Korea University, Seoul 02841, Korea
(Received 17 July 2020; revised 25 November 2020; accepted 7 January 2021; published 20 January 2021)
We theoretically and numerically study current-induced modification of ferrimagnetic spin-wave dynamics
when an electrical current generates adiabatic and nonadiabatic spin-transfer torques. We find that the sign of theDoppler shift depends on the spin-wave handedness because the sign of spin polarization carried by spin wavesdepends on the spin-wave handedness. It also depends on the sign of the adiabatic-torque coefficient, originatingfrom unequal contributions from two sublattices. For a positive nonadiabaticity of spin current, the attenuationlengths of both right- and left-handed spin waves increase when electrons move in the same direction withspin-wave propagation. Our result establishes a way to simultaneously measure important material parametersof a ferrimagnet, such as angular momentum compensation point, spin polarization, and nonadiabaticity usingcurrent-induced control of ferrimagnetic spin-wave dynamics.
DOI: 10.1103/PhysRevB.103.014433
I. INTRODUCTION
Conventional semiconductor devices use the electron
charge to compute and store information, which inevitablycauses Joule heating. In contrast, spin wave (SW) devices,where the SW is used as the information carrier, avoid theJoule heating as the SW is a collective low-energy magneticexcitation that does not involve moving charges [ 1–3]. Several
concepts of SW devices implementing Boolean/non-Booleancomputing and multi-input/output operations have been re-ported [ 4–17]. Up until now, most SW studies have focused
on ferromagnetic SWs.
In comparison to ferromagnetic SWs, antiferromagnetic
SWs have several distinct features. Unlike ferromagnetic SWswhose frequency is in gigahertz (GHz) ranges, the frequencyof antiferromagnetic SWs can reach terahertz (THz) ranges[18,19], which allows fast SW operation. In addition, both
right-handed and left-handed modes are allowed in antiferro-magnets because of the antiferromagnetic coupling betweentwo sublattice moments [ 20,21]. This gives an additional de-
gree of freedom for SW operations [ 22–26] as compared to
the ferromagnetic SW that has only the right-handed mode.
This intriguing antiferromagnetic dynamics is also realized
in compensated ferrimagnets [ 27–40]. Antiferromagnetically
coupled ferrimagnets composed of rare-earth (RE) and tran-sition metal (TM) elements have two compensation points.One is the magnetic moment compensation point where thenet magnetic moment is zero and the other is the angularmomentum compensation point where the net angular mo-mentum is zero. These two compensation points are different
*kjlee@kaist.ac.krwhen the Landé gfactors of RE and TM elements are dif-
ferent [ 27]. As the intrinsic dynamics of localized spins is
governed by the commutation relation between angular mo-mentum (not magnetic moment) and the relevant Hamiltonian,antiferromagneticlike spin dynamics is realized at the angularmomentum compensation point of compensated ferrimagnets.Given that the net magnetic moment is nonzero at the angularmomentum compensation point, RE-TM ferrimagnets allowus to investigate antiferromagneticlike spin dynamics with afinite Zeeman coupling. For this reason, antiferromagneticlikespin dynamics of compensated ferrimagnets has been exten-sively studied in recent studies [ 27–40].
Another intriguing feature of compensated ferrimagnets
is that spin transport is distinct from both ferromagnets andantiferromagnets. When a spin-polarized current is injectedinto a magnetic material, it exerts a torque on the local mag-netic moment by transferring spin angular momentum. Thisspin-transfer torque (STT) [ 41,42] consists of two mutually
orthogonal vector components, adiabatic torque and nonadi-abatic torque [ 43–51], for continuously varying spin textures
such as SW, domain wall, and skyrmion. For ferromagnets, itis well known that the adiabatic STT causes current-inducedSW Doppler shift [ 52,53] whereas the nonadiabatic STT con-
trols SW attenuation [ 54–56]. It was predicted [ 57] that the
current-induced SW Doppler shift by the adiabatic STT isalso present for antiferromagnets. Although there has beenno study on the current-controlled SW attenuation for antifer-romagnets, a recent numerical study found a non-negligiblenonadiabatic STT for antiferromagnetic domain walls [ 58],
suggesting that electrical currents can control the attenuationof antiferromagnetic SWs.
In addition, a recent experiment on GdFeCo ferrimagnets
shows that the adiabatic torque in this material can be large
2469-9950/2021/103(1)/014433(7) 014433-1 ©2021 American Physical SocietyKIM, OH, LEE, KIM, AND LEE PHYSICAL REVIEW B 103, 014433 (2021)
FIG. 1. (a) A schematic illustration of ferrimagnetic spin waves
when the current is applied along the xaxis. For numerical simu-
lations, an ac field Hac(10 mT) is applied to excite SWs. (b) The
Doppler shift for right- (solid line) and left-handed (dashed line)
SW [/Delta1ω±=ω±(J=1×109A/m2)−ω±(J=0)] as a function of
net spin density δs. Here, we assume that the exchange constant
A=3×10−12J/m, the easy-axis anisotropy constant along the zdi-
rection K=104J/m3, spin polarization PRE=0.1,PTM=0.4, and
the wave vector is 0 .02, 0.03, and 0 .04 nm−1.
[59], which stems from a finite net spin polarization of RE
and TM sublattices. Thus, the current-induced SW Dopplershift of compensated ferrimagnets is expected to be similarin magnitude to that of ferromagnets. Moreover, the sameexperiment [ 59] shows that the nonadiabatic torque in this
material is large (i.e., equivalently, the ratio of nonadiabaticityβto damping αis large). This large nonadiabaticity of spin
current in compensated ferrimagnets is attributed to the en-hanced spin mistracking [ 46,48,58,59], originating from the
weakened spin dephasing in the antiferromagnetically alignedspin moments [ 60,61]. This unique STT characteristic of com-
pensated ferrimagnets motivates us to investigate STT effectson ferrimagnetic SWs.
In this work, we theoretically and numerically study the
STT-induced control of ferrimagnetic SW dynamics nearthe angular momentum compensation point. To begin with,we derive the equations of motion for ferrimagnetic SWsin the presence of two torque components. From the equa-tions of motion, we obtain current-driven ferrimagnetic SWDoppler shift and attenuation. Then, we perform atomisticlattice model simulations to verify the obtained analytic so-lutions. We show that the ferrimagnetic SW Doppler shift dueto the adiabatic torque for right-handed SWs is opposite tothat for left-handed SWs since they carry opposite spin polar-izations. We also find that the SW attenuation is suppressed,and the SW amplitude is even amplified when a sufficientlylarge nonadiabatic torque is exerted.
II. ANALYTIC THEORY
We consider a ferrimagnet consisting of RE and TM mo-
ments, which are antiferromagnetically coupled as shown inFig. 1(a). We introduce two unit vectors A
kandBkdenoting
localized spins located at two sublattices, the AandBsites.
We define the total magnetization vector and the staggeredmagnetization vector as m=A
k+Bkandn=(Ak−Bk)/2,
respectively. The spin density is sA(B)=MA(B)/γA(B)where
MA(B)is the saturation magnetization and γA(B)is the gyro-
magnetic ratio. The Lagrangian density Lfor ferrimagnets isgiven by [ 30,62–65]
L=−s˙n·(n×m)−δsa(n)·˙n−U, (1)
where s=(sA+sB)/2 is the sum of spin densities of two sub-
lattices, δs=sA−sBis the net spin density, a(n) is the vector
potential, and the potential energy Ucontains the exchange
energy and easy-axis anisotropy energy, given by
U=A
2(∇n)2+a
2m2+Lm·∂xn−K
2(ˆz·n)2. (2)
Here Ais the inhomogeneous exchange, ais the homogeneous
exchange, Lis the parity-breaking exchange term [ 65,66], and
Kis the effective easy-axis anisotropy including the demag-
netization effect in the zdirection. We assume that the Gilbert
damping constant αis the same regardless of site ( αA=αB),
which simplifies the Rayleigh dissipation function as R=
αs˙n2. In this theory, we neglect nonlocal dipolar interaction
because net magnetization is an order of magnitude smallerthan the ferromagnets.
By solving the above equations for nandm, we obtain
two staggered equations of motion to linear order in thecurrent-induced STT effective field (i.e., by working withinlinear-response theory) and to the first order in the net mag-netization |m|by assuming that a change from a ground state
(with m=0) is small, i.e., |m|/lessmuch 1, due to the strong anti-
ferromagnetic exchange coupling by following the approachtaken in Ref. [ 67]:
˙n=−1
sfm×n+Tn
STT, (3)
˙m=−1
sfn×n+2α˙n×n−δs
s˙n+Tm
STT, (4)
where fm=−∂U
∂m,fn=−∂U
∂n,Tn(m)
STTis the STT that affects
n(m) dynamics, given as (see Appendix)
Tn
STT=−b+
j
2∂n
∂x−βb−
j
2n×∂n
∂x, (5)
Tm
STT=−b−
j∂n
∂x−βb+
jn×∂n
∂x, (6)
where b±
j=−μB
2e(PAgA
MA±PBgB
MB)Jeis the magnitude of adia-
batic spin torque, PA(PB) is the spin polarization, gA(gB)i s
the Landé gfactor, μBis the Bohr magneton, eis the electron
charge, Jeis the current density, and βis the nonadiabaticity.
Note that, when the two sublattices are equivalent and thusb
−
j=0, Eqs. ( 5) and ( 6) are same (except for numerical
factors) as the two spin-transfer torque terms for antiferro-magnets shown in Eqs. ( 5) and ( 6)o fR e f .[ 67]. When deriving
Eqs. ( 5) and ( 6), we retained the terms involving the gradient
of the order parameter nwhile neglecting the terms involving
the small net magnetization mby assuming mis strongly
suppressed by the antiferromagnetic exchange coupling. Here,we define that all of spin polarization, Landé gfactor, Bohr
magneton, and electron charge are positive and assume β
A=
βB=βfor simplicity. We note that b+
jcorresponds to a stag-
gered torque exerting on two sublattice moments, whereasb
−
jcorresponds to a uniform torque. For antiferromagnets,
b−
jvanishes and b+
jis the only torque to drive dynamics of
antiferromagnetic spin textures. In contrast, for ferrimagnets,
014433-2CURRENT-INDUCED SPIN-W A VE DOPPLER SHIFT AND … PHYSICAL REVIEW B 103, 014433 (2021)
both b+
jandb−
jare nonzero in general so that both torques
affect the dynamics.
We derive the equation of motion by inserting the STT
[Eqs. ( 5) and ( 6)] into the staggered equations of motion
[Eqs. ( 3) and ( 4)]. Then, we obtain the equation of motion
fornas
ρnרn+2αsn×˙n+δs˙n
=A∗n×∂2
xn+Kn×nzˆz−sb−
j∂xn−sβb+
jn×∂xn,(7)
where A∗=A−L2/ais the renormalized exchange stiffness
constant [ 65] andρ=s2/ais the inertia. It is worthwhile to
note that the STT effect, i.e., the third and fourth terms on theright-hand side of Eq. ( 7), comes from T
m
STT[Eq. ( 6)], which is
the STT acting on a ferromagnetic component m. On the other
hand, the contribution of Tn
STT[Eq. ( 5)], i.e., the STT acting
on a stagger vector n, does not appear in Eq. ( 7) because it is
of the third order in small parameters and thus negligible.
By defining a complex field as ψ±=nx∓inyfor right- and
left-handed SWs and linearizing the above equation for nxand
ny, we obtain
±δS˙ψ±−i2αs˙ψ±−iρ¨ψ±
=− iA∗∂2
xψ±+iKψ±∓sb−
j∂xψ±+isβb+
j∂xψ±.(8)
The upper (lower) sign corresponds to right- (left-)
handed SW. By inserting the plane wave solution ψ±=
exp[i( kx−ω±t)] exp[ −x//Lambda1±] into Eq. ( 8), we obtain the SW
dispersion and SW attenuation length /Lambda1, given as
ω±=±δs+/radicalBig
δ2s+4ρ(A∗k2+K∓sb−
jk)
2ρ, (9)
/Lambda1±=2A∗k∓sb−
j
s(2αω±−βb+
jk). (10)
Equations ( 9) and ( 10) are our central results.
We first discuss the current-induced SW Doppler shift
[Eq. ( 9)]. For antiferromagnets ( δs=0 and b−
j=0), Eq. ( 9)
shows no current-induced SW Doppler shift. This is causedby the fact that we derive the equations with the second-orderexpansion of small parameters. When we consider up to thethird-order terms, there is a finite SW Doppler shift evenfor antiferromagnets, which is consistent with Ref. [ 57]. For
ferrimagnets, the last term in the square root of Eq. ( 9) (i.e.,
∓sb
−
jk) signifies the current-induced SW Doppler shift. It
originates from the uniform adiabatic torque b−
jacting on a
ferromagnetic component m.
Figure 1(b) shows the current-induced SW Doppler shift
/Delta1ω±as a function of the net spin density δs, computed from
Eq. ( 9). Three observations are worth mentioning. First, the
sign of Doppler shift depends on the SW handedness be-cause opposite spin polarizations are carried by right- andleft-handed SWs. Second, the Doppler shift is also related tothe sign of b
−
jbecause b−
jcan be positive or negative depend-
ing on the material parameters such as polarization, Landé g
factor, and saturation magnetization. For a specific RE-TMferrimagnet, i.e., a GdCo ferrimagnet, the sign of b
−
jwould
not change with temperature in the vicinity of TAbecause
gGd≈gCoand MGdis not much different from MCo[59],while PGdis four times smaller than than PCo[68]. Third, the
Doppler shift /Delta1ω±is maximized in the vicinity of the angular
momentum compensation point TA(i.e.,δs=0). To get an
insight into the second observation, we expand Eq. ( 9)i nt h e
limit of small current density and obtain ω±≈ω0,±+/Delta1ω±,
where the current-independent frequency ω0is given by
ω0,±=±δs+/radicalbig
δ2s+4ρ(A∗k2+K)
2ρ, (11)
and, the current-induced Doppler shift /Delta1ω±is given by
/Delta1ω±=∓sb−
jk
/radicalbig
δ2s+4ρ(A∗k2+K). (12)
Equation ( 12) shows that, in this limit, the current-induced
Doppler shift of ferrimagnetic SW is linear in kand in current
density as for ferromagnetic SWs [ 52–54]. It also shows that
the current-induced Doppler shift /Delta1ω±is maximized in the
vicinity of TAwhere δsvanishes. This result suggests that one
can experimentally determine TAby measuring the current-
induced SW Doppler shift.
We next discuss the current-induced control of SW atten-
uation [Eq. ( 10)]. For antiferromagnets ( δs=0 and b−
j=0),
Eq. ( 10) shows that the staggered nonadiabatic torque (i.e.,
βb+
jk) modifies the SW attenuation length. It means that
the SW attenuation length in antiferromagnets is determinedby the denominator (2 αω
±−βb+
jk), which describes the
competition between the damping torque and the staggerednonadiabatic torque. For ferrimagnets, in addition to the stag-gered nonadiabatic torque, the uniform adiabatic torque (i.e.,∓sb
−
j) in the numerator of Eq. ( 10) also controls the SW at-
tenuation length, but its contribution is independent of k. With
typical material parameters, however, this adiabatic-torquecontribution to the SW attenuation length is usually negligibleso that the main contribution is the competition between thedamping torque and the staggered nonadiabatic torque, evenfor ferrimagnets.
Current-induced effect on the SW attenuation length de-
pends on the relative flow direction of the electron and theSW ( k). Considering β> 0, when electrons flow in the same
(opposite) direction as SWs, the attenuation length increases(decreases). When a large current is injected, i.e., b
+
j>2αω±
βk,
Eq. ( 10) becomes negative so that the SW solution is ψ=
exp[i( kx−ωt)] exp[ +x/|/Lambda1|], meaning that SWs are amplified
for both antiferromagnets and ferrimagnets.
III. NUMERICAL ANALYSIS
To verify the above analytic results, we perform atomistic
lattice model simulations. We consider the one-dimensionalatomistic Hamiltonian as
H=A
sim/summationdisplay
i,jSi·Sj−Ksim/summationdisplay
i(Si·ˆz)2, (13)
where Asimis the exchange constant, Ksimis the easy-axis
anisotropy constant, Siis the spin moment vector at the isite,
andjis the notation representing the nearest lattice of the site
i. The atomistic Landau-Lifshitz-Gilbert equation including
014433-3KIM, OH, LEE, KIM, AND LEE PHYSICAL REVIEW B 103, 014433 (2021)
TABLE I. The saturation magnetizations for RE and TM
elements. The index T2corresponds to the angular momentum com-
pensation temperature TA.
Index T1 T2(=TA) T3
MRE(kA/m) 426 386 344
MTM(kA/m) 455 424.6 392
δs(×10−8Js/m3) 7.02 0 −7.02
STT terms is given as
∂Si
∂t=−γiμ0Si×Heff,i+αiSi×∂Si
∂t−bJ,iSi+1−Si−1
2d
−βibJ,iSi×Si+1−Si−1
2d. (14)
We solve the above equation by using the Runge-Kutta
fourth-order method. Here, γi=giμB/¯his the gyromagnetic
ratio, μ0is the permeability in vacuum, giis the Landé g
factor, Heff,i=−1
μi∂H
∂Siis the effective field, μiis the magnetic
moment, αiis the Gilbert damping constant, bJ,i=−giPiμB
2eMiJe
is the magnitude of adiabatic STT, Piis the spin polarization,
Miis the saturation magnetization, and βiis the nonadia-
baticity. We locally apply a circularly polarized external field,μ
0Hac=μ0H0(cos 2πft,sin 2πft,0) with μ0H0=10 mT
to excite SWs in a ferrimagnet. We also inject an in-planecurrent corresponding to the current density J
eranging from
−5×1012A/m2to+5×1012A/m2to induce STT. We use
the following simulation parameters: the lattice constant d=
0.4 nm, the exchange constant Asim=7.5 meV, the easy-axis
anisotropy constant Ksim=0.004 meV, the Gilbert damping
constant α=0.003, the nonadiabaticity β=10αandβ=
100α, the Landé gfactor gRE=2,gTM=2.2, and the spin
polarization PRE=0.1,PTM=0.4. In the continuum limit,
the corresponding parameters in Eq. ( 7)a r eg i v e nb y A∗=
4Asim/dandK=4Ksim/d3. We assume that both damping
constant and nonadiabaticity are the same regardless of thesublattice site as assumed for the analytic theory. We use thesaturation magnetization listed in Table I, which is measured
in Ref. [ 59] for GdFeCo. We consider the system size of
3200×100×0.4n m
3with cell size 0 .4×100×0.4n m3
and perform simulations up to 4 ns, after which the system
reaches a sufficiently steady state.
Figures 2(a) and 2(b), respectively, show dispersions of
the right- and left-handed SWs at zero applied current. T2
corresponds to the angular momentum compensation point
TAwhere δs=SRE−STM=0 and T1<T2<T3. In all cases,
numerical results (symbols) are in agreement with analyticalresults [lines, Eq. ( 9)]. The frequency of the right-handed SW
is the highest at T
1[Fig. 2(a)], whereas the frequency of the
left-handed SW is the lowest at T1[Fig. 2(b)]. This difference
originates from different δs[Eq. ( 9)].
Figures 2(c) and 2(d), respectively, show the current-
induced SW Doppler shifts of the right- and left-handedSWs at the angular momentum compensation temperatureT
A(=T2) when the current density Je=± 5×1012A/m2is
applied. Numerical results (symbols) are in reasonable agree-ment with Eq. ( 9) (solid lines). For the right-handed SW
[Fig. 2(c)] and k>0, a positive (negative) current decreases
FIG. 2. Ferrimagnetic SW dispersion for (a) right- and (b)
left-handed SW in the vicinity of angular momentum compensa-tion temperature ( T
A) when no current is applied. Current-induced
Doppler shift of (c) right- and (d) left-handed SWs in ferrimagnet
atTA.
(increases) the SW frequency. On the other hand, for the left-
handed SW [Fig. 2(d)] and k>0, a positive (negative) current
increases (decreases) the SW frequency. Therefore, the sign ofthe Doppler shift of the right-handed SW is opposite to that ofthe left-handed SW, consistent with the analytic expression[Eq. ( 9)]. The same tendency of Doppler shift is obtained for
other temperatures (not shown).
Figures 3(a) [3(b)] shows the SW attenuation length as
a function of the current density for β=10αand right-
(left-)handed SWs. The SW frequency ( ω/2π)i s0 . 4T H z .
Numerical results (symbols) are in reasonable agreement withEq. ( 10) (solid lines). For a positive β, we find that the SW at-
tenuation length of both right- and left-handed SWs increaseswhen electrons move in the same direction with the SW prop-agation. When the nonadiabatic torque is sufficiently large[β=100α,F i g s . 3(c) and 3(d)], the antidamping effect of
nonadiabatic torque overcomes the intrinsic damping torqueand, as a result, the SW attenuation length becomes negative,meaning that the SW is amplified.
IV . SUMMARY
To summarize, we theoretically study the STT effects on
ferrimagnetic SWs. Unlike antiferromagnetic SWs for whichcurrent-induced Doppler shift is small, ferrimagnetic SWsexhibit non-negligible Doppler shift because of a finite spinpolarization. The current-induced Doppler shift is maximizedin the vicinity of the angular momentum compensation pointT
A, providing a way to measure TA. The sign of the Doppler
shift depends on the SW handedness, because the spin polar-ization carried by SWs also depends on the SW handedness.A recent experiment has identified the SW handedness in
014433-4CURRENT-INDUCED SPIN-W A VE DOPPLER SHIFT AND … PHYSICAL REVIEW B 103, 014433 (2021)
FIG. 3. The SW attenuation length as a function of current den-
sity at β=10αfor (a), (b) and β=100αfor (c), (d). (a), (c) are
for right-handed SWs and (b), (d) are for left-handed SWs. The solidlines are analytic results and symbols are numerical results.
ferrimagnets by measuring the relative magnitudes of Stokes
and anti-Stokes peak in the Brillouin light scattering [ 39]. Our
work suggests an alternative way to identify the SW handed-ness by measuring the sign of current-induced SW Dopplershift.
It is found that the attenuation length of ferrimagnetic SWs
is modified by nonadiabatic staggered torque, which can be
used to experimentally determine the nonadiabaticity βof a
ferrimagnet. Combined with the current-induced SW Dopplershift, our work provides a way to simultaneously determineimportant material parameters of ferrimagnets, namely, theangular momentum compensation point T
A, the spin polar-
ization P, and the nonadiabaticity β, by performing a single
series of time-domain measurements of current-induced SWdynamics in a ferrimagnet. However, the determination ofthe handedness or the unknown parameters is experimentallychallenging and may need to be combined with other indepen-dent measurements of the spin polarization [ 68] and T
A[29].
ACKNOWLEDGMENTS
K.-J.L. was supported by the National Research Founda-
tion (NRF) of Korea (Grant No. NRF-2020R1A2C3013302).S.K.K. was supported by Brain Pool Plus Program throughthe National Research Foundation of Korea funded bythe Ministry of Science and ICT (Grant No. NRF-2020H1D3A2A03099291).APPENDIX: DERIV ATION OF EXPRESSION FOR STT
ON FERRIMAGNETS
In this part, we derive Eqs. ( 5) and ( 6) from the STT
exerting on each sublattice as
∂Ak
∂t=−bj,A∂Ak
∂x−βAbj,AAk×∂Ak
∂x, (A1)
∂Bk
∂t=−bj,B∂Bk
∂x−βBbj,BBk×∂Bk
∂x, (A2)
where bj,i=−giμBPi
2eMiJeand the first (second) term represents
the adiabatic (nonadiabatic) torque. Using Ak=m
2+nand
Bk=m
2−n, we obtain
∂
∂t/parenleftBigm
2+n/parenrightBig
=−bj,A∂
∂x/parenleftBigm
2+n/parenrightBig
−βAbj,A/parenleftBigm
2+n/parenrightBig
×∂
∂x/parenleftBigm
2+n/parenrightBig
, (A3)
∂
∂t/parenleftBigm
2−n/parenrightBig
=−bj,B∂
∂x/parenleftBigm
2−n/parenrightBig
−βBbj,B/parenleftBigm
2−n/parenrightBig
×∂
∂x/parenleftBigm
2−n/parenrightBig
. (A4)
Combining Eqs. ( A3) and ( A4) and assuming a uniform β,w e
obtain
∂n
∂t=−b−
j
4∂m
∂x−b+
j
2∂n
∂x−βb−
j
8m×∂m
∂x−βb+
j
4m
×∂n
∂x−βb+
j
4n×∂m
∂x−βb−
j
2n×∂n
∂x, (A5)
∂m
∂t=−b+
j
2∂m
∂x−b−
j∂n
∂x−βb+
j
4m×∂m
∂x−βb−
j
2m
×∂n
∂x−βb−
j
2n×∂m
∂x−βb+
jn×∂n
∂x, (A6)
where b±
j=−μB
2e(PAgA
MA±PBgB
MB)Je. By retaining the terms in-
volving the gradient of the order parameter nwhile neglecting
the terms involving the small net magnetization mby assum-
ing that mis strongly suppressed by the antiferromagnetic
exchange coupling and thus |m|/lessmuch 1, the staggered equations
of STT are given as
Tn
STT=−b+
j
2∂n
∂x−βb−
j
2n×∂n
∂x, (A7)
Tm
STT=−b−
j∂n
∂x−βb+
jn×∂n
∂x. (A8)
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PhysRevA.95.022327.pdf | PHYSICAL REVIEW A 95, 022327 (2017)
Hybrid quantum systems with trapped charged particles
Shlomi Kotler,*Raymond W. Simmonds, Dietrich Leibfried, and David J. Wineland
National Institute of Standards of Technology, 325 Broadway St., Boulder, Colorado 80305, USA
(Received 9 August 2016; published 21 February 2017)
Trapped charged particles have been at the forefront of quantum information processing (QIP) for a few decades
now, with deterministic two-qubit logic gates reaching record fidelities of 99 .9% and single-qubit operations of
much higher fidelity. In a hybrid system involving trapped charges, quantum degrees of freedom of macroscopicobjects such as bulk acoustic resonators, superconducting circuits, or nanomechanical membranes, couple tothe trapped charges and ideally inherit the coherent properties of the charges. The hybrid system thereforeimplements a “quantum transducer,” where the quantum reality (i.e., superpositions and entanglement) of smallobjects is extended to include the larger object. Although a hybrid quantum system with trapped charges couldbe valuable both for fundamental research and for QIP applications, no such system exists today. Here we studytheoretically the possibilities of coupling the quantum-mechanical motion of a trapped charged particle (e.g.,an ion or electron) to the quantum degrees of freedom of superconducting devices, nanomechanical resonators,and quartz bulk acoustic wave resonators. For each case, we estimate the coupling rate between the chargedparticle and its macroscopic counterpart and compare it to the decoherence rate, i.e., the rate at which quantumsuperposition decays. A hybrid system can only be considered quantum if the coupling rate significantly exceedsall decoherence rates. Our approach is to examine specific examples by using parameters that are experimentallyattainable in the foreseeable future. We conclude that hybrid quantum systems involving a single atomic ionare unfavorable compared with the use of a single electron because the coupling rates between the ion and itscounterpart are slower than the expected decoherence rates. A system based on trapped electrons, on the otherhand, might have coupling rates that significantly exceed decoherence rates. Moreover, it might have appealingproperties such as fast entangling gates, long coherence, and flexible topology that is fully electronic in nature.Realizing such a system, however, is technologically challenging because it requires accommodating both atrapping technology and superconducting circuitry in a compatible manner. We review some of the challengesinvolved, such as the required trap parameters, electron sources, electrical circuitry, and cooling schemes in orderto promote further investigations towards the realization of such a hybrid system.
DOI: 10.1103/PhysRevA.95.022327
I. INTRODUCTION
Trapping of charged particles [ 1,2] has enabled long
interrogation times of their external and internal states,enabling precision metrology, such as atomic clocks. Applyingthese tools to atomic ions, paired with laser-enabled statemanipulation, can also turn ions into a quantum informationprocessing (QIP) platform [ 3–7]. Ions have demonstrated
record fidelities for initialization, readout, individual spinmanipulation [ 8], and entanglement [ 9,10].
Other quantum-coherent systems might therefore benefit,
by coupling to trapped ions, potentially inheriting aspectsof their high controllability and coherence. For example,as described below, we might be able to use a single
9Be+ion coupled to a ∼10 mg quartz resonator to cool
the latter close to its ground state. By placing the ion ina superposition state of motion and transferring it to amacroscopic resonator, we could explore bounds on quantummechanics for massive objects. The ion therefore could providea “quantum transducer” that enables the manipulation of amuch larger object in a coherent way at the single-phononlevel. For the purpose of QIP, ions might be used as excellentmemory units, e.g., for superconducting devices, as long asquantum information can be exchanged between the twosystems on timescales that are sufficiently short compared
*shlomi.kotler@nist.govwith the decoherence time of the superconducting circuit. Theinternal degrees of freedom of an ion can remain coherentfor tens to hundreds of seconds [ 8,11–13], significantly
exceeding the lifetime of coherent excitation in currentsuperconducting devices, typically limited to less than 100 μs
(see, e.g., Ref. [ 14]), setting the timescale for useful quantum
exchange.
The resonant interaction of ions with radio frequency
electrical resonators was studied in Ref. [ 15]. Complementary
parametric interaction schemes for the nonresonant case werestudied in Refs. [ 16–20]. Other suggestions include interfacing
nanomechanical resonators [ 21–25], electrical wires [ 26],
and superconducting qubits [ 25]. These reports analyzed the
basic physics involved in each of the different couplingmechanisms as well as the prospects of using such hybridsystems.
Here, we focus on a few specific examples of hybrid
systems rather than presenting a general treatment. For theseexamples we take into account available materials, achievablequality factors. and practical limitations. Nevertheless, ouranalysis is based on a unified framework (Sec. II) that allows
for direct comparison of relevant figures of merit associatedwith the different systems. We hope these examples arerepresentative of the different opportunities available and canilluminate some of the issues of hybrid QIP with chargedparticles.
A charged particle moving in a harmonic trap gives rise to
an oscillating electric dipole. This dipole in turn can couple
2469-9926/2017/95(2)/022327(29) 022327-1 ©2017 American Physical SocietyKOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
to nearby charged objects [ 21,27,28], generate image currents
in a nearby conductor [ 15], polarize a dielectric material, or
induce motion in a piezoelectric crystal. If the coupled systemalso has a harmonic mode resonant with the ion motion, energyexchange will occur between the ion harmonic motion and thecoupled system.
The analysis that follows below is guided by the realization
that coupling two quantum systems is a double-edged sword.Ideally, we would like to benefit from the useful propertiesof both systems. In reality, the hybrid system often inheritsthe disadvantages of both constituents. Therefore, to retainany useful quantum characteristics, we require that thecoupling rate between the two systems exceeds the fastestrelevant decoherence rate in both systems. Additionally, wefocus on specific architectures where the two technologiesinvolved could be compatible and not preclude either ofthe coupled systems from being close to a pure quantumstate.
Although we cannot completely rule out all mechanisms
considered here that involve an atomic ion, the analysisemphasizes how challenging it would be to incorporate ionsinto a hybrid system at the quantum level. The coupling rateswe calculate, based on experimentally attainable parameters,are either well below the decoherence rates or marginally closeto them. This conclusion changes when considering couplinga charged particle to a superconducting resonator, assumingan electron rather than an ion (e.g., see Refs. [ 15,18,29,30]
as well as Sec. VIfor a more extensive reference list). This
follows from the fact that for a particle of mass mthe coupling
rate is proportional to m
−1/2(see Sec. IV), rendering coupling
rates for an electron on the order of ∼0.1 to 1 MHz, where we
expect to exceed decoherence rates.
The shift from using an atomic ion to using an electron
has significant practical implications, as detailed in Sec. VI.
Laser-enabled state manipulation, specifically laser cooling,plays an important role in trapped atomic ion QIP experiments.Without these tools, electrical-circuit-based alternatives needto be considered along with their implications on the systemas a whole. We therefore embark on a feasibility study thattakes these implications into account, considering amongother factors trap stability, trap depth, maintaining super-conductivity, the requirements from a low-energy electron
source, electrical wiring, and the superconducting resonator
involved. A previous report [ 18] has already suggested a
specific electron trap that would support a parametric couplingscheme. The different aspects considered in the feasibil-ity study bear significance on the trap design, suggestingthat a larger trap be used for an electron-based hybridsystem.
Although technically challenging, these issues do not seem
to preclude a hybrid system based on a trapped electron. Asdetailed in Sec. VI, such a platform might offer appealing
qualities such as fast entangling gates ( ∼10 ns) and long
coherence times (seconds), rendering a coherence time togate time ratio of /greaterorequalslant10
8, far exceeding any current QIP
system. Moreover, the platform could offer a flexible couplingtopology enabled by interfacing engineered electrical circuits,potentially enabling high-fidelity electron spin readout. This,in turn, could open new avenues of basic research, interestingin their own right.II. ELECTRICAL EQUIVALENT OF MECHANICAL
MOTION
There are various systems that could, in principle, couple
to a trapped charged particle. Those systems differ from thecharged particle and from one another in frequency, mass,length scale, and coupling mechanism, as highlighted inFig. 1. With the exception of the electrical LC resonator,
all other systems considered here are mechanical resonatorsactuated by an electromagnetic field. To place all of themon an equal footing we associate an electrical equivalent foreach of these mechanical systems. This reduces the analysisof any of the hybrid systems into an all-electrical circuitproblem. Our discussion extends the treatment in Ref. [ 31]
where the electrical equivalent circuit of a trapped ion wasderived. This could also be derived by using the generalframework developed by Butterworth and Van Dyke [ 32–34]
that associates a circuit equivalent for electrically actuatedmechanical systems. We refer to the resulting electricalnetwork as the BVD equivalent circuit.
Suppose a mechanical system of mass mis placed near
an electrode that is biased with voltage V, resulting in a
forceF=βV acting on it. For simplicity, we assume the
geometry in Fig. 2(a), where two electrodes form the two
plates of a parallel plate capacitor, separated by a distanced. An important example (analyzed in Refs. [ 31,35]) is
that of a single charged particle with charge qresulting in
F=qV/d , i.e., β=q/d. In general, electrical actuation
could also result from dipolar interaction, electrostriction,piezoelectricity, etc. Since microscopically these mechanismsoriginate from having nonzero local charge densities within themechanical system, we lump the overall effect of the voltagewith a single effective parameter β.
When the mass mmoves at velocity v[see Fig. 2(b)],
it will induce a current I=βvat the electrode. This is an
immediate generalization of the single-charged-particle case:if it is at a distance xfrom an electrode it induces an image
charge of q
image=qx/d . Therefore, within the electrostatic
approximation, a velocity v=˙xwould translate into a current
I=qv/d . The induced charges will back-act on the mass
mwith an additional force /Delta1F. This force, however, will be
independent of Vand will not contribute to the induced current
I. The effect of /Delta1F can therefore be lumped into a (usually
but not necessarily) small change of the system’s mechanicalproperties, e.g., its spring constant in the case of a harmonicoscillator (for a rigorous derivation see Refs. [ 31,35]).
Now assume that the mechanical system is harmonic, i.e.,
that it has a resonant frequency ω
0and a friction coefficient γ.
If the voltage is time varying, V(t), the equation of motion for
the harmonic-oscillator position xis
m¨x+γ˙x+mω2
0x=βV(t). (1)
By using the relation I(t)=β˙xthis can be rewritten as
m
β2dI
dt+γ
β2I+mω2
0
β2/integraldisplayt
dt/primeI(t/prime)=V(t). (2)
Therefore, from the perspective of the electrical circuit, the
mechanical system is equivalent to a series combination of
022327-2HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
Electrostatic
Ind. currentsPiezoelectric
Piezoelectric198Hg+
FIG. 1. Examples of different platform candidates for a hybrid architecture considered in this paper. Clockwise from the top-middle:
198Hg+ion trap, quartz bulk acoustic wave resonator, gallium nitride nanobeams, superconducting LC circuit, and nanomechanical silicon
nitride (SiN) membrane. The ion (green shading) is coupled via piezoelectricity (red shading), induced image currents (purple shading) orelectrostatics (blue shading). Ion trap photograph courtesy of J. Bergquist, NIST, Boulder, Colorado 80305, USA. Gallium nitride nanobeams
photographs courtesy of K. Bertness, NIST, Boulder, Colorado 80305, USA. Quartz resonator device courtesy of S. Galliou, FEMTO-ST
institute, 25000 Besanc ¸on, France. SiN membrane photograph courtesy of K. Cicak, NIST, Boulder, Colorado 80305, USA.
mFV
d C0mI
vxV
C0
RLC
C0(a) (b)
(c)
FIG. 2. Simplified geometry for an electrically actuated mechan-
ical system. (a) A mechanical system of mass mis placed inside a
capacitor C0that is biased at a voltage V. The force acting on mis
assumed to be proportional to the capacitor bias voltage F=βV.( b )
If the mechanical system velocity is v/negationslash=0 an image current I=βvis
induced. (c) BVD equivalent circuit. The mechanical system electrical
response is identical to that of a series RLC circuit connected inparallel with the capacitor C
0.resistance, inductance, and capacitance; namely,
LdI
dt+RI+1
C/integraldisplayt
dt/primeI(t/prime)=V(t), (3)
where
L↔m
β2,R↔γ
β2,C↔β2
mω2
0, (4)
and their series combination is added in parallel to the
capacitance of the drive electrode C0[see Fig. 2(c)].
Throughout this paper, we refer to the mechanical system
and its electrical equivalent interchangeably, in order tosimplify the coupling analysis.
III. COUPLING IN STRONG QUANTUM REGIME
Our general problem is concerned with two resonantly
coupled harmonic oscillators (mechanical or electrical). Weassume that the coupling rate gis much smaller than the
frequencies of the harmonic oscillators so that the couplingHamiltonian can be treated perturbatively. The Hamiltoniancoupling term for two mechanical harmonic oscillators ofmasses m
1,m 2and bare frequencies ω/prime
1,ω/prime
2by a spring of
constant k[Fig. 3(a)]i s
Hc=kx1x2, (5)
022327-3KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
k1
m1k
m2k2
System A System B
C1L1
CL2
C2(a)
(b)
FIG. 3. (a) Coupled mechanical harmonic oscillators. (b) Cou-
pled electrical harmonic oscillators.
where x1andx2are the displacements of the oscillators from
equilibrium. The resonant frequency for each of the harmonicoscillators in the presence of the coupling spring is ω
i=
(ω/prime2
i+k/m i)1/2.I fω1=ω2=ω0the coupling Hamiltonian
can be rewritten in terms of a coupling rate gby expressing xiin
terms of their respective harmonic-oscillator ladder operatorsx
i=√¯h/(2miωi)(ˆai+ˆai†) so that
Hc=¯hg(ˆa1+ˆa1†)(ˆa2+ˆa2†), (6)
where
g=k
2ω0√m1m2, (7)
and ¯his the Planck constant divided by 2 π.
It will be useful later to express gin terms of an analog
electrical system [Fig. 3(b)] of two LC resonators coupled by
a shunt capacitor C. In this case, the coupling Hamiltonian is
Hc=1
Cq1q2, (8)
where q1andq2are the charges on the capacitors C1and
C2, respectively. The resonant frequency for each of the LC
resonators is ωi=1//radicalbig
LiC/prime
iwhere C/prime
i=CiC/(Ci+C)i st h e
series capacitance of CiandC. Assuming ω1=ω2=ω0,w e
can rewrite Eq. ( 8) in terms of the ladder operators, qi=/radicalbig
¯hω0C/prime
i/2(a+a†), so that Hctakes the form of Eq. ( 6) with
g=ω0
2/radicalBigg
C1C2
(C1+C)(C2+C). (9)
We stress that both Eqs. ( 7) and ( 9) are valid only if the coupling
rategis smaller than the harmonic oscillator’s frequency, i.e.,
g/lessmuchω0.
We will be particularly interested in the strong-coupling
quantum regime , i.e., when a large number of complete
energy oscillations occur between the two oscillators beforethey significantly lose coherence: N
osc≈τcoh/τosc/greatermuch1. Here
τosc=π/g is the time required for a complete energy os-
cillation (back and forth) between the two oscillators. Fora system of two harmonic oscillators, τ
cohis the average
exchange period of a single energy quantum with any of thethermal baths of the oscillators. We assume that coherence islimited by energy relaxation. In reality, there are additional
decoherence mechanisms that could decrease N
oscfurther and
the values calculated here should be considered as an upperbound. An important case is motional dephasing of a trappedcharged particle [ 21,36]. Although the motional heating rate
for trapped ions could be as low as a few quanta per second(see Appendix B), trap-frequency drifts, for example, could
cause motional dephasing at a higher rate. Another well-knownsource of motional decoherence is the nonlinear couplingbetween trap axes due to trap imperfections [ 21]. Although
these mechanisms could be reduced by technical means, itwould be highly favorable from a practical standpoint thatthe coupling strength g/greaterorequalslant2π×1 kHz, posing an additional
constraint in what follows.
When expressing the above condition in terms of the lower
of the two quality factors Qassociated with the two oscillators
and the temperature Tof their environment, we observe two
regimes. At “high” temperatures ( k
BT/greaterorequalslant¯hω0), the thermal
equilibration time constant τthermal=Q/ω 0of the oscillators
can be thought of as the 1 /etime required to heat the mechan-
ical oscillator from 0 K to the surrounding temperature T, i.e.,
the time it takes to acquire an average of (1 −1/e)nthermal
phonons where nthermal=[exp (¯hω0
kBT)−1]−1≈kBT
¯hω0energy
quanta and kBis the Boltzmann constant. Any quantum
coherent phenomena will therefore be restricted to timesshorter than τ
coh=τthermal/nthermal≈¯hQ/k BT, roughly the
time required to absorb one phonon at the rate of thermalequilibration. At “low” temperatures ( k
BT/lessorequalslant¯hω0) the equili-
brated oscillator contains one phonon or less on average andtherefore τ
coh=Q/ω 0. The strong quantum regime condition
therefore translates to
Nosc≈gQ
π(nthermal+1)ω0/greatermuch1. (10)
At typical liquid-helium temperatures of ∼4K ,kBT/¯h=
2π×83 GHz, so for frequencies below 83 GHz we require
Nosc≈gQ
2π×262 GHz/greatermuch1. (11)
For dilution-refrigerator temperatures of /lessorequalslant50 mK for
example, kBT/¯h=2π×1 GHz, so for frequencies below
1 GHz we require
Nosc≈gQ
2π×3.3 GHz/greatermuch1. (12)
The inequalities in Eqs. ( 10)–(12) introduce stringent
constraints both on the coupling strength gand the Qfactors
involved. The need for high Qfactors accounts for why
superconducting circuits, which often have high Qfactors,
naturally arise in the context of hybrid systems, as will be seenin the next section.
If the two oscillators have different eigenfrequencies ( ω
1/negationslash=
ω2) their weak off-resonant coupling could be brought into
a strong effective resonant coupling by modulating one ormore of the system parameters by a fraction 0 <η< 1, at
the difference frequency, ω
1−ω2, usually at the expense of
a lower coupling rate. For example, if the two mechanicaloscillators in Fig. 3(a) have different resonant frequencies,
022327-4HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
they can still be coupled by modulating the spring constant kat
the difference frequency. The expression for the coupling ratein Eq. ( 6) generalizes to g=ηk/(4√
ω1ω2m1m2). Therefore,
the coupling strength is reduced by η/2, where ηis typically
at the 0 .05 to 0 .2 range to avoid nonlinear behavior of the
coupling spring. We note that parametric schemes can havecertain advantages. For example, by coupling a low-frequencyresonator to a high-frequency resonator, a low number ofphonon or photon occupancy for the low-frequency resonatorcan be achieved which could be useful for experimentinitialization, for example. This, however, does not improvethe coherence time of either system unless they are coupledto different thermal baths with different temperatures (e.g.,see Ref. [ 37]). Since large coupling rates compared with
decoherence rates are critical, we concentrated on resonantoscillators in the above discussion and in what follows. Fordetails of parametric coupling schemes in the context of hybridsystems involving ions, see Refs. [ 17–20].
IV . TRAPPED CHARGED PARTICLE COUPLED
TO AN ELECTRICAL RESONATOR
The first hybrid system we consider is that of a trapped
charged particle coupled to an electrical resonator, followingRef. [ 15]( s e ea l s oR e f .[ 25]). Schematically, a point particle
of mass mand charge qis elastically bound by a trap, here
modeled by a spring (see Fig. 4), with a resonant radial
frequency ω
0. If the particle is placed between the two plates
of a capacitor, any voltage difference Vbetween the plates
would result in a force F=αqV/d acting on it, where dis
the distance between the plates and αis a unitless geometric
factor ( α=1 for a parallel plate capacitor with infinite plate
areas). The equivalent electrical circuit [Eq. ( 4)] is composed
of an effective inductance Lpand capacitance Cp, where
Lp=md2
α2q2,C p=1
Lpω2
0. (13)
Therefore, the hybrid system composed of a harmonically
confined charged particle and resonator is equivalent to alumped element LC circuit ( L
p,Cp) shunted by the trap
capacitance Ctrapand coupled to the electrical resonator, as
shown in Fig. 4(b).F r o mE q .( 9) and assuming C/greatermuchCtrapfor
m, qL
CdCpLp
CtrapL
C(a) (b)
FIG. 4. (a) A simplified picture of a trapped particle coupled to
an LC resonator. (b) The corresponding electrical BVD equivalent
circuit. The trap capacitance Ctrapin panel (b) is formed by the two
equivalent parallel plates, which are a distance dfrom one another in
panel (a).maximal coupling, we get
g=ω0
2/radicalBigg
Cp
Ctrap=αq
2d1/radicalbigmC trap. (14)
Notice that this is an upper bound on the coupling rate g.I n
any realistic implementation, the two trap electrodes need tobe dc biased independently and therefore a finite value of C
should be taken into account.
This coupling can be increased by trapping more than one
charged particle. If N
pparticles are trapped and form a Wigner
crystal, their common mode motion can be treated as that ofa single particle with a charge of N
pqand a mass of Npm.
From Eq. ( 14) it follows that g∝/radicalbigNp. For very small traps
however, Npwill be limited by the Coulomb repulsion between
the charges.
B a s e do nE q .( 10), Table Isummarizes the constraints on the
Qfactor of the electrical resonator required to be in the strong-
coupling quantum regime for various charged particles. Theseshould be compared with experimentally attainable values forlumped-element superconducting resonators that are typicallyin the range of Q∼10
4–105and in some cases up to 106,
mostly limited by dielectric losses [ 14,38]. Since the required
Qis greater than these values, achieving strong coupling of
an ion to a superconducting resonator at 4 K does not seemfeasible. In fact, the only two candidates from Table Ithat stand
out in terms of reasonable Qfactors are
9Be+(Q/greatermuch7×105at
50 mK) and electrons ( Q/greatermuch4×105at 4 K and Q/greatermuch7×103
at 50 mK). For9Be+it would require incorporating atomic ion
trapping technology into a dilution refrigerator, the discussionof which is beyond the scope of this paper and can be foundelsewhere [ 20]. We discuss the prospects of electron coupling
in the last part of the paper. Our estimates are compatible withprevious results [ 18,26].
In the above discussion we considered only lumped-
element electrical resonators. A different approach would be touse low frequency transmission line resonators. Those can besimpler to fabricate and could potentially have higher qualityfactors. As an example, Fig. 5(a) shows a simple geometry
where an ion is trapped close to the voltage antinode of aquarter-wave resonator. Near resonance, the transmission lineresonator is equivalent to a parallel LC circuit [see Fig. 5(b)]
with effective capacitance C=π/(4ω
0Z0) and inductance
L=1/(ω2
0C) where ω0is the resonance frequency and Z0
is the characteristic impedance of the transmission line [ 39].
The coupling strength is calculated, as before, by using theelectrical equivalent circuit
g=ω
0
2/radicalBigg
Cp
C+Ctrap. (15)
The main concern is that the effective capacitance Cof
these resonator modes is very large. For a typical Z0=50 ohm
transmission line and ω0=2π×10 MHz, C∼250 pF. The
coupling strength gwill therefore degrade by a factor of ∼70 as
compared with the numbers in Table I, requiring, for example,
a quality factor satisfying Q/greatermuch4×109for9Be+at 4 K. This
number exceeds the best quality factors for such resonators,having Q∼10
7at 10 MHz [ 40]. Moreover, our estimate for
gis an upper bound since, in a real geometry, the field lines at
022327-5KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
TABLE I. Coupling strengths of different trapped charged particles coupled to an electrical resonator. The mass of the proton and the
electron are mpandme, respectively. We assume the geometry in Fig. 4, withd=50μm,Ctrap=50 fF, and α=1, and use Eq. ( 14) to calculate
g. The table states a lower bound for the required Qfactors; namely, Qcorresponding to Nosc=1. Actual Qfactors should be at least an order
of a magnitude greater to comfortably satisfy inequality ( 10). These estimates are consistent with Ref. [ 26], where 600 Hz coupling strength
was estimated for40Ca+in a 1 MHz trap with 2 .5 pF trap capacitance, d=50μm, and α=1. Our trap-capacitance estimate of Ctrap=50 fF
can only be achieved in small trap geometries through careful design (see, for example, Sec. VI A ). Moreover, additional capacitors required
for the trap circuit operation may add to the total capacitance resulting in a lower coupling strength (see Sec. VI E ). The values for ghere,
therefore, should be considered as an upper bound estimate.
Particle Mass, m Trap frequency, ω0 Coupling strength, gQ min(4 K) Qmin(50 mK)
Electron me 1.3 GHz 1.2 MHz 4 ×1057×103
9Be+9mp 10 MHz 9 kHz 56 ×1067×105
24Mg+24mp 6M H z 6k H z 9 2 ×1061.1×106
40Ca+40mp 4.7 MHz 4 kHz 119 ×1061.5×106
88Sr+88mp 3.2 MHz 3 kHz 176 ×1062×106
the voltage antinode of the resonator will differ from those
of an ideal parallel plate capacitor. For these reasons, ouranalysis has focused on coupling the charged particle to alumped-element electrical oscillator, where the same resonantfrequency can usually be achieved with significantly lessoverall capacitance.
V . COUPLING TO MACROSCOPIC MECHANICAL
RESONATORS
To circumvent the limitations of attainable Qfactors of
superconducting devices, it has been suggested to try andcouple an ion directly to a high- Qmacroscopic mechanical
object by using electrostatic coupling [ 15,21,23–25] or piezo-
electricity [ 15,41].
m, qd
xV
CpLp
Ctrap C L(a)
(b)
FIG. 5. (a) A simplified picture of a trapped ion coupled to a trans-
mission line resonator. The ion is trapped close to the voltage antinodeof a short-circuited quarter-wave resonator. (b) The corresponding
electrical equivalent circuit. The ion is replaced with its equivalent
series capacitance C
pand inductance Lpwhile the resonator is
replaced with its equivalent lumped element representation formed by
a parallel LC resonator. Additional capacitance due to trap electrodes
is represented by Ctrap.A. Electrostatic coupling to a nanomechanical membrane
Commercial nanomechanical membrane resonators can
have high quality factors, over 107at 300 mK [ 42]. Recent
advances in membrane fabrication [ 43–47] have resulted in
quality factors as high as 108, even at room temperature. If
such a membrane is metalized on one side, and biased with avoltage U, it could electrostatically couple to an ion trapped
near its surface. To estimate this coupling, we assume thesimple geometries shown in Fig. 6. In both cases, the coupling
Hamiltonian is
H=αqUz
izm
d2
0, (16)
where zi,zmare the displacements of the ion zmotion and
the membrane, respectively, d0is the distance between the
membrane and the bottom electrode of the ion trap, and αis a
geometric factor as in Sec. IV. For the geometries considered
here, 0 .5/lessorequalslantα/lessorequalslant1 and we assume α=1 to get an upper bound
forg.A si nE q .( 6), we can derive the coupling strength
g=αqU
2d2
0ω0√mionM, (17)
where Mis the membrane mode mass and ω0its resonant
frequency. These masses are significantly larger than the ion
q,m ionU
d0q,m ionU(a) (b)
FIG. 6. Electrostatic coupling of a trapped ion (charge qand mass
mion) to a nearby rectangular nanomechanical membrane biased by a
voltage U. The ion is assumed to be trapped at a height d0/2 above
a surface trap, which is dc grounded with respect to the membrane,
suspended above the ion (for simplicity the trap rf electrodes areomitted). (a) A membrane (blue) is clamped at its rim, allowing for
a sinusoidal fundamental mode as in Ref. [ 43]. (b) A membrane
(blue) is attached by thin wires (red), allowing for a center-of-massfundamental mode as in Refs. [ 45,46].
022327-6HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
mass, thereby lowering the coupling strength, with a mass
ratio on the order of M/m ion∼1014for9Be+. We assume
thatd0=100μm and the ion is trapped midway between
the membrane and the trap. For a SiN membrane [ 43] with
dimensions 500 μm×500μm, coupled to a9Be+ion, we
get a mode mass of M∼2×10−11kg, a resonant frequency
ω∼2π×1 MHz, and a coupling strength of g/2π∼0.24 Hz
atU=1 V bias. Combined with an assumed quality factor
of 2×108, such a device does not satisfy the strong quan-
tum criteria at T=50 mK since gQ/ 2π∼0.048 GHz [see
Eq. ( 12)]. For a suspended trampoline membrane [ 45,46] with
dimensions 100 μm×100μm, coupled to a9Be+ion, we
get a mode mass of M∼10−12kg, a resonant frequency of
ω∼2π×140 kHz, and a coupling strength of g/2π∼12 Hz
atU=1 V, leading to gQ/ 2π∼1.2 GHz. The latter nearly
enters the strong quantum regime for T=50 mK. However,
taking into account ion heating rates still makes this schemeunfavorable, because ion motional heating rate and motionaldephasing would typically exceed g.
The coupling can be made stronger by increasing the bias
voltage Uat the expense of changing the trapping potential,
the ion position, and possibly the trapping stability. Evenwith the U=1 V assumed above, the equilibrium position
of, say a
9Be+ion in a 10 MHz harmonic trap, would move
by∼7μm. This might be mitigated by adding additional
electrodes that compensate for the static voltage bias effectof the membrane (e.g., see Ref. [ 25]). Those electrodes,
however, might shield some of the trapping field and needto be taken into account when estimating the ion-trappingpotential. In addition, a more careful estimation of gwould
take the membrane mode shape and finite size into account.Finally, adding an electrode to a membrane might decrease itsQfactor. Previous experiments [ 48] with lower quality factors
(Q∼10
6) showed that metallization of the membrane was
not the limiting factor. Whether this is also true for the case ofQ∼10
8would need to be tested experimentally.
B. Piezoelectric coupling to acoustic resonator
A piezoelectric resonator is an acoustic resonator made
from piezoelectric materials and can therefore be excited byusing external electric fields [ 49]. Quartz resonators have been
optimized for stable frequency operation and are therefore
natural candidates for ion coupling, despite being relativelymassive. A different plausible candidate is GaN-nanobeamsthat have low masses.
To estimate the coupling strength, we start by considering
the geometry shown in Fig. 7. An ion is trapped at a distance h
above a GaN nanobeam. Such an arrangement can be achieved,for example, by bringing a surface ion trap [ 50,51]o ra
stylus ion trap [ 52,53] close to the beam. The main challenge
would seem to be to compensate for electric fields from straycharges on the dielectric beam due to its close proximity.We assume throughout that those are compensated for. Whensuch a beam undergoes small oscillations, the position ofeach point in the beam can be written as /vectorr+/vectoru(/vectorr,t) where
/vectorr=(r
1,r2,r3) is the equilibrium position and /vectoru=(u1,u2,u3)
is the time-dependent displacement from equilibrium. In aflexure acoustic mode, /vectoruis along the ˆr
3direction and its
spatial dependence is restricted to the first component of /vectorrˆr1ˆr3
lq,m
hr1,opt
(r1,t) displacement
FIG. 7. Piezo coupling between an ion of mass mand charge q
to a nanobeam. The ion is held at a height habove a beam of length
lby a Paul trap (not shown). The geometry shown is not to scale
sinceh/greatermuchl(see Sec. VC). Harmonic motion about the trap center
generates an alternating electric field which drives the mechanicalflexure mode of the beam (light blue) via the piezoelectric effect. The
ion position r
1,optmaximizes the coupling and is close to but smaller
than the beam length l, due to edge effects.
(see Fig. 7). Moreover, the dependence on time and spatial
coordinates can be separated, i.e., /vectoru(r1,t)=a(t)/vectors(r1), where
/vectors(r1)=(0,0,s3(r1))is the mode shape (unitless) and a(t) is its
amplitude. The acoustic oscillation can therefore be reducedto a one-dimensional harmonic oscillator a(t) with frequency
ω
0, effective mode mass M, and effective spring constant K
as
M¨a=−Ka, (18a)
M=ρ/integraldisplay
Vd3r|s|2, (18b)
K=E/integraldisplay
Vd3r/vextendsingle/vextendsingle/vextendsingle/vextendsingleds
dr1/vextendsingle/vextendsingle/vextendsingle/vextendsingle2
, (18c)
where ρis the material density, Vis the volume of the beam,
andEis its Young’s modulus.
The harmonic motion of the ion can couple to the beam
acoustic mode via piezoelectricity. A simplified model of thebeam piezoelectric material is that of an ionic lattice. When thebeam is at rest, the electric fields generated by the positive andnegative charges inside it ideally cancel each other. If, howeverthe ions are displaced from equilibrium nonuniformly,
1the
beam will exhibit a bulk polarization Pthat can interact with
the electric field of the ion. Such a polarization therefore,depends linearly on the strain tensor composed of all the partialderivatives of the displacement components ∂
iuj≡∂uj/∂ri
fori,j∈{1,2,3}. Since the strain tensor is symmetric, this
linear relation can be written as /vectorP=eu/primewhere eis the 3 ×6
matrix of piezo coefficients (in units of C /m2) and u/primerep-
resents strain in V oigt notation u/prime=(∂1u1,∂2u2,∂3u3,∂2u3+
∂3u2,∂3u1+∂1u3,∂1u2+∂2u1). This bulk polarization will in
turn be influenced by the ion electric field /vectorEion. The coupling
constant between the ion motion along the ith axis and the
1A uniform displacement of all the ions cannot generate bulk
polarization.
022327-7KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
piezoelectric beam is
gi=/integraltext
Vd3r∂i/vectorEiones/prime
2ω0√Mm ion,i=1,2,3. (19)
Here we used the assumption that /vectoru=a(t)/vectors(r1) and s/primeis
defined in the same manner as u/prime.
The expression in Eq. ( 19) is general and not particular
to any specific beam geometry. While the denominator is thestandard term we encountered for two coupled mechanicaloscillators [see Eq. ( 6)], the numerator is a rather involved
overlap integral. To appreciate its complexity, we write itsintegrand in explicit matrix form as
∂
i(Eion,1,Eion,2,Eion,3)⎛
⎜⎝e1,1···e1,6
...
e3,1···e3,6⎞
⎟⎠⎛
⎜⎜⎜⎜⎜⎝∂
1s1
∂2s2
∂3s3
∂2s3+∂3s2
∂3s1+∂1s3
∂1s2+∂2s1⎞
⎟⎟⎟⎟⎟⎠.
(20)
This integrand can be understood as a dipole-dipole energydensity. To see this, notice that since the field of the ion is
that of a monopole, its spatial derivative ∂
i/vectorEionis equivalent
to a dipole field aligned along the ith axis ˆi. We may therefore
rewrite Eqs. ( 19) and ( 20) in terms of an integral over an
effective dipole-dipole interaction as
gi=1
4π¯h¯/epsilon1/integraldisplay
Vd3r3(/vectorpion·ˆr)(/vectorP·ˆr)−/vectorpion·/vectorP
r3, (21)
where
/vectorpion=q/radicalBigg
¯h
2mionω0ˆi, (22a)
/vectorP=es/prime/radicalBigg
¯h
2Mω 0, (22b)
and we use ¯ /epsilon1=(/epsilon10+/epsilon1dielectric )/2 since the field of the ion
inside the piezoelectric material can be approximated as thatof an ion in vacuum, with the dielectric constant of vacuum/epsilon1
0replaced by ¯ /epsilon1, the average of the vacuum and dielectric
constants [ 54].
Ap r i o r i , the overlap integral in the numerator of Eq. ( 19)
should not be expected to be large. The piezoelectric coefficientmatrix eis a material property, while the mode shape /vectorsis
a result of both geometry and material constraints. Those
impose a polarization density /vectorPwhich need not necessarily
align with /vectorp
ion. We next perform a calculation for two specific
piezoelectric resonators in order to demonstrate this difficulty.We use Eqs. ( 19) and ( 21) interchangeably.
C. Ion coupled to GaN nanobeam
Figure 8shows an image of gallium nitride (GaN)
nanobeams. A single beam, clamped at one end, can resonatein a flexure mode [ 55] with a resonance frequency of ω
0=
(βa2E/ρl4)1/2. Here, ais the cross-section radius, lis the
beam length, Eis its Young’s modulus, ρis its density, and β
100 nm
1μm
FIG. 8. SEM microscopy of GaN nanobeams with hexagonal
cross section. Gallium nitride nanobeam photographs courtesy ofK. Bertness, NIST, Boulder, Colorado 80305, USA.
is a numerical factor (3 .09 for a circular cross section, 2 .57 for
a hexagonal cross section2).
We can estimate an upper limit on the coupling rate based
on Eq. ( 19) and by using the simplified geometry in Fig. 7:
g=q˜eA
4π¯/epsilon1h3ω0√Mm ionf(h/l), (23)
where fis a unitless geometric factor depending on the h/l
aspect ratio, Ais the cross-section area, ˜eis the largest element
of the 3 ×6 GaN piezo-coefficient matrix, and ¯ /epsilon1is the average
of its dielectric constant and that of vacuum. The ion positionalong the beam r
1,optis chosen so as to maximize the coupling.
It turns out that r1,opt∼0.6ldue to edge effects.
Figure 9shows the coupling coefficient as a function
of ion height h. At an experimentally attainable height of
h=50μm, beam length l=15μm, and frequency ω0=
2π×868 kHz, the coupling strength is g=2π×235 Hz.
Even for a beam with a relatively high quality factor of Q=
6×104[56], the product gQ/ 2π=1.4×107Hz whereas the
strong quantum regime requires gQ/ 2π/greatermuch2.6×1011Hz at
4 K and gQ/ 2π/greatermuch3.3×109Hz at 50 mK [Eq. ( 10)].
Based on Eq. ( 23), the coupling to materials other than GaN
can be estimated. Another notable material is lithium niobate
2For a hexagon, the radius is defined to be that of the smallest circle
enclosing it.
25 30 35 40 45 50012
h[μm]g/2π(kHz)
FIG. 9. Ion to GaN nanobeam piezoelectric coupling strength
gvs ion height habove the beam. The beam cross section is
as in Fig. 8. The geometry is as in Fig. 7withl=15μm,
E=3×1011kg m−1s−2,ρ=6.15×104kg/m3,˜e=0.375 Cm−2
(the strongest piezo coefficient of GaN), ¯ /epsilon1=5/epsilon10,w i t h /epsilon10being the
vacuum permittivity. The beam flexure mode frequency is 868 kHz.
022327-8HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
where the strongest of the piezoelectric coefficients is an order
of a magnitude larger than for GaN, with the other parametersreasonably close to those of GaN [ 57]. That, however, would
still have a gQfactor which is below our criteria ( N
osc∼10−4
at 4 K), and even that estimate assumes a high- Qlithium
niobate resonator, which has yet to be demonstrated. Anotherapproach would be to use beams with higher quality factorsthat are close to 10
6; for example, silicon nitride [ 58] doubly
clamped beams or other resonators (see Tables 1 and 2 inRef. [ 59]). However, since these resonators are not made
from piezoelectric material, it would require incorporatingpiezoelectric material into the beam while maintaining thehigh quality factors.
D. Ion coupled to quartz resonator
Recent work with quartz bulk acoustic resonators at both
4 K and at temperatures of tens of millikelvin demonstratedquality factors of up to 7 .8×10
9and might therefore be useful
as part of a hybrid quantum system [ 60–64]. Conveniently, the
resonance frequencies of these devices are compatible withthose of trapped ions, i.e., in the 5 to 15 MHz range.
A BV A resonator (Bo ˆıtier ´a Vieillissement Am ´elior ´e,
enclosure with improved aging) is a quartz resonator designedfor high- Qclock oscillators [ 65]. The resonator described here
is formed from a disk of L=6.5 mm radius and t=1m m
thickness mechanically clamped at its rim (see Fig. 10). The
mechanical motion of the disk is actuated by placing the diskbetween the two plates of a capacitor. The origin of the high- Q
factors becomes apparent when considering the mechanicaldisplacement profiles of one family of its acoustic modes [ 66]:
/vectors(x,y,z )=e
−(x2+z2)/2σ2sin(kny)ˆs. (24)
Here an acoustic standing wave is formed along the unit vector
ˆs=(0.226,0.968,0.111) which is approximately along the
ˆyaxis (see Fig. 11). The mode kvector satisfies knt=
nπ, n =3,5,... and has a radial Gaussian profile, with
σ∼1m m <L . This is very similar to the standing wave
formed in a Fabry–P ´erot optical cavity. The acoustic mode
is therefore well protected from dissipation through contactsat the rim, where the disk is clamped. Other acoustic-modefamilies are not considered here since they exhibit lowerquality factors [ 62]. This is also the reason why we do not
consider the fundamental n=1 mode of Eq. ( 24).
An ion can be coupled to the quartz resonator by trapping
it a distance h=50μm from the surface, as shown in Fig. 11.
Calculating the coupling strength can be accomplished byusing Eq. ( 19) and considering the acoustic-mode shape [see
Eq. ( 24)]. An upper bound, which does not take into account
the relative angle between the derivative of the field of the ionand the polarization of the bulk, yields g∼2π×1k H z .T h i si s
calculated by applying the Cauchy–Schwarz inequality to theintegrand in Eq. ( 20) of the overlap integral in Eq. ( 19). When
combined with the high quality factors involved ( Q∼10
9),
this yields gQ/ 2π∼1012Hz.
This bound, however, cannot be saturated when using the
actual integrand in Eq. ( 20). To see this, recall Eq. ( 21) where
gis expressed as an integral over the dipole-dipole interaction
between the dipole defined by the ion motion, /vectorpion, and the
piezoelectrically induced polarization density /vectorP. Figure 12
t
Lxy(a)
(b)
FIG. 10. High- Qquartz bulk acoustic resonator. (a) Photograph
of a resonator. Device courtesy of Serge Galliou, FEMTO-ST
institute, 25000 Besanc ¸on, France. (b) Schematic cross section.
Quartz resonator of thickness tis shown by the light blue fill. Quartz
holders (dark blue fill) clamp the resonator at its rim. The resonator
is sandwiched between two metallic electrodes forming the actuating
capacitor (yellow fill). Thickness of the electrodes as well as the gapsbetween the quartz resonator and the quartz holders are exaggerated
for clarity. The modes with highest Qfactor can be described
by standing waves, approximately along the yaxis, with resonant
frequencies of f
n≈nvs
2t=n×3.38 MHz where vs=6757 m /si s
the speed of sound and nis the mode number.
illustrates the structure of /vectorP. Naturally its magnitude follows
that of the acoustic mode, having a Gaussian radial profile andforming a standing wave along the ˆyaxis. The polarization
direction of each standing-wave antinode is approximatelyconstant and opposite to that of its neighboring antinodes.Based on this structure, we can refine our upper bound for g
xy
t
Lhq,m ion
FIG. 11. Basic geometry for ion-to-quartz resonator coupling. An
ion of mass mionand charge qis hovering at a distance h=50μm
(exaggerated) above a disk of radius L=6.5 mm and thickness t=
1 mm. The Gaussian radial profile of the acoustic mode is shown
in gray. The ion motion generates an oscillating electric field thatactuates the acoustic modes via piezoelectricity.
022327-9KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
-6 -4 -2 0 2 4 6-0.500.5
z (mm)y (mm)
01|P|
|P|maxion
FIG. 12. Piezoelectrically induced polarization density /vectorPfor third-overtone acoustic mode [Eq. ( 24)w i t h n=3]. Magnitude (relative)
is shown by the color plot. Direction is shown by the unit-vector arrows (darker arrows indicate stronger field strengths). Inset shows modeoverlap between the electric-dipole field due to a fixed dipole /vectorp
ionat the ion position, which is associated with its motion along ˆy, and the quartz
resonator polarization density /vectorP. The ion is assumed to be trapped 50 μm above the resonator surface. The integral over the dipole-dipole
interaction between /vectorpionand/vectorP[Eq. ( 21)] yields a coupling strength g/2π/lessorequalslant1 Hz (see Appendix A).
by using
g/lessorequalslant2|/vectorpion||/vectorPmax|
4π¯h¯/epsilon1/integraldisplay
Vd3r
r3≈3.2|/vectorpion||/vectorPmax|
4π¯h¯/epsilon1, (25)
where we utilized the fact that the interaction energy between
two dipoles obtains a maximum when they are aligned withthe vector /vectorrconnecting them. For the mode configuration in
Fig. 12, we get g/lessorequalslant2π×1.7 Hz. This bound is confirmed
in Appendix A, where we numerically calculate the coupling
strengths for various ion motion axes according to Eq. ( 19)
and get g/2πin the range of 0 .49 to 1 .46 Hz.
To increase the coupling strength, we could reshape the
dipole field associated with the trapped ion to better matchthe acoustic-mode polarization density. A simple and practicalway to do this is to use a capacitor to mediate the electric fieldsbetween the ion and the quartz resonator (see Ref. [ 15], Ap-
pendix C), as in Fig. 13. Here, the ion motion generates image
currents on the trap electrodes that generate a time-varying,but uniform, electric field near the center of the crystal.
The coupling gcan be calculated directly as done in
Eq. ( A3). However, since the BVD equivalent capacitance
C
quartz and inductance Lquartz of the quartz resonator have
been measured for various acoustic modes, we present herea simpler analysis based on the BVD equivalent circuit ofboth the ion and the quartz resonator, shown in Fig. 13(b) .W e
rewrite Eq. ( 9) for this case as
g=ω
0
2/radicalbigCionCquartz
Ctrap+Cshunt, (26)
where we utilized the fact that the trap and shunt capacitances
are much larger than the mechanical equivalent capacitancesC
ionandCquartz . In fact, Cion<0.2 aF [see Eq. ( 13)] and
typical values for Cquartz are in the 1 to 200 aF range [ 67,68].
Therefore, it is imperative that the sum of the trap and shuntcapacitance C
total≡Ctrap+Cshunt are kept to a minimum. On
the other hand, the quartz capacitor must be large enoughto have considerable overlap with the quartz acoustic mode.Because the mode radius is on the order of σ∼1m m , t h ecapacitor plate area should have a comparable radius, leading
toC
shunt∼0.13 pF, given the dielectric constant of these
crystals /epsilon1=4×10−11F/m. The trap capacitance, therefore,
should be comparable or lower than that value. Figure 13(c)
shows an ion-trap design where these low capacitances canbe realized. The crux of the design is that, instead of forminga trap capacitor separate from the quartz resonator capacitorand connecting them with wires, the top capacitor plate of theBV A also serves as the trap bottom dc plate. This arrangementis therefore able to minimize the effect of additional straycapacitances. By using an electrostatic simulation, we estimateC
total=0.18 pF.
The capacitor reshaping of the ion electric field indeed
improves the coupling to 10 to 20 Hz for known parametersofC
quartz . With Nions we get gQ/ 2π∼√
N×1010Hz,
requiring a Wigner crystal of more than 100 ions in orderto satisfy the strong-coupling regime constraint at 4 K.Maintaining such a crystal in the trap might not be trivial due tothe anharmonicities and finite size of the trap. In Appendix A,
we show that the coupling dependence on different deviceparameters and mode overtone number does not allow forsubstantial increases in g. It has been shown that high-overtone
modes, e.g., n=65, can exhibit quality factors of almost
Q∼10
10[62]. That high Qis counteracted by the n−0.5
dependence of gin the mode number (see Appendix A).
Nonetheless, it is worth noting the outstanding properties
of such a device. The mechanical mode, which is resonantlycoupled to the ion motion, can potentially be cooled to nearits ground state by laser cooling the ion. Since laser coolingcan be done much faster than the coupling rate, the quartzcooling rate is close to 2 g/2π. The thermal heating rate is
(1−e
−1)nthermalτ−1
thermal≈(1−e−1)kBT/(¯hQ) (see Sec. III).
The steady-state number of quanta of the quartz acoustic modewould therefore be
¯n≈π(1−e
−1)kBT
¯hgQ. (27)
If operated at 4 K, the 5 to 15 MHz mechanical modes of
the quartz resonator could be cooled to ¯n∼16 quanta by
022327-10HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
Quartz resonatorRF
DC2FL
1m m
RF
DC1
FL9Be+FL
DC 2 DC 1q,m ion
CionLion
CFLLquartz
Cquartz(b)
(c)(a)
FIG. 13. Coupling an ion to a quartz resonator mediated by a
shunt capacitor. (a) The ion is trapped between two endcap electrodes
forming a capacitor between FL and DC 1. Ion motion generates
image currents in the wires connecting the trap endcap DC1 and thequartz shunt capacitor (formed between FL and DC 2), which in turn
generate an oscillating electric field at the quartz resonator, actuating
its acoustic modes through piezoelectricity. (b) BVD equivalentcircuit of the two coupled systems. The capacitance C
FLis the
total capacitance between FL and ground. (c) A Paul trap design
minimizing CFLfor maximal coupling of a9Be+ion to the quartz
resonator. The trap is formed from a circular inner dc electrode (DC
1), surrounded by an outer cylindrical shell rf electrode (RF). Two
disks of 1 mm radius placed at the top (FL) and bottom (DC 2) of
the quartz resonator form the quartz shunt capacitance. Ideally, the
top plate should be kept floating (FL) or connected to ground by alarge ( >G/Omega1) resistor. The trap drive circuity that connects to the RF
electrode and the RF ground connection between DC 1 and DC 2 is
omitted.
laser cooling the coupled ion. Starting at dilution-refrigerator
temperatures ( <50 mK) would result in ¯n∼0.2 quanta. The
mechanical coherence times τcoh=¯hQ/k BTcould reach
∼2 ms in a 4 K environment and up to 150 ms in a 50 mK
environment. Due to its very large mode mass (1 to 10 mg),such a device, if placed in a superposition state of motion, couldbe used to restrict certain decoherence theories of massiveobjects (see Sec. VII).VI. PRACTICAL CONSIDERATIONS FOR COUPLING AN
ELECTRON TO A SUPERCONDUCTING RESONATOR
In Sec. IV, we concluded that, based on its small mass,
the electron is potentially the most favorable candidate fora strongly coupled hybrid system composed of a chargedparticle and a superconducting resonator. Coupling strengthson the order of 0 .1 to 1 MHz can be expected for an electron
trapped 50 to 100 μm away from the trap electrodes, requiring
a very moderate quality factor of Q/greaterorequalslant10
4for the electrical
resonator, at dilution-refrigerator temperatures. To estimateelectron motional decoherence, we take the measured heatingrates for trapped ions and extrapolate them to an electron witha secular oscillation frequency of 1 GHz. We find a heatingrate of ˙n∼100 quanta /s, well below the coupling rate (see
Appendix B).
An electron-based hybrid system might enable a fast and
coherent quantum information processing technology. A plat-form of trapped electrons could be realized where the electronspin serves as the quantum bit (qubit). Unitary single andtwo-qubit gates can be implemented using rf gradients [ 69,70].
In the presence of magnetic gradients, the electron spin couplesto its motion, which in turn is coupled to the underlying LCresonator. Spin initialization and readout could therefore beimplemented with the superconducting resonator acting bothas a reservoir and as an interface for readout circuitry (e.g., seeRef. [ 71]). The proposed architecture may be more scalable
compared with trapped ion QIP since the interconnectingelements are chip based, requiring only rf or microwavecontrol and no optical elements or laser beams. The absenceof optical design constraints could allow for smaller traps,which translates into stronger coupling between electrons andsuperconducting elements, enabling faster two-qubit gates.Moreover, recent advances in QIP with trapped ions havereached gate speeds that are only an order of magnitudeslower than the trap frequency [ 9]. If that scaling holds for
electrons, that would correspond to tens of nanosecond gatetimes, making them on par with superconducting qubit gatetimes (see, for example, Ref. [ 72]). Qubit (i.e., spin) coherence
could extend to seconds [ 73]. Therefore, an electron-based QIP
platform could allow for a coherence time to gate time ratioof/greaterorequalslant10
8, far exceeding any other QIP technology. Moreover,
if the motional heating rates estimated in Appendix Bare
experimentally verified, such fast gates would correspond to aBell-state generation fidelity error of ∼10
−6(see Ref. [ 74]).
The hybrid nature of such a system might offer an
additional way, albeit slower, to entangle electrons, usingthe coupling to the underlying circuitry. This would enrichthe QIP toolbox available for electron spins, for example, byentangling electrons in different traps that are far apart. Here,by using magnetic-field gradients, the spin of the electroncan be entangled with its motion. Since the motion of eachelectron is strongly coupled ( g/2π∼0.1t o1M H z )t oa
corresponding LC resonator, entanglement can be achievedby electrical coupling (either inductive or capacitive) ofthe two LC circuits. Moreover, the inclusion of Josephson-junction–based (JJ-based) devices could play an importantrole within the rf circuitry, allowing for greater flexibilityin addressing and connecting electrons, e.g., by enablingtunable and/or parametric coupling [ 75,76] between electrons.
022327-11KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
In addition, the electron could couple to an on-chip JJ-based
qubit, a nonlinear resource with a high speed of operation.For example, swapping information to a JJ qubit could enablehigh-fidelity state readout (e.g., see Ref. [ 77]).
The idea of using trapped electrons as part of a hybrid
quantum system was first suggested for Penning traps [ 15,29].
To that end, novel planar Penning traps have been developedand demonstrated [ 78,79]. Moreover, electrons were trapped
with cryogenic planar Penning traps [ 80]. Although single
electrons have already been detected in three-dimensional Pen-ning traps by driving their motion [ 16,81], the anharmonicity
of planar traps makes single-electron detection challenging.An optimization of the design of the planar trap electrodes [ 82]
led to the detection of one or two electrons [ 83]. The outlook
for planar Penning traps is discussed elsewhere [ 83–85].
Recently, an ensemble of ∼10
5electrons trapped on super-
fluid Helium with normal-mode frequencies in the tens of giga-hertz range were nonresonantly coupled to a superconductingresonator at ∼5 GHz [ 86]. By measuring dispersive shifts
in the resonator frequency in the presence of the electrons,the authors could deduce a coupling strength of ∼1 MHz per
electron. Further studies of that technology could determine ifthe single-electron regime can be achieved, establishing a newand interesting route for quantum information processing withelectrons, as proposed in Refs. [ 30,87–90].
The potential advantages and prospects of using rf Paul
traps for electron-based quantum information processing weresuggested and analyzed [ 18]. Clearly, since a Paul trap does not
involve the strong magnetic fields required in a Penning trap, itnaturally avoids exceeding the typical critical magnetic fieldsof superconducting circuitry. Strontium ions, for example,have been trapped with a superconducting niobium planar-chiptrap [ 91]. Two-dimensional trapping of electrons with rf fields
was recently demonstrated, resulting in guiding electronsalong a given trajectory [ 92]. To date, however, electrons have
been almost exclusively trapped in three-dimensional Penningtraps, with the exception of Ref. [ 93]. There, a macroscopic
combined Penning and Paul trap was used to simultaneouslytrap tens of ions and electrons.
In Ref. [ 18], a ring Paul trap design for electrons is analyzed,
where a parametric coupling scheme is suggested, based ongeometric nonlinearities of the potential. The coupling rates
and decoherence rates reported here are consistent with those
results. The trap volume used in Ref. [ 18] was relatively small
[5μm×π×(15μm)
2] with a trap depth of 1 meV, placing
the electron 5 μm away from the nearest electrode, rendering
a strong coupling of g=2π×1.1M H z .
Here, we analyze the experimental conditions of two trap
geometries, aimed at achieving the strong-coupling regime, fora larger trapping volume and a deeper trap. As will be apparentin what follows, the design of these traps involves a delicateinterplay between the trap stability and depth, its ability tomaintain superconductivity, the energy range of the electronsource, and the strong-coupling requirement. In broad strokes,it is easier to build a large trap that is stable and deep so thatcurrently available electron sources could be used. Large trapdimensions, however, would prevent satisfying the couplingcriteria in Eq. ( 10). On the other hand, a small trap is optimal
for strong coupling, but it can only support a shallow trappingpotential and therefore requires a low-energy electron source toensure trapping. Because these problems are intertwined, our
presentation includes a discussion of each of these aspects, aswell as their compatibility.
A. Stable trapping of electrons
A Paul trap [ 1] is formed when a time-varying voltage
Vrfcos(/Omega1rft) is applied to an electrode arrangement that gives
a quadratic spatial dependence for the electric potential in theneighborhood of its electric-field null point. For simplicity,we assume cylindrical symmetry and write the time-varyingpotential in terms of the standard ( ρ,z) cylindrical coordinates
as
φ=qV
rfcos(/Omega1rft)/Phi1(ρ,z),
/Phi1(ρ,z)=βρ2−2z2
d2forρ,z/lessmuchd, (28)
where qis the electron charge, βis a unitless geometry
prefactor ( β=1 for an ideal quadrupole), and dis the trap
electrodes’ length scale (e.g., distance from the trap center tothe nearest point of an electrode surface). The time-varyingfield generates a confining potential provided that the Mathieucriterion for stability is satisfied [ 1]:
q
mathieu ≡8βqV rf
md2/Omega12
rf<1. (29)
The confinement can then be described, to lowest order, by a
time-independent pseudopotential:
φpseudo=q2V2
rf
4m/Omega12
rf|∇/Phi1|2, (30)
where mis the electron mass. It follows that the pseudopoten-
tial trap depth can be expressed as D=qVrfqmathieu/ζ, where
ζis a unitless factor dependent only on the trap geometry.
For a perfect quadrupole trap D=qVrfqmathieu/6, whereas, for
example, for a planar “five-wire” surface electrode trap [ 94],
D=qVrfqmathieu/404.
The first constraint we consider is trap stability [Eq. ( 29)].
Since the electron mass is small compared with ions, either
the trap voltage should be lowered or the trap scale dand/or
frequency /Omega1rfshould be increased, as compared with ion
traps, to maintain stability. Lowering the voltage would reducethe trap depth and increasing dwould diminish the coupling
strength. Therefore, it appears to be advantageous to increasethe trap frequency to the gigahertz regime.
The second parameter we consider is trap depth. Naturally,
it is easier to trap electrons in a deeper trap. For that purpose,increasing V
rfis beneficial. Other constraints; namely, the
need to maintain superconductivity in the trap electrodes andcircuitry, limit the maximal rf voltage to a few tens of volts (seeSec. VI B ). Thus far, the shallowest Penning trap that was able
to maintain trapped electrons had a trap depth of D∼1e V ,
the electrons being loaded first into a 5-eV-deep trap whosevoltages were subsequently lowered to form the 1 eV trap [ 83].
We therefore require the trap depth to be at least D∼1e V .
Figure 14shows two different three-dimensional geome-
tries of traps satisfying the above constraints. Table II
022327-12HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
TABLE II. Trap parameters for the designs shown in Fig. 14.T h e
pseudopotential secular frequencies are ωx,ωy,a n dωzwhere x,y
are in the plane of the rf ring and zis perpendicular to it, Dis the trap
depth, Ctrap[see Eq. ( 14)] is the inherent total capacitance between the
dc endcaps and gis the electron-superconducting resonator coupling
rate [see Eq. ( 14) as well as Fig. 17for circuit schematics]. With the
above choices of d, the geometric parameter in Eq. ( 14)i sα∼1
for both traps. Parameters are estimated by using an electrostatic
simulation (this is a reasonable approximation since in both traps the
rf wavelength is >10 cm, i.e., much larger than trap dimensions).
The maximal rf current Irfis estimated based on Irf=/Omega1rfCtrapVrf.
Additional capacitance would result in higher values for the rf current.
Parameter Fig. 14(a) Fig. 14(b)
Vrf 50 V 50 V
Irf 42 mA 243 mA
/Omega1rf/2π 9 GHz 7 .15 GHz
ωx/2π 0.6 GHz 0 .75 GHz
ωy/2π 0.6 GHz 0 .75 GHz
ωz/2π 1.2 GHz 1 .5 GHz
D 1e V 0 .9e V
qmathieu 0.40 .6
Ctrap 15 fF 108 fF
d 100μm 200 μm
g 2π×1.2M H z 2 π×203 kHz
summarizes the resulting trap parameters. Figure 14(a) de-
scribes a three-dimensional configuration of electrodes similarto that of Ref. [ 95]. Here, the trap endcap-to-endcap distance is
set tod=100μm in order to yield reasonable coupling, while
keeping a minimum distance of 50 μm between the ion and the
nearest electrode to avoid large heating rates. The coupling also
DC U
DC Lrf
100µme−DC U
DC Lrf(a)
(b)
FIG. 14. Two Paul trap designs for electron trapping. (a) An rf
ring with 300 μm inner diameter and 500 μm outer diameter forms
a quadrupole field at its center with respect to two dc endcaps. Theflat-ended endcaps have a diameter of 200 μm and are 100 μma p a r t .
(b) A two-dimensional cut through a stacked chip version of (a). The
blue region is a silicon substrate. The electron is trapped at the centerof the middle rf ring electrode. The upper and lower endcap disks
are 200 μm apart. The center ring inner diameter is 240 μma n d
the silicon-free region diameter is 500 μm. Table IIsummarizes the
resulting trap parameters.benefits from having no nearby dielectrics, thereby minimizing
the trap capacitance. The challenge in constructing sucha trap, however, is the tolerance required for holding andaligning the electrodes. One way to solve this is shown inFig. 14(b) where a trap is constructed from stacked chips,
with lithographically patterned metal electrodes, pressed andaligned together [ 96,97]. Because convenient wafer thickness
is/greaterorequalslant100μm,d=200μm and the trap capacitance is increased
(due to the additional dielectrics), lowering the coupling rates.
B. Maintaining superconductivity
An immediate concern with the above designs is that the
relatively high rf currents involved will generate dissipationand magnetic fields that could potentially lead to breakdownof the superconductivity in the trap electrodes. Usually, theelectrodes of Paul traps form part of the capacitance Cof a
parallel rf LC resonator (e.g., in Fig. 17, it would be the total
capacitance between the two leads of L
rf). We can estimate the
on-resonance peak current Imaxfrom the rf voltage amplitude
Vrfby using1
2LI2
max=1
2CV2
rf. We find Imaxin the range of
200 to 400 mA for the conditions described below.
For simplicity, we restrict our analysis to thin film wires on
chip, where an analytic treatment is available. The criticalcurrent I
c, above which a thin film wire is no longer
superconducting, is
Ic=/Lambda1√
wb
0.74Jc, (31)
where bis the film thickness, wis its width, /Lambda1is the London
penetration depth of the superconducting material, and Jcis
its critical current density [ 98].
Of the two commonly used materials for superconducting
circuits; namely, aluminum (Al) and niobium (Nb), aluminumis disadvantageous due to its lower values for J
cand/Lambda1
and, with a critical temperature of Tc=1.2 K, it requires
operation at dilution-refrigerator temperatures. For example,a 100 nm ×10μm aluminum wire has a critical current of
I
c=11.3 mA. A niobium wire with the same dimensions
would have a critical current of Ic=221 mA and would be
fairly strongly superconducting even at 4 K ( Tc=9.2K ) .
To maintain superconductivity in the chip-based design in
Fig. 14(b) with niobium films, we require thicknesses and
widths that satisfy bw > 16μm2. Here, the features of the
narrowest electrode or wire would serve as the bottleneckdetermining the critical current for the entire circuit. Forexample, a 50 μm×500 nm film cross section would be
convenient to fabricate and could provide I
c=1.105 A.
These numbers are compatible with those measured in asuperconducting niobium trap for strontium ions [ 91].
Equation ( 31) actually constrains the dc critical current
through a wire; however, the rf critical current for a su-perconducting resonator has similar values [ 99], at least for
the case of a half-wavelength stripline resonator. Whether asimilar result holds for a lumped element resonator, wherethe current distribution is significantly different, has yet to bedemonstrated.
022327-13KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
C. Low-energy electron source
In principle, one method to load electrons into the trap
would be to target the trapping volume with slow electronsand capture them by turning the trap on when they reachthe trap center. In this case, the challenge lies in the fastelectronics required. A slow electron source could be, forexample, an ultracold GaAs photocathode [ 100,101], which
has demonstrated beams with less than 1 eV average energyand less than 50 meV energy spread [ 102]. Such slow 0 .1
to 1 eV electrons traversing a trap with a typical length of100 to 200 μm requires turning the trap on faster than 0 .1t o
1 ns. In Sec. VI D , however, we show that the trap resonator
quality factor should exceed 10
4in order to comply with
the typical cooling power of a cryogenic refrigerator. Thiswould realistically limit the switching time of such a trapto the microsecond regime. We could mitigate this problemby constructing even slower electron sources. For example,using electron tunneling from bound states on the surfaceof liquid helium [ 103] could potentially generate <1m e V
electrons, thereby relaxing the trap-switching-time constraint.The analysis of such a source is beyond the scope of thispaper.
A second type of electron source, which is commonly used
in Penning traps, is based on secondary electrons [ 104,105].
For example, in Ref. [ 83], a sharp tungsten tip was used to field
emit high-energy ( /greaterorequalslant200 eV) electrons that collided with the
trap surfaces, liberating gas molecules. During this process,some of these molecules reach the trapping region wherethey have a probability of being ionized by the incoming fastelectrons. The relatively slow “secondary” electrons generatedin the ionization process can then be trapped.
This approach seems to be effective with deep ( /greaterorequalslant5e V )
and large ( d=0.1 to 2 cm) traps [ 83]. Trap depth U
depth
is defined as the maximum minus the minimum of the trap
pseudopotential within the trap volume. It is not obviousthat this technique would be efficient enough for a U
depth=
1 eV trap with a typical length scale of 100 μm. As an
alternative, photo-ionization of a cold atomic gas could bemore compatible with a shallow trap (e.g., see Ref. [ 106]),
albeit at the expense of requiring optical access to the cryogenicchamber of the electron trap. One would also have to considerwhether the cold atoms would immediately stick to the trapsurfaces thereby creating a possible charging effect that wouldchange the trapping potential. Here, we consider a refinementof the secondary electron technique that might be less violent tothe trap electrodes, as well as increase the trapping probability,while not requiring optical access.
Rather than directing the incoming beam of electrons at
the trap electrodes, we consider focusing the beam into thecenter of the trapping region and away from any surfaces. As asource of secondary electron emitters, a cold charcoal adsorbercontaining helium might be used. Primarily used for pumpingresidual helium gas, a charcoal adsorber can be heated witha resistor in order to liberate some helium and increase itsvapor pressure in the chamber [ 107]. Incoming electrons will
ionize the helium gas and generate secondary electrons thatcould then be trapped. In Sec. VI D we show that, in order
to accommodate for the heat load generated by the trap, itshould be operated at temperatures in the range of 1 to 4 Kand not dilution-refrigerator temperatures. That would also
leave enough cooling power to remove the heat generated bythe charcoal heating resistor. We henceforth assume that therefrigerator is operated at 4 K.
The total cross section for helium ionization is maximal
when the incoming electrons have a kinetic energy of E
p∼
120 eV [ 108]. Here, however, we are interested in maximizing
the cross section for generating low-energy secondary elec-trons rather than the total ionization cross section. In fact,since the threshold ionization for helium is ∼24.58 eV, it
is not surprising that the low-energy cross-section peaks atE
p∼30 eV [ 109,110]. The incoming electron energy should
therefore be set to around 30 eV, resulting in an optimal cross
section of σion∼0.05˚A2for secondary electrons with energy
below 1 eV [ 109]. The resulting ionizing rate of helium atoms
within the trapping volume is
/Gamma1ion/similarequalJπr2
0
qenHelσion, (32)
where Jis the incoming current density of electrons, qeis
the electron charge, r0is the incoming electron beam radius,
lis the radius of the spherical trapping volume, and nHeis
the vapor density of helium atoms. We restrict the discussionto secondary electron generation due to the interaction ofhelium with the primary incoming electron beam. Additionalionization events due to, for example, elastically scatteredelectrons, could only increase /Gamma1
ion. In the presence of the
rf trap, the incoming electron energy Epwill be spread by
less than ±15 eV around 30 eV, as shown in Appendix C.
This, in turn, could reduce the average value of σionby
<18% to σion>0.041 ˚A2(see Ref. [ 109]). Equation ( 32) can
therefore be considered as an average estimate for /Gamma1ion.I n
addition, trap rf voltage can deflect the incoming electrons,
causing the average beam radius to expand to r1=ξr0. Since
the rf trap voltages Vrfconsidered in this paper have the
same order of magnitude as Ep/qe(see Table II),ξ/lessorequalslant4a s
shown in Appendix C. We can still use r0in Eq. ( 32) since
it depends on the total current of electrons traversing thetrapping region. As long as r
1<l, electrons are not lost due to
collisions with the trap walls and this total current should bepreserved.
The steady-state number of trapped electrons is determined
by the ratio between the low-energy secondary electrongeneration rate /Gamma1
ionand the total electron loss rate. Electrons
that have already been trapped may collide with incomingelectrons or with the surrounding helium atoms. The averageenergy of the electrons gradually increases due to thesecollisions (heating) until eventually it exceeds the trap depthand they are lost (boiling).
In Appendix C, we derive analytically an upper bound
on the contribution to the heating rate due to collisionswith incoming electrons. Briefly, since each collision is aRutherford-type scattering problem, it cannot be attributed afinite cross section. Its geometric scale is therefore dictated bythe incoming electron beam finite radius rwhere r
0/lessorequalslantr/lessorequalslantr1.
Therefore, the average energy a single trapped electron gainsin a single collision is <q
2
e/(4π/epsilon10r0). Since the rate of
collisions is Jπr2
0/qethe resulting heating rate is ( dE/dt )|e<
022327-14HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
Jr0qe/(4/epsilon10). This translates to an electron loss rate of
/Gamma1e=1
Udepth/parenleftbiggdE
dt/parenrightbigg/vextendsingle/vextendsingle/vextendsingle/vextendsingle
e<Jr0qe
4/epsilon10Udepth. (33)
The contribution to the heating rate due to collisions with
the helium gas is known as “rf-heating.” This follows fromthe helium atom playing the role of a hard immovable ballin the collision process, being much heavier than the electron.Therefore, when an electron collides with it, its instantaneousmicromotion kinetic energy before the collision transformsinto the secular motion energy after the collision [ 111,112].
During the harmonic secular motion of the ion, kinetic energyis exchanged between rf and secular motion, the rf fractionbeing maximal farthest from the trap center and ideally zeroat the center. Therefore, collisions that occur farther from thecenter will potentially transfer more energy into the secularmotion. If the secular energy of the trapped electron priorto collision is E
in, the energy gain after a single collision
is/lessorequalslantEin/2, when averaging over the secular motion period.
Assuming that the trapped electrons have a uniform energydistribution between 0 and U
depth, the average energy gain per
collision with a single helium atom is less than Udepth/4. The
rate of collisions in this case is ∼σelasticnHe/angbracketleft|v|/angbracketrightwhere σelastic∼
6˚A2is the electron-helium elastic cross section for low-energy
(/lessorequalslant2 eV) electrons [ 113] and /angbracketleft|v|/angbracketright ∼4√
2
3π/radicalbigUdepth/meis the
average velocity of the trapped electrons, with mebeing the
electron mass. The resulting heating rate is ( dE/dt )|He<
σelasticnHe/angbracketleft|v|/angbracketrightUdepth/4. We translate it to an electron loss rate
of
/Gamma1He<1
Udepth/parenleftbiggdE
dt/parenrightbigg/vextendsingle/vextendsingle/vextendsingle/vextendsingle
He=σelasticnHe
3π/radicalBigg
2Udepth
me. (34)
Combining Eqs. ( 32)–(34), the steady-state number of
electrons in the trap, Ne, is dictated by setting dNe/dt=0
in the rate equation
dNe
dt=/Gamma1ion−Ne(/Gamma1e+/Gamma1He). (35)
For trapping, we require the steady-state number of elec-
tronsNebe greater than a threshold value Nthreshold ,a sw e
discuss below. This can always be satisfied if the current
density Jand the density of helium, nHe, are large enough
[Eq. ( 35)]. To see this quantitatively, in Fig. 15(a) ,w ep l o tt h e
number of steady-state electrons for different current densitiesand helium-pressure values.
The value for N
threshold depends on the dynamics of the
electron loading process; specifically, on the cooling rate ofthe electron motion /Gamma1
coolduring loading. Without cooling,
once the incoming electron source is turned off ( J→0), any
trapped electrons would rapidly boil out of the trap due tocollisions with the helium background gas. Indeed, the heliumpressure can be decreased significantly to avoid this process byallowing the charcoal adsorber to cool to its 4 K surroundings.However, the timescale for removing the helium is likely to belong compared with 1 //Gamma1
He. The latter is inversely proportional
to the helium pressure and, for example, equals 1 .3μsa t
a helium pressure of 10−2Pa. Collisions with other atoms
are neglected in our discussion because we expect the trap10−410−310−210−1100100101102
Pressure (Pa)J(A/m2)
10−310−210−1100Ne
10−410−310−210−1100100101102
Pressure (Pa)J (A/m2)
10−210−1100101τsteady (μs)(a)
(b)
FIG. 15. Effect of loading parameters. (a) Estimated steady-state
number electrons, Ne, in a 1-eV-deep trap having a trapping volume
of∼(95μm)3when the electron gun is on. Incoming electron beam
radius is assumed to be r0=10μm. (b) 1 /etime to reach steady-state
number of electrons.
chamber to be in an ultrahigh vacuum cryogenic environment
with pressures of 10−10Pa or less.
In the design we consider below, we assume the zmotion
of the trapped electrons is strongly coupled to an LC resonatorto experience damping. In Sec. VI E , we show that a ∼1 GHz
LC resonator with a quality factor Q
det∼1000 should suffice
for single-electron detection. Therefore, the LC resonatorequilibrates with its 4 K surroundings at a ∼1 MHz rate, i.e.,
much faster than the coupling rate gbetween the LC resonator
and the electron motion. The resulting z-motion damping
rate is dictated by the slower of the rates, /Gamma1
cooling∼g/2π/greaterorequalslant
100 kHz. To cool the xandymotion, these modes could be
parametrically coupled to the zmotion [ 114] as discussed in
Sec. VI F . We will henceforth assume a similar damping rate
for all axes.
Once the incoming electron beam is turned off, the trapped-
electron energy Eis dictated by the cooling rate and the helium
collision-induced heating rate:
dE
dt=−/Gamma1coolE+1
π(σelasticnHe)/radicalBigg
2E
meE. (36)
022327-15KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
For this equation to be correct, the initial energy of the electron
must be below a value Einitdetermined by trap anharmonicity,
which manifests as an amplitude dependence of the resonantfrequency. Since damping is based on resonant coupling to theLC resonator, large-amplitude motion will not cool effectively.Based on Sec. VI E , we can estimate E
init/lessorsimilar0.3 meV. This
threshold can be increased in a few ways. One techniquecould be to detune the trap in order to match the resonantfrequency of higher-energy electrons, then adiabatically followtheir frequency as they cool down. Another way is to designa trap with lower anharmonicity (see references in Sec. VI E ).
A third way could be to design an LC resonator with a tunablequality factor by using a tunable coupler [ 75,115] where the
Qfactor is first lowered for cooling purposes and increased
once the electrons are cold. For the sake of the discussionhere, we will adopt the more conservative estimate for E
initof
/lessorequalslant0.3m e V .
To achieve net cooling, the right-hand side of Eq. ( 36)
should be negative, i.e.,
E/lessorequalslantEcapture≡me
2/parenleftbiggπ/Gamma1 cool
σelasticnHe/parenrightbigg2
. (37)
Therefore, if the electron zmotion satisfies E<E thresh≡
min(Ecapture,Einit), it will remain trapped. For helium pressures
below 0 .027 Pa, Einitis the smaller of the two and determines
Ethresh=0.3 meV. For a pressure Pgreater than that, Ethresh=
Ecapture=0.3m e V ×(0.027 Pa /P).
Equation ( 36) was based on the assumption that excess
micromotion can be neglected. Excess micromotion occurswhen the ion experiences rf fields even at its equilibriumposition that is usually shifted from the rf null due to strayfields. This would lead to a constant heating term in Eq. ( 36),
thereby limiting both E
capture as well as the steady-state
energy. By using dc compensation fields, the electron positioncan be adjusted back to the rf null. We require the heatingrate due to excess micromotion to be much lower than theheating rate for electrons with E
capture energy. If the electron
is at a position xaway from the rf null, this constraint
can be written as mev2
mm(x)/lessmuchEcapture where vmm(x)i st h e
micromotion velocity amplitude at x. For a 1 GHz trap and
Ecapture=0.3 meV this constrains x/lessmuch1μm.
From Figs. 15(a) and15(b) we can extract the time needed
to trap a single electron. Within the parameters explored, thesteady-state number of trapped electrons, N
e, is less than
one and the threshold energy is Ethresh∼0.3 meV or smaller.
Therefore, the loading process should be operated in pulsedmode, with ∼(U
depth/Ethresh )/Nepulses required on average
to trap a single electron (provided that the electron energydistribution is uniform between zero and U
depth). Combined
with the 1 /etime required to reach the steady state [Fig. 15(b) ],
we extract the average total time required for trapping asingle electron, shown in Fig. 16(a) . As long as E
thresh is
not dominated by the helium pressure P, i.e., by Ecapture ,
increasing Pis beneficial since Neincreases. An optimal
helium pressure of ∼0.027 Pa is reached, beyond which
Ethresh=Ecapture∝1/P2.
These estimates assume that, once a single electron is
trapped, it is immediately detected. Realistically, some sortof detection procedure needs to be applied in order to verify10−410−310−210−1100100101102
Pressure (Pa)J(A/m2)
10−310−210−1100101102Ttot(s)
10−410−310−210−1100100101102
Pressure (Pa)J(A/m2)
100101102103104Ttot(s)(a)
(b)
FIG. 16. Estimated average total time Ttotfor trapping and
detecting a single electron, based on the same parameters used for
Fig. 15. The incoming electron beam gun is operated in pulse mode,
the duration of each pulse [Fig. 15(b) ] allows a steady-state number
of electrons [Fig. 15(a) ]. This translates into a probability of trapping
a single electron after a single pulse. The process must be repeated a
number of times, which is inversely proportional to that probability.After the electron loading pulse, a detection procedure needs to be
applied for T
det. (a) Assuming Tdet=0, i.e., negligible. (b) Assuming
Tdet=10μs based on the conservative detection-time estimates from
Sec. VI E .
that indeed an electron is present. In Sec. VI E , we analyze
the detection scheme of Ref. [ 31]. We estimate that the time
to detect a single electron Tdetis in the 1 to 10 μs range.
In Fig. 16(b) , we plot the total time required to trap and
detect a single electron for the more conservative estimateofT
det=10μs. Based on the plot, working in the helium
pressure range of 10−4to 10−1Pa and a current-density range
of 1 to 100 A/m2, the range of times we get is similar to that
of Paul trap loading times for ions.
The current-density range in Figs. 15and 16is chosen
such that the total current of incoming electrons is in thenano-ampere regime for a beam radius of r
0=10μm. The
beam radius was chosen so that, even after expansion to r1
due to the trap rf fields, it would avoid the trap walls. These
parameters can be easily obtained with commercial electronsources. Smaller beam radii with the same total current wouldreduce the total time required to trap an electron even further.
022327-16HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
That would require a design of electron optics combined with
either a commercial or homemade cold field emission source,the details of which are beyond the scope of this paper.
D. Electrical circuitry
Stable trapping requires applying large voltages and cur-
rents in a cryogenic environment, next to a sensitive detectionresonator. This has implications on the heat load experiencedby the refrigerator and the circuit design of the trap.
Achieving a trap drive amplitude of V
rf=100 V at fre-
quencies in the 7 to 9 GHz range requires resonating the trapcapacitance C
rfwith an inductor. The resulting dissipation
rate would be Pdis=/Omega1rfCrfV2
rf/Q, where Qis the rf resonator
quality factor. With Crf/lessorequalslant150 fF (based on simulations of
the traps in Fig. 14) andQin the 104to 105range, implies
/lessorequalslant0.2 to 2 mW of dissipated power for frequencies in the 7 to
9 GHz range. With the cooling power of a dilution refrigeratortypically being in the 100 to 400 μW range at T=100 mK,
too low to survive such heat loads, it seems that working at4 K would be required, where 2 mW of power dissipation iseasily absorbed, even with a lower ( Q∼10
4) quality factor.
In fact, even 1–2 K cryostats with ∼60 to 200 mW of cooling
power would suffice.
To understand the implications of the trap drive on the
electron detection circuit, we model the traps in Figs. 14(a)
and 14(b) with the lumped-element circuit shown in Fig. 17.
Detecting the presence of electrons would be accomplished byusing a tank circuit technique [ 31,81]. The electron thermal
motion generates image currents that couple to the resonatorformed from the trap capacitance and the inductor L
det, chosen
to be resonant with the ∼1 GHz secular motion. The trap is
driven by a different resonator, formed from the ring-to-end-caps capacitance and another inductor, L
rf, chosen to resonate
at the 7 to 9 GHz drive frequency.
The possible cross talk between the drive and detection
resonators could deteriorate their respective quality factors.If the trap is electrically symmetric, i.e., C
rf,1=Crf,2and
Ciso,1=Ciso,2, the two circuits are essentially orthogonal.
The detection circuit is connected to equipotential points inthe trap drive circuit and is therefore not influenced by thehigh currents flowing there. Moreover, due to the Wheatstonebridge topology, the detection circuit is not sensitive to the rfinductor L
rfand its coupling port. It is only influenced by the
additional capacitances Ciso,jforj=1,2 that add to the total
trap capacitance. Similarly, the rf resonator is indifferent tothe added impedance of the detection resonator. The impact oftrap asymmetry on the quality factor of the two resonators canbe estimated by
/Delta1Q
rf
Qrf∼Qrfω0
Qdet/Omega1rfCcap
Ciso,1+Crf,1+2Ccap/epsilon1, (38a)
/Delta1Q det
Qdet∼Qdetω0
Qrf/Omega1rfCiso,1+Crf,1
Ciso,1+Crf,1+2Ccap/epsilon1, (38b)
/epsilon1=|Crf,1−Crf,2|+|Ciso,1−Ciso,2|
Crf,1+Ciso,1, (38c)
where QrfandQdetare the rf and detection resonator quality
factors, respectively, when the trap is completely symmetric,/Delta1Q
rfand/Delta1Q detis their respective change due to asymmetry,ω0∼2π×1 GHz is the secular frequency, /Omega1rf/(2π)∼7t o
9 GHz is the trap drive frequency and /epsilon1is the asymmetry
parameter. Clearly, if QrfandQdetare comparable, and the
capacitances involved are of the same order of magnitude,then keeping /epsilon1below a few percent should suffice.
E. Nonlinearity and detection of a single electron
One of the main concerns with detecting a single electron in
Penning trap experiments is the trap anharmonicity [ 80,82,84].
In these traps, the signal of a single electron has a few-hertzlinewidth due to damping resulting from its coupling to thedetection circuit, whereas the effect of anharmonicity in theseplanar traps is to broaden the electron detection signal to10 kHz to 1 MHz. However, in Ref. [ 82], it was shown that, by
adding compensation electrodes and carefully adjusting their
relative voltages, we could avoid the dominant anharmonicterms of the potential. Similarly, careful consideration forelectrode shape and geometry allow for higher degree ofharmonicity in three-dimensional traps [ 116,117].
In the designs considered here, the electron is strongly
coupled to the detection circuit, giving a relatively broadsignal linewidth, which in turn relaxes the constraints onthe trap harmonicity. By assuming a moderate quality factorfor the detection circuit Q
det∼1000, the detection-circuit
linewidth is on the order of ∼1 MHz and therefore larger than
anharmonicity-induced broadening of the electron signal, aswe show below. To reach the strong quantum regime, however,we require Q
det/greatermuch7000 (see Table I). However, with a tunable
coupler [ 75,115], we could potentially tune the quality factor
of the detection circuit to accommodate for both Q-factor
regimes. Detailed analysis of such a coupler is beyond thescope of this paper. Therefore, in this section and in Sec. VI F ,
we use the lower Q
det∼1000 value.
Figure 17shows the schematics of a typical tank detection
circuit and Fig. 18shows a simplified equivalent circuit.
The simplification follows first from replacing the trappedelectron with its BVD equivalent network L
e,Ceand a
current source Iecorresponding to the induced currents due
to electron motion. Further simplification is achieved byreplacing the entire network connected to the two ends of thedetection inductor L
detwith its total equivalent capacitance
Ctotal. This will define the tank circuit resonant frequency
ω0=1/√LdetCtotal, which we assume to be resonant with
the electron trap frequency. Finally, the amplification networkthat couples to L
detvia mutual inductance to the coupling
inductor Lcplis replaced by an equivalent resistor Rdet.T h e
coupling inductor Lcpltransduces the input impedance of the
amplifier, the real part of which presents an effective resistanceR
extin parallel with the internal resistance Rintof the LC tank
circuit. The total resistance of the detection circuit is thereforeR
det=RextRint/(Rext+Rint). The width of the electron signal
can be estimated to be Rdet/Le∼2π×100 kHz, expressed in
terms of the trap parameters
Rdet
Le=Qdetq2
eα2
ω0Ctotalmed2, (39)
where d∼200μm is the endcap-to-endcap distance, ω0=
2π×1 GHz is the trap secular motion frequency, and Ctotal∼
180 fF for the trap in Fig. 14(b) . The capacitance Ctotalis
022327-17KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
CcapRVcap,1
DCU
R
Vcap,2DCLCiso,3
Ldet
Ciso,4e−
Crf,2Crf,1
Ciso,2Ciso,1
Lrfrf
VrfLcplAMP
FIG. 17. Schematic of trap and detection resonators for the traps illustrated in Fig. 14. The electrodes DC U,D C L, and rf of Fig. 14are
indicated here in the schematic. The trap capacitances are shown in blue where Crf,1andCrf,2are the capacitances between the center ring and
each endcap and Ccapis the endcap-to-endcap capacitance. For the trap in Fig. 14(a) , these equal 21.3, 21.3, and 4.6 fF, respectively. For the
trap in Fig. 14(b) , these equal 146, 146, and 35 fF, respectively. The Lrfinductor forms a resonator with the total capacitance between its ends
generating the quadrupole trapping field. The Ldetinductor along with the capacitance shown forms the detection resonator that monitors the
electron motion (double red arrow). The four isolation capacitors enable independent dc biasing of the upper and lower endcaps ( Vcap,j,j=1,2)
with bias resistors R/greaterorequalslant10 M/Omega1to avoid loading the detection circuit, assumed to have a quality factor of ∼1000 [see Sec. VI E ]. The leftmost
isolation capacitors Ciso,1andCiso,2are chosen to equal Crf,1=Crf,2. The rightmost isolation capacitors Ciso,3andCiso,4are chosen to be much
greater than the total capacitance between DC Land DC U, e.g., on the order of 1 pF. The mutual inductance of LdetandLcplallows for electron
detection using an amplifier.
calculated by expressing it in terms of the other capacitances
in Fig. 17as
Ctotal=Ccap+Crf,1Crf,2
Crf,1+Crf,2+Ciso,1Ciso,2
Ciso,1+Ciso,2, (40)
assuming that Ciso,k(k=3,4) are much larger than Ctrap.
While Crf,k,k=1,2 and Ccapare dictated by the trap
electrodes, Ciso,k,k=1,2 can be chosen independently. There
is an inherent tradeoff in this choice, however. On the one hand,
IeCeLe
Ctotal Ldet Rdet
FIG. 18. Simplified electron-detection circuit, based on the cir-
cuit in Fig. 17. Here, Ctotalis the total capacitance between the two
ends of the detection inductor Ldet. The trapped electron is replaced
by its electrical equivalent of a series LC resonator with inductance
Leand capacitance Ce. Currents generated by electron motion are
represented by Ie. The coupling inductor Lcplin Fig. 17transduces
the input impedance of the amplifier to an effective resistance,
which, combined with LC internal dissipation, are represented byan equivalent shunt resistor R
det.these should be much larger than Crf,kin order to maximize the
trap drive voltage. On the other hand, these should be as smallas possible so as to minimize C
trapand increase the coupling
rateg. For simplicity, here we choose Ciso,1=Ciso,2=Crf,1=
Crf,2but other choices could be explored. For the trap in
Fig. 17(a) ,Ctotal∼26 fF, so Rdet/Lion∼2π×0.7 MHz. See
the caption of Fig. 17for the capacitance values for both traps.
The relatively large difference between the signal bandwidthscalculated above and the typical signal bandwidth in a Penningtrap experiment follows from the small dimensions and smallcapacitance of the designs considered here.
The width of the electron signal should be compared with
the frequency spread resulting from the trap anharmonicity.By using first-order perturbation theory, we can estimate theeffects of the r
4,r2z2,z4terms in the trap potential (see, for
example, Ref. [ 80]) resulting in /lessorequalslant0.5 MHz dispersion in the
signal for both traps in Fig. 14, assuming the electron thermal
motion equilibrates to a 4 K bath. This should contribute verylittle to the broadening of a single-electron signal, therebysimplifying its detection without the need for a more elaborateelectrode design. Notice also that the /lessorequalslant0.5 MHz dispersion
falls within the bandwidth of the detection circuit describedabove, rendering the cooling induced by coupling to thedetection circuit to be effective for electrons with temperatures/lessorequalslant4 K (energies /lessorequalslant0.34 meV). Even in the presence of nonlin-
earities, a single electron could be detected by parametricallydriving its motion and coherently detecting the resulting imagecurrents in the detection circuit [ 16].
The bandwidths calculated above fall in between 0 .1 and
1 MHz, and therefore correspond to a single-electron detection
022327-18HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
time of 1 to 10 μs. By integrating the thermal power spectral
density at Rdetover a bandwidth of B≡Rdet/(2πLe) centered
atω0, the total detected power will vary from Pdet∼4kbTB
when no electron is trapped to Pdet∼0 when an electron is
trapped [ 31]. This is a result of the fact that, on resonance, the
electron equivalent circuit is effectively a short which shuntsR
det, as seen in Fig. 18. To avoid a large noise background,
an amplifier with an effective noise temperature that is /lessorequalslantT
is required. As an example, for the T=4 K experiments
explored here, using an amplifier with a noise temperatureof 2 K at ω
0/2π∼1 GHz such as in Ref. [ 118] could suffice,
giving an estimated signal-to-noise ratio of unity or larger indetermining the variation in P
detbefore and after trapping.
F. Parametric cooling
The low-energy electron source described in Sec. VI C
relies on the ability to cool the motion in all three spatialaxes. As described there, adequate z-motion cooling can be
achieved when the detection circuit is resonant with the z
motion. By parametrically coupling the radial xandymotion
to the zmotion, cooling on all axes can be achieved [ 114].
Such a scheme has the benefit of not needing an extra radialelectrode for damping or additional resonant circuitry on theexisting ring electrode.
The coupling scheme in Ref. [ 114] was based on xyandxz
terms in the pseudopotential, which were proportional to a volt-ageU. Time modulating U(t)=U
0cos(/Delta1ωt ) at the difference
frequency /Delta1ω=ωi−ωjcauses energy exchange between
the motion along the iandjaxes. The traps considered in
Fig. 14, however, are axially symmetric and therefore should
have negligibly small cross terms of that type. We could alsoconsider this approach by modifying the electrodes to be ableto induce couplings of this form. Alternatively, a variationon this coupling scheme could be used that incorporates thesymmetry of the simpler electrode structures. To see this, weapproximate the trap pseudopotential around its minimum as
φ
pseudo=1
2me/parenleftbig
ω2
xx2+ω2
yy2+ω2
zz2/parenrightbig
+βx2z2+γy2z2,
(41)
where the x2y2anharmonic term is also negligible for the
axially symmetric traps considered and β≈γ. In terms of the
harmonic ladder operators, the x2z2cross term, for example,
contains the following summands:
¯hξ(a2b†2+b2a†2), (42)
where a, a†are the z-motion operators and b, b†are the x-
motion counterparts. Coherently driving the zmotion at ωd=
2ωx−ωzcan be described mathematically by replacing a/mapsto→
αe−iωdt+a. Rewriting Eq. ( 42) and neglecting fast rotating
terms introduces terms of the form
2¯hξα(ab†2+b2a†). (43)
As an example, consider the trap design in Fig. 14(a) .
There, in order to achieve x-zcoupling, ωdshould be ∼2π×
90 MHz. By expressing βin terms of the pseudopotential
parameters,
β=ζ2q2
eV2
rf
me/Omega12rfd6, (44)where ζ=0.166 is a geometric prefactor, we can express the
x-zcoupling frequency as
2ξα=ζ√
2¯hq3
eV2
rfVd
m3.5e/Omega12
rfωxω2.5zd7, (45)
where Vdis the drive voltage applied to the trap endcaps. For
the trap in Fig. 14(a) , we get a rate of 2 π×0.92 MHz /V×Vd.
Therefore, a Vd∼109 mV drive, corresponding to ∼3.36μm
of motion amplitude, would render an x-zcoupling rate of
2π×100 kHz. This would enable cooling of the xmotion
on the order of that rate. With a Qfactor of 1000 for
the detection circuit, a 109 mV drive at ωd∼2π×90 MHz
would dissipate less than 10 nW of power, well within thecryogenic capabilities of the refrigerator.
G. Planar arrangements
Planar chip traps have some advantages over the three-
dimensional traps analyzed above. They can be easier to fabri-cate, require no alignment, and are more suited for scalability.Such traps, however, have a much shallower trapping potentialfor the same applied voltages and frequencies, as comparedwith three-dimensional traps. This can be mitigated by addinga cover electrode a few millimeters away from the trap chip,and applying a negative voltage [ 82,119,120].
0 50 100 150 200 250 300 350100150200250300350400
r(μm)z(μm)
012eV(a)
(b)r DC
RF
GNDz
e
FIG. 19. Planar point Paul trap for electrons. (a) Inner DC disk
radius is 100 μm. Outer RF ring radius is 250 μm. The electron is
trapped at a height of ∼100μm above the surface. (b) Pseudopotential
trap depth of the trap in panel (a), with 100 V trap drive at 7 .1 GHz
and a capping electrode, here represented by adding a uniform field
of 58.5 V/cm along −z. The trap minimum is at r=0,z∼100μm.
Resulting secular frequency along zisωz=2π×1.46 GHz.
022327-19KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
Figure 19shows an example of a planar electrode Paul
trap [ 119,121], here chosen to be cylindrically symmetric
for simplicity. With the addition of a cover electrode gen-erating a uniform field of 58 .5V/cm, the trap depth is
D=0.02qV
rfqmathieu . When applying a trap drive voltage
ofVrf=100 V to the RF annulus electrode (DC and GND
electrodes are rf grounded) and assuming a Mathieu parameterofq
mathieu ∼0.5, we expect a 1 eV trap depth, as in the
three-dimensional designs shown earlier. The relevant trapcapacitance that dictates the value of the coupling rate g
is formed between the central dc electrode and ground.Due to the trap geometric aspect ratio, the coupling ratedecreases to g=2π×180 kHz. As a side effect of using a
cover electrode, the electron equilibrium position should shifttowards the trap chip by 7 .7μm. This would result in ∼2μm
micromotion amplitude (corresponding to a pseudopotentialenergy of ∼15 meV) that should be compatible with a stable
trap operation. This, however, would compromise electronloading into the trap due to the additional rf heating resultingfrom excess micromotion (see Sec. VI C ). One remedy could
be to compensate for micromotion by applying dc voltages onthe center DC electrode. In the example considered here, 1 .5V
of dc bias would restore the ion position to the rf-null point,while still rendering a 1.6-eV-deep trap.
Although planar traps seem promising, separating the
detection circuit from the drive circuit would be more difficultdue to the lack of symmetry assumed in Sec. VI D . Also, since
planar traps tend to be more anharmonic compared with three-dimensional ones, additional compensation electrodes may berequired in order to enable single-electron detection [ 82].
VII. CONCLUDING REMARKS
We first consider coupling the motion of a confined
charged particle to a superconducting resonator. Limited bythe currently achieved quality factors of such resonators(Q/lessorequalslant10
6), we conclude that, for the systems considered,
it will be very difficult to reach the strong-coupling regimeby using a single trapped charged particle, with perhaps theexception of
9Be+at dilution-refrigerator temperatures or
trapped electrons.
We explored coupling a trapped ion to a nanomechanical
resonator, either through electrostatics or piezoelectricity.
Based on recent advances in the fabrication of membranes(Q/greaterorequalslant10
8), we considered their electrostatic coupling to a
trapped ion. By coating such a membrane with a thin metallicfilm and applying a voltage bias to it, the coupling could beon the order of 10 Hz for a 1 V bias, within reach of thestrong-quantum regime at T=50 mK.
We analyzed the possibility of direct piezoelectric coupling
of ion motion to a mechanical resonator. An interestingcandidate was a quartz acoustic resonator with a very highquality factor ( Q> 10
9). However, due to the relatively small
overlap between the ion electric field and the acoustic-modeshape, the coupling strength is found to be on the order of1 Hz. Reshaping the ion field with the aid of a capacitor led toan increase in the coupling, to 10 Hz, approaching the strongquantum regime.
By laser cooling a single
9Be+ion that interacts with the
quartz resonator, the acoustic mode with an effective mass of/greaterorequalslant1 mg (!) could be cooled close to its ground state of motion. If
such a massive object is placed in a superposition state, it couldbe used to restrict various macroscopic decoherence theories.For example, quantum gravity has been suggested to result ina motional decoherence rate that is proportional to M
2for an
object of mass M[122]. If a few-milligram mechanical oscil-
lator is placed in a superposition of position states differing bytwice its zero-point motion, that superposition would decoherein∼10 ps. This effect should be testable since the expected
coherence time of the quartz resonator is much longer, evenat 4 K. To be well within the strong quantum regime, wecould engineer a different resonator, perhaps with strongerpiezoelectric coefficients, that maintains a high Qfactor and
where the acoustic-mode shape has a large overlap with theion electric field. Such a task, however, is not straightforwardbecause these different demands may not be compatible.
Lastly, we considered coupling an electron to a supercon-
ducting electrical resonator. We examined two specific trapdesigns with a 1 eV trap depth, a depth we view as crucialfor initial trapping where laser cooling is not available. Therelatively high voltages and currents required to create sucha trap depth suggest the need for thick niobium conductorsto form the trap, in order to maintain superconductivity.Additionally, a 1 eV trap requires a low-energy source ofelectrons, and damping to combat heating. We examined athree-dimensional trap arrangement, which can separate thehigh voltage, high current rf trapping circuitry from the lowvoltage, low currents flowing in the electron detection circuitby using trap symmetry. Obtaining a similar effect for aplanar-chip trap geometry would be more complicated dueto the lack of symmetry.
It is worth noting the appealing properties that a hybrid
system based on a trapped electron might have. Such anarchitecture might be more scalable compared with trappedion QIP since the interconnecting elements are chip based,requiring only rf control and no optical elements or laserbeams. The absence of optical elements could allow forsmaller traps, enabling stronger coupling between electronsand superconducting elements. Moreover, as the speed ofentangling gates based on the Coulomb interaction of twocharged particles scales with the trapping frequency, and as atrap for electrons would typically have secular frequencies
that are two orders of magnitude larger than for ions, we
expect shorter electron gate times as compared with trappedions [ 69]. Recent advances in entangling trapped ions have
reached gate speeds that are only an order of magnitudeslower than the trap frequency [ 9]. If that were to scale for
a trapped electron, it would correspond to a ∼10–100 ns gate
time, comparable to superconducting qubit gate times [ 72].
Electron spin-coherence times can exceed a second [ 73] and
therefore be orders of magnitude larger than coherence timesfor superconducting qubits, where the best values to dateare close to a millisecond [ 123]. Therefore, a hybrid QIP
platform based on trapped electrons might have a much largerqubit coherence time to gate time ratio. The platform mightoffer an additional way to entangle electrons, mediated bythe underlying circuitry. This would enrich the QIP toolboxavailable for electron spins. For this second method, gate speedis limited to the exchange rate between the electron and itsaccompanying superconducting resonator, which we estimate
022327-20HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
to be on the order of g∼2π×1M H z f o r 5 0 μm distance
between electrons and superconducting circuitry and faster forsmaller traps.
ACKNOWLEDGMENTS
The authors would like to thank K. Cicak for her help
in estimating the coupling of an ion to a membrane and forher help with electron trap design and resulting fabricationconstraints. We thank K. Bertness for discussions regardingGaN nanobeams. We thank M. Goryachev, S. Galliou, andM. E. Tobar for introducing us to the physics of BV A resonatorsas well as lending us devices to measure. We thank A. Sandersfor introducing us to electron source and electron opticstechnology and for his help in assessing their relevance. Wethank F. Lecocq, J. D. Teufel, and J. Aumentado for discussionsregarding the superconducting and rf measurement aspectsof this manuscript. We thank A. Sirois and D. Allcock forcarefully reading this manuscript and their helpful comments.We appreciate support of the NIST Quantum Informationprogram.
APPENDIX A: CALCULATING QUARTZ RESONATOR
TO ION COUPLING
Coupling calculations require knowing the quartz resonator
mode shape /vectors, the orientation of the crystallographic axes of
the resonator, the corresponding 3 ×6 piezoelectric coefficient
matrix of quartz e, and the ion electric field. We focus on the
high-Qmodes [Eq. ( 24)] that are quasilongitudinal, i.e., along
the ˆn=(0.226,0.968,0.111) unit vector, in the coordinate
system described in Fig. 20. The BV A quartz resonators
are made from doubly rotated SC (stress-compensated) cutquartz [ 62]. The coefficient matrix efor this cut is taken from
Table 7 in the IEEE standard of piezoelectricity [ 124].
Denote the overlap integral in the numerator of Eq. ( 24)b y
g
c, i.e.,
gi=/integraltext
Vd3r∂iEiones/prime
2ω0√Mm ion≡gc
2ω0√Mm ion,i=x,y,z. (A1)
The mode mass is calculated by the integral
M=/integraldisplay
vd3rρquartz|s|2
=ρquartzπσ2t
2(1−e−L2/σ2), (A2)
Rt
Lry
FIG. 20. BV A geometry. Cylindrically symmetric about the yaxis
with a maximal thickness t. The BV A lower surface is a flat disk of
radius L. The BV A upper surface can be described by a curved surface
y=t(1−r2
2Rt) with a radius of curvature R. We consider a resonator
(not to scale) with R=300 mm, L=6.5m m , t=1.08 mm.where σis the Gaussian profile radial scale of the mode shape
/vectors.F r o mR e f .[ 66],
σ=/parenleftbiggRt3
3n2π2/parenrightbigg1/4
, (A3)
where R=300 mm is the radius of curvature of the upper
surface of the resonator, tis its thickness, and nis the
mode number (see Fig. 20). An approximate formula for the
resonance frequency is
ω0=csoundnπ
t, (A4)
where csound=6750 m/s is the speed of sound for the quasi-
longitudinal modes.
An exact calculation of gccan be found in Appendix A2.
Before doing so, we first estimate in Appendix A1an upper
bound on gcand correspondingly g, by avoiding the vector
nature of the overlap integrand.
1. Upper bound on direct ion-quartz coupling
An upper bound can be obtained by using the Cauchy–
Schwarz inequality applied to gc:
gc=/integraldisplay
d3r∂iEioneu/prime
/lessorequalslant/radicalBigg/integraldisplay
d3r(∂iEion)2/integraldisplay
d3r(eu/prime)2
/lessorequalslant/radicalBigg/integraldisplay
d3r(∂iEion)2emax/integraldisplay
d3r(u/prime)2, (A5)
where emax≈0.234 C/m2is the square root of the maximal
eigenvalue of e†e. The electric field of an ion hovering at
a height halong the ˆyaxis is Eion(/vectorr)≈q/vectorR/4π/epsilon1R3where
/vectorR=/vectorr−hˆyand/epsilon1is the average dielectric constant of vacuum
and quartz. We can therefore write
gc/lessorequalslantγemaxq
4π/epsilon1√
h3/radicalBigg/integraldisplay
d3r(u/prime)2, (A6)
where γis a numerical factor of order unity for all i=x,y,z
directions.
To estimate the last integral of the strain ( u/prime)2, recall that
the mode mass M=/integraltext
d3rρquartzu2, where ρquartz=2.6×
103kg/m3is the quartz density. Due to the mode shape
[Eq. ( 24)] we may approximate u/prime∼ku, where kis the wave
number of the longitudinal oscillations within the BV A, i.e.,kt=nπ fortthe resonator thickness and n=1,3,5,....
Therefore,/integraltext
d
3r(u/prime)2∼k2/integraltext
d3ru2and we may estimate an
upper bound,
g≡gc
2ω0√Mm ion
/lessorequalslantγemaxq
4π/epsilon1cs/radicalBig
mionρquartzh3
0∼2π×1k H z, (A7)
where cs=6757 m /s is the speed of sound for the quasilon-
gitudinal mode.
022327-21KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
TABLE III. Direct coupling of a9Be+i o nt oaB V Aq u a r t z
resonator. The ion is assumed to be trapped 50 μm above the quartz.
The quartz thickness is assumed to be 1 .08 mm. Coupling strength
gifori=x,y,z corresponds to an ion motion along the iaxis. The
longitudinal mode number is n.
n Frequency gy gx gz
3 9.4 MHz 2 π×1.46 Hz 2 π×1.09 Hz 2 π×0.49 Hz
5 15.6 MHz 2 π×1.39 Hz 2 π×1.02 Hz 2 π×0.47 Hz
7 21.9 MHz 2 π×1.33 Hz 2 π×0.97 Hz 2 π×0.44 Hz
9 28.1 MHz 2 π×1.28 Hz 2 π×0.94 Hz 2 π×0.43 Hz
2. Direct ion-quartz-coupling calculation
Now that the upper bound has been established, we
numerically calculate the integral in Eq. ( A1)f o rt h el o w -
frequency modes of the quartz resonator (Table III). We see
that all coupling strengths are below 1 .5H z .
It is interesting to notice the weak dependence of the
coupling strengths on the mode number n. Due to the frequency
and mode mass scaling, the denominator of Eq. ( A1) scales
like√n. On the other hand, because the derivative of the
ion field is equivalent to a dipole field, the integrand of gc
scales as 1 /r3whereas its Jacobian scales as rdrso overall we
should expect a 1 /r∼1/σ∼√ndependence, which nearly
cancels the similar dependence in the denominator for theexpression in g. Although, for very high frequency modes, g
should deteriorate due to high spatial frequency averaging ofthe ion field.
3. Ion-quartz coupling via shunt capacitor
In the body of the paper, we estimate the coupling of the
ion to the quartz resonator via a shunt capacitor by usinga BVD equivalent electrical circuit. The main advantage ofthat approach, other than its simplicity, is that the effectivecapacitance of a BV A quartz resonator is a rather easilymeasured quantity [ 67].
H e r e ,w eu s eE q .( A1) to directly calculate the coupling
strength, in order to infer its dependence on mode parameters.To this end, we have to introduce parameters that describe thegeometry involved. The ion is assumed to be trapped at thecenter of a parallel plate capacitor whose plates are a distanced
Tfrom one another (see Fig. 21). The quartz resonator is
dQA
Cshunt
Leq,m ion dT Ctrap
FIG. 21. Coupling an ion to a quartz resonator mediated by a
shunt capacitor. An ion is elastically trapped (trap electrodes notshown) at the center of a parallel plate capacitor. The ion motion
generates image currents that in turn generate an electric field
between the parallel plate capacitor (each plate with area A=πL
2
e)
encapsulating the quartz resonator.assumed to be enclosed in another parallel plate capacitor,
with a distance dQbetween the plates and a plate area of A.
If the ion is displaced by /Delta1yfrom equilibrium towards one
of the plates, it will generate an image charge q∗=/Delta1yq/d T.
A portion of these image charges spread uniformly on theBV A shunt capacitor plates, creating a charge density σ=
q
∗/A(1+Ctrap/Cshunt) and exerting a field inside the BV A
volume E=σ//epsilon1. We get
dE
d/Delta1y=q
/epsilon1AdT(1+Ctrap/Cshunt), (A8)
where Ctrapis the trap capacitance, and Cshunt is the BV A
shunt capacitance and the field is perpendicular to the plates.As before, we focus on the quasilongitudinal mode shapes[Eq. ( 24)]. Performing the overlap integral in this case results
in
g
c=4q¯e
/epsilon1dTσ2
L2e/parenleftbig
1−e−L2
e/2σ2/parenrightbig 1
1+Ctrap
Cshunt, (A9)
where Leis the electrode radius, ¯eis the mode-
shape weighted average of e22,e2,4,e26, i.e., ¯e=nye22+
nze24+nxe26=7.43×10−2C/m−2and ˆn=(nx,ny,nz)=
(−0.23,−0.97,0.1) is the quasilongitudinal mode direction
vector. By maximizing gcas a function of Leand for
Ctrap=50 fF trap capacitance, we estimate Le=1.05σ,s o
the coupling rate is
g=0.58qe
/epsilon1dTω0√Mm ion=2π×10 Hz, (A10)
where we assumed coupling to a9Be+ion, trapped between
capacitor plates a distance dT=200μm away from one
another.
To see the geometric scaling of this, recall that σ=(t3R
3π2n2)1
4
andω0≈csnπ/t [66]. We get
g≈0.3qe
/epsilon1cs√mionρquartz1
dT(tR/2)1
4√n. (A11)
From Eq. ( A11), we expect the coupling to diminish
for higher modes (increasing n). The dependence in the
geometrical parameters t,R is also very weak (1 /4 exponent)
with values limited to thicknesses in the range of 0 .5t o1m m
and radii of curvature in the R∼300 mm range.
APPENDIX B: ESTIMATING ELECTRON “ANOMALOUS”
MOTIONAL HEATING RATE FROM AMBIENT NOISE
We estimate the “anomalous” heating rate of the electron
motion by extrapolating from known ion heating rates [ 125–
127]. Ifndenotes the average number of motional quanta in a
trap with frequency fthen
˙n∝q2
m1
d4f1+α, (B1)
where q,m are the particle charge and mass, respectively, and
αvaries between 0 .5 and 2 in various experiments. In this
expression, dis the distance of the charge from the nearest
electrode and we assume the electric-field noise is generatedby independent fluctuating patch potentials of extent <d[125].
022327-22HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
TABLE IV . Selected measured heating rates ˙nfor ion traps. Ion-
to-surface distance is d,fis the trap frequency.
Trap material T ion df ˙n Ref.
Au on sapphire 5 K88Sr+50μm1.32 MHz 4 quanta /s[128]
Au on quartz 300 K9Be+40μm3.6 MHz 58 quanta /s[129]
Nb on sapphire 6 K88Sr+100μm 1 MHz 2 quanta /s[91]
From Table IVand Eq. ( B1) we can estimate the electron
heating rate to be between 30 to 160 quanta/s for a trap-to-electron distance of ∼50μm and an electron motional
frequency of ∼1 GHz, assuming α=0.5. For α=2, all of the
extrapolated heating rates are below 0 .02 quanta/s. These rates
are at least three orders of magnitude smaller than the couplingrates we expect between the electron and the superconductingresonator. Specifically, with the traps considered in this paper,the coupling rates were estimated to be in the range of 0 .18 to
1.06 MHz.
APPENDIX C: ELECTRON HEATING RATE DUE TO
INCOMING ELECTRONS DURING THE LOADING
PROCESS
We estimate an upper bound for the heating rate of trapped
electrons due to collisions with incoming electrons during traploading. We assume that a single electron is trapped in athree-dimensional harmonic potential with ∼1 GHz secular
frequency in all axes with a trap depth of U
depth=1e V .
Incoming electrons, each having Ep=30 eV of kinetic
energy, collide with the trapped electron, causing heating.
We focus on a single trapped electron collision process
since we are aiming at a steady-state number of just one to afew trapped electrons. Moreover, we assume that the trappedelectron interacts with just one incoming electron at a time.This is consistent with the incoming electron current valueswe considered in Sec. VI C and the timescale for the collision
process (see below).
We ignore the trap dynamics during any single collision
since the former is relatively slow compared with the latter. To
see this, first note that the timescale for a collision process isb/v
p,0where bis the impact parameter and vp,0is the incoming
electron initial velocity. The impact parameter is limited by theoverall incoming electron beam radius r
0, which we assume is
<100μm. The incident electron speed is vp,0=/radicalbig2Ep/me=
3.2×106m/s where meis the electron mass. Therefore, the
collision duration times are /lessorequalslant3×10−11s, i.e., shorter than the
trap drive period ( ∼10−10s) and much shorter than the trap
harmonic period ( ∼10−9s). Based on our trap parameters, we
can estimate that, during a collision, trap forces will changethe positions of the two electrons by no more than ∼20% as
compared with a collision where no trap is involved. Sincewe are interested only in an order-of-magnitude estimate, weignore these deviations from a trap-free calculation.
For our purposes, however, the trap still plays a role in
determining the initial conditions of the collision process.Trapped electrons have an initial energy below U
depth.F o r
simplicity we assume that the initial energy distribution isuniform in the range 0 /lessorequalslantE
s,0/lessorequalslantUdepth (see, for example,Fig. 5 in Ref. [ 109]). The incoming electron, at the moment
of entrance into the trapping region, either accelerates ordecelerates prior to the collision, depending on the phaseof the trap drive. For concreteness we use the geometry inFig. 14(b) , the trap parameters of Table II, and assume that the
incoming electron velocity is initially along the trap symmetryaxisz. The incoming electron’s initial kinetic energy prior to
collision will be spread by ±15 eV around E
p=30 eV, as
we show later. Since the primary electron beam is initiallyaligned parallel to the rf electric field, the rf-trap-inducedspread in E
pis maximal. If, for example, the electrons come
at an angle of ∼54.7◦with respect to z, the energy spread
inEpreduces to ±2.5 eV. At this angle, to first order, the
rf-trap field lines are perpendicular to the incoming electrons’
initial velocity. Our choice of geometry and electron direction
therefore accentuates the spread in Epdue to the rf in order to
fully appreciate its influence on the heating rate. Another effectof the trap is electron deflection in the transverse directionresulting in a rastering of the incoming beam. It can be shownby using elementary electrostatic consideration that the beamradius will expand by /lessorequalslantexp{2a r c s i n[ q
eVrf/(Ep+eVrf)]}<
4. Therefore, we must make sure that the initial beam diameter
is small enough such that the beam does not strike the trap
electrodes from rastering.
We assume that the process can be reasonably captured
by classical mechanics. We therefore ignore the spins of theelectrons, as well as scattering interference effects. The ratiobetween the quantum-mechanical differential cross sectionfor electron-electron Coulomb scattering ( dσ/d/Omega1 )
quantum and
its classical counterpart ( dσ/d/Omega1 )classical can be bounded by
0.5<|(dσ/d/Omega1 )quantum /(dσ/d/Omega1 )classical|<1.03, based on our
parameters; see, e.g., Ref. [ 130]. The quantity of interest is
the energy gain per collision, /Delta1E, which is the average of
the energy gained per scattering direction over an appropriaterange of solid angle. Therefore, our classical estimation of/Delta1E will also not deviate from a full quantum-mechanical
estimation by more than the above bounds.
The geometry of a collision process is shown in Fig. 22(a) .
An incoming electron with velocity /vectorv
p,0and position /vectorrp
collides with a relatively slow trapped electron (the target
electron) with velocity /vectorvs,0and position /vectorrs. Our subscripts
follow the convention of electron scattering terminology where
the incoming electrons are called “primary” whereas the (pos-
sibly) scattered electrons are called “scattered.” The scatteringproblem can be described in the center-of-mass and reduced-mass coordinates: R
c.m.≡(/vectorrp+/vectorrs)/2, and /vectorr≡/vectorrp−/vectorrs,r e -
spectively. Ignoring the trapping potential as mentioned above,we can assume that the center of mass will move at a constantvelocity of /vectorV
c.m.=(/vectorvp,0+/vectorvs,0)/2. The relative motion is
described in the primed coordinate system shown in Fig. 22(b) .
It is subsequently reduced to a Rutherford scattering problemof a particle of one electron charge and a reduced mass ofμ=m
e/2, moving with an initial velocity /vectorv=/vectorvp,0−/vectorvs,0and
an impact parameter b, in the Coulomb potential of a fixed elec-
tron at the origin [see Fig. 22(b) ]. The relative velocity vector
will therefore be deflected with respect to its initial direction by
θR=2a r c t a n/parenleftbiggq2
e/4π/epsilon10b
μv2/parenrightbigg
, (C1)
where v≡| /vectorv|.
022327-23KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
x
yz
s,0
e−,me s
p,0p
e−,mexz
be−,μθR(b) (a)
FIG. 22. Geometry of electron-electron scattering. (a) Laboratory
frame. An incoming fast electron with velocity /vectorvp,0collides with a
slow (trapped) electron with velocity /vectorvs,0. (b) Reduced-mass frame
of reference. Here, /vectorr≡/vectorrp−/vectorrs,/vectorv≡/vectorvp,0−/vectorvs,0,a n dμ=me/2i st h e
reduced mass. The angle θRis the deflection angle of /vectorvwith respect
to its initial direction, after the collision.
Returning to the laboratory frame, the target electron final
velocity is
/vectorvs=/vectorvp,0+/vectorvs,0
2−/vectorvcosθR+vˆusinθR
2, (C2)
where
ˆu=/vectorr−(/vectorr·ˆv)ˆv
|/vectorr−(/vectorr·ˆv)ˆv|,ˆv=/vectorv
v. (C3)
By using Eq. ( C2) and the triangle inequality, we can find
an upper bound for |/vectorvs|as
|/vectorvs|/lessorequalslant|/vectorvp,0−/vectorvs,0|/vextendsingle/vextendsingle/vextendsingle/vextendsinglesinθ
R
2/vextendsingle/vextendsingle/vextendsingle/vextendsingle+|/vectorv
s,0|
/lessorequalslant/parenleftBigg
1+/radicalBigg
Ethresh
Ep/parenrightBigg
|/vectorvp,0|/vextendsingle/vextendsingle/vextendsingle/vextendsinglesinθ
R
2/vextendsingle/vextendsingle/vextendsingle/vextendsingle+|/vectorv
s,0|,(C4)
where Ethresh is the maximal energy of an initially
trapped electron (see Sec. VI C ). This translates into a
bound on the change in the kinetic energy of the targetelectron
|/Delta1E|=/vextendsingle/vextendsingle/vextendsingle/vextendsingle1
2me|/vectorvs|2−1
2me|/vectorvs,0|2/vextendsingle/vextendsingle/vextendsingle/vextendsingle
/lessorequalslantγE
p/vextendsingle/vextendsingle/vextendsingle/vextendsinglesinθ
R
2/vextendsingle/vextendsingle/vextendsingle/vextendsingle, (C5)
where
γ=/parenleftBigg
1+/radicalBigg
Ethresh
Ep/parenrightBigg/parenleftBigg
1+3/radicalBigg
Ethresh
Ep/parenrightBigg
. (C6)
If we use Udepth as a bound for Ethresh , we get γ≈1.83.
However, in Sec. VI C we showed that only electrons with
Ethresh=0.3 meV are expected to be trapped, correspondingtoγ≈1.01. The average change in the absolute value of the
target electron kinetic energy is therefore
/angbracketleft|/Delta1E|/angbracketright/lessorequalslantγq2
e
4π/epsilon10r0, (C7)
where r0is the incoming electron beam radius. Here, we
averaged over all possible impact parameters b, assuming that
the incoming electrons are uniformly distributed in an electronbeam having a radius of r
0:
/angbracketleftbigg
γEp/vextendsingle/vextendsingle/vextendsingle/vextendsinglesinθ
R
2/vextendsingle/vextendsingle/vextendsingle/vextendsingle/angbracketrightbigg
=γE
p
2r2
0/integraldisplay2r0
0dbb1/radicalBig
1+/parenleftbig2π/epsilon10bmev2
q2e/parenrightbig2
≈γEp
2r2
0/integraldisplay2r0
0dbb1/radicalBig
1+/parenleftbig4π/epsilon10bEp
q2e/parenrightbig2
≈γq2
e
4π/epsilon10r0, (C8)
where the approximation v∼vpwas used.
A subtle point in the calculation of the average in Eq. ( C8)
is the assumption of a uniformly distributed (spatial) incidentelectron beam. While this assumption is reasonable in thelaboratory frame, it is not immediately clear that it is adequatefor the center-of-mass frame. For trapped electrons withan initial energy /lessorequalslantE
thresh=0.3 meV; that is, significantly
smaller than Ep=30 eV, the assumption of uniformity is a
good approximation since the laboratory frame and center-of-mass frame are nearly identical. The value of E
thresh might be
larger if measures are taken to decrease trap anharmonicity.The ultimate bound for E
thresh is therefore Udepth. In that case,
we can see numerically that going to the center-of-mass frame
0 10−702004006008001000120014001600
|ΔE|/EpEvent count
FIG. 23. Histogram of the absolute value of the change in
total energy of a trapped electron, |/Delta1E|, due to collisions with
anEp=30 eV incoming electrons. Shaded pink region shows the
analytic bound in Eq. ( C7). We numerically integrate the equations
of motion for an electron, trapped initially at x=y=z=0, with
initial energy Esinteracting with the incoming electron. We assume
a pseudopotential harmonic trap with 1 GHz frequencies in all axes
in a trapping volume of l3=(95μm)3. Here we do not account for
micromotion dynamics. The energy Esis assumed to be uniformly
distributed between 0 /lessorequalslantEs/lessorequalslantUdepth=1.01 eV and the incoming
electron position is assumed to be at z=− 1 mm with x,y uniformly
distributed in the beam cross section, ( x2+y2)1/2/lessorequalslantr0=100μm.
022327-24HYBRID QUANTUM SYSTEMS WITH TRAPPED CHARGED . . . PHYSICAL REVIEW A 95, 022327 (2017)
00 . 511 . 522 . 530100200300400
t/τrf||(μm)
05101520253035
Ep(eV)
012345050100150200250300
t/τrf||(μm)
253035404550
Ep(eV)
10−410−310−210−110010110210−1210−1010−810−610−410−2100102
b(μm)Es(eV)
10010110210−510−410−310−2
r0(μm)ΔEbound (eV)(a) (b)
(c) (d)
FIG. 24. The effect of micromotion on electron-electron scattering for a harmonic trap with dimensions and frequencies similar to those
described in Fig. 14(b) . (a) Example of a simulated trajectory of a trapped electron (dotted blue curve) colliding with an incoming electron
(dashed red curve) at an impact parameter b=10˚A, as a function of time in units of the trap rf period τrf. Trap center is assumed at the origin
x=y=z=0a n d/vectorris the particle position. The instantaneous kinetic energy of the incoming electron Ep(solid green curve) decreases prior
to the collision due to the varying rf potential. When the incoming electron is at a distance of the order of ∼bfrom the trap center (dashed
black line), the incoming electron looses 1 .39 eV giving the trapped electron enough energy to escape the trap. (b) Same as panel (a), but for
an initial rf phase shifted by πradians as compared to panel (a). In this case, the trapped electron gains 0 .27 eV due to the collision, resulting
in confined oscillations. (c) Blue vertical lines show the spread in the final target electron energy Esvs impact parameter b, resulting from
different initial trap rf phases. Analytic theory of Eq. ( C10) is shown by the solid red line. (d) Bound on the average energy gain per collision
vs incoming electron beam radius r0. Target electron initial kinetic energy is assumed to be uniformly distributed from 0 eV to 1 eV. Analytic
theory of Eq. ( C8) (solid blue line) is compared with a numerical integration of Eq. ( C11) that includes the spread in impact parameters and
incoming electron kinetic energies due to micromotion (blue circles). The spread in these values is calculated by numerical integration of the
equations of motion for the two electrons, for various initial conditions, and under the influence of the trap rf field as well as their Coulombrepulsion. Initial conditions are assumed uniform as in Fig. 23.
redistributes the impact parameters to include a larger range of
distances and consequentially a lower average impact energy.The calculation in Eq. ( C8) can therefore be regarded as an
upper bound on the actual average value of |sin(θ
R/2)|.A sa n
example, we compare this bound to a histogram of |/Delta1E|de-
rived from a numerical integration of the collision equation ofmotion for a random set of initial conditions, as seen in Fig. 23.
The target electron energy before collision E
s,0is assumed
to be uniformly distributed 0 /lessorequalslantEs,0/lessorequalslantUdepth. The incoming
electron beam is assumed to be uniformly distributed. From thehistogram, the average absolute value of the energy imparted tothe target electron per collision is ∼0.74×10
−7Ep. Assuming
0/lessorequalslantEs,0/lessorequalslantUthresh , this average decreases to ∼10−9Ep.B o t h
values are consistent with the analytic expression in Eq. ( C7)
which yields a bound of 4 .8×10−7Ep. The simulation is set
up to account for the effect of the trapping pseudopotentialduring the collision process, thereby serving as an independentvalidation of the omission of trap dynamics in our analytic
derivation.
Since the bound in Eq. ( C7) does not depend on the target
electron initial velocity, it can be translated to a correspondingaverage heating rate bound by multiplying it by the incomingrate of electrons. A current density of Jincoming electrons
results in Jπr
2
0/qecollisions per second, which in turn results
in a heating rate bound of
/parenleftbiggdE
dt/parenrightbigg
e/lessorequalslantqeJr0
4/epsilon10, (C9)
where we approximated γ≈1.
The above discussion did not include the effect of micro-
motion on the collisions. The effect of the trap drive is tospread the kinetic energy of the incoming electron as well asthe impact parameter of the collision. The bound in Eq. ( C9)
changes only by a factor of order unity due to micromotion. To
022327-25KOTLER, SIMMONDS, LEIBFRIED, AND WINELAND PHYSICAL REVIEW A 95, 022327 (2017)
see this, we first consider the simple case of a target electron
initially at rest in the absence of rf fields. By using Eq. ( C2)
we can write the target electron exact final kinetic energy dueto a single collision:
E
s=Epx2
1+x2,x≡q2
e/4π/epsilon10b
Ep. (C10)
Forx/lessmuch1 (equivalently b/greatermuch1˚A), faster (slower) incoming
electrons result in a smaller (larger) increase of the targetelectron energy, E
s∝1/Ep.
In the presence of a rf trap, the incoming electron can
either accelerate or decelerate before the collision, dependingon the initial phase of the trap drive when it entered thetrapping region. An accelerated (decelerated) electron willtherefore transfer less (more) energy to the target electron ascompared with the no-trap collision. This is exactly the casefor the two examples shown in Figs. 24(a) and 24(b) . These
simulate collision processes for initial rf phases that differbyπradians. For concreteness, we assumed an rf trap with
dimensions and frequencies as in Fig. 14(b) and Table II.W e
simplified the calculation by assuming the trap is harmonic inthe entire cylindrical volume bounded by the electrodes. Theincoming electron initial velocity is assumed to be parallel tothe trap zaxis. Figure 24(a) shows a collision process where the
incoming electron is maximally decelerated to a kinetic energyofE
p=15 eV at the beginning of the collision. This results in
the ejection of the target electron from the trap. Figure 24(b)
shows the other extreme case where the incoming electronexperiences maximal acceleration resulting in E
p=46 eV so
the target electron remains trapped. Although this may seemparadoxical, it follows immediately from Eq. ( C10) for impact
parameters which satisfy b/greatermuch1˚A.To see how well this explanation encapsulates the effect
of micromotion for the general case, we compare the theoryin Eq. ( C10) to the values of E
sextracted from numerical
simulations as a function the impact parameter b.W ev a r yt h e
values of bfrom 1 ˚A, below which collisions are essentially
head on [equivalently x∼1i nE q .( C10)], to 100 μm, i.e.,
the electron beam radius. For a given value of b, the different
values of the trap initial rf phase result in the spread in Es
values shown in Fig. 24(c) (blue markers). The center of these
distributions, however, follows the theory in Eq. ( C10), which
assumes no trap drive [solid red line in Fig. 24(c) ]. Overall,
the effect of micromotion is a ∼60% spread in the value of Es,
centered at the value given by Eq. ( C10).
Finally, we extend our treatment to include nonzero initial
velocity for the target electron. To this end, we repeat thecalculation in Eq. ( C8) with the addition of averaging over the
rf initial phase φ
rf:
/angbracketleftbigg
γEp/vextendsingle/vextendsingle/vextendsingle/vextendsinglesinθ
R
2/vextendsingle/vextendsingle/vextendsingle/vextendsingle/angbracketrightbigg
=γ
2πr2
0/integraldisplayr0
0dbb/integraldisplay2π
0dφrfEp,col/radicalBig
1+/parenleftbig2π/epsilon10bcolmev2
q2e/parenrightbig2,(C11)
where Ep,colandbcolare the impact energy and impact
parameter at the time of collision and are functions of φrf.
Numerical evaluations of Eq. ( C11) are in good agreement
with the analytic theory which assumed the absence of a trap[Eq. ( C8)], as can be seen in Fig. 24(d) . Here, the value of γ
in Eq. ( C6) changes to γ∼2.23 to account for the maximally
decelerated incoming electrons, with energies as low as 15 eV.
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022327-29 |
PhysRevApplied.10.024031.pdf | PHYSICAL REVIEW APPLIED 10,024031 (2018)
Effect of (Co xFe1−x)80B20Composition on the Magnetic Properties of the Free
Layer in Double-Barrier Magnetic Tunnel Junctions
Shalabh Srivastava,1Andy Paul Chen,2,5Tanmay Dutta,1,3Rajagopalan Ramaswamy,1Jaesung Son,1,4
Mohammad S. M. Saifullah,3Kazutaka Yamane,4Kangho Lee,4Kie-Leong Teo,1Yuan Ping Feng,2,5
and Hyunsoo Yang1,*
1Department of Electrical and Computer Engineering, National University of Singapore, Singapore 117576
2Department of Physics, National University of Singapore, 2 Science Drive 3, Singapore 117542
3Institute of Materials Research and Engineering, A*STAR (Agency for Science, Technology, and Research),
2 Fusionopolis Way, #08-03 Innovis, Singapore 138634
4GLOBALFOUNDARIES Singapore Pte. Ltd., 60 Woodlands Industrial Park D, Street 2, Singapore 738406
5NUS Graduate School of Integrative Sciences and Engineering, National University of Singapore, 28 Medical
Drive, Singapore 117456, Singapore
(Received 14 December 2017; revised manuscript received 31 May 2018; published 22 August 2018)
The alloy Co-Fe-B finds extensive application in spintronics, and in particular the perpendicular mag-
netic anisotropy characteristic of Co-Fe-B-MgO systems is of great interest. While some efforts have been
made to examine the effect of composition on magnetic properties of Co-Fe-B materials, the magnetic-
property–composition relationship for the Co-Fe-B-MgO system is still not fully understood. Therefore,it is fundamentally and practically important to understand the Co-Fe-B composition dependence of
the magnetic properties of Co-Fe-B-MgO systems. This work focuses on the data-storing free layer of
double-barrier magnetic tunnel junctions with perpendicular magnetic anisotropy (PMTJs), which include
(Co
xFe1−x)80B20ultrathin films sandwiched between two MgO layers and a W insert layer. We study
magnetic properties of various (Co xFe1−x)80B20compositions at different annealing conditions and find
x∼35% to have the highest anisotropy energy to ensure high thermal stability, while maintaining the
lowest Gilbert damping parameter which is essential to achieve a low critical switching current. This
composition also shows the highest thermal stability at elevated temperatures. In addition, we performfirst-principle calculations to explain the anomalous composition trends of the magnetization and Gilbert
damping parameter. Moreover, we find that the conventional Slater-Pauling curve is not applicable, and it
is necessary to consider the magnetization’s dependence on the magnetic anisotropy which in turn dependson (Co
xFe1−x)80B20composition and the oxide interface. Our results provide a perspective for a better
understanding of metal-oxide systems with desirable properties for DBL PMTJ applications.
DOI: 10.1103/PhysRevApplied.10.024031
I. INTRODUCTION
Spin-transfer-torque magnetic random-access memory
(STT MRAM) based on a magnetic tunnel junction (MTJ)
with a MgO tunnel barrier and Co-Fe-B magnetic elec-
trodes provides a promising solution for universal memory.
STT MRAM has the potential to achieve a low power
consumption, high density, fast read-and-write speed, very
high endurance, and excellent scalability [ 1,2]. MTJs with
perpendicular magnetic anisotropy (PMA), called PMTJs,
are currently the subject of extensive research and com-
mercialization work. PMA has a magnetic anisotropy
easy-axis orientation in the orthogonal direction of the
magnetic film, while, on the other hand, in-plane mag-
netic anisotropy has an easy-axis orientation in the plane
*eleyang@nus.edu.sgof the film, which is a preferred orientation because of
the demagnetization field. Compared to materials with
in-plane magnetic anisotropy, materials with PMA show
a higher STT switching efficiency, lower power consump-
tion, and better scalability with improved thermal stabil-
ity, which are the essential properties for long-term data
storage [ 3–5].
The switching between the memory states in a MTJ is
governed by two mechanisms, namely, coherent uniform
switching and domain-nucleation-based switching. In the
case of coherent uniform switching, the thermal stability
of a magnetic thin film mainly depends on the factor /Delta1=
KeffV/kBT, where Keffis the effective anisotropy energy,
Vis the volume of the magnetic layer, kBis the Boltz-
mann constant, and Tis the operation temperature [ 3].Keff
is the effective anisotropy energy, which is given by the
intrinsic uniaxial anisotropy ( KU) and the demagnetization
2331-7019/18/10(2)/024031(11) 024031-1 © 2018 American Physical SocietyS. SRIVASTAVA et al. PHYS. REV. APPLIED 10,024031 (2018)
energy according to the relation Keff=KU−2πMS2.
The coherent-uniform-switching mechanism is valid for
small magnetic dimensions, whereas for larger magneticdimensions (approximately 4 δ
w, where δwis the domain-
wall width) the switching proceeds predominantly via a
domain-nucleation mechanism. The dimension limit of the
transition between the above two mechanisms is deter-
mined by the exchange stiffness ( AS) of magnetic mate-
rials [ 6–9].
A double-barrier layer (DBL) is a PMTJ structure that
has a free layer sandwiched between two MgO layers [ 10].
A DBL is effective in increasing /Delta1of the free layer by
increasing Vand Keff. The perpendicular magnetic ori-
entation of the free layer is stabilized with a relatively
strong uniaxial magnetic anisotropy, which is character-
ized by twofold symmetry and assisted by the interfa-
cial anisotropy originating from the interface of Co-Fe-B
with MgO and the heavy metal (e.g. W). The uniaxial
anisotropy causing PMA can be attributed to the spin-orbit
interaction (SOI) between the ferromagnet and the heavy
metal, as well as overlap between the O porbital and
SOI-induced hybridization of the dorbital of the ferro-
magnetic material [ 11]. For reliable memory applications,
PMA materials should have a high value of Keffto ensure
/Delta1> 60 for high thermal stability [ 12]. At the same time, a
small Gilbert damping parameter ( α) is required to achieve
a low switching current ( Ic) while maintaining a high /Delta1.
Maximizing thermal stability at higher temperatures and
maintaining annealing robustness are crucial factors in the
development of a PMTJ. Therefore, it is important to study
the annealing and temperature dependence of the magnetic
properties of PMTJ stacks. For example, it has been shown
that the temperature dependence of magnetocrystalline
anisotropy for (Fe 1−xCo x)2B ingot systems arises from the
changes in the electronic structure induced by spin fluctua-
tions [ 13,14]. Moreover, temperature-dependent measure-
ments of Keffand the saturation magnetization ( MS) can
also provide insight into the nature of anisotropy by a rela-
tionship given by the Callen-Callen model [ 15,16]. Apart
from the temperature dependence of the magnetic proper-
ties, there are few experimental and theoretical studies in
the literature on the composition dependence of magnetic
properties such as the Curie temperature ( TC),MS[17,18],
Keff[17–20], lattice parameter ( a0), coercivity ( HC)[21],
gfactor [ 17],α[22–24], and tunneling magnetoresis-
tance (TMR) [ 25]. Since it is hard to give a semi-classical
description for most of these above properties, some stud-
ies have attempted to provide quantum-mechanical expla-
nations [ 26]. However, it is noted that most of these studies
are limited only to bulk magnetic materials.
In contrast, the current STT MRAM involves ultra-
thin films with the MgO tunnel barrier (approximately
1 nm) and metals as adjacent layers, whose properties
are very different from the bulk magnetic materials. In
ultrathin films, the break in symmetry, strains, interfaces,oxygen hybridization, and change in crystallization are the
determining factors for the change in magnetic properties
(MS,TC,Keff,a n dα)[27–30]. Therefore, there is a need
to calculate the band structure of thin-film systems with
proper consideration given to oxide interfaces and film
thickness since the Slater-Pauling model, which predicts
the dependence of magnetic moment on the composition in
the bulk materials [ 31–33], may not be applicable for thin-
film systems. Furthermore, it is observed that the tempera-
ture dependence of αis independent of intrinsic factors of
the bulk and instead depends on the interfacial anisotropy
[16]. Thus, the role of the MgO-Co-Fe-B interface must be
considered in engineering the αof the materials. In addi-
tion, increases in ASand decreases in αwith the annealing
temperature are found to be related to the Fe-O interface,
Co-Fe-B crystallization, and the differential modification
of the thin films compared to the bulk [ 34–37].
In this work, we present a comprehensive analysis of
the factors that are affected by changing the composition
of (Co xFe1−x)80B20in the free layer of DBL PMTJs. The
effects of annealing on MS, the saturation field in the hard-
axis direction Heff
K[5],Keff,a n dαare studied to identify a
suitable (Co xFe1−x)80B20composition for CMOS integra-
tion (at least 400 °C annealing temperature). The results
based on density-functional-theory calculations are used to
explain the anomalies in trends of αand MSwith respect
to (Co xFe1−x)80B20composition. We also identify com-
positions that show the lowest effects of temperature on
magnetic properties to ensure data retention during the
solder-reflow process (260 °C for 90 s). The results of
temperature-dependent measurements are used to compute
ASas a function of (Co xFe1−x)80B20composition. The tem-
perature dependences of MSand Keffare also analyzed
using the Callen-Callen model to give an insight into the
natures of the magnetization and anisotropy for different
(Co xFe1−x)80B20compositions.
II. EXPERIMENTAL DETAILS
The films with the stack structure of substrate/Ta(27)/
Co20Fe60B20(4)/MgO(13)/(Co xFe1−x)80B20(13)/W(4)/(Co x
Fe1−x)80B20(9)/MgO(9)/Ta(9)/Ru(27) (thicknesses in Å)
are sputter deposited onto thermally oxidized silicon
wafers in a magnetron-sputtering chamber with a base
pressure of 5 ×10−9Torr. A schematic diagram of the
deposited structure is shown in Fig. 1(a). The refer-
ence layer is taken to be 0.4 nm of Co 20Fe60B20so
that it is magnetically dead, and we can independently
study the properties of the free layer of the DBL PMTJ.
The W is chosen as the insertion material between two
(Co xFe1−x)80B20layers, because it has a better tolerance
for 400 °C annealing conditions, as compared to a Ta
insertion layer [ 38–40]. In order to achieve the different
compositions of (Co xFe1−x)80B20, the two composite tar-
gets of Co 60Fe20B20(target 1) and Co 20Fe60B20(target 2)
024031-2EFFECT OF (Co xFe1−x)80B20COMPOSITION ON MTJ FREE LAYER. . . PHYS. REV. APPLIED 10,024031 (2018)
are co-sputtered, keeping the boron constant in terms of
mole fraction. Since the deposition rates of both targets are
similar (close to 0.029 nm/s), the sputtering power of tar-
get 1 is fixed at 60 W (P1), while the sputtering power
of target 2 (P2) is varied to achieve an intended composi-
tion x. TOF SIMS coupled with plasma etching is utilized
to determine the composition of Co and Fe relative to B
(which is assumed to be constant). The deposited compo-
sitions of (Co xFe1−x)80B20are very close to the intended
compositions as shown in Fig. 1(b). The deposited films
are annealed at 300, 400, and 450 °C for 30 min. A VSM
is used to characterize the magnetic properties of the films,
such as, MS,Heff
K,a n d HC. TEM is performed on selected
samples to check the crystallinity and the film thickness.
The TEM image and hysteresis loop obtained from VSM
for the sample with a composition of x=25% are shown
in Figs. 1(c) and1(d), respectively. The W insertion layer
is indistinguishable in the middle of two (Co xFe1−x)80B20
free layers because of a very small thickness and simi-
larly the 0.4-nm-thick (Co xFe1−x)80B20reference layer is
indistinguishable from the Ta layer in Fig. 1(c).Heff
Kis
determined by the saturation magnetic field in the hard-
axis direction (in-plane) in Fig. 1(d).MSis determined by
the saturation magnetic moment in the easy-axis (out-of-
plane) hysteresis and the coercivity HCis shown in the
inset of Fig. 1(d).
Ferromagnetic resonance (FMR) measurements are car-
ried out to determine αand the gfactor. A radiofrequency
signal with an amplitude of 4 dBm is applied to the
waveguide to excite FMR. In order to determine the res-
onance magnetic field Hresat each frequency fres,a n
external magnetic field perpendicular to the waveguide
is swept at different rf signal frequencies, in stepwise
changes. The value of αis determined by the relationship
/Delta1H=/Delta1H0+4πα fres/μ0γ, where /Delta1His the resonance
field linewidth and γis the gyromagnetic ratio calcu-
lated using the Kittel equation, fres=γμ 0Hres/2π, for the
out-of-plane magnetic field configuration [ 41].
In order to determine the exchange stiffness AS, the
temperature dependence of the magnetization is analyzed
using the Kuz’min model [ 42,43],
MS(T)
MS(0)=/bracketleftBigg
1−s/parenleftbiggT
TC/parenrightbigg3/2
−(1−s)/parenleftbiggT
TC/parenrightbigg5/2/bracketrightBiggβ
,( 1 )
where s=0.0586 (gμB/βM0)(kT C/D)3/2,TCis the Curie
temperature, βis a constant based on anisotropy, and is
typically taken as 1/3, Dis the spin-wave stiffness, and
MS(0) is the saturation magnetization at 0 K. Dis related
to exchange stiffness according to the equation [ 44]D=
2gμBAS(T)/MS(T).
In order to provide a qualitative understanding of the
observed magnetic properties, we carry out first-principles
calculations using the Vienna ab initio simulation package(VASP ). The Co xFe100−x/MgO structure is modeled using
a superlattice model that comprises three layers of (001)-
oriented MgO and five layers of (001)-oriented bcc
Co xFe100−xper unit cell. The in-plane lattice constant of
the Co xFe100−xlayer is fixed at 2.84 Å, producing an in-
plane compressive strain of 5.2% and a corresponding
volume-conserving tetragonal distortion perpendicular to
the plane of the interface by approximately 4% on the MgO
layer. To achieve a reasonable resolution of Co composi-
tion in our study, we use an enlarged supercell containing
16 metal atoms per atomic layer of Co xFe100−x(4×4
units) and the [110] direction of MgO aligned with the
[100] direction in bcc Co xFe100−x[45]. The Co compo-
sition xin Co xFe100−xis varied from 0 to 50%, where
bcc Co xFe100−xis known to be stable [ 23]. We assume
an ordered alloy structure of Co xFe100−xconstructed by
replacing N(N=0, 2, 4, 5, 6, 7, or 8) Fe atoms per
atomic layer with Co atoms. The site of each subsequent
replacement of Fe with Co is chosen to form an arrange-
ment approximating an even distribution of Co and Fe
atoms in the Co xFe100−xmonolayers. The atomic arrange-
ment is maintained for each Co xFe100−xmonolayer in our
construction of the model.
Structural relaxations and total energy calculations are
performed using the pseudopotential plane-wave method
with the generalized gradient approximation [ 46] of the
exchange-correlation energy implemented in VASP [47,48].
A plane-wave basis set with a kinetic energy cutoff of
500 eV is used to expand the Kohn-Sham orbitals to obtain
reliable atomic coordinates. For the reciprocal space sam-
pling, a Monkhorst-Pack mesh of 3 ×3×3kpoints is used
for the Co xFe100−x/MgO supercell to maintain a k-point
spacing under 0.03 Å−1. The method of Methfessel-Paxton
is used to treat partial occupancies, with a smearing width
of 0.2 eV. The energy convergence threshold is 10−4eV
per unit cell in structural relaxation steps or 10−5eV
per unit cell for electronic structure optimization. After
structural relaxation, the stable Fe—O or Co—O bond
lengths are found to range from 2.14 to 2.19 Å, similar
to the values found in earlier calculations [ 49]. During
the analysis of superlattice density-of-states (DOS) pro-
files, the minimum DOS n(EF) at the Fermi surface and
magnetic moment for each atom is obtained. While the
two interfaces (MgO/Co xFe100−xand Co xFe100−x/MgO) in
the supercell can be magnetically inequivalent, their differ-
ences in the quantities that interest us, i.e., the calculated
magnetic moments, DOS, etc., are negligible. To simplify
the calculations we do not consider the W insert layer, and
we assume that no diffusion of W has taken place in the
(Co xFe1−x)80B20layer.
III. RESULTS AND DISCUSSION
Figures 2(a)–2(d) show the variations of MS,Heff
K,Keff,
and HC, respectively, as a function of (Co xFe1−x)80B20
024031-3S. SRIVASTAVA et al. PHYS. REV. APPLIED 10,024031 (2018)
0.0 0.2 0.4 0.6 0.8 1.00.00.20.40.60.8)eF+oC(/oC
Power ratio P2/(P1+P2) SIMS calculated composition
Nominal deposition composition
P1 – Power of Co20Fe60B20
P2 – Power of Co60Fe20B20
-30 -20 -10 0 10 20 30-1000-50005001000Magnetization(emu/cm3)
Magnetic field (kOe) Out-of-plane field
In-plane field
Slope fit-200 0 200-100001000MS cm3)/ume(
Magnetic field (Oe)Saturation field(a)
(c)(b)
(d)Co20Fe60B20(4 Å)MgO (13 Å)
Si/SiO2substrateTa (27 Å)
2.2 ÅRu (27 Å)
Ta (9 Å)
MgO (9 Å)
(CoxFe1-x)80B20(9Å)
(CoxFe1-x)80B20W buffer (4 Å)
(CoxFe1-x)80B20(13Å) FIG. 1. (a) Schematic diagram for
the film deposited. (b) Composition of
deposited samples versus the sputterpower. (c) TEM image of the cross
section of a film with composition
x=25% annealed at 400 °C for 30 min.
(d) In-plane and out-of-plane magnetic
hysteresis loops for a film with x=25%
annealed at 400 °C for 30 min. The insetshows a hysteresis loop in the low field
range.
composition for the samples annealed at 300, 400, and
450 °C, where xis the percentage mole fraction of
Co/(Co +Fe) in (Co xFe1−x)80B20. First, we discuss the
variation of magnetic properties with respect to annealing
temperature. In order to ensure annealing robustness, the
change in the magnetic properties of the free layer with
respect to annealing temperature should be minimum near
the annealing temperature of 400 °C. For all the composi-
tions, MSis stable for the annealing range of 300–400 °C
without significant deviation [Fig. 2(a)]. However, as we
increase the annealing temperature to 450 °C, MSincreases
significantly for all compositions. This increased value of
MSat a higher annealing temperature could arise from the
degradation of uniaxial anisotropy and an increase in the
contribution of cubic anisotropy [ 50–52]. From Fig. 2(b),
it is observed that the effect of annealing on Heff
Kis mini-
mal for x=35–42% in the annealing range of 300–400 °C,
and then Heff
Kdecreases drastically at 450 °C for all com-
positions. This decrease in Heff
Kat 450 °C annealing tem-
perature is also observed as a reduction in Keffat the
450 °C annealing temperature as shown in Fig. 2(c).T h e
decrease in Heff
Kand Keffat higher annealing temperatures
is consistent with earlier studies [ 53,54] and can again
be attributed to the degradation of interfacial (uniaxial)
anisotropy, as the higher annealing temperatures do not
affect bulk (cubic) anisotropy appreciably.
Some of the reasons for this degradation in uniaxial
anisotropy, which is responsible for PMA in our sys-
tem, at a high annealing temperature of 450 °C, include
the crystallization of (Co xFe1−x)80B20and overoxidation.A good interface is necessary to enable the hybridiza-
tion of 3 delectrons of Fe and 4 dor 5 delectrons of the
heavy-metal underlayer to obtain a high PMA [ 55–57].
However, a high temperature of 450 °C also causes an
enhancement of (Co xFe1−x)80B20crystallization and crys-
tal relaxation, which results in a detrimental effect on PMA
due to the decrease in (Co xFe1−x)80B20-MgO interfacial
strain [ 58,59]. Weakening of PMA is also attributed to
overoxidation of (Co xFe1−x)80B20[11]. Figure 2(d) shows
an improvement in the out-of-plane coercivity for the sam-
ples annealed at 450 °C, compared to the 300 and 400 °C
annealing cases. This increase in the out-of-plane coerciv-
ity at 450 °C can result from the enhanced (Co xFe1−x)80B20
crystallization at higher annealing temperature as reported
before [ 58,59], leading to a significant reduction in crys-
tal defects and dislocations. In our DBL PMTJ structure,when the annealing temperature is changed from 300 to
400 °C, there is limited change in M
S,Heff
K,and Kefffor
x=35–37.5% compared to other compositions. This indi-
cates that the compositions x=35–37.5% are more robust
in terms of annealing.
Next, we discuss the effect of variation of Co composi-
tion on the magnetic parameters MS,Heff
K,a n d Keff.F r o m
Fig. 2(a), it is observed that the MStrend as a function
of Co composition has a sharp minimum at x=37.5% for
all the annealing temperatures. This contradicts an earlier
report [ 17], in which the MSprofile shows a broad max-
imum at x∼40% in accordance with the Slater-Pauling
curve which is valid for bulk (cubic anisotropy) mag-
netic materials. Hence, our observation of a minimum at
024031-4EFFECT OF (Co xFe1−x)80B20COMPOSITION ON MTJ FREE LAYER. . . PHYS. REV. APPLIED 10,024031 (2018)
25 30 35 40 45 5003006009001200MS (emu/cm3)
Co/(Co+Fe) (%)300 °C
400 °C
450 °C
25 30 35 40 45 50-30369Heff
K )eOk(
Co/(Co+Fe) (%)300 °C
400 °C
450 °C
25 30 35 40 45 50-101234Keff cm3)/greM(
Co/(Co+Fe) (%)300 °C
400 °C
450 °C
25 30 35 40 45 50020406080100HC )eO(
Co/(Co+Fe) (%)300 °C
400 °C
450 °C(a)
(c)(b)
(d)FIG. 2. Composition dependence of
(a) magnetization ( MS), (b) saturation
field(Heff
K), (c) effective anisotropy
energy ( Keff), and (d) coercivity ( HC)
for the DBL PMTJ samples annealed
at 300, 400, and 450 °C for 30 min andmeasured at room temperature.
x=37.5% indicates that, for our thin films, the Slater-
Pauling curve is not suitable for explaining the MStrend
and more careful considerations of uniaxial anisotropy are
required, as we show later using VASP simulations. Further,
for the case of 400 and 450 °C annealing temperatures,
both Heff
Kand Keff, shown in Figs. 2(b) and2(c), respec-
tively, remain almost constant with a change in the Co
concentration up to x=37.5%, and then decrease with a
further increase in the Co concentration beyond x=37.5%.
The decrease in Heff
Kand Kefffor higher Co concentra-
tions arises due to the decrease in the out-of-plane orbital
moment because of the hybridization of Co xFe100−xand W
[19,57], as we discuss later in this section.
The effect of annealing on the Gilbert damping param-
eterαis studied using FMR. Figure 3(a) shows the
extracted αas a function of (Co xFe1−x)80B20composi-
tion for different annealing temperatures. For the sam-
ples annealed at 300 °C, αis almost independent with
respect to (Co xFe1−x)80B20composition, while the αpro-
file shows a minimum at x=35% for the annealing
temperatures of 400 °C and above. A similar profile of
αis also observed in the composition studies of the
metal/Co xFe100−x/metal system [ 22,23], where a minimum
inαis found at x∼25%. Similarly, in another study [ 60],
for the Ta/(Co xFe1−x)80B20/MgO system, a minimum in
αis found at x∼50% when studying only three com-
positions of x=25, 50 and 75%. In our case of DBL
MgO/(Co xFe1−x)80B20/W/(Co xFe1−x)80B20/MgO systems,
the minimum value of αoccurs at x=35%. The rea-
sons for this occurrence of minimum αatx=35% willbe discussed later in this section. Nevertheless, the find-
ing of this Co composition for the minimum value of
αis important for achieving low switching currents in
(Co xFe1−x)80B20/MgO-based DBL PMTJ devices. Further-
more, αshows a decreased value for all compositions
for the 450 °C annealing case, compared to the 300 and
400 °C cases, which suggests that the enhanced crys-
tallinity at a high annealing temperature of 450 °C reduces
the contribution of extrinsic factors to α. A similar depen-
dence of damping on the Co xFe100−xcrystallinity is also
observed in previous studies [ 39,61], where epitaxially
grown Co xFe100−xshows a smaller αthan polycrystalline
Co xFe100−x.
Figure 3(b) shows a local minimum in the product of
Keffandαat x=35% (for 400 °C annealing tempera-
ture), which is critical for achieving a low STT switching
current density ( JC∝ Keffα), while maintaining a high
value of Keff[62]. Even though x=46% shows a lower
value of the Keffαproduct compared to that of x=35%,
a very low Keffatx=46% [see Fig. 2(c)] is not ben-
eficial for thermal stability of the device. Figure 3(c)
shows the composition trend of the gfactor, calculated
using the equation [ 17],γ=gμB//planckover2pi1. As we increase the
annealing temperature, the gfactor decreases, but this
decrease becomes very prominent for Co compositions
above 37.5%. The gfactor can be used to calculate the
orbital and spin components of average magnetic moment
using the relations μL/μ S=(g−2)/2a n dμ=μS+μL,
where μLandμSare, respectively, the orbital and spin
components of the magnetic moment μ[63].μLis one
024031-5S. SRIVASTAVA et al. PHYS. REV. APPLIED 10,024031 (2018)
25 30 35 40 45 5001234×104(tcudorP Keff)
Co/(Co+Fe) (%)300 °C
400 °C
450 °C
25 30 35 40 45 500.0000.0050.0100.015(gnipmaD)
Co/(Co+Fe) (%)300 °C
400 °C
450 °C
25 30 35 40 45 502.002.052.102.152.202.25rotcafg
Co/(Co+Fe) (%)300 °C
400 °C
450 °C
25 30 35 40 45 500.000.020.040.060.08
Co/(Co+Fe) (%)(tnemomlatibrO)
02468
KU (Merg/ cm3)
Orbital moment (B)
Uniaxial anisotropy energy ( KU)(a)
(c)(b)
(d)FIG. 3. FMR results showing com-
position dependence of (a) damping α
for samples annealed at 300, 400, and450 °C for 30 min, (b) the product of
effective anisotropy energy K
effandα
for the samples annealed at 300, 400,and 450 °C for 30 min, and (c) gfac-
tor calculated using gyromagnetic ratio
for samples annealed at 300, 400, and450 °C for 30 min. (d) Comparison of
orbital moment and uniaxial anisotropy.
of the main factors in determining the spin-orbit coupling
(SOC) of the Co xFe100−x-W system [ 19,57], which, in
turn, is correlated with the uniaxial magnetic anisotropy,
KU[64,65]. Figure 3(d) shows the comparison of μLand
KU, where KU=Keff+2πMS2. It is noted that the dras-
tic decrease of μLafter 42% leads to a weakening of
SOC and thus, can be correlated to the decrease in KU
atx=46%.
Figure 4(a) shows the results of DOS calculations for
different compositions of Co xFe100−x/MgO superlattices,
and Fig. 4(b) shows the DOS calculated at the Fermi level,
n(EF), and its comparison with αfor the samples annealed
at 450 °C. We find that there is a minimum for n(EF)
between x=31.25 and x=37.5% [Fig. 4(b)], which arises
due to the shift of the DOS to the lower energies [as shown
in Fig. 4(a)] as Co concentration increases. In the literature,
for a metal/Co xFe100−x/metal system [ 23], this minimum
inn(EF) is observed at a Co composition of 25%. How-
ever, in our case, the introduction of an MgO interface
causes the minimum in n(EF) to shift to a Co compo-
sition in the range of 31.25–37.5%. This shift is due to
the presence of metal-oxygen bonds across the interface,
which divert a portion of the metallic electrons to localized
bonding states and decrease the conduction band-filling in
Co xFe100−x. In contrast, increasing the Co concentration
increases the filling of the conduction band in Co xFe100−x.
Therefore, a larger concentration of Co is needed to
achieve the minimum DOS for the interface model with
metal-oxygen bonds in comparison with bulk Co xFe100−x.
In the limit of intraband scattering, the damping param-
eter has been demonstrated to be largely proportional ton(EF)[23,66,67]. Therefore, the profile for n(EF) in the
MgO/Co xFe100−x/MgO structure is in close agreement to
our experimental observation of a minimum αatx=35%.
In order to ensure the program-retention capability of
the devices, it is important that the samples can maintaingood magnetic properties, that is, limited change in M
Sand
high/Delta1, at an elevated temperature up to 260 °C. Figures
5(a)–5(c) show the temperature dependence (measured at
60, 85, 125, 150, 175, 225, and 260 °C) of magnetic prop-
erties for each composition ( x)o f( C o xFe1−x)80B20samples
annealed at 400 °C. Figure 5(a) shows the temperature
variation of MSfor different compositions. It is observed
that x=42 and 46% show the highest MSvalues and small-
est rate of decrease in MSwith respect to temperature.
However, from Fig. 5(b), it is observed that x=35% main-
tains the highest Heff
Kvalues and the lowest rate of decrease
ofHeff
Kwith respect to temperature .The trend of Heff
Kis
also reflected in the trend of Keffas shown in Fig. 5(c),
in which it is observed that x=35% has the highest Keff
values for higher temperatures. Since a high Keffvalue
is important for a high /Delta1,x=35% is a good candidate
from a thermal stability perspective for sustaining solder-
reflow processes at 260 °C. Furthermore, for our DBL
PMTJ structure with the free-layer thickness of 2.6 nm, the
calculated thermal-stability factor for x=35% at 260 °C
is approximately 60 (assuming a 50 nm diameter), which
is enough for embedded MRAM applications [ 12]. Subse-
quently, we fit the temperature-dependent magnetization,
using Kuz’min’s model given by Eq. (1), to calculate the
value of ASfor different Co compositions as shown in Fig.
5(d). The value of ASshows a maximum at x=37.5%. As
024031-6EFFECT OF (Co xFe1−x)80B20COMPOSITION ON MTJ FREE LAYER. . . PHYS. REV. APPLIED 10,024031 (2018)
-0.2 -0.1 0.0 0.1 0.205101520
37.5%n(E) (eV-1)
50% 31.25% 25%
43.75%
25 30 35 40 45 509101112n(EF) (Simulation)
Damping (Experimental)
Co/(Co+Fe) (%)n(EF) (eV-1)
0.0040.0060.0080.0100.012
Damping ( )(a) (b) FIG. 4. DOS calculation and com-
parison with measured damping val-
ues. (a) DOS calculation results forCo
xFe100−x/MgO for different Co
compositions. (b) Majority DOS at
the Fermi level n(EF) and damping
αobtained from FMR plotted as a
function of xfor 450 °C annealed
samples.
the domain-wall width δwis proportional to√AS, this com-
position can be beneficial for uniform coherent switching
for larger diameter devices.
We analyze the temperature-dependent MSand Keff
data using the Callen-Callen law, MS(T)/MS(0)=
(Keff(T)/Keff(0))m, in which mshould be 3 for uniaxial
anisotropy and 10 for cubic anisotropy [ 68,69]. Figure
6(a) shows the composition dependence of mfor the
400 °C annealed samples. The obtained values of mvary
in the range of 3–10, which arises due to the combined
contributions of both uniaxial and cubic anisotropies.
Since there is no direct way to find the ratio of the sites
with uniaxial and cubic anisotropy, we assume wto be the
weighting of the uniaxial contribution to the anisotropy
and the factor mto be weighted between 3 and 10 (m=
w×3+(1−w)×10). We assume that this weight wis
the ratio of the sites with uniaxial anisotropy and use thisfactor to calculate the average moment per atom, ma, using
the equation
ma=mu×w+mc×(1−w),( 2 )
where muis the moment per atom at the sites contributing
to the uniaxial anisotropy and mcis the moment per atom
at the sites contributing to the cubic anisotropy.
For different Co compositions, the cubic contribution
mccan be extracted from the Slater-Pauling curve for
Co xFe100−x[70]. In order to obtain the uniaxial con-
tribution mu, we performed VASP simulations for the
Co xFe100−x/MgO system at different Co concentrations.
For the uniaxial Co xFe100−x/MgO system, the magnetic
moments of Co and Fe delectrons are found to be in par-
allel directions and are the prime contributors to the net
magnetic moment per atom for both species. Switching
0 50 100 150 200 250 30002468Heff
K (kOe)
Temperature (°C)25%
32%
35%
37.5%
42%
46%
25 30 35 40 45 500123
25 °C 60 °C 85 °C
105 °C 125 °C 150 °C
175 °C 225 °C 260 °CKeff )cm3/greM(
Co/(Co+Fe) (%)25 30 35 40 45 500246810)m/Jp(ssenffitsegnahcxE
Co/(Co+Fe) (%)(a)
(c)(b)
(d)0 50 100 150 200 250 30002004006008001000 MS /cm3) ume(
Temperature (°C)25%
32%
35%
37.5%
42%
46%FIG. 5. Temperature dependence of
(a) magnetization and (b) anisotropy
field for different Co compositions. (c)
Anisotropy energy dependence on Cocomposition at different temperatures.
(d) Exchange stiffness plotted as a
function of Co composition. Samplesannealed at 400 °C for 30 min.
024031-7S. SRIVASTAVA et al. PHYS. REV. APPLIED 10,024031 (2018)
25 30 35 40 45 50246810m )walnellaC-nellaC(
Co/(Co+Fe) (%)Cubic anisotropy
Uniaxial anisotropy
0 1 02 03 04 05 01.21.62.02.42.8(mota/tnemoM)
Co/(Co+Fe) (%)Fe – Interface
Fe – 1 away
Fe – 2 away
Co – Interface
Co – 1 away
Co – 2 away
0 1 02 03 04 05 02.02.12.22.32.42.5(mota/tnemoM)
Co/(Co+Fe) (%) Slater-Pauling ( mc)
Simulation ( mu)
25 30 35 40 45 50700800900ma (Simulation)
MS (Experimental)
Co/(Co+Fe) (%)MS cm3)/ume(
2.22.32.4
Moment/atom ( )(a)
(c)(b)
(d)FIG. 6. (a) Dependence of mon com-
position for 400 °C annealed samples.
(b)VASP simulation results for magnetic
moment per atom of Co and Fe lay-
ers at different positions with respect to
MgO. (c) Comparison of the moment peratom from the Slater-Pauling curve and
the average moment per atom calculated
for the PMA system. (d) Comparison ofmagnetization from VSM measurement
and average magnetic moment per atom
calculated using Eq. (2). The simulation
curves in (b), (c), and (d) are fitted using
splines.
the magnetization direction out of or into the MgO layer
is found to have a negligible effect on the absolute value of
the magnetization per atom. Figure 6(b) shows the contri-
butions of individual Co and Fe atoms to the magnetization
obtained from the simulations at different positions with
respect to the MgO interface. The contribution of moment
from each Co atom is less than that from each Fe atom,
which leads to a net decrease in mu[blue line in Fig. 6(c)]
as the composition of Co increases from 0 to 50%. This
agrees with Madelung’s rule of the ordering of spins in
atomic subshells [ 71]. Interestingly, as Co is introduced
into the system, the magnetic moment per Co atom rises,
showing a peak at x∼24%, then decreases sharply again
in Fig. 6(b). Increasing the Co content higher than x=30%
does not affect the atomic magnetic moment of Co further.
From Fig. 6(b), it is also observed that the presence of the
MgO interface enhances the magnetic moment per atom in
the case of Fe and suppresses it in the case of Co [ 11].
Figure 6(c) shows the calculated values of mufor the
PMA (interfacial) system that are fitted with spline curves
to interpolate the intermediate values from the simulation.
Figure 6(c)also shows mcobtained from the Slater-Pauling
(cubic) curve [ 70]. Subsequently, the values of muand
mcare used to calculate the average magnetic moment
per atom, mausing Eq. (2). Figure 6(d) shows the calcu-
lated values of mafor different Co compositions. Figure
6(d) also shows the trend of the saturation magnetization
(MS) obtained from VSM for 400 °C annealed samples.
It is observed that both maand MSshow a very close
relationship in terms of Co concentrations, which con-
firms that the observed trend of MSwith Co composition
is due to the transition from uniaxial anisotropy to cubicanisotropy with increasing Co concentration. Moreover,
this close relationship of maand MSsuggests that, for the
case of ultrathin films with a MgO interface, the tradi-
tionally used Slater-Pauling curve is not suitable, and it
is necessary to consider the contributions of both uniaxial
and cubic anisotropies as well as their dependence on com-
position for magnetization calculations. Furthermore, the
uniaxial anisotropy can be indicative of a better hybridiza-
tion between Fe and O, resulting in higher /Delta11symmetry,
which can be useful in determining materials with a high
TMR in DBL PMTJs [ 72].
IV. CONCLUSIONS
We study the (Co xFe1−x)80B20composition dependence
of magnetic properties of the free layer in a double-barrier
PMTJ. We investigate the annealing robustness of our
system, with the range of Co composition x=35–37.5%
showing the least deviation in the magnetization and
anisotropy energy with respect to annealing temperature.
We also extract the orbital angular moment that explains
the profile for Keffwith respect to Co composition. The
composition dependence of the damping parameter reveals
that a low critical current density for STT switching is
achievable for x=35%. The analysis of the magnetic prop-
erties at elevated temperatures demonstrates that a high
thermal stability at elevated temperature can be achieved
atx=35%. Further, we identify that the exchange stiff-
ness maximizes at x=37.5%, which is indicative that this
composition supports a larger diameter size for coherent
uniform switching. Using the Callen-Callen law, we iden-
tify that the anisotropy of our system transits from uniaxial
024031-8EFFECT OF (Co xFe1−x)80B20COMPOSITION ON MTJ FREE LAYER. . . PHYS. REV. APPLIED 10,024031 (2018)
to cubic as Co concentration increases. This transition from
uniaxial to cubic anisotropy is used to explain the anoma-
lous dip in the magnetization. Our analysis lays down a
platform to develop material systems for double-barrier
PMTJs.
ACKNOWLEDGMENTS
This research is supported by an NRF Industry–IHL
Partnership (IIP) grant R-263-000-C26-281. We thank Ms.
Doreen Lai Mei Ying from IMRE for TOF SIMS charac-
terization.
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024031-11 |
PhysRevApplied.13.064050.pdf | PHYSICAL REVIEW APPLIED 13,064050 (2020)
Laser-Induced Abnormal Cryogenic Magnetoresistance Effect in a Corbino Disk
Xinyuan Dong,1,2Diyuan Zheng,1,2Meng Yuan,1,2Yiru Niu,1,2Binbin Liu,1,2and Hui Wang1,2,*
1State Key Laboratory of Advanced Optical Communication Systems and Networks, School of Physics and
Astronomy, Shanghai Jiao Tong University, 800 Dongchuan Road, Shanghai 200240, People’s Republic of China
2Key Laboratory for Thin Film and Microfabrication Technology of the Ministry of Education, Research Institute
of Micro/Nano Science and Technology, Shanghai Jiao Tong University, 800 Dongchuan Road,
Shanghai 200240, People’s Republic of China
(Received 7 September 2019; revised manuscript received 27 April 2020; accepted 1 June 2020; published 19 June 2020)
The geometric magnetoresistance effect in semiconductors has remained a heated discussion for many
years. However, there are few reports on laser-triggered geometric magnetoresistance in traditional struc-tures. In this work, we use a laser to change the carrier concentration to obtain a large magnetoresistance
(212.6%) under a low magnetic field (1 T) at 150 K in a Corbino disk with Co-Ag films. One unantici-
pated finding is that the large positive magnetoresistance does not change monotonously with temperature,which is different from previous research. Theoretical calculation reveals that the interaction among a pho-
togenerated carrier, bending of the current path, and magnetic nanoparticles in low temperature improves
the magnetoresistance in a Corbino disk. These findings reveal an important strategy for creating laser-trigged nanoscale magnetoresistance devices, while presenting a wide range of possibilities for exploring
the dependence of photogenerated carriers on temperature under magnetic field.
DOI: 10.1103/PhysRevApplied.13.064050
I. INTRODUCTION
The geometric magnetoresistance (MR) effect [ 1,2]i n
nanoscale films has attracted increasing research attention
since its discovery [ 3,4], which is widely used in accurate
measurement of carrier concentration [ 5–7], evaluation of
transferred electron device performance [ 8], high magnetic
field sensors [ 9], current sensors [ 10], and other fields
[11]. A Corbino disk is a quintessential structure to inves-
tigate the geometric magnetoresistance effect thoroughly
since it can eliminate Hall voltage. Considerable research
efforts have been devoted to explain the underlying mech-
anism of the geometric magnetoresistance effect, which
can be attributed to the bending of the current path and
uneven carrier distribution [ 12–14]. However, using a laser
to change the carrier concentration and mobility is rarely
involved in these studies. Moreover, relatively little atten-
tion has been paid to the temperature dependence of the
effect, despite its importance for the selection of mech-
anisms and the development of a microscopic theory of
geometric magnetoresistance.
Previously, our group reported a large laser-triggered
positive magnetoresistance in a Corbino disk of Cu/SiO 2/
Si [15]. With the combined application of laser and mag-
netic field, the magnetoresistance is significantly improved
by more than 60 times compared with other research
*huiwang@sjtu.edu.cn[16,17] at the same magnetic field (1 T). On the basis
of our previous research, this work investigates the
laser-triggered geometric magnetoresistance effect in Co-
Ag films, especially to further explore the temperature
response of this effect. Thin films consisting of cobalt
nanoparticles embedded in a silver matrix are attractive
for magnetoresistive research. The phase diagram indi-
cates there is very limited mutual solubility of Co with
Ag, which offers the possibility of heterogeneity [ 18,19].
Experimental results show the laser-triggered magnetore-
sistance of Co-Ag films can reach 212.6% and 8.2% at
150 K and room temperature under a magnetic field of
1 T, respectively. The magnetoresistance is significantly
enhanced compared with previous studies under the same
circumstances (1 T magnetic field) [ 12,15,18,20]. We also
notice, most surprisingly, that the magnetoresistance does
not change monotonously with temperature, unlike the
monotonous rise in magnetoresistance of granular films
caused by scattering with a decreasing temperature [ 19].
This research extends the knowledge into the geometric
magnetoresistance mechanisms induced by laser and tem-
perature, while opening the door to the possibilities in
temperature sensors and magnetoresistance devices.
II. FABRICATION AND METHODS
We fabricate Co-Ag composite films on the doped
n-type Si (111) wafers (approximately 0.3 mm thickness,
20–50 /Omega1cm resistivity) with a native ultrathin oxide layer
2331-7019/20/13(6)/064050(8) 064050-1 © 2020 American Physical SocietyXINYUAN DONG et al. PHYS. REV. APPLIED 13,064050 (2020)
approximately 1.2 nm thick on one side. Co-Ag films are
deposited by co-sputtering of Co and Ag targets (purity
better than 99.9%) using dc magnetron sputtering from
two confocal sputter magnetron guns at room tempera-
ture. The whole sputtering process is in an argon pressure
of 0.78 Pa, and the base pressure of the vacuum system
is better than 3.8 ×10−4Pa. The dc power of cobalt and
silver is fixed at 10 and 20 W, respectively. The depo-
sition rate is 3.2 Å s−1, which is determined by the step
profiler on thick calibration samples fabricated under the
same condition. A ring-shape mask is utilized to deposit
the film. First, the ring groove is covered by the mask and
deposited for 145 s. Then, the mask is removed, and the
whole part is deposited for 5 s. Counting with the depo-
sition rate, the electrode layer of 48 nm Co-Ag alloy is
deposited on center and peripheral areas of the Si substrate,
as annotated in Fig. 1(a). The annular region between two
electrodes is 1.6 nm (nominal thickness) superthin Co-Ag
composite films. We switch the dc power of the Co target to
regulate the content of cobalt in the samples. The compo-
sitional distribution of the alloy film is further investigated
by energy dispersive spectroscopy (EDS).
Figure 1(a) shows a representative schematic diagram
of a Corbino disk, where rais the radius of center region
and rbis the outer radius of the ring. The width of thering groove is defined as rb−ra. During the experiment,
the ring width of all samples is maintained at 1.5 mm.
Electrodes A and B of alloying indium (less than 1 mm
in diameter) are pressed on the central and peripheral
bulk Co-Ag areas, respectively. Figures 1(b) and 1(c)
show SEM images of the two different regions, and the
inset shows the corresponding EDS spectra. SEM images
recorded at high magnification clearly show that the as-
deposited films consist of a bulk region with uniform
shapes [Fig. 1(b)] and nanoparticles [Fig. 1(c)].
In the experimental process, electrode A is irradiated by
a 635-nm, 3-mW laser focused on a roughly 50- µm diam-
eter spot continuously, and without any background light
illumination. We measure the magnetoresistance using the
two-probe method in a vacuum cavity with a pressure of
1.0×10−4Pa, and the chamber temperature ranged from
20 to 300 K in the presence of a magnetic field in the z-
axis direction varying up to 1 T. The chamber temperature
is regulated by helium compressors and a temperature con-
troller, and the resistance is determined using the Keithley
4200-SCS Semiconductor Characterization System. The
magnetoresistance is defined as
/Delta1R/R0=[(RH−R0)/R0]×100%. (1)
(3 mm)(1.5 mm)(a)
(b) (c)FIG. 1. (a) Schematic diagram of
Corbino structure with Co-Ag/SiO 2/Si
and the experimental measurement
method. (b) SEM image of the bulk Co-Ag layer. Inset shows the corresponding
EDS spectra. (c) SEM image of the
annular groove region where superthinCo-Ag films are deposited.
064050-2LASER-INDUCED ABNORMAL . . . PHYS. REV. APPLIED 13,064050 (2020)
Here, RHrepresents the resistance with the external mag-
netic field applied, and R0is the resistance in the absence
of magnetic field.
III. RESULTS AND DISCUSSION
Figure 2(a) shows the I-Vcurves of the Co-Ag/SiO 2/Si
sample between electrode A and B under different condi-
tions at 20 K (equipment limit). We define the forward-
sweep voltage to represent the case where electrode A is
the anode and B is the cathode. The original I-Vcurve
(i.e., without laser irradiated and magnetic field applied)
is symmetrical, and the sample is in a high-resistance
state. However, when a fixed 635-nm laser is applied
perpendicularly to electrode A, the resistance is signifi-
cantly reduced. Most surprisingly, the I-Vcurve exhibited
extreme asymmetry, which suggested a laser-induced polar
resistance effect. This bipolar resistance effect has been
reported in our previous research, which can be attributed
to diffusion and scattering of carriers based on Schottkybarriers [ 15]. On this basis, we apply a 1-T magnetic field
perpendicular to the sample, the I-Vcharacteristic as indi-
cated by the blue line in Fig. 2(a). The resistance of the
sample increases observably under the combined effect of
laser and magnetic field. Nevertheless, when the laser is
removed, the I-Vcharacteristic is almost the same as the
original curve. From the results we can conclude that the
laser plays an indispensable role in the effect.
In order to further investigate the effect of temperature
and magnetic field on magnetoresistance, we fix the laser
position and change the ambient temperature, and mea-
sure the magnetoresistance under different magnetic fields.
The MR values are calculated by Eq. (1). Figure 2(b)
shows MR data of the Co-Ag/SiO 2/Si sample versus mag-
netic field for various temperatures. As the magnetic field
increases, the MR value is drastically promoted, which is
in consonance with the work we have reported before [ 15].
Besides, the magnetoresistance in a Corbino disk struc-
ture presents excellent symmetry to the direction of applied
magnetic field. As for temperature dependence, the MR
(a) (b)
(c) (d)
FIG. 2. (a) I-Vcurves of the Co-Ag/SiO 2/Si sample with different laser and magnetic field conditions. The ambient temperature
is set to 20 K, and measurement details are shown in the inset. A fixed 635-nm, 3-mW laser on a roughly 50- µm diameter spot
perpendicular to electrode A. (b) MR ratio of the Co-Ag/SiO 2/Si sample as a function of magnetic field at different temperatures.
(c) The Co-Ag/SiO 2/Si sample’s MR ratio versus cobalt content as a function of temperature. The applied magnetic field is fixed at
1 T and the measurement condition is identical to before. (d) The dependence of the Co-Ag/SiO 2/Si sample’s MR on temperature with
different laser conditions. The measurement condition is the same compared to before (with a 1-T magnetic field and 635-nm laser
applied).
064050-3XINYUAN DONG et al. PHYS. REV. APPLIED 13,064050 (2020)
values increase with the increasing temperature and grow
up to the maximum when the temperature is 150 K, and
then decrease sharply above 170 K. We obtain a large
magnetoresistance of 212.6% at 150 K, only 1-T magnetic
field, which is comparable to other research.
To gain deeper insight related to the laser-triggered MR
effect in Co-Ag films, a systematic study has been carried
out in Co-Ag/SiO 2/Si samples with cobalt content varying
from 3.01% to 26.53%. The cobalt content is governed by
sputtering time and power, and determined by energy dis-
persive spectroscopy. We prepare samples with the same
nominal Co-Ag thickness but different cobalt contents.
During the experiment, the applied magnetic field is fixed
at 1 T and the samples are irradiated by a 635-nm laser con-
tinuously. A clear dependence of MR on the cobalt content
is observed [Fig. 2(c)]. The same general trend is found
at different temperatures: the MR value increases with the
cobalt content up to a maximum and then drops off with
the higher cobalt content.
As is widely known, a laser may cause the temperature
change in the place of irradiation, and further leading to the
apparition of temperature gradients. In order to eliminate
the possibility that the local temperature change caused
by a laser contributes to the magnetoresistance, we mea-
sure the dependence of MR on temperature with different
laser conditions in a 1-T magnetic field. As annotated in
Fig.2(d), MR values present the same tendency with tem-
perature changes under different illumination conditions.
When the temperature is below 150 K, the magnetoresis-
tance increases slowly with temperature. With temperature
increasing from 150 to 200 K, the magnetoresistance value
is drastically reduced. Once the temperature is greater than
200 K, the magnetoresistance decreases very slowly with
increasing temperature. Besides, the MR effect with 1550-
nm laser irradiation almost has no change compared with
the case with no laser irradiation, but it is greatly enhanced
with 635-nm laser irradiation, indicating the local temper-
ature change caused by the laser does not contribute to the
magnetoresistance effect.
The influence of magnetic materials on magnetoresis-
tance is non-negligible. To further investigate the mag-
netism of samples, magnetic hysteresis, the field cooled
(FC), and the zero field cooled (ZFC) are employed.
Figure 3(a) shows the full hysteresis loops of the mag-
netization measured at room temperature on the Co-Ag
(nominal thickness, 1.6 nm, and 13.27% Co) sample for
parallel ( ||) and perpendicular ( ⊥) to film plane orienta-
tions of the applied magnetic field. The inset shows the
enlarged image of the M-Hcurve corresponding to H
perpendicular ( ⊥) to the film, and the sample exhibits
negligible coercivity force (16.8 Oe). It is found that thetwo M-Hcurves could not reach saturation even at the
maximum magnetic field of 1.5 T, which clearly indicates
the presence of superparamagnetic particles [ 21]. And the
easy axis of the nanoparticles is out of plane. To confirmthe superparamagnetic behavior, we measure the ZFC and
FC data in the temperature range 2–400 K, as shown in
Fig.3(b). For samples with 13.27% Co, the M
ZFC(T) curve
exhibits the maximum at TB∼170 K, while the MFC(T)
curve decreases monotonously with the increasing temper-
ature. Such magnetic properties indicate the superparam-
agnetic character of the Co nanoparticles in our samples
[22]. Besides, the blocking temperature in the sample with
13.27% Co is larger than the sample with 8.22% Co, which
suggests the increase in particle size. Moreover, the FC
curves suggest the absence of cobalt oxide. Because CoO
is antiferromagnetic, the magnetization of FC curve will
exhibit a sharp drop above the Neel temperature of 290 K.
However, this is not observed in our samples.
Magnetic measurements of the samples are carried out to
determine whether the Co-Ag materials contribute greatly
to magnetoresistance. Figure 3(c) shows the MR ratio as
a function of temperature in Co-Ag/SiO 2/Si with ordinary
structure (without Corbino geometry). The nominal thick-
ness of Co-Ag film is fixed at 1.6 nm, which is the same
as the thickness in a Corbino disk. And the content of
cobalt is 13.27%. As can be seen in Fig. 3(c), the magne-
toresistance values are quite small in the absence of laser,
and the temperature dependence of MR is consistent with
previous researches [ 19,23]. However, the magnetoresis-
tance is considerably improved when the laser is applied.
And the temperature dependence is completely different
from that without laser. With the temperature increasing
from 20 to 170 K, the laser-triggered MR declines slowly.
Once the temperature is higher than 170 K, the laser-
triggered MR ratio decreases sharply until 230 K. Obvi-
ously, the magnetic material has a certain contribution to
the magnetoresistance below TB(170 K), but it makes lit-
tle contribution once the temperature is higher than TB.W e
think these results can be attributed to the transition from
ferromagnetism to superparamagnetism, which involves a
transition from ordered to disordered orientations of the
electron spins. The neighboring islands tend to be parallel
aligned by the external field and reduce the resistance in the
absence of laser, thereby, the negative magnetoresistance.
But when the laser is applied, the photogenerated carriers
play a vital role in the magnetoresistance. In the diffusion
process of carriers, electrons in Co-Ag also may recombine
with holes in silicon. And the carrier recombination rate
is affected by scattering. When the temperature is below
TB, the particles exhibit ferromagnetism. Under the applied
magnetic field, the spin-dependent scattering of conducting
electrons contribute to the increase of photogenerated car-
rier recombination rate, thereby, the increased resistance
and positive magnetoresistance. But when the temperature
is higher than TB, the thermal energy can disrupt the mag-
netic moment, thereby weakening the magnetism, which
contributes little to the magnetoresistance.
For comparison, we also measure the temperature
dependence of laser-triggered MR in Corbino disks with
064050-4LASER-INDUCED ABNORMAL . . . PHYS. REV. APPLIED 13,064050 (2020)
(a) (b)
(c) (d)
FIG. 3. (a) M-Hhysteresis loops corresponding to Hparallel ( ||) and perpendicular ( ⊥) to film measured at room temperature for
the Co-Ag (nominal thickness, 1.6 nm, and 13.27% Co) sample. (b) Temperature dependence of magnetization in Co-Ag samples
with different Co contents, in the ZFC and FC protocols in the presence of magnetic field of 100 Oe. (c) The MR ratio as a function
of temperature in Co-Ag/SiO 2/Si with ordinary structure (without Corbino geometry). The nominal thickness of the Co-Ag film is
1.6 nm and the content of cobalt is 13.27%. The inset shows the measurement method. (d) Dependence of laser-triggered MR ratio on
temperature with nonmagnetic materials in Corbino disks. The width of the ring groove is fixed at 1.5 mm, and the thickness of metalkept consistent.
nonmagnetic materials, as shown in Fig. 3(d). Both of the
samples show similar nonmonotonic temperature depen-
dence. Compared with the magnetoresistance in magnetic
materials shown in Fig. 2(d), there is a striking difference
when the temperature is quite low. The magnetoresis-
tance in magnetic materials is much larger than that in
nonmagnetic materials.
To explain these phenomena, we propose a model based
on the Schottky barrier. The samples contain bulk Co-
Ag layers and superthin films, and the Schottky barrier is
much lower in the annular groove region, which covered
by superthin films [ 15]. Therefore, the equivalent circuit
can be considered as two reverse diodes and a pure resis-
tor, as indicated in Fig. 4(left). Obviously, the system is in
a high-resistance state without laser irradiation. When the
laser is applied, a large amount of photogenerated carriers
are generated in the silicon substrate. There was a high car-
rier concentration at the laser spot, so carriers diffuse to the
surrounding. [ 24–26] And photogenerated electrons havethe opportunity to tunnel into the alloy layer. The applica-
tion of magnetic field brought on the deflection of a carrier
motion path under Lorentz force, thereby, the increased
resistance (Fig. 4, right).
If we suppose the initial resistivity without a laser and
magnetic field is ρ0, the resistance at position x(i.e., the
distance from the laser spot) can be written as [ 27,28]
ρ(x)≈ρ0/parenleftbigg
1−n0
N0+n0
N0λx/parenrightbigg
.( 2 )
Hereλis the diffusion length, n0and N0represent the den-
sity of laser-induced electrons and drift carriers at the laser
spot, respectively.
In previous research, we have derived the current path
formula under the applied magnetic field, which can be
written as [ 15,29]
s=αx,( 3 )
064050-5XINYUAN DONG et al. PHYS. REV. APPLIED 13,064050 (2020)
FIG. 4. Schematic diagram of
photogenerated carriers’ move-
ment only laser irradiated (left).The carriers’ motion path with the
combined effect of laser and mag-
netic field (right).
here,
α=/radicalbigg
1+μ2H2
c2,( 4 )
andμis the carrier mobility, His the density of magnetic
field, and cis a constant in the Gauss unit system. We find
that the new parameter αcharacterizes the current path
change caused by magnetic field in the Corbino disk. More
simply, αcharacterizes the extent of motion-path bending.
Note that a laser is a prerequisite in the experiment. R0rep-
resents the resistance with laser irradiation only, and it can
be written as a path integral of ρ(x):
R0=/integraldisplayrb
raρ(x)dx.( 5 )
However, when the magnetic field is applied, the current
path changed, thereby, the resistivity at different positions.
RH=/integraldisplayrb
raρ(s)ds=α/integraldisplayrb
raρ(α x)dx.( 6 )
Finally, the laser-triggered magnetoresistance can be writ-
ten as
/Delta1R/R0≈α+(α2−α)
1+kλ/parenleftBig
N0
n0−1/parenrightBig.( 7 )
Here k=1/(ra+rb)is a constant. From Eq. (7), we can
see the temperature Thas an influence on three parameters:
λ,N0/n0,a n dα. The diffusion length λcan be written as
[26,30]
λ=√
Dτ∝T−1,( 8 )
where Dis diffusion coefficient affected by temperature.
And according to the Boltzmann distribution function, thecarrier concentration satisfies
N0
n0∝e−EC−EF
k0T∝e−1
T.( 9 )
The parameter α, which measures the current path change
caused by magnetic field described in Eq. (4), can be sim-
plified as α∝μ. Here, μis the mobility, which can be
written as [ 17]
μ=qτ
m∗. (10)
Here m∗andτare the effective mass and lifetime of the
carrier, respectively. Hence, the MR can be simplified as
/Delta1R/R0∝μ(T)/braceleftbigg
1+[μ(T)−1]T
e−1/T/bracerightbigg
. (11)
Here, e−1/Tapproaches a constant as temperature
increases. Therefore, we mainly take the mobility μinto
consideration. The scattering processes influence the life-
time, thereby, limiting the mobility. Due to the large carrier
density, the thermal vibration of the lattice has a non-
negligible influence on the mobility even at low tempera-
ture. Therefore, the ionized impurity scattering dominates
at low temperatures, where μ∝T3/2. Apparently, the mag-
netoresistance increases with the increasing temperature.
But as the temperature further rises, the lattice vibration
scattering dominates, which satisfies μ∝T−3/2[17]. As
a result, the magnetoresistance decreases. Similar tem-
perature dependence of magnetoresistance (without laser
irradiation) in a Corbino disk has been reported in previous
research [ 17]. According to the above analysis, we con-
clude that the nonmonotonic temperature dependence of
magnetoresistance is mainly due to the change of mobility
in Corbino structure. And the laser plays a significant role
in generating photogenerated carriers and amplifying mag-
netoresistance. Under the influence of these factors, themagnetoresistance grows monotonously up to maximum,
above which it precipitously decreases.
Besides, taking into account the contribution of mag-
netic nanoparticles below the blocking temperature T
B,
064050-6LASER-INDUCED ABNORMAL . . . PHYS. REV. APPLIED 13,064050 (2020)
the recombination rate of photogenerated carriers increases
due to the spin-dependent scattering. As a result, the diffu-
sion length λdecreases. According to Eq. (7), the magne-
toresistance is enhanced below TB, which also explains the
reason why the MR effect in magnetic particles is better
than nonmagnetic at low temperatures.
As for the cobalt content dependence of MR shown
in Fig. 2(c), it can be attributed to changes in parti-
cle size. When the concentration of magnetic particles
is small, there is less scattering and larger particle spac-
ing, which leads to the small magnetoresistance. There-
fore, as the cobalt content is increased, the MR effect
is improved. However, as indicated in Fig. 3(b),TB
increases with increasing cobalt content, which suggests
the increase in particle size. As the particles grow larger,
the surface:volume ratio decreases, which weaken the
spin-dependent scattering of conducting electrons [ 19,31].
As a result, the photogenerated carrier recombination rate
decreases, thereby, the magnetoresistance is reduced.
IV. CONCLUSION
In conclusion, we obtain a colossal magnetoresistance
effect using a simple laser-triggered method in Corbino
disks with Co-Ag films. The temperature dependence of
the laser-triggered magnetoresistance effect is investigated
in the temperature range from 20 to 300 K. What is surpris-
ing is that the dependence of the MR ratio on temperature
is nonmonotonic. Moreover, the MR effect is closely asso-
ciated with the elemental component of samples. We show
that the Corbino geometry, diffusion length, and magnetic
nanoparticles contribute to the magnetoresistance. This
work expands the possibility of design for laser-trigged
and temperature-regulated magnetoresistance devices.
ACKNOWLEDGMENTS
We acknowledge the financial support of the National
Natural Science Foundation of China under Grants
No. 11874041, No. 61574090, No. 11374214, and
No. 10974135.
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064050-8 |
PhysRevB.92.104430.pdf | PHYSICAL REVIEW B 92, 104430 (2015)
Respective influence of in-plane and out-of-plane spin-transfer torques in magnetization switching
of perpendicular magnetic tunnel junctions
A. A. Timopheev, R. Sousa, M. Chshiev, L. D. Buda-Prejbeanu, and B. Dieny
Univ. Grenoble Alpes, INAC-SPINTEC, F-38000 Grenoble, France;
CEA, INAC-SPINTEC, F-38000 Grenoble, France;
CNRS, SPINTEC, F-38000 Grenoble, France
(Received 3 June 2015; revised manuscript received 26 August 2015; published 28 September 2015)
The relative contributions of in-plane (damping-like) and out-of-plane (field-like) spin-transfer torques (STT) in
the magnetization switching of out-of-plane magnetized magnetic tunnel junctions (pMTJ) has been theoreticallyanalyzed using the transformed Landau-Lifshitz-Gilbert (LLG) equation with the STT terms. It is demonstratedthat in a pMTJ structure obeying macrospin dynamics, the out-of-plane torque influences the precession frequency,but it does not contribute significantly to the STT switching process (in particular to the switching time andswitching current density), which is mostly determined by the in-plane STT contribution. This conclusion isconfirmed by finite temperature and finite writing pulse macrospin simulations of the current field switchingdiagrams. It contrasts with the case of STT switching in in-plane magnetized magnetic tunnel junction (MTJ) inwhich the field-like term also influences the switching critical current. This theoretical analysis was successfullyapplied to the interpretation of voltage field STT switching diagrams experimentally measured on pMTJ pillars36 nm in diameter, which exhibit macrospin behavior. The physical nonequivalence of Landau and Gilbertdissipation terms in the presence of STT-induced dynamics is also discussed.
DOI: 10.1103/PhysRevB.92.104430 PACS number(s): 85 .75.−d,75.78.−n,85.70.Ay
I. INTRODUCTION
Fully perpendicular magnetic tunnel junctions (pMTJ)
constitute the storage element of spin-transfer torque magne-toresistive random access memory (STT-MRAM) [ 1–6]. STT-
MRAMs are very promising emerging nonvolatile memoriessince they combine nonvolatility, low energy consumption,high thermal stability, and almost unlimited endurance. Thestrongest research and development efforts are nowadaysfocused on out-of-plane magnetized MgO-based MTJs. In-deed, the latter combine several advantages. They exhibit ahigh tunnel magnetoresistance effect [ 7] amplitude due to a
very efficient spin-filtering phenomenon associated with thesymmetry of the tunneling electron wave function [ 8,9]. Fur-
thermore, they present a very large perpendicular anisotropyat the interface between the magnetic electrode and the MgOoxide barrier (Ks ∼1.4 erg /cm²)[10], which allows the
storage layer magnetization to achieve a quite high thermalstability and therefore long memory retention. Additionally,a remarkable property of this interfacial anisotropy is thatit exists in materials having weak spin-orbit coupling andtherefore relatively low Gilbert damping α(α< 0.01). This
is very important in STT-MRAM since the critical current forSTT-induced switching [ 11,12] of storage layer magnetization
is directly proportional to the Gilbert damping. The advantageof using out-of-plane rather than in-plane magnetized MTJsin STT-MRAM is twofold: first, the interfacial perpendicularanisotropy at the CoFeB/MgO interface provides higherthermal stability at smaller dimensions (sub-60 nm) thandoes the usual-shaped anisotropy by giving elliptical shapeto in-plane magnetized MTJs. Second, for a given retention,i.e., a given thermal stability factor, the critical current forSTT-induced switching is lower with an out-of-plane than withan in-plane magnetized storage layer [ 13,14].
From a theoretical point of view, a first approach to
STT-induced switching can be developed by solving theLandau-Lifshitz-Gilbert (LLG) equation under the assump-
tions of 0 K macrospin approximation under stationary applied
spin-polarized current. The equilibrium configurations of thesystem can thus be calculated, and the precessional dynamicsof the system submitted to a small perturbation from thestatic equilibrium can be studied. This allows derivation ofthe threshold current required to achieve STT switching,as was done in Refs. [ 13–15]. Thermal fluctuations can
be taken into account in several limiting cases using the
Fokker-Planck equation. Thermal activation mainly decreasesthe threshold current value and the switching time, introducingan undesirable stochastic magnitude effect in both parameters[16,17]. The influence of the writing pulse duration was also
theoretically studied [ 16,18–21].
Despite the numerous experimental results [ 22,23] and
micromagnetic simulations [ 24–26] generally pointing to
quantitative disagreements with the macrospin-based esti-mations, usage of the macrospin approach is still justifiedfor at least two reasons. First, it gives a simple but solidpicture of the physical processes involved in STT switchingthat creates a common basis for qualitative analysis ofthe different magnetic multilayered systems, while most of
the conclusions derived from micromagnetic approaches are
rather of particular character. Micromagnetic behavior canbe mimicked, for example, by introduction of an effectiveactivation volume instead of Stoner-Wohlfarth behavior, butstill using a thermal activation model for the subvolume [ 22].
Second, considering the general trend to reduce the volume ofthe storage element (and, consequently, the energy needed per
write/read cycle), magnetic memory elements will eventually
behave in a macrospin manner.
Based on these viewpoints, we investigated STT switching
in fully perpendicular magnetic tunnel junction systems, wherein addition to the Slonczewski STT term (sometimes calledparallel or in-plane torque since it lies in the plane defined
1098-0121/2015/92(10)/104430(9) 104430-1 ©2015 American Physical SocietyA. A. TIMOPHEEV et al. PHYSICAL REVIEW B 92, 104430 (2015)
by the local magnetization and that of the spin polarization
usually defined by the magnetization direction of the referencepinned layer), having a damping-like structure, an out-of-plane(also called field-like or perpendicular) term exists. Severaltheoretical papers predicted that the torque produced by theout-of-plane STT term could reach an amplitude comparableto that of in-plane torque [ 27–29]. Several experimental
papers carried out on in-plane MTJ structures have alreadyestimated it to be in the range of 30–40% of the in-planetorque [ 30–33]. It was mentioned [ 34] that its presence may
lead to a backswitching process, a very undesirable effect inmagnetic memory applications causing write errors.
In this paper, after having analyzed the Landau-Lifshitz-
Gilbert-Slonczewski equation mathematically transformedinto Landau-Lifshitz (LL) form, we show that in fullyperpendicular MTJ structures, the field-like torque plays anegligible role in the switching process. In contrast to in-planeMTJ systems [ 30–34], it only influences the precessional
frequency preceding the switching, but the switching currentdensity is primarily determined by the in-plane STT term.The experiment carried out on 36-nm-diameter pMTJ pillarsupports our conclusions.
II. PHASE BOUNDARIES FROM LLG EQUATION
TRANSFORMED INTO LL EQUATION
The most accepted form of the LLG equation describing
dynamics of a macrospin under constant spin-polarized currentcan be presented as
dˆm
dt=−γ(ˆm×/vectorHeff)+α/parenleftbigg
ˆm×dˆm
dt/parenrightbigg
−γˆm×(ˆm×a/bardblˆp)+γˆm×a⊥ˆp, (1)
where ˆm=/vectorM
MSis the unit vector along the free layer
magnetization direction (in which M Sis the free layer’s volume
magnetization saturation parameter), /vectorHeffis the effective field
(comprising applied field, anisotropy field, and demagnetizingfield), ˆpis the unit vector along the magnetization direction of
the polarized layer, αis Gilbert damping, γis the gyromagnetic
ratio, and a
/bardblanda⊥are in-plane (damping-like) and out-of-
plane (field-like) STT prefactors, respectively. Both prefactorscan be phenomenologically represented as functions of spinpolarization in the magnetic electrodes, current density, orvoltage bias applied to the tunneling barrier, as will be donelater in the text.
In-plane and out-of-plane STT terms as written in Eq. ( 1)
are geometrically equivalent to the precession and dampingterms of the LL equation. One can therefore transform Eq. ( 1)
into LL form using the standard technique, i.e., by making an
ˆm×product on both sides of the equation,
ˆm×dˆm
dt=−γˆm×(ˆm×/vectorHeff)+αˆm×/parenleftbigg
ˆm×dˆm
dt/parenrightbigg
−γa/bardblˆm×[ˆm×(ˆm׈p)]+γa⊥ˆm×(ˆm׈p)
FIG. 1. (Color online) Geometry of the fully perpendicular MTJ
system.
and replacing the damping term in Eq. ( 1) with the result. This
yields,
(1+α2)
γdˆm
dt=− ˆm×[/vectorHeff−(a⊥+αa/bardbl)ˆp]
−ˆm×{ˆm×[α/vectorHeff−(αa⊥−a/bardbl)ˆp]}.(2)
To this moment, all the transformations born only a
character of mathematical identities, and Eq. ( 2)i sv a l i df o r
any system with any configuration of /vectorHeffand ˆp. Rewritten
in such a way, it acquires a more suitable form for furtheranalytical treatment because dynamics in this system are fully
determined by two vectors, namely [ /vectorH
eff−(a⊥+αa/bardbl)ˆp] and
[α/vectorHeff−(αa⊥−a/bardbl)ˆp], which have many similarities and
whose form can be significantly simplified as soon as the
geometry of /vectorHeffand ˆphas been set. Also, the use of Eq. ( 2)
is more convenient in numerical integration schemes. Furtheranalysis will focus on the case of the pMTJ structure assumingmacrospin dynamics of the storage layer described by Eq. ( 2).
We consider fully perpendicular magnetic tunnel junctions
submitted to an out-of-plane external magnetic field /vectorH
ext
and, therefore, applied parallel to the symmetry axis. This
situation allows analytical analysis wherein the quantities
/vectorHeff,ˆp,/vectorHext,ˆzremain collinear independently of the in-
stantaneous direction of ˆm.The magnetic free energy density
functional U of such a system depends only on one variable,θ,the angle between magnetization vector ˆmand quantization
axis ˆz(see Fig. 1) and is written:
U=/parenleftbig
K
⊥−2πM2
S/parenrightbig
sin2θ−MSHextcosθ. (3)
When |Hext|<H ⊥,H⊥=2K⊥
MS−4πM S, and Hext=
/vectorHext·ˆz, there are two stable magnetic moment orientations
104430-2RESPECTIVE INFLUENCE OF IN-PLANE AND OUT-OF- . . . PHYSICAL REVIEW B 92, 104430 (2015)
independent of Hextand always collinear with ˆz:
∂U
∂θ=0,∂2U
∂θ2>0,
−H⊥<H ext<H ⊥,
H⊥>0.→θ0=0,θ 0=π. (4)
The collinearity of the four vectors /vectorHeff,ˆp,/vectorHext,ˆzgreatly
simplifies Eq. ( 2), allowing it to work only with the magnitudes
a⊥,a/bardbl,andHeff:
(1+α2)
γdˆm
dt=− ˆm×Aˆz−ˆm×(ˆm×Bˆz),
A=Heff−(a⊥+αa/bardbl),
B=αH eff−(αa⊥−a/bardbl),
Heff=/vectorHeff·ˆz=−∂U
∂/vectorM·ˆz=H⊥/parenleftbig
cosθ0+Hext/H⊥/parenrightbig
.(5)
Here, two scalar parameters AandBare introduced, which
represent the direction and magnitude of the perpendicular andin-plane (the plane is formed by ˆmand ˆp) effective torques
(see Fig. 1) acting on magnetization when the latter departs
from its equilibrium position θ
0(0 orπ) because of thermal
fluctuations.
An important specific of the considered system is that the
Aparameter cannot change orbit (i.e., the angle θ); rather, it
only influences the frequency of the precession. One can derivethe ferromagnetic resonance (FMR) condition, which is just amodified “easy axis” Kittel formula for this case:
ω/γ=H
eff−(a⊥+αa/bardbl), (6)
where ωis the angular frequency of the resonance precession.
One can see, that if a⊥>H eff−αa/bardbl,the precession direction
will be changed, while an increase or decrease of θis
exclusively determined by the sign of the Bparameter,
wherein the damping-like STT term is dominating since α
is usually small (typically in the range 0.007–0.02). Theprecessional response of the system before the switching couldbe measured—for instance, by measuring ωversus the dc
applied voltage bias V
biason a single pMTJ pillar either by
rf voltage frequency detection, noise measurements [ 35], STT
experiments, or microfocused Brillouin light scattering (BLS)FMR technique. The excitation frequency would give accesstoa
⊥(Vbias) dependence, while the FMR linewidth parameter
change versus Vbiaswould reflect mostly a/bardbl(Vbias) dependence.
Turning back to the analysis of Eq. ( 5) and Fig. 1, one
can note that only the damping term, ˆm×(ˆm×Bˆz), can
change the precession angle θ. It is therefore possible to derive
the boundary conditions for a current-magnetic field stabilityphase diagram. The magnetization switching process startswhen the Bparameter changes sign. This condition yields
the threshold criterion for the STT-induced magnetizationswitching:
αH
eff+a/bardbl−αa⊥=0. (7)
One can see from Eq. ( 7) that the contribution from the
in-plane STT term ( a/bardbl) is largely dominating the switching
process. Indeed, the in-plane torque is on the order of αH eff
while the contribution of the perpendicular torque is weightedby the Gilbert damping, resulting in a much weaker influence
in the switching process. Here one can note again that thebest method to determine a
⊥experimentally is through FMR
measurements, and not from the influence of a⊥on the
(current, field) phase diagram boundaries since the latter isvery weak. Indeed, from the above discussion, being able tosee an influence of a
⊥on the phase diagram boundaries would
require a⊥≈a/bardbl/αwhich seems to be physically unachievable
in standard pMTJ systems [ 27–34]. Also, as will be shown in
Sec. VI,t h eαa⊥term in Eq. ( 7) disappears if one chooses the
dissipation term in the LL formulation. In any case, Eqs. ( 6,7)
are quite useful for the analysis of STT switching experimentsperformed on pMTJ systems.
III. STABILITY PHASE DIAGRAM BOUNDARIES
Having set the relations between electric current flowing
through pMTJ and the STT prefactor magnitudes, one canconstruct the stability phase diagram explicitly from Eq. ( 7)
assuming that the spin-polarized current pulse is long enoughto complete any STT-induced switching while influence ofthe thermal fluctuations is limited to setting a small initialmisalignment angle θ
0so that |cosθ0|≈1.Modification
of the phase boundaries due to thermal fluctuations andunder a short-pulse writing regime, which are essential inreal magnetic memory applications, will be analyzed in thefollowing sections, while in this section, the conditions oflong-pulse and low-temperature regime are assumed.
In most investigated pMTJs, one can expect the condition
a
⊥<a/bardblandαa⊥/lessmucha/bardblto be fulfilled. In this case, one can set
a⊥=0 and build up the boundaries of the (current, field) sta-
bility phase diagram. In absence of the spin-polarized current(a
/bardbl=0,a⊥=0), switching occurs when αH effchanges sign,
i.e., when Hext=−H⊥forθ0=0 andHext=H⊥forθ0=π.
This defines the vertical boundaries of the diagram shown inFig. 2(a), depicted by dashed vertical lines. For H
ext=0 and
by setting a/bardbl=st/bardblGpVbias[where st/bardbl=/planckover2pi1
2e·η
tFMS=STT is the
conversion efficiency factor in units of Oe/(A cm−2);ηis the
effective spin polarization parameter; and Gpis the tunneling
conductance factor, generally dependent on θandVbias, in units
of/Omega1−1cm−2, representing in the simplest interpretation the
inverse of the R ×A product], one can obtain that the switching
current density Iswis proportional to αH⊥:
Isw0=GpVsw0=αH⊥
st/bardbl=2e
/planckover2pi1·tFαH⊥Ms
η. (8)
In the case of Hext/negationslash=0,relation ( 8) leads to a linear depen-
dence between the switching current and external magneticfield, yielding a linear slope on the switching phase diagramgiven by
dI
sw
dH ext=α
st/bardbl=2e
/planckover2pi1·tFαM s
η. (9)
One can conclude that if the effective spin polarization
parameter ηis constant (i.e., weakly dependent on the bias
voltage Vbias), then the STT-driven parts of the switching dia-
gram are linearly dependent on the applied field, with the slope
104430-3A. A. TIMOPHEEV et al. PHYSICAL REVIEW B 92, 104430 (2015)
FIG. 2. (Color online) (a) Stability phase diagram constructed from Eq. ( 7) assuming a/bardbl=st/bardblGpVbiasanda⊥=0; (b) modification of
the phase boundaries for the same a/bardblprefactor ( a/bardbl=st/bardblGpVbias,st/bardbl=67G−1
pOe/V) and different forms of a⊥prefactor: solid line a⊥=0;
circles a⊥=st⊥2(GpVbias)2withst⊥2=154G−2
pOe/V2;d a s h e dl i n e a⊥=st⊥1GpVbias+st⊥2(GpVbias)2withst⊥1=500G−1
pOe/Va n d st⊥2=
10 000 G−2
pOe/V2.Other system parameters are α=0.05 and H⊥=200 Oe.
proportional to the intrinsic damping parameter αand inversely
proportional to the STT efficiency prefactor st/bardbl, and with the
zero-field switching current magnitude being proportional tothe effective perpendicular anisotropy H
⊥. One should also
note that Eq. ( 8) is in full agreement with previously obtained
expressions [ 13–15,36] for the zero-field-threshold switching
current derived from analysis of the precessional response ofthe system, assuming linear dependence of the damping-likeSTT prefactor versus the applied current. In our case, Eq. ( 7)
allows one to calculate I-Hstability phase diagram boundaries
for any a
/bardbl,a⊥prefactors with arbitrary bias current (voltage)
dependence, or by choosing it from the theoretical estimationsmade for the concrete MTJ system [ 28,29].
Simultaneous influence of both in-plane and out-of-plane
STT terms on the phase boundaries is shown in Fig. 2(b).
We have chosen realistic values for the magnetic system (seethe figure caption), letting the in-plane prefactor be linearlydependent on bias voltage with s
t/bardbl=67G−1
pOe/V. A s f o r
the out-of-plane prefactor a⊥,we show three different cases:
zero, quadratic dependence with st⊥2=154G−2
pOe/V2, and
quadratic +linear dependence (which mimics features ofan asymmetric MTJ structure; see the expression in the
caption of Fig. 2) with unreasonably large STT conversion
coefficients. One can see that within the difference betweenthe phase boundaries in all three cases is negligible. Thesecond case uses exactly the same parameters as those inRef. [ 15]i nF i g . 3. We can see that the boundaries calculated
and simulated there are identical to our three cases, nomatter what prefactor dependence is introduced −H
⊥<
Hext<H ⊥,for the out-of-plane STT term. This confirms
that the out-of-plane STT term has a negligible influence onthe STT switching diagram. Parabolic shape of boundariesstarts being observed only in the third case, and it becomesnoticeably different only for current magnitudes several timeslarger than the threshold switching current. Thus, one canconclude that under long-pulse/low-temperature conditions,STT switching in fully perpendicular MTJ structures obeyingmacrospin dynamics is almost not influenced by the out-of-plane STT term and by its prefactor bias voltage or currentdependence. Below, we will show that this statement isstill valid at finite temperature and reasonably short writingpulses.
FIG. 3. (Color online) Finite writing pulse phase diagrams for different in-plane and out-of-plane STT prefactor magnitudes: (a) T=0K ;
(b)T=300 K .The model parameters are H⊥=200 Oe ,g=2.20 (g-factor), α=0.01. Integration time was 1 μs in each field point, and the
writing pulse width is 40 ns. Each diagram is an average of 10 identical simulations.
104430-4RESPECTIVE INFLUENCE OF IN-PLANE AND OUT-OF- . . . PHYSICAL REVIEW B 92, 104430 (2015)
IV . MACROSPIN SIMULATIONS
Aiming at extending the conclusions made in the previous
sections to the case of finite temperatures and finite writ-ing pulse regime, a series of macrospin simulations wereperformed using Eq. ( 2) (i.e., with Gilbert damping). The
simulations were carried out with a fixed writing pulse duration
of 40 ns and a cumulative integration time of 1 µs for each field
point. The following assumptions of bias voltage dependencesfor the STT prefactors were used: a
⊥=st⊥2G2
pV2
biasanda/bardbl=
st/bardblGpVbias, which is the case of symmetrical MTJ systems
with a high spin polarization parameter. For convenience, theparameter G
pwas set constant and equal to 1 /Omega1−1cm−2.The
temperature was included in the form of a stochastic thermalfield H
thwith Gaussian distribution [ 37], added directly to
the effective field Heff.Statistical properties of these thermal
fluctuations are given by the following relations:
/angbracketleftHth,i(t)/angbracketright=0
and
/angbracketleftHth,i(t)Hth,j(t/prime)/angbracketright=2αkBT
γM SVpδijδ(t−t/prime)
where kBis the Boltzmann constant, and Vpis the
free layer volume. The chosen LLG equation is inte-grated with a (predictor-corrector) Heun scheme [ 38].
Here we used V
p=2.07×10−17cm3,H⊥=200 Oe, Ms=
1000 emu /cm3, which gives the effective stability factor at
T=300 K:
/Delta1=H⊥MSVp
2kBT=50.
This set of the parameters was chosen to mimic working
conditions of an actual STT-MRAM device. Two sets ofmacrospin simulations, at T=0 K and T=300 K, respec-
tively, presented in Fig. 3show how the phase boundaries
are changed for the different combinations of in-plane andout-of-plane STT prefactor magnitudes. We will discuss firstthe results shown in Fig. 3(a) corresponding to the case with
finite pulse duration and no thermal fluctuations ( T=0K ) .
The finite duration of the writing pulse brings two main ef-
fects. First, the STT-driven boundaries are shifted toward muchhigher voltages (currents). Evidently, to achieve switchingwithin the considered finite time period, one has to apply higheramplitudes for the writing pulses. In the initial stage, when ˆm
is almost collinear with the symmetry axis ˆz, the torque is very
weak, which results in very slow STT-induced dynamics in the
system. It is evident that in absence of thermal fluctuations, theswitching time from ˆm/bardblˆzinitially would be infinite for any
spin-polarized current magnitude [ 13,14]. To avoid this in the
T=0 K simulations, a small misorientation (0 .1
◦) between ˆp
andHextwas introduced in the system. The second effect is
nonlinearities of the phase boundaries, which are seen even onthe diagrams with the in-plane STT term only. This effect islinked with a nonlinear dependence of time necessary for STTswitching versus the applied magnetic field. Both effects areentirely of dynamical nature, and their influence on the phaseboundaries can be theoretically described using the formalismdeveloped in Ref. [ 16]. Renormalization of the effective
dynamic time allows one to link dependence between thecritical current, pulse width, and finite temperature. This alsowill be done in the next section, while here the discussion will
be focused on a qualitative analysis of the relative contributionsof the in-plane and out-of-plane STT terms to phase boundariesshapes.
One can see from Fig. 3(a) that the general behavior of
the phase boundary modifications on the simulated phasediagrams under finite writing pulse regime is in agreementwith the conclusions made in the previous sections for the
dc regime. For the case of s
t⊥2=400G−2
pOe/V2andst/bardbl=
0G−1
pOe/V, the simulated phase diagram demonstrates a
unidirectional STT switching due to quadratic dependence
ofa⊥versus applied voltage. In other words, switching to
the antiparallel configuration is possible only for st⊥2>0,
st/bardbl=0.Zero-field ( Hext=0) STT switching voltage for
this diagram is ±1.6 V. This voltage induces an effective
STT field in the damping term of Eq. (2) of ∼1000 Oe,
which is five times higher than the effective perpendicularanisotropy field H
⊥=200 Oe. At the same time, if one adds
a relatively small damping-like prefactor st/bardbl=30G−1
pOe/V,
it completely removes any apparent influence of the field-like
STT term from the phase diagram, despite the huge valuechosen for its prefactor. When the effective contributions fromboth prefactors are comparable, the phase diagram acquires anoticeable asymmetry, as can be seen for the last two diagramsin the middle column. However, such a combination of s
t/bardbland
st⊥2already can be physically unrealistic.
Figure 3(b) shows the same set of simulations made
under T=300 K. Several temperature-induced effects are
observed: (i) decrease of the coercive field showing thatthermally activated magnetization reversal takes place whenthe external magnetic field substantially lowers the effectivebarrier height in the system; (ii) shift of the voltage-driven partsof the boundaries toward lower switching voltages. Thermalfluctuations of the magnetic moment direction increases theprobability of launching STT switching thanks to a thermallyinduced misorientation between ˆmand ˆp. This increases
the initial STT amplitude and substantially decreases theswitching time for a given writing pulse amplitude. Thisis consistent with earlier observations in STT-MRAM cellsand with theoretical expectation of a I
c=Ic0{1−kBT
/Delta1Eln(τ
τ0)}
dependence of switching current on the pulse duration underfinite temperature [ 39]. Therefore, Fig. 3(b) Indicates that the
general features observed in the switching phase diagram at0 K [i.e., Fig. 3(a)] are conserved at finite temperature and
illustrates again the negligible role of the out-of-plane STTterm in the switching process [see in particular the last columnin Fig. 3(b)].
V . EXPERIMENTAL MEASUREMENTS OF THE ( I-H)
SWITCHING DIAGRAM
In this section, the STT efficiency and other magnetic
parameters of pMTJ pillars are directly extracted from themeasured diagram. Nominal 50-nm-diameter pMTJ pillarswere fabricated from an MTJ stack grown by magnetronsputtering. The stack contains a 1.7-nm-thick Co
20Fe60B20
free layer sandwiched between two MgO barriers. Magneti-zation saturation parameter of the free layer was measuredto be 1030 emu /cm
3.Current in-plane magnetotransport
measurements (CIPTMR) yielded R ×A=5.7/Omega1μm2and
104430-5A. A. TIMOPHEEV et al. PHYSICAL REVIEW B 92, 104430 (2015)
FIG. 4. (Color online) Experiment carried out on pMTJ pillar at room temperature applying 100-ns writing pulses. (a) Examples of
magnetoresistance loops measured with zero writing pulses; (b) stability phase diagram; (c) extracted phase boundaries and their linear fittings.
TMR=126%. The second MgO barrier was introduced to
increase the perpendicular anisotropy of the free layer. It hasa negligible resistance-area (R ×A) product compared with
the main tunnel barrier. The bottom fixed layer is a syntheticantiferromagnetic-based, perpendicularly magnetized multi-layer, and the polarizer material has the same compositionas the free layer. The metallic electrode above the secondMgO barrier is nonmagnetic. Experimentally, it was foundthat the pillar diameter slightly differs from its nominal valuedue to the nanofabrication technology (36 nm instead of 50 nmnominal). This was recalculated using the values of the lowresistive state ( R
pp=5.6k/Omega1) of the magnetoresistance curve
[Fig. 4(a)] and assuming that the R ×A value is preserved after
the nanofabrication. Knowing the volume of the free layer inthe pillar V
p,its room temperature coercivity, measurement
time (∼1s ),and attempt frequency f0=1010s−1,one can
recalculate the perpendicular magnetic anisotropy from theN´eel-Brown formula [ 37,40],
H
C(T)=H⊥/parenleftBigg
1−/radicalBigg
2kBTln(tmf0)
MSH⊥Vp/parenrightBigg
, (10)
which gives H⊥=2.6 kOe and /Delta1=56.
The phase diagram measured at room temperature is shown
in Fig. 4(b). At each magnetic field point, a 100-ns writing
pulse with fixed amplitude was applied to the pMTJ pillar.Subsequently, the resistance was measured under small dcbias current, and the next magnetic field point was set. Toreduce the stochasticity in the switching field values, themagnetoresistance loop was measured 15 times, and theiraverage was used for switching field determination. The sameprocedure was used for all writing pulse amplitudes, and thefinal phase diagram was constructed from these averaged mag-
netoresistance loops. Magnetic field loop repetition frequency
was 2 Hz.
The extracted phase boundaries are shown in Fig. 4(c).T h e
coercive field of the free layer is 940 Oe, and the coupling fieldwith the reference layer is only 11 Oe and is ferromagnetic. Thevoltage driven parts are linear and almost parallel to each other.To reduce the influence of small nonlinearities at the edgesof the boundaries, only the central parts (within the ±500 Oe
region) were used in the fitting. The extracted slopes are 1 .27×
10
−4and 1.23×10−4V/Oe; their difference is within the
fitting error. The zero-field switching voltages are 0.359 and0.385 V , respectively. The difference is most probably due to
the small dc bias current used for the resistance measurements.
The phase diagram shape is similar to those obtained from
the theoretical analysis (Sec. III) and the simulations (Sec. IV)
where the out-of-plane STT term is not dominating. For thissystem, we can choose the STT prefactor model a
⊥=0,a/bardbl=
st/bardblGpVbias. It corresponds to the dc diagram shown in Fig. 2
whose boundaries are described by Eqs. ( 8,9). To recalculate
thest/bardblparameter from the extracted diagram slopes, one first
needs to remap the experimental finite temperature–finite writ-ing pulse diagram to that of the long pulse–low temperaturemodel case. Here, we will follow the formalism described inRef. [ 16]. Thermal effects in our case can be reduced to the
regime of thermally assisted ballistic STT switching. In thisregime, the main role of thermal fluctuations is to increasethe probability of STT switching thanks to an increased initialmisorientation angle θ
0,|cos(θ0)|/negationslash=1. As already mentioned,
STT switching dynamics starting from a tilted state reducesthe switching time τ,in agreement with [ 13,14]. The cone
angle 2 θ
0, for which the equilibrium probability for the
magnetic moment orientation distribution is 0.5, is determinedby thermal stability parameter /Delta1and applied magnetic field
θ
0=(ln 2//Delta1)1/2(1+Hext/H⊥)−1/2,while the final angle, the
extremum on the energy barrier θτ=arccos( −Hext/H⊥)( f o r
θ0<π / 2), is determined by magnetic field (see Eq. (77) in
Ref. [ 16]). Having defined the initial θ0and final θτangles of
the STT-induced dynamics, one can calculate analytically theswitching time τ(see Eq. (58) in Ref. [ 16]):
(i−1)τ
τD=ln/parenleftbiggxτ
x0/parenrightbigg
−1
i+1ln/parenleftBiggi−1
i+1+x2
τ
i−1
i+1+x2
0/parenrightBigg
, (11)
Here,x0=tanθ0,xτ=tanθτ,τD=(1+α2)
αμ 0γH⊥,and, according
to our formalism, i=Iτ
sw/Isw0−Hext
H⊥.Having calculated
θ0=6◦andτD=9.9 ns and assuming α=0.02 [ 41] and
writing pulse duration τ=100 ns, we recalculated Iτ
sw(Hext)
dependence from Eq. ( 11) (Fig. 5, blue line) and compared it
with the Isw(Hext) dc diagram case (Fig. 5, circles) derived from
Eqs. ( 8,9). One can conclude that 100-ns writing pulses are
long enough to remove the effect of dynamical distortion of thephase boundaries. For the measured device of Fig. 5, we find
τ
τD=100.6,which is quite high. This makes it possible to work
directly with the phase boundaries [Eqs. ( 8,9)] derived from
104430-6RESPECTIVE INFLUENCE OF IN-PLANE AND OUT-OF- . . . PHYSICAL REVIEW B 92, 104430 (2015)
dc
FIG. 5. (Color online) Finite pulse–finite temperature diagram
boundary forτ
τD=100.6 (blue for experiment) andτ
τD=1.5 (red
for simulations). The dots are the respective boundary obtained fromEqs. ( 8,9).
Eq. ( 7). However, ifτ
τD<10 (the writing pulse width in the
experiment would be <10 ns) and/or θ0is too small, the phase
boundary remapping procedure is necessary before furtheranalysis of the phase boundaries can be made. Indeed, inthe simulations shown in the previous sections, the respectivevalue of
τ
τDis 1.54. Therefore, the switching currents are much
higher and the linear slope is different from that expected fromthe model. One also should notice that this formalism worksonly in high- /Delta1approximation. Therefore, the parts of the phase
boundaries close to the regions where H
extapproaches H⊥
should be removed from the analysis.
From extrapolation of the voltage -driven boundaries to
V=0 one can estimate H⊥∼2.8−3.1 kOe, which is slightly
higher than the corresponding value extracted from Eq. ( 10)
(2.6 kOe). Nevertheless, the obtained H⊥values are in quite
good agreement considering these two values are derivedfrom very different physical phenomena (superparamagnetismvs STT switching). The spin-torque efficiency prefactor s
t/bardbl
can be directly determined from the experimental slope
using Eq. ( 9):st/bardbl=162G−1
pOe/V.From this, assuming that
Gp=1/R×A, the effective spin polarization parameter in
the system can be derived as η=0.49. If one uses the
measured TMR value to estimate the polarization factor,assuming that η=√
TMR (TMR +2)/[2(TMR +1)] [ 42]
and TMR =1.26, this would yield η=0.44, which is close
to the value extracted from the diagram boundary slope. Thezero-field switching current, recalculated using Eq. ( 8)f o r
obtained values of H
⊥,st/bardbl,and known parameter α,gives
Isw0=0.35GpV.
Therefore, one can conclude that the experiments carried
out in the 36-nm pMTJ system can be well described withinthe macrospin approximation and thermally activated ballisticregime of STT switching. The H
⊥,st/bardblparameters extracted
from the phase boundaries of the Vbias-Hstability diagram are
in good agreement with those extracted independently from themagnetoresistance loop and N ´eel-Brown model. It is worth
noting that a macrospin behavior is not specific only to themeasured device but is a generally observed feature for pillarswith a nominal diameter <80 nm.VI. LANDAU vs GILBERT
In this section, we emphasize an important issue naturally
arising from the analysis carried out in the previous sections.If the STT terms are added directly to the LL equation [ 43],
then instead of Eq. ( 2) (obtained with the Gilbert dissipation
term [ 44]), the following modified equation is obtained:
1
γμ 0dˆm
dt=− ˆm×/parenleftbigg1
1+α2/vectorHeff−a⊥ˆp/parenrightbigg
−ˆm
×/bracketleftbigg
ˆm×/parenleftbiggα
1+α2/vectorHeff+a/bardblˆp/parenrightbigg/bracketrightbigg
. (12)
Still preserving the main features and general behavior
of STT switching in fully perpendicular structures, Eq. ( 10)
forbids switching only by the out-of-plane STT term, incontrast to Eq. ( 2), where the [ αa
⊥ˆm×(ˆm׈p)] component
allows the system to change its energy even if a/bardbl=0. That
turns us to the still open discussion [ 45–52] of physical validity
of Gilbert damping and Landau damping formulation in themagnetization dynamics equation. Although it is generallyclaimed that LL and LLG equations are mathematicallyequivalent, we can see a significant difference when the STTterms are added: the field-like STT term written in the LLequation is fully conservative , and it cannot change the system
energy if Eq. ( 12) is chosen to describe the STT-induced
dynamics. Leaving this fact “as is,” one should notice thatin numerical simulations, it is more common to use the LLform instead of the LLG form, and different ways to introduceSTT terms [i.e., explicitly into the LL equation (Eq. 12)o rv i a
transformation of LLG +STT (Eq. 2)] can lead to significantly
different results.
Figure 6demonstrates this important issue by comparing
examples of macrospin simulations using either LL or Gilbertdamping terms to describe dissipation during STT-inducedswitching. Here, we adjusted the relative magnitudes of thefield-like and damping-like STT prefactors to have comparablecontributions in the second part of Eq. ( 2), which is the LLG +
STT case. As soon as the field-like STT prefactor is set tohave only a quadratic-bias voltage dependence (the case of asymmetrical tunnel junction), the produced torque always pullsthe free layer magnetization in the antiparallel configurationwith the fixed layer. The damping-like STT prefactor is set to belinear on the bias voltage, and therefore the torque direction is
FIG. 6. (Color online) Two identical macrospin simulations of a
stability phase diagram carried out at T=0 K: (a) using Eq. ( 2),
LLG+STT; (b) using Eq. ( 12), LL+STT. STT prefactors: st/bardbl=
12G−1
pOe/Va n d st⊥2=400G−2
pOe/V2. Other parameters are the
same as used for the simulations in Sec. IV.
104430-7A. A. TIMOPHEEV et al. PHYSICAL REVIEW B 92, 104430 (2015)
determined by the current polarity. When a negative voltage is
applied to the system, field-like torque helps the damping-liketorque switch magnetization in the antiparallel state. It shiftsthe phase boundary toward lower switching voltages. Howeverthe expected boundary shift is too small to be visible in oursimulations considering the chosen step for the voltage writingpulse amplitude. Also, a quadratic dependence of the field-likeSTT prefactor allows it to compete with the damping-liketorque only at relatively high writing pulse voltages. At thesame time, for positive pulses, field-like torque works againstthe damping-like torque, which shifts the phase boundaryto higher voltages. The higher the switching voltage, thehigher the relative contribution from the field-like torque.Finally, when the writing pulse is about 1.6 V , field-like torquecompensates the damping-like one, and further increase ofthe writing pulse amplitude starts shifting the phase boundaryback toward negative fields, decreasing the field window of thebipolar STT switching. The same effect is observed at finitetemperatures in Fig. 3(b) for the bottom middle diagram. This
competition between the STT terms, however, is impossiblein simulations with the Landau damping term because theαa
⊥ˆm×(ˆm׈p) term is absent in Eq. ( 12).
Finally, it is traditionally accepted that the LLG and LL
equations are geometrically equivalent, and the mathematicaltransformation from one to another ends up with
1
1+α2
rescaling of the gyromagnetic ratio. This1
1+α2correction
in real physical systems is very small and experimentallyundetectable. However, this is not the case anymore if theSTT terms are added to the LLG equation. The equationsare now different .The same transformation (i.e., LLG +
STT→LL) leads to the appearance of two additional STT
pseudo-torques [ αa
⊥ˆm×(ˆm׈p),α a /bardblˆm׈p], which are
linearly proportional to the damping constant αand in principle
can be detected experimentally.
Experimentally, it should be possible to assess which
formulation of damping is correct by measuring the variation ofthe precession frequency in the subswitching threshold regimein samples having various damping constants. Such samplescould be produced, for instance, by depositing a wedge ofPt above the storage layer before the patterning of the wafer.For this experiment, it would be preferable to use symmetricMTJs so that the field-like torque has a quadratic dependenceon bias voltage. If the LLG formulation is correct, we expecta linear variation of the frequency with damping constantunder fixed bias voltage, whereas if the LL formulation isvalid, no dependence of the frequency on damping should beobserved.
VII. CONCLUSIONS
It has been shown that the LLG equation with the field-like
and damping-like STT terms transformed into the LL formconsiderably simplifies the analysis of the STT switchingprocess. In the case of a fully perpendicular MTJ system, theboundaries of the I-Hstability phase diagram can be obtained
directly from the transformed Eq. ( 2). It was shown that the
field-like term has negligible influence on the STT switchingprocess in pMTJs with low damping, influencing mainly theFMR precession frequency for the small oscillations near theequilibrium. Considering that in standard pMTJ structures its
effective magnitude cannot be much higher than the magnitudeof the in-plane torque, it would be hard to track its bias voltage(current) dependence from experimentally measured stabilityphase diagrams. Measuring the bias voltage dependence ofthe frequency in the precessional regime would certainlybetter reveal the influence of the field-like STT term, butthe contribution of the field-like term still would have tobe separated from the nonlinear influence of the oscillationamplitude on the frequency.
Finite temperature macrospin simulations in LLG-STT
formalism under finite writing pulse duration have confirmedthe negligible role of the field-like term in the STT switchingprocess of pMTJ structure. Limitations of the macrospinmodel are not expected to be important in the case of pMTJpillars with diameters comparable to or below the exchangelength. This is confirmed by the experiments carried out on36-nm-diameter pMTJ pillars.
One should note that the method developed for the phase
boundaries construction gives the same results as thoseobtained from the analysis of dynamical response of thesystem carried out by different groups supposing the lineardependence of the damping-like STT prefactor versus appliedbias voltage. However, we believe that it will be more useful inthe interpretation of the experiment and simulations, becauseit is much more flexible, and it allows the introduction of anydesirable current (voltage) dependences for the in-plane andout-of-plane STT prefactors.
Using the developed formalism, the spin-torque efficiency
and effective spin polarization parameters have been derivedfrom the current field stability diagram boundaries experi-mentally measured on a 36-nm pMTJ pillar. The obtainedparameters have been cross-checked by estimations frommagnetoresistance curves and from the thermally activatedmagnetization reversal regime. Good agreement betweenthe values derived from the analysis of different physicalprinciples strongly supports the assumption of macrospinbehavior in the measured sample.
We also showed that the different dissipation terms (i.e.,
LL or Gilbert) give rise to different analytical expressionsdescribing the phase boundaries of I-Hswitching diagrams,
which can be important in heavily damped systems. If theLandau damping term is physically correct, the action of thefield-like and the damping-like torques in the pMTJ system iscompletely separated in precession and dissipation terms in theequation of dynamics. If the Gilbert damping term is correct,then two additional torques [ αa
⊥ˆm×(ˆm׈p) andαa/bardblˆm׈p]
are mixed in with the main STT contributors [ a/bardblˆm׈pand
a⊥ˆm×(ˆm׈p),respectively]. An experimental way to assess
which damping formulation is correct in combination with
STT was proposed.
ACKNOWLEDGMENTS
This paper was supported by the Samsung Global MRAM
Innovation Program and EUROTALENTS Program. Theauthors are grateful to Ursula Ebels for fruitful discussions.
104430-8RESPECTIVE INFLUENCE OF IN-PLANE AND OUT-OF- . . . PHYSICAL REVIEW B 92, 104430 (2015)
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104430-9 |
PhysRevB.93.224410.pdf | PHYSICAL REVIEW B 93, 224410 (2016)
Phase locking of spin-torque nano-oscillator pairs with magnetic dipolar coupling
Hao-Hsuan Chen,1Ching-Ming Lee,2,*Zongzhi Zhang,1,†Yaowen Liu,3,‡Jong-Ching Wu,4
Lance Horng,4and Ching-Ray Chang5
1Shanghai Ultra-Precision Optical Engineering Center, Department of Optical Science and Engineering, Fudan University,
Shanghai 200433, People’s Republic of China
2Graduate School of Materials Science, National Yunlin University of Science and Technology, Douliou, 64002, Taiwan,
3School of Physics Science and Engineering, Tongji University, Shanghai 200092, People’s Republic of China
4Department of Physics, National Changhua University of Education, Changhua 500, Taiwan
5Department of Physics, National Taiwan University, Taipei 10617, Taiwan
(Received 1 December 2015; revised manuscript received 17 May 2016; published 8 June 2016)
A spin-torque nanopillar oscillator (STNO) that combines a perpendicular-to-plane polarizer (PERP) with
an in-plane magnetized free layer is a good candidate for phase locking, which opens a potential approach toenhancement of the output power of STNOs. In this paper, the magnetic dipolar coupling effect is used as thedriving force to synchronize two STNOs. We develop an approximation theory for synchronizing two identicaland nonidentical pairs of PERP STNOs, by which the critical current of synchronization, dipolar couplingstrength, phase-locking transient time, and frequency can be analytically predicted. These predictions are furtherconfirmed by macrospin and micromagnetic simulations. Finally, we show the phase diagrams of the phaselocking as a function of applied current and separation between two STNOs.
DOI: 10.1103/PhysRevB.93.224410
I. INTRODUCTION
A spin-polarized current can be used to excite persistent
magnetization oscillations in a nanomagnet through the spin-transfer torque (STT) effect [ 1,2]. Such STT-driven magnetic
precession has attracted considerable attention because ofboth the fundamental interest for studying nanoscale magneticdynamics and the applications in the frequency tunablemicrowave oscillators [ 3], which can be used in telecom-
munications, microwave signal processors, and microwavefield detectors [ 4–9]. The frequency of STT oscillators can be
tuned by the strength of magnetic fields or current. However,the present output power of a single spin-valve spin-torquenanopillar oscillator (STNO) is typically in the range ofpicowatts to nanowatts [ 10,11], which is still too weak for
any practical applications.
Increasing output power of a STNO is essential for suc-
cessful adaptation of the STT excitation scheme for advancedmicrowave oscillators. Several ways to enhance the outputsignals have been reported. For example, using a magnetictunnel junction (MTJ) to replace the spin valve element canincrease the output power to microwatt level [ 12–14]; using the
perpendicular-to-plane magnetized layer as the spin polarizerof STNOs can excite large angle out-of-pane (OP) precessionfor enhancement of the power output [ 15–21]. Up to now, a
single STT device has been significantly optimized, but theoutput power still cannot reach the required milliwatts.
Another promising approach to increasing the emitted
power has been suggested by using the phase-locking modeof an array of STNOs through the synchronization technique.This is a very challenging issue due to the strongly nonlinearproperty of STNOs [ 22,23]. A phase-locking experiment has
*cmlee@yuntech.edu.tw
†zzzhang@fudan.edu.cn
‡yaowen@tongji.edu.cnbeen reported in spin-torque devices with multiple nanocon-
tacts [ 24–31], in which the magnetization in all the nanocontact
regions can be locked in the same phase via propagatingspin-waves [ 32–34]. Alternatively, the phase locking by using
the coupled electrical circuits has also been proposed in anarray of STNO nanopillars electrically connected in series or inparallel [ 35–37]. Recently, a third scheme using the magnetic
dipolar coupling effect as the driving source of synchronizationhas been demonstrated in nanopillars that combines the out-of-plane magnetized polarizer and the in-plane magnetizedfree layer namely, perpendicular-to-plane polarizer (PERP)STNO [ 19,38,39]. Additionally, another kind of oscillator
based on the spin Hall effect (SHE), i.e. spin Hall oscillators(SHOs), have been also reported recently [ 40–45]. Moreover,
the synchronization of vortex-based nonuniformly magnetizedSTNOs in a horizontal array has also been reported [ 46–49].
Among these synchronization schemes, the scheme using themagnetic dipolar effect displays special features [ 38,47,48]:
First, the dipolar coupling among STNOs with nanopillarstructure is an intrinsic property, so that it does not need anyother external sources such as external microwave field or aspecial design of resistor-inductor-capacitor (RLC) circuit toassist synchronization. Second, unlike the scheme employinga propagating spin wave [ 31], in which the phase-locking
mode can be either in phase or antiphase, depending on theintercontact distance and current strength, the magnetizationphase-locking state induced by the dipolar interaction is verystable, and the antiphase mode is independent of the currentand separation between neighboring STNOs [ 38].
In this paper, we present a phase-locking scheme to
synchronize two horizontally arranged PERP STNOs throughthe dipolar coupling effect of the free layers. The paper isorganized as follows: In Sec. II, we develop a theory for
synchronizing two identical and nonidentical pairs of PERPSTNOs. The pairs are horizontally arranged. The sufficient andnecessary parametric conditions for the synchronization areaddressed, based on the assumption of strong demagnetization
2469-9950/2016/93(22)/224410(12) 224410-1 ©2016 American Physical SocietyCHEN, LEE, ZHANG, LIU, WU, HORNG, AND CHANG PHYSICAL REVIEW B 93, 224410 (2016)
energy and the dipolar coupling approximation with a single
domain model. We analytically predict the critical current,critical dipolar coupling strength, as well as the phase-lockingfrequency and phase-locking transient time. In Sec. III,w e
perform both macrospin and micromagnetic simulations. Thesimulation results are consistent with our analytical predic-tions, by showing the time evolution of the phase difference,spectrum analysis of the synchronization oscillations, thecurrent range, and the separation distance between the twosynchronized STNOs. We also show parameter diagramsof phase locking. Finally, a brief summary and discussionsare given in Sec. IV. Appendix Aprovides details of the
calculation of magnetic dipolar interaction between twocircular, uniformly magnetized discs, and Appendix Bpresents
an approximation theory using a low-energy orbit to derive theNewton-like Eq. ( 5).
II. MODEL AND THEORETICAL FRAMEWORK
As a model system, we consider here a pair of STNOs
shown in Fig. 1. The bottom layer is the spin polarizer layer (P)
whose magnetization is fixed along the perpendicular-to-planedirection. The top layer is supposed to be etched down tothe nonmagnetic metal layer. The free layers (F1 and F2) ofthe two nanopillars are separated by an edge-to-edge distanced
ee. We assume that the free layer has a quasiuniform in-
plane magnetization due to its small size. A dc electric currentseparately flows from the bottom layer to the two free layersF1 and F2. We assume that the two pillars have the sameamount of injected current (each one has −I). When the current
strength is larger than a critical value, the current-inducedSTT effect will drive the two free-layer magnetizations into
a precessional state [ 15,21]. Owing to the magnetic dipolar
interaction between the two free layers, the two STNOs canoscillate synchronously under certain conditions.
The magnetization dynamics of the two free layers can
be described by the Landau-Lifshitz-Gilbert (LLG) equationincluding the STT term [ 19,50–52]
dm
i
dτ=−/parenleftbig
∇miG/parenrightbig
×mi+α/parenleftbigg
mi×dmi
dτ/parenrightbigg
−aJ(mi)[mi×(mi×p)], (1)
FIG. 1. (a) Sketch of a horizontal array containing two PERP
STNOs. P denotes the spin polarizer layer (i.e. the fixed layer),
and F denotes the free layer. (b) The unit vector mof free layer
magnetization is illustrated in the polar coordinate representation(θ,φ).where the subscript i(=1,2) is used to distinguish the
two nanopillars. Here, m=M/Msis the unit vector of
the free-layer magnetization, Msis the saturation magne-
tization, and τ=(4πMsγ)tis the scaled time, with γ=
1.76×107Oe−1·s−1being the gyromagnetic ratio. Also,
G(m) is the total energy density of the free layer which
has been normalized by 4 πM2
s. Further, αis the Gilbert
damping constant. The third term on the right side ofEq. ( 1) is the STT term, in which pis a unit vector
of the polarizer magnetization along the zdirection, and
a
J(mi)=AJ(mi)(4πMsγ)−1=aJ0ε(θi,Pi,/Lambda1i) is the scaled-
down STT strength in which AJ(mi)=AJ0ε(θi,Pi,/Lambda1i)=
(γ/planckover2pi1J/2eMsd)ε(θi,Pi,/Lambda1i). Here, Jis the injected current
density, Pis the spin polarization, dis the free-layer thickness,
andθis the angle between the magnetization vectors of
the free layer and the polarizer layer. Also, ε(θi,Pi,/Lambda1i)=
Pi/Lambda1i2/[(/Lambda1i2+1)+(/Lambda1i2−1) cos θi](i=1,2) is the angular
dependence factor of the Slonczewski STT [ 1], in which
Pand/Lambda1are dimensionless quantities which determine the
spin-polarization efficiency.
In the spherical coordinates ( θ,φ)[ s e eF i g . 1(b)], the total
energy density G(m) is given by the sum of the demagnetiza-
tion energy, uniaxial anisotropic energy, and magnetic dipolarinteraction energy
G
dem(θ1,θ2)=1
22/summationdisplay
i=1m2
zi=1
22/summationdisplay
i=1cos2θi, (2)
Gu(θ1,φ1,θ2,φ2)=k
22/summationdisplay
i=1m2
xi=k
22/summationdisplay
i=1sin2θisin2φi, (3)
Gdip(θ1,φ1,θ2,φ2)=Adisc(dee)[3(m1·r)(m2·r)−m1·m2]
=Adisc(dee)[sinθ1sinθ2(sinφ1sinφ2
−2 cosφ1cosφ2)
+cosθ1cosθ2], (4)
where kis the uniaxial anisotropy constant, either a magnetic
anisotropy or a shape anisotropy. The easy-axis of theanisotropy is along the x-axis direction. Here, A
disc(dee)i s
the strength coefficient of the dipolar field that describes themagnetostatic interaction effect between the two nanopillars,andd
eeis the edge-to-edge separation distance. The vector
ris a unit vector of the displacement between two magnetic
dipoles. In order to improve the accuracy of our approximation,the dipolar interaction in Eq. ( 4) is treated as the interaction
between two circular uniformly magnetized discs (for detailssee Appendix A). The strength A
disc(dee) is more realistic than
the point dipoles strength Apoint(dee) due to the finite size
effect [ 53]. We find that, when the distance deeis smaller than
30 nm, then Adisc(dee) is significantly larger than Apoint(dee),
see Appendix A.
In order to get proper parameters and gain insight into
the phase-locking behavior, an approximation theory is intro-duced here. We assume that the free-layer magnetization isapproximately suppressed in the easy plane with θ
i∼π/2
due to the strong demagnetizing field. In this case, thesystem executes low-energy orbits, and the total magneticenergy density of the system can be approximately writtenas|G|∼k>|G
dip|∼Adisc(dee). These low-energy orbits
224410-2PHASE LOCKING OF SPIN-TORQUE NANO-OSCILLATOR . . . PHYSICAL REVIEW B 93, 224410 (2016)
FIG. 2. Effective potential energy Geff(φ+,φ−) for the (a) and (b) identical STNO pair and (c) and (d) nonidentical STNO pair at different
uniaxial anisotropy kand different current I. Three cross-sections taken at φ+=0,π/2,πare shown in the corresponding bottom panels of
each figure. Here, dee=20 nm, and Adisc(dee)=0.002. All parameters are marked in the figures.
satisfy [ θi(τ),φi(τ)]=[π/2+δθi(τ),φi(τ)](i=1,2), where
|δθi|∼√
k. If the damping constant and the STT strength
satisfy Eq. ( B13), then Eq. ( 1) can be rewritten as a pair of
Newton-like equations (see Appendix Bfor details)
¨φ1+α˙φ1=Adisc(dee)[−sin(φ1+φ2)−sinφ1cosφ2]
−k
2sin 2φ1+aJ1/parenleftbigg
θ1=π
2/parenrightbigg
, (5a)
¨φ2+α˙φ2=Adisc(dee)[−sin(φ1+φ2)−cosφ1sinφ2]
−k
2sin 2φ2+a21/parenleftbigg
θ2=π
2/parenrightbigg
, (5b)
where the effective force is dominated by the dipolar interac-
tion term (the first term of the right-hand side), the uniaxialanisotropy (the second term), and the STT term (the thirdterm). For simplicity, by using a new set of variables formedby the phase sum φ
+=φ1+φ2and the phase difference
φ−=φ1−φ2, we rewrite Eqs. ( 5a) and ( 5b)a s
d2φ+
dτ2+αdφ+
dτ=−∂G eff(φ+,φ−)
∂φ+, (6a)
d2φ−
dτ2+αdφ−
dτ=−∂G eff(φ+,φ−)
∂φ−, (6b)
where the effective potential energy is now given by
Geff(φ+,φ−)=Adisc(dee)(−3 cosφ+−cosφ−)
−kcosφ−cosφ++aJ+φ++aJ−φ−.(7)
Here,aJ+≡aJ1+aJ2andaJ−=aJ1−aJ2.A. An identical STNO pair
According to the design shown in Fig. 1, the STT
strength is the same for two identical PERP STNOs, thatis,a
J−=0 and aJ+=2aJ.F r o mE q .( 6a) with Eq. ( 7), by
setting |∂G eff/∂ φ+|>0, we obtain |aJ+|>3Adisc(dee)+k,
and under this condition, all equilibria of Geffalong the φ+-axis
direction are eliminated (Fig. 2). This condition indicates that
there exists a critical STT strength (or critical current) to drivethe two STNOs into a steady OP precessional state
|a
J1,c|=|aJ2,c|=(1/2)|aJ+,c|=(1/2)[3Adisc(dee)+k].
(8a)
Atdee=20 nm, we have Adisc(dee)=0.002 (Fig. 10in
Appendix A). In the absence of uniaxial anisotropy (i.e.
k=0), we further get the critical STT strength aJ+,c=0.006
and the current Ic=0.29 mA. Similarly, in the presence of
uniaxial anisotropy ( k=0.008), we have aJ+,c=0.014 and
Ic=0.68 mA.
Note that, when the current is larger than the critical value
given by Eq. ( 8a), the two STNOs can be driven into a
precessional state, but the precession may not be synchronous.Therefore, the synchronization or phase-locking state requiresadditional conditions. From Eqs. ( 6b) and ( 7), by setting
∂G
eff/∂(φ−)=0 and ∂2Geff/∂(φ−)2>0, the condition for
φ−=0 as the only stable equilibrium point in the range of
φ+∈[0,2π] can be derived
Adisc(dee)>k . (8b)
We would like to emphasize that Eq. ( 8b) guarantees that
the two free layers of the coupled system always evolve intoa final state with a stable phase difference beginning with anarbitrary initial state. If Eqs. ( 8a) and ( 8b) are simultaneously
satisfied, Eqs. ( 6a) and ( 6b) can be reduced to a single equation
224410-3CHEN, LEE, ZHANG, LIU, WU, HORNG, AND CHANG PHYSICAL REVIEW B 93, 224410 (2016)
of motion
¨φ+α˙φ=− (1/2)[3Adisc(dee)+k]s i n2φ−aJ, (9)
where φ≡(1/2)φ+=φ1=φ2andaJ≡(1/2)aJ+=aJ1=
aJ2. It should be noticed that Eq. ( 9) has the same form as
Eq. ( 5) for a single oscillator, but the anisotropy energy is
enhanced by including the dipolar coupling term 3 Adisc(dee).
Therefore, we conclude that Eqs. ( 8a) and ( 8b)a r et h e
necessary and sufficient conditions for the phase locking ofmagnetization precession of two nano-oscillators. On the otherhand, note from Eqs. (8) and ( 8b) that the anisotropy kcan raise
the threshold values of the dipolar strength A
disc, and of the
critical spin-transfer strength aJcas well. This analytical result
suggests that the reduction of anisotropy is a possible way toreduce the critical current as well as to enhance the stability ofa phase-locked array of STNOs.
In order to obtain a qualitative insight into Eq. (8), we regard
the dipolar coupled STNOs pair as an effective Newton-likeparticle moving on the energy surface G
eff.A ss h o w ni n
Fig. 2(a), in the absence of uniaxial anisotropy when the
current I=0.34 mA (larger than Ic=0.29 mA at k=0),
the energy surface will be tilted along −φ+direction by the
sum of the STT strengths aJ+. Because there are no stable
equilibrium points along the φ+axis, the particle will move
downward along the −φ+direction with an average terminal
velocity |/angbracketleft˙φ/angbracketright|τ=|aJ+|/α. Furthermore, the dipolar coupling
creates stable equilibrium points at φ−=0 on the energy
surface. The barrier height between the local equilibria alongtheφ
−axis is Adisc(dee), as is shown in the lower panel of
Fig.2(a). Due to energy dissipation, the particle will eventually
move downward along the ditch from any initial state withthe average terminal velocity |a
J+|/α, indicating that the
two STNOs precess in phase. In the presence of uniaxialanisotropy, as shown in Fig. 2(b), besides the elevation of
the critical current, also the cross-section shape of the ditchon the energy surface is changed with φ
+[see the lower panel
of Fig. 2(b)], meaning that uniaxial anisotropy is certainly
detrimental to phase locking.
B. A nonidentical STNO pair
Now we consider two nonidentical PERP STNOs. The non-
identical property may be caused by asymmetric STT strengths(that is, a
J−/negationslash=0) or by other parameters (for example, shape
difference). Similar to the identical case, by analytically setting|∂G
eff/∂ φ+|>0,∂G eff/∂(φ−)=0, and ∂2Geff/∂(φ−)2>0,
one can obtain the phase-locking conditions as the followingform:
|a
J+|>3Adisc(dee)+k, (10a)
Adisc(dee)>k , (10b)
and |aJ−|<A disc(dee)−k. (10c)
Here, Eq. ( 10c) guarantees the difference of STT strengths
is not so strong as to destroy the phase-locking state.Additionally, from the Eq. ( 10a), we can estimate that the
critical currents I
cin the absence and presence of the energy
kare 0.26 and 0.62 mA, respectively.
Assuming that the edge-to-edge distance deeis approxi-
mately 30 nm or less, the corresponding dipolar interactionstrength Adisc(dee) does not easily satisfy the condition of
Adisc(dee)>k. This circumstance is due to the fact that, for
the given value k=0.008, the value of Adisc(dee) is, according
to Fig. 10, smaller than kunless the separation deeis decreased
down to 5 nm. By inserting Eq. ( 7) into Eq. ( 6b), we now obtain
d2φ−
dτ2+αdφ−
dτ=− sin(φ−)[Adisc(dee)+kcos(φ+)]−aJ−,
(11)
The first term on the right-hand side of Eq. ( 11)i st h e
restoring force, in which the uniaxial anisotropy kactually
contains a prefactor rapidly varying in time cos( φ+). This is
because the φ+varies faster than the growth of the phase
difference φ−when|aJ−|is smaller than the dipolar interaction
strength Adisc(dee). Thus, the terminal velocity of the phase
difference |˙φ−|<A disc(dee)/αmust be smaller than that of the
phase sum |˙φ+|>(3Adisc(dee)+k)/α. Here, the perturbation
of anisotropy koscillates very fast compared to the phase
difference change, so that the perturbation can be omitted bythe approach presented below [ 54].
Taking a time average of φ
−in Eq. ( 6b) over a period of
/Delta1T=2π/|˙φ−|=2πA disc(dee)/α, one can easily find that the
contribution of the time-varying part in φ−becomes close
to zero, i.e. /angbracketleftcos(φ+)/angbracketright/Delta1T≈0. Therefore, the right-hand side
of Eq. ( 6b) takes on the form −Adisc(dee)s i n (φ−)−aJ−.
As a consequence, a soft phase-locking condition for thenonidentical pair of PERP STNOs is obtained
|a
J+|>3Adisc(dee)+k, (12a)
|aJ−|<A disc(dee). (12b)
These two Eqs. ( 12a) and ( 12b) are supported by numerical
solutions of Eqs. ( 6a) and ( 6b). When the above conditions are
satisfied, Eq. ( 6a) for phase sum φ+is rewritten as
d2φ+
dτ2+αdφ+
dτ=− [3Adisc(dee)+kcosφ+0]s i nφ+−aJ+,
(13)
in which φ−0is the stable, nonzero phase difference. Accord-
ingly, the phase-locked angular velocity is given by
|˙φ1|=|˙φ2|=1
2/vextendsingle/vextendsingle/vextendsingle/vextendsingled(φ
+)
dτ/vextendsingle/vextendsingle/vextendsingle/vextendsingle=1
2α|aJ+|.
From the viewpoint of the Newton-like particle, in the
absence of uniaxial anisotropy k=0, when the current I=
0.69 mA is larger than the critical value 0.26 mA, the energy
surface will not only be tilted along the −φ+direction by the
sum of the STT strengths aJ+, but will also be tilted along the
+φ−direction by the STT strength difference aJ−,a ss h o w n
in Fig. 2(c). Thus, the position of the ditch created by dipolar
coupling is shifted by aJ−slightly away from φ−=0, and
the barrier height between the local equilibriums along the φ−
axis is smaller than Adisc(dee), implying that the phase-locking
ability of dipolar coupling is weakened by negative aJ−values
[lower panel of Fig. 2(c)]. Due to the energy dissipation, the
particle will eventually move downward along the new ditchfrom any initial state, meaning that the two STNOs precesswith a small phase difference. However, similar to the identicalcomponents case, the uniaxial anisotropy still changes thestability of the local equilibrium points.
224410-4PHASE LOCKING OF SPIN-TORQUE NANO-OSCILLATOR . . . PHYSICAL REVIEW B 93, 224410 (2016)
III. NUMERICAL SIMULATIONS:
RESULTS AND DISCUSSION
In order to verify the analytical model, both macrospin and
full micromagnetic (FMM) simulations have been performedfor a coupled PERP STNO pair with dipolar magneticinteraction. In this section, we will show the time dependenceof the phase difference φ
−and the inclination angle θ,t h ex
andzcomponents of the precessional magnetization, and the
spectrum analysis of magnetization oscillation. Furthermore,the critical conditions for triggering phase locking of magneti-zation with a minimum current Iand a maximum edge-to-edge
distance d
eewill be discussed. The simulated parameter ranges
for phase locking will be compared with the results from theapproximate theory.
In this paper, both macrospin and FMM simulations are
conducted. The macrosopin code is developed in our groupindependently, and the micromagnetic simulations are carriedout by using two open micromagnetic codes, the finiteelement package magpar [ 55] and the finite difference package
MuMax3 [ 56]. In these simulations, we assume that the STNOs
have an elliptical shape with size 70 ×60 nm, and that the
free-layer thickness d=3 nm. For simplicity, we only focus
on the magnetization dynamics of the free layers. The initialmagnetization state is aligned along the xaxis (long axis of
the sample) direction. The thickness of the free layer is 3 nm.Typical material parameters are used for the Co free layer[16]: 4πM
s=1.09×104Oe (saturation magnetization), k=
0.008 (in-plane uniaxial anisotropy), A=2.5×10−11Jm−1
(exchange stiffness constant), α=0.02 (Gilbert damping
constant). The discretization cell size for MuMax3 is set at1×1n m×3 nm, while the magpar average size of tetrahedron
mesh is 2 nm. The spin polarization of the left STNO is setto be P
1=0.38 and /Lambda11=1.8. The right STNO is given
byP2=0.44,/Lambda1 2=2. Without dipolar interaction, the two
STNOs have different oscillation frequencies (we will showthis later) due to different spin polarizations.
In this paper, the current-induced Oersted field [ 57]i s
ignored. Our calculations indicate that the maximum valueof the Oersted field created by a current of 0.7 mA is ∼40 Oe
located in the perimeter zone of an isolated nanopillar (notshown). This is a reasonable estimation for considering theOersted fields created by current as an infinite wire. TheOersted field is therefore much smaller than other fieldssuch as the in-plane uniaxial anisotropy field ( ∼170 Oe)
and the demagnetizing field ( ∼1.09×10
4Oe). For a pair
of nanopillars horizontally arranged with an edge-to-edgeseparation changing from 5 to 20 nm, the calculated Oerstedfield is further reduced down to ∼25 Oe due to the cancellation
between the two STNOs. For this reason, the Oersted field isignored in this paper.
A. Synchronization of an STNO pair: Phase-locking state
First, a phase-locking state is obtained both from the
analytical theory and simulations: The injected current is setto be I=0.8 mA. Using the above parameter values and
θ
1=θ2=π/2, we analytically obtained the STT difference
|aJ−|=|aJ1−aJ2|=0.0017, which is smaller than the value
ofA(dee)=0.002, meaning that the analytical condition forphase locking shown in Eq. ( 12b) is satisfied. Numerically,
both the macrospin and micromagnetic simulations with theseparameters indicate that the phase-locking magnetization statecan be achieved within several nanoseconds, as shown in theupper panels of Figs. 3(a) and 3(c). In this paper, the total
simulation time is 50 ns. In order to show clearly the transientbehavior, the time scales in Fig. 3are confined to the initial
several nanoseconds. The phase-locking state has a small phasedifference φ
−=0.23 rad/πin the macrospin simulation and
0.34 rad/ πin the micromagnetic simulation. This nonzero φ−
corresponds to the position shift of equilibrium points [see
Fig. 2(b)], caused by aJ−. In addition, the phase-locking state
of the inclination angle θof the two STNOs has also been
achieved in both simulations, as shown in the lower panel ofFig.3(a). This phase locking of θcan also be inferred from the
locking of ˙φ, according to the conjugacy between the variables
ofφandθ[see Appendix B,E q .( B5)]. In other words, when
the locking of φoccurs (that is ˙φ
1=˙φ2),θ1must be equal to
θ2. Similarly, the phase locking can also be clearly seen from
the magnetization plot in Cartesian coordinates, as shown inFig. 3(b).
From Figs. 3(a)–3(c), one can see that there exists a transient
state before the STNO pair synchronizes into a stable phase-locked state. The typical time order of the transient state can betheoretically estimated from the Newton-like motion equationof Eq. ( 6b). As mentioned before, the uniaxial anisotropy kin
Eq. ( 6b) contains a fast time-varying prefactor cos( φ
+) which
makes it possible to neglect k.Therefore, Eq. ( 6b) can be
linearized close to the equilibrium point φ−∼0. For a small
angleδ(φ−), we have
d2δ(φ−)
dτ2+αdδ(φ−)
dτ=− {/radicalBig
[Adisc(dee)]2−(aJ−)2}δ(φ−).
The general solution δ(φ−)(τ) of this equation has a decay
factor e−(α/2)τ, in which τcan be defined as the time order of
the transient state. For example, if τ=460 for α=0.02 then
e−(α/2)τ∼1%. Furthermore, the real physical time tcan be
easily derived from the relation of τ=(4πMsγ)t. This yields
the transient time t=2.4 ns which is in good agreement with
our simulation results shown in Fig. 3.
Figure 3(d) shows the phase difference of the final state
φ−=φ1−φ2as a function of the injected current I,including
both the prediction curve of the approximate theory (blackline) and the simulation curves from macrospin (blue solidsquares) and micromagnetic (red open squares) calculations.From the approximate theory, the stable phase differencefor the softer (without k) phase-locking condition satis-
fies−A
disc(dee)s i n (φ−)−aJ−=0 and |aJ−/Adisc(dee)|<1.
Therefore, the relationship between φ−andI, and the max-
imum injected current for phase locking can be analyticallyobtained
φ
−=sin−1/bracketleftbigg
−/parenleftbigg/planckover2pi1
8πeM2
SV/parenrightbigg/Delta1ε
Adisc(dee)I/bracketrightbigg
,
|I|</parenleftbigg8πeM2
SV
/planckover2pi1/parenrightbiggAdisc(dee)
|/Delta1ε|. (14)
Here, /Delta1ε=ε1−ε2with P1=0.38,P2=0.44,/Lambda1 1=
1.8,/Lambda1 2=2, and θ1=θ2=π/2. Inserting all the pa-
rameters into Eq. ( 14), we obtain φ−=sin−1[1.087×I],
224410-5CHEN, LEE, ZHANG, LIU, WU, HORNG, AND CHANG PHYSICAL REVIEW B 93, 224410 (2016)
FIG. 3. The phase difference φ−=φ1−φ2and of the inclination angles θifor two nonidentical PERP STNOs. Macrospin simulations for
(a) the time evolution of θiand the phase difference φ−and (b) time evolution of the xandzcomponents of the free-layer magnetization.
The currents flowing through the STNO-1 and STNO-2 are 0.8 mA. The dipolar interaction strength is Adisc(dee)=0.002. (c) Micromagnetic
simulation for time evolution of φ−ave. Here, φ−aveis the spatial averaged phase difference between the two free layers. (d) The current
dependence of the phase difference φ−calculated from different models: The black curve for the approximate theory, the blue solid squares for
the macrospin simulation, and the red open squares for the micromagnetic simulations. Ic=0.618 mA denotes the threshold current predicted
by the approximation and ( Ic)M=0.5 mA by the macrospin simulation.
|I|<0.92 mA. It should be noted that the theoretical curve
predicted by Eq. ( 14) is quite close to the macrospin and
micromagnetic simulation results for the low-current case. Inthe high-current case, the Idependence of φ
−predicted by the
approximate theory is still quite close to the micromagneticresult, but a little different from the macrospin result. Inter-estingly, these results confirm that the angular profile of thedisc dipolar coupling used in the approximation theory (seeAppendix A) is quite reasonable. We would like to point out
that the approximation theory is in principle valid only forprecessions close to the thin film plane, i.e. for θ
i=π/2+δθi
and|δθi|∼√
k/lessmuch1, which corresponds to the case where
the STT reaches its maximum magnitude when the free-layermagnetization lies in the plane of the film [ 19], but our
calculations indicate that the dipolar coupling coefficient A
disc
can still be used if θ=0.34π=61.54◦forI=0.8m A .
Another interesting point is that the dependence of the
phase difference φ−=φ1−φ2on current in Fig. 3(d) shows
that the analytical curve is much closer to the micromagneticsimulation curve. We assume that unexpected behavior iscaused by the fact that the analytical theory is in principleonly valid for the case of magnetization precession close to
the film plane. At large currents, the phase difference can beenhanced in the analytical approximation by the fact that thehigh order terms of δθin the expansion of the STT torque
in Eqs. ( B7) and ( B8) have been eliminated. By contrast, in
the micromagnetic simulation, due to the nonuniformity ofthe local magnetization configuration, the calculated dipolarcoupling is actually smaller than that of the macrospin modelin the high-current region. As a result, the phase difference inthe micromagnetic simulation is enhanced at a large currentwhen compared with the macrospin simulation.
The critical current to excite magnetization oscillation can
be derived from Eq. ( 12a)
I
c=/parenleftbigg8πeM2
SV
/planckover2pi1/parenrightbigg/bracketleftbigg3Adisc(dee)+k
ε1+ε2/bracketrightbigg
. (15)
Note that, in Fig. 3(d), the theoretical critical current is Ic=
0.618 mA, which is slightly larger than that of the macrospin
(0.5 mA) and micromagnetic results (0.4 mA).
224410-6PHASE LOCKING OF SPIN-TORQUE NANO-OSCILLATOR . . . PHYSICAL REVIEW B 93, 224410 (2016)
FIG. 4. Frequency spectra of the two nonidentical STNOs calcu-
lated by the FFT technique from the time evolution of xcomponents
of the free-layer magnetization. The current is fixed to I=0.8m A
for each STNO. (a) Macrospin simulations: The blue curves show therespective frequency of the two STNOs in the case without dipolar
coupling; the red curve shows the frequency of the phase-locking state
in the case with dipolar coupling. (b) Micromagnetic simulations:The blue curves show the respective frequency of the two STNOs
without dipolar coupling, and the red curve shows the phase-locking
frequency by the dipolar coupling.
B. Frequency spectra of magnetization oscillations
The oscillation frequency can be calculated from the time
evaluation of magnetization. Figures 4(a) and 4(b) show
the oscillation frequency spectra for the STNO pair with(red curves) and without (blue curves) dipolar interactioneffect simulated by the macrospin and the micromagneticmodel, respectively. Here, the frequency spectra are calculatedfrom the xcomponents through the fast Fourier transform
(FFT) technique. The applied current for each STNO is0.8 mA. Note that both the macrospin and micromagneticsimulations display two separate oscillation frequencies (bluecurves) for the case without dipolar interaction betweenthe two STNOs. This corresponds to the case where theseparation d
ee=∞ orAdisc(dee)=0. The left STNO has a
low frequency (10.58 GHz in macrospin and 9.34 GHz inmicromagnetics) due to its relatively small spin-polarizationefficiency ( P
1=0.38,/Lambda1 1=1.8), while the right STNO has
a higher frequency (12.2 and 9.76 GHz for macrospin andmicromagnetic simulations, respectively).
When the separation is decreased to 20 nm [i.e. A
disc(dee)=
0.002], the frequency of the STNO pair is locked at a medium
FIG. 5. Precession frequency of two nonidentical STNOs as a
function of the current Icalculated from (a) approximation theory,
(b) macrospin simulation, and (c) micromagnetic simulation. The redcurves show the frequency for the STNO-1, the blue curves show
the frequency for the STNO-2, and the black curves show the phase-
locking frequency of the two STNOs through the dipolar coupling.The yellow background color regions show the current tunable range
to achieve the phase-locking state. The threshold currents to excite
precession states of STNO-1 and STNO-2 are indicated by I
c1and
Ic2, respectively. The threshold current for the phase-locking state of
the two STNOs is marked by Ic.
value, 11.39 GHz in the macrospin simulation and 9.7 GHz
in the micromagnetic simulations. This is shown by the redcurves in Figs. 4(a) and4(b). The synchronized frequency in
the macrospin simulation is exactly located at the center ofthe two separated blue peaks, while in the micromagneticsimulation, there is a little shift to that of STNO-2. Thisresult clearly confirms that, for a synchronized STNO pair, themagnetization of the two free layers precesses with the sameangular velocity ˙φas described by Eq. ( 13). The phase-locking
angular velocity ˙φis an average of the two original angular
velocities ˙φ
1,2.
Figure 5shows the current tunable range of the phase-
locking frequency in two nonidentical PERP STNOs. Themacrospin simulations for the two STNOs with P
1=
0.38,/Lambda11=1.8 and P2=0.44,/Lambda12=2a r es h o w nb yt h er e d
and blue branches in Fig. 5(b). The critical driving current Ic
is around 0.3 ∼0.4 mA. This critical value Iccan be estimated
224410-7CHEN, LEE, ZHANG, LIU, WU, HORNG, AND CHANG PHYSICAL REVIEW B 93, 224410 (2016)
from Eq. ( 5). From |aJ1,2|/greaterorequalslantk/2, one obtains
aJ01ε1(θ1=π/2,P1=0.38,/Lambda11=1.8)/greaterorequalslant0.008/2
aJ02ε2(θ2=π/2,P2=0.44,/Lambda12=2)/greaterorequalslant0.008/2.
The calculated critical current for the left STNO is thus
I1c=0.39 mA, and for the right one I2c=0.323 mA. We
attribute the lower critical current in the right STNO toits relatively larger P. The right STNO therefore requires a
relatively smaller current which can generate a strong enoughSTT to overcome the system barrier and then lead to amagnetization precession state. Note that, for current rangingfrom 0.4 to 1.2 mA, the macrospin simulation shows that thecurrent dependence of the precessional frequency is linear[Fig. 5(b)], which is consistent with the prediction of the
approximate theory [Fig. 5(a)]. Theoretically, an approximate
relationship between current and frequency can be derivedfrom Eq. ( 5) for a steady precession angular velocity |˙φ
1,2|=
|aJ1,2|/α,
f1,2(GHz) =|aJ1|
2πα(4πMsγ)
=/planckover2pi1(4πMsγ)
8πeM2sV(2πα)ε1,2(θ,P,/Lambda1 )I1,2
=/braceleftbigg
15.6×I1(mA)
18.9×I2(mA). (16)
As we have mentioned before, the synchronization fre-
quency of the two STNOs is an average value between theirindividual natural frequencies. From Eq. ( 14), the phase-
locking frequency as a function of current is given by theblack curve shown in Fig. 5(a). This result has been confirmed
by both macrospin and micromagnetic simulations, as shownin Figs. 5(b) and 5(c). On the other hand, compared with
individual STNO, it should be noticed that the critical currentfor the phase locking of the STNO pair increases due to thedipolar effect [Figs. 5(a) and5(b)], as indicated in Eq. ( 12a).
Note that, not only no synchronization is observed at a smallcurrent, but that the dipolar coupling effect will also failto achieve the phase-locking state for a very large current.This is caused by the enhanced frequency difference betweenthe two STNOs at an increased current [see Eq. ( 16)]. Our
simulations indicate that the effective current of phase lockingis 0.5–1.1 mA for the macrospin model and 0.4–0.8 mA forthe micromagnetic model.
The phase-locking state of the two nonidentical STNOs
precession strongly depends on the edge-to-edge distance d
ee
between the two nanopillars. This is due to the fact that the
dipolar coupling decreases with increasing distance. Figure 6
shows the onset of phase locking as a function of theseparation distance d
eefor a given current I=0.8m Afl o w i n g
through each nanopillar. Clearly, both the macrospin and themicromagnetic simulations show almost the same parameterrange of the phase-locking state. The maximum edge-to-edgedistance ( d
ee)Mis∼20 nm. Below this critical value, the two
STNOs have the same precessional frequency, implying thatthe dipolar coupling is strong enough to drive them into aphase-locked state. On the contrary, when the distance d
eeis
larger than this value, the two nonidentical STNOs lose phase,
FIG. 6. Precession frequencies of two nonidentical STNOs as a
function of the edge-to-edge distance dee. The injected current for
each STNO is I=0.8 mA. The yellow background color shows the
parameter region of the phase-locking synchronization state. ( dee)M
denotes the maximum edge-to-edge distance of the phase-locking
state. (a) Macrospin simulation results. The dipolar coupling strength
as a function of the edge-to-edge distance is taken from Fig. 10in
Appendix A. (b) Micromagnetic simulation results, in which the red
and blue curves are results from the MuMax3 and magpar simulation
codes, respectively.
and the frequency difference between them increases gradually
with increasing distance dee, showing the decreased frequency
in the left STNO, and the increased frequency in the right one.
Compared with the macrospin model, the locked frequency
in the micromagnetic simulations increases gradually withthe decrease of the separation d
ee. This interesting result can
be attributed to the following: For a small separation (e.g.d
ee=4 nm), the stray fields generated by the neighboring
STNO slightly reduce the nonuniformity of the magnetizationconfiguration. The increase of the uniform magnetization willin turn enhance the demagnetization fields. Therefore, theenhanced demagnetization field will increase the oscillationfrequency.
C. Phase-locking diagram
Finally, the phase diagrams of the two nonidentical STNO
pairs as a function of distance and current are summarizedin Fig. 7. The phase diagram is divided into three regions,
224410-8PHASE LOCKING OF SPIN-TORQUE NANO-OSCILLATOR . . . PHYSICAL REVIEW B 93, 224410 (2016)
FIG. 7. Phase diagrams as a function of the edge-to-edge distance deeand of the injected current I. (a) Prediction of the approximate theory.
(b) Macrospin simulation. (c) Micromagnetic simulation. The central blue region represents the phase-locking (PL) mode. The yellow region is
the steady (S) state without magnetization precession. The yellow region denotes the asynchronous (AS) precession mode. The border between
the PL and AS states is separated by ( dee)M.
including the steady state without magnetization precession
(S state), the phase-locking precession state (PL state), andasynchronous state (AS state). The boundary between S andPL is the threshold current I
c, defined in Fig. 5. The boundary
between the PL and AS states is the maximum edge-to-edgedistance ( d
ee)M, defined in Fig. 6. In the S state region, the
current is too small to trigger the free-layer magnetizationoscillation. In contrast, in the AS state region, the dipolarcoupling between the two STNOs is not strong enough to drivea phase-locking state. From Fig. 7, one can see that the phase
region of the approximation theory gives a good qualitativeprediction with the numerical simulations, indicating thatthe dipolar coupling strength A
disc(dee) estimated from the
assumption of uniformly magnetized thin film disc is quitereasonable for study of the phase-locking precession.
IV . SUMMARY
We show that the magnetic dipolar coupling between PERP
STNOs can be used as a driving force to synchronize a seriesof horizontally aligned nanopillar oscillators. In this paper, wehave developed an approximate theory for two identical ornonidentical STNOs to predict their stable phase-locking stateand the requisite parametric conditions. The theoretical pre-dictions have been well confirmed qualitatively by macrospinand micromagnetic simulations. We calculated the relationshipbetween the critical current of synchronization, the criticaldipolar coupling strength, the phase-locking frequency, andthe transient time as well. These results may open a startingpoint for the design of a reliable horizontal array of PERPSTNOs phase locked through the dipolar coupling effect. Thiswould represent an effective way to raise the output power ofSTNOs.
ACKNOWLEDGMENTS
This paper is supported by the National Basic Research
Program of China (Grants No. 2015CB921501 and No.2014CB921104). Z. Zhang thanks for the support fromNational Natural Science Foundation of China (Grants No.51222103, No. 51171047, and No. 11474067). Y . Liu thanksfor the support from NSFC of China (Grants No. 11274241and No. 51471118).APPENDIX A: APPROXIMATION THEORY
FOR CALCULATION OF MAGNETIC DIPOLAR
INTERACTION BETWEEN TWO CIRCULAR UNIFORMLY
MAGNETIZED DISCS
As shown in Fig. 8, for two uniformly magnetized circular
thin-film discs separated by an edge-to-edge distance dee,t h e
magnetic dipolar interaction can be calculated via integratingthe magnetostatic energy due to magnetic surface charges
A
disc/parenleftbiggπ
2,φ1,π
2,φ2/parenrightbigg
=1/parenleftbig
4πM2s/parenrightbig
V/contintegraldisplay
S1/contintegraldisplay
S2(σ1dS1)(σ2dS2)
η,
(A1)
Here, we assume that the magnetizations of the two discs
are aligned in the film plane, i.e. θ1=θ2=π/2. The surface
charge densities accumulated on the edges of two discs are
written as σ1=Mscos(φ1−φ/prime) and σ2=Mscos(φ2−φ/prime/prime),
where φ1andφ2are the φcoordinates of magnetizations,
andφ/primeandφ/prime/primeare the surface charge densities. The area
elements dS1=(Rd)dφ/primedz/primeanddS2=(Rd)dφ/prime/primedz/prime/prime, where
Ris the radius of the discs. The distance between any
pair of surface charges on the two discs is written as η=/radicalbig
[2R+dee+R(cosφ/prime/prime−cosφ/prime)]2+[R(sinφ/prime/prime−sinφ/prime)]2+(z/prime/prime−z/prime)2.
In fact, when the edge-to-edge distance deeis much larger than
FIG. 8. A top view of two uniformly magnetized circular discs.
The plus and minus signs represent the magnetic surface charge
distributions σ1(φ/prime)a n dσ2(φ/prime/prime).φ/primeandφ/prime/primeare the coordinates used to
designate the locations of σ1andσ2.ηis the distance between any
pair of magnetic surface charges between the two discs. φ1andφ2
are the magnetization directions, Ris the common radius of the two
discs, and deeis the edge-to-edge distance between them.
224410-9CHEN, LEE, ZHANG, LIU, WU, HORNG, AND CHANG PHYSICAL REVIEW B 93, 224410 (2016)
the disc thickness d,E q .( A1) can be well approximated by calculating the magnetic interaction between two uniformly magnetized
circle discs modeled by the inscribed regular npolygons
Adisc/parenleftbiggπ
2,φ1,π
2,φ2/parenrightbigg
≈1/parenleftbig
4πM2s/parenrightbig
Vlim
s,l→∞s−1/summationdisplay
n=0l−1/summationdisplay
m=0q1nq2m
η12. (A2)
Here, the magnetic surface charges accumulated on the nth and mth edges of the two discs are given by q1n=Mscos(φ1−
φn)×2Rsin(π
l)×dandq2m=Mscos(φ2−φm)×2Rsin(π
s)×d. In these expressions, landsdenote the edge numbers of two
regular npolygons. The distance between the two charges has the form
η12=/radicalBigg/bracketleftbigg
2R+dee+Rcos/parenleftbiggπ
s/parenrightbigg
cos(φm)−Rcos/parenleftbiggπ
l/parenrightbigg
cos(φn)/bracketrightbigg2
+/bracketleftbigg
Rcos/parenleftbiggπ
s/parenrightbigg
sin(φm)−Rcos/parenleftbiggπ
l/parenrightbigg
sin(φn)/bracketrightbigg2
.
In order to analyze the phase-locking behavior from the
point of view of dipolar interactions, a new set of variables(φ
+,φ−) are introduced to replace ( φ1,φ2). Note that, the
form of the angular profile of Adisc(φ+,φ−) is very similar
to that of point dipolar interaction Apoint (φ+,φ−), especially
in the locations of local energy maxima and minima, asshown in Fig. 9. However, when the distance d
eeis smaller
than 30 nm, the energy difference between local maximaand local minima of A
disc(φ+,φ−) along φ−direction is
obviously larger than that of Apoint(φ+,φ−). This means that
the dipolar coupling strength of two uniformly magnetizationdiscsA
disc(dee) is larger than that of two point magnetic dipoles
Apoint(dee). This is because, when the magnetizations of two
discs are placed in head-to-head or tail-to-tail configuration,they correspond to the local maximum of A
disc(φ+,φ−),
i.e.|φ−|=π. The magnetic energy comes mainly from the
surface charges with the same sign, which are accumulated onthe face-to-face edges of the two discs. The actual distancebetween any pair of magnetic charges is much smaller thanthe center-to-center distance 2 R+d
ee. Hence, for a smaller
dee, the maximum dipolar interaction significantly grows
with decreasing dee. Conversely, for configurations with local
minimum of Adisc(φ+,φ−), corresponding to the head-to-tail
or tail-to-head configuration, the minimum dipolar interactionbecomes significantly lower.
The energy difference between the local maxima and
minima of A
point (φ+,φ−) along φ−isApoint(dee)=
V/4π(2R+dee)3. Since Adisc(φ+,φ−)i ss i m i l a rt o Apoint
(φ+,φ−), the disc dipolar field strength Adisc(dee) can be
approximately estimated as the energy difference along φ−
between the local maxima and minima of Adisc(φ+,φ−).
Figure 10shows the comparison of Adisc(dee) andApoint(dee).
Obviously, the growth rate of Adisc(dee) is faster than that of
Apoint(dee) when deedecreases.
APPENDIX B: NEWTON-LIKE EQUATIONS
For the low-energy orbits with the total magnetic
energy density |G|∼k>|Gdip|∼Adisc(dee), the orbits
can be written as [ θi(τ),φi(τ)]=[π/2+δθi(τ),φi(τ)](i=
1,2), where |δθi|/lessmuch 1. In the absence of damping and
the STT effect, these orbits obey the energy con-servation law G
0(π/2,π/2,φ01,φ02)=G1(π/2+δθ1,π/2+
δθ2,φ11,φ12), where G0andG1denote the energies of the
initial and final states. By substituting Eqs. ( 3) and ( 4)i n t o
the energy conservation equation and expanding ( δθi)2on theright-hand side, one can easily obtain
1
22/summationdisplay
i=1(δθi)2≈k
22/summationdisplay
i=1(sin2φ0i−sin2φ1i)+Adisc(dee)
×[(sinφ01sinφ02−2 cosφ01cosφ02)
−(sinφ11sinφ12−2 cosφ11cosφ12)].(B1)
Thus, the order of magnitude of |δθi|∼√
k.
In the absence of Gilbert damping and the STT effect, by
substituting θi=π/2+δθiinto Eq. ( 2) and expanding it to
the first order of δθi, we obtain/braceleftBigg
δ˙θi=−∂G
∂φi
˙φi=∂G
∂δθi,(i=1,2). (B2)
Here, the total energy density Gis
G(δθ1,δθ2,φ1,φ2)=1
22/summationdisplay
i=1δθi2+k
22/summationdisplay
i=1sin2φi+Adisc(dee)
×(sinφ1sinφ2−2 cosφ1cosφ2).(B3)
Note that δθiandφiin Eq. (B2) form a set of conjugate
variables in the Hamiltonian formulation. Accordingly, aneffective Hamiltonian can be defined as
H(δθ
1,δθ2,φ1,φ2)=1
22/summationdisplay
i=1δθi2+k
22/summationdisplay
i=1sin2φi+Adisc(dee)
×(sinφ1sinφ2−2 cosφ1cosφ2),(B4)
and Eq. (B2) becomes/braceleftBigg
δ˙θi=−∂H
∂φi
˙φi=∂H
∂δθi,(i=1,2). (B5)
We can obtain an effective Lagrangian by introducing
the Legendre transformation L(φ1,φ2,˙φ1,˙φ2)=/summationtext2
i=1˙φiδθi−
H(δθ1,δθ2,φ1,φ2).
Thus, the effective Lagrangian is given by
L(φ1,φ2,˙φ1,˙φ2)=1
22/summationdisplay
i=1˙φ2
i−k
22/summationdisplay
i=1sin2φi−Adisc(dee)
×(sinφ1sinφ2−2 cosφ1cosφ2).
(B6)
The STT and the Gilbert damping torques are nonconser-
vative effects, and we therefore need to construct it from the
224410-10PHASE LOCKING OF SPIN-TORQUE NANO-OSCILLATOR . . . PHYSICAL REVIEW B 93, 224410 (2016)
FIG. 9. Magnetic dipolar coupling as a function of the phase sum
and the phase difference ( φ+,φ−). The edge-to-edge distance deeis
20 nm. The dipolar coupling profile is produced by two magnetic
dipoles which are arranged (a) horizontally and (b) by two uniformlymagnetized circular discs.
exact energy balance equation
dG
dτ=2/summationdisplay
i=1−/bracketleftbigg
α/vextendsingle/vextendsingle/vextendsingle/vextendsingledm
i
dτ/vextendsingle/vextendsingle/vextendsingle/vextendsingle2
+aJi(mi)(mi×p)·dmi
dτ/bracketrightbigg
.(B7)
Under the low-energy approximation, θi=π/2+δθi,
|δθi|∼√
k/lessmuch1, the energy Eq. ( B7) can be approximated
as
dG
dτ∼=−α2/summationdisplay
i=1/parenleftbig
δ˙θ2
i+˙φ2
i/parenrightbig
−2/summationdisplay
i=1aJi/parenleftbigg
θi=π
2/parenrightbigg
˙φi.(B8)
For a low-energy orbit, the order of magnitudes of |˙φi|and
|δ˙θi|in Eq. (B2) can be estimated as
/braceleftbiggδ˙θi∼−k
˙φ∼√
k,(i=1,2) (B9)
FIG. 10. The dependence of the dipolar coupling strength on
the edge-to-edge distance dee. The red circles represent the strength
produced by two magnetic dipoles in a horizontal array. The black
circles represent the strength produced by two uniformly magnetizedcircular discs in a horizontal array.
Here,|˙φi|/greatermuch|δ˙θi|. Therefore, the energy balance equation
can be further approximated in the form
dG
dτ∼=−α2/summationdisplay
i=1˙φ2
i−2/summationdisplay
i=1aJi/parenleftbigg
θi=π
2/parenrightbigg
˙φi. (B10)
Besides the damping effect, the contribution from the STT
is also taken rigorously into account. We then can easily definean effective dissipation function in the Lagrangian dynamics
F
dis≡1
2α2/summationdisplay
i=1˙φ2
i+2/summationdisplay
i=1aJi/parenleftbigg
θi=π
2/parenrightbigg
˙φi. (B11)
From the Euler-Lagrangian equations with dissipation,
Eq. ( 5) is obtained.
Equation ( 5) is formally equivalent to
/braceleftBiggδ˙θi+α˙φi+aJi/parenleftbig
θi=π
2/parenrightbig
=−∂G
∂φi
˙φi=∂G
∂δθi,(i=1,2), (B12)
and if the magnitudes of |δ˙θi|,|˙φi|,|∂G/∂φ i|, and|∂G/∂δθ i|
are on the same order as those in Eq. (B2), then the necessaryconditions for the validity of Eq. ( 5)a r e
/braceleftBigg
α/lessorequalslant√
k,/vextendsingle/vextendsingleaJi/parenleftbig
θi=π
2/parenrightbig/vextendsingle/vextendsingle∼k, (i=1,2). (B13)
Finally, we would like to point out that a closely related
analytical work by using Lagrangian approach was presentedin Ref. [ 58], in which spin-wave normal modes have been
studied in a single STT nanopillar device.
224410-11CHEN, LEE, ZHANG, LIU, WU, HORNG, AND CHANG PHYSICAL REVIEW B 93, 224410 (2016)
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224410-12 |
PhysRevB.100.054506.pdf | PHYSICAL REVIEW B 100, 054506 (2019)
Electrical control of magnetization in superconductor /ferromagnet /superconductor junctions on a
three-dimensional topological insulator
M. Nashaat,1,2I. V . Bobkova ,3,4A. M. Bobkov,3Yu. M. Shukrinov,1,5I. R. Rahmonov,1,6and K. Sengupta7
1BLTP , Joint Institute for Nuclear Research, Dubna, Moscow Region, 141980, Russia
2Department of Physics, Cairo University, Cairo, 12613, Egypt
3Institute of Solid State Physics, Chernogolovka, Moscow reg., 142432, Russia
4Moscow Institute of Physics and Technology, Dolgoprudny, 141700, Russia
5Dubna State University, Dubna, 141980, Russia
6Umarov Physical Technical Institute, TAS, Dushanbe, 734063, Tajikistan
7School of Physical Sciences, Indian Association for the Cultivation of Science, Jadavpur, Kolkata-700032, India
(Received 29 April 2019; published 6 August 2019)
Strong dependence of the Josephson energy on the magnetization orientation in Josephson junc-
tions with ferromagnetic interlayers and spin-orbit coupling opens a way to control magnetization byJosephson current or Josephson phase. Here we investigate the perspectives of magnetization control insuperconductor /ferromagnet /superconductor (S /F/S) Josephson junctions on the surface of a 3D topological
insulator hosting Dirac quasiparticles. Due to the spin-momentum locking of these Dirac quasiparticles astrong dependence of the Josephson current-phase relation on the magnetization orientation is realized. It isdemonstrated that this can lead to splitting of the ferromagnet’s easy axis in the voltage driven regime. We showthat such a splitting can lead to stabilization of an unconventional fourfold degenerate ferromagnetic state.
DOI: 10.1103/PhysRevB.100.054506
I. INTRODUCTION
By now it is well known that current-phase relation (CPR)
in Josephson junctions with multilayered ferromagnetic in-terlayers is strongly sensitive to the mutual orientation of
the magnetizations in the layers [ 1–12]. CPRs of Joseph-
son junctions with ferromagnetic interlayers in the presenceof spin-orbit coupling also depends on the magnetizationorientation. This occurs primarily via the appearance ofthe magnetization-dependent anomalous phase shift [ 13–26].
This coupling between the Josephson and magnetic subsys-tems leads to the supercurrent-induced magnetization dynam-
ics [ 1,6,27–32]. In particular, the reversal of the magnetic
moment by the supercurrent pulse [ 33] was predicted. A
unique possibility of controlling the magnetization dynamicsvia external bias current and series of specific magnetizationtrajectories has been reported [ 34]. In Refs. [ 27,35]i tw a s
also reported that in the presence of spin-orbit coupling thesupercurrent can cause reorientation of the magnetization easy
axis. Assuming the initial position of the easy axis along the
zdirection these works demonstrate that under the applied
supercurrent stable position of the magnetization becomesbetween zandyaxes depending on parameters of the system.
Here we investigate prospects of superconductor /
ferromagnet /superconductor (S /F/S) Josephson junctions
constructed atop a three-dimensional topological insulator
(3D TI) surface, which hosts Dirac quasiparticles, in the
field of supercurrent-induced magnetization control. Ourmotivation is that these Dirac quasiparticles on the surface ofthe 3D TI exhibit full spin-momentum locking: An electronspin always makes a right angle with its momentum. Thisgives rise to a very pronounced dependence of the CPRon the magnetization direction [ 17,36,37]. In particular,
the anomalous ground state phase shift proportional to thein-plane magnetization component perpendicular to thesupercurrent direction was reported.
The second reason to study magnetization dynamics in
such a system is that at present there is a great progressin experimental realization of F /TI hybrid structures. In
particular, to introduce the ferromagnetic order into the TI,random doping of transition metal elements, e.g., Cr or V , hasbeen employed [ 38–41]. The second option, which has been
successfully realized experimentally, is a coupling of the non-magnetic TI to a high T
cmagnetic insulator to induce strong
exchange interaction in the surface states via the proximityeffect [ 42–46].
Here we demonstrate that the anomalous phase shift causes
the magnetization dynamics analogously to the case of aspin-orbit coupled system. However, in contrast to the spin-orbit coupled systems, where the magnetization dynamicswas studied before, for the system under consideration theabsolute value of the critical current also depends stronglyon the magnetization orientation. It only depends on the in-plane magnetization component along the current direction.We demonstrate that such dependence, in a suitably cho-sen voltage-driven regime, can lead to supercurrent inducedsplitting of the magnetic easy axis of the ferromagnet. Weshow that this effect may lead to stabilization of a fourfolddegenerate ferromagnetic state, which is in sharp contrast tothe conventional twofold degenerate easy-axis ferromagneticstate.
The paper is organized as follows. In Sec. IIwe derive
a CPR for the S /F/S junction atop a topological insula-
tor surface starting from the quasiclassical Green function
2469-9950/2019/100(5)/054506(7) 054506-1 ©2019 American Physical SocietyM. NASHAAT et al. PHYSICAL REVIEW B 100, 054506 (2019)
FIG. 1. Sketch of the system under consideration. Superconduct-
ing leads and a ferromagnetic interlayer are deposited on top of the
TI insulator.
formalism. This is followed by a discussion of the mag-
netization dynamics of such systems in Sec. III. Next, in
Sec. IV, we discuss the stabilization of the fourfold degenerate
ferromagnetic state. Finally, we conclude in Sec. V.
II. CURRENT-PHASE RELATION IN A BALLISTIC S /F/S
J U N C T I O NO NA3 DT I
The sketch of the system under consideration is presented
in Fig. 1. Two conventional s-wave superconductors and a
ferromagnet are deposited on top of a 3D TI insulator to forma Josephson junction.
First of all, we consider a current-phase relation of a
Josephson junction. The interlayer of the junction consists ofthe TI conducting surface states with a ferromagnetic layer ontop of it. It is assumed that the magnetization M(r)o ft h ef e r -
romagnet induces an effective exchange field h
eff(r)∼M(r)
in the underlying conductive surface layer. The Hamiltonianthat describes the TI surface states in the presence of anin-plane exchange field h
eff(r) reads:
ˆH=/integraldisplay
d2r/primeˆ/Psi1†(r/prime)ˆH(r/prime)ˆ/Psi1(r/prime), (1)
ˆH(r)=−ivF(∇×ez)ˆσ+heff(r)ˆσ−μ, (2)
where ˆ/Psi1=(/Psi1↑,/Psi1↓)T,vFis the Fermi velocity, ezis a unit
vector normal to the surface of TI, μis the chemical potential,
and ˆσ=(σx,σy,σz) is a vector of Pauli matrices in the spin
space. It was shown [ 37,47] that in the quasiclassical approx-
imation ( heff,ε,/Delta1 )/lessmuchμthe Green’s function has the fol-
lowing spin structure: ˇ g(nF,r,ε)=ˆg(nF,r,ε)(1+n⊥σ)/2,
where n⊥=(nF,y,−nF,x,0) is the unit vector perpendicular
to the direction of the quasiparticle trajectory nF=pF/pF
and ˆgis the spinless 4×4 matrix in the particle-hole and
Keldysh spaces containing normal and anomalous quasiclas-sical Green’s functions. The spin structure above reflectsthe fact that the spin and momentum of a quasiparticle atthe surface of the 3D TI are strictly locked and make aright angle. Following standard procedures [ 48,49]i tw a s
demonstrated [ 37,47,50] that the spinless retarded Green’s
function ˆ g(n
F,r,ε) obeys the following transport equations
in the ballistic limit:
−ivFnFˆ∇ˆg=[ετz−ˆ/Delta1,ˆg]⊗, (3)
where [ A,B]⊗=A⊗B−B⊗Aand A⊗B=exp[( i/2)
(∂ε1∂t2−∂ε2∂t1)]A(ε1,t1)B(ε2,t2)|ε1=ε2=ε;t1=t2=t.τx,y,zare
Pauli matrices in particle-hole space with τ±=(τx±iτy)/2.ˆ/Delta1=/Delta1(x)τ+−/Delta1∗(x)τ−is the matrix structure of the
superconducting order parameter /Delta1(x) in the particle-hole
space. We assume /Delta1(x)=/Delta1e−iχ/2/Theta1(−x−d/2)+
/Delta1eiχ/2/Theta1(x−d/2). The spin-momentum locking allows
for including heffinto the gauge-covariant gradient
ˆ∇ˆA=∇ˆA+(i/vF)[(hxey−hyex)τz,ˆA]⊗.
Equation ( 3) should be supplemented by the normaliza-
tion condition ˆ g⊗ˆg=1 and the boundary conditions at x=
∓d/2. As we assume that the Josephson junction is formed at
the surface of the TI, the superconducting order parameter /Delta1
andheffare effective quantities induced in the surface states
of TI by proximity to the superconductors and a ferromagnet.In this case there are no reasons to assume existence ofpotential barriers at the x=∓d/2 interfaces and we consider
these interfaces as fully transparent. In this case the boundaryconditions are extremely simple and are reduced to continuityof ˆgfor a given quasiparticle trajectory at the interfaces.
To obtain the simplest sinusoidal form of the current-phase
relation we linearize Eq. ( 3) with respect to the anomalous
Green’s function. In this case the retarded component ofthe Green’s function ˆ g
R=τz+fRτ++˜fRτ−. The anomalous
Green’s function obeys the following equation:
−1
2ivF,x∂xfR+heffn⊥fR=εfR−/Delta1(x). (4)
Equation for ˜fRis obtained from Eq. ( 4)b yvF→−vF,/Delta1→
−/Delta1, andχ→−χ.
The solution of Eq. ( 4) satisfying asymptotic conditions
fR→(/Delta1/ε)e±iχ/2atx→± ∞ and continuity conditions at
x=∓d/2 takes the form [the solution is written for x∈
(−d/2,d/2), the solution in the superconducting leads is also
found, but it is not required for finding the Josephson current]:
fR
±=/Delta1e∓iχ/2
εexp/bracketleftbigg∓2i(heffn⊥−ε)(d/2±x)
vx/bracketrightbigg
,
(5)
˜fR
±=−/Delta1e∓iχ/2
εexp/bracketleftbigg∓2i(heffn⊥−ε)(d/2∓x)
vx/bracketrightbigg
,
where the subscript ±corresponds to the trajectories
sgnvx=±1.
The density of electric current along the xaxis is
jx=−eNFvF
4/integraldisplay∞
−∞dε/integraldisplayπ/2
−π/2dφ
2πcosφ
×[(gR
+⊗ϕ+−ϕ+⊗gA
+)−(gR
−⊗ϕ−−ϕ−⊗gA
−)],
(6)
where φis the angle, which the quasiparticle trajectory makes
with the xaxis.ϕ±is the distribution function corresponding
to the trajectories sgn vx=±1.
Here we consider the voltage-biased junction. In principle,
in this case the electric current through the junction consistsof two parts: the Josephson current j
sand the normal current
jn. The Josephson current is connected to the presence of
the nonzero anomalous Green’s functions in the interlayerand takes place even in equilibrium. Here we assume thelow applied voltage regime eV /(k
BTc)/lessmuch1. In this case the
deviation of the distribution function from equilibrium is weakand can be disregarded in the calculation of the Josephsoncurrent: ϕ
+=ϕ−=tanh(ε/2T). Exploiting the normaliza-
054506-2ELECTRICAL CONTROL OF MAGNETIZATION IN … PHYSICAL REVIEW B 100, 054506 (2019)
tion condition one can obtain gR
±≈1−fR
±˜fR
±/2. Taking into
account that gA
±=−gR∗
±we find the following final expression
for the Josephson current:
js=jcsin(χ−χ0), (7)
jc=evFNFT/summationdisplay
εn>0/integraldisplayπ/2
−π/2dφcosφ/Delta12
ε2n
×exp/bracketleftbigg
−2εnd
vFcosφ/bracketrightbigg
cos/bracketleftbigg2hxdtanφ
vF/bracketrightbigg
, (8)
χ0=2hyd/vF, (9)
where εn=πT(2n+1). At high temperatures T≈Tc/greatermuch/Delta1
the main contribution to the current comes from the lowestMatsubara frequency and Eq. ( 8) can be simplified further
j
c=jb/integraldisplayπ/2
−π/2dφcosφ
×exp/bracketleftbigg
−2πTd
vFcosφ/bracketrightbigg
cos/bracketleftbigg2hxdtanφ
vF/bracketrightbigg
, (10)
where jb=evFNF/Delta12/(π2T). A similar expression has al-
ready been obtained for Dirac materials [ 50]. The normal
current is due to deviation of the distribution function fromthe equilibrium. However, for the system under consideration,where we assume the ferromagnet to be metallic, practicallyall the normal current flows through the ferromagnet becausein real experimental setups the TI resistance should be muchlarger as compared to the resistance of the ferromagnet. Asfor the Josephson current, it is carried by Cooper pairs andis strongly suppressed inside the ferromagnetic layer becausethe exchange field there is typically much larger as comparedto the induced exchange field h
effin the TI surface layer.
Therefore, it flows through the TI surface states and we canassume that it is equal to the total electric current flowing viatheTI surface states .
III. MAGNETIZATION DYNAMICS INDUCED BY A
COUPLING TO A JOSEPHSON JUNCTION
The dynamics of the ferromagnet magnetization can be
described in the framework of the Landau-Lifshitz-Gilbert(LLG) equation
∂M
∂t=−γM×Heff+α
MsM×∂M
∂t, (11)
where Msis the saturation magnetization, γis the gyromag-
netic ratio, and Heffis the local effective field. The electric
current flowing through the TI surface states causes spin-orbital torque [ 51–54] due to the presence of a strong coupling
between a quasiparticle spin and momentum. In principle, ifthe ferromagnetism and spin-orbit coupling spatially coexist,this torque is determined by the total electric current flowingthrough the system. However, for the case under considerationonly the supercurrent flows via the TI surface states, wherethe spin-momentum locking takes place. Therefore, only thissupercurrent generates a torque acting on the magnetiza-tion. The normal current flows through the homogeneousferromagnet, where we assume no spin-orbit coupling. Con-
sequently, it does not contribute to the torque.
The torque caused by the supercurrent can be accounted
for as an additional contribution to the effective field. In orderto find this contribution we can consider the energy of thejunction as a sum of the magnetic and the Josephson energies:
E
tot=EM+EJ, (12)
where the Josephson energy EJ=Ec[1−cos(χ−χ0)] with
Ec=/Phi10Ic/2π,Ic=jcS(Sis the junction area) and χ=
2e Vtin the presence of the applied voltage. EM=
−KVFM2
y/2M2
sis the uniaxial anisotropy energy with the easy
axis assumed to be along the yaxis. VFis the volume of the
ferromagnet. The effective field Heff=−(1/VF)(δEtot/δM)
and takes the form:
Heff,x
HF=/Gamma1/bracketleftbigg/integraldisplayπ/2
−π/2e−˜d/cosφsinφsin(rmxtanφ)dφ/bracketrightbigg
×[1−cos(/Omega1Jt−rmy)], (13)
Heff,y
HF=/Gamma1/bracketleftbigg/integraldisplayπ/2
−π/2e−˜d/cosφcosφcos(rmxtanφ)dφ/bracketrightbigg
×sin(/Omega1Jt−rmy)+my, (14)
Heff,z=0, (15)
where we have introduced the unit vector m=M/Ms,
˜d=2πTd/vFis the dimensionless junction length, /Gamma1=
/Phi10jbSr/2πKVFis proportional to the ratio of the Joseph-
son and magnetic energies, r=2dheff/vF,/Omega1J=2e V i s t h e
Josephson frequency, and HF=/Omega1F/γ=K/Ms.
The effective field consists of two contributions: The
anisotropy field, which is directed along the easy axis, isrepresented by the last term in Eq. ( 14). The other terms
are generated by the supercurrent. The same approach tostudy magnetization dynamics in voltage biased junctionshas already been applied to systems with spin-orbit couplingin the interlayer [ 27,35]. The qualitative difference of our
system based on the TI surface states from these works is thatthe critical current demonstrates strong dependence on the x
component of magnetization in our case, while it has beenconsidered as independent on the magnetization directionearlier. This dependence leads to nonzero H
eff,x∼mxat small
mx. This means that the easy yaxis can become unstable in
a voltage-driven or current-driven junction, while this axisis always stable if the critical current does not depend onmagnetization direction. Moreover, there is no difference forthe system between ±m
xcomponents of the magnetization.
This leads to the remarkable fact that in a driven system theeasy axis is not reoriented keeping two stable magnetizationdirections, as has already been obtained before, but is splitdemonstrating four stable magnetization directions. In the
following section we study this effect in detail.
IV . MAGNETIZATION EASY AXIS SPLITTING
It is obvious that mx=mz=0 is an equilibrium point of
Eq. ( 11) with Heffdetermined by Eqs. ( 13)–(15). Now we
investigate stability of this point. In the linear order with
054506-3M. NASHAAT et al. PHYSICAL REVIEW B 100, 054506 (2019)
respect to mxthe effective field can be written as follows:
Heff,x=AHFmx[1−cos(/Omega1Jt−r)],
Heff,y=HF[1+Bsin(/Omega1Jt−r)], (16)
where A>0 and B>0 are constants. By comparing Eqs. ( 16)
and ( 13) it is seen that
A=r/Gamma1/integraldisplayπ/2
−π/2e−˜d/cosφsinφtanφdφ. (17)
The LLG equation ( 11) in the linear order with respect to mx
andmztakes the form
˙mx=γ
1+α2[Heff,y(mz−αmx)+αHeff,x],
(18)
˙mz=γ
1+α2[−Heff,y(mx+αmz)+Heff,x],
while ˙ my=0.
One can estimate the parameter /Omega1F//Omega1J∼γHF/(eIcRn)
for 3D TI Josephson junctions. Taking IcRn∼10−3V, as has
been reported for Nb /Bi2Te3/Nb Josephson junctions [ 55],
and the easy-axis anisotropy field HF∼500 Oe, what was
reported for Py [ 56,57], we obtain /Omega1F//Omega1J∼3×10−3.I n
the regime /Omega1F//Omega1J/lessmuch1 the magnetization varies slowly at
t∼/Omega1−1
J, therefore we can average Eqs. ( 18) over a Josephson
period thus obtaining the following system:
˙mx=/Omega1F
1+α2[mz−α(1−A)mx],
(19)
˙mz=/Omega1F
1+α2[−(1−A)mx−αmz].
The general solution of this system takes the form mx(z)=/summationtext
k=1,2Ck,x(z)exp[λkt]. The equilibrium point mx=mz=0
becomes unstable under the condition Re λ1>0o rR e λ2>0.
One can obtain that it is realized at A>1.
It is rather difficult to make accurate estimates of the nu-
merical value of Afor realistic parameters. The main problem
is the absence of experimental data on the value of heff.H o w -
ever, if we take K=500 J/m3from the measurements [ 58]
on permalloy with very weak anisotropy, Ic=10μA,vF∼
105m/c from Ref. [ 55] and the permalloy volume d×
l×w∼100 nm ×10 nm ×50 nm, then we can obtain A∼
r/Gamma1∼Icheff/(vFeKlw)∼0.4–8 for heff∼10–200 K. There-
fore, we can conclude that the range of Avalues discussed in
our work should be experimentally accessible.
Now we turn to study the stationary points of the magne-
tization and their stability. Beyond the linear approximation(with respect to m
xandmz) it is convenient to parametrize the
magnetization as m=(sin/Theta1cos/Phi1,cos/Theta1,sin/Theta1sin/Phi1). Then
from the LLG equation one obtains
˙/Theta1=γ
1+α2[−αHeff,ysin/Theta1
+Heff,x(sin/Phi1+αcos/Theta1cos/Phi1)],
˙/Phi1sin/Theta1=γ
1+α2[−Heff,ysin/Theta1
+Heff,x(−αsin/Phi1+cos/Theta1cos/Phi1)].(20)
At/Omega1F//Omega1J→0 effective fields Heff,x,ydetermined by
Eqs. ( 13), (14) should be averaged over a Josephson period0. 0. 1.0 1.5 2.0.0.0.0.0.1.00. 0. 1.0 1.5 2.0.0.0.0.0.1.00. 0. 1.0 1.5 2.0.0.0.0.0.1.00. 0. 1.0 1.5 2.0.0.0.0.0.1.0
ΦΘΘΘΘ
0π
2π0π
2π0π
2π0π
2π
0π
2π3π
22π(a)
(b)
(c)
(d)
FIG. 2. Vector fields according to Eq. ( 20). (a) A=0.90 (/Gamma1=
1.26), (b) A=1.05 (/Gamma1=1.46), (c) A=1.25 (/Gamma1=1.84), (d) A=
1.50 (/Gamma1=2.10).r=0.5,˜d=0.3,α=0.25 for all the panels. Blue
points indicate unstable stationary solutions, and the stable solutions
are marked by red points.
Heff,x,y→/angbracketleftHeff,x,y/angbracketright. The stationary points are to be found as
solutions of Eqs. ( 20) corresponding to ˙/Theta1=˙/Phi1=0.
Figure 2shows vector fields in the plane 0 /lessorequalslant/Phi1< 2π,
0/lessorequalslant/Theta1<π according to Eq. ( 20) at four different values of
A. The stationary solutions are indicated by color points. The
blue points correspond to unstable stationary solutions, whilethe red points indicate the stable magnetization directions.The Gilbert damping constant α=0.25. We have chosen such
a large unrealistic value of the Gilbert constant in order toclearly show the stability /instability of the stationary points
because for α=0.01, which is more appropriate for a realistic
situation, stability /instability of a solution is not clearly seen
in the figure [compare Figs. 3(a) and3(b)], although in fact
the topology of the vector field is not changed. Figure 2(a)
054506-4ELECTRICAL CONTROL OF MAGNETIZATION IN … PHYSICAL REVIEW B 100, 054506 (2019)
0.0 0.5 1.0 1.5 2.00.00.20.40.60.81.00. 0. 1.0 1.5 2.0.0.0.0.0.1.0
ΦΘΘ
0π
2π0π
2π
0π
2π3π
22π(a)
(b)
FIG. 3. (a) Vector field corresponding to the parameters of Fig. 4,
but for /Omega1F//Omega1J→0. (b) The same as in panel (a), but for α=0.25
in order to demonstrate stability /instability of the stationary points.
represents the regime A<1, when the only stable solutions
mstaremst
y=±1, which corresponds to upper and bottom
horizontal lines in the figure. Panels (b) and (c) demonstratethe vector fields in the regime of not very large A>1. Four
stable red points are clearly seen. Upon further increase ofAthe stable points get closer to /Theta1=π/2 and finally merge
into two stable points at some A
crit, as is shown in Fig. 2(d).
Therefore, there exists a finite range of 1 <A<Acrit, where
the ferromagnet has four stable magnetization directions inthe voltage-biased regime considered here. From Fig. 2it is
seen that all the stationary points correspond to m
z=±1o r
mz=0. The stationary points mz=±1 are always unstable.
Let us consider the stationary points corresponding to mz=0,
that is /Phi1=0,π. It is obvious that in order to have four
stable points |mst
x|and|mst
y|should be nonzero simultaneously.
Substituting mz=0 into Eq. ( 20) and taking into account
that/angbracketleftHeff,y/angbracketright=HFmy, we obtain that mst
xcan be determined
from the simple nonlinear equation mx=/angbracketleftHeff,x/angbracketright/HF.T h i s
equation always has the solution mx=0, but at 1 <A<Acrit
it also has the second nonzero solution mst
x. In this situation
there are four stable points mst=(±|mst
x|,±|mst
y|,0).
Further in Fig. 4we demonstrate the full time evolution of
the magnetization mobtained from the numerical solution of
the LLG equation. It is seen that starting from different initialconditions it is possible to reach all four stable magnetizationsolutions. The results are obtained at /Omega1
F//Omega1J=0.2, but the
averaged values of magnetization at large times are in goodagreement with the results for stable points obtained in thelimit/Omega1
F//Omega1J/lessmuch1, which are demonstrated in Fig. 3(a) for
the same parameters /Gamma1,r,α, and d. Figure 3(b) only differs
from (a) by the value of α=0.25. While the topology of
the vector fields presented in panels (a) and (b) is the same,the stability /instability of all the stationary points is more
clearly seen for larger values of the damping constant α.A t
FIG. 4. Time evolution of the magnetization starting from
different initial conditions. (a) mx(t=0)=−0.6,my(t=0)=
0.8, (b) mx(t=0)=0.6,my(t=0)=0.8, (c) mx(t=0)=−0.6,
my(t=0)=−0.8, and (d) mx(t=0)=0.6,my(t=0)=−0.8. For
all the panels we take mz(t=0)=0. The four panels correspond
to four possible stable states, which are reached by the system atlarge t./Gamma1=1.57,r=0.5,˜d=0.3,α=0.01,/Omega1
F//Omega1J=0.2; time
is measured in units of /Omega1−1
J.
finite values of /Omega1F//Omega1Jthe magnetization oscillates around
the vector trajectory presented in Fig. 3and the amplitude of
the oscillations is suppressed at /Omega1F//Omega1J→0.
In order to show that the system under consideration can
demonstrate spontaneous behavior we investigate the system
FIG. 5. Time evolution of the magnetization starting from an
unstable point with the initial condition mx=my=0a n d mz=1
in the presence of noise. The four panels correspond to four possible
stable states, which are reached by the system at large t./Gamma1=1.57,
r=0.5,˜d=0.3,α=0.01,/Omega1F//Omega1J=0.2; time is measured in units
of/Omega1−1
J.
054506-5M. NASHAAT et al. PHYSICAL REVIEW B 100, 054506 (2019)
FIG. 6. (a) Averaged values of magnetization components at
large times as functions of /Omega1J//Omega1F.˜d=0.2,/Gamma1=1.62. (b) The same
as functions of /Gamma1.˜d=0.2,/Omega1J//Omega1F=5. (c) The same as functions
of˜d./Omega1F//Omega1J=0.2,/Gamma1=1.62. For all the panels r=0.5,α=0.01.evolution starting from one of the unstable points mz=±1. A
small noise is introduced to the system in order to allow forleaving the unstable equilibrium point. From the vector fieldsrepresented in Fig. 3(a) it is seen that at small values of α
the system finally comes to one of the four stable states withpractically equal probabilities. It is shown in Fig. 5, where
different panels correspond to all the possible final states.
Figure 6demonstrates the behavior of the absolute values
of averaged magnetization at t→∞ depending on essential
parameters of the system. The dependence on /Omega1
J//Omega1Fis
represented in Fig. 6(a). It is seen that at /Omega1J//Omega1F/greatermuch1|/angbracketleftmi/angbracketright|
tend to constant values and, in particular, |/angbracketleftmz/angbracketright| → 0, as it
follows from our analysis of stationary points of Eqs. ( 20).
The dependence on /Gamma1is plotted in Fig. 6(b)./Gamma1is linearly
proportional to A. For this reason one can explicitly see in this
panel the range of Awhere four stable limiting magnetization
directions exist: it corresponds to the regions where |/angbracketleftmx/angbracketright|and
|/angbracketleftmy/angbracketright|are nonzero simultaneously.
Panel (c) of Fig. 6represents the dependence of |/angbracketleftmi/angbracketright|on
the junction length. Analogously to the previous panel, therange of existence of four stable limiting magnetization direc-tions is also clearly seen. The dependence on ris qualitatively
very similar to the dependence on /Gamma1, therefore we do not
represent it. Figures 6(b) and6(c) also provide the optimal
range of parameters /Gamma1and dfor experimental realization
of the easy axis splitting. The effect can be experimentallyinvestigated, for example, by measuring the magnetic fieldpattern away from the nanomagnet.
V . CONCLUSIONS
In this work we study a S /F/S Josephson junction atop
a topological insulator and discuss the possibility of electricalcontrol of magnetization in such a device. Our analysis, whichcombines microscopic Keldysh Green function techniquefor obtaining the Josephson current with phenomenologicalLandau-Lifshitz-Gilbert equations for studying magnetizationdynamics, shows that the property of full spin momentumlocking can lead to destabilization of a transverse easy magne-tization axis m
yin such systems in the presence of appropriate
voltage or current bias. Such an instability, in turn, resultsin a ferromagnet with two easy axes allowing for four sta-
blemagnetization directions instead of usual two. Switching
between these states by means of voltage or current impulsesis of interest from the applied point of view.
ACKNOWLEDGMENTS
The work of I.V .B. and A.M.B. was carried out within
the state task of ISSP RAS. The reported study was par-tially funded by the RFBR research Projects No. 18-02-00318 and No. 18-52-45011-IND. Numerical calculationshave been made in the framework of the RSF Project No.18-71-10095. K.S. thanks DST for support through ProjectNo. INT /RUS/RFBR /P-314.
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054506-7 |
PhysRevLett.109.067203.pdf | Atomistic Molecular Dynamic Simulations of Multiferroics
Dawei Wang,1,2,*Jeevaka Weerasinghe,2and L. Bellaiche2,3
1Electronic Materials Research Laboratory—Key Laboratory of the Ministry of Education, and International Center
for Dielectric Research, Xi’an Jiaotong University, Xi’an 710049, China
2Physics Department, University of Arkansas, Fayetteville, Arkansas 72701, USA
3Institute for Nanoscience and Engineering, University of Arkansas, Fayetteville, Arkansas 72701, USA
(Received 18 October 2011; revised manuscript received 9 February 2012; published 8 August 2012)
A first-principles-based approach is developed to simulate dynamical properties, including complex
permittivity and permeability in the GHz–THz range, of multiferroics at finite temperatures. It includesboth structural degrees of freedom and magnetic moments as dynamic variables in Newtonian andLandau-Lifshitz-Gilbert (LLG) equations within molecular dynamics, respectively, with the couplingsbetween these variables being incorporated. The use of a damping coefficient and of the fluctuation fieldin the LLG equations is required to obtain equilibrated magnetic properties at any temperature. Noelectromagnon is found in the spin-canted structure of BiFeO
3. On the other hand, two magnons with very
different frequencies are predicted via the use of this method. The smallest-in-frequency magnon
corresponds to oscillations of the weak ferromagnetic vector in the basal plane being perpendicular tothe polarization while the second magnon corresponds to magnetic dipoles going in and out of this basalplane. The large value of the frequency of this second magnon is caused by static couplings betweenmagnetic dipoles with electric dipoles and oxygen octahedra tiltings.
DOI: 10.1103/PhysRevLett.109.067203 PACS numbers: 75.85.+t, 31.15.xv, 75.30.Gw, 76.50.+g
Multiferroics form a promising class of materials exhib-
iting a rare coexistence between ferroelectricity and mag-netism. They are experiencing a huge resurgence ininterest, partly for designing novel advanced technologies(see, e.g., Refs. [ 1,2] and references therein). The develop-
ment and use of ab initio atomistic schemes recently had
helped in gaining a better knowledge of these complexmaterials. For instance, first-principles-based simulationsexplained why so few compounds are multiferroics [ 3] and
how their magnetic ordering can be controlled by theapplication of electric fields along specific directions[4–7]. They also provided a deep insight into the strain-
driven phase transition towards states with giant axial
ratio and large out-of-plane polarization in BiFeO
3
(BFO) multiferroics [ 8–11]. Similarly, ab initio techniques
revealed that a dramatic enhancement of magnetoelectriccoefficients can be achieved near this latter phase transition[12,13]. Another example is the prediction of array of
ferroelectric (FE) vortices in BFO films [ 14], that was
then experimentally confirmed [ 15]. Interestingly, all these
latter breakthroughs from first principles concerned static
properties of multiferroics. On the other hand, one particu-
larly challenging issue that remains to be tackled byatomistic methods, in general, and by first-principles tech-niques, in particular, is the prediction of dynamical prop-erties of multiferroics at finite temperature. One particularreason behind such lack of numerical tool is that ionicvariables (e.g., polarization and/or tilting of oxygen octa-hedra) obey Newton’s equations of motion while the spin
degrees of freedom do not [such latter degrees of freedom
follow Landau-Lifshitz [ 16] or even more complicatedequations such as Landau-Lifshitz-Gilbert (LLG) [ 17]].
In order to realistically mimic dynamical properties ofmultiferroics, one thus needs to develop a tool wheredifferent equations are simultaneously obeyed, and thatalso includes the coupling between ionic and magnetic
variables. Moreover and in order to predict finite-
temperature dynamics of multiferroics, this hypotheticaltool should also be able to control (at the same time) thetemperature associated with ionic motions and the tem-perature associated with magnetic degrees of freedom.Such simultaneous control is not an easy task to accom-plish. On the other hand, developing such code can havelarge benefits. For instance, it may help in understanding
what is the nature of the excitation, having a frequency that
is larger than typical magnon frequencies but smaller thanphonon frequencies, which has been recently observed inBFO systems (see Ref. [ 18] and Fig. 2 of Ref. [ 19] for the
‘‘mysterious’’ excitation having a frequency of the orderof30–60 cm
/C01). Can it be an electromagnon [ 20–22], as
suggested in Ref. [ 18]?
The purpose of this Letter is to demonstrate that it is
possible to develop such an ab initio scheme and to apply it
to the study of BFO. It is found that LLG equations, inwhich a realistic damping coefficient is used and in which afluctuation field is incorporated, coupled with classicalNewtonian equations allows us to reach the equilibriumstates of both the structural and magnetic variables at anytemperature. The use of this tool also yields the computa-tion of the complex electric and magnetic susceptibilities
for any frequency in the GHz–THz range. In particular, it
predicts that the aforementioned mysterious excitation is inPRL 109, 067203 (2012) PHYSICAL REVIEW LETTERSweek ending
10 AUGUST 2012
0031-9007 =12=109(6) =067203(6) 067203-1 /C2112012 American Physical Societyfact a magnon rather than an electromagnon, and that
its large frequency originates from static (rather thandynamic) couplings between the magnetic dipoles with
electric dipoles and oxygen octahedra tilting.
Here, we first take advantage of the first-principles-
based effective Hamiltonian developed for BFO systems[23,24]. Its total internal energy E
totis written as a sum of
two main terms:
Etot¼EFE/C0AFDðfuig;f/C17g;f!igÞ
þEMAGðfmig;fuig;f/C17g;f!igÞ; (1)
where uiis the local soft mode in unit cell i, which is
directly proportional to the electrical dipole centered on
that cell. The f/C17gis the strain tensor and contains both
homogeneous and inhomogeneous parts [ 25,26]. The !i
pseudo-vector characterizes the oxygen octahedra tilt,
which is also termed the antiferrodistortive (AFD) motion,in unit cell i[23]. The m
iis the magnetic dipole moment
centered on the Fe-site iand has a fixed magnitude of 4/C22B
[27]. The EFE/C0AFDis given in Ref. [ 28] and involves terms
associated with ferroelectricity, strain, and AFD motions,
and their mutual couplings. The EMAG gathers magnetic
degrees of freedom and their couplings and is given inRefs. [ 23,24]. Note that the use of this effective
Hamiltonian approach within Monte Carlo (MC) simula-tions was shown to (i) correctly yield the R3cground state
that exhibits a coexistence of a spontaneous polarizationwith antiphase oxygen octahedra tilt in BFO bulks [ 23],
(ii) provide accurate Ne ´el and Curie temperatures and
intrinsic magnetoelectric coefficients in BFO bulks andthin films [ 13,23,29], and also (iii) reproduces the spin-
canted magnetic structure that is characterized by a weakmagnetization superimposed on a large G-type antiferro-
magnetic (AFM) vector in BFO films (note that this spin-canted structure originated from the AFD motions ratherthan the polarization) [ 24]. Note, however, that the current
version of this effective Hamiltonian approach does not
yield a spin cycloid structure in BFO bulks, unlike inexperiments [ 20]. The probable reason for that is either
the lack of an additional energetic term that generates suchcycloid or that the period of the cycloid [ 20] is too large to
be mimicked by atomistic simulations. The present resultsshould thus be relevant to BFO thin films (for which nocycloid exists) [ 30,31].
Here, we decided to combine the effective Hamiltonian
scheme within an original molecular dynamics (MD)scheme in order to be able to predict dynamical properties.Technically, and as done in Refs. [ 32–34], Newtonian
equations are implemented for the fu
ig;f/C17g;f!igvariables,
with the corresponding forces appearing in these equationshaving been obtained by taking partial differential of theE
totenergy of Eq. ( 1) with respect to each variable. As also
previously implemented [ 32,33], the temperatures of these
lattice variables are controlled by Evans-Hoover thermo-stats [ 35]. The novelty here is to also include the dynamics
of the magnetic moments on the same footing than thedynamics of the structural variables at a given temperature
(note that we are not aware of any previous study address-ing such simultaneous ‘‘double’’ dynamics and that con-
trolling temperature for the magnetic sublattice is a
challenging problem [ 17,36,37]). For that, we imple-
mented the stochastic LLG equation [ 17] for the m
i’s
degrees of freedom:
dmi
dt¼/C0/C13mi/C2½Bi
effðtÞþbi
flðtÞ/C138 /C0/C13/C21
jmijð1þ/C212Þmi
/C2fmi/C2½Bi
effðtÞþbi
flðtÞ/C138g; (2)
where Bi
eff¼/C0@Etot=@miis the effective magnetic field
acting on the ith magnetic moment, /C13is the gyromagnetic
ratio, /C21is the damping coefficient, and bi
flis a fluctuation
field that also acts on the ith magnetic moment. As we will
see below, the introduction of this latter fluctuation field iscrucial to obtain correct magnetic properties in a multi-ferroic at finite temperature, as consistent with previousstudies done on magnetic systems [ 38,39]. Technically, we
use the Box–Muller method (that generates Gaussian dis-
tributed numbers for each magnetic moment) to simulate
b
i
fland to enforce the following conditions to be obeyed by
this fluctuation field at the finite temperature T[17,38]:
hbi
fli¼0; (3)
hbi
fl;/C11ðt1Þbi
fl;/C12ðt2Þi ¼ 2/C21kBT
/C13jmij/C14/C11;/C12/C14ðt1/C0t2Þ; (4)
where /C11and/C12denote Cartesian coordinates and t1andt2
are two different times. The hiindicates an average over
possible realizations of the fluctuating field [ 17],/C14/C11;/C12is
Kronecker delta function, and /C14ðt1/C0t2Þis a Dirac delta
function. A semi-implicit method devised by Mentink et al.
[40] is adopted here to (i) properly integrate the LLG
equation, which is a Stratonovich stochastic differentialequation [ 17] (the need to properly integrate LLG equation
is a pivotal point that has been discussed in several studies
[17,40–44]), and (ii) to enforce the conservation of the
magnetic moments’ magnitude. The Mentink algorithmis efficient by limiting the matrix inversion procedure—which is needed by an implicit integrator—for each mag-netic moment at each time step. We have checked that thisalgorithm indeed conserves the magnitude of the individ-ual magnetic moments very well and satisfies our need for
efficiency and stability.
Simulations on a periodic 12/C212/C212supercell
(8640 atoms) are performed within the presently developedMD scheme to obtain finite-temperature properties ofBFO. The system is first equilibrated at a chosen tempera-ture and pressure ( NPT ensemble), and then, depending on
the purpose of the simulation, we either continue havingNPT steps to extract static properties or adopt NVE steps
to obtain time-resolved properties, such as autocorrelation
functions of electric or magnetic dipoles, to predict dy-namical properties. A time step of 0.5 fs is used in allsimulations.PRL 109, 067203 (2012) PHYSICAL REVIEW LETTERSweek ending
10 AUGUST 2012
067203-2One important problem to address when dealing with
dynamics of magnetic degrees of freedom and the LLGequation is to determine the realistic value, or range ofvalues, of the damping coefficient for a given system. Oneway to solve such problem is to realize that MC and MDshould give identical results for static properties at anytemperature. As a result, MC can be used as a way ofgauging MD simulations and extracting the proper damp-ing constant /C21[45]. We numerically found that, at any
temperature, /C21has little effect on the spontaneous polar-
ization and oxygen octahedra tilting, therefore yieldingMD results being similar to the MC predictions for thesestructural properties for a wide range of damping coeffi-
cients. In fact, the effect of /C21can be clearly seen when
investigating magnetic properties in the multiferroicBFO—as consistent with the fact that /C21‘‘only’’ appears
in the spin equations of motions. Consequently, Fig. 1
shows the temperature evolution of the magnitude of theG-type AFM vector ( L) for different /C21values within the
MD scheme, as well as the MC prediction for such quan-tity. Moreover, parts (a) and (b) of this figure display theresults when the fluctuation field is neglected and ac-counted for, respectively, in the MD simulations, in orderto also reveal the importance of b
i
flon finite-temperature
magnetism. One can see that, without the fluctuation field,
(i) MD simulations with /C21*1:0/C210/C04give an AFM
vector that is significantly larger than that from the useof the MC technique for any temperature ranging between
10 and 800 K and therefore also generates a larger Ne ´el
temperature, while (ii) for damping coefficients smallerthan 1:0/C210
/C04(including the case of /C21¼0), the MD
results are consistent with the MC calculations for tem-peratures larger than 250 K but yield too small AFM
vectors for lower temperatures [ 46]. Therefore, not a single
proper /C21value allowing the MD simulations of the AFM
vector to match the MC results across all temperaturescan be found without a fluctuation field. On the otherhand, Fig. 1(b) demonstrates that a wide range of /C21
(namely, 1:0/C210
/C04/C20/C21/C201:0/C210/C01) leads to a satis-
factory agreement (i.e., a difference of less than 3%)between the MD and MC results at any temperature,
when the fluctuation field is included. Such results thus
prove the crucial importance of a fluctuation field foraccurately modelling finite-temperature spin dynamics inmultiferroics. Note also that a large range of /C21can be
adopted to obtain equilibrated static properties, whichmakes the MD approach suitable to model different multi-ferroic or ferromagnetic bulks or nanostructures that mayhave very different damping constants due to different
damping mechanisms [ 47].
Let us now use the proposed MD scheme, incorporating
the fluctuation field and choosing /C21¼1:0/C210
/C04to com-
pute the complex electric and magnetic susceptibilities ofBFO, to be denoted by /C31
eand/C31m, respectively. Such
quantities can be calculated as follows [ 32,48,49]:
½/C31eð/C23Þ/C138/C11/C12¼1
"0VkBT/C20
hd/C11ðtÞd/C12ðtÞi
þi2/C25/C23Z1
0dtei2/C25/C23thd/C11ðtÞd/C12ð0Þi/C21
;(5)
½/C31mð/C23Þ/C138/C11/C12¼/C220
VkBT/C20
hM/C11ðtÞM/C12ðtÞi
þi2/C25/C23Z1
0dtei2/C25/C23thM/C11ðtÞM/C12ð0Þi/C21
;(6)
where /C23is the frequency while /C11and/C12define Cartesian
components, with the x,y, and zaxes being along the
pseudocubic [100], [010], and [001] directions, respec-
tively. The dðtÞandMðtÞare the electric and magnetic
dipole moments at time t, respectively. Here, we focus on a
fixed temperature of 20 K, for which the crystallographicequilibrium state is R3c.
Figure 2(a) shows the isotropic value of the ½/C31
eð/C23Þ/C138/C11;/C12
dielectric response, that is f½/C31eð/C23Þ/C138xxþ½/C31eð/C23Þ/C138yyþ
½/C31eð/C23Þ/C138zzg=3. Four peaks can be distinguished, having
resonant frequencies of 151 cm/C01,176 cm/C01,240 cm/C01,
and263 cm/C01. They correspond to E,A1,E, and A1
symmetries, respectively [ 50]. Not all the modes appearing
in measured Raman or infrared spectra [ 19,54–61] can be
reproduced by our simulations because of the limitednumber of degrees of freedom included in the effectiveHamiltonian. In particular, the modes observed around 74
and81 cm
/C01, and that are E(TO) and E(LO) modes, re-
spectively, according to Ref. [ 61], are missing in our
computations. Moreover, we numerically found that thefirst two (lowest-in-frequency) peaks of Fig. 2(a) are0.00.51.01.52.02.53.03.54.0Magnetic moment (Bohr magneton)(a)λ = 2.0 ×10-4
λ = 1.0 ×10-4
λ = 5.0 ×10-5
λ = 1.0 ×10-5
λ = 0.0
MC
0.00.51.01.52.02.53.03.5
0 200 400 600 800 1000 1200 1400
Temperature (K)(b)λ = 1.0λ = 1.0 ×10-1
λ = 1.0 ×10-4
λ = 1.0 ×10-5
MC
FIG. 1 (color online). Temperature dependency of the magni-
tude of the antiferromagnetic vector within the proposed MDscheme and for different damping coefficients, when the fluc-tuation field is neglected (a) and incorporated (b). For compari-
son, the MC results are also indicated by the red line with red
solid circles.PRL 109, 067203 (2012) PHYSICAL REVIEW LETTERSweek ending
10 AUGUST 2012
067203-3mostly related to the sole FE degree of freedom incorpo-
rated in the effective Hamiltonian scheme, while the lasttwo peaks have also a significant contribution from AFDdistortions, as consistent with Ref. [ 51]. As revealed in
Refs. [ 33,62], bilinear couplings between the FE and AFD
modes in the R3cphase allow the AFD mode to acquire
some polarity, which explains why these last two peaksemerge in the dielectric spectra.
Regarding the permeability, two peaks can be seen in
Fig. 2(b). Their predicted resonant frequencies are
/C247c m
/C01and/C2485 cm/C01, respectively [ 63]. Since none
of the frequencies coincides with the dielectric resonantfrequencies shown in Fig. 2(a), we can safely conclude that
they are not electromagnons. They are rather ‘‘solely’’
magnons. Interestingly, we further numerically found thatthe lowest-in-frequency magnon entirely disappears whenwe switch off in our simulations the parameter responsible
for the spin-canted structure of BFO. In other words, the
purely AFM G-type structure does not possess such mag-
non. Moreover, the video shown in the SupplementalMaterial S1 [ 64] demonstrates that this magnon is associ-
ated with the rotation of magnetic dipoles inside the (111)
plane (which contains the polarization). In other words,this magnon is the low-in-frequency excitation (possessinga gap) that has been predicted in Refs. [ 65,66] and that
corresponds to the oscillation of the weak ferromagnetic
moment about its equilibrium position in the basal plane[67]. Let us now try to understand the origin of the
second magnetic peak, for which the frequency is much
larger than those of typical magnons (which are usually
lower than 20 cm
/C01) but is smaller than the phonon fre-
quencies shown in Fig. 2(a) (this second peak is thusconsistent with the ‘‘mysterious’’ excitations observed in
Refs. [ 18,19]. This second magnetic peak is associated
with fast oscillations of the magnetic dipoles going in
and out of the (111) plane, as well as, a change in length
of the weak FM vector (see Fig. 3and video in
Supplemental Material S1 [ 64]). This second peak there-
fore corresponds to the so-called optic antiferromagnetic
mode of Ref. [ 68] and to the high-frequency gapped mode
of Ref. [ 66]. Interestingly, we also numerically found that
this second peak (i) has a resonant frequency that is in-
sensitive to the effective masses associated with the FE and
AFD motions (in other words, the frequency of this second
magnetic peak is insensitive to a change of FE or AFDresonances), and (ii) becomes a broad peak ranging from
0c m
/C01to’16 cm/C01when switching off the coupling
parameters between magnetic moments with FE and
AFD motions in our simulations (in that case, the corre-
sponding motions of the magnetic dipoles are not only inand out of the (111) plane but also are within the (111)
plane). As a result, we can safely conclude that the abnor-
mally large frequency of the second peak results from
static (rather than dynamic) couplings between the m
i’s
and structural variables, with these couplings generating alarge magnetic anisotropy. Furthermore, this second peak
has a resonant frequency of around 60 cm
/C01rather than
/C2485 cm/C01, if one ‘‘only’’ switches off the static coupling
between magnetic degrees of freedom and AFD motions.
In other words, AFD distortions (that have not been ex-
plicitly incorporated in phenomenological models so far to
study dynamics of BFO systems) do significantly affect the
resonant frequency of this second peak. Analytical expres-sions derived in the Supplemental Material S2 [ 69] from
energetic terms included in the effective Hamiltonian con-
firm and even shed more light on such features, such as
revealing that the resonant frequency of this second mag-
netic peak also depends on the values of the spontaneouspolarization and angle of oxygen octahedra tilting [ 70]. We
thus hope that our proposed atomistic MD method is, and
will be, of large benefit to gain a deeper knowledge of the-3-2-10123456
100 150 200 250 300χe(ν) (103)
Frequency (cm-1)(a)Re(χe)
Im(χe)
-3-2-101234567
0 20 40 60 80 100 120χm(ν) (10-3)
Frequency (cm-1)(b)Re(χm)
Im(χm)
FIG. 2 (color online). Complex electric (a) and magnetic (b)
susceptibilities as a function of frequency in BFO at T¼20 K .FIG. 3 (color online). Sketch of the FM vector (the short green
vector) and the Lvector (the long red vector) at one instance.
We note, at this instance, these two vectors slightly deviate from
the (111) plane due to couplings with AFD and FE (see
Supplemental Material S2 [ 69]). The (weak) FM vector is
enhanced by /C2459times to be seen in this figure.PRL 109, 067203 (2012) PHYSICAL REVIEW LETTERSweek ending
10 AUGUST 2012
067203-4fascinating multiferroic materials [ 71]. Note that it can also
open the door to many exciting studies, such as the com-
putation and understanding of the cross-coupled electro-
magnetic susceptibility defined in Ref. [ 68].
Discussions with J. In ˜iguez, Dr. Kamba, M. Cazayous,
and M. Bibes are greatly acknowledged. We mostly thank
Office of Basic Energy Sciences, under contract ER-46612
for personnel support. NSF Grants No. DMR-0701558 and
No. DMR-1066158, ARO Grant No. W911NF-12-1-0085,
and ONR Grants No. N00014-11-1-0384 and No. N00014-
08-1-0915 are also acknowledged for discussions with
scientists sponsored by these grants. D. W. acknowledges
support from the National Natural Science Foundation of
China under Grant No. 10904122. Some computationswere also made possible thanks to the MRI grant
0959124 from NSF, and N00014-07-1-0825 (DURIP)
from ONR.
*dawei.wang@mail.xjtu.edu.cn
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067203-6 |
PhysRevB.101.140404.pdf | PHYSICAL REVIEW B 101, 140404(R) (2020)
Rapid Communications
Deterministic approach to skyrmionic dynamics at nonzero temperatures:
Pinning sites and racetracks
Josep Castell-Queralt , Leonardo González-Gómez , Nuria Del-Valle , and Carles Navau*
Departament de Física, Universitat Autònoma de Barcelona, 08193 Bellaterra, Barcelona, Catalonia, Spain
(Received 6 February 2020; revised manuscript received 27 March 2020; accepted 30 March 2020;
published 16 April 2020)
The discovery of room-temperature skyrmions in some magnetic materials has boosted the investigation of
their dynamics in view of future applications. We study the dynamics of skyrmions in the presence of defectsor borders using a deterministic (finding and solving a deterministic Fokker-Planck differential equation) whileprobabilistic (the solution is the probability density for the presence of a skyrmion) approach. The probability thata skyrmion becomes trapped in a pinning center or the probability of the survival of a skyrmion along a racetrackare obtained as a function of temperature. The present work can be relevant in the design of skyrmionic deviceswhere the probability of finding skyrmions at a given position and time is crucial for their feasibility.
DOI: 10.1103/PhysRevB.101.140404
Magnetic skyrmions are whirling magnetic structures that
can be found on certain magnetic materials [ 1]. Their small
size and high mobility have promoted them as promisinginformation carriers as well as basic elements in ultradensemagnetic memories, logic devices, or computational sys-tems [ 2–6]. In ferromagnetic ultrathin films, it has been found
that skyrmions can be stabilized with the aid of interfacialDzyaloshinskii-Moriya (iDM) interactions with a heavy-metalsubstrate [ 7–10]. The same mechanism allows the formation
of skyrmions in multilayers with alternate ferromagnets andheavy metals [ 11,12]. The experimental discovery of room-
temperature skyrmions [ 13] has boosted the potentiality of
skyrmions for applications and, as a result, the study of theircurrent-driving dynamics at nonzero temperatures.
Skyrmionic racetracks were proposed to transport
skyrmions using the spin-orbit torque produced by aspin-polarized current fed into a heavy-metal substrate [ 2,14].
In such systems, defects or granularity result in a thresholdcurrent density for the activation of the movement [ 15–20] and
the borders of the track create a confining potential that sets adriving velocity threshold above which the skyrmions wouldescape [ 21–24]. At increasing temperature, the stochastic
effects on the skyrmions’ position [ 25–27] could compromise
their existence when approaching the borders or de-fects [ 22,28]. Also, their topological protection is weakened,
which can lead to their collapse [ 22,29–32]. This stochastic
motion sets different conditions (or restrictions) on the appli-cability of racetracks that should be addressed. In particular,some questions arise: What is the probability for the skyrmionto escape from a pinning center? What is the probability fora skyrmion to overcome the racetrack border’s confiningpotential? What is the probability of finding a skyrmion at agiven distance from the initial position after a given time?
At temperature T=0 the movement of the skyrmion is
not probabilistic [ 21,23,33,34] and the previous questions do
*Corresponding author: carles.navau@uab.catnot apply. The inclusion of thermal effects in micromagnetic
simulations can be done either by using a stochastic Landau-Lifshitz-Gilbert equation, Landau-Lifshitz-Bloch equation, orby stochastic atomic spin dynamics [ 35–38]. Thiele’s equa-
tion [ 39], originally introduced for magnetic bubble domain
motion, with the inclusion of extra stochastic terms [stochas-tic Thiele’s equation (STE)], is also used to study the dy-namics of skyrmions [ 17,25,27,28,40,41]. In this case, it is
assumed that the skyrmion maintains its shape during themovement (rigid approximation). Even at room temperature,this assumption can be a valid approximation as shown forPt/Co/Ir, Pt/CoFeB /MgO, or Pt /Co/Ta multilayers [ 13,20].
In all these cases, the simulations for a single skyrmion have tobe repeated a large number of times and the average quantitiesevaluated with the corresponding statistical dispersion.
Here, we use a deterministic, while probabilistic, approach
for studying the dynamics of skyrmions including tempera-ture. We evaluate the effects of pinning potentials as well asracetrack borders. Instead of solving the STE many times, wesolve the corresponding deterministic Fokker-Planck equa-tion [ 42] (FPE) for the probability density of the presence
of a skyrmion as a function of time. The main advantagesof this approach are as follows: (i) One needs to solve theFPE only once; (ii) some approximations can be analyticallyworked out; (iii) FPE is a partial differential equation thatcan be solved using well-known numerical techniques (evencommercial software); and (iv) complex potentials can beincluded without a significant increase in the computationtime.
Some previous works have also used the same de-
terministic approach for studying the dynamics of rigidskyrmions [ 26,43] (and vortices [ 44] ) .I nR e f .[ 26] the mobil-
ity of skyrmions in a periodic potential was evaluated in thestationary limit. Also, in Ref. [ 43] the steady-state velocity
(of antiferromagnetic skyrmions in this case) for the lowest-order traveling wave solutions of the probability density wasobtained. In contrast to these works, here we obtain the fulltime and position dependence of the solution of the FPE for
2469-9950/2020/101(14)/140404(5) 140404-1 ©2020 American Physical SocietyJOSEP CASTELL-QUERALT et al. PHYSICAL REVIEW B 101, 140404(R) (2020)
the case in which rigid skyrmions travel in the presence of a
pinning site or along a racetrack. From these solutions, all theprobabilistic properties of the dynamics can be obtained.
Our starting point is the stochastic Thiele’s equation for a
rigid skyrmion moving on a magnetic ultrathin film (thicknessd, volume V) with background magnetization pointing in the
−ˆzdirection and located on the z=0 plane. The movement of
the skyrmion is described by the position of its center of masswhose time derivative is the velocity of the skyrmion V
s.W e
consider here that the skyrmion is driven through dampingliketorques produced by spin-polarized currents coming from thespin-Hall effect after feeding an in-plane current J
Hin a
heavy-metal substrate [ 45]. The STE can be written as [ 46]
(G−MsαD)Vs+MsNVH+γM2
s(Fext+Fst)=0,(1)
whereGandDare the gyrocoupling and dissipation ma-
trix, respectively. Ncomes from the integration of the spin-
transfer torque term in the Landau-Lifshitz-Gilbert equation.They all are 2 ×2 matrices whose elements are ( u,v=x,y)
G
uv=/integraltext
VM0·(∂M0
∂u×∂M0
∂v)dV,Duv=/integraltext
V(∂M0
∂u·∂M0
∂v)dV, and
Nuv=(1/d)/integraltext
V(∂M0
∂u×M0)vdV.VH=−μBθH
eMs(z×JH), with
μBthe Bohr magneton, θHthe Hall angle, and e(>0)
the charge of the electron. In the present case, consideringaxisymmetric skyrmions, G
xy=−Gyx≡G,Dxx=Dyy≡D,
Nxy=−Nyx≡−N, where G>0,D>0, and N>0. All
other elements of the matrices are zero. γis the gyromag-
netic constant ( γ=2.21×105mA−1s−1),αis the Gilbert
damping constant, and Msthe saturation magnetization. The
force terms FextandFstcome, respectively, from the exter-
nal and stochastic forces.1Fstis considered a white noise
with/angbracketleftFst,j/angbracketright=0 and/angbracketleftFst,iFst,j/angbracketright=2αDkBT
γμ 0Msδijδ(t−t/prime)[25], with
i,j=x,y,z,μ0the vacuum permeability, kBthe Boltzmann
constant, δijthe Kronecker delta, and δ(t−t/prime) the temporal
Dirac’s delta.
For a given initial position of the skyrmion, the stochastic
nature of Eq. ( 1) results in different trajectories for each simu-
lated solution. However, the probability density of finding thecenter of mass of the skyrmion at position r=(x,y) and time
t,p(r,t), can be directly evaluated from its corresponding
FPE (see Supplemental Material for the derivation [ 47] ) that
can be written as
∂
∂tp(r,t)=−∇·[p(r,t)(Vdrv+Vext)]+Dd∇2p(r,t),
(2)
where we have used the definitions
Dd=γM3
sαDkBT
μ0(G2+D2α2M2s), (3)
Vdrv=− (G−αMsD)−1MsNVH, (4)
Vext=− (G−αMsD)−1γM2
sFext. (5)
Equation ( 2) is a convection-diffusion equation. The first
term on the right-hand side indicates that the probability
1Strictly, FextandFstdo not have units of force, but we follow the
usual nomenclature.density is transported at a velocity Vdrv+Vext, whereas the
second term is a linear, homogeneous, and isotropic diffusionterm with constant D
d. Actually, the FPE is also a continuity
equation
∂
∂tp(r,t)=−∇·Jp(r,t), (6)
where one can define the current of probability density
Jp(r,t)=(Vdrv+Vext)p(r,t)−Dd∇p(r,t).
Equation ( 2) can be analytically solved in some cases. If
one considers a free skyrmion [no driving ( VH=0), no exter-
nal forces ( Fext=0)], whose initial position probability den-
sity is described by a Gaussian function centered at the originof coordinates with a given variance σ
2,p0(x,y)=N(0,σ),
the solution of Eq. ( 2)i s p(x,y,t)=N(0,/radicalbig
σ2+2Ddt),
which indicates that the initial Gaussian distribution diffuseswithout translation, maintaining the Gaussian shape, wherethe variance is a linear function of the time and proportional tothe temperature. These results are in complete agreement withRef. [ 25] which used a completely different approach (thermal
agitation of classical spins on a triangular lattice) to monitorthe Brownian motion of skyrmions.
Another interesting analytical solution of the FPE is the
stationary ( t→∞ ) solution of the probability density when a
harmonic pinning center is present. In this case, if the pinningcenter is at the origin, the force felt by the skyrmion canbe described by F
ext=−k(xˆx+yˆy)(kindicates the restor-
ing coefficient of the force, assumed constant). No drivingcurrent is considered. The stationary solution of Eq. ( 2)i s
found to be, independently of the initial probability density,
p(x,y,∞)=N(0,/radicalbigg
MskBT
μ0Ddk). It is also a Gaussian distribution
whose variance increases linearly with temperature and is
inversely proportional to k. This indicates that the skyrmion,
regardless of the initial position, will go to the pinning site,jiggling around it with a variance that represents a competitionbetween the thermal diffusive effect and the attractive pinningforce.
Consider a more realistic case of a skyrmion driven by
current density J
Hwhich finds an attractive pinning center
whose force is described by [ 46]
Fext=−F0pr
λexp/parenleftbigg
−|r|2
λ2/parenrightbigg
, (7)
where λandF0pcontrol the scope and the strength of the
pinning potential, respectively. Although only the position ofthe center of mass of the skyrmion is evaluated, the rigidmodel assumes a fixed shape of the skyrmions. However, itsradius can change in an order of magnitude from T=0t o
room temperature [ 20,31]. Since λin Eq. ( 7) is related to
the radius of the skyrmion [ 21], we set λ=R
sand we use
the results of Ref. [ 31] to find its dependence on T(see
Supplemental Material for the details [ 47]).λ(T) increases
with temperature in a nonlinear way, with a larger slope atlarger temperatures. We assume that GandDare independent
of temperature (models predict that Gis basically independent
of the radius and that Ddepends on the diameter /domain wall
width ratio [ 40,48]; we are thus assuming that the change in
temperature maintains this ratio constant).
140404-2DETERMINISTIC APPROACH TO SKYRMIONIC DYNAMICS … PHYSICAL REVIEW B 101, 140404(R) (2020)
FIG. 1. Snapshots for the probability density p(r,t) (color bar in units of 10−3nm−2), evaluated at different times, indicated in each
figure in ns. The central green cross indicates the position of the pinning center and the solid blue square indicates the initial position. The
open blue squares indicate the initial position of the skyrmions considered in Fig. 2. The parameters used in this simulation are T=150 K,
α=0.3,Ms=580 kA m−1,D=G=4π,VH=277.4ms−1,λ(T)=38.3 nm, and F0p=5.8×10−14m2A−1. See Supplemental Material
for numerical details and video [ 47].
We want to evaluate the probability that a skyrmion is
trapped by this pinning center, as a function of the temper-
ature. The resulting FPE [Eqs. ( 2)–(5) with Eq. ( 7)] has to
be solved numerically (see Supplemental Material [ 47] and
Ref. [ 49] for the numerical details). Results do depend on the
initial position of the skyrmion. As described in Ref. [ 46]f o r
T=0, for a given VHbelow a threshold velocity, the solution
of Thiele’s equation yields two differentiated regimes depend-ing on the initial position of the skyrmion: (i) The skyrmionis trapped and (ii) the skyrmion escapes. Actually, there is asaddle point in the T=0 phase portrait of the trajectories that
determines if the skyrmion is or is not trapped, depending onfrom which side of the saddle point the skyrmion is approach-ing. However, at T>0 these two regimes are not so clearly
differentiated. Due to the thermal diffusion, it is possible thata skyrmion that would escape at T=0 does not at T>0.
The opposite is also true: A skyrmion that would be trappedatT=0 has some “thermal chance” of escaping. We show
in Fig. 1some snapshots, at different times, of the calculated
probability density p(x,y,t) in a region close to a pinning
center (indicated as a green cross) for a given initial position(blue solid square) and a given temperature ( T=150 K).
We observe that some probability density escapes from thepinning center. After a long time the situation stabilizes andthe probability of being trapped,
P
t=/integraldisplay
Scp(x/prime,y/prime,∞)dx/primedy/prime, (8)
can be evaluated. To evaluate Pt, we have considered a calcula-
tion window Scof dimensions much larger than λ(T)×λ(T).
Note that the persistence of the driving currents makes thatthe final probability density distribution is not centered on thepinning site but at a nearby position [ 46,50].
In Fig. 2we show the calculated P
tas a function of the tem-
perature, for different initial positions. At T=0 the situation
is binary: Ptis either one or zero, depending on the initial
position. Increasing T, the potential well becomes broader
and shallower [due to the λ(T) dependence], increasing the
probability for those skyrmions that would escape at T=0
(red lines) to fall into the well at relatively low T.A tt h e
same time, for those skyrmions that would be trapped atT=0 (blue lines) the probability of trapping decreases when
the potential becomes shallower, although the broadeningacts as a counteracting effect. Finally, at large T, regardlessof the initial position of the skyrmions, the thermal energy
overcomes the potential well and P
tgoes to zero in all cases.
An increase in the F0pfactor would shift the temperature at
which Ptgoes to zero to higher values.
One of the important issues in the skyrmionic roadmap
is the transport along racetracks [ 2]. The feasibility of such
systems is based on the survival of skyrmions when theyare driven along the racetrack. We now want to evaluate theprobability of such a survival. Consider a long racetrack alongthexaxis, with a width 2 Win the yaxis (the center line of the
racetrack is y=0). The force over the skyrmion due to the
borders can be modeled as [ 21]
F
ext=F0t/bracketleftbig
−e−W−y
λ+e−W+y
λ/bracketrightbig
ˆy. (9)
The corresponding FPE [Eqs. ( 2)–(5) with Eq. ( 9)] is also
solved numerically (see Supplemental Material for numer-ical details [ 47]). In Fig. 3we show the probability den-
sity evolving with time for two temperatures [ T=100 K in
Fig. 3(a), and T=300 K in Fig. 3(b)] at a fixed driving
FIG. 2. Probability Ptthat a skyrmion is trapped in a Gaussian
pinning center when it is driven by currents as a function of the
temperature, for different initial positions of the skyrmion, indicatedwith the xcoordinate with respect the green cross in Fig. 1(the
initial positions are shown as open blue squares in Fig. 1). The blue
(red) dots correspond to cases where the skyrmion would be trapped(escape) at T=0. The rest of the parameters are the same as in
Fig. 1. The encircled point corresponds to the case of the snapshots
in Fig. 1.
140404-3JOSEP CASTELL-QUERALT et al. PHYSICAL REVIEW B 101, 140404(R) (2020)
FIG. 3. Snapshots [(a) T=100 K; (b) T=300 K] of the prob-
ability density (color bar in units of 10−5nm−2) for the central
position of a rigid skyrmion driven along a track, p(x,y,t). In
each track, the blue dot (at left) indicates the initial position and
p(x,y,t) at several times t(indicated in the figure in ns) are
plotted. The gray regions correspond to y’s such that W>|y|>
W−λ(T). The parameters used are W=150 nm, VH=325 m s−1,
F0t=5.325×10−14m2A−1,λ(T=100 K) =25.05 nm, λ(T=
300 K) =70.33 nm. The rest of the parameters are the same as
in Fig. 1. See Supplemental Material for numerical details and
videos [ 47].
velocity VHbelow the threshold (thus, at T=0, the skyrmion
would not escape from the track). When T>0 there is some
probability of escaping through the borders due to thermaldiffusion.
One interesting figure of merit is the probability that a
skyrmion reaches a certain position along the track, which isevaluated from the flux of current density through a sectionof the track at position x[initially, the skyrmion is located at
(x,y)=(0,0)],
P
s(x)=/integraldisplayW−λ(T)
−W+λ(T)dy/prime/integraldisplay∞
0dt/primeˆx·Jp(x,y/prime,t/prime). (10)
Note that, in order to consider the radius of the skyrmion at
different temperatures, apart from considering λ(T)i nE q .( 9),
we have considered that the skyrmion escapes from the trackwhen|y|>W−λ(T) (that is, when the “skyrmion border”—
not its center—reaches the track border). In Fig. 4(a) we
show P
s(x) at different temperatures. The region of Ps/similarequal1
corresponds to small distances where the skyrmion has not yetreached the borders. The subsequent decay in the probabilityindicates that, when the skyrmion is moving along the border,the probability of escaping increases as it goes further away[thus, the P
s(x) track decreases with increasing x].
In Fig. 4(b) we show Psat a fixed value of x=xL,a s
a function of temperature, for several values of the drivingvelocity. In general, the probability of survival up to a givendistance decreases with increasing temperature. We observea plateau, even a slight increase in P
s(xL) at intermediate
temperatures: The confining potential from the borders cancompensate the thermal diffusion (and the increase in theradius of the skyrmion) up to a certain temperature and theskyrmion can reach the desired x
L. For large temperatures,
the borders are not able to compensate the diffusion and itbecomes less likely to reach x
L.
FIG. 4. (a) Probability of surviving a certain distance xalong the
track as a function of x,Ps(x), for different temperatures (indicated
in the figure). (b) Ps(xL=1115 nm) as a function of temperature for
different driving currents (indicated in the figure). The parameters
not shown are as in Fig. 3. The encircled points in (b) correspond to
the simulations of Fig. 3.
Averages over infinite runs of the STE could give the same
information as the FPE. Comparing similar computationaltimes and /or precision, the presented calculations are a better
approach since the numerical errors in the solution of FPEare orders of magnitude lower that the statistical errors inthe averages of the solutions of the STE (see SupplementalMaterial for a comparison of both methods [ 47]).
Some of the most promising applications of skyrmions are
those based on the one-skyrmion one-bit principle. Knowingthe probability of finding a skyrmion at a given position andtime is crucial for assessing the viability of such systems atroom temperature. Since borders and defects are unavoidablein realistic samples, the present results may help in the futuredesign of skyrmionic devices.
We thank Dr. S. Serna for her advice in the nu-
merical techniques in solving the FPE. We also ac-knowledge Catalan Project No. 2017-SGR-105 and Span-ish Project No. MAT2016-79426-P of Agencia Estatalde Investigación /Fondo Europeo de Desarrollo Regional
(UE) for financial support. J.C.-Q. acknowledges a Grant(FPU17 /01970) from Ministerio de Ciencia, Innovación y
Universidades (Spanish Government).
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140404-5 |
PhysRevB.98.220410.pdf | PHYSICAL REVIEW B 98, 220410(R) (2018)
Rapid Communications
Damping and antidamping phenomena in metallic antiferromagnets: An ab initio study
Farzad Mahfouzi*and Nicholas Kioussis†
Department of Physics and Astronomy, California State University, Northridge, California 91330, USA
(Received 13 November 2018; revised manuscript received 10 December 2018; published 26 December 2018)
We report on a first-principles study of antiferromagnetic resonance (AFMR) phenomena in metallic systems
[MnX(X=Ir, Pt, Pd, Rh) and FeRh] under an external electric field. We demonstrate that the AFMR linewidth
can be separated into a relativistic component originating from the angular momentum transfer between thecollinear AFM subsystem and the crystal through spin-orbit coupling, and an exchange component that originatesfrom the spin exchange between the two sublattices. The calculations reveal that the latter component becomessignificant in the low-temperature regime. Furthermore, we present results for the current-induced intersublatticetorque which can be separated into fieldlike and dampinglike components, affecting the intersublattice exchangecoupling and AFMR linewidth, respectively.
DOI: 10.1103/PhysRevB.98.220410
Spintronics is a field of research exploiting the mutual
influence between the electrical field/current and the magneticordering. To date, the realization of conventional spintronicdevices has relied primarily on ferromagnetic (FM) basedheterostructures [ 1–6]. On the other hand, antiferromagnetic
(AFM) materials have been recently revisited as potentialalternative candidates for active elements in spintronic devices[7,8]. In contrast to their FM counterparts, AFM systems have
a weak sensitivity to magnetic field perturbations, produceno perturbing stray fields, and can offer ultrafast writingschemes in the terahertz (THz) frequency range. The THzspin dynamics due to AFM ordering has been experimentallydemonstrated using all-optical [ 9,10], and Néel spin-orbit
torque (SOT) [ 11,12] mechanisms.
One of the most important parameters in describing the
dynamics of the magnetic materials is the Gilbert dampingconstant α. Intrinsic damping in metallic bulk FMs [ 13,14]
is associated with the coupling between the conduction elec-trons and the time-dependent magnetization /vectorm(t), where the
latter in the presence of spin-orbit coupling (SOC) leads to amodulation (breathing) of the Fermi surface [ 13] and hence
excitation of electrons near the Fermi energy. The excitedconduction electrons in turn relax to the ground state throughinteractions with the environment (e.g., phonons, photons,etc.), leading to a net loss of the energy/angular momentum inthe system. While the damping in FMs has been extensivelystudied both experimentally and theoretically, the damp-ing in metallic AFM has not received much attention thusfar.
Manipulation of the damping constant in magnetic devices
is one of the prime focuses in the field of spintronics. Con-ventional approaches to manipulate the damping rate of aFM rely on the injection of a spin-polarized current into theFM. The spin current is often generated either through thespin Hall effect (SHE) [ 15,16] by a charge current passing
*Farzad.Mahfouzi@gmail.com
†Nick.Kioussis@csun.eduthrough a heavy metal (HM) adjacent to the FM in a lateral
structure, or spin filtering in a magnetic tunnel junction (MTJ)in a vertical heterostructure [ 17]. Similar mechanisms have
also been proposed [ 8,18–22] for AFM materials, where the
goal is often to cause spontaneous THz-frequency oscilla-tions or reorientation [ 11,23–25] of the AFM Néel ordering,
/vectorn(t)=(/vectorm
1−/vectorm2)/2. Here, /vectormsis a unit vector along the
magnetization orientation of the sublattice s. In contrast to
the aforementioned studies that require breaking of inversionsymmetry to induce Néel ordering switching, in this RapidCommunication we focus on the current-induced excitation ofthe sublattice spin dynamics of bulk metallic AFM materialswith inversion symmetry intact, and hence no Néel SOT[11,12,26,27].
The objective of this work is to (1) provide a general
analytical expression for the antiferromagnetic resonance(AFMR) [ 28] frequency and linewidth in the presence of
current-induced sublattice torque, and (2) employ the Kubo-like formalism with first-principles calculations to calculatethe Gilbert damping tensor α
ss/prime(s,s/prime=↑,↓), and the field-
like,/vectorτFL, and dampinglike, /vectorτDL, components of the sublat-
tice torque for a family of metallic AFM materials includ-ing Mn X(X=Ir,Pt,Pd,Rh) and FeRh, shown in Fig. 1.
We demonstrate that the zero-bias AFMR linewidth can beseparated into the relativistic, /Gamma1
r=λα0/2M, and exchange,
/Gamma1ex=Kαd/2Mcomponents [ 29], where αd≡/summationtext
sαss,α0≡
αd−/summationtext
sαs¯s,Mis the magnetic moment of each sublat-
tice,λis the intersublattice exchange interaction, and Kis
the magnetocrystalline anisotropy energy. In agreement withrecent first-principles calculations [ 30], we find that α
dis
about three orders of magnitude larger than α0, indicating
the crucial role of the exchange component to the AMFRlinewidth. Our calculations reveal that at high temperaturesdue to the interband contribution, the relativistic componentbecomes the dominant term in the AFMR linewidth, whileat low temperatures both exchange and relativistic compo-nents contribute to the AFMR linewidth on an equal footing.We further demonstrate that the current-induced antidamp-inglike (fieldlike) torque changes the AFMR linewidth
2469-9950/2018/98(22)/220410(6) 220410-1 ©2018 American Physical SocietyFARZAD MAHFOUZI AND NICHOLAS KIOUSSIS PHYSICAL REVIEW B 98, 220410(R) (2018)
FIG. 1. Crystal structure of (left) MnX with (X=Ir, Pt, Pd, Rh)
and (right) FeRh used for the first-principles calculations, where the
corresponding spin configuration and primitive cells are shown withsolid lines.
(intersublattice exchange interaction), thereby allowing the
manipulation of the damping constant (Néel temperature) inbulk AFM materials.
Precessional magnetization dynamics of AFMs is often
described by a system of coupled equations for each spinsublattice [ 20,22,31], where a local damping constant αis
assigned to each of the two sublattices ignoring the effects ofthe rapid (atomic scale) spatial variation of the magnetizationon the damping constant due to the AFM ordering. Takinginto account the Gilbert damping tensor α
ss/prime, the coupled
Landau-Lifshitz-Gilbert (LLG) equations of motion for thetwo sublattices can be written as
d/vectorm
s(t)
dt=−γ/vectorms(t)×/vectorHeff
s+/summationdisplay
s/primeαss/prime/vectorms(t)×d/vectorms/prime(t)
dt,
(1)
where the local effective field in the presence of the external
electric ( /vectorEext) and magnetic ( /vectorBext) fields is given by
/vectorHeff
s=/vectorBext+/summationdisplay
i=xyz/parenleftbig
K(2)
i;s+K(4)
s/bracketleftbig
1−m2
i;s(t)/bracketrightbig/parenrightbigmi;s(t)
Msˆei
+e/vectorτ0
DL·/vectorEext/vectorms(t)×/vectorm¯s(t)
+/parenleftbiggλ
Ms+e/vectorτ0
FL·/vectorEext/parenrightbigg
/vectorm¯s(t). (2)
Here,λis the exchange coupling between the two sublattices,
/vectorτ0
DL(/vectorτ0
FL) is the current-induced intersublattice dampinglike
(fieldlike) torque component, and K(2)
i;s(K(4)
s) is the second-
order (fourth-order) magnetocrystalline anisotropy energy(MCAE). Equation ( 2) shows that the effect of /vectorτ
0
FLis to
renormalize the intersublattice exchange coupling, λ/prime=λ+
Mse/vectorτ0
FL·/vectorEext.
In the following, without loss of generality, we assume
Kz
2=0 and Kx,y
2/greaterorequalslant0, where in the absence of an external
magnetic field the magnetization relaxes towards the ˆezaxis
which can be either in or out of plane. Consequently, we con-sider/vectorm
s(t)=mz
sˆez+δ/vectorms(t), where mz
s=±1 and δ/vectorms(t)i s
a small deviation of the magnetic moment normal to the easy(ˆe
z) axis. Solving the resulting linearized LLG equations of
motions, the poles of the transverse dynamical susceptibilityyield two oscillating modes with resonance frequencies ω
j,given by
/parenleftbiggωj
γ−i/vectorτ0
DL·/vectorEext/parenrightbigg2
=/parenleftbig
ω0
j/parenrightbig2+2i/Gamma1jωj
γ,j=x,y,
(3a)
ω0
j=/radicalbig
KxKy+2λ/primeKj
M, (3b)
where M=|Ms|,Kj=K(2)
j+K(4), and the AFMR
linewidth
/Gamma1j≡/Gamma1r+/Gamma1ex
j=1
2M(λ/primeα0+Kjαd)( 4 )
can be separated into a relativistic component originating
from the angular momentum transfer between the collinearAFM orientation and the crystal through the SOC, and anexchange component that originates from the spin currentexchange between the two AFM sublattices. For a system withuniaxial MCAE, Eq. ( 3a) can be used in both cases of out-of-
and in-plane precessions with K
(2)
x,y=|K(2)
⊥|andK(2)
y=0,
K(2)
x=|K(2)
⊥|, respectively, where |K(2)
⊥|is the amplitude of
the out-of-plane MCAE. Equation ( 3a) is the central result
of this Rapid Communication which is used to calculatethe AFMR frequency and linewidth and their correspondingcurrent-induced effects. A more general form of Eq. ( 3a)i n
the presence of an external magnetic field along the precessionaxis is presented in the Supplemental Material [ 32].
Equation ( 3a) also yields the effective Gilbert damping
α
eff
j≡δIm(ωj)
δRe(ωj)=λα0+Kjαd
2M/radicalbig
KxKy+2λKj,j=x,y. (5)
Similarly to the linewidth, αeff
jcan be separated into the
relativistic, αr
j=/Gamma1r
j/ω0
jand exchange, αex
j=/Gamma1ex
j/ω0
j, contri-
butions. To understand the origin of the relativistic componentof the AFMR linewidth, one can use a unitary transformationinto the rotating frame of the AFM direction, where α
0can
be written in terms of the matrix elements of ˆHSOCusing the
spin-orbital torque correlation (SOTC) expression [ 14], also
often referred to as Kambersky’s formula [ 13],
α0=¯h
πNkM/summationdisplay
/vectorkTr(ˆA/vectork[ˆHSOC,σ+]ˆA/vectork[ˆHSOC,σ−]).(6)
Here, ˆA/vectork=Im(Gr
/vectork) is the spectral function, ˆGr
/vectorkis the retarded
Green’s function calculated at the Fermi energy, 2 σ±=σx±
iσyare the spin ladder operators, and Nkis the number of
k-point sampling in the first Brillouin zone.
A similar approach applied to the intersublattice elements
of the damping tensor leads to a relationship between differentelements of α
ss/prime, rather than an explicit expression for each
element. This is due to the fact that in the rotating frameof one sublattice, the other sublattices precess. Therefore,to calculate α
dwe employ the original torque correlation
expression [ 14],
αd=/summationdisplay
s¯h
πNkM/summationdisplay
/vectorkTr/parenleftbigˆA/vectorkˆ/Delta1s
/vectorkˆσ+ˆA/vectorkˆ/Delta1s
/vectorkˆσ−/parenrightbig
, (7)
220410-2DAMPING AND ANTIDAMPING PHENOMENA IN METALLIC … PHYSICAL REVIEW B 98, 220410(R) (2018)
TABLE I. Calculated sublattice magnetic moment ( Ms), magnetocrystalline anisotropy energy per unit cell ( K⊥
2), intersublattice exchange
coupling per unit cell ( λ), ratio of the resistivity ( ρxx) to the broadening parameter η, and the experimental values of ρxx. We also list values
ofαd,α/vectorms/bardbl/vectora(/vectorc)
0 for sublattice magnetization parallel to the /vectora(/vectorc) axis, the relativistic ( αr
⊥) and exchange ( αex
⊥) damping parameter for the
out-of-plane oscillation mode, for ηandη/10 corresponding to the high- and low-temperature regimes, respectively. Finally, we list values
of the sublattice current-induced fieldlike ( τ0,/vectorE/bardbl/vectora(/vectorc)
FL ) and antidampinglike ( τ0,/vectorE/bardbl/vectora(/vectorc)
DL ) components of the spin-orbit torques under an external
electric field along the /vectora(/vectorc) axis for room-temperature broadening.
|Ms|c/a K⊥
2 λρ xx/η ρexpt
xx ηα dα/vectorms/bardbl/vectorc
0 α/vectorms/bardbl/vectora
0 αr
⊥ αex
⊥ τ0,/vectorE/bardbl/vectora(/vectorc)
FL τ0,/vectorE/bardbl/vectora(/vectorc)
DL
(μB) (meV) (eV) (μ/Omega1cm
meV)(μ/Omega1cm) (meV) (10−3)( 1 0−3)( 1 0−3)( 1 0−3)( 1 0−3Å) (10−3Å)
FeRh 3.1 1 +x−1.2x0.44 3.4 ≈100a29 0.25 0.8 0.8 1 .7/√|x|1.5√|x|33 (33) −14 (−14)
2.9 2.5 0.27 0.27 0 .6/√|x|15√|x|
MnRh 3.1 0.94 −0.7 0.42 0.57 95b166 0.13 3.3 3.9 10 0.6 10 (7) 6 ( −3)
16.6 0.45 1.5 1.7 5 2
MnPd 3.9 0.93 −0.6 0.5 2.6 223c103 0.3 0.5 0.6 1.6 0.9 −2(−5) 93 (4)
10.3 1.8 0.1 0.5 1.3 5.6
MnPt 3.8 0.93 0.45 0.48 2.7 119,d164c48 0.43 2.2 7.1 6.7 1.2 −15 (17) 1 (11)
4.8 3.5 1.5 21 4.6 10
MnIr 2.6 0.97 −5.9 0.4 0.5 176–269e350 0.22 36 35 39 3.6 7 (13) 18 ( −7)
35 0.36 14 11 12 6
aReference [ 33].
bReference [ 34].
cReference [ 35].
dReference [ 36].
eReferences [ 35,37–39].
where ˆ/Delta1s
/vectorkis the exchange spitting of the conduction electrons
for sublattice s[32].
Since for AFMs with Néel temperatures above room tem-
perature λ/greatermuchKj, one might conclude that αr/greatermuchαexand the
effects of the intersublattice spin exchange on the AFMRlinewidth become negligible. However, since |α
ss|is propor-
tional to the intersublattice hopping strength [ 32], one can ex-
pect to have /bardblαss/prime/bardbl/greatermuchα0. Therefore, the interplay between the
relativistic and exchange terms is material dependent, wherefor systems with λ/greatermuchK
j, the effect of the intersublattice spin
exchange on the AFMR linewidth may dominate.
The crystal structure, conventional and primitive cell, and
the AFM ordering of the MnX (X=Pt, Pd, Ir, Rh) family
of metallic bulk AFMs and the biaxially strained AFM bulkFeRh is shown in Fig. 1. The details of the electronic structure
calculations of the various damping and antidamping proper-ties are described in detail in the Supplemental Material [ 32].
Table Ilists the ab initio results of the sublattice magnetic
moment M
s,c/aratio, magnetocrystalline anisotropy energy
K(2)
⊥, intersublattice exchange interaction λ, and ratio of the
longitudinal conductivity to the broadening parameter ρxx/η
for the FeRh and Mn Xsystems, respectively. We also list
experimental values of the room-temperature ρxxwhich were
used to determine the broadening parameter. For FeRh we
provide the linear dependence of K(2)
⊥as a function of biaxial
strain, x≡c/a−1, which shows that under compressive
(tensile) biaxial strain the magnetization is along the c(a) axis
[40]. For the Mn Xfamily the magnetization is along the aaxis
except for MnPt. The MCA values for both Mn Xand FeRh
are in good agreement with previous ab initio calculations
[40–43].We also list in Table Ivalues of αdandα/vectorms/bardbl/vectora(/vectorc)
0 for sublat-
tice magnetization parallel to the /vectora(/vectorc) axis, and the relativistic
(αr
⊥) and exchange ( αex
⊥) damping components of the effective
Gilbert damping for ηat room temperature and η/10 corre-
sponding to low temperature. The decrease (increase) of thedamping constants with decreasing temperature is associatedwith the conductivitylike (resistivitylike) regime where theinterband (intraband) scattering contribution is dominant. Wefind that for the ηvalue corresponding to room temperature,
the AFMR linewidth is mostly dominated by the relativisticcomponent, while at low temperatures the two components arecomparable in magnitude. For FeRh a relatively large strain(i.e.,x≈0.1) is required to render the exchange component
to have a significant contribution to the AFMR linewidth atlow temperature.
In Fig. 2(a) we show the variation of α
dandα/vectorms/bardbl/vectora
0
withηfor cubic FeRh as a representative example. We
find that in the experimentally relevant range of η(≈10–
100 meV), α0is in the resistivity regime where the in-
terband component is dominant. On the other hand, αd
decreases monotonically with η, suggesting that the intra-
band component is dominant. Unlike α0which may depend
on the orientation of the Néel ordering, αdis relatively
isotropic.
Finally, Table Ilists the values for the current-induced
FL and DL intersublattice torque coefficients τ0,i
FL/DLunder
an external electric field along the i(aorc) direction.
The sublattice torques are determined by fixing the orien-tation of the ¯ssublattice magnetization and calculating the
torque for different magnetization orientations of the ssub-
lattice, using the symmetric and antisymmetric correlation
220410-3FARZAD MAHFOUZI AND NICHOLAS KIOUSSIS PHYSICAL REVIEW B 98, 220410(R) (2018)
FIG. 2. (a) Sublattice Gilbert damping αd(dashed blue curve)
andα0(solid red curve) components for bulk cubic FeRh vs broad-
ening parameter η. (b) Sublattice current-induced FL (dashed blue)
and DL (red solid) torque coefficients for FeRh under an external
electric field along the aaxis. The coefficients were calculated by
fitting the vector dependence of the DL [ ∝/vectorms×(/vectorms×/vectorm¯s)] and
FL (∝/vectorms×/vectorm¯s) expressions for the symmetric and antisymmetric
components in Eq. ( 8a), respectively. The insets display the top view
of the vector field of the FL and DL torques for cone angles /lessorequalslant30◦.
expressions [ 44],
/vectorτS
s;i=¯h
πNkMs/vectorms×/summationdisplay
/vectorkTr/parenleftBigg
ˆA/vectorkˆ/Delta1s
/vectork/vectorˆσˆA/vectork∂ˆH/vectork
∂ki/parenrightBigg
, (8a)
/vectorτAS
s;i=2
MsNk/vectorms×/summationdisplay
nm/vectorkRe⎡
⎣Im/bracketleftbig/parenleftbigˆ/Delta1s
/vectork/vectorˆσ/parenrightbig
nm/parenleftbig∂ˆH/vectork
∂ki/parenrightbig
mn/bracketrightbig
(εn/vectork−εm/vectork−iη)2⎤
⎦fn/vectork.
(8b)
Here,fn/vectorkis the Fermi-Dirac distribution function and εm/vectorkare
the eigenvalues of the Hamiltonian ˆH/vectork. Having determined the
torques, we fit the results to the expected τ0,i
FL/vectorms×/vectorm¯sand
τ0,i
DL/vectorms×(/vectorms×/vectorm¯s) expressions and find the values for the
FL and DL torque coefficients. The calculations reveal thatthe symmetric (antisymmetric) torque expression leads to theDL (FL) component, in contrast to the SOT results in HM/FM
bilayers [ 44].
Figure 2(b) displays the current-induced FL and DL inter-
sublattice torques under an external electric field along theadirection for FeRh, as a representative example, versus
the broadening parameter η. Note the FL component that
originates from the antisymmetric torque term [Eq. ( 8b)] is
relatively insensitive to η(or temperature). On the other hand,
the DL intersublattice torque varies almost linearly with η(for
η< 0.1 eV) and is of extrinsic origin. Thus, in the ballistic
regime where the electronic spin diffusion length is infinite,there is no current-induced transfer of angular momentum be-tween the two sublattices, as it would violate the conservationlaw of total angular momentum. In the extreme opposite limit,where the spin diffusion length is much smaller than the latticeconstant, each sublattice can be viewed as a magnetic leadin a spin valve system where the intersublattice DL torque isanalogous to the DL spin transfer torque.
In summary, we have employed ab initio based calcula-
tions to investigate the AFMR phenomena in Mn X(X=Ir,
Pt, Pd, Rh) and biaxially strained FeRh metallic AFMs inthe presence or absence of an external electric field. Wedemonstrate that both the AFMR linewidth and effectiveGilbert damping parameter can be separated into relativisticand exchange contributions, where the former dominates atroom temperature while the latter becomes significant at lowtemperatures. We find that both the AFMR linewidth and theintersublattice exchange interaction (and hence the AFMRfrequency and Néel temperature) can be tuned by the externalelectric field. For example for AFM FeRh an external electricfield of 1 V /μm (current density of ≈10
12A/m2) yields an
intersublattice FL torque of 3.3 meV ( ≈0.01λ) and DL torque
of 1.4m e V ≡2.1 THz change of AFMR linewidth.
The work is supported by NSF ERC-Translational Applica-
tions of Nanoscale Multiferroic Systems (TANMS) Grant No.1160504 and by NSF-Partnership in Research and Educationin Materials (PREM) Grants No. DMR-1205734 and No.DMR-1828019.
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220410-6 |
PhysRevB.96.054444.pdf | PHYSICAL REVIEW B 96, 054444 (2017)
Gate-controlled magnon-assisted switching of magnetization
in ferroelectric/ferromagnetic junctions
Yaojin Li,1Min Chen,1Jamal Berakdar,2and Chenglong Jia1,2
1Key Laboratory for Magnetism and Magnetic Materials of the Ministry of Education, Lanzhou University, Lanzhou 730000, China
2Institut für Physik, Martin-Luther Universität Halle-Wittenberg, Halle (Saale) 06099, Germany
(Received 21 June 2017; revised manuscript received 23 July 2017; published 30 August 2017)
Interfacing a ferromagnet with a polarized ferroelectric gate generates a nonuniform, interfacial spin density
coupled to the ferroelectric polarization. This coupling allows for an electric field control of the effective fieldacting on the magnetization. To unravel the usefulness of this interfacial magnetoelectric coupling we investigatethe magnetization dynamics of a ferroelectric/ferromagnetic multilayer structure using the Landau-Lifshitz-Baryakhtar equation. The results demonstrate that the interfacial magnetoelectric coupling is utilizable as ahighly localized and efficient tool for manipulating magnetism by electrical means. Ways of enhancing thestrength of the interfacial coupling and/or its effects are discussed.
DOI: 10.1103/PhysRevB.96.054444
I. INTRODUCTION
Electrical control of magnetism has the potential to boost
spintronic devices with a number of novel functionalities[1–5]. To mention an example, magnetization switching can be
achieved via a spin-polarized electric current by virtue of thespin-transfer torque or the spin-orbital torque in the presence ofa spin orbital interaction [ 6–15]. One may also use an electric
field to manipulate the magnetization dynamics [ 16–22]i n
which case the electric field may lead to modulations in the
charge-carrier density or may affect the magnetic propertiessuch as the magnetic moment, the exchange interaction,and/or the magnetic anisotropy [ 16–19]. Compared to driving
magnetization via a spin-polarized current, an electric fieldgoverning the magnetization has a clear advantage as it allowsfor nonvolatile device concepts with significantly reduced
energy dissipation. On the other hand, an external electric field
applied to an itinerant ferromagnet (FM) is shielded by chargeaccumulation or depletion caused by the spin-dependentscreening charge that extends on a length scale of only a fewangstroms into the FM [ 23]. This extreme surface confinement
of screening hinders its utilization to steer the magneticdynamics of bulk or a relatively thick nanometer-sized FM
[24,25]. Experimentally, ultrathin metallic FM films were thus
necessary to observe an electric-field influence on the dynamicof an FM [ 16,17,26].
In this work we show that while the spin-polarized
screening charge is surface confined, in the spin channel a local
nonuniform spiral spin density builds up at the interface and
goes over into the initial uniform (bulk) magnetization awayfrom the interface. Hence, this interfacial spin spiral acts as a
topological defect in the initial uniform magnetization vector
field. The range of the spiral defect is set by the spin diffusion
length λ
m[27] which is much larger than the charge screening
length. This spin-spiral constitutes a magnetoelectric coupling
with a substantial influence on the transversal magnetization
dynamics of the FM layer with a thickness as large as tens
of nanometers [ 28]. The interfacial spiral spin density can
be viewed as a magnonic accumulation stabilized by the
interfacial, spin-dependent charge rearrangement at the contact
region between the FM and the ferroelectrics (FE) (with aFE polarization P) and by the uniform (bulk) magnetization
of FM far away from the interface [ 30].Presponds to an
external electric field and so does the magnetic dynamics.
As shown below, this magnonic-assisted magnetoelectric
coupling arising when using a dielectric FE gate allows a
(ferro)electric-field control of the effective driving field that
governs the magnetization switching of a FM layer with a
thickness on the range of the spin diffusion length λm, which
is clearly of an advantage for designing spin-based, nonvolatile
nanoelectronic devices.
In Sec. IIwe discuss the mathematical details of the
spin-spiral magnetoelectric coupling, followed by its imple-mentation into the equations of motion for the magnetiza-tion dynamics in Sec. III. In Sec. IVresults of numerical
simulations are presented and discussed showing to whichextent the spin-spiral magnetoelectric coupling can allowfor the electric-field control of the magnetization in FE/FMcomposites. Ways to enhance the effects are discussed andbrief conclusions are made in Sec. V.
II. INTERFACIAL MAGNETOELECTRIC COUPLING
Theoretically, the above magnon accumulation scenario
maybe viewed as follows: When a FE layer with remanentelectric polarization Pand surface charges σ
FEis brought in
contact with an itinerant (charge-neutral) FM, bond rearrange-ments occur within a few atomic layers in the interface vicinity[31]. On the FM side, the rearranged spin polarized charge
density implies a spin configuration different from the bulkone. The modifications of the magnitude of the interfaciallocal magnetic moments are dictated by hybridization andcharge transfer and were studied thoroughly both theoreticallyand experimentally (e.g., Ref. [ 31]). Here we are interested in
the consequence on the long-range magnetic order extendingto the asymptotic bulk magnetization. In the mean-fieldformulations, the induced spin density sis exchange coupled
with the localized magnetic moments S, which can be treated
classically as an effective magnetization M=−
gμ B
a3Swith
μB,g, andabeing the Bohr magneton, gfactor, and lattice
constant, respectively. The associated sdexchange coupling
2469-9950/2017/96(5)/054444(6) 054444-1 ©2017 American Physical SocietyY AOJIN LI, MIN CHEN, JAMAL BERAKDAR, AND CHENGLONG JIA PHYSICAL REVIEW B 96, 054444 (2017)
energy at the FM interface is
Fsd=JsdM
Mss·m, (1)
where mis a unit vector in the direction of M.Msis the intrinsic
saturation magnetization. Within the Stoner mean-field theory[32] the spin polarization ηof the electron density in transition
FM metals is usually less than 1; we can decompose theinduced spin density sas [30]
s=s
/bardbl+s⊥, (2)
where s/bardblrepresents the spin density whose direction follows
adiabatically the intrinsic magnetization Mat an instantaneous
timet.s⊥describes the transverse deviation from M.G i v e n
that the steady-state charge accumulation entails much higherenergy processes than spin excitations, in the absence of acharge current across the FE/FM interface, the spin diffusionnormal to the FM/FE interface (hereafter refereed to as the z
direction with its origin at the interface) follows the dynamicequation (see Refs. [ 30,33] for details)
∂s
/bardbl
∂tm+s/bardbl∂m
∂t+∂s⊥
∂t−D0∇2
zs/bardbl−D0∇2
zs⊥
=−s/bardbl
τsf−s⊥
τsf−s⊥×m
τex, (3)
where D0is the diffusion constant and τex≈¯h/(2Jsd).τsf
is the spin-flip relaxation time due to scattering from impu-
rities, electrons, and phonons; τsf∼10−12–10−14s[34] and
τex/τsf∼10−2for typical FM metals [ 27]. The time-derivative
terms∂s/bardbl
∂t,∂m
∂t, and∂s⊥
∂tbelow THz are negligible compared
withs/τsfands/τex. Thus the steady state is set by [ 30]
D0∇2
zs/bardbl=s/bardbl
τsfandD0∇2
zs⊥=s⊥×m
τex, (4)
implying an exponentially decaying spiral spin density [ 30],
s/bardbl=ησFM
λmee−z/λ m, (5)
s⊥=(1−η)QmσFM
ee−(1−i)Qm·r. (6)
HereσFM=σFE≈/epsilon1FEEis the surface charge density due to
the electric neutrality constraint at the interface, /epsilon1FEandEare
the dielectric permittivity of FE and an applied normal electricfield, respectively. λ
m=√D0τsfis the effective spin-diffusion
length and the normal spin spiral wave vector Qm=1√2D0τexˆez.
Clearly, in the presence of the exchange interaction with long-
range FM ordering, the accumulated (magnonic) spin densityextends in the FM system over a nanometer characteristiclength ( ∼λ
mbeing 38 ±12 nm in Co [ 27]) which is much
larger than the electrostatic screening length (a few angstroms),albeit both are associated by largely different energy scales.
As we are interested in the effect of the low-energy
accumulated magnonic density on the spin dynamic in FM wecan safely assume that the spin-dependent charge excitationsare frozen (because of the higher energy scale) during the(GHz-THz) spin dynamics in the FM. Treating the magneticdynamics, we consider the additional effective magnetoelectricfieldH
meacting on the magnetization dynamics M(t) due to the
interfacial spin order. To leading terms, from the sdinteraction
FIG. 1. Schematics of the plane of variation for the magnetization
M=M{cosφsinθ,sinφsinθ,cosθ}. The FM/FE interface is re-
ferred to as the xyplane. Hme
θandHme
φare the transversal components
of the interface magnetoelectric field.
energy [Eq. ( 1)] we derive
Hme=−δFsd/δM=−Jsd
Mss. (7)
We choose nanometer-thick layers Co and BaTiO 3as prototyp-
ical FM and FE layers for estimating the characteristics of Hme.
The density of surface charges [ 35] reads σFE=0.27 C/m2and
the parameters of Co are [ 36]Ms=1.44×106A/m,K1=
4.1×105J/m3,λm=40 nm [ 27], and η=0.45 [ 32]. We
find thus |Hme|≈0.2 T with Jsd≈0.1e V/atom and the FM
thickness dFM=40 nm. Such a strong magnetoelectric field is
comparable with the uniaxial anisotropic fieldK1
Ms≈0.3To f
Co. More importantly, note that the nonadiabatical componentH
me
⊥is always perpendicular to the direction of magnetization
M, acting as a fieldlike torque and a dampinglike torque at all
time (cf. Fig. 1), which would play a key role for electric-field
assisted magnetization switching.
III. MAGNETIZATION DYNAMICS
We start from the Landau-Lifshitz-Baryakhtar equation
(LLBar) [ 37–39] for the magnetization dynamics at the FM
interface,
∂M
∂t=−γM×Heff+ˆ/Lambda1r·Heff−ˆ/Lambda1e,ij∂2Heff
∂xi∂xj, (8)
where γis the gyromagnetic ratio. The last two terms
describe the local and nonlocal relaxations. ˆ/Lambda1rand ˆ/Lambda1eare
generally the relaxation tensors of relativistic and exchangenatures, respectively. The anisotropy of relaxations decreaseswith increasing temperature. Experimentally, the isotropy ofrelaxations were discussed in Ref. [ 40]. We can represent the
relaxation tensors as ˆ/Lambda1
r=λrand ˆ/Lambda1e=λewhere λr=γαM s
andλe=γgμ B¯hG 0/(8e2) with αandG0being the Gilbert
damping coefficient and the conductivity of FM system,respectively. eis the electron charge. In contrast to the
Landau-Lifshitz-Gilbert equation, the LLBar equation doesnot conserve the magnitude of the magnetization capturingthe magnetic relaxations in metals, especially the case for FM
054444-2GATE-CONTROLLED MAGNON-ASSISTED SWITCHING OF . . . PHYSICAL REVIEW B 96, 054444 (2017)
metal interfaces. This is necessary in our case to ensure that the
local magnetic order which is in equilibrium with the interfaceregion relaxes to the asymptotic bulk magnetization.
By introducing M=Mminto the LLBar equation, we infer
the following equation for the direction of magnetization [ 39]:
∂m
∂t=−γm×Heff+1
MsR⊥ (9)
withR=λrHeff−λe∇2
zHeffandR⊥=−m×(m×R).Here
Heff=H0
eff+Hme(10)
is the effective magnetic field, in which H0
efffollows from the
functional derivative of the free-energy density via [ 41]
H0
eff=−δF0/δM,
F0=−K1(sin2θcos2φsin2θu+cos2θcos2θu)
−K1
2sin 2θsin 2θucosφ
−/parenleftbig
Ks/dFM−μ0M2
s/2/parenrightbig
cos2θ−M·B. (11)
K1is the uniaxial magnetocrystalline anisotropy energy, Ks
is the magnetic surface anisotropy contribution which is
significant for relatively thin magnetic films and favors amagnetization out of the xyplane. μ
0M2
sdenotes the demag-
netizing field contribution, which favors a magnetization inplane. M·Bis the Zeemann interaction and θ
uis the tilted
angle of the easy axis from the zdirection.
Clearly, the nonuniform effective field Hmedue to the s-d
interaction with the exponentially decaying spiral spins wouldgive rise to a nonlocal damping of the magnetization dynamics.Considering that the contribution of the induced spin densityto the spatial distribution of local ferromagnetic moments issmall, we have
/angbracketleftbig
∇
2
zs⊥/angbracketrightbig
=2Q2
m(/angbracketleftsφ
⊥/angbracketrightˆeθ−/angbracketleftsθ
⊥/angbracketrightˆeφ). (12)
Without loss of generality one can take /angbracketleftsφ
⊥/angbracketright=/angbracketleftsθ
⊥/angbracketright=1√
2/angbracketlefts⊥/angbracketright.
It is also convenient to redefine some dimensionless pa-
rameters which are ˜dFM=dFM
λm,˜t=tγT≈28tGHz, and
˜Jsd=Jsd
eVσFM
Psλm
dFMwith the FE spontaneous polarization Ps.I n
the following ˜Jsdis taken as an adjustable parameter in view
of ferroelectric tuning of magnetoelectric field Hme.
IV . NUMERICAL RESULTS AND DISCUSSIONS
For the surface anisotropy Ks≈10−3J/m2andμ0M2
s/2≈
1.3×106J/m3of Co sample [ 36], the dominant contribution
of the anisotropic term ( Ks/dFM−μ0M2
s/2) in Eq. ( 11) has the
form either Ks/dFMor−μ0M2
s/2 depending on the thickness
dFM, i.e., the magnetization will be either normal to the FM
interface ( θu=0) or in the interface plane ( θu=π/2).
Case I . Normal FM magnetization with θu=0: The free
energy density is
F0=−Keffcos2θ−M·B,K eff=K1+Ks
dFM−μ0M2
s
2,
(13)which leads to
H0
eff=2Keff
Mscosθˆez (14)
without an applied magnetic field B. The LLBar equation reads
then
∂θ
∂˜t=γe
+√
2Hme
⊥−αKeff
Mssin 2θ, (15)
sinθ∂φ
∂˜t=−γe
−√
2Hme
⊥+Keff
Mssin 2θ (16)
withγe
±=1−2Q2
mλe
γM s±λr
γM s=γe±α.
Clearly, under a weak interfacial ME field, the condition
Hme
⊥=√
2α
γe
+Keff
Mssin 2θ (17)
can be satisfied; the polar angle θends up processionally in
the equilibrium state [cf. Fig. 2(a) with∂θ/∂ ˜t=0]. Otherwise,
the strong transversal field Hme
⊥results in a magnetization flip
over the normal ˆezdirection [Fig. 2(b)]. Considering that the
ME field depends linearly on the applied electric field andthe reciprocal of FM thickness, one would expect a transitionfrom the magnetization procession around the zaxis (for a
small electric field Eand/or relatively thick FM layers) to
the magnetization flip over the normal direction (for a strongelectric field and/or ultrathin FM film) at the critical points, asdemonstrated in Figs. 2(c) and2(d).
Case II . In-plane magnetization with θ
u=π/2: Disregard-
ing the surface anisotropy ( Ks/dFM/lessmuchμ0M2
s/2) for a thick
FM film, the effective magnetic field reads
H0
eff=2K1/M ssinθcosφˆex−μ0Mscosθˆez+B (18)
and the magnetization favors an in-plane ˆexaxis, which means
φ(0)=0 with the external magnetic field B=0. Upon some
simplifications the LLBar equation reads
∂θ
∂˜t=γe
+√
2Hme
⊥+αμ0Ms
2sin 2θ+αK1
Mssin 2θcos2φ
−K1
Mssinθsin 2φ+αBcosθcosφ−Bsinφ, (19)
sinθ∂φ
∂˜t=−γe
−√
2Hme
⊥−μ0Ms
2sin 2θ−αK1
Mssinθsin 2φ
−K1
Mssin 2θcos2φ−Bcosθcosφ−αBsinφ.
(20)
In the absence of an external magnetic field B, the magnetiza-
tion dynamics is determined by three parameters: α,Hme
⊥, and
K1/M s. First, let us ignore the damping terms for small Gilbert
damping coefficient α; the weak ME field Hme
⊥satisfies∂θ
∂˜t=0
and∂φ
∂˜t=0, resulting in a relocation of the magnetization with
an equilibrium tilted angle in the vicinity of xaxis, as shown in
Fig. 3(a). However, when Hme
⊥is stronger than the anisotropic
fieldK1/M sand the demagnetization field μ0Ms, no solutions
exist for ∂θ/∂ ˜t=0 at all time; the magnetization possesses
az-axial flip mode in the whole spin space [cf. Fig. 3(b)]
similar to the case of normal FM magnetization. On the otherhand, after accounting for terms containing αin the LLBar
054444-3Y AOJIN LI, MIN CHEN, JAMAL BERAKDAR, AND CHENGLONG JIA PHYSICAL REVIEW B 96, 054444 (2017)
FIG. 2. Dynamics of the normal magnetization. The polar angle θvs dimensionless time ˜tfor different ME field (a) ˜Jsd=0.005 and
(b) ˜Jsd=0.03, respectively. Panels (c) and (d) demonstrate the thickness and electric-field dependence of δθmax=θmax−θ(0), where θ(0)
andθmaxare respectively the initial value [ θ(0)=0] and the maximum value of the polar angle during the time evolution of magnetization.
δθmax=πindicates a magnetization flip over the normal ˆezdirection. Here, α=0.1,/epsilon1FE=1000, and Keff∼K1.
equations, we would have additional magnetization rotation
around the zaxis [Fig. 3(c)]. Further insight into the detailed
characterization of magnetization dynamics is delivered bynumerics for a varying strength of the ME field ˜J
sdand the
uniaxial anisotropy K1/M sin Fig. 4withα=0.1. There
are two new phases, the z-axial flip mode and the z-axial
rotational mode, which were unobserved in the FM systems inthe absence of interface ME interaction. With decreasing thedamping α, the area of the z-axial rotational mode shrinks and
vanishes eventually. By applying an external magnetic field B
along the xdirection, only slight modifications are found in
the phase diagram. However, the initial azimuthal angle φ(0)
deviates from the easy axis with a rotating magnetic field Bin
thexyinterface plane. Considering the LLBar equations with
the initial condition θ(t=0)=π/2, we have
∂θ
∂˜t|˜t=0≈γe
+√
2Hs−d
⊥−K1
Mssin 2φ(0) (21)with a small damping α. As the dynamic equation is sensitive to
the initial azimuthal angle φ(0), the calculations show that the
magnetization dynamics may change between the processionalmode around the xaxis and the z-axial flip or z-axial rotational
mode, depending on the initial value of φ(0).
Phenomenologically, such z-axial flip mode and z-axial
rotational mode are exhibited as a precessional motion of themagnetization with a negative damping, as shown in the exper-imental observation for polycrystalline CoZr/plumbum mag-nesium niobate–plumbum titanate (PMN-PT) heterostructures[5], where an emergence of positive-to-negative transition of
magnetic permeability was observed by applying external elec-tric field. There is also some analogy between these nonequi-librium switching behaviors in FM/FE heterostructures andthe negative damping phenomenon in trilayer FM/normal-metal/FM structures, in which the supplying energy is thoughtto be provided by injecting spin polarized electrons from
FIG. 3. Dynamics of the in-plane magnetization for different interface ME field and anisotropic field: (a) ˜Jsd=0.03 and 2 K1/M s=0.6T ,
(b)˜Jsd=0.03 and 2 K1/M s=0.3T ,a n d( c ) ˜Jsd=0.015 and 2 K1/M s=0.1 T, respectively. Here ˜dFM=1a n dα=0.1.
054444-4GATE-CONTROLLED MAGNON-ASSISTED SWITCHING OF . . . PHYSICAL REVIEW B 96, 054444 (2017)
FIG. 4. Phase diagrams of the in-plane magnetization dynamics
withα=0.1,˜dFM=1, and B=0: (a) the localized precessional
mode, (b) the z-axial flip mode, and (c) the z-axial rotational mode,
respectively. The characterization of the dynamic behavior of the
magnetization in three different phases is illustrated in Fig. 3.I n s e t s
show the corresponding time evolution of the magnetization in eachphase.
an adjacent FM layer, magnetized in the opposite direction
compared to the FM layer under consideration [ 42,43].
V . CONCLUSION AND OUTLOOK
The above theoretical considerations along with numerical
simulations for specific FE/FM composites endorse that themagnetization dynamics can be controlled by an electricfield of moderate strength. The excitations triggered by theelectric field are transferred to the spin system via theinterface spiral-mediated magnetoelectric coupling and mayresult in a magnetization switching. This direct electric-field
control of the magnetization switching offers a qualitatively
different way to manipulate magnetic devices swiftly andwith low-power write capability. On the other hand, even
FIG. 5. Schematic structure diagram of the FE/FM multilayer
system with enhanced magnetoelectric effect. The arrows mark the
directions of the FE polarization Pand the FM magnetization M,
respectively.
though the spin-mediated magnetoelectric coupling has a
much longer range than the surface localized charge-mediatedFE/FM coupling, its range is still limited by the spin-diffusionlength which is material dependent but yet is in the rangeof several tens of nanometers. Hence, the full power of thepredicted effect is expected for multilayer systems such asthose schematically shown in Fig. 5: Starting from a bilayer
structure with a thick FE interfaced with a FM layer, whichhas a thickness in the range of the spin-diffusion length, wesuggest to cap this structure with a spacer layer, for instance an(oxide) insulator. Repeating the whole structure as proposedin Fig. 5allows for a simple serial extension from a double
to multilayer structure while enhancing the influence of themagnetoelectric coupling.
ACKNOWLEDGMENTS
This work is supported the National Natural Science Foun-
dation of China (Grant No. 11474138), the German ResearchFoundation (Grant No. SFB 762), the Program for Changjiang
Scholars and Innovative Research Team in University (Grant
No. IRT-16R35), and the Fundamental Research Funds for theCentral Universities.
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PhysRevB.98.165444.pdf | PHYSICAL REVIEW B 98, 165444 (2018)
Magnetization nutation induced by surface effects in nanomagnets
R. Bastardis,*F. Vernay,†and H. Kachkachi‡
Laboratoire PROMES CNRS (UPR-8521) & Université de Perpignan Via Domitia,
Rambla de la thermodynamique, Tecnosud, 66100 Perpignan, France
(Received 19 July 2018; revised manuscript received 4 October 2018; published 30 October 2018)
We investigate the magnetization dynamics of ferromagnetic nanoparticles in the atomistic approach taking
account of surface anisotropy and the spin misalignment it causes. We demonstrate that such inhomogeneousspin configurations induce nutation in the dynamics of the particle’s magnetization. More precisely, in additionto the ordinary precessional motion with frequency f
p∼10 GHz, we find that the dynamics of the net magnetic
moment exhibits two more resonance peaks with frequencies fcandfnwhich are higher than the frequency fp:
fc=4×fp∼40 GHz is related with the oscillations of the particle’s magnetic moment between the minima of
the effective potential induced by weak surface anisotropy. On the other hand, the much higher frequency fn∼
1 THz is attributed to the magnetization fluctuations at the atomic level driven by exchange interaction. We havecompared our results on nutation induced by surface effects with those rendered by the macroscopic approachbased on the Landau-Lifshitz-Gilbert equation augmented by an inertial term (proportional to the second-ordertime derivative of the macroscopic moment) with a phenomenological coefficient. The good agreement betweenthe two models has allowed us to estimate the latter coefficient in terms of the atomistic parameters such as thesurface anisotropy constant. We have thus proposed a different origin for the magnetization nutations as beinginduced by surface effects and have interpreted the corresponding resonance peaks and their frequencies.
DOI: 10.1103/PhysRevB.98.165444
I. INTRODUCTION
Research on nanoscale magnetic materials benefits from
a continuing impetus owing to an increasing demand of ourmodern societies for ever smaller devices with ever higherstorage densities and faster access times. These devices arethe upshot of spintronics or magnonic applications with ma-terials exhibiting thermally stable magnetic properties, energyefficient magnetization dynamics, and controlled fast magne-tization switching. In the macroscopic approach, the magneti-zation dynamics on time scales ranging from microsecondsto femtoseconds can be described by the Landau-Lifshitz-Gilbert (LLG) equation [ 1–3]
dm
dt=m×/parenleftbigg
γHeff−α
mdm
dt/parenrightbigg
, (1)
where Heffis the effective field acting on the macroscopic
magnetic moment mcarried by the nanomagnet, γthe gy-
romagnetic factor, and αthe phenomenological damping pa-
rameter. Equation ( 1) describes the relaxation of mtowards
Heffwhile maintaining a constant magnitude, i.e., /bardblm/bardbl=m,
assuming that the nanomagnet is not coupled to any heatbath or other time-dependent external perturbation. The firstterm on the right hand of Eq. ( 1) describes the precessional
motion of the magnetic moment maround the effective field
H
eff. This is well known from the classical mechanics of a
gyroscope. Indeed, if an external force tilts the rotation axis of
*roland.bastardis@univ-perp.fr
†francois.vernay@univ-perp.fr
‡hamid.kachkachi@univ-perp.frthe gyroscope away from the direction of the gravity field, therotation axis no longer coincides with the angular-momentumdirection. The consequence is an additional movement of thegyroscope around the axis of the angular momentum. Thismotion is called nutation . In the case of the magnetic moment
m, this additional motion (nutation) can occur if the effective
field H
effbecomes time dependent. Indeed, in the presence
of a time-dependent magnetic field (rf or microwave field),there appears the fundamental effect of transient nutationswhich has been widely investigated in NMR [ 4], EPR [ 5,6],
and optical resonance [ 7]; see also the review by Fedoruk
[8]. Magnetic or spin nutation was first predicted in Joseph-
son junctions [ 9–13] and was later developed using various
approaches based on first principles [ 14], electronic structure
theory [ 15–19], or in a macrospin approach where the LLG
equation ( 1) is extended by a second-order time derivative
[20–23].
Magnetic nutation may also occur at the level of atomic
magnetic moments on ultrashort time scales. For instance, inRef. [ 24] it is argued that nutation is enhanced for atomic
spins with low coordination numbers and that it occurs ona time scale of the magnetic exchange energy, i.e., a fewtens of femtoseconds. More generally this spin nutation iscaused by a nonuniform spin configuration which leads toan inhomogeneous effective field H
effwhose magnitude and
orientation are different for different lattice sites. These spatialinhomogeneities are a typical result of surface effects thatbecome very acute in nanoscale magnetic systems such asmagnetic nanoparticles. In this work we adopt this atomisticapproach and show that, for a magnetic nanoparticle regardedas a many-spin system, a model henceforth referred to asthemany-spin problem (MSP), surface effects do induce
2469-9950/2018/98(16)/165444(9) 165444-1 ©2018 American Physical SocietyR. BASTARDIS, F. VERNAY , AND H. KACHKACHI PHYSICAL REVIEW B 98, 165444 (2018)
nutations of the net magnetic moment of the nanoparticle.
More precisely, this approach involves at least three energyscales, namely the core (magnetocrystalline) anisotropy, thesurface anisotropy, and exchange coupling. Consequently,there appear at least three different frequencies: the lowestcorresponds to the ordinary precession around a fixed axiswith a constant projection of the net magnetic moment on thelatter and the other two frequencies correspond to nutationswith a time-dependent projection of m. In the limiting case
of weak surface effects, inasmuch as the spin configurationinside of the nanomagnet can be regarded as quasicollinear,the dynamics of the nanomagnet can be described with thehelp of an effective macroscopic model for the net magneticmoment of the nanomagnet. This model will be referred toin the sequel as the effective one-spin problem (EOSP). More
precisely, it has been shown that a many-spin nanomagnet of agiven lattice structure and energy parameters (on-site core andsurface anisotropy, local exchange interactions) can approx-imately be modeled by a macroscopic magnetic moment m
evolving in an effective potential [ 25] that comprises second
and fourth powers of the components m
α,α=x,y,z . Within
this approach we find two precession frequencies fpandfc:
fpcorresponds to the precession of maround the reference z
axis with constant mzandfcto the frequency of oscillations of
mbetween the four minima of the effective potential produced
by its quartic term. When surface or boundary effects are toostrong, the spin configuration can no longer be considered asquasicollinear, and thereby the effective model is no longer agood approximation, one has to take account of higher-orderfluctuations of the atomic spins. Doing so numerically, wefind an additional nutation frequency f
nwhich is much higher
thanfpandfcas it corresponds to a movement of the atomic
spins that occurs at the time scale of the magnetic exchangeinteraction.
Observation of nutation in magnetization dynamics is dif-
ficult because the effect is rather small and the correspondingfrequency is beyond the detection capabilities of standardtechniques using the magnetization resonance such as thestandard FMR or a network analyzer with varying frequency.Nevertheless, from the high-frequency FMR (115–345 GHz)spectra obtained for ultrafine cobalt particles, the authors ofRef. [ 26] inferred low values for the transverse relaxation time
τ
⊥(two orders of magnitude smaller than the bulk value)
and suggested that this should be due to inhomogeneousprecession which possibly originates from surface spin dis-order. Likewise, in Ref. [ 24] it was shown that nutation in
magnetization dynamics of nanostructures occurs at edgesand corners, with a much smaller amplitude than the usualprecession. More recently, Li et al. [27] performed HF-FMR
measurements of the effective magnetic field and showed thatthere was an additional contribution which is quadratic infrequency as obtained from the additional term d
2m/dt2in
the LLG equation [ 20,21].
To sum up, in this work we first demonstrate that surface
effects or, more generally, noncollinear atomic spin orderinginduce nutation in the magnetization dynamics of a nano-magnet. Second, it establishes a clear connection betweennutation within our atomistic approach and that describedby the quadratic frequency dependence of the effective fieldas described within the macroscopic approach includingmagnetization inertia. If we cannot provide an analytical con-
nection between the corresponding parameters, we do providea numerical correspondence between the phenomenologicalparameter of the macroscopic approach and our atomisticparameters, such as the surface anisotropy constant. We alsopropose an intermediate macroscopic model which accountsfor all three resonance frequencies. Finally, we speculate thatthe resonance peak at f
c, induced by surface effects, provides
a route for observing nutation in well prepared assembliesof nanomagnets. All in all, the main objective of the presentwork is to show that magnetic nutation in a nanoparticle origi-nates from surface effects which lead to spin noncollinearitieswithin the nanoparticle and the latter affect the high-frequencydynamics.
The paper is organized as follows. In Sec. IIwe present our
model of many-spin nanomagnets, discuss the effects of sur-face anisotropy on the magnetization dynamics, and presentour main results showing two resonance peaks which weattribute to two kinds of magnetization nutation. In Sec. II A
we also discuss a particular situation where it is possible toanalytically derive the equation of motion of the net magneticmoment of the (many-spin) nanomagnet, which makes it clearthat nutation is related with the spin fluctuations at the atomiclevel. In Sec. II B we compare our results with other works
in the literature mostly based on the macroscopic approachusing the Landau-Lifshitz-Gilbert equation augmented by aninertial term, and establish a quantitative relationship betweenthe corresponding sets of parameters. Finally, in Sec. IIIwe
summarize the main results of this work and then discussthe possibility to observe the magnetization nutations inresonance experiments.
II. MODEL AND HYPOTHESIS
We consider a nanomagnet with Natomic spins sion a
simple cubic lattice described by the (classical) Hamiltonian(/bardbls
i/bardbl= 1)
H=−1
2/summationdisplay
i,jJijsi·sj−h·N/summationdisplay
i=1si−N/summationdisplay
i=1Han,i, (2)
where h=μaH,μais the magnetic moment associated with
the atomic spin, His the magnetic field, Jijis the exchange
interaction (that may be different for core-surface, surface-surface, and core-core links), and H
an,iis the anisotropy
energy at site i,a function of sisatisfying the symmetry of
the problem. More precisely, Han,iis the energy of on-site
anisotropy which is here taken as uniaxial for core spins andof Néel’s type for surface spins [ 28], i.e.,
H
an,i=/braceleftbigg−Kc(si·ez)2,i ∈core,
+1
2Ks/summationtext
j∈n.n.(si·eij)2,i∈surface ,(3)
where eijis the unit vector connecting the nearest neighbors
at sites iandjandKc>0 and Ks>0 are respectively the
core and surface anisotropy constants.
The spin dynamics is described by the Landau-Lifshitz
equation (LLE) for the atomic spin si
dsi
dτ=si×heff,i−αsi×(si×heff,i), (4)
165444-2MAGNETIZATION NUTATION INDUCED BY SURFACE … PHYSICAL REVIEW B 98, 165444 (2018)
with the (normalized) local effective field heff,iacting on si
being defined by heff,i=−δH/δsi;τis the reduced time
defined by
τ≡t
τs, (5)
where τs=μa/(γJ) is a characteristic time of the system’s
dynamics. By way of example, for cobalt J=8 meV leading
toτs=70 fs. Henceforth, we will only use the dimensionless
timeτ. In these units, heff,i=μaHeff,i/J.
Equation ( 4)i sas y s t e mo f2 Ncoupled equations for the
spins si,i={1,..., N}. In this work, it is solved using itera-
tive optimized second-order methods using Heun’s algorithm.
The particle’s net magnetic moment is defined as
s0=1
NN/summationdisplay
i=1si. (6)
Next, we introduce the unit vector of s0
m≡1
s0s0,s 0=/vextenddouble/vextenddouble/vextenddouble/vextenddouble/vextenddouble1
N/summationdisplay
isi/vextenddouble/vextenddouble/vextenddouble/vextenddouble/vextenddouble. (7)
As discussed in the Introduction, because of surface effects
or spatial inhomogeneities of the effective field (mainly due tothe fact that the anisotropy constant and the easy axis dependon the lattice site), the spin configuration is not uniform foran arbitrary set of energy parameters. As a consequence, thevectors s
iare not all parallel to each other and as such we may
define their deviation from the direction mas [29]
si=(m·si)m+ψi,
where we have introduced the vector
ψi≡si−(m·si)m.
It can be easily checked that ψiis perpendicular to si, i.e.,
ψi·si=0=ψi·mand satisfies/summationtextN
i=1ψi=0. This means
that the transverse vector ψicontains the Fourier components
with k/negationslash=0and describes spin waves in the nanomagnet.
Whereas in the standard spin wave theory s0is a constant
corresponding to the ground-state orientation, here it is treatedas a time-dependent variable.
Note that using the condition /bardbls
i/bardbl= 1, we may write
si=m√
1−ψ2
i+ψi. Now, in the realistic case, Ks/lessmuchJ,
the deviations of sifrom the homogeneous state mare small
and one can adopt the following approximation:
si/similarequalm/parenleftbig
1−1
2ψ2
i/parenrightbig
+ψi≡m+δsi,
where
δsi≡−1
2ψ2
im+ψi. (8)
Then, we define the magnetization deficit due to surface
anisotropy as follows:
/Delta1m≡−1
N/summationdisplay
im·δsi. (9)
Using Eq. ( 8) and/summationtextN
i=1ψi=0we obtain
/Delta1m=1
2N/summationdisplay
iψ2
i=1−1
N/summationdisplay
i(m·si)=1−s0.(10)In what follows, we will show that the magnetization
nutations are a consequence of the magnetization deficit /Delta1m
(which is due to the transverse spin fluctuations ψi) with
respect to s0. In order to study nutation, we compute /Delta1m(τ)
or the components mα(τ), with α=x,y,z . In the sequel, we
will mainly study the latter as their behavior clearly illustratesthe precession and nutation phenomena. In the next sectionwe present a sample of our results obtained for a cube-shapednanomagnet described by the Hamiltonian ( 2) together with
the anisotropy model in Eq. ( 3).
A. Magnetization nutation induced by surface anisotropy
In order to clearly illustrate the central result of this
work, namely that spin noncollinearities, induced by surfaceanisotropy, lead to nutation in the magnetization dynamicsof a nanomagnet, we consider a simple shape, e.g., a cube.Today, nanocubes (of iron or cobalt) are routinely investigatedin experiments since their synthesis has become fairly wellcontrolled [ 30–35]. Here we consider a nanocube of N=729
spins located on the vertices of a simple cubic lattice (i.e.,N
x=Ny=Nz=9). This choice has the main advantage that
the number of core spins ( Nc=343) is comparable to that of
surface spins ( Ns=386), a configuration suitable for study-
ing the role of surface effects versus core properties. Then, wecompute the time evolution of the net magnetic moment mby
solving the system of equations ( 4), using Eqs. ( 6) and ( 7).
We start from the initial state s
i(t=0)=(1/2,1/2,1/√
2),
which corresponds to all spins tilted to the same angle withrespect to the zaxis of the laboratory frame.
Let us first consider the case of a nanocube with anisotropy
energy defined in Eq. ( 3), i.e., uniaxial for core spins and of
Néel’s type for surface ones. A surface spin is defined as thespin whose coordination number is smaller than in the core(here six on a simple cubic lattice). For simplicity, we set allexchange couplings equal to a reference value Jeverywhere
in the core, on the surface and at the interface betweenthem, i.e., J
cc=Jcs=Jss=J. All energy constants are then
measured in units of J, so that J=1 andkc≡Kc/J=0.01,
ks≡Kc/J=0.1. These are typical values extracted from
experiments on cobalt and iron nanoparticles [ 36–38]. In this
calculation, the external magnetic field and damping are bothset to zero.
Solving the LLE ( 4) renders the components of m(τ) de-
fined in Eq. ( 7). These are shown in Fig. 1. In the lower panel,
m
x(τ) andmy(τ) show the usual precessional movement of
m(τ) around the zaxis. The corresponding frequency for the
parameters given above is fp=14 GHz. If m(τ)w e r et o
exhibit only this precession, its component mz(τ) would be
a constant with a constant tilt angle between m(τ) and the z
axis. However, as can be seen in the upper panel, it is clearlynot the case. Indeed, we see a double modulation of m
z(τ)
in time; there are two oscillations: (i) one with frequencyf
c=4×fp=56 GHz and an amplitude that is an order of
magnitude smaller than precession and (ii) another oscillationwith the much higher frequency f
n=1.1 THz and an ampli-
tude two orders of magnitude smaller than precession. Theseoscillations are further illustrated in Fig. 2.
Let us now discuss the origin of these oscillations. As
discussed in the Introduction, in the case of not-too-strong
165444-3R. BASTARDIS, F. VERNAY , AND H. KACHKACHI PHYSICAL REVIEW B 98, 165444 (2018)
0 1 02 03 04 0 50 60 70-0.6-0.4-0.200.20.40.60 1 02 03 04 0 50 60 700.70.710.720.73
mx
mymz
t(ps)Reduced magnetic moment
FIG. 1. Time evolution of the average magnetization components
(mx,my,mz) for a nanomagnet of N=9×9×9=729 spins
with uniaxial anisotropy in the core and Néel surface anisotropy onthe surface.
surface effects, the MSP may be mapped onto an EOSP
[25,39–41] for the net magnetic moment mof the particle
evolving in an effective potential containing a quadratic anda quartic term in the components of m. This work has recently
been extended to cube-shaped magnets [ 42]. So for a nano-
magnet within the EOSP approach the equation of motionreads
dm
dτ=m×/bracketleftbig
2k2mzez−4k4/parenleftbig
m3
zez+m3
yey+m3
xex/parenrightbig/bracketrightbig
.(11)
Herez=6 is the coordination number and k2=kcNc/N.
For a sphere k4=κk2
s/zJ, where κis a surface integral [ 25],
and for a cube we have k4=(1−0.7/N1/3)4k2
s/zJ [42].
The components mα(τ) rendered by Eq. ( 11) exhibit two
resonance peaks corresponding to (i) the ordinary precessionwith frequency f
pand (ii) the oscillation with frequency fc
between the minima of the effective potential induced by the
term in k4. The latter is due to the fact that the effective
magnetic moment has now to explore a potential-energy sur-face that comprises four saddle points because of the cubicanisotropy (with constant k
4). Therefore, mzvisits a minimum
each time mpasses over one of these saddle points, and
this occurs with the frequency fc=4×fp=56 GHz. Thus
FIG. 2. Illustration of the nutation of the macrospin s0in the
presence of damping ( α/negationslash=0). We have used nonzero damping for
later reference.01234 56 7-0.8-0.6-0.4-0.200.20.40.60.8
0 0.5 11.5 20.7050.710.715
mxmy
mz
mz(0)(1+ Δm)
t (ps)ΔmReduced magnetic moment
FIG. 3. Time evolution of the net magnetic moment compared
with that of the magnetization deficit. The exchange parametersare homogeneous ( J=J
cs=Js=1); both surface and core spins
have a uniaxial anisotropy along the zaxis with surface anisotropy
ks=0.1 and core anisotropy kc=0.01.
fcis a consequence of the first correction stemming from
(relatively weak) surface effects.
In the case of larger values of ksand thereby stronger
spin noncollinearities, it is no longer possible to map themany-spin particle onto an effective particle. One then has tofully deal with the spin fluctuations. As a consequence it is nolonger an easy matter to derive an equation of motion similarto Eq. ( 11) in the general case. Nevertheless, in Ref. [ 29]
two relatively simpler configurations of anisotropy were stud-ied, namely a uniform uniaxial anisotropy (with the sameconstant and orientation) or a random anisotropy (with thesame constant and random orientation). It was then possibleto derive a system of (coupled) equations for m(t) andψ
i(t)
containing higher-order terms in ψi(t); see Eqs. (21) and
(26) in Ref. [ 29]. In the present situation with a nonuniform
anisotropy configuration, these higher-order contributions areresponsible for the nutation movement with frequency f
n,
as they lead to a net magnetization deficit; see Eq. ( 10) and
Fig. 3where the plot of /Delta1mshows such a movement. More
precisely, these fluctuations of the atomic spins lead to a pre-cession of the latter around their local effective field h
eff,ithat
evolves in time due to exchange interaction. Unfortunately, inthis complex situation it is a rather difficult task to derive anexplicit expression for h
eff,iand thereby an analog of Eq. ( 11).
However, we may consider a simpler model of a nanomagnetwith a uniaxial anisotropy having the easy axis along e
zfor all
sites, but with a constant that is different in the core from thaton the surface, i.e., e
i/bardblez,kc/negationslash=ks. Therefore, instead of the
model in Eq. ( 3) we consider the following one:
Han,i=/braceleftbigg
−kc(si·ez)2,i ∈core,
−ks(si·ez)2,i∈surface .(12)
This configuration is quite plausible especially in elon-
gated nanomagnets such as nanorods [ 43] and nanowires [ 44]
where the magnetostatic energy is strong enough to induce
165444-4MAGNETIZATION NUTATION INDUCED BY SURFACE … PHYSICAL REVIEW B 98, 165444 (2018)
an effective uniaxial anisotropy along the major axis of the
nanomagnet.
Then, it is possible to derive a system of equations for
mandψi(to second order in ψi). The equation for ψiis
cumbersome and thus omitted here as it is not necessary tothe discussion that follows. That of mreads
dm
dτ/similarequalm×2
N/summationdisplay
iki/parenleftbig
mz+ψz,i−mzψ2
i/parenrightbig
ez
+m×2
N/summationdisplay
iki⎡
⎣1
N/summationdisplay
j/parenleftBigg
mzψ2
j
2/parenrightBigg⎤
⎦ez
−m×2
N/summationdisplay
iki[(mz)2+mzψz,i]ψi. (13)
First, setting ψi=0above we obtain dm/dτ=m×
1
N/summationtext
i(2ki)mzez=m×2keffmzez, which describes the pre-
cession of maround the effective field heffwith
heff=2keffmzez,k eff=Nckc+Nsks
N. (14)
This clearly shows that nutation disappears in the absence
of the spin fluctuations ψi. Furthermore, projection on the z
axis of Eq. ( 13) yields the relation dmz/dτ/similarequalmzd(/Delta1m)/dτ,
where/Delta1mis the magnetization deficit defined in Eqs. ( 9) and
(10). Upon integrating over time we obtain (to lowest order in
ψi)
mz(τ)/similarequalmz(0)[1+/Delta1m(τ)]. (15)
This expression shows that mz(τ) and/Delta1m(τ)h a v et h es a m e
frequency, as confirmed by the green dots in the inset of Fig. 3.
Therefore, this simplified model emphasizes the appear-
ance of two relevant frequencies: the low-frequency of theordinary precession and the higher frequency of nutationrelated with spin fluctuations at the atomic level driven by theexchange coupling. These two frequencies clearly show up inFig. 1(blue wiggles in m
z). Furthermore, in Eq. ( 13)w ea l s o
see that the spin fluctuations ψiare directly coupled to the
anisotropy parameters ki, and this implies that the nutation’s
magnitude is not only related to the ratio of surface-to-corespin number, but also to the value of the anisotropy constants.Note, however, that the connection between Eq. ( 13) and
Eq. ( 11) is not a direct one, and one has to eliminate the fast
variables ψ
i, e.g., by integration or by making use of their
equations of motion in a perturbative way.
Finally, we have systematically varied the physical pa-
rameters ( Jij,ki) and studied the effect on nutation and
the frequencies fp,fc, and fn. First, we confirm that in
the absence of surface anisotropy (e.g., the same uniaxialanisotropy k
cfor all spins), no nutation has been observed.
This is a direct consequence of the fact that, in this specificcase, there is no magnetic inhomogeneity in the particle thatcan lead to a nonuniform effective field. Second, we findthat the precession frequency f
pmainly depends on kcsince
all spins are parallel to each other forming a macrospin thatprecesses in the effective uniform field. In general, this wouldalso include the shape anisotropy and the dc magnetic field.On the other hand, the frequency f
nstrongly depends on the
exchange coupling as can be seen in Table I.TABLE I. Precession and nutation frequencies for fixed values of
the exchange couplings J=Jcs=Js=1 (top) and for fixed values
of core and surface anisotropies kc=0.005 and ks=0.01 (bottom).
Precession frequency Nutation frequencykc ksfp(GHz) fn(THz)
0.001 0.001 3.2 0
0.001 0.01 19 ≈1
0.001 0.05 86 ≈1
0.001 0.1 170 ≈1
0.005 0.01 25 ≈1
0.005 0.05 93 ≈1
0.005 0.1 180 ≈1
0.01 0.1 185 ≈1
Precession frequency Nutation frequencyJcs Jsfp(GHz) fn(THz)
2 2 25 1.5
1 2 25 1.25
11 2 5 1
1 0.5 25 0.75
1 0.1 25 0.25
0.5 0.5 25 0.7
We have checked that the observed magnetic nutation
features also occur in cube-shaped particles of different size(20×20×20 or 30 ×30×30). We have obtained qualita-
tively the same oscillating behavior. A more detailed system-atic and quantitative analysis of this data is being carried outand will be published later as it is beyond the scope of thepresent paper.
We have also performed these calculations for a spherical
nanomagnet which has a different distribution of coordinationnumbers than in a cube. The results are qualitatively the samebut the nutation frequency f
nis higher.
B. Comparison with the macroscopic approach
to magnetization nutation
As discussed in the Introduction, magnetization nutation
has been studied by many authors within the macroscopicapproach based on Eq. ( 1) augmented by an inertial term pro-
portional to the second time derivative of the (macroscopic)magnetic moment m:
dm
dτ=m×/bracketleftbigg
heff−αm×heff−β
τsd2m
dτ2/bracketrightbigg
, (16)
where the coefficient βis often taken proportional to the
damping parameter αand to a phenomenological relaxation
timeτ1related with, e.g., the dynamics of the angular mo-
mentum, which is on the order of a femtosecond. In Ref. [ 14],
it was shown that the inertial damping results from high-ordercontributions to the spin-orbit coupling effect and is relatedto the Gilbert damping through the magnetic susceptibilitytensor. In the sequel, we shall use the notation ˜β≡β/τ
sand
this macroscopic model, with the equation of motion ( 16)
and phenomenological parameter ˜β, will be referred to as the
inertial one-spin problem (IOSP).
Solving the equation above, in the presence of dc and
ac magnetic fields, i.e., heff=hdc+hac,O l i v e et al. [21]
observed two resonance peaks, the first of which corresponds
165444-5R. BASTARDIS, F. VERNAY , AND H. KACHKACHI PHYSICAL REVIEW B 98, 165444 (2018)
to the ordinary large-amplitude precession at frequency fp
and a second resonance peak, at a much higher frequency
fnwith smaller amplitude, that was attributed to the nutation
dynamics. A number of other authors made similar observa-tions by also investigating the IOSP model [ 16,20,24,27]. In
Ref. [ 21] it was suggested that ω
nutation =2πfn=1/β.
Let us summarize the situation. On one hand, we have
the EOSP model (applicable when surface effects are nottoo strong) in which the dynamics of the net magneticmoment is described by the equation of motion ( 11). The
solution to the latter only exhibits two resonance peaks withfrequencies f
pandfc. On the other hand, we have the IOSP
model where the equation of motion is given by ( 16) (with the
phenomenological parameter ˜β) whose solution only provides
the two resonance peaks with frequencies fpandfn.N o w ,t h e
MSP approach, when treated in its full generality, provides uswith a self-consistent scheme in which all three frequenciesappear in a natural manner. In particular, it shows hownutation with the high-frequency f
nsets in, in the presence of
surface effects which induce noncollinear spin configurationsand generate high-frequency and small-amplitude spin-waveexcitations. See, for example, a thorough study of spin-waveexcitations in a nanocube in Ref. [ 45]. However, within the
MSP approach, the derivation of the equation of motionfor the net magnetic moment m(and the spin-wave vectors
ψ
i) is too cumbersome, if not intractable. This issue will
be investigated in the future. Nevertheless, in the case of aspherical nanomagnet, a Helmholtz equation was derivedfor the vectors ψ
iin Ref. [ 41], see Eq. ( 8) therein, which is
nothing other than the propagation equation for the spin wavesdescribed by ψ
i. Now, using the expansion si/similarequalm+ψi,w e
may infer that the exchange contribution J/Delta1siis proportional
to the second time derivative of mand, as such, the coefficient
β∝1/Jand thereby ωnutation ∝J. The exact relation will be
investigated in a future work.
Nevertheless, there is a specific situation in which we
can establish a clear connection between the MSP approachand the IOSP model. This is the case of weak surfaceeffects or, equivalently, a quasicollinear spin configuration.
Indeed, under this condition, we may combine the EOSPand IOSP models and write an equation of motion whosesolution renders all three frequencies, f
p,fc, andfn.M o r e
precisely, we start from Eq. ( 11) with the effective field
heff=2k2mzez−4k4(m3
zez+m3
yey+m3
xex) and add a term
similar to that in Eq. ( 16) with coefficient ˜β, leading to the
following equation of motion:
dm
dτ=m×/bracketleftbig
2k2mzez−4k4/parenleftbig
m3
zez+m3
yey+m3
xex/parenrightbig/bracketrightbig
−˜βm×d2m
dτ2, (17)
where again we have k2=kcNc/Nand for a cube
k4=(1−0.7/N1/3)4k2
s/zJ, and ˜β=β/τs. Henceforth,
this model will be referred to as the inertial effective one-spin
problem (IEOSP).
Compared with Eq. ( 16), the field heffhas been replaced
in Eq. ( 17) by the effective field produced by the combined
uniaxial and cubic anisotropies, induced by relatively weaksurface effects. Of course, we could also include an externalmagnetic field and a demagnetizing field in the EOSP equa-tion. The advantage of the IEOSP model is twofold: (i) itrenders the three resonance peaks at the frequencies f
p,fc,
andfnand (ii) it allows us to establish a clear connection
between the phenomenological parameter ˜βand the atomistic
physical parameters of the MSP approach, such as the surfaceanisotropy constant k
s.
For solving Eq. ( 17) one needs to set the initial velocity
form. For Néel’s anisotropy, the system exhibits several
different velocities, depending on the spin position in thestructure (edge, corner, face, or core). In this case, one wouldhave to set up a global constraint by imposing an initialvelocity for the net magnetic moment ( 6). In practice, we
have found it sufficient to use the average velocity ˙m(t=0)=/summationtext
i˙si(t=0)/N. The solution of Eq. ( 17) is plotted (in dots)
in Fig. 4(left).
01 0 2 0 3 0 4 0 50 60 70-0.6-0.4-0.200.20.40.601 0 2 0 3 0 4 0 50 60 700.70.710.720.73
sxsymx
mxsxmz
t(ps)Reduced magnetic moment
0 5 10 15 20 25 30 35 40 45 50 55-0.8-0.400.40.80 5 10 15 20 25 30 35 40 45 50 550.70710.707120.707140.7071600 . 5 1 1.5 2
t (ps)mxmymzMSP
MSP
MSPIOSP
IOSP
IOSPReduced magnetic moment
FIG. 4. Time evolution of the components of the macroscopic magnetic moment m(dots) and the net magnetic moment (lines) for MSP. On
the left, for Néel surface anisotropy, the MSP results are compared to the IEOSP model ( 17) and on the right, for uniaxial anisotropy, they are
compared to the IOSP model ( 16). The inset shows a magnification of the mz(t) component with a typical period ∼0.9p s(ωnutation /similarequal7T H z ) .
165444-6MAGNETIZATION NUTATION INDUCED BY SURFACE … PHYSICAL REVIEW B 98, 165444 (2018)
In Fig. 4we show the results from the MSP, IOSP, and
IEOSP models. The parameters for the MSP calculations aret h es a m ea si nF i g . 1, i.e.,k
c=0.001,ks=0.01. On the left,
we compare the MSP approach to the IEOSP model Eq. ( 17)
withk2=0.00475 ,k4=0.0011,˜β=2.25. On the right, the
MSP approach is compared to the IOSP model ( 16) with
the effective field given in Eq. ( 14) and parameters keff=
0.00576 ,˜β=2.2. Note that instead of using the expression
forkeffin Eq. ( 14) one might perform a fitting to the MSP
curves. Doing so, we find a slight discrepancy in keff(here
0.00585) as well as in the initial velocities ˙mα(t=0),α=
x,y,z . This is most likely due to the fact that the velocity
average does not exactly account for the spin noncollinear-ities. All in all, the results from the MSP approach are invery good agreement with those rendered by the macroscopicmodel, either IOSP or IEOSP, upon using the correspondingeffective field for the given anisotropy configuration in MSP,namely ( 12)o r( 3), respectively. In Fig. 4(left), the MSP
approach with the anisotropy model ( 3) is in good agreement
with the IEOSP model with a given parameter ˜β. Both models
exhibit the three frequencies f
p,fc, andfn. Regarding the
nutation with frequency fn, there is a slight discrepancy in
amplitude between the two models. As mentioned above,this is attributed to the average over the initial velocities.In Fig. 4(right) we see that, for MSP with the anisotropy
model ( 12), the IOSP model ( 16) with the effective field ( 14)
recovers the two resonance peaks with f
pandfn.W ed r a w
the attention of the reader to the difference in time scale andamplitude for the zcomponent. Indeed, the oscillations of the
zcomponent on the right are to be identified with the wiggles
of the same component on the left panel. In Ref. [ 21]t h e
authors argued that ω
nutation =1/β. Here, from Fig. 4(right)
we extract β/similarequal1.43×10−13s, which should be compared to
˜βτs/similarequal1.5×10−13s, showing a good agreement.
Finally, the major difference between the results on the left
and right panels is related with the frequency fc. This implies
that the model with uniaxial anisotropy, same easy axis butdifferent constants in the core and the surface, cannot accountfor this frequency. This confirms the fact that the latter isrelated with the inhomogeneity of the on-site anisotropy easydirection and thereby with the cubic effective anisotropy as a
first correction to surface effects.
In general, the relation between ˜βand the frequency f
n,
within the MSP approach, is difficult to derive analyticallysince ˜βdepends on the atomic parameters. Nevertheless, we
have tried to establish a quantitative correspondence betweenthe phenomenological parameter ˜βand the microscopic pa-
rameters such as k
s,kcor the effective parameters k2,k4that
appear in Eq. ( 11). Accordingly, in Fig. 5we plot 1 /˜βas the
result of the best fit between the MSP and IEOSP models. Onthe right panel of Fig. 5, this is done for the uniform uniaxial
anisotropy model ( 12) and on the left panel for the anisotropy
model in Eq. ( 3). These results show that 1 /˜βis nearly linear
ink
sand that the value of the phenomenological parameter
˜βinvolved in the IEOSP model can be estimated for a given
value of the surface anisotropy constant ks, which is an input
parameter of the MSP approach.
Finally, we have investigated the effect of damping with
parameter α[see Eq. ( 4)] within the MSP approach. The
results are shown in Fig. 6for the magnetization deficit.
Together with the 3D picture in Fig. 2, this indicates how the
spin fluctuations and thereby /Delta1mdecays in time towards zero.
This result is obviously in agreement with those of Fig. 1(b) inRef. [ 21]. We would like to emphasize, though, that the IOSP
approach in its actual formulation cannot account for the mag-netization nutation in the absence of damping because thecoefficient βappearing in Eq. ( 16) before the inertial term
d
2m/dt2is proportional to damping and thus vanishes when
the latter does. This is one of the major discrepancies withthe MSP approach since the latter does produce magnetizationnutation even in the absence of such a damping ( α=0). How-
ever, within the MSP approach the surface-induced nutationis due to local spin fluctuations and is thus affected by thespin-spin correlations or multimagnon processes which causedamping effects and relaxation of the magnetization deficit.But in the absence of a coupling of the spin subsystem tothe lattice, referred to in Ref. [ 46] as the direction relaxation,
these damping effects are not dealt with in this work and thisis why when we set α=0 the time evolution of m
αor/Delta1mis
undamped, but does exhibit nutation.
0.005 0.01 0.015 0.02 0.025 0.03 0.035 0.04 0.045 0.0500.050.10.150.20.250.30.005 0.01 0.015 0.02 0.025 0.03 0.035 0.04 0.045 0.050.45750.460.46250.465
k4
k2
ksks1
β~
0.005 0.025 0.05 0.075 0.1 0.125 0.15 0.175 0.20.2750.30.3250.350.3750.40.4250.450.475
0.005 0.025 0.05 0.075 0.1 0.125 0.15 0.175 0.200.0250.050.0750.10.1250.15β1
keff
ksks~
FIG. 5. Left: k4/k2and 1/˜βagainst ks. Right: keffand 1/˜βagainst ks.
165444-7R. BASTARDIS, F. VERNAY , AND H. KACHKACHI PHYSICAL REVIEW B 98, 165444 (2018)
0 1 02 03 04 0 50 60 7000.00050.0010.0015Δm
t (ps)
FIG. 6. Time evolution of the magnetization deficit, showing the
damping effect. Same parameters as in Fig. 1with a damping value
ofα=0.01.
III. CONCLUSION AND PERSPECTIVES
We have proposed an atomistic approach for studying the
effects of surface anisotropy and investigating nutation inthe magnetization dynamics in ferromagnetic nanoparticles.We have then shown that because of these effects, whichinduce spin noncolinearities leading to nonuniform local ef-fective fields, the magnetization dynamics exhibits severalresonance peaks. In addition to the ordinary precessionalmotion with frequency f
p∼10 GHz, we have shown that
the dynamics of the net magnetic moment exhibits two moreresonance peaks with frequencies f
candfn, which are higher
than the FMR frequency. Indeed, fc=4×fp∼40 GHz is
related with the oscillations of the particle’s magnetic momentbetween the minima of the effective potential induced byweak surface anisotropy. On the other hand, the much higherfrequency f
n∼1 THz is attributed to the magnetization fluc-
tuations at the atomic level driven by exchange couplingwhich becomes relevant in the presence of strong nonuniformspin configurations.
We have compared our results on nutation induced by sur-
face effects with those rendered by the macroscopic approachbased on the Landau-Lifshitz-Gilbert equation augmented byan inertial term (proportional to the second-order time deriva-tive of the macroscopic moment) with a phenomenologicalcoefficient. The good agreement between the two modelsmakes it possible to estimate this coefficient in terms of theatomistic parameters such as the surface anisotropy constant.In brief, the atomistic approach provides an origin for themagnetization nutations and a global and a self-consistentpicture that renders all three frequencies.In the case of not-too-strong surface effects, an effective
model renders two frequencies f
pandfc. On the other hand,
the Landau-Lifshitz-Gilbert equation with an inertial termonly renders the frequencies f
pandfn. Now, in the case of
arbitrary surface effects, it is a rather difficult task to derive aneffective equation of motion for the magnetization dynamics.As such, we have proposed an intermediate model that startsfrom the effective model established for weak surface effectsand added magnetization inertia through the term proportionalto the second-order time derivative of the magnetization.Then, we have shown that this macroscopic model is in verygood agreement with the atomistic approach and renders allresonance peaks and their frequencies. This establishes a clearquantitative connection between the phenomenological pa-rameters of the macroscopic approach to the atomistic energyparameters.
Our final word is devoted to the possibility of experimen-
tal observation of nutation in magnetization dynamics. Firstof all, establishing the fact that surface effects do inducemagnetization nutation may provide us with an additionalmeans for observing the latter. Indeed, surface effects onferromagnetic resonance in nanoparticles have been studiedfor a few decades now. For example, the authors of Ref. [ 26]
reported on high-frequency FMR (115–345 GHz) spectra forultrafine cobalt particles and inferred rather small values of thetransverse relaxation time τ
⊥, which suggests that this should
be due to an inhomogeneous precession caused by (relativelyweak) surface spin disorder. There are several other pub-lications on FMR measurements on magnetic nanoparticles[47–52]. However, these measurements can only capture the
two frequencies f
pandfc. Nevertheless, the observation of
the frequency fc, which is on the order of tens of GHz, should
be an easy matter using a network analyzer with variablefrequency covering this range. Doing so would clearly provethe existence of the first nutation motion induced by spindisorder as a consequence of surface anisotropy. A variantof the FMR spectroscopy, called magnetic resonance forcemicroscopy [ 53–55], yields a highly sensitive local probe
of the magnetization dynamics and consists in mechanicallydetecting the change in the longitudinal fluctuations of themagnetization, i.e., /Delta1m
z. This would be particularly suited
for detecting the fluctuations in mzseen in Figs. 1and4, if not
for the mismatch in the frequency range. Now, the frequencyf
nis rather in the optical range and we wonder whether the
corresponding oscillations could be detected by coupling themagnetization of the nanoparticle to a plasmonic nanoparticleof gold or silver, thus making use of the magnetoplasmoniccoupling evidenced in many hybrid nanostructures [ 56–58].
Graphene plasmons is another promising route for detectionof THz radiation [ 59].
ACKNOWLEDGMENT
We would like to acknowledge useful discussions with
J.-E. Wegrowe on his early work on magnetization nutation.
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165444-9 |
PhysRevB.97.134405.pdf | PHYSICAL REVIEW B 97, 134405 (2018)
Magnetism of a Co monolayer on Pt(111) capped by overlayers of 5 delements: A spin-model study
E. Simon,1,*L. Rózsa,2K. Palotás,3,4and L. Szunyogh1,5
1Department of Theoretical Physics, Budapest University of Technology and Economics, Budafoki út 8, H-1111 Budapest, Hungary
2Department of Physics, University of Hamburg, D-20355 Hamburg, Germany
3Department of Complex Physical Systems, Institute of Physics, Slovak Academy of Sciences, SK-84511 Bratislava, Slovakia
4MTA-SZTE Reaction Kinetics and Surface Chemistry Research Group, University of Szeged, H-6720 Szeged, Hungary
5MTA-BME Condensed Matter Research Group, Budapest University of Technology and Economics,
Budafoki út 8, H-1111 Budapest, Hungary
(Received 21 January 2018; published 9 April 2018)
Using first-principles calculations, we study the magnetic properties of a Co monolayer on a Pt(111) surface
with a capping monolayer of selected 5 delements (Re, Os, Ir, Pt, and Au). First we determine the tensorial
exchange interactions and magnetic anisotropies characterizing the Co monolayer for all considered systems.We find a close relationship between the magnetic moment of the Co atoms and the nearest-neighbor isotropicexchange interaction, which is attributed to the electronic hybridization between the Co and the capping layers,in the spirit of the Stoner picture of ferromagnetism. The Dzyaloshinskii-Moriya interaction is decreased forall overlayers compared to the uncapped Co/Pt(111) system, while even the sign of the Dzyaloshinskii-Moriyainteraction changes in the case of the Ir overlayer. We conclude that the variation of the Dzyaloshinskii-Moriyainteraction is well correlated with the change of the magnetic anisotropy energy and of the orbital momentanisotropy. The unique influence of the Ir overlayer on the Dzyaloshinskii-Moriya interaction is traced by scalingthe strength of the spin-orbit coupling of the Ir atoms in Ir/Co/Pt(111) and by changing the Ir concentrationin the Au
1−xIrx/Co/Pt(111) system. Our spin dynamics simulations indicate that the magnetic ground state of
Re/Co/Pt(111) thin film is a spin spiral with a tilted normal vector, while the other systems are ferromagnetic.
DOI: 10.1103/PhysRevB.97.134405
I. INTRODUCTION
Owing to promising technological applications, chiral mag-
netic structures have become the focus of current experimentaland theoretical research activities [ 1,2]. Chiral magnetism is
essentially related to the breaking of space-inversion symme-try, since in this case spin-orbit coupling (SOC) leads to theappearance of the Dzyaloshinskii-Moriya interaction (DMI)[3,4] that lifts the energy degeneracy between noncollinear
magnetic states rotating in opposite directions. Noncollinearchiral magnetic structures stabilized by the DMI, such as spinspirals and magnetic skyrmion lattices, have been explored incrystals with bulk inversion asymmetry such as MnSi [ 5–7].
Magnetic thin films and multilayers with broken interfacialinversion symmetry represent another class of systems inwhich chiral magnetic structures can emerge. In these systems,magnetic transition-metal thin films are placed on heavy metal(e.g., Pt, Ir, W) substrates supplying strong spin-orbit inter-action. For instance, spin spiral ground states were reportedfor Mn monolayers on W(110) [ 8,9] and on W(001) [ 10],
spin spirals and skyrmions were detected in the Pd/Fe/Ir(111)bilayer system [ 11–13], while in the case of an Fe monolayer on
Ir(111) the formation of a spontaneous magnetic nanoskyrmionlattice has been observed [ 14]. Competing ferromagnetic (FM)
and antiferromagnetic (AFM) isotropic exchange couplingsare also capable of stabilizing noncollinear spin structures
*esimon@phy.bme.huin magnetic thin films and nanoislands [ 15–18], while the
chirality of these structures is still determined by the DMI.
Understanding and controlling the sign and strength of
the DMI at metallic interfaces is one of the key tasks inexploring and designing chiral magnetic nanostructures. A
large number of experiments has been devoted to the study
of the influence of different nonmagnetic elements on theDMI at magnetic/nonmagnetic metal interfaces [ 19–21], also
supported by first-principles calculations [ 22]. Recently, it was
shown that at 3 d/5dinterfaces the trend for the DMI follows
Hund’s first rule as the number of valence electrons in themagnetic layer is varied [ 23], while for a Co/Pt bilayer it was
studied how the DMI depends on the number of occupied states
close to the Fermi energy by resolving the DMI in reciprocalspace [ 24]. It was also demonstrated that the magnetic ground
state of an Fe monolayer on 5 dmetal surfaces is strongly
influenced by the electronic properties of the substrate [ 25,26].
Because of the interplay between large spin-orbit coupling andhigh spin polarizability, particular attention has been paid to
the influence of the heavy metal Ir on the DMI. This includes
the formation of noncollinear spin structures in ultrathinmagnetic films on Ir substrates [ 12–14] and the insertion of
Ir into multilayer structures [ 27–30]. It was demonstrated
that the insertion of Ir leads to a sign change of the DMI in
the Pt/Co/Ir/Pt system [ 20,31], and it was suggested that the
Ir/Co/Pt stacking order in magnetic multilayers can lead to an
enhancement of the DMI [ 22,27].
Motivated by previous experimental and theoretical inves-
tigations, in the present paper we explore the role of selected
2469-9950/2018/97(13)/134405(11) 134405-1 ©2018 American Physical SocietySIMON, RÓZSA, PALOTÁS, AND SZUNYOGH PHYSICAL REVIEW B 97, 134405 (2018)
monatomic 5 d(Re, Os, Ir, Pt, Au) overlayers in influencing
the magnetic properties of a Co monolayer deposited onPt(111). We focus on the investigation of how the electronichybridization with heavy metal capping layers possessingdifferent numbers of valence electrons and different strengthsof the spin-orbit interaction influences the magnetic propertiesof the Co layer.
In Sec. II, the parameters of an extended classical Heisen-
berg model are discussed, where the coupling between the spinsis described by tensorial exchange interactions using first-principles electronic structure calculations. It is also explainedhow these interactions can be converted to effective or micro-magnetic parameters. In Sec. III A, the modifications of the Co
magnetic moments and of the nearest-neighbor (NN) isotropicexchange coupling between the Co atoms are found to correlatewith the change of the electronic states in the Co and the 5 d
overlayers. In Sec. III B, the correlations between the DMI, the
magnetic anisotropy energy (MAE), and the orbital momentanisotropy are highlighted. In the case of the Ir/Co/Pt(111)system, we find that the DMI in the Co monolayer changes signcompared to Co/Pt(111) and the systems with the other cappinglayers, and we scale the spin-orbit coupling of the Ir layer in
order to get a more profound insight into this phenomenon.
This investigation is supplemented by investigating the DMIand the MAE in Au
1−xIrx/Co/Pt(111) thin films with an alloy
overlayer. Finally, in Sec. III C we determine the magnetic
ground state of the Co monolayer on the Pt(111) substrate withdifferent capping layers using spin dynamics simulations. Theresults are summarized in Sec. IV.
II. COMPUTATIONAL METHODS
A. Details of ab initio calculations
We performed self-consistent electronic structure calcula-
tions for X/Co/Pt(111) ( X=Re, Os, Ir, Pt, Au) ultrathin films
in terms of the relativistic screened Korringa-Kohn-Rostoker(SKKR) method [ 32,33]. For the case of chemically disordered
overlayers, we employed the single-site coherent-potentialapproximation (CPA). We used the local spin-density approx-imation as parametrized by V osko et al. [34] and the atomic
sphere approximation with an angular momentum cutoff of/lscript
max=2. The energy integrals were performed by sampling
16 points on a semicircle contour in the upper complexenergy semiplane. The layered system treated self-consistentlyconsisted of nine Pt atomic layers, one Co monolayer, one X
monolayer, and four layers of vacuum (empty spheres) betweenthe semi-infinite Pt substrate and semi-infinite vacuum. Formodeling the geometry of the thin films we used the value
a
2D=2.774˚A for the in-plane lattice constant of the Pt(111)
surface and fcc growth was assumed for both the Co andthe different overlayers. The distances between the atomiclayers were optimized in terms of
V ASP calculations [ 35–37].
Relative to the interlayer distance in bulk Pt, we found aninward relaxation between 5 and 10% for the Co monolayerand between 8 and 15% for the different overlayers.
In order to study the magnetic structure in the Co layer we
use the generalized classical Heisenberg model
H=−1
2/summationdisplay
i,j/vectorsiJij/vectorsj+/summationdisplay
i/vectorsiK/vectorsi, (1)where /vectorsidenotes the spin vector of unit length at site i,Jijis the
exchange coupling tensor [ 38], and Kis the on-site anisotropy
matrix. The tensorial exchange coupling can be decomposedinto an isotropic, an antisymmetric, and a traceless symmetriccomponent [ 31]:
J
ij=JijI+1
2/parenleftbig
Jij−JT
ij/parenrightbig
+/bracketleftbig1
2/parenleftbig
Jij+JT
ij/parenrightbig
−JijI/bracketrightbig
. (2)
The isotropic part Jij=1
3TrJijrepresents the Heisenberg
couplings between the magnetic moments. The antisymmetricpart of the exchange tensor can be identified with the DMvector:
/vectors
i1
2/parenleftbig
Jij−JT
ij/parenrightbig
/vectorsj=/vectorDij(/vectorsi×/vectorsj). (3)
From the diagonal elements of the traceless symmetric
part of the exchange tensor the two-site anisotropy may becalculated.
The second term of Eq. ( 1) comprises the on-site anisotropy
with the anisotropy matrix K. Note that for the case of C
3v
symmetry the studied systems exhibit, the on-site anisotropy
matrix can be described by a single parameter, /vectorsiK/vectorsi=K(sz
i)2.
The effective MAE of the system can be obtained as a sum ofthe two-site and on-site anisotropy contributions as will bediscussed in Sec. II C. Note that the sign convention for J
ij,
/vectorDij, andKis opposite to Ref. [ 31], from which we include the
values for the Co/Pt(111) system without a capping layer forcomparison with the present results.
The exchange coupling tensors were determined in terms
of the relativistic torque method [ 38,39], based on calculating
the energy costs due to infinitesimal rotations of the spins atselected sites with respect to the ferromagnetic state orientedalong different crystallographic directions. For these orienta-tions we considered the out-of-plane ( z) direction and three
different in-plane nearest-neighbor directions, being sufficientto produce interaction matrices that respect the C
3vsymmetry
of the system. The interaction tensors were determined for allpairs of atoms up to a maximal distance of 5 a
2D, for a total of
90 neighbors including symmetrically equivalent ones.
B. Determining the ground state of the system
To find the magnetic ground state of the Co monolayer, we
calculated the energies of flat harmonic spin spiral configura-tions:
/vectors
i=/vectore1cos/vectork/vectorRi+/vectore2sin/vectork/vectorRi, (4)
where /vectorkdenotes the spin spiral wave vector, /vectore1and/vectore2are
unit vectors perpendicular to each other, and /vectorRiis the lattice
position of spin /vectorsi. Substituting Eq. ( 4) into Eq. ( 1) yields
1
NESS(/vectork,/vectorn)=−1
2/summationdisplay
/vectorRij1
2/parenleftbig
TrJij−/vectornJsymm
ij/vectorn/parenrightbig
cos/vectork/vectorRij
−1
2/summationdisplay
/vectorRij/vectorDij/vectornsin/vectork/vectorRij+1
2(TrK−/vectornK/vectorn),(5)
with/vectorn=/vectore1×/vectore2the normal vector of the spiral, /vectorRij=/vectorRj−
/vectorRi, and Jsymm
ij=1
2(Jij+JT
ij). The ground state configuration
was approximated by optimizing Eq. ( 5) with respect to /vectorkand
134405-2MAGNETISM OF A Co MONOLAYER ON Pt(111) CAPPED … PHYSICAL REVIEW B 97, 134405 (2018)
/vectorn, and comparing it to the energy of the ferromagnetic state:
1
NEFM(/vectoreFM)=−1
2/summationdisplay
/vectorRij/vectoreFMJij/vectoreFM+/vectoreFMK/vectoreFM, (6)
which was minimized with respect to the ferromagnetic direc-
tion/vectoreFM.
Due to the magnetic anisotropy, actual spin spiral config-
urations become distorted compared to the harmonic shapedefined in Eq. ( 4). In order to take this effect into account,
we further relaxed the configurations obtained above usingzero-temperature spin dynamics simulations by numericallysolving the Landau-Lifshitz-Gilbert equation [ 40,41]:
∂/vectors
i
∂t=−γ
1+α2/vectorsi×/vectorBeff
i−αγ
1+α2/vectorsi×/parenleftbig
/vectorsi×/vectorBeff
i/parenrightbig
,(7)
where αis the Gilbert damping parameter and γ=2μB/¯h
is the gyromagnetic ratio. The effective field /vectorBeff
iis obtained
from the generalized Hamiltonian Eq. ( 1)a s
/vectorBeff
i=−1
m∂H
∂/vectorsi=1
m/summationdisplay
j(/negationslash=i)Jij/vectorsj−2
mK/vectorsi. (8)
The spin magnetic moment of the Co atom mwas determined
from the electronic structure calculations. We used a two-dimensional lattice of 128 ×128 sites populated by classical
spins with periodic boundary conditions and considered the fulltensorial exchange interactions and the on-site anisotropy termwhen calculating the effective field. In all considered cases wefound that the harmonic model provided a good approximationfor the wave vector and normal vector of the spin spiral orcorrectly determined the ferromagnetic ground state. We alsoperformed simulations initialized in random initial configura-tions to investigate whether noncoplanar configurations canemerge in the systems, but found no indication for such abehavior in the absence of external magnetic field.
C. Effective interaction parameters
In order to allow for a comparison between different ab
initio calculation methods and experimental results, here we
discuss how one can transform between the atomic interactionparameters calculated for many different neighbors used inthis paper, and effective nearest-neighbor interactions andparameters in the micromagnetic model.
Complex magnetic textures are often studied in terms of
micromagnetic models, where it is assumed that the magneti-zation direction is varying on a length scale much larger thanthe lattice constant, and the spins may be characterized by thecontinuous vector field /vectors(/vectorr), the length of which is normalized
to 1. In order to describe chiral magnetism, for a magneticmonolayer with C
3vpoint-group symmetry, the energy density
is usually expressed as
e(/vectors)=J/summationdisplay
α=x,y,z(/vector∇sα)2+DwD(/vectors)−K(sz)2, (9)
with the linear Lifshitz invariant:
wD(/vectors)=sz∂xsx−sx∂xsz+sz∂ysy−sy∂ysz. (10)
The relationship between the micromagnetic parameters
J,D, and Kand the atomic parameters in Eq. ( 1) may beobtained by calculating the energy of the same type of spin
configurations. Here we will consider spin spiral states withwave vectors along the ydirection:
/vectors(/vectorr)=/vectore
zcosky+/vectoreysinky, (11)
where the plane of the spiral is spanned by the wave-vector
direction /vectoreyand the out-of-plane direction /vectorez, corresponding to
cycloidal spin spirals. In the micromagnetic model, the averageenergy over the spin spiral reads
E
micromagnetic =JVak2+DVak−1
2KVa, (12)
if it is calculated for the atomic volume Va. For the atomic
model one obtains [cf. Eq. ( 5)]
Eatomic=−1
2/summationdisplay
/vectorRij1
2/parenleftbig
Jyy
ij+Jzz
ij/parenrightbig
coskRy
ij
+1
2/summationdisplay
/vectorRijDx
ijsinkRy
ij+1
2K. (13)
Expanding Eq. ( 13) up to second-order terms in kyields
Eatomic≈Jeffk2+Deffk+1
2Keff (14)
apart from a constant shift in energy, with the effective spin-
model parameters defined as
Jeff=1
4/summationdisplay
jJij/parenleftbig
Ry
ij/parenrightbig2, (15)
Deff=/summationdisplay
jDx
ijRy
ij, (16)
Keff=K+1
2/summationdisplay
/vectorRij/parenleftbig
Jyy
ij−Jzz
ij/parenrightbig
. (17)
The effective parameters JeffandDeffare also known
as spin stiffness and spiralization, respectively [ 42,43]. The
relationship between the micromagnetic and the effectiveparameters is given by
J=1
VaJeff,D=1
VaDeff,K=−1
VaKeff. (18)
Note that it is possible to define the atomic volume as
Va=√
3
2a2
2Dtwhere√
3
2a2
2Dis the area of the in-plane unit
cell and tis the film thickness. In Ref. [ 22]t h ev a l u eo f
t=nlayer√2
3a2Dwas used with nlayerthe number of magnetic
atomic layers, corresponding to the ideal interlayer distancein an fcc lattice along the (111) direction. However, thisapproximation becomes problematic when lattice relaxationsare taken into account at the surface, since in this descriptionthe positions of the centers of the atoms are defined instead ofthe thickness of the layers. Therefore, we used the expressionV
a=4π
3R3
WS, where RWSis the radius of the atomic spheres
used in the SKKR calculations, with RWS≈1.49˚Af o rt h e
considered X/Co/Pt(111) systems.
The cycloidal spin spiral defined in Eq. ( 11) is called clock-
wise or right-handed for k>0, meaning that when looking
at the system from the side with the out-of-plane directiontowards the top the spins are rotating clockwise when movingto the right along the modulation direction of the spiral [ 44]. For
134405-3SIMON, RÓZSA, PALOTÁS, AND SZUNYOGH PHYSICAL REVIEW B 97, 134405 (2018)
k<0, the spin spiral is called counterclockwise or left-handed.
According to Eq. ( 12), the micromagnetic DMI creates an
energy difference between the two rotational senses, withD>0 preferring a counterclockwise rotation. Equation ( 16)
demonstrates that the micromagnetic parameter is connected tothexcomponent of the atomic DM vector for spin spirals with
wave vectors along the ydirection, or the in-plane component
D
/bardbl
ijof the vector for general propagation directions. Note that
the magnitude of D/bardbl
ijis the same for all neighbors that can
be transformed into each other via the C3vsymmetry of the
system, while the sign can be defined based on whether thevectors prefer clockwise or counterclockwise rotation of thespins. Note that in the case of C
3vsymmetry /vectorDijalso has
a nonvanishing zcomponent, the effect of which on domain
walls was investigated in Ref. [ 31].
Finally, we also define nearest-neighbor atomic interaction
parameters JandD, which reproduce the effective parameters
in Eqs. ( 15) and ( 16):
Jeff=3
4a2
2DJ, D eff=3
2a2DD, (19)
where Dis the in-plane component of the nearest-neighbor
DM vector with the sign convention discussed above.
Instead of performing the direct summations in Eqs. ( 15)
and ( 16), we fitted the spin spiral dispersion relation in Eq. ( 13)
calculated from all interaction parameters in Eq. ( 1) with an
effective nearest-neighbor model containing J,D, andKeff.
The fitting was performed in a range that is sufficiently largeto avoid numerical problems, but sufficiently small that themicromagnetic approximations may still be considered valid,corresponding to |k|a
2D/2π/lessorequalslant0.1. We note that this procedure
is similar to how the atomic interaction parameters are deter-mined from spin spiral dispersion relations directly obtainedfrom total-energy calculations (see, e.g., Refs. [ 8,12,45]), but
we used the spin model containing interaction parametersbetween many neighbors to determine the dispersion relationin the first place. We confirmed with spin dynamics simula-tions that in ferromagnetic systems the domain-wall profilescalculated with the full model Hamiltonian ( 1) agree well
with the profiles that can be calculated analytically from amicromagnetic model with the interaction parameters obtainedusing the above procedure. Nevertheless, we found that not allsystems can be sufficiently described by the three parametersused in the micromagnetic model, and this discrepancy canbe attributed to the competition between ferromagnetic andantiferromagnetic isotropic Heisenberg interactions (see Sec.III C for details).
In order to support the comparison of our calculated param-
eters with corresponding values obtained from experimentsor other theoretical approaches we shall present the micro-magnetic, effective, and nearest-neighbor atomic parameters asdefined above for all considered systems. As an example, in Ta-bleIwe present the comparison between DMI values obtained
for the Co monolayer on Pt(111) without a capping layer usingdifferent ab initio calculation methods in Refs. [ 12,22,31,43],
similarly to the summary given in Ref. [ 47]. Using the above
definitions, we find reasonable agreement between the differenttheoretical descriptions, and all parameters fall into the rangewhere a ferromagnetic ground state is expected based on theexperimental investigations in Ref. [ 47].TABLE I. Nearest-neighbor atomic ( D), effective ( Deff), and mi-
cromagnetic ( D) DM coupling obtained in several earlier publications
for the Co monolayer on Pt(111). Positive values indicate that the
counterclockwise (left-handed) chirality is preferred in the system.For a consistent transformation between the different parameters we
used the values a
2D=2.774˚Aa n d RWS=1.44˚A. For Ref. [ 12]w e
took into account the different definition of the atomic interactionparameters compared to Eq. ( 1). For Ref. [ 22] we considered the DMI
value for the Co(3)/Pt(3) structure and the correction in Ref. [ 46].
D(meV) Deff(meV ˚A) D(mJ/m2)
Ref. [ 31] 2.86 11.90 15.11
Ref. [ 43] 2.72 11.30 14.35
Ref. [ 12] 3.60 14.98 19.02
Ref. [ 22] 3.12 12.98 16.48
III. RESULTS
A. Isotropic exchange interactions
Figure 1shows the calculated isotropic exchange constants
Jijbetween the Co atoms as a function of interatomic distance
for the different capping layers (CL) and for the uncapped sys-tem (no CL). According to Eq. ( 1), positive and negative signs
of the isotropic exchange parameters refer to FM and AFMcouplings, respectively. For all overlayers the ferromagneticNN interaction is dominating: it is the largest in magnitude forthe Au overlayer, for Pt and Ir a small decrease can be seen,while for Os and Re overlayers it is dramatically reduced. Thesecond- and third-nearest-neighbor couplings are considerablysmaller in magnitude than the NN couplings and the trendfor the different overlayers is also less systematic; e.g., in thecase of Au, Pt, and Os overlayers the second-NN couplingis ferromagnetic, while for Ir and Re it is AFM. Overall, themagnitude of the isotropic interactions decays rapidly with thedistance, becoming negligible beyond the third-NN shell.
In Table II, the NN exchange couplings ( J
1) and the spin
magnetic moments of Co atoms ( mCo) are summarized for the
different overlayers.
FIG. 1. Calculated Co-Co isotropic exchange parameters Jijas a
function of the interatomic distance and different overlayers, and forthe Co/Pt(111) system without the capping layer (no CL) [ 31].
134405-4MAGNETISM OF A Co MONOLAYER ON Pt(111) CAPPED … PHYSICAL REVIEW B 97, 134405 (2018)
TABLE II. Calculated nearest-neighbor exchange interactions J1
between the Co atoms and the spin magnetic moment of Co mCofor
all considered capping layers and for the Co/Pt(111) system without
the capping layer (no CL) [ 31].
J1(meV) mCo(μB)
Re 5.03 1.04
Os 9.66 1.55Ir 31.73 2.11
Pt 31.55 2.17
Au 37.54 2.10No CL 42.46 2.10
We find that capping by 5 doverlayers systematically
reduces J1compared to the uncapped case, which can be at-
tributed to the hybridization between the Co and the overlayer.The magnetic moment of Co is almost constant for the Au, Pt,and Ir overlayers, while it shows an apparent decrease for Osand Re, similarly to the NN isotropic exchange. This decreaseis, however, much less drastic than for J
1:mCoin the case of
the Re overlayer is about half of mCoin the case of the Au
layer, while this ratio is about 1 /7f o rJ1.
According to the Stoner model of ferromagnetism, the
density of states (DOS) of the delectrons of Co at the
Fermi level, n(/epsilon1F), in the nonmagnetic phase plays the crucial
role in stabilizing spontaneous magnetization: in the case ofIn(/epsilon1
F)>1 (with Ibeing the Stoner parameter) the system
becomes ferromagnetic. Hence the observed trends in mCoand
J1are governed by the filling of the 5 dband of the overlayer
that influences the 3 dband of Co via hybridization. In order
to trace this effect, in Fig. 2we plot the density of states of
thedelectrons in the Co layer and in the overlayer in the
nonmagnetic phase, meaning that the exchange-correlation
magnetic field was set to zero during the density functional
theory calculations. Since all the dstates of Au are occupied,
the corresponding 5 dband lies well below the Fermi level,
024Re
024Os
024Ir
024Pt
−6 −4 −2 0 2
/epsilon1−/epsilon1F(eV)024AuDOS (states/eV)
FIG. 2. DOS of delectrons in the Co layer (solid red line) and
in the overlayer (dashed blue line) in nonmagnetic X/Co/Pt(111)
(X=Re, Os, Ir, Pt, Au) systems.TABLE III. Nearest-neighbor atomic ( J), effective ( Jeff), and
micromagnetic ( J) parameters of Co for the isotropic exchange
interaction of X/Co/Pt(111) ( X=Re, Os, Ir, Pt, Au) and Co/Pt(111)
thin films (no CL) [ 31] obtained from the calculated spin-model
parameters by the fitting procedure in Sec. II C.
J(meV) Jeff(meV ˚A2) J(pJ/m)
Re 0.82 4.73 0.56
Os 22.58 130.32 15.48
Ir 6.94 40.05 4.71
Pt 41.89 241.76 27.99Au 49.23 284.12 31.98
No CL 54.40 313.96 39.86
leaving the Co 3 dband localized around the Fermi level, with
a large n(/epsilon1F) that explains the strong magnetic moment of Co
in this case. Although the 5 dband of Pt is shifted upwards due
to the decrease of the band filling and the hybridization withthe Co dband increases, the large peak in the Co DOS at the
Fermi level still pertains, keeping m
Coat a high value. This
trend remains also in the case of the Ir overlayer, where the3d-5dhybridization further increases and n(/epsilon1
F) of Co clearly
decreases, but the magnetic moment of Co is of similar valueas for the Au overlayer. For the cases of Os and Re overlayersthe Co 3 dband gets rather delocalized due to hybridization
with the wider 5 dbands and n(/epsilon1
F) is further reduced leading
to the observed drop in mCo. Note that a similar dependence
of the Co moments on the overlayer was obtained for othersystems [ 48–51].
From the calculated isotropic exchange interactions we
obtained the spin stiffness constant ( J
eff), the corresponding
micromagnetic parameter ( J), and the NN atomic value ( J)
for all considered overlayers as described in Sec. II C, and
presented them in Table III. Apparently, these values follow
the variation of mCoorJ1for Os, Pt, and Au capping layers;
however, in the case of Ir and Re they are considerably reduced.The reason for this behavior is the amplification of the role ofexchange interactions between farther atoms in J
effas follows
from Eq. ( 15). From Fig. 1one can see that in the case of
the Ir overlayer both the second- and third-NN couplings arenegative (AFM), which drastically reduces the value of J
eff.
The decrease of the NN coupling is apparently insufficientin itself to explain the very small value of J
effin the case
of the Re overlayer. However, a detailed investigation ofFig.1shows that the seventh-NN interaction, J
7=−0.39 meV ,
gives a dominating negative contribution to Jeffdue to the
large distance ( d=3.606a2D) and the large number (12) of
neighbors in this shell.
B. Relativistic spin-model parameters
1. Different capping layers
Next, we investigate the in-plane components of
Dzyaloshinskii-Moriya interactions between the Co atomswhich are shown in Fig. 3for all capping layers as a function
of the distance between the Co atoms, compared to the valuesin the absence of a capping layer [ 31]. The sign changes of the
DMI indicate switchings in the preferred rotational sense from
134405-5SIMON, RÓZSA, PALOTÁS, AND SZUNYOGH PHYSICAL REVIEW B 97, 134405 (2018)
4 6 8 10 12 14−1.5−1.0−0.50.00.51.01.52.0D/bardbl
ij(meV)
clockwisecounterclockwiseRe
Os
Ir
Pt
Au
no CL
FIG. 3. In-plane component of the DM vectors D/bardbl
ijas a function
of the distance between the Co atoms for different overlayers, and for
the Co/Pt(111) system without the capping layer (no CL) [ 31].
shell to shell, analogously to the oscillation between ferro-
magnetic and antiferromagnetic isotropic exchange interactioncoefficients. Except for the case of the Au capping layer, the NNDMI is the largest in magnitude; however, the DM vectors formore distant pairs also play an important role. This is somewhatdifferent for the isotropic couplings, J
ij,i nF i g . 1, where the NN
interaction is much larger in magnitude than the interactionsfor farther shells; therefore, the slow decay with the Co-Codistance is less visible than for the DMI in Fig. 3.
To illustrate the overall effect of the overlayers on the DMI,
we calculated the NN atomic, effective, and micromagneticDMI coefficients of Co from the ab initio spin-model parame-
ters as discussed in Sec. II C. These values are summarized
in Table IVfor different capping layers. For comparison,
we also included the corresponding values for Co/Pt(111).It is worthwhile to mention that the effective parameters inTable IVfollow exactly the same order for the different capping
layers as the in-plane NN DM vectors in Fig. 3, unlike in
the case of the isotropic exchange interactions. Regardless ofthe choice of the capping layer, the DMI is shifted towardsthe direction of clockwise rotational sense compared to theuncapped system. For the Pt/Co/Pt(111) system, the DMI isexceptionally weak, which is to be expected since inversionsymmetry is almost restored in this system if we consider that
TABLE IV . Nearest-neighbor atomic ( D), effective ( Deff), and
micromagnetic ( D) DM coupling of Co obtained from the spin-model
parameters for X/Co/Pt(111) thin films ( X=Re, Os, Ir, Pt, Au) and
for Co/Pt(111) without any capping layer (no CL).
D(meV) Deff(meV ˚A) D(mJ/m2)
Re 1.82 7.57 8.94
Os 2.58 10.74 12.75
Ir −1.75 −7.28 −8.56
Pt 0.20 0.83 0.96Au 1.50 6.24 7.02
No CL 2.86 11.90 15.11−0.15−0.10−0.05-Δmorb(μB)
Co/Pt(111)
05Keff(meV) in-plane
out-of-plane
Re Os Ir Pt Au010Deff(meV ·)
counterclockwise
clockwise
FIG. 4. Calculated values of orbital moment anisotropy in the
Co layer with negative sign −/Delta1m orb,M A E Keff, and effective
DMIDeffforX/Co/Pt(111) thin films ( X=Re, Os, Ir, Pt, Au).
The corresponding parameters for Co/Pt(111) are also illustrated bydashed green lines.
generally the interfacial DMI is dominated by the magnetic and
nonmagnetic heavy metal layers directly next to each other.
We would also like to point out that the Ir capping layer is the
only one that switches the sign of the DMI preferring clockwiserotation. This is somewhat unexpected since the Ir layer alsochanged the preferred rotational sense to clockwise when itwas introduced between the Co monolayer and the Pt(111)substrate [ 31], so it should prefer a counterclockwise rotation
for the opposite stacking order according to the three-sitemodel of the DMI [ 52]. A possible reason for this effect is that
the reduced coordination number of the Ir atoms in the cappinglayer as well as the electrostatic potential barrier at the surfacesignificantly modify the electronic structure of the cappinglayer compared to the bulk case or when the Ir is inserted belowthe Co layer. This sign change of the DMI in Ir/Co/Pt(111)indicates that ultrathin-film systems can display qualitativelydifferent features compared to magnetic multilayers, where theIr/Co/Pt stacking was suggested as a way of enhancing the DMI[27]. The different behavior of Ir as a capping layer and as an
inserted layer was recently investigated in Ref. [ 53].
In order to study the dependence of the DMI on the
capping layer, we calculated additional quantities determinedby the strength of the spin-orbit coupling, namely, the totalMAE K
effand the anisotropy of the orbital moment of Co
atoms, /Delta1m orb=m⊥
orb−m/bardbl
orb, where the superscripts ⊥and
/bardblrefer to calculations performed for a normal-to-plane and
an in-plane orientation of the magnetization in the Co layer,respectively. Figure 4shows /Delta1m
orbwith a negative sign (top
panel), Keff(middle panel), and Deff(bottom panel) for the Co
monolayer depending on capping layer. Note that negative andpositive signs of K
effrefer to easy-axis and easy-plane types
of magnetic anisotropy, respectively.
For 3dtransition metals, where the spin-orbit coupling is
small compared to the bandwidth, second-order perturbationtheory describes the uniaxial magnetic anisotropy well [ 54].
According to Bruno’s theory, neglecting spin-flop coupling andfor a filled spin-majority dband, a negative proportionality
between the MAE and /Delta1m
orbapplies, that was confirmed
134405-6MAGNETISM OF A Co MONOLAYER ON Pt(111) CAPPED … PHYSICAL REVIEW B 97, 134405 (2018)
4 6 8 10 12 14
d−1012D/bardbl
ij(meV)counterclockwise
clockwiseλ=0.0
λ=0.2
λ=0.4
λ=0.6
λ=0.8
λ=1.0
FIG. 5. In-plane DMI as a function of the distance between the
Co atoms for various values of the SOC scaling parameter λin the Ir
capping layer of the Ir/Co/Pt(111) system.
theoretically and experimentally for Co layers [ 54–58]. From
Fig. 4a good qualitative correlation can be inferred between
Keffand−/Delta1m orbwith the exception of the Re overlayer.
Indeed, due to the large 3 d-5dhybridization, the delocalization
of the spin-majority band of Co is increased in the case of theRe overlayer such that the above-mentioned conditions for thesimple proportionality do not apply.
From Fig. 4it turns out that the variations of K
effand
Deffalso correlate well with each other. This is somewhat
surprising since, as mentioned above, the MAE is of secondorder in the SOC, while the DM term appears in the firstorder of the perturbative expansion [ 4]. Compared to the
Co/Pt(111) system, the Os capping layer does not modify theDMI significantly, but we observe a strong easy-plane MAE.The Re and the Au capping layers decrease the magnitudeofD
eff, and the preferred magnetization direction is also in
plane. An out-of-plane magnetization was obtained for Ir andPt capping layers, and as discussed above the Ir cappinglayer prefers a clockwise rotation, while in the case of thePt overlayer the DMI is close to zero.
2. Scaling of the spin-orbit coupling in the Ir overlayer
To gain further insight into the the sign change of the DMI
in the Co monolayer with the Ir capping layer, we artificiallymanipulated the strength of SOC at the Ir atoms. Ebert et al.
introduced a continuous scaling of the SOC via the parameter λ
within the relativistic KKR formalism [ 59]: calculation without
scaling ( λ=1) corresponds to the fully relativistic case, while
λ=0 can be identified with the so-called scalar-relativistic
description. Importantly, in the above formalism the scaling ofthe SOC can be used selectively for arbitrary atomic cells. Wethus applied it to the Ir monolayer, while the SOC at all othersites of the system remained unaffected.
Figure 5shows D
/bardbl
ijas a function of the distance between
the Co atoms for different scaling parameters. Varying λ
has a strong influence on the NN in-plane DMI: it changescontinuously from preferring counterclockwise ( λ=0) to
preferring clockwise ( λ=1) rotational direction, while the−3−2−10Keff(meV)
0.0 0.2 0.4 0.6 0.8 1.0
λ−505Deff(meV ·)
FIG. 6. Calculated MAE Keff, and effective DMI Deffas a
function of the SOC scaling parameter λin the Ir overlayer of the
Ir/Co/Pt(111) system.
changes in the other shells are smaller in relative and in absolute
terms. In the case of λ=0, the NN in-plane DMI takes a value
of 2.32 meV , which means that the NN DMI of the Co/Pt(111)system (1.98 meV) [ 31] is nearly restored in this case.
In accordance with the results of first-order perturbation
theory, Fig. 6illustrates that the variation of the effective DMI
is rather linear with λ.F o rλ=0,K
effis close to the value
of the uncapped Co/Pt(111) system ( −0.20 meV [ 31]) and it
increases in magnitude to −3m e Vf o r λ=1. Following the
change in the NN in-plane DMI interaction in Fig. 5, the sign
of the effective DMI turns from preferring counterclockwiseto preferring clockwise rotation when increasing the strengthof the SOC in the Ir overlayer. On the other hand, at λ=0D
eff
is somewhat smaller in magnitude than in the case of the
uncapped Co/Pt(111) (11 .90 meV ˚A). This indicates that the
Ir overlayer influences the DMI of the system not just due toits strong SOC but also by modifying the electronic states inthe Co monolayer via hybridization.
3. Changing the capping layer composition in
Au1−xIrx/Co/Pt(111)
Controlling the Ir concentration xin the alloy capping
layer Au 1−xIrx(0/lessorequalslantx/lessorequalslant1) represents a transition where the
effect of increasing hybridization between the 3 dband of
Co and the 5 dband of the capping metal can be traced, as
shown in Fig. 2. On the other hand, the strength of the SOC,
defined by the operator ξ/vectorL/vectorS, in Au and Ir is roughly the
same ( ξ≈600 meV), meaning that the alloying is expected
to have a different effect than the scaling of the SOC discussedin the previous section. Thus, we performed calculations ofthe spin-model parameters for x=0.1,0.2,..., 0.9b yu s i n g
the CPA for the chemically disordered overlayer. The layerrelaxation was varied as a function of xaccording to Vegard’s
law using the calculated layer relaxation of the Au/Co/Pt(111)and Ir/Co/Pt(111) systems.
The in-plane components of the DM vectors in the Co
monolayer from the first to the fourth shell are shown in Fig. 7
as a function of the Ir concentration. When increasing the Ir
134405-7SIMON, RÓZSA, PALOTÁS, AND SZUNYOGH PHYSICAL REVIEW B 97, 134405 (2018)
0.0 0.2 0.4 0.6 0.8 1.0
x(Ir concentration)−1.0−0.50.00.5D/bardbl
ij(meV)counterclockwise
clockwise
D1
D2
D3
D4
FIG. 7. In-plane components of the DM vectors D/bardbl
ijof Co from
the first ( D1) to the fourth shell ( D4), as a function of the Ir
concentration ( x)i nt h eA u 1−xIrx/Co/Pt(111) system.
concentration, the sign of the first-NN and the second-NN
D/bardbl
ijchanges from positive to negative. The third-NN in-plane
DM for the Au/Co/Pt(111) system is negative, it turns positivearound x≈0.1, and it has approximately the same magnitude
around 20% Ir concentration as for the pure Ir/Co/Pt(111)layer, with a maximal amplitude at about x=0.5. The sign
of the fourth-NN D
/bardbl
ijis not changed by the alloying, and the
magnitude remains nearly constant.
The changes of the effective DMI and MAE are shown
in Fig. 8as a function of the Ir concentration. Unlike the
case where the SOC was scaled (Fig. 6), the variation of
KeffandDeffwithxis nonmonotonous, with a maximum of
Keffat around 10% and a minimum of Deffat around 90% Ir
concentration.
The effect of alloying the nonmagnetic heavy metals on
the DMI was also investigated recently in Ref. [ 60], where
4-ML Ir xPt1−x/1-ML Co /4-ML Pt and 4-ML Pt xAu1−x/1-
FIG. 8. Calculated total MAE Keffand effective DMI Deffin
the Co monolayer as a function of Ir concentration ( x)i nt h e
Au1−xIrx/Co/Pt(111) system.TABLE V . Obtained magnetic ground states for X/Co/Pt(111) thin
films ( X=Re, Os, Ir, Pt, Au).
KJ/D2Ground state
Re −0.20 Tilted SS
Os −6.77 In-plane FM
Ir 2.27 Out-of-plane FM
Pt 436.13 Out-of-plane FMAu −1.46 In-plane FM
ML Co /4-ML Pt trilayers were considered along the (111)
stacking direction. Similarly to the results presented here,a nonmonotonous dependence on the concentration was re-ported, together with a switching to negative DMI due to thepresence of Ir in the capping layer, although only at smallerIr concentration. In Ref. [ 60], for pure Au or pure Ir capping
layers similar values of the DMI were obtained to the uncappedvalues summarized in Table I. As discussed above, in the
present calculations the decrease of the DMI due to the Auoverlayer and the sign change due to the Ir overlayer canprobably be attributed to the reduced coordination numberof the atoms if the capping layer is only 1 ML thick. As apossible alternative for obtaining a microscopic understanding,an interesting perturbative model for the DMI in zig-zag chainscan be found in Ref. [ 61], where the dependence of the sign
and strength of the DMI on different parameters is reported.
C. Magnetic ground states
The ground states of the systems were determined by com-
bining harmonic spin spiral calculations with spin dynamicssimulations as described in Sec. II C. After scaling out the
energy and length scales, the micromagnetic energy density inEq. ( 9) can be described by a single dimensionless parameter
KJ/D
2, which governs the formation of the magnetic ground
state. As already discussed in earlier publications [ 44,62,63],
noncollinear ground states are expected to be formed for −1<
KJ/D2<π2
16≈0.62 in this model; the upper limit denotes
where magnetic domain walls become energetically favorablein out-of-plane oriented ferromagnets, while the lower limitindicates the instability of the in-plane oriented ferromagneticstate towards the formation of an elliptic conical state.
The calculated values are summarized in Table Vfor these
systems. For most considered capping layers the parameterKJ/D
2is outside the range where the formation of non-
collinear states is expected, and in the simulations we indeedobserved FM ground states. This can be explained eitherby the strong easy-plane (Os) or easy-axis (Ir) anisotropies,the weakness of the DMI for the Pt/Co/Pt(111) system, orthe combination of the above for the Au capping layer. Forthe Re/Co/Pt(111) system, the micromagnetic model predicts[62,63] a cycloidal spin spiral ground state with the normal
vector in the plane, just as it was assumed in Eq. ( 11). However,
by minimizing Eq. ( 4) with respect to the wave vector /vectorkand
the normal vector /vectorn, we obtained a tilted spin spiral state of the
form
/vectors
i=/vectorexcoskRy
isin/Phi10−/vectoreysinkRy
i+/vectorezcoskRy
icos/Phi10.
(20)
134405-8MAGNETISM OF A Co MONOLAYER ON Pt(111) CAPPED … PHYSICAL REVIEW B 97, 134405 (2018)
xy
z
xz
yΦ0=3 8◦allJij(a)
xy
z
xz
yΦ0=0◦NNJ(b)
xy
z
xz
yΦ0=5 8◦NNNJ1,J2(c)
FIG. 9. The tilted spin spiral ground state found in the
Re/Co/Pt(111) system in spin dynamics simulations. The tilting angle
/Phi10is defined in Eq. ( 20). (a) Ground state obtained using the full Jij
exchange interaction tensors. (b) Ground state obtained with only
nearest-neighbor (NN) atomic interaction parameters, J=0.82 meV
from Table III, NN DMI, and effective on-site anisotropy. (c)
Ground state obtained by performing the fitting procedure discussedin Sec. II C for NN and next-nearest-neighbor (NNN) exchange
interactions, J
1=53.46 meV and J2=−18.20 meV, NN DMI, and
effective on-site anisotropy. Red and blue colors correspond topositive and negative out-of-plane spin components, respectively.
The ground state obtained from the spin dynamics simu-
lations is displayed in Fig. 9(a). Although the spiral became
slightly distorted due to the anisotropy, we found that it couldstill be relatively well described by Eq. ( 20) using a wavelength
ofλ=2π/k≈3.5 nm and a tilting angle of /Phi1
0≈38◦.T h eenergy gain due to the tilting is approximately 0 .04 meV /atom.
Note that the tilted spin spiral state is still a cycloidal spiral inthe sense that the wave vector is located in the rotational planeof the spirals, but the normal vector is no longer confined tothe surface plane. This is different from the case of weak DMIin out-of-plane magnetized films, where the normal vector ofdomain walls gradually rotates in the surface plane from Néel-type to Bloch-type rotation due to the presence of the magne-tostatic dipolar interaction (see, e.g., Ref. [ 64] ) .I ta l s od i f f e r s
from the elliptic conical spin spirals discussed in Refs. [ 62,63]
because the tilted spin spiral state has no net magnetization.
The formation of such a ground state can be explained by
the easy-plane anisotropy preferring an in-plane orientationof the spiral, the DMI preferring a spiral plane perpendicularto the surface, and the simultaneous presence of competingferromagnetic and antiferromagnetic isotropic exchange inter-actions in the system, the latter also leading to the reducedvalue of the effective J
effparameter for the Re capping layer
in Table II. This is illustrated in Figs. 9(b) and9(c):i nt h e
nearest-neighbor atomic model, a vertical cycloidal spin spiralground state is obtained, in agreement with the prediction of themicromagnetic description [ 62,63]. The spin spiral wavelength
is also significantly shorter, λ≈1.4 nm, due to the inaccuracy
of the nearest-neighbor fitting procedure. On the other hand, ifthe fitting is performed with taking nearest- and next-nearest-neighbor isotropic exchange interactions into account, thetilted spin spiral ground state is recovered with λ≈3.8n m
and/Phi1
0≈58◦, in reasonable agreement with the full model.
IV . SUMMARY AND CONCLUSIONS
In conclusion, we examined the X/Co/Pt(111) ( X=Re, Os,
Ir, Pt, Au) ultrathin films using first-principles and spin-modelcalculations. We determined the Co-Co magnetic exchangeinteraction tensors between different pairs of neighbors andthe magnetic anisotropies. From the results of the ab initio
calculations we also determined effective and micromagneticspin-model parameters for the Co layers. For the isotropicexchange couplings we found dominant ferromagnetic nearest-neighbor interactions for all systems, which decrease withthed-band filling of the capping layer. This effect due to
the hybridization between the 3 dstates of the Co layer
and the 5 dstates of the capping layer can be qualitatively
explained within a Stoner picture, which also accounts forthe similarly decreasing magnetic moment. Considering theeffective isotropic couplings of Co, we found significantlylower values for Re and Ir overlayers than what would beexpected simply based on the decrease of the nearest-neighborinteractions; this we attributed to competing antiferromagneticcouplings with further neighbors.
We also investigated the in-plane Dzyaloshinskii-Moriya
interactions of Co, and found it to be weaker for all capping
layers compared to the uncapped Co/Pt(111) system. For the Ircapping layer we found a switching from counterclockwise toclockwise rotation, which is unexpected since the same switch-
ing can also be observed if the Ir is inserted between the mag-
netic layer and the substrate [ 31]. We attributed this effect to the
reduced coordination number of Ir atoms and the electrostaticpotential barrier at the surface. We also found a correlation
between the effective Dzyaloshinskii-Moriya interactions D
eff,
134405-9SIMON, RÓZSA, PALOTÁS, AND SZUNYOGH PHYSICAL REVIEW B 97, 134405 (2018)
the effective magnetic anisotropies Keff, and the anisotropy of
the orbital moment /Delta1m orb. We further investigated the sign
change of the effective Dzyaloshinskii-Moriya interaction ofCo for the Ir capping layer by scaling the strength of thespin-orbit coupling at the Ir sites and by tuning the filling of the
5dband in a Au
1−xIrx/Co/Pt(111) system. We found a linear
dependence of the effective Dzyaloshinskii-Moriya interactionon the spin-orbit coupling strength in agreement with theperturbative description, and a nonmonotonic dependence on
the band filling.
Using the spin-model parameters we determined the mag-
netic ground state for all considered systems. For Os, Ir, Pt,and Au capping layers we found a ferromagnetic ground state,in agreement with the analytical prediction based on the calcu-lated micromagnetic parameters. For the Re/Co/Pt(111) sys-tem we found a tilted spin spiral ground state, the appearanceof which can only be explained if competing ferromagnetic andantiferromagnetic isotropic exchange interactions are takeninto account alongside the Dzyaloshinskii-Moriya interactionand the easy-plane anisotropy.Our results highlight the importance of ab initio calculations
and atomic spin-model simulations in cases where simplermodel descriptions might lead to incomplete conclusions. Thepresent paper may motivate further experimental investigationsin this direction, exploring the sign of the Dzyaloshinskii-Moriya interaction and the role of competing isotropic ex-change interactions in ultrathin-film systems.
ACKNOWLEDGMENTS
The authors would like to thank F. Kloodt-Twesten and M.
Mruczkiewicz for insightful discussions. The authors grate-fully acknowledge the financial support of the National Re-search, Development, and Innovation Office of Hungary underProjects No. K115575, No. PD120917, and No. FK124100,of the Alexander von Humboldt Foundation, of the DeutscheForschungsgemeinschaft via SFB668, of the SASPRO Fel-lowship of the Slovak Academy of Sciences (Project No.1239/02/01), and of the Hungarian State Eötvös Fellowship.
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134405-11 |
PhysRevB.101.134423.pdf | PHYSICAL REVIEW B 101, 134423 (2020)
Realization of Su-Schrieffer-Heeger states based on metamaterials of magnetic solitons
Gyungchoon Go,1,*Ik-Sun Hong,2Seo-Won Lee,1Se Kwon Kim ,3and Kyung-Jin Lee1,2
1Department of Materials Science and Engineering, Korea University, Seoul 02841, Korea
2KU-KIST Graduate School of Converging Science and Technology, Korea University, Seoul 02841, Korea
3Department of Physics and Astronomy, University of Missouri, Columbia, Missouri 65211, USA
(Received 10 October 2019; revised manuscript received 23 March 2020; accepted 1 April 2020;
published 21 April 2020)
We theoretically investigate coupled gyration modes of magnetic solitons whose distances to the nearest
neighbors are staggered. In a one-dimensional bipartite lattice, we analytically and numerically find that thereis a midgap gyration mode bounded at the domain wall connecting topologically distinct two phases which isanalogous to the Su-Schrieffer-Heeger model. As a technological application, we show that a one-dimensionaldomain-wall string in a two-dimensional soliton lattice can serve as a waveguide of magnetic excitations, whichoffers functionalities of a signal localization and selective propagation of the frequency modes. Our resultoffers an alternative way to control the magnetic excitation modes by using a magnetic metamaterial for futurespintronic devices.
DOI: 10.1103/PhysRevB.101.134423
I. INTRODUCTION
Topological properties embedded in band structures are
one of the central themes in modern condensed-matterphysics. In two-dimensional (2D) electron systems, represen-tative examples supporting topologically protected edge states[1] are the Haldane model [ 2] and the Kane-Mele model
[3], which exhibit the quantum Hall and quantum spin Hall
phases, respectively. A classical example in one-dimensional(1D) topological systems is the Su-Schrieffer-Heeger (SSH)model supporting a midgap bound state with fermion number1/2[4,5]. Inspired by the topological effects in electronic
systems, numerous studies have been devoted to investigatingtopological properties in bosonic systems such as magnons[6–8], phonons [ 9,10], and their hybridized states [ 11–14].
Such topological effects of band structures can also be
realized in artificially structured composites, called meta-materials, whose functionalities arise as the collective dy-namics of local resonators [ 15]. Analogs of topologically
protected edge states in 2D systems have been proposed andexperimentally observed in acoustic [ 15,16], optical [ 17–21],
magnetic [ 22–24], mechanical [ 25,26], and electric circuit
[27–29] systems. Moreover, the 1D SSH model has been
realized in optical waveguides [ 30], electric circuits [ 31,32],
and magnetic spheres [ 33]. An intriguing feature of the meta-
materials is that the band structures and their topologicalproperties can be manipulated by changing the crystal param-eters. This tunability of metamaterials is of crucial importancefor widespread applications of topological properties in, forinstance, reconfigurable logic devices [ 15,19].
Magnetic solitons such as magnetic vortices and skyrmions
are resonators whose dynamics exhibit gyroscopic mo-tion [ 34–36]. Theoretical [ 37–39] and experimental [ 40–42]
*gyungchoon@gmail.comresults on the dynamics of coupled gyration modes of the
magnetic solitons provide a potential application for a dif-ferent type of information device [ 39]. Moreover, internal
degrees of freedom of magnetic solitons such as polarity andchirality can offer efficient control of the functionalities ofsoliton-based metamaterials [ 43]. One of us has shown that
the collective excitation of the magnetic solitons supports achiral edge mode in a honeycomb lattice [ 23], which was
later confirmed by micromagnetic simulation [ 24]. Recently,
the topological corner states have been realized in breathingkagome [ 44] and honeycomb lattice [ 45]. However, the SSH
state in the 1D system has not been realized for collectivegyration modes of magnetic solitons.
In this paper, we first study a metamaterial composed of
the magnetic soliton disks structured in a one-dimensionalbipartite chain. By using both analytic calculation and micro-magnetic simulation, we show the existence of a midgap statebounded at a domain wall connecting topologically distincttwo configurations, which is analogous to the electronic SSHmodel. Then we derive a 2D extension of our 1D magneticSSH model, which is shown to be able to support a magneticwaveguide with selective propagation of frequency modes.
II. REALIZATION OF THE SSH MODEL WITH AN ARRAY
OF SOLITON DISKS
We consider a quasi-one-dimensional array of nanodisks
containing magnetic vortices or skyrmions. In general, thesteady-state motion of topological solitons can be describedby the dynamics of the center-of-mass position R(t) and
m=m[r−R(t)], where mis a unit vector along the direc-
tion of local magnetization. The dissipationless magnetizationdynamics of the coupled vortices /skyrmions is described by
Thiele’s equation [ 46]:
Gˆz×dU
j
dt+Fj=0, (1)
2469-9950/2020/101(13)/134423(7) 134423-1 ©2020 American Physical SocietyGO, HONG, LEE, KIM, AND LEE PHYSICAL REVIEW B 101, 134423 (2020)
where Uj=Rj−R0
jis the displacement of the soliton from
the equilibrium position R0
j,G=− 4πMstDQ/γis the gy-
rotropic coefficient, Msis the saturation magnetization, tD
is the thickness of the disk, and γis the gyromagnetic
ratio. Here, Q=1
4π/integraltext
dxdym·(∂xm×∂ym) is the topologi-
cal charge which characterizes the topological solitons. Thetopological charge of the magnetic vortices and skyrmionsareQ=± 1/2 and ±1, respectively. F
j=−∂W/∂Ujis the
conservative force from the potential energy
W=/summationdisplay
jK
2U2
j+/summationdisplay
j/negationslash=kUjk
2, (2)
where K>0 is the spring constant and Uj≡(uj,vj)i s
the displacement vector. Here, Ujkis the interaction energy
between two solitons:
Ujk(djk)=Ix(djk)ujuk−Iy(djk)vjvk, (3)
where djk(=|R0
j−R0
k|) is the distance between centers of
two neighboring disks, and Ix(djk) and Iy(djk) are interac-
tion parameters between two disks. This system of coupledmagnetic solitons has been studied both theoretically andexperimentally [ 37,38,41,42]. In particular, the values of the
parameters in Eqs. ( 2) and ( 3) have been experimentally mea-
sured and theoretically calculated for certain sizes of solitondisks.
Let us first consider the situation where the nearest-
neighbor disk pairs are separated by a uniform distance. Usingthe complex variable ψ
j≡uj+ivj, we write Eq. ( 1)i na
simplified form [ 23,24]:
i˙ψj=ωKψj+/summationdisplay
k∈/angbracketleftj/angbracketright(ζψk+ξψ∗
k), (4)
where ωK=K/Gis the gyration frequency of an isolated
soliton and ζ=(Ix−Iy)/Gandξ=(Ix+Iy)/Gare the
reparametrized interactions. In order to eliminate ψ∗
k,w e
expand the complex variable as
ψj=χjexp(−iω0t)+ηjexp(iω0t), (5)
where χj(ηj) is a counterclockwise (clockwise) gyration am-
plitude. Substituting Eq. ( 5) into Eq. ( 4) and applying |χj|/greatermuch
|ηj|(|χj|/lessmuch|ηj|) for counterclockwise (clockwise) soliton
gyrations, we have
i˙ψj=/parenleftbigg
ωK−ξ2
ωK/parenrightbigg
ψj+ζ/summationdisplay
k∈/angbracketleftj/angbracketrightψk−ξ2
2ωK/summationdisplay
l∈/angbracketleft/angbracketleftj/angbracketright/angbracketrightψl,(6)
where /angbracketleft/angbracketleftj/angbracketright/angbracketrightrepresents second-neighbor sites of j. The right-
hand side of Eq. ( 6) contains zeroth-order ( ωK), first-order ( ζ),
and second-order ( ξ2) terms of the interdisk interactions. For
1D chain systems, we have
i˙ψj=/parenleftbigg
ωK−ξ2
ωK/parenrightbigg
ψj+ζ(ψj+1+ψj−1)
−ξ2
2ωK(ψj+2+ψj−2). (7)
Taking the Fourier transformation, we obtain an eigenvalue
equation, i˙/Psi1(kx,t)=Hk/Psi1(kx,t) with a momentum space
FIG. 1. A schematic illustration of the staggered 1D chain of
magnetic nanodisks without the domain-wall defect (a), and witha pair of domain-wall and anti-domain-wall defects (b). A single
(double) bond represents the longer (shorter) interdisk distance. Band
structure of the system without the domain-wall defect (c), and with
a pair of domain-wall and anti-domain-wall defects (d). A pair of
states at ω=ω
Kis induced by the defects (red).
Hamiltonian
Hk=ωK+2ζcoskx−2ξ2
ωKcos2kx, (8)
describing a single-band Hamiltonian of magnetic excitations.
Now, let us consider a staggered 1D chain of magnetic
nanodisks [Fig. 1(a)] with periodic boundary condition which
mimics the SSH system [ 4]. Because of the staggered lattice
structure, the interdisk interactions ( ζandξ) are divided into
two different types:
ζ→/braceleftbigg
ζ(1+/Delta1)
ζ(1−/Delta1),ξ →/braceleftbigg
ξ(1+/Delta1/prime)
ξ(1−/Delta1/prime). (9)
Here,/Delta1and/Delta1/prime, which can be either positive or negative, rep-
resent the staggeredness of the SSH system. By substitutingEq. ( 9) into Eq. ( 6) and introducing sublattice indices Aand
B,w eh a v e
i˙ψ
A
2m=/parenleftBigg
ωK−ξ2(1+/Delta1/prime2)
ωK/parenrightBigg
ψA
2m
+ζ(1+/Delta1)ψB
2m+1+ζ(1−/Delta1)ψB
2m−1
−ξ2(1−/Delta1/prime2)
2ωK/parenleftbig
ψA
2m−2+ψA
2m+2/parenrightbig
, (10)
i˙ψB
2m+1=/parenleftBigg
ωK−ξ2(1+/Delta1/prime2)
ωK/parenrightBigg
ψB
2m+1
+ζ(1−/Delta1)ψA
2m+2+ζ(1+/Delta1)ψA
2m
−ξ2(1−/Delta1/prime2)
2ωK/parenleftbig
ψB
2m−1+ψB
2m+3/parenrightbig
. (11)
We note that ξ2/Delta1/prime2terms, which are induced from the stag-
geredness of ξ, appear in the identity matrix part of the
momentum space Hamiltonian. Because these terms cannot
134423-2REALIZATION OF SU-SCHRIEFFER-HEEGER STATES … PHYSICAL REVIEW B 101, 134423 (2020)
change the topology of the Hamiltonian and are negligible
in the small /Delta1/primelimit, we discard ξ2/Delta1/prime2terms in this paper.
Taking the Fourier transformation, we obtain
Hk=/parenleftBigg
ωK−2ξ2
ωKcos2kx 2ζ(coskx−i/Delta1sinkx)
2ζ(coskx+i/Delta1sinkx) ωK−2ξ2
ωKcos2kx/parenrightBigg
=/parenleftbigg
ωK−2ξ2
ωKcos2kx/parenrightbigg
I2×2+n(kx)·σ, (12)
where the basis of the Hamiltonian is /Psi1(kx)=
(ψA(kx),ψB(kx))Tandσ=(σx,σy) are the Pauli matrices.
The eigenvalues of Eq. ( 12)a r eg i v e nb y
ω±=ωK−2ξ2
ωKcos2kx±2ζ/radicalBig
cos2kx+/Delta12sin2kx.(13)
In Fig. 1(c), we show the dispersion relation of Eq. ( 13).
For calculation, we take the model parameters ωK/2π=
0.955 GHz, ζ/2π=− 0.04 GHz, ξ/2π=0.13 GHz, and
/Delta1=0.3 in accordance with micromagnetic simulation results
in next section. The staggeredness /Delta1induces a finite gap. We
note that the particle-hole symmetry is broken because of themomentum dependent diagonal component in Eq. ( 12)f r o m
the second-order interactions ( −
2ξ2
ωKcos2kxI2×2). The second-
order interaction term can be treated as a smooth perturbationof the Hamiltonian and does not change the topological char-acter of the system. The topological number of the Hamil-tonian ( 12) is the winding number of the two-component
unit vector ˆn(k
x)=n(kx)/|n(kx)|≡(cosθk,sinθk) which is
expressed by the integral [ 47–49]
N=1
2π/integraldisplay
BZdkx/parenleftbiggdθk
dkx/parenrightbigg
=sgn(/Delta1), (14)
where θk=tan−1(ny/nx)=tan−1(/Delta1tankx) is a polar angle of
the unit vector in momentum space. The winding number iscorresponding to the homotopy map π
1(S1)=Z. Equation
(14) implies that there are two topologically distinct phases
which are represented by the sign of /Delta1.
Expanding Eq. ( 12) around kx=π/2, which minimizes the
band gap, we obtain an effective Dirac Hamiltonian
Hk=/parenleftBigg
ωK −2ζ/bracketleftbig/parenleftbig
kx−π
2/parenrightbig
+i/Delta1/bracketrightbig
−2ζ/bracketleftbig/parenleftbig
kx−π
2/parenrightbig
−i/Delta1/bracketrightbig
ωK/parenrightBigg
.(15)
Diagonalizing Eq. ( 15), we obtain the eigenfrequencies with
a band gap /Delta1,
ω±=ωK±2ζ/radicalbigg/parenleftBig
kx−π
2/parenrightBig2
+/Delta12. (16)
Because a topological bound state exists at the interface
between the two topologically distinct phases, we considera situation where the staggeredness /Delta1is reversed its sign at
x=0:/Delta1(x)=/Delta1
0sgn(x). In this case, a midgap bound state
appears at ω=ωK, without changing the bulk dispersions of
upper and lower bands [see Fig. 1(d)]. From Eq. ( 15), we read
that the midgap bound state satisfies
/parenleftbigg
0 i∂x−i/Delta1(x)
i∂x+i/Delta1(x)0/parenrightbigg
/Psi1bound=0, (17)
FIG. 2. Band structures of the Dirac Hamiltonian (a) and lo-
calization of the bound state (b) for /Delta10=0.2 (dotted), /Delta10=0.3
(dashed), and /Delta10=0.5 (solid).
which results in
/Psi1bound (x)∼/parenleftbigg0
e−/Delta10|x|/parenrightbigg
(/Delta10>0),
/Psi1bound (x)∼/parenleftbigg
e/Delta10|x|
0/parenrightbigg
(/Delta10<0). (18)
Equation ( 18) shows that the bound state is exponentially
localized at the domain wall. This is a magnetic analogof the SSH system which possesses a soliton with half-electric charge [ 4]. Creation of the bound state is compensated
by one-half of a state missing from the two bulk bandscorresponding to ω=ω
±.I nF i g . 2, we show the band
structures of the effective Dirac Hamiltonian in Eq. ( 15)
and localization of the bound state for different valuesof/Delta1
0.
III. MICROMAGNETIC SIMULATION
We perform micromagnetic simulations to visualize the
collective dynamics of the magnetic vortex lattice. Here,we use following parameters of typical permalloy [ 37]: the
saturation magnetization M
s=800 erg /cm3, the exchange
stiffness A=1.3×10−6erg/cm. In order to obtain the
clear fast Fourier transform (FFT) image, we choose asmall Gilbert damping constant α=0.001. The diameter
and thickness of magnetic nanodisk are chosen to be 80and 20 nm, respectively. The unit-cell size is chosen to be4×4×20 nm
3.
We consider a 1D bipartite chain of 40 identical magnetic
nanodisks with a periodic boundary condition as shown inFig. 3(a). Each disk has a magnetic vortex with the same
polarity ( p=1) and chirality ( C=− 1) [see Fig. 3(b)]. We
simulate the collective dynamics of the vortex gyration inthe bipartite lattice with a domain wall (11th disk) and ananti-domain wall (31st disk) which are separated by 20 disks.To obtain the dispersion relation of collective vortex gyra-tion modes, we apply a sinc function of external magneticfield,
H(t)=H
0sin[2πf(t−t0)]/[2πf(t−t0)]ˆx, (19)
on one of the disks with H0=10 mT, f=20 GHz, and t0=
1n s .
Then, we obtain the dispersion relation from the fast
Fourier transform (FFT) of the temporal oscillations of x
component of the vortex core position. Figure 3(d) shows
the resonant spectrum of a vortex gyration mode in anisolated magnetic nanodisk. We find that the single vortex
134423-3GO, HONG, LEE, KIM, AND LEE PHYSICAL REVIEW B 101, 134423 (2020)
FIG. 3. (a) Illustration of the 1D bipartite lattice of magnetic nanodisk with a domain wall (11th disk) and an antidomain wall (31st disk)
profile. (b) A magnetic nanodisk containing a single vortex. (c) V ortex core dynamics in an isolated magnetic nanodisk. (d) Resonant spectrum
of single vortex gyration in an isolated magnetic nanodisk. Dispersion relation of collective vortex gyration in the bipartite lattice when theexternal field is far away from the domain-wall position (21st disk) with interdisk distance [ d
1,d2] of (e) [16 nm, 24 nm], (f) [12 nm, 28 nm],
(g) [8 nm, 32 nm], and (h) [4 nm, 36 nm], and when the external field is on the domain-wall position (11th disk) with interdisk distance of (i)
[16 nm, 24 nm], (j) [12 nm, 28 nm], (k) [8 nm, 32 nm], and (l) [4 nm, 36 nm].
gyration mode has a peak at f0=ωK/2π=0.955 GHz.
Figures 3(e)–3(h) show the dispersion relation of the bipartite
chain when the external field is located far away from thedomain-wall position (21st disk). As the difference of inter-disk distance ( d=d
2−d1) increases, a more distinct band
splitting (into upper and lower bands) is observed. Note thatthe in-gap mode between the upper and lower bands has notbeen excited in this case, because it is localized on the defectposition and thus far away from the external-field position.When the external field locates on the domain-wall position(11th disk), we find that a midgap mode is excited near f
0
without significant change of the bulk dispersion [Figs. 3(i)–
3(l)]. The simulation results coincide with the analytic results
in Sec. IIwith appropriate model parameters [see Figs. 1(c)
and1(d)].IV . 2D MAGNETIC WA VEGUIDE
Now let us consider a 2D extension of our 1D magnetic
SSH model, which will be shown to support a magneticwaveguide of excitations below. The schematic illustration ofthe 2D lattice is shown in Fig. 4(a). The 2D extended model
includes additional interactions proportional to ζ
y,ξ2
y/2ωK,
andξ2
xy(1±¯/Delta1)/2ωK[see Fig. 4(b)]. We note that ¯/Delta1represents
the staggeredness of the second-order interactions, and itssign is reversed at the defect position. In momentum spacerepresentation, we have an effective Hamiltonian (see theAppendix)
H
2D(kx,ky)=/parenleftbigg
HAAHAB
(HAB)∗HBB/parenrightbigg
, (20)
134423-4REALIZATION OF SU-SCHRIEFFER-HEEGER STATES … PHYSICAL REVIEW B 101, 134423 (2020)
FIG. 4. (a) A schematic illustration a two-dimensional extension
of the 1D magnetic SSH model. (b) Additional interactions of the
2D tight-binding model. Bulk and bound-state dispersions of the 2Dmodel without the domain-wall defect (c) and with the domain-wall
defect (d). For calculation, we take the model parameters ω
K/2π=
0.955 GHz ζ/2π=− 0.04 GHz, ξ/2π=0.13 GHz, /Delta1=0.3,ζy=
ζ/4,ξxy=ξ/4,ξy=ξ/6, and ¯/Delta1=/Delta1. (e) Magnetic wave propaga-
tion in the magnetic waveguide supporting signal localization. (f)
Magnetic wave propagation in the magnetic waveguide supportingselective propagation of frequency.
where
HAA=ω2D
0−2ξ2
ωKcos2kx=HBB, (21)
HAB=2ζ(coskx−i/Delta1sinkx)
+2ξ2
xy
ω0cosky(coskx−i¯/Delta1sinkx), (22)
andω2D
0(ky)=ωK−2ξ2
y
ωKcos2ky+2ζycosky. The additional
interactions yield the additional dispersion along kydirection.
The resultant 2D band dispersions without and with the(stringlike) domain-wall defect are shown in Figs. 4(c) and
4(d), respectively. In the 2D lattice, the pointlike defect in the
1D model is extended in the ydirection and forms a domain-
wall string. In the presence of the domain-wall defect, we findthat the bound state with a frequency ω
2D
0(ky) is localized on
the defect position (see the Appendix).
In this 2D soliton lattice model, the topological midgap
bound states are localized at the defect position and spatiallyconnected in the ydirection. Therefore, magnetic excitations
on the bound state propagate well along the defect stringwith a small spread in the transverse ( x) direction. This
propagation characteristic realizes a magnetic waveguide byusing magnetic solitons with signal localization and selec-tive propagation of frequency modes. Figures 4(e) and 4(f)
show the schematic illustration of two functionalities of themagnetic soliton waveguide. In Fig. 4(e), the incoming wavepacket is a plane wave (i.e., uniform along the xdirec-
tion) and has a frequency corresponding to the bound state.Because this frequency mode can only propagate throughthe defect string, the outgoing wave packet is localized onthe defect site. In Fig. 4(f), the incoming wave packet on the
defect site is a white signal having equal intensities for allfrequencies. However, most frequency modes on the defectsite cannot propagate in the ydirection, except for the bound
state. As a result, the outgoing wave packet on the defectsite has a peak at a frequency corresponding to the boundstate. Unfortunately, in our magnetic waveguide, we cannotobtain a single frequency outgoing wave packet because thegroup velocity along the bound state ( v
y) is very small if the
bandwidth of the bound state is too narrow. For a waveguidewith finite group velocity, we need some intermediate valuesofy-directional hopping parameters. In Figs. 4(c) and4(d),w e
choose a set of parameters which results in
|vy|/|vupper
x|≈1
and|vy|/|vlowerx|≈0.4, where |vupper
x|and|vlowerx|are the aver-
aged absolute value of group velocities (along the xdirection)
of the upper and lower band over the first Brillouin zone,respectively.
Note that our 2D magnetic waveguide does not show the
topologically protected (back-scattering free) transport. Anydisorders or defects in our 2D waveguide give rise to back-scattering for transport along the waveguide. However, theexistence of the waveguide with frequencies separated fromthe bulk bands is topological in a sense that the waveguide iscomposed of topological modes in each SSH chain.
We note that the frequency of the bound state is mainly
determined by the gyrotropic frequency of a single magneticsoliton, which is tunable by external perturbations. For ex-ample, in the presence of an effective magnetic field H
eff
perpendicular to the disk plane, the gyrotropic frequency can
be described as [ 50,51]
ω/similarequalK
G(1+kHeff), (23)
where kis a proportionality constant. This suggests that
the waveguide property can be manipulated by the exter-nal magnetic field or voltage-induced magnetic anisotropychange [ 52].
V . CONCLUSION
To summarize, we have studied collective dynamics in
a one-dimensional bipartite chain of the magnetic vorticesor skyrmions. In our magnetic system, the domain-wall-likedefects are produced by changing the interdisk distances.We have found that the defects induce the midgap stateswhich are confined at the defect position. We also providethe micromagnetic simulation results supporting the analyticresults. Our finding on the 1D model is analogous to that of theSSH model in the electron system. In contrast to the electronicSSH model, in which it is hard to manipulate the domain-wallprofiles of atomic arrangement, the topological manipulationis feasible in our magnetic SSH model. As a technologicalapplication, we propose a two-dimensional extension of our1D model, which supports a magnetic waveguide of magneticexcitations. The magnetic waveguide provides not only a sig-nal localization but also selective propagation of the frequency
134423-5GO, HONG, LEE, KIM, AND LEE PHYSICAL REVIEW B 101, 134423 (2020)
modes. Our work suggests that a spintronics device based on
magnetic metamaterials can offer a way for precise control ofthe the oscillation of magnetic soliton lattice.
ACKNOWLEDGMENTS
G.G. was supported by the National Research Foundation
of Korea (NRF) (Grant No. NRF-2019R1I1A1A01063594).S.K.K. was supported by a Young Investigator Grant (YIG)from Korean-American Scientists and Engineers Association(KSEA) and Research Council Grant No. URC-19-090 of theUniversity of Missouri. K.-J.L. acknowledges support by the
NRF (Grant No. NRF-2020R1A2C3013302).
G.G. and I.-S.H. contributed equally to this work.
APPENDIX: COMPUTATIONAL DETAILS
OF THE 2D MODEL
Here, we derive the effective Hamiltonian of the 2D ex-
tension of our 1D magnetic SSH model. The lattice structureof our 2D model is shown in Fig. 4(a) and the second-order
interactions are shown in Fig. 4(b). By using Eq. (6) of
Ref. [ 23], we write
i˙ψA
2m=/parenleftbigg
ωK−ξ2+ξy2
ωK/parenrightbigg
ψA
2m+ζ(1+/Delta1)ψB
2m+x+ζ(1−/Delta1)ψB
2m−x+ζy/parenleftbig
ψA
2m+y+ψA
2m−y/parenrightbig
−ξ2
2ωK/parenleftbig
ψA
2m+2x+ψA
2m−2x/parenrightbig
−ξ2
y
2ωK/parenleftbig
ψA
2m+2y+ψA
2m−2y/parenrightbig
+ξ2
xy(1+¯/Delta1)
2ωK/parenleftbig
ψB
2m+x+y+ψB
2m+x−y/parenrightbig
+ξ2
xy(1−¯/Delta1)
2ωK/parenleftbig
ψB
2m−x+y+ψB
2m−x−y/parenrightbig
, (A1)
i˙ψB
2m+x=/parenleftbigg
ωK−ξ2+ξy2
ωK/parenrightbigg
ψB
2m+x+ζ(1−/Delta1)ψA
2m+2x+ζ(1+/Delta1)ψA
2m+ζy/parenleftbig
ψB
2m+x+y+ψB
2m+x−y/parenrightbig
−ξ2
2ωK/parenleftbig
ψB
2m+3x+ψB
2m−x/parenrightbig
−ξ2
y
2ωK/parenleftbig
ψB
2m+x+2y+ψB
2m+x−2y/parenrightbig
+ξ2
xy(1−¯/Delta1)
2ωK/parenleftbig
ψA
2m+2x+y+ψA
2m+2x−y/parenrightbig
+ξ2
xy(1+¯/Delta1)
2ωK/parenleftbig
ψA
2m+y+ψA
2m−y/parenrightbig
. (A2)
In Eqs. ( A1) and ( A2), we neglect ξ2/Delta1/prime2/ωKterms which are induced from the staggeredness of ξ. Taking the Fourier
transformation, we obtain a momentum space Hamiltonian
H2D(kx,ky)=/parenleftbigg
HAAHAB
HBAHBB/parenrightbigg
, (A3)
where
HAA=ωK−2ξ2
ωKcos2kx−2ξ2
y
ωKcos2ky+2ζycosky=HBB, (A4)
HAB=2ζ(coskx−i/Delta1sinkx)+2ξ2
xy
ω0cosky(coskx−i¯/Delta1sinkx)=(HBA)∗. (A5)
In order to obtain the bound-state solution, we expand the Hamiltonian around kx=π/2 and replace kx−π/2t o−i∂x. Then we
have
HAA=ω2D
0(ky)=HBB, (A6)
HAB=2ζ(i∂x−i/Delta1)+2ξ2
xy
ω0cosky(i∂x−i¯/Delta1)=2ζ[1+α(ky)]i∂x−2iζ/Delta1[1+β(ky)]=(HBA)∗, (A7)
where ω2D
0(ky)=ωK−2ξ2
y
ωKcos2ky+2ζycosky,α(ky)=ξ2
xy
ζωKcosky,β(ky)=¯/Delta1
/Delta1α(ky). In the presence of the domain-wall
defect, i.e., /Delta1(x)=/Delta10sgn(x) and ¯/Delta1(x)=¯/Delta10sgn(x), by solving the Schrödinger equation
H2D(x,ky)/Psi1bound (x,ky)=ω2D
0(ky)/Psi1bound (x,ky), (A8)
we obtain the bound-state solution which is confined at the defect position:
/Psi1bound (x,ky)∼/parenleftbigg0
e−ρ(ky)/Delta10|x|/parenrightbigg
(/Delta10>0),
/Psi1bound (x,ky)∼/parenleftbigg
e−ρ(ky)/Delta10|x|
0/parenrightbigg
(/Delta10<0), (A9)
where ρ(ky)=1+β(ky)
1+α(ky).
134423-6REALIZATION OF SU-SCHRIEFFER-HEEGER STATES … PHYSICAL REVIEW B 101, 134423 (2020)
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134423-7 |
PhysRevB.97.184432.pdf | PHYSICAL REVIEW B 97, 184432 (2018)
Composition and temperature-dependent magnetization dynamics in ferrimagnetic TbFeCo
Wei Li,1Jiaqi Yan,1Minghong Tang,2Shitao Lou,1,*Zongzhi Zhang,2,†X. L. Zhang,1and Q. Y . Jin1,2,‡
1State Key Laboratory of Precision Spectroscopy, East China Normal University, Shanghai 200062 , China
2Department of Optical Science and Engineering, Fudan University, Shanghai 200433 , China
(Received 16 November 2017; revised manuscript received 12 May 2018; published 30 May 2018)
The temperature-dependent magnetization dynamics in ferrimagnetic TbFeCo alloys with various compositions
of Tb is investigated by the pump-probe time-resolved magneto-optical Kerr effect (TR-MOKE) in differentgeometries. It is shown that, for the case when a magnetic field is applied noncollinearly to the easy axis atroom temperature, the decrease of the MOKE signal occurring at several tens of picoseconds (ps) after a rapiddemagnetization within a few hundred femtoseconds (fs) is in fact caused by a highly damped precessional motionwith precession lifetime shorter than the precession period. This is demonstrated by reducing the Tb content to6% in atomic ratio and measuring TR-MOKE at elevated temperatures. This has the dual effect of reducing thedamping constant allowing the observation of more precession cycles and of weakening the exchange interactionbetween Tb and FeCo, making the precession oscillations more pronounced. The results give important insightinto the ultrafast spin dynamics of rare-earth-doped transition-metal alloys, and the remarkable impact of Tb onthe damping in such alloy systems.
DOI: 10.1103/PhysRevB.97.184432
I. INTRODUCTION
In the past few decades, ultrafast magnetization dynamics
in magnetic structures has attracted a great deal of attentiondue to its crucial importance for ultrafast magnetic recordingand ultrafast spintronic devices [ 1–7]. Using an ultrashort laser
pulse incident on magnetic films, the magnetization can beperturbed, showing an ultrafast demagnetization, in certaincases followed by a precession, and even a reversal of magne-tization. The pioneering work by Beaurepaire et al. exploiting
the time-resolved magneto-optical Kerr effect (TR-MOKE) onnickel thin films demonstrated an ultrafast demagnetization[1]. They introduced a phenomenological three-temperature
(3T) model, describing the interaction between the electron,spin, and lattice subsystems and giving an explanation of thedemagnetization and its relaxation. The ultrafast demagneti-zation of thin films consisting of only ferromagnetic transitionmetals (TMs) is considered to follow the 3T model with ademagnetization occurring at less than 1 ps.
In recent years, the magnetization dynamics of rare-earth–
transition-metal (RE-TM) ferrimagnetic alloys such as GdCo,GdFeCo, TbFeCo, etc. has also been studied [ 6,7], and it
has shown some different behaviors from that of ferromag-netic TM materials due to their complex magnetic struc-tures. Mekonnen et al. presented their results of the laser-
induced demagnetization in GdCo and GdFeCo [ 7], where
they found a second demagnetization step. They proposeda four-temperature (4T) model to describe this phenomenonwith four coupled differential equations that take the heatflow between the different heat baths (electrons, lattice, Gd
*stlou@admin.ecnu.edu.cn
†zzzhang@fudan.edu.cn
‡qyjin@phy.ecnu.edu.cn; qyjin@fudan.edu.cn4fspins, and FeCo 3 dspins) into consideration. The new
observation of two-step demagnetization can then be wellexplained, with a result that the demagnetization of rare-earth(RE) metal is about two or three orders of magnitude slowerthan that of TMs [ 5,8–11]. In addition, some work including
theoretical [ 12] and experimental [ 13–15] investigations has
concerned the magnetization dynamics of precessional damp-ing for RE-metal doped permalloy. It was found that mostRE-metal atoms (such as Tb, etc.) induced a large increaseof damping constant αexcept for Eu and Gd, which have no
orbital momentum. Therefore, it is expected and also has beenreported that the precession in RE-TM ferrimagnetic alloyswith Tb, Dy, etc. rare-earth dopants ( >10%) is hardly observed,
due to the very large increase of damping with those REelements.
In RE-TM ferrimagnetic alloys, the magnetizations of RE
and TM sublattices are aligned antiparallel and cancel eachother at the magnetization compensation temperature T
comp
[16]. The magnetic properties of RE-TM alloys, such as net sat-
uration magnetization Ms, coercive field Hc, Curie temperature
Tc, andTcomp, depend on Tb composition [ 16,17]. AtTcomp,t h e
net magnetization changes sign: below or above Tcomp, the net
magnetization is dominated by one of the magnetic sublattices(RE-dominant or TM-dominant).
To understand the magnetization dynamics of RE-TM
ferrimagnets in more detail, we present here a careful andsystematic study of the ultrafast demagnetization and relax-ation of TbFeCo films, a typical RE-TM alloy with ferri-magnetic order. We investigate the magnetization dynamicbehavior for different cases relative to T
comp by using Tb
or FeCo-dominant alloys at room temperature (RT) and bychanging the measurement temperature through T
comp at a
given composition of Tb. The results show that when themagnetic field is applied noncollinearly to the easy axis, amagnetization precession takes place around the time range of
2469-9950/2018/97(18)/184432(6) 184432-1 ©2018 American Physical SocietyLI, YAN, TANG, LOU, ZHANG, ZHANG, AND JIN PHYSICAL REVIEW B 97, 184432 (2018)
several tens of ps after a rapid demagnetization, with various
damping constants depending on the Tb composition andtemperature.
II. EXPERIMENTS
A. Samples
A series of amorphous thin films Tb x(Fe 0.2Co0.8)1−xwith
various Tb compositions were deposited on Corning glasssubstrates in a Kurt J. Lesker magnetron sputtering systemwith a base pressure better than 1 ×10
−8Torr. The TbFeCo
films were achieved by cosputtering from Tb and Fe 0.2Co0.8
targets. A 4-nm-thick Ta layer was deposited on the glass
as a buffer layer and a 6.7-nm-thick Pt on the top as acapping layer protecting the magnetic layer from oxidation.The thickness of TbFeCo is about 12 nm. All of the filmswere confirmed to have a perpendicular anisotropy by vibratingsample magnetometer (VSM) measurements in both in-planeand out-of-plane directions [ 18].
B. Measurement methods
The pump-probe TR-MOKE measurements were per-
formed at various temperatures by a pulsed Ti:sapphire ampli-fier laser at a central wavelength of 800 nm, with a repetitionrate of 1 kHz and a pulse width of about 130 fs. The linearlypolarized laser beam was split into two parts with unequalpowers, and the ratio of pump-to-probe beams was chosen tobe approximately 40 : 1. The probe pulse beam was incidentonto the sample at a small angle, and the spot sizes of thepump and probe beam are about 0.5 and 0.1 mm, respectively,so that homogeneous heating was ensured in the probing areaof the sample. An external magnetic field H
extgenerated by an
electromagnet was applied at an angle of 17owith respect to
the sample plane and perpendicular to the sample plane (i.e.,parallel to the direction of magnetization). In these two con-figurations, the magneto-optical Kerr rotation was measured.The ellipticity was also measured to ensure that the optical(magnetization-independent) contributions to MOKE werenegligible [ 19]. The signals were read out by a lock-in amplifier
with an optical chopper that modulates the pump beam at afrequency of 108 Hz. We should mention that at a photonenergy of 1.55 eV (800 nm in wavelength), the contributionto the magneto-optical Kerr signal is predominantly given bythe FeCo subsystem [ 20,21].
III. RESULTS AND DISCUSSIONS
A. Static magnetic property measurements
The static magnetic properties were first measured by a
vibrating sample magnetometer (VSM) at room temperature(RT). The sample with a Tb composition of 24% exhibitsno obvious magnetic signal, which means the compensationtemperature with 24% Tb is around RT, where the antiparallellyaligned Tb and FeCo magnetic sublattices compensate eachother [ 22]. The samples with Tb compositions higher than 24%
are Tb-dominant, and those having Tb compositions below24% are FeCo-dominant. Figure 1(a) shows a variation of the
FIG. 1. (a) The saturation magnetization Msas a function of
temperature for Tb x(FeCo) 1−x(x=22%, 24%, and 30%). (b) The
Kerr loops of MOKE without pump pulse for Tb x(FeCo) 1−xsamples
with various Tb compositions ( x=17%, 19%, 24%, 30%, and 33%)
at RT.
saturation magnetization Mswith temperature below 500 K
for samples with x=22%, 24%, and 30% corresponding to
FeCo-dominant, compensation composition, and Tb-dominantcases, respectively. Their T
comp are found to be 210, 295, and
470 K, respectively, and the measured Curie temperature Tc
of the sample of x=30% is about 500 K. No measurements
were made beyond 500 K, but we would expect Tcfor samples
of 22% and 24% to be greater than this value. Tcomp increases
with increasing Tb composition, while Tcdecreases [ 23]. Due
to the strong intersublattice 3 d-5d6s-4fexchange interaction
between FeCo and Tb magnetic moments, Tcis higher than
RT for TbFeCo alloys, though that of pure Tb is very low(only about 220 K [ 24]). The static magnetic properties were
also measured using standard Kerr loops for all samples withvarious Tb compositions at RT [typical results are shown inFig. 1(b)]. Clearly, the coercivity H
cincreases close to the
compensation composition of x=24%. The MOKE signal
reverses when the composition increases through 24% (fromFeCo-dominant to Tb-dominant, or vice versa) due to thechange of direction of the FeCo magnetization. Moreover,magnetic hysteresis could not be observed for the concentrationx=24%, which is attributed to its high coercivity (larger than
our maximum magnetic field ∼14 kOe).
184432-2COMPOSITION AND TEMPERATURE-DEPENDENT … PHYSICAL REVIEW B 97, 184432 (2018)
FIG. 2. TR-MOKE curves in Tb x(FeCo) 1−xusing a pump fluence
of 4.2 mJ /cm2withHextof 9.2 kOe at RT. (a) x=10%, 12%,
15%, 17%, and 19%; and (b) x=30% and 33%. The orientation of
magnetization (up or down) is decided by the external magnetic field.
The inset between (a) and (b) shows the schematic illustration of the
TR-MOKE measurement with Hextapplied with an angle θHof 73o
away from the easy-axis direction of magnetization. (c) TR-MOKE
curves at RT for samples of Tb 0.12(FeCo) 0.88and Tb 0.33(FeCo) 0.67in
the polar geometry ( θH=0o), i.e., Hextis perpendicular to the film
plane (parallel to the perpendicular anisotropy field of the films).
B. Composition-dependent magnetization dynamics
Figure 2shows the TR-MOKE results of laser-induced
magnetization dynamics with demagnetization and relaxationrecovery in Tb
x(FeCo) 1−x(x=10%, 12%, 15%, 17%, 19%,
30%, and 33%) using a pump fluence of 4.2 mJ /cm2under
an external field of 9.2 kOe at RT. In Fig. 2(a), ultrafast
demagnetization occurs initially at ∼600 fs. This process
refers to the demagnetization of FeCo with a rapid increaseof spin temperature of 3 delectrons. Subsequently, a fast
magnetization recovery takes place within about 2 ps, cor-responding to the thermal equilibrium of the FeCo electron-spin-lattice system. With increasing Tb composition (from10% to 19%), the amplitude of the demagnetization increasesslightly [see the inset of Fig. 2(a)]. On changing from FeCo-
dominant to Tb-dominant compositions, as shown in Fig. 2(b),
the demagnetization amplitude for Tb-dominant samples islarger. The Kerr signal originates from the FeCo subsystemin TbFeCo alloys at a wavelength of 800 nm. In addition, theexchange interaction between FeCo spins is the most importantfactor to determine the demagnetization behavior, which isobviously Tb-composition-dependent. With the increase of Tb
composition in TbFeCo, the demagnetization is thought tobe easier due to the weakening of the exchange interactionbetween FeCo spins arising from the inhibition effect inducedby Tb doping ( T
cis also lower for higher Tb composition
[23]). This is in accord with the result in Ref. [ 18], where
it was found in TbCo alloys that the trend of magnetizationquenching increased with increasing Tb composition becauseof the decreasing Co-Co coupling constant. In addition, anotherexplanation of faster reduction of the signal with increasingTb composition is the more efficient transfer of angular mo-mentum between FeCo and Tb sublattices. The intersublatticeangular momentum transfer speeds up the demagnetization inantiferromagnetically ordered materials [ 25].
After the ultrafast demagnetization and recovery processes
within 2 ps, the curves exhibit an interesting phenomenonin that the Kerr signal decreases again. However, this phe-nomenon is not observed for Tb-dominant samples shownin Fig. 2(b). The schematic geometry for this TR-MOKE
measurement is illustrated in the inset of Fig. 2. The external
magnetic field H
extis applied with an angle θHof 73oaway
from the easy-axis direction of magnetization (i.e., 17orelative
to the film plane), driving the magnetization orientation away
from the perpendicular easy axis. This geometry is set for thepurpose of initiating the possible precession of magnetizationwhen the external magnetic field is applied along the directionclose to the hard axis of magnetization (with a small angle).This suggests that the second decrease of the Kerr signal mightbe related to the precession of magnetization.
To test this hypothesis, we carried out TR-MOKE mea-
surements in a polar geometry, i.e., the magnetic field isapplied perpendicular to the film plane (along the easy axisof magnetization for TbFeCo). Figure 2(c) gives the typical
results for the samples with Tb compositions of 12% and 33%,where only ultrafast demagnetization can be observed for bothFeCo-dominant and Tb-dominant samples. We did not findthe second demagnetization described in GdFeCo with thesame measurement geometry [ 7], because in TbFeCo alloys
the angular momentum transfer from Tb magnetic moments tothe lattice is considerably faster than that from Gd magneticmoments to the lattice in GdFeCo alloys, due to the nonzero4forbital momentum of Tb [ 9]. The second decrease of the
Kerr signal occurring after 2 ps measured in the geometry ofFig.2(a)is believed to correspond to the first oscillation of the
magnetization precession of FeCo spins. Due to the very largedamping constant in TbFeCo with rare-earth Tb atoms, theprecession decays very fast and dies out before the completionof the first period of oscillation. This argument is also supportedby the evidence of the magnetic-field-dependent TR-MOKEexperiment. Figure 3(a) displays the TR-MOKE data for the
sample of x=12% using the same geometry as for the data
in Fig. 2(a) withH
extchanging from 750 Oe to 14 kOe. The
corresponding delay time of the minimum Kerr signal for thesecond decrease becomes smaller as H
extincreases, which is
a typical feature of precession. Therefore, we believe that thedynamics occurring at several tens of ps timescale in Fig. 2(a)is
the magnetization precession, which is sensitive to the appliedmagnetic field.
At the large delay (200–300 ps) shown in Fig. 2(a),t h e
relative reduction of the MOKE signal is larger for smaller
184432-3LI, YAN, TANG, LOU, ZHANG, ZHANG, AND JIN PHYSICAL REVIEW B 97, 184432 (2018)
FIG. 3. TR-MOKE curves at RT as a function of Hextfor
Tb0.12(Fe 0.2Co0.8)0.88(a) for Tb 0.06(Fe 0.2Co0.8)0.94and pure Fe 0.2Co0.8
(b). The solid lines in (a) are fitting curves. Parts (c)–(e) are, respec-
tively, the magnetic-field dependences of magnetization precession
frequency f, decay time τ, and the effective Gilbert damping αeff,
fitted from the TR-MOKE curves in (a).
Tb compositions. We know that at that delay, the precession
is completely over, and the magnetization is oriented alongthe effective field direction. The relative reduction of the z
projection of the magnetization is defined by the pump-inducedtilt of the effective field, which reduces with increasing Tbcomposition. This could be caused by the relatively largerreduction of anisotropy field upon laser pumping for smallerTb compositions, also it is possible due to the demagnetizingfield effect when the external magnetic field is applied at anangle with respect to the sample plane. The demagnetizing fielddecreases with increasing Tb composition as a result of thesmaller saturation magnetization for larger Tb compositions.
In addition, we know that Tb-doped FeCo films show a
very strong dependence of the damping constant on the dopantcomposition. With increasing Tb composition, the dampingconstant αincreases significantly [ 13,15]. We fabricated one
sample with a low Tb composition of 6% and measured itsdynamic curve at RT, as shown in Fig. 3(b), in which we
see more precession oscillations than those with higher Tbcompositions. As a comparison, the TR-MOKE curve of pureFeCo film is also displayed. Apparently, a very low Tb dopingof 6% in FeCo has dramatically destroyed the precession,though still two precession oscillations could be identified. Wefit the measured dynamic Kerr signal from Fig. 3(a) by using
the following formula [ 26,27]:
θ
k=a+be−t/t0+csin(2πf t+ϕ)e−t/τ, (1)
where the first term acorresponds to the background signal
and it is close to zero. The second exponential decay termrepresents the slow magnetization recovery, where bis the
amplitude and t
0is the characteristic relaxation time. The third
term describes the magnetization precession dynamics, wherec,f,ϕ, andτrefer to the oscillation amplitude, frequency,
initial phase, and decay time, respectively. The typical valueof fit parameters a,b,c, andt
0withHextof 10 kOe is 0.1, 0.07,
0.2, and 304.4, respectively. The fitted precession frequency f
and decay time τare, respectively, plotted in Figs. 3(c)and3(d)
as a function of Hext. We obtain that the precession frequency
fincreases monotonically with Hext. Based on the fitted f
andτ, the effective Gilbert damping constant αeffis derived
approximately from the simple equation of αeff=1/2πf τ
[28]. As shown in Fig. 3(e),αeffdecreases dramatically with an
increase of the external field Hext. We can expect that by further
increasing Hext, the effective damping constant will eventually
approach its intrinsic value. The high αeffvalue in the low-field
region results mainly from the inhomogeneous distributionof magnetization or magnetic anisotropy, which may arisefrom the interface roughness, thin layer thickness, and otherfactors [ 29].
We next utilize a decaying exponential function [ 29],
α
eff=αex0exp(−Hext/H0)+α0,t ofi tt h e αeffdata, where
the extracted α0corresponds to αeffat an infinite Hext.T h e
fitting curve is described by the solid line in Fig. 3(e), and
the extracted α0is 0.714±0.021, which is very close to
the early experimental work for Tb-doped Ni 80Fe20[13]. In
general, the origin of the increase of damping in TMs withRE impurities is based on the strong spin-orbit couplingor the spin-spin interaction. Theoretical work investigatingorbit-orbit coupling between the conduction electrons and theimpurity ions was presented by Rebei et al. [12]. But it was
sharply contradicted by Woltersdorf et al. , who explained the
temperature-dependent Gilbert damping by using the slowlyrelaxing impurity model [ 15]. Although these two models
cannot be distinguished by the data in our paper, both ofthem reach the same conclusion, namely that the dampingconstant becomes large when RE is added in TM, whichis consistent with the results in Fig. 2(b) showing that the
precession damping of the Tb-dominant samples of 30% and33% is so large that we cannot observe the occurrence ofoscillation.
C. Temperature-dependent magnetization dynamics
As we mentioned at the beginning, in addition to the Tb
composition change, measuring the TR-MOKE at various tem-peratures is another way to study the magnetization dynamicsacross T
comp(for some compositions of Tb). The compensation
point Tcomp of our Tb 0.24(FeCo) 0.76sample is near RT. It
goes to a lower temperature if Tb in TbFeCo becomes less,and it goes to a higher temperature in the opposite case.Studying temperature-dependent magnetization dynamics isalso a way to change the exchange interaction between Tband FeCo, which gives rise to a change in the precessiondamping constant. The temperature plays an important rolein the precession damping [ 13].
Figure 4(a) shows the TR-MOKE signal dependence on
the temperature for Tb
0.15(FeCo) 0.85. Its static MOKE curves
without a pump pulse are shown in Fig. 4(b), where a reversal
of the hysteresis loop is found at 80 K after crossing thecompensation point ( T
comp≈100 K). At RT, the precession
starts but has not completed the first cycle, implying that thelifetime of precession is shorter than its period. This time we
184432-4COMPOSITION AND TEMPERATURE-DEPENDENT … PHYSICAL REVIEW B 97, 184432 (2018)
FIG. 4. (a) TR-MOKE curves measured at various tempera-
tures for Tb 0.15(FeCo) 0.85and (b) its static MOKE loops without
a pump pulse. (c) TR-MOKE curves at various temperatures for
Tb0.06(Fe 0.2Co0.8)0.94. Note that the sample temperature presented here
does not include the temperature increase (roughly ∼40 K) induced
by the pump heating.
use a higher pump fluence of 6.0 mJ /cm2in order to ensure
that we can measure the precession for lower temperatures,thus the recovery seems more difficult than that with a lowerpump fluence. At 200 K, we can still see the decrease ofmagnetization (part of the precession) to a minimal valueat about 20 ps and a recovery afterward. But at 80 K, noclear precession could be distinguished. So, the precessionbecomes weakened as the temperature decreases from RTto 80 K, implying that the damping constant αincreases
with deceasing temperature. When we focus on the lower Tbcomposition of 6%, this phenomenon is revealed more clearly.Figure 4(c) shows the TR-MOKE results measured at various
temperatures for the sample of Tb
0.06(Fe 0.2Co0.8)0.94. Several
complete oscillation periods of precession are clearly observed.The higher temperature leads to more precession oscillations.Normally we know that the scattering with magnons andphonons becomes stronger when the temperature increases,
leading to a higher damping at higher temperature. Indeed,a phenomenon has been observed in Ref. [ 13] in which the
damping constant αshows a small increase for undoped NiFe
with increasing temperature. However, the NiFe sample withTb doping exhibits a decreasing behavior in damping quitestrongly with increasing temperature. The key point to explainthis is the significant increase of damping originating fromTb dopants. When the temperature increases, the exchangeinteraction between Tb and FeCo becomes weaker [ 25]. Thus,
the dissipation of precession energy becomes smaller since theefficiency of transfer of FeCo spin to the lattice through Tbmagnetic moments reduces with increasing temperature, andthe damping, which dominantly represents the dynamics ofFeCo spins for TR-MOKE curves measured at a wavelengthof 800 nm, will be lower at higher temperature. As a result, weobserved a decrease of damping with increasing temperature.
IV . CONCLUSIONS
In summary, laser-induced ultrafast magnetization dynam-
ics in the amorphous alloy TbFeCo is investigated by pump-probe TR-MOKE experiments. In the range of Tb compositionfrom 10% to 33% in our samples, the amplitude of ultrafastdemagnetization o na1p st i m e s c a l es h o w sas l i g h t l yi n c r e a s i n g
trend with an increase of Tb composition. Moreover, if themagnetic field is applied noncollinearly to the easy axis atRT, the reduction of the MOKE signal occurring in tens ofps is a magnetization precession of FeCo spins, with a largedamping constant when Tb composition is not very low. Thisis evidenced by the experiment with a magnetic field appliedalong its easy axis where the MOKE oscillation disappears. Bychanging the measurement temperature for the sample with alow Tb composition, we have found that the temperature playsan important role in helping to adjust the precession dampingconstant, so that we can see clear precession oscillationspresented in TbFeCo alloys with less Tb composition at highertemperatures.
ACKNOWLEDGMENTS
This work was supported by the National Key R&D
Program of China (2017YFA0303403), the National BasicResearch Program of China (2014CB921104), the NationalNatural Science Foundation of China (Grants No. 11674095,No. 51671057, and No. 11474067), and the 111 project(B12024).
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184432-6 |
PhysRevLett.108.076604.pdf | Spin Drift Velocity, Polarization, and Current-Driven Domain-Wall Motion in (Ga,Mn)(As,P)
J. Curiale,1,2,*A. Lemaı ˆtre,2C. Ulysse,2G. Faini,2and V. Jeudy1,3,†
1Laboratoire de Physique des Solides, Universite ´Paris-Sud, CNRS, 91405 Orsay, France
2Laboratoire de Photonique et de Nanostructures, CNRS, 91460 Marcoussis, France
3Universite ´Cergy-Pontoise, 95000 Cergy-Pontoise, France
(Received 10 November 2011; published 17 February 2012)
Current-driven domain-wall motion is studied in (Ga,Mn)(As,P) ferromagnetic semiconducting tracks
with perpendicular anisotropy. A linear steady state flow regime is observed over a large temperaturerange of the ferromagnetic phase ( 0:1T
c<T<T c). Close to 0 K, the domain-wall velocity is found to
coincide with the spin drift velocity. This result is obtained below the intrinsic threshold for domain-wall
motion which implies a nonadiabatic contribution to the spin transfer torque. The current spin polarization
is deduced close to 0 K and to Tc. It suggests that the temperature dependence of the spin polarization can
be inferred from the domain-wall dynamics.
DOI: 10.1103/PhysRevLett.108.076604 PACS numbers: 72.25.Dc, 75.50.Pp, 75.60.Jk, 75.78.Fg
A spin polarized current flowing through a domain wall
(DW) exerts a torque on the DW magnetization. At suffi-ciently large current, this torque produces DW motion. In
the damping limited flow regimes, the DW dynamics is
commonly derived from a modified Laudau-Lifshitz-Gilbert equation [ 1,2]. Within this phenomenological de-
scription, two contributions to the spin torque are usuallyintroduced: an adiabatic term, and a nonadiabatic contri-
bution, proportional to the so-called /C12factor. The pre-
dicted DW velocities vare proportional to the spin drift
velocity of the current carriers and depend on the ratio
/C12=/C11, where /C11is the Gilbert damping coefficient. Several
authors have carried out microscopic derivations of /C12and
/C11from spin relaxation mechanisms due to impurity scat-
tering in metals [ 3], or due to spin-orbit interaction [ 4,5].
However, these predictions are rather different and canhardly be compared quantitatively to the limited numberof experimental results.
Experimentally, the damping limited flow regimes are
difficult to reach due to the high current density threshold
Jth required to move DWs. For metallic structures, linear
flow regimes vðJÞwere observed only recently, in
Pt=Co=AlO
xtracks [ 6] with perpendicular anisotropy
(Jth¼1012A=m2). In (Ga,Mn)As ferromagnetic semicon-
ductors, flow regimes were evidenced ( Jth¼109A=m2
[7]) only close to the Curie temperature in layers with
perpendicular magnetic anisotropy [ 7,8]. A /C12=/C11 value
close to 1 was deduced from the analysis of current-
induced domain-wall dynamics [ 7], performed in the frame
of the 1D model [ 1,2]. However, this result remains puz-
zling since the /C11values deduced from field-driven mea-
surements [ 7,9] strongly differ from theoretical predictions
and ferromagnetic resonance measurements. Obviously abetter understanding of the fundamental physics of current-driven DW dynamics would benefit from a model-
independent determination of the parameters governing
DW motion, such as the carrier spin polarization and thespin drift velocity. Moreover, it would be particularly
interesting to study DW motion at low temperature.Indeed, to our best knowledge, carrier spin polarization
in (Ga,Mn)As was only estimated close to zero tempera-
ture [ 10–12], from point-contact Andreev reflection mea-
surements. Reducing the temperature would also decreasethe thermal fluctuations which may significantly affect DWdynamics [ 13].
In previous studies, the flow regime was only accessible
in a narrow temperature range below T
c. These experi-
ments were performed on (Ga,Mn)As tracks grown on
metamorphic (In,Ga)As substrates [ 7,8], required to pro-
vide a perpendicular anisotropy. However, the metamor-phic growth mode is inherently associated with theformation of emerging dislocations [ 14] and other defects
which act as pinning centers for DWs. Moreover, the lowheat conductivity of (In,Ga)As substrates [ 15,16] results in
a large track temperature rise produced by Joule heatingwhich impedes the exploration at low temperature.
Recently, we developed a new alloy (Ga,Mn)(As,P) grown
pseudomorphically on GaAs substrate [ 17], presenting a
perpendicular anisotropy. Current-driven DW motion hasbeen reported in this alloy well below T
c[18].
In this Letter, we present a thorough investigation of the
linear flow regime in (Ga,Mn)(As,P) tracks over the wholetemperature range, from /C240:1T
c(T¼13 K )u pt o Tc.D W
velocity vis shown, without any assumptions on the nature
of the flow regime, to coincide with the carrier spin drift
velocity u, close to 0 K. Rather interestingly, these experi-
ments suggest that DW dynamics give access to the currentspin polarization P
cover the whole temperature range up
toTc.
The micro-tracks with a perpendicular magnetic anisot-
ropy were elaborated [ 17] from a 50 nm thick
ðGa0:90Mn0:10ÞðAs0:89P0:11Þfilm, deposited by molecular
beam epitaxy on a 375/C22mthick GaAs (001) substrate
atT¼250/C14C. The film was then annealed during 1 h, atPRL 108, 076604 (2012) PHYSICAL REVIEW LETTERSweek ending
17 FEBRUARY 2012
0031-9007 =12=108(7) =076604(5) 076604-1 /C2112012 American Physical SocietyT¼250/C14C. The Curie temperature of the film is Tc¼
119/C61K. For the details on experimental methods, see
Supplemental Material [ 19]. Micro-tracks 90/C22mlong,
oriented along the ½1/C2210/C138, [110], and [100] axes with differ-
ent widths (0.5, 1, 2, 4/C22m), and connected to a nucleation
pad, were patterned by e-beam lithography. The saturation
magnetization MsðTÞwas determined from magnetometry
measurements (SQUID). The estimated effective Mn spinconcentration is 5% [ 19]. Current-induced DW motion was
studied in an open cycle optical cryostat with a temperatureaccuracy of 0.2 K. DW motion is produced by current
pulses of different amplitudes Jand of a single duration
/C1t¼1/C22s. The magnetic state of the tracks was observed
by differential polar magneto-optical Kerr microscopywith a 1/C22mresolution. As the DW displacements /C1x
were found to be proportional to the pulse duration andto the number of pulses, the average DW velocity is definedasv¼/C1x=/C1t[7,19]. The Joule heating of the track due to
current pulses was studied extensively [ 15] and carefully
taken into account (see [ 19]). In order to compare DW
dynamics for a fixed track temperature T, for each Jvalue,
the sample holder was set to an initial temperature T
i¼
T/C0/C1TðJ;1/C22sÞ, where /C1TðJ;1/C22sÞis the temperature
rise at the end of the pulse. For the lowest exploredtemperature T¼13 K , the initial temperature was set to
T
i¼4KforJ¼13 GA =m2.
The current-driven DW velocity vis reported in Fig. 1as
a function of the current density for several temperatures.
DW motion is observed over a large temperature range(13 K <T< 110 K ). Three different regimes can be iden-
tified [ 7,8]. At low values of the current density J(see inset
of Fig. 1,T¼95 K ), DWs move in a creep regime domi-
nated by pinning barriers and thermal activation. Theirvelocity is low ( v<0:1m=s) and varies exponentially
withJ.F o r J>J
dep/C255G A =m2(T¼95 K ),vbecomes
larger than /C241m=s. DWs move in a depinning regime
controlled by pinning and dissipation. For J>J fl/C25
11 GA =m2(T¼95 K ), DW motion enters a linear flow
regime, only limited by dissipation. This linear regime,whose nature is discussed later, is observed for each tem-perature. The linear extrapolation to zero current yields
v¼0m=s, within the experimental errors (see [ 19]). In
this flow regime, the current DW mobility, defined as/C22
J¼v=J, decreases as the temperature is lowered from
105 to 42.5 K. At lower temperature, /C22Jbecomes weakly
temperature dependent, as evidenced by two additionalvelocity values measured at 28 and 13 K, which fall closeto the curve obtained at 42.5 K. A characteristic slopechange indicates the transition from the depinning regime
to the linear one, which gives a determination of the linear
regime lower bound: J
flðTÞ¼5:5, 11, 13 GA =m2for
T¼105, 95, and 42.5 K, respectively.
To get a better insight into the temperature variations of
the DW mobility /C22J¼v=J, DW dynamics was studied as
a function of the temperature for three different currentdensities. Results are reported in Fig. 2. For the lowest
density J¼7:0/C60:5G A =m
2(circles), /C22Jdecreases
strongly as Tis reduced. The DW dynamics crosses the
boundary between the flow and the depinning regimes andeventually the DWs become pinned ( /C22
J¼0) at finite
temperature ( T/C2570 K ). For the intermediate density J¼
11:5/C61:8G A =m2(triangles), a pronounced temperature
variation is also observed for T>80 K . Below 80 K, /C22Jis
almost independent of temperature ( /C250:5m m3=C). As
J<J flðTÞ, the flow regime threshold, this could be the
FIG. 1 (color online). Current-driven DW velocity vmeasured
at different temperatures T. Each point and its error bar corre-
spond to the average and to the standard deviation calculatedwith more than 20 measurements, respectively. At T¼42:5K,
larger error bars also reflect a slight asymmetry of DW displace-
ments found as the current is reversed. Inset: Semilogarithmicplot of vmeasured at 95 K for the lowest current densities.FIG. 2 (color online). Temperature variations of the current
mobility ( /C22J¼v=J). The empty symbols correspond to three
different current values: 13:3/C62:0G A =m2(squares), 11:5/C6
1:8G A =m2(triangles), and 7:0/C60:5G A =m2(circles). The
filled symbols correspond to the boundary between the pinning
controlled and the flow linear regimes, deduced form the slope
changes observed in Fig. 1. The flow linear regime is material-
ized by a shaded area.PRL 108, 076604 (2012) PHYSICAL REVIEW LETTERSweek ending
17 FEBRUARY 2012
076604-2signature of a DW motion controlled by a distribution of
energy barriers [ 20]. For the highest current density J¼
13:3/C62:0G A =m2(squares) the curve goes through the
/C22Jvalues already reported in Fig. 1for the linear regime
(J/C21Jfl). The current-induced linear flow regime is
thus evidenced over the whole temperature range ( 13 K <
T<110 K ).
We now focus on the origin of the temperature variations
of/C22Jfor the flow regime. As the DW velocity vis
proportional to the current density J, we write v¼
rflðTÞu, where rflðTÞis to be determined. The spin drift
velocity is u¼JPcðTÞg/C22B
2eMsðTÞ[1,2], where g,/C22B,e, and PcðTÞ
are the Lande ´factor, the Bohr magneton, the electron
charge, and the current spin polarization, respectively.Close to 0 K, ucan be deduced from M
sðT/C240KÞ
(Fig. 3) and PcðT/C240KÞ.Pcwas estimated close to 4 K
from point-contact Andreev reflection spectroscopy for(Ga,Mn)As samples with similar Mn concentrations: P
c/C25
0:75,6 %M n[ 10];Pc>0:85,5 %M n[ 11], and Pc¼0:57,
7% Mn [ 12]. Taking the values from Refs. [ 10,12] we get
u¼8:5–11:2m=sforJ¼13:3G A =m2. We now compare
these values to the DW velocity vwith the same current
density, at 13 K. v¼10:5/C60:7m=s, a value very close to
the spin drift velocity uat 4 K, i. e., rfl/C241forT/C240K.I n
order to determine to what extent this result is valid forother temperatures, the current spin polarization P
DWcðTÞ
deduced from DW dynamics is plotted in Fig. 3, assuming
rflðTÞ¼1. Values of PDWcðTÞare calculated using the
measured magnetization MsðTÞ(see Fig. 3) and current
mobility /C22JðTÞ, forJ/C21Jfl(see Fig. 2). Results obtained
close to Tcwith an annealed ðGa0:93;Mn0:07ÞAs 4/C22mwide
track, with similar Mn concentration [ 21] are also reported
in Fig. 3. The temperature variations for both (Ga,Mn)As
and (Ga,Mn)(As,P) tracks shows similar trends close to Tc.The curve extrapolates to PDWc¼0:67/C60:03, for
T!0K. As shown in Fig. 3, this value is found in
between the estimations of Pcgiven in Refs. [ 10,12].
Taking those estimations as boundaries for PDWc, it follows
that0:85<r¼v=u < 1:12, close to 0 K. This is a key
result of this Letter. It shows that a rather accurate estima-tion of the current spin polarization can be deduced fromcurrent-induced DW dynamics. Moreover, it demonstrates,without adjustable parameter, that the domain-wall veloc-ityvis quantitatively close to the spin drift velocity u, for
T/C250K.
The generalization of this result far from 0 K is not
straightforward due to the lack of estimations of P
cvalues.
However, the following shows that u/C25vis compatible
with experimental results, close to the Curie temperature.
As observed in Fig. 3,PDWc!0fort¼T=T c!1. Indeed
the spin polarization tends to zero with the collapse of holemediated ferromagnetism. Moreover, P
DWcðTÞfollows the
temperature variation of MsðTÞ. This observation is con-
sistent with the predictions of Dietl et al. [8,22], close to
Tc, where the thermodynamic spin polarization PðTÞ¼
6kBTC
ðSþ1ÞpJpdMsðTÞ
MsðT¼0Þ.kB,Jpd,S, and pare the Boltzmann
constant, the exchange integral ( Jpd¼/C054 meV nm3),
the Mn spin ( S¼5=2), and the carrier density, respec-
tively. If we assume PDWcðTÞ¼1:0–1:8PðTÞ, (the upper
boundary is proposed in Ref. [ 12], close to 0 K), the carrier
density pcan be deduced from PDWcðTÞandMsðTÞ(Fig. 3)
and the predictions for PðTÞ. The obtained values are
p/C250:18–0:32 nm/C03andp/C250:23–0:42 nm/C03for the
(Ga,Mn)(As,P) and (Ga,Mn)As tracks, respectively. The
carrier densities for both materials are rather close andcompatible with the somewhat larger resistivity measuredfor (Ga,Mn)(As,P) (a factor two) [ 14,23]. The same orders
of magnitude were deduced from other experimental meth-ods in samples exhibiting similar magnetic properties, asreported in Ref. [ 21]. Therefore, the measured temperature
variations of /C22
Jare also compatible with v/C25u, close to
Tc. An alternative analysis based on the Do ¨ring inequality
leads to the same conclusion, as reported in Refs. [ 7,21].
The fact that v/C25uclose to 0 K and to Tc, strongly
suggests that for the linear flow regime, the temperature
variation of the current mobility /C22Jis essentially deter-
mined by the ratio PcðTÞ=MsðTÞbetween the current spin
polarization and the magnetization. In this respect, thecurve P
DWcðTÞ(obtained for v¼u) reported in Fig. 3
does reflect the temperature variation of the current spinpolarization.
We now discuss the nature of the linear flow regime and
the nonadiabaticity of the spin transfer torque. In Fig. 4, the
reduced DW velocity v=v
wpredicted by the 1D model
[1,2] is plotted as a function of the reduced spin drift
velocity u=v w, where vwis the so-called Walker velocity,
for different values of /C12=/C11. Two linear flow regimes are
predicted to occur (see the curves obtained for /C12=/C11¼8
and1=8). For the lowest uvalues, DWs move in the steadyFIG. 3 (color online). Temperature variation of the spin polar-
ization PDWcdeduced from domain-wall dynamics (left scale:
same legend as for Fig. 2) and of the magnetization Ms(right
scale: /C12). Values of the spin polarization Pc(left scale: down
triangles) deduced from point-contact Andreev reflection mea-
surements [ 10–12]. The crossed symbols ( aa) correspond to results
obtained for PDWc, withðGa0:93;Mn0:07ÞAs 4 /C22mwide tracks.PRL 108, 076604 (2012) PHYSICAL REVIEW LETTERSweek ending
17 FEBRUARY 2012
076604-3state flow regime whenever the magnetization direction
within the DW remains constant with time. In this regime,the velocity v¼ð/C12=/C11Þu. Above the so-called Walker
limit, the motion becomes nonlinear with current: DWsare in the precessional regime (the direction of the DWmagnetization precesses during the DW motion). Forhigher uvalues, DWs follow the asymptotic precessional
regime for which v¼u. Let us note that no steady
state regime is predicted for /C12=/C11¼0, while no preces-
sional regime should occur for /C12=/C11¼1. In that specific
case, the DW motion would remain in the steady stateregime for any arbitrary large current.
Figure 4also reports experimental results deduced from
Fig. 1. The Walker velocities are obtained from v
w¼
/C220/C13M sðTÞ/C1=2, where the wall thickness parameter /C1¼
6:5/C61:0n m is taken from Ref. [ 24].uis estimated from
the values of PDWcðTÞand of MsðTÞreported in Fig. 3.I ti s
worth noting that the u=v wvalues span over more than 1
order of magnitude ( 0:3< u=v w<6) because of the large
MsðTÞchange over the investigated temperature range. In
the linear flow regime, the reduced domain-wall velocities(filled symbols) gather onto a single linear master curvesince we assumed that v¼u. The points departing from
thev¼uline (empty symbols) correspond to DW motion
occurring in the depinning regime, as discussed previously.The coincidence between the points measured T¼95and
105 K in the depinning regime (empty symbols) and theflow regime predictions for /C12=/C11¼0and1=8is therefore
accidental.
As seen in Fig. 4, DW motion occurs in the flow regime
well below the intrinsic DW motion threshold u=v
w¼1
expected for a purely adiabatic spin transfer torque. This isa clear evidence of a nonadiabatic contribution (i.e., /C12/C2220)
to the spin transfer torque, in contradiction with the con-clusions of Ref. [ 8]. Two different ranges of /C12=/C11 values
would reproduce our experimental data. A good agreementis obtained with the predicted steady regime, for /C12=/C11¼1.
The experimental results seem to be also compatible with
the asymptotic precessional regime for /C12=/C11¼8, as pre-
dicted in Ref. [ 4]. A higher /C12=/C11 ratio, as proposed in
Ref. [ 5], would shift the Walker peak towards lower values
ofu=v
wand improve the quantitative agreement. In order
to discriminate between the steady state and the preces-
sional regimes, experiments combining current and mag-
netic field-induced motion of magnetic domains were
performed, as proposed in Ref. [ 7]. Weak magnetic fields
are applied ( /C05<H< 5O e ) during the current pulse.
The magnetic field DW mobility /C22H¼dv=/C22 0dHis then
extracted and compared to mobilities measured in experi-
ments where both flow regimes have been clearly identified
[9]. Close to T¼0K, the measured magnetic field mo-
bility /C22H¼2:3/C60:4m=sm T . This value is close to the
DW mobility in the steady state regime ( /C22H¼
1:6/C60:5m=sm T ) deduced from field-induced DW mo-
tion in (Ga,Mn)As films [ 9] with similar Mn concentration.
It is far larger than the mobility ( /C22H¼0:11/C6
0:02 m=sm T ) measured in the asymptotic precessional
regime. Therefore this experiment clearly supports the
hypothesis of DW motion in the steady state regime (i.e.,
/C12/C2220) and, in the frame of the 1-D model, a ratio /C12=/C11
close to 1.
Our investigations on current-induced domain-wall mo-
tion have evidenced a linear domain-wall flow regime overa wide range of temperatures ( 0:1T
c<T<T c). Domain
walls were shown to move in the steady state regime with
velocities corresponding to the carrier spin drift velocities.
Hence, we inferred that the /C12term, characterizing the
nonadiabatic spin transfer torque, is close to the Gilbertdamping coefficient. Moreover, our results suggest that
DW dynamics give direct access to the temperature varia-
tion of the current spin polarization. This parameter is
crucial for understanding the spin transfer phenomena.
However its estimation is not straightforward experimen-tally [ 25,26].
The authors thank A. Thiaville, J. Ferre ´, and J. Miltat for
useful discussions. This work was partly supported by the
French projects RTRA Triangle de la physique Grants
No. 2009-024T-SeMicMac and No. 2010-033T-
SeMicMagII and performed in the framework of theMANGAS project (No. 2010-BLANC-0424).
*Now at Consejo Nacional de Investigaciones Cientı ´ficas y
Te´cnicas, Centro Ato ´mico Bariloche Comisio ´n Nacional
de Energı ´a Ato´mica, Avenida Bustillo 9500, 8400 S. C. de
Bariloche, Rı ´o Negro, Argentina
†vincent.jeudy@u-psud.fr
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076604-5 |
PhysRevB.96.064423.pdf | PHYSICAL REVIEW B 96, 064423 (2017)
Consistent microscopic analysis of spin pumping effects
Gen Tatara
RIKEN Center for Emergent Matter Science (CEMS), 2-1 Hirosawa, Wako, Saitama 351-0198, Japan
Shigemi Mizukami
WPI - Advanced Insitute for Materials Research, Tohoku University Katahira 2-1-1, Sendai, Japan
(Received 2 June 2017; revised manuscript received 28 July 2017; published 18 August 2017)
We present a consistent microscopic study of spin pumping effects for both metallic and insulating
ferromagnets. As for the metallic case, we present a simple quantum mechanical picture of the effect as due tothe electron spin flip as a result of a nonadiabatic (off-diagonal) spin gauge field. The effect of interface spin-orbitinteraction is briefly discussed. We also carry out a field-theoretic calculation to discuss on equal footing the spincurrent generation and torque effects such as an enhanced Gilbert damping constant and a shift of precessionfrequency both in metallic and insulating cases. For thick ferromagnetic metals, our study reproduces the results ofprevious theories such as the correspondence between the dc component of the spin current and the enhancementof the damping. For thin metals and insulators, the relation turns out to be modified. For the insulating case,driven locally by interface sdexchange interaction due to magnetic proximity effect, the physical mechanism is
distinct from the metallic case. Further study of the proximity effect and interface spin-orbit interaction wouldbe crucial to interpret experimental results in particular for insulators.
DOI: 10.1103/PhysRevB.96.064423
I. INTRODUCTION
Spin current generation is of a fundamental importance in
spintronics. A dynamic method using magnetization preces-sion induced by an applied magnetic field, called the spin
pumping effect, turns out to be particularly useful [ 1] and is
widely used in a junction of a ferromagnet (F) and a normalmetal (N) (Fig. 1). The generated spin current density (in unit
of A/m
2) has two independent components, proportional to ˙n
andn×˙n, where nis a unit vector describing the direction of
localized spin, and thus is represented phenomenologically as
js=e
4π(Arn×˙n+Ai˙n), (1)
where eis the elementally electric charge and ArandAiare
phenomenological constants having unit of 1 /m2.T h es p i n
pumping effect was theoretically formulated by Tserkovnyaket al. [2] by use of the scattering matrix approach [ 3]. This
approach, widely applied in mesoscopic physics, describestransport phenomena in terms of transmission and reflectionamplitudes (scattering matrix), and provides a quantum me-chanical picture of the phenomena without calculating explic-itly the amplitudes. Tserkovnyak et al. applied the scattering
matrix formulation of general adiabatic pumping [ 4,5]t ot h e
spin-polarized case. The spin pumping effect was described inRef. [ 2] in terms of spin-dependent transmission and reflection
coefficients at the FN interface, and it was demonstrated thatthe two parameters, A
randAi, are the real and the imaginary
parts of a complex parameter called the spin mixing conduc-tance. The spin mixing conductance, which is represented bytransmission and reflection coefficients, turned out to be aconvenient parameter for discussing spin current generationand other effects like the inverse spin-Hall effect. Nevertheless,the scattering approach hides the microscopic physical pictureof what is going on, as the scattering coefficients are notfundamental material parameters but are composite quantitiesof the Fermi wave vector, the electron effective mass, and the
interface properties.
The effects of a slowly varying potential are described in
a physically straightforward and clear manner by the use ofa unitary transformation that represents the time dependence(see Sec. II Afor details). The laboratory frame wave function
under a time-dependent potential |ψ(t)/angbracketrightis written in terms of
a static ground state (“rotated-frame” wave function) |φ/angbracketrightand a
unitary matrix U(t)a s|ψ(t)/angbracketright=U(t)|φ/angbracketright. The time derivative
∂
tis then replaced by a covariant derivative ∂t+(U−1∂tU),
and the effects of time dependence are represented by (the timecomponent of) an effective gauge field, A≡−i(U
−1∂tU)[ s e e
Eq. ( 12)]. In the same manner as the electromagnetic gauge
field, the effective gauge field generates a current if spatialinhomogeneity is present (like in junctions), and this is thephysical origin of the pumping effect in metals.
It should be noted that the effective gauge field that drives
spin current is a nonadiabatic one, off-diagonal in spin, andnot the adiabatic gauge field that induces spin Berry’s phase,the spin motive force, and spin transfer effects. Nevertheless,the pumping efficiency can be calculated within an adiabaticpumping scheme, as shall be discussed in Sec. II C.
In the perturbative regime or in insulators, a simple picture
instead of an effective gauge field can be presented. Letus focus on the case driven by an sdexchange interaction,
J
sdn(t)·σ, where Jsdis a coupling constant and σis the
electron spin. Considering the second-order effect of thesdexchange interaction, the electron wave function has a
contribution of a time-dependent amplitude
U(t
1,t2)=(Jsd)2(n(t1)·σ)(n(t2)·σ)
=(Jsd)2{(n(t1)·n(t2))+i[n(t1)×n(t2)]·σ},(2)
where t1andt2are the times of the interactions. The first
term on the right-hand side, representing the amplitude forcharge degrees of freedom, is neglected. The spin contributionvanishes for a static spin configuration, as is natural, while for
2469-9950/2017/96(6)/064423(23) 064423-1 ©2017 American Physical SocietyGEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
FNn(t)js
FIG. 1. Spin pumping effect in a junction of ferromagnet (F)
and normal metal (N). Dynamic magnetization n(t) generates a spin
current jsthrough the interface.
the slowly varying case, it reads
U(t1,t2)/similarequal−i(t1−t2)(Jsd)2(n×˙n)(t1)·σ. (3)
As a result of this amplitude, spin accumulation and spin
current is induced proportional to n×˙n. This fact indicates
thatn×˙nplays a role of an effective scalar potential or voltage
in electromagnetism, as we shall demonstrate in Sec. VII B for
insulators. [The factor of time difference is written in terms ofa derivative with respect to energy or angular frequency in arigorous derivation. See, for example, Eqs. ( E6) and ( E9).]
The essence of the spin pumping effect is therefore thenoncommutativity of spin operators. The above picture in theperturbative regime naturally leads to the effective gauge fieldpicture in the strong-coupling limit [ 6].
The same scenario applies for cases of spatial variation of
spin, and an equilibrium spin current proportional to n×∇
in
emerges, where idenotes the direction of spatial variation [ 7].
The spin pumping effect is therefore the time analog of theequilibrium spin current induced by vector spin chirality.Moreover, a charge current emerges from the third-orderprocess from the identity [ 6]
tr[(n
1·σ)(n2·σ)(n3·σ)]=2in1·(n2×n3), (4)
and this factor, a scalar spin chirality, is the analog of the spin
Berry phase in the perturbative regime. The spin pumpingeffect, spin Berry’s phase, and the spin motive force have thesame physical root, namely, the noncommutative spin algebra.
From the scattering matrix theory view point, the cases
of metallic and insulating ferromagnet make no differencesince what the conduction electrons in the normal metal seeis the interface. From the physical viewpoint, such treatmentappears too crude. Unlike the metallic case discussed above, inthe case of an insulator ferromagnet, the coupling between themagnetization and the conduction electron in a normal metaloccurs due to a magnetic proximity effect at the interface,as is experimentally indicated [ 8]. Thus the spin pumping
by an insulator ferromagnet is a locally induced perturbativeeffect rather than a transport induced by a driving force dueto a generalized gauge field. We therefore need to applydifferent approaches for the two cases. In the insulatingcase, one may think that a magnon spin current is generatedinside the ferromagnet because the magnons couple to aneffective gauge field [ 9] similarly to the electrons in metallic
case. This is not, however, true, because the gauge field formagnons is Abelian [U(1)], and has no off-diagonal “spin-flip” component. Although the scattering matrix approachapparently seems to apply to both metallic and insulating cases,it would be instructive to present in this paper a consistent
microscopic description of the effects to see the differentphysics governing the two cases.
A. Brief overview of theories and scope of the paper
Before carrying out calculations, let us overview the history
of theoretical studies of the spin pumping effect. Spin currentgeneration in a metallic junction was originally discussed bySilsbee et al. [10] before Tserkovnyak et al. It was shown there
that dynamic magnetization induces spin accumulation at theinterface, resulting in a diffusive flow of spins in the normalmetal. Although at that time the experimental interest wasfocused on the interface spin accumulation, which enhancesthe signal of conduction electron spin resonance, it would befair to say that Silsbee et al. pointed out the “spin pumping
effect”.
In Ref. [ 2], the spin pumping effect was originally argued
in the context of enhancement of Gilbert damping in anFN junction, which had been a hot issue after the study byBerger [ 11], who studied the case of FNF junctions based on
a quantum mechanical argument. Berger discussed that whena normal metal is attached to a ferromagnet, the damping ofthe ferromagnet is enhanced as a result of spin polarizationformed in the normal metal, and the effect was experimentallyconfirmed by Mizukami et al. [12]. Tserkovnyak et al. pointed
out that the effect can be interpreted as the counteractionof spin current generation, because the spin current injectedinto the normal metal indicates emergence of a torque forthe ferromagnet. In fact, the equation of motion for themagnetization of ferromagnet reads
˙n=−γB×n−αn×˙n−a
3
eSdjs, (5)
where γis the gyromagnetic ratio, αis the Gilbert damping
coefficient, dis the thickness of the ferromagnet, Sis the
magnitude of localized spin, and ais the lattice constant. The
spin current of Eq. ( 1) thus indicates that the gyromagnetic
ratio and the Gilbert damping coefficient are modified by thespin pumping effect to be [ 2]
˜α=α+a
3
4πSdAr,
˜γ=γ/parenleftbigg
1+a3
4πSdAi/parenrightbigg−1
. (6)
The spin pumping effect is therefore detected by measuring
the effective damping constant and gyromagnetic ratio. For-mula ( 6) is, however, based on a naive picture neglecting the
position dependence of the damping torque and the relationbetween the pumped spin current amplitude and damping, orγwould not be so simple in reality (see Sec. V).
The issue of damping in an FN junction was formu-
lated based on linear-response theory by Simanek andHeinirch [ 13,14]. They showed that the damping coefficient is
given by the first-order derivative with respect to the angularfrequency ωof the imaginary part of the spin correlation
function and argued that the damping effect is consistent withTserkovnyak’s spin pumping effect. Recently, a microscopicformulation of spin pumping effect in metallic junctions was
064423-2CONSISTENT MICROSCOPIC ANALYSIS OF SPIN . . . PHYSICAL REVIEW B 96, 064423 (2017)
provided by Chen and Zhang [ 15] and one of the authors of
Ref. [ 16] by use of the Green’s functions, and a transparent
microscopic picture of pumping effect was provided. Thescattering representation and the Green’s function one arerelated [ 15] because the asymptotic behaviors of the Green’s
functions at long distance are governed by the transmissioncoefficient [ 17]. In the study of Ref. [ 16], the uniform
ferromagnet was treated as a dot having only two degrees offreedom of spin. Such simplification neglects the dependenceon electron wave vectors in ferromagnets and thus cannotdiscuss the case of inhomogeneous magnetization or positiondependence of spin damping.
The aim of this paper is to provide a microscopic and
consistent theoretical formulation of spin pumping effect formetallic and insulating ferromagnets. We do not rely onthe scattering approach. Instead, we provide an elementaryquantum mechanical argument to demonstrate that spin currentgeneration is a natural consequence of magnetization dynam-ics (Sec. II). Based on the formulation, the effect of interface
spin-orbit interaction is discussed in Sec. III. We also provide
a rigorous formulation based on the field-theoretic approachemployed in Ref. [ 16] in Sec. IV. We also reproduce within
the same framework Berger’s result [ 11] that the spin pumping
effect is equivalent to the enhancement of the spin damping(Sec. V). The effect of inhomogeneous magnetization is briefly
discussed in Sec. VI.
The case of insulating ferromagnet is studied in Sec. VII
assuming that the pumping is induced by an interface ex-change interaction between the magnetization and conductionelectrons in a normal metal, namely, by the magnetic proximityeffect [ 8]. The interaction is treated perturbatively similarly to
Refs. [ 18,19]. The dominant contribution to the spin current,
the one linear in the interface exchange interaction, turns outto be proportional to ˙n, while the one proportional to n×˙nis
weaker if the proximity effect is weak.
The contribution from the magnons, magnetization fluc-
tuations, is also studied. As has been argued [ 9], a gauge
field for magnons emerges from magnetization dynamics. Itis, however, an adiabatic one, diagonal in spin, which acts as achemical potential for magnons, giving rise only to adiabaticspin polarization proportional to n. This is in sharp contrast
to the metallic case, where electrons are directly driven bythe spin-flip component of the spin gauge field, resulting inperpendicular spin accumulation, i.e., along ˙nand n×˙n.
The excitation in a ferromagnet when the magnetization istime-dependent is therefore different for the metallic andthe insulating cases. We show that a magnon excitationnevertheless generates perpendicular spin current, n×˙n,i n
the normal metal as a result of annihilation and creation at theinterface, which in turn flips the electron spin. The result of themagnon-driven contribution agrees with the one in the previousstudy [ 20] carried out in the context of thermally driven
spin pumping (“spin Seebeck” effect). It is demonstratedthat the magnon-induced spin current depends linearly on thetemperature at high temperature compared to magnon energy.The amplitude of magnon-driven spin current provides themagnitude of the magnetic proximity effect.
In our analysis, we calculate consistently the pumped spin
current and change of the Gilbert damping and resonantfrequency and obtain the relations among them. It is shownthat the spin mixing conductance scenario saying that the
magnitude of spin current proportional to n×˙nis given by
the enhancement factor of the Gilbert damping constant [ 2],
applies only in the case of thick ferromagnetic metals. For thethin metallic and insulator cases, different relations hold (seeSec. VIII).
II. QUANTUM MECHANICAL DESCRIPTION
OF METALLIC CASE
In this section, we derive the spin current generated by
the magnetization dynamics of a metallic ferromagnet by aquantum mechanical argument. It is sometimes useful forintuitive understanding, although the description may lackclearness as it cannot handle many-particle aspects like particledistributions. In Sec. IV, we formulate the problem in the
field-theoretic language.
A. Electrons in ferromagnet with dynamic magnetization
The model we consider is a junction of a metallic fer-
romagnet (F) and a normal metal (N). The magnetization(or localized spins) in the ferromagnet is treated as spatiallyuniform but changing with time slowly. As a result of strongsdexchange interaction, the conduction electron’s spin follows
instantaneous directions of localized spins, i.e., the system isin the adiabatic limit. The quantum mechanical Hamiltonianfor the ferromagnet is
H
F=−∇2
2m−/epsilon1F−Mn(t)·σ, (7)
where mis the electron mass, σis a vector of Pauli matrices,
Mrepresents the energy splitting due to the sdexchange
interaction, and n(t) is a time-dependent unit vector denoting
the localized spin direction. The energy is measured from theFermi energy /epsilon1
F.
As a result of the sdexchange interaction, the electron’s
spin wave function is given by [ 21]
|n/angbracketright≡cosθ
2|↑/angbracketright + sinθ
2eiφ|↓/angbracketright, (8)
where |↑/angbracketrightand|↓/angbracketrightrepresent the spin-up and -down states,
respectively, and ( θ,φ) are polar coordinates for n. To treat
slowly varying localized spins, we switch to a rotated framewhere the spin direction is defined with respect to an instan-taneous direction n[7]. This corresponds to diagonalizing the
Hamiltonian at each time by introducing a unitary matrix U(t)
as
|n(t)/angbracketright≡U(t)|↑/angbracketright, (9)
where
U(t)=/parenleftBigg
cos
θ
2sinθ
2e−iφ
sinθ
2eiφ−cosθ
2/parenrightBigg
, (10)
where states are in vector representation, i.e., |↑/angbracketright = (1
0) and
|↓/angbracketright = (0
1). In the rotated frame, the Hamiltonian is diagonalized
as (in the momentum representation)
/tildewideHF≡U−1HFU=/epsilon1k−Mσz, (11)
064423-3GEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
HF HFU
A±s,t
FIG. 2. Unitary transformation Ufor conduction electrons in a
ferromagnet converts the original Hamiltonian HFinto a diagonalized
uniformly spin-polarized Hamiltonian /tildewideHFand an interaction with a
spin gauge field, As,t·σ.
where /epsilon1k≡k2
2m−/epsilon1Fis the kinetic energy in the momentum
representation (Fig. 2). In general, when a state |ψ/angbracketrightfor a
time-dependent Hamiltonian H(t), satisfying the Schrödinger
equation i∂
∂t|ψ/angbracketright=H(t)|ψ/angbracketright, is written in terms of a state |ψ/angbracketright
connected by a unitary transformation |φ/angbracketright≡U−1|ψ/angbracketright, the new
state satisfies a modified Schrödinger equation:
/parenleftbigg
i∂
∂t+iU−1∂
∂tU/parenrightbigg
|φ/angbracketright=˜H|φ/angbracketright, (12)
where ˜H≡U−1HU. Namely, there arises a gauge field
−iU−1∂
∂tUin the new frame |φ/angbracketright. In the present case of
dynamic localized spin, the gauge field has three components(suffix tdenotes the time component):
A
s,t≡−iU−1∂
∂tU≡As,t·σ, (13)
explicitly given as [ 7]
As,t=1
2⎛
⎜⎝−∂tθsinφ−sinθcosφ∂tφ
∂tθcosφ−sinθsinφ∂tφ
(1−cosθ)∂tφ⎞
⎟⎠. (14)
Including the gauge field in the Hamiltonian, the effective
Hamiltonian in the rotated frame reads
/tildewideHeff
F≡/tildewideHF+As,t·σ=/parenleftBigg
/epsilon1k−M−Az
s,t A−
s,t
A+
s,t /epsilon1k+M+Az
s,t/parenrightBigg
,
(15)
where A±
s,t≡Ax
s,t±iAy
s,t. We see that the adiabatic ( z)
component of the gauge field, Az
s,t, acts as a spin-dependent
chemical potential (spin chemical potential) generated bydynamic magnetization, while the nonadiabatic ( xandy)
components cause spin mixing. In the case of the uniformmagnetization we consider, the mixing is between the electronswith different spin ↑and↓but with the same wave vector k,
because the gauge field A
±
s,tcarries no momentum. This leads
to a mixing of states having an excitation energy of Mas
shown in Fig. 3. In low-energy transport effects, what matters
are the electrons at the Fermi energy; the wave vector kshould
be chosen as kF+andkF−, the Fermi wave vectors for ↑and
↓electrons, respectively. (Effects of finite momentum transfer
are discussed in Sec. VI.)
Hamiltonian ( 15) is diagonalized to obtain energy eigenval-
ues of ˜ /epsilon1kσ=/epsilon1k−σ√
(M+Az
s,t)2+|A⊥
s,t|2, where |A⊥
s,t|2≡
A+
s,tA−
s,tandσ=± represents spin ( ↑and↓correspond to +
and−, respectively). We are interested in the adiabatic limit,
FIG. 3. For uniform magnetization, the nonadiabatic components
of the gauge field A±
s,tinduce a spin flip conserving the momentum.
and so the lowest order contribution, namely, the first order, in
the perpendicular component A⊥
s,t, is sufficient. In the present
rotated-frame approach, the gauge field is treated as a staticpotential, since it already includes the time derivative to thelinear order [see Eq. ( 14)]. Moreover, the adiabatic component
of the gauge field, A
z
s,t, is neglected, as it modifies the spin
pumping only at the second order of the time derivative. Theenergy eigenvalues /epsilon1
kσ/similarequal/epsilon1k−σMare thus unaffected by the
gauge field, while the eigenstates to the linear order read
|k↑/angbracketrightF≡|k↑/angbracketright−A+
s,t
M|k↓/angbracketright,
(16)
|k↓/angbracketrightF≡|k↓/angbracketright+A−
s,t
M|k↑/angbracketright,
corresponding to the energy of /epsilon1k+and/epsilon1k−, respectively. For
low-energy transport, the states that we need to consider arethe following two, having spin-dependent Fermi wave vectorsk
Fσforσ=↑,↓, namely,
/vextendsingle/vextendsinglekF↑↑/angbracketrightbig
F=/vextendsingle/vextendsinglekF↑↑/angbracketrightbig
−A+
s,t
M/vextendsingle/vextendsinglekF↑↓/angbracketrightbig
,
/vextendsingle/vextendsinglekF↓↓/angbracketrightbig
F=/vextendsingle/vextendsinglekF↓↓/angbracketrightbig
+A−
s,t
M/vextendsingle/vextendsinglekF↓↑/angbracketrightbig
. (17)
B. Spin current induced in the normal metal
The spin pumping effect is now studied by taking account
of the interface hopping effects on the states of Eq. ( 17)t ot h e
linear order. The interface hopping amplitude of electrons inF to N with spin σis denoted by ˜t
σand the amplitude from N
to F is ˜t∗
σ. We assume that the spin dependence of the electron
state in F is governed by the relative angle to the magnetizationvector, and hence the spin σis the one in the rotated frame.
Assuming, moreover, that there is no spin-flip scattering atthe interface, the amplitude ˜t
σis diagonal in spin. (Interface
spin-orbit interaction is considered in Sec. III.) The spin-wave
function formed in the N region at the interface as a result ofthe state in F [Eq. ( 17)] is then
|k
F↑/angbracketrightN≡˜t|kF↑/angbracketright=˜t↑|kF↑/angbracketright−˜t↓A+
s,t
M|kF↓/angbracketright
|kF↓/angbracketrightN≡˜t|kF↓/angbracketright=˜t↓|kF↓/angbracketright+˜t↑A−
s,t
M|kF↑/angbracketright, (18)
064423-4CONSISTENT MICROSCOPIC ANALYSIS OF SPIN . . . PHYSICAL REVIEW B 96, 064423 (2017)
where kFis the Fermi wave vector of an N electron. The spin
density induced in N region at the interface is therefore
/tildewides(N)=1
2(N/angbracketleftkF↑|σ|kF↑/angbracketrightNν↑+N/angbracketleftkF↓|σ|kF↓/angbracketrightNν↓),(19)
where νσis the spin-dependent density of states of F electrons
at the Fermi energy. It reads
/tildewides(N)=1
2/summationdisplay
σνσTσσˆz−ν↑−ν↓
M(Re[T↑↓]A⊥
s,t
+Im[T↑↓](ˆz×A⊥
s,t)), (20)
whereA⊥
s,t=(Ax
s,t,Ay
s,t,0)=As,t−ˆzAz
s,tis the transverse
(nonadiabatic) components of spin gauge field and
Tσσ/prime≡˜t∗
σ˜tσ/prime. (21)
The spin density of Eq. ( 20) is in the rotated frame. The spin
polarization in the laboratory frame is obtained by a rotationmatrix R
ij, defined by
U−1σiU≡Rijσj, (22)
as
s(N)
i=Rij/tildewides(N)
j. (23)
Explicitly, Rij=2mimj−δij, where m≡
(sinθ
2cosφ,sinθ
2sinφ,cosθ
2)[7]. Using
Rij(A⊥
s,t)j=−1
2(n×˙n)i,
(24)
Rij(ˆz×A⊥
s,t)j=−1
2˙ni,
andRiz=ni, the induced interface spin density is finally
obtained as
s(N)=ζs
0n+Re[ζs](n×˙n)+Im[ζs]˙n, (25)
where
ζs
0≡1
2/summationdisplay
σνσTσσ,ζs≡ν↑−ν↓
2MT↑↓. (26)
Since the N electrons contributing to induced spin density
are those at the Fermi energy, the spin current is simplyproportional to the induced spin density as j
sN=kF
ms(N),
resulting in
j(N)
s=kF
mζs
0n+kF
mRe[ζs](n×˙n)+kF
mIm[ζs]˙n.(27)
This is the result of spin current at the interface. The
pumping efficiency is determined by the product of hoppingamplitudes t
↑andt∗
↓. The spin mixing conductance defined in
Ref. [ 2] corresponds to T↑↓. In the scattering approach [ 2]
based on adiabatic pumping theory [ 3–5], the expression
for the spin mixing conductance in terms of scatteringmatrix element is exact as for the adiabatic contribution. Ourresult ( 27), in contrast, is a perturbative one valid to the second
order in the hopping amplitude. To take full account of thehopping in the self-energy is possible numerically in a fieldtheoretical approach.
In bulk systems without spin-orbit interaction and magnetic
field, the hopping amplitudes t
σare chosen as real, while at
interfaces, this is not the case because inversion symmetryis broken. Nevertheless, in metallic junctions such as Cu/Co,Cr/Fe, and Au/Fe, first-principles calculations indicate thattn(t)(a)2M
tn(t)(b)
FIG. 4. Schematic figures of electron energy /epsilon1under precessing
localized spin n(t) in the adiabatic limit (a) and with nonadiabaticity
(b). Top figures represent energy levels with separation of 2 Min
the rotated frame. In the perfectly adiabatic case (a), the electronstate keeps the minimum energy state as n(t) changes. Spin pumping
does not occur in this limit. Case (b) is with nonadiabaticity taken
into account, where temporal change of localized spin ˙ninduces a
perpendicular spin polarization along n×˙n. This nonadiabatic effect
is represented by the nonadiabatic gauge field A
±
s,tand causes spin
flip in the rotated frame, leading to a high-energy state (shown in red)and spin current generation.
the imaginary part of spin mixing conductance (our ζs)i s
smaller than the real part by 1–2 orders of magnitude [ 22,23].
A large spin current proportional to ˙nwould therefore suggest
existence of strong interface spin-orbit interaction, as shall bediscussed in Sec. III.
C. Adiabatic or nonadiabatic?
In our approach, the spin pumping effect at the linear
order in time derivative is mapped to a static problem of spinpolarization formed by a static spin-mixing potential in therotated frame as was mentioned in Ref. [ 16]. The rotated-frame
approach employed here provides a clear physical picture, asit grasps the low-energy dynamics in a mathematically propermanner. In this approach, it is clearly seen that pumping ofspin current arises as a result of off-diagonal components ofthe spin gauge field that causes electron spin flip.
If so, is spin pumping an adiabatic effect or nonadiabatic
one? Conventional adiabatic processes are those where thesystem under a time-dependent external field remains to be thelowest energy state at each time [Fig. 4(a)]. In the spintronics
context, an electron passing through a thick domain wall seemsto be in the adiabatic limit in this sense; the electron spinkeeps the lowest energy state by rotating it according to themagnetization profile at each spatial point [ 7] (see Table I). In
contrast, as is seen from the above analysis, the spin pumpingeffect does not arise in the same adiabatic limit; it is inducedby the nonadiabatic (off-diagonal) spin gauge field A
±
s,t, which
changes electron spin state in the local rotated frame with acost of sdexchange energy [Fig. 4(b)]. For the spin pumping
effect, therefore, nonadiabaticity is essential, as indicated alsoin a recent full counting statistics analysis [ 24].
In spite of this fact, the spin pumping effect appears to be
treated within an adiabatic pumping theory [ 3–5]. In fact, a
nonadiabatic gauge field serves just as a driving field for spincurrent, while the pumping efficiency is determined solely by
064423-5GEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
TABLE I. Comparison of electron transmission through a domain wall and spin pumping effect. In
the figures, large arrows represent the localized spins, n, as a function of position xor time t, and the
electron spin is denoted by a small arrow with a circle. A nonadiabatic spin polarization δsinduced by the
nonadiabatic gauge field A±
s,μis essential in both cases (represented by yellow arrows).
the static (adiabatic) response of the system. This feature is the
same as the linear response theory; the response function to anexternal field can be calculated within an equilibrium scheme,although the system is out of equilibrium as a result of theexternal field. Such separation of a driving field and a responsefunction is possible only by a microscopic formulation, andhas not been clearly identified in theories so far.
A careful microscopic description indicates that a nonadi-
abaticity is essential even in the spin transfer effect. In fact,an electron spin injected into a domain wall along xdirection
gets polarized along n×∇
xnas a result of a nonadiabatic
gauge field [ 7,25]. This nonequilibrium spin polarization is
perpendicular to the wall plane, and thus induces a translationalmotion of the wall. This is the physical mechanism of spintransfer effect. At the same time, the spin transfer effect can bediscussed phenomenologically using the conservation law ofangular momentum [ 26]. One should not forget, however, that
nonadiabaticity is implicitly assumed because spin rotation iscaused only by a perpendicular component. Physically, the spinpumping effect is essentially the same as electron transmissionthrough the domain wall if we replace a spatial coordinatexand the time, as summarized in Table I. In the case of a
domain wall, including the nonadiabatic gauge field to thenext order leads to consideration of domain wall resistanceand nonadiabatic βtorque [ 27–29], while such a nonadiabatic
regime has not been explored in the context of pumping.
III. EFFECTS OF INTERFACE SPIN-ORBIT
INTERACTION
In this section, we discuss the effect of spin-orbit interaction
at the interface, which modifies hopping amplitude ˜tσ.W e
particularly focus on that linear in the wave vector, namely theinteraction represented in the continuum representation by aHamiltonian
H
so=a2δ(x)/summationdisplay
ijγijkiσj, (28)
where γijis a coefficient having the unit of energy representing
the spin-orbit interaction, ais the lattice constant, and theinterface is chosen as at x=0. Assuming that spin-orbit
interaction is weaker than the sdexchange interaction in F,
we carry out a unitary transformation to diagonalize the sd
interaction to obtain
Hso=a2δ(x)/summationdisplay
ij/tildewideγijkiσj, (29)
where/tildewideγij≡/summationtext
lγilRlj, with Rijbeing a rotation matrix
defined by Eq. ( 22). This spin-orbit interaction modifies the
diagonal hopping amplitude ˜tiin the direction iat the interface
to become a complex as
/tildewideti=˜t0
i−i/summationdisplay
j/tildewideγijσj. (30)
(In this section, we denote the total hopping amplitude
including the interface spin-orbit interaction by /tildewidetand the
one without by /tildewidet0.) We consider the hopping amplitude
perpendicular to the interface, i.e., along the xdirection, and
suppress the suffix irepresenting the direction. In the matrix
representation for spin, the hopping amplitude is
/tildewidet(≡/tildewidetx)=/parenleftBigg
/tildewidet↑/tildewidet↑↓
/tildewidet↓↑/tildewidet↓/parenrightBigg
, (31)
where
/tildewidet↑=˜t0
↑−i/tildewideγxz,/tildewidet↓=˜t0
↓+i/tildewideγxz,
/tildewidet↑↓=i(/tildewideγxx+i/tildewideγxy),/tildewidet↓↑=i(/tildewideγxx−i/tildewideγxy). (32)
Let us discuss how the spin pumping effect discussed in
Sec. II Bis modified when the hopping amplitude is a matrix
of Eq. ( 31). The spin pumping efficiency is written as in
Eqs. ( 21) and ( 26). In the absence of spin-orbit interaction, the
hopping amplitude ˜tis chosen as real, and thus the contribution
proportional to n×˙nin Eq. ( 27) is dominant. The spin-orbit
interaction enhances the other contribution proportional to ˙n
because it gives rise to an imaginary part. Moreover, it leads tospin mixing at the interface, modifying the spin accumulationformed in the N region at the interface.
064423-6CONSISTENT MICROSCOPIC ANALYSIS OF SPIN . . . PHYSICAL REVIEW B 96, 064423 (2017)
The electron states in the N region at the interface are now
given instead of Eq. ( 18) by the following two states (choosing
the basis as (|kF↑/angbracketright
|kF↓/angbracketright)):
|kF↑/angbracketrightN≡/tildewidet|kF↑↑/angbracketrightF=⎛
⎝/tildewidet↑−/tildewidet↑↓A+
s,t
M
/tildewidet↓↑−/tildewidet↓A+
s,t
M⎞
⎠,
|kF↓/angbracketrightN≡/tildewidet|kF↓↓/angbracketrightF=⎛
⎝/tildewidet↑↓+/tildewidet↑A−
s,t
M
/tildewidet↓+/tildewidet↓↑A−
s,t
M⎞
⎠. (33)
The pumped (i.e., linear in the gauge field) spin density for
these two states are
N/angbracketleftkF↑|σ|kF↑/angbracketrightN=−2
M⎛
⎜⎝A⊥
s,tRe[Ttot
↑↓]+(ˆz×A⊥
s,t)Im[Ttot
↑↓]
+Re[(/tildewidet↑↓)∗/tildewidet↓↑]⎛
⎜⎝Ax
s,t
−Ay
s,t
0⎞
⎟⎠
+Im[(/tildewidet↑↓)∗/tildewidet↓↑]⎛
⎝Ay
s,t
Ax
s,t
0⎞
⎠⎞
⎠
−ˆz/parenleftbig
Ax
s,tRe[(/tildewidet↑)∗/tildewidet↑↓−/tildewidet↓(/tildewidet↓↑)∗]
−Ay
s,tIm[(/tildewidet↑)∗/tildewidet↑↓−/tildewidet↓(/tildewidet↓↑)∗]/parenrightbig
, (34)
N/angbracketleftkF↓|σ|kF↓/angbracketrightN=2
M⎛
⎜⎝A⊥
s,tRe[Ttot
↑↓]+(ˆz×A⊥
s,t)Im[Ttot
↑↓]
+Re[(/tildewidet↑↓)∗/tildewidet↓↑]⎛
⎜⎝Ax
s,t
−Ay
s,t
0⎞
⎟⎠
+Im[(/tildewidet↑↓)∗/tildewidet↓↑]⎛
⎝Ay
s,t
Ax
s,t
0⎞
⎠⎞
⎠
+ˆz/parenleftbig
Ax
s,tRe[(/tildewidet↑)∗/tildewidet↑↓−/tildewidet↓(/tildewidet↓↑)∗]
−Ay
s,tIm[(/tildewidet↑)∗/tildewidet↑↓−/tildewidet↓(/tildewidet↓↑)∗]/parenrightbig
. (35)
We here focus on the linear effect of interface spin-
orbit interaction and neglect the spin polarization along themagnetization direction, n. The expression for the pumped
spin current then agrees with Eq. ( 27) with the amplitude ζ
s
written in terms of hopping including the interface spin orbit,
T↑↓=((˜t0
↑)∗+i(/tildewideγxz)∗)(˜t0
↓+i/tildewideγxz). (36)
In metallic junctions of Cu/Co, Cr/Fe, and Au/Fe, Im[ T↑↓]i s
orders of magnitude smaller than Re[ T↑↓][22,23], suggesting
that the imaginary part of bare hopping amplitude ˜t0
σis small.
According to Eq. ( 36), large Im[ T↑↓] is expected if strong
interface spin-orbit interaction exist. If the imaginary part of˜t0
σis neglected, we obtain (using /tildewideγxz=niγxi)
Im[ζs]=ν↑−ν↓
2M(˜t0
↑+˜t0
↓)γxini. (37)
The measurement of the amplitude of the spin current is
proportional to ˙n, thus, it works as a probe for the interface
spin-orbit interaction strength γxi.
Let us discuss some examples. Of recent particular interest
is the interface Rashba interaction, represented by the anti-symmetric coefficient
γ(R)
ij=/epsilon1ijkαR
k, (38)
where αRis a vector representing the Rashba field. In the
case of an interface, αRis perpendicular to the interface, i.e.,
αR/bardblˆx. Therefore the interface Rashba interaction leads to
γ(R)
xj=0 and does not modify the spin pumping effect at the
linear order. (It contributes at the second order as discussedin Ref. [ 15].) In other words, the vector coupling between the
wave vector and spin in the form of k×σexists only along
thexdirection, and does not affect the interface hopping (i.e.,
does not include k
x).
In contrast, a scalar coupling η(D)(k·σ)(η(D)is a coef-
ficient), called the Dirac type spin-orbit interaction, leads to
γ(D)
ij=η(D)δij. The spin current along ˙nthen reads
j˙n
s=η(D)kF(ν↑−ν↓)
2mM(˜t0
↑+˜t0
↓)nx˙n. (39)
For the case of in-plane easy axis along the zdi-
rection and magnetization precession given by n(t)=
(sinθcosωt,sinθsinωt,cosθ), where θis the precession
angle and ωis the angular frequency, we expect to have a
dc spin current along the ydirection, as nx˙n=−ω
2sin2θˆy
(nx˙ndenotes time average).
Recently, spin pumping effects are discussed including
a phenomenological “spin-memory loss” parameter δsml,t o
represent the interface spin-flip rate [ 30,31]. The parameter
corresponds roughly to δsml=|/tildewidet↑↓|2/(|/tildewidet↑|2+|/tildewidet↓|2) in our
scheme [see Eq. ( 31)].
IV . FIELD THEORETIC DESCRIPTION
OF METALLIC CASE
Here we present a field-theoretic description of the spin
pumping effect of a metallic ferromagnet. The many-bodyapproach has an advantage of taking into account the particledistributions automatically. Moreover, it describes the propa-gation of particle density in terms of the Green’s functions,and thus is suitable for studying spatial propagation as wellas for intuitive understanding of transport phenomena. All thetransport coefficients are determined by material constants.
The formalism presented here is essentially the same as
in Ref. [ 16], but treats ferromagnets of finite size and takes
account of electron states with different wave vectors. Interfacespin-orbit interaction is not considered here.
Conduction electrons in ferromagnetic and normal metals
are denoted by field operators d,d
†andc,c†, respectively.
These operators are vectors with two spin components, i.e.,d≡(d
↑,d↓). The Hamiltonian describing the F and N electrons
064423-7GEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
t
rr1
r2
Ga
NGr
N
r4r3 G<
(a)
rr1
r2Ga
NGr
N
Σ<
(b)t
Ga
NGr
N G<
(c)r
FIG. 5. (a) Schematic diagrammatic representations of the lesser Green’s function for an N electron connecting the same position r,
G<
N(r,r)/similarequalGr
N/Sigma1<
NGa
Nrepresenting the propagation of electron density. It is decomposed into a propagation of N electrons from rto the
interface at r2, then hopping to r4in the F side, a propagation inside F, followed by a hopping to N side (to r1) and propagation back to r.
[Position labels are as in Eqs. ( 43)a n d( 44).] (b): The self-energy /Sigma1<
Nrepresents all the effects of the ferromagnet. (c) Standard Feynman
diagram representation of lesser Green’s function for N at r,E q s .( 46)a n d( 44).
isHF+HN, where
HF≡/integraldisplay
Fd3rd†/parenleftbigg
−∇2
2m−/epsilon1F−Mn(t)·σ/parenrightbigg
d,
HN≡/integraldisplay
Nd3rc†/parenleftbigg
−∇2
2m−/epsilon1F/parenrightbigg
c. (40)
We set the Fermi energies for the ferromagnet and the normal
metal equal. The hopping through the interface is described bythe Hamiltonian
H
I≡/integraldisplay
IFd3r/integraldisplay
INd3r/prime(c†(r/prime)t(r/prime,r,t)d(r)
+d†(r)t∗(r/prime,r,t)c(r/prime)), (41)
where t(r/prime,r,t) represents the hopping amplitude of electrons
from rin the ferromagnetic regime to a site r/primein the normal
region and the integrals are over the interface (denoted by I F
and I Nfor F and N regions, respectively). The hopping ampli-
tude is generally a matrix that depends on the magnetizationdirection n(t), and thus depends on time t. Hopping is treated
as energy conserving. Assuming a sharp interface at x=0,
the momentum perpendicular to the interface is not conservedon hopping.
We are interested in the spin current in the normal region,
given by
j
α
s,i(r,t)=−1
4m(∇(r)−∇(r/prime))itr[σαG<
N(r,t,r/prime,t)|r/prime=r,(42)
where G<
N(r,t,r/prime,t/prime)≡i/angbracketleftc(r,t)c†(r/prime,t/prime)/angbracketrightdenotes the lesser
Green’s function for the normal region. It is calculated from
the Dyson’s equation for the path-ordered Green’s function
defined for a complex time along a complex contour C:
GN(r,t,r/prime,t/prime)=gN(r−r/prime,t−t/prime)+/integraldisplay
cdt1/integraldisplay
cdt2/integraldisplay
d3r1
×/integraldisplay
d3r2gN(r−r1,t−t1)
×/Sigma1N(r1,t1,r2,t2)GN(r2,t2,r/prime,t/prime),(43)
where g<
Ndenotes the Green’s function without interface
hopping and /Sigma1N(r1,t1,r2,t2) is the self-energy for N elec-
trons, given by the contour-ordered Green’s function in theferromagnet as
/Sigma1N(r1,t1,r2,t2)≡/integraldisplay
IFd3r3/integraldisplay
IFd3r4t(r1,r3,t1)
×G(r3,t1,r4,t2)t∗(r2,r4,t2).(44)
Here, r1andr2are coordinates at the interface I Nin N region
andr3andr4a r et h o s ei nI Ffor F. Gis the contour-ordered
Green’s function for F electrons in the laboratory frame
including the effect of spin gauge field. We denote the Green’sfunctions of F electrons by Gandgwithout suffix and those
of N electrons with suffix N. The lesser component of thenormal metal Green’s function is obtained from Eq. ( 43)a s
(suppressing the time and space coordinates)
G
<
N=/parenleftbig
1+Gr
N/Sigma1r
N/parenrightbig
g<
N/parenleftbig
1+/Sigma1a
NGaN/parenrightbig
+Gr
N/Sigma1<
NGaN.(45)
For pumping effects, the last term on the right-hand side is
essential, as it contains the information of excitations in Fregion [ 16]. We thus consider the second term only,
G
<
N/similarequalGr
N/Sigma1<
NGaN, (46)
and neglect the spin dependence of the normal region Green’s
functions, Gr
NandGa
N. The contribution is diagrammatically
shown in Fig. 5.
A. Rotated frame
To solve for the Green’s function in the ferromagnet, it is
convenient to use the rotated frame we used in Sec. II A.I nt h e
field representation, the unitary transformation is representedas [Fig. 6(c)]
d=U˜d, c=U˜c, (47)
FNdct
t∗
(a)
FNd cUt
t∗U−1
(b)
FNd ct
t∗
(c)
FIG. 6. Unitary transformation Uof F electrons converts the
original system with field operator d[shown as (a)] to the rotated
one with field operator ˜d≡U−1d(b). The hopping amplitude for
representation in (b) is modified by U. If N electrons are also rotated
as˜c≡U−1c, hopping becomes ˜t≡U−1tU, while the N electron spin
rotates with time, as shown as (c).
064423-8CONSISTENT MICROSCOPIC ANALYSIS OF SPIN . . . PHYSICAL REVIEW B 96, 064423 (2017)
where Uis the same 2 ×2 matrix defined in Eq. ( 10). We
rotate N electrons as well as F electrons, to simplify thefollowing expressions. The hopping interaction Hamiltonianreads
H
I=/integraldisplay
IFd3r/integraldisplay
INd3r/prime(˜c†(r/prime)˜t(r/prime,r)˜d(r)
+˜d†(r)˜t∗(r/prime,r)˜c(r/prime)), (48)
where
˜t(r/prime,r)≡U†(t)t(r/prime,r,t)U(t) (49)
is the hopping amplitude in the rotated frame. The rotated am-
plitude (neglecting interface spin-orbit interaction) is diagonalin spin:
˜t=/parenleftbigg˜t
↑0
0 ˜t↓/parenrightbigg
. (50)
Including the interaction with a spin gauge field, the Hamil-
tonian for F and N electrons in the momentum representationis
H
F+HN=/summationdisplay
k˜d†
k/parenleftBigg
/epsilon1k−M−Az
s,t A−
s,t
A+
s,t /epsilon1k+M+Az
s,t/parenrightBigg
˜dk
+/summationdisplay
k/epsilon1(N)
k˜c†
k˜ck. (51)
As for the hopping, we consider the case the interface is
atomically sharp. The hopping Hamiltonian is then writtenin the momentum space as
H
I=/summationdisplay
kk/prime(˜c†(k)˜t(k,k/prime)˜d(k/prime)+˜d†(k/prime)˜t∗(k,k/prime)˜c(k)),(52)
where k=(kx,ky,kz),k/prime=(k/prime
x,ky,kz), choosing the interface
as the plane of x=0. Namely, the wave vectors parallel to the
interface are conserved while kxandk/prime
xare uncorrelated.
B. Spin polarization and current in N
Pumped spin current in N is calculated by using Eqs. ( 42)
and ( 46). The lesser component of the self-energy connecting
Green’s functions with wave vectors kandk/primeis written using
Eq. ( 44) as (in the matrix notation)
/Sigma1<
N(k,k/prime)=/summationdisplay
k/prime/prime˜t(k,k/prime/prime)G<(k/prime/prime)˜t∗(k/prime/prime,k/prime). (53)
The lesser Green’s function in F in the rotated frame is
calculated including the spin gauge field (a driving field of spinpumping) to the linear order by use of the Dyson’s equation
G
<=g<+gr(As,t·σ)g<+g<(As,t·σ)ga, (54)
where gα(α=<,r,a) represents Green’s functions without
a spin gauge field. The lesser Green’s function satisfies
for static case g<=F(ga−gr), where F≡(f↑ 0
0f↓)i st h e
spin-dependent Fermi distribution function. We thus obtain
the Green’s function at the linear order, written as δG<,as [16]
δG<=gr[As,t·σ,F]ga+gaF(As,t·σ)ga
−gr(As,t·σ)Fgr. (55)
The last two terms of the right-hand side are rapidly oscillating
as a function of position and are neglected. The commutatoris calculated as (sign ±denotes spin ↑and↓)
[A
s,t·σ,F]=(f+−f−)/summationdisplay
±(±)A±
s,tσ∓. (56)
The self-energy linear in the spin gauge field is thus
/Sigma1<
N(k,k/prime)=/summationdisplay
±σ∓/summationdisplay
k/prime/prime(fk/prime/prime±−fk/prime/prime∓)A±
s,t˜t∓(k,k/prime/prime)
טt∗
±(k/prime/prime,k/prime)gr
∓(k/prime/prime,ω)ga
±(k/prime/prime,ω). (57)
The spin polarization of an N electron therefore reads (diagram
shown in Fig. 7)
−itr[σ±G<
N(r,t,r/prime,t)]
=−i/summationdisplay
kk/primek/prime/primeeik·re−ik/prime·r/primegr
N(k,ω)ga
N(k/prime,ω)(fk/prime/prime±−fk/prime/prime∓)
×A±
s,t˜t∓(k,k/prime/prime)˜t∗
±(k/prime/prime,k/prime)gr
∓(k/prime/prime,ω)ga
±(k/prime/prime,ω). (58)
We assume that the dependence of N Green’s functions on
ωis weak and use/summationtext
keik·rgr
N(k,ω)=−iπν NeikFxe−|x|//lscript≡
gr
N(r), where /lscriptis the elastic mean free path, νNandkFare the
density of states at the Fermi energy and Fermi wave vector,respectively, whose ωdependencies are neglected. (For an
infinitely wide interface, the Green’s function becomes onedimensional.) As a result of summation over wave vectors, theproduct of hopping amplitudes ˜t
∓(k,k/prime/prime)˜t∗
±(k/prime/prime,k/prime) is replaced
by the average over the Fermi surface, ˜t∓˜t∗
±≡T±∓, i.e.,
˜t∓(k,k/prime/prime)˜t∗
±(k/prime/prime,k/prime)→T±∓. (59)
The spin polarization of N electrons induced by magnetization
dynamics (the spin gauge field) is therefore obtained in therotated frame as [with correlation function χ
±defined in
Eq. ( A5)]
˜s(N)
±(r,t)=−/vextendsingle/vextendsinglegr
N(r)/vextendsingle/vextendsingle2/summationdisplay
±A±
s,tχ±T±∓, (60)
A±s,tgr∓
ga±˜s(N)
±grN
gaN˜t∓
˜t∗±
FIG. 7. Feynman diagram for electron spin density of normal
metal driven by the spin gauge field of ferromagnetic metal As.T h e
spin current is represented by the same diagram but with spin currentvertex.
064423-9GEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
or using χ∗
+=χ−,
˜s(N)(r,t)=−2/vextendsingle/vextendsinglegr
N(r)/vextendsingle/vextendsingle2[A⊥
s,tRe[χ+T+−]
+(ˆz×A⊥
s,t)Im[χ+T+−]]. (61)
In the laboratory frame, we have (using s(N)
i=Rij˜s(N)
j)
s(N)(r,t)=/vextendsingle/vextendsinglegr
N(r)/vextendsingle/vextendsingle2[Re[χ+T+−](n×˙n)+Im[χ+T+−]˙n].
(62)
The spin current induced in N region is similarly given by
(neglecting the contribution proportional to n)
js(r,t)=kF
m/vextendsingle/vextendsinglegr
N(r)/vextendsingle/vextendsingle2[Re[χ+T+−](n×˙n)+Im[χ+T+−]˙n]
=e−|x|//lscript(Re[ζs](n×˙n)+Im[ζs]˙n), (63)
where
ζs≡π2kFν2
N
2mM(n+−n−)T+−. (64)
The coefficient ζsis essentially the same as the one in Eq. ( 27)
derived by a quantum mechanical argument, as the quantummechanical dimensionless hopping amplitude corresponds toν
N˜tof the field representation.
For a 3 dferromagnet, we may estimate the spin current
by approximating roughly M∼1/νN∼/epsilon1F∼1 eV and nσ∼
kF3. The hopping amplitude |T+−|in the metallic case would
be of order of /epsilon1F. The spin current density then is of the order of
(including electric charge eand recovering ¯ h)js∼e¯hkF
mh¯hω
/epsilon1F∼
5×1011A/m2if the precession frequency is 10 GHz.
V . SPIN ACCUMULATION IN FERROMAGNET
The spin current pumping is equivalent to the increase
of spin damping due to magnetization precession, as wasdiscussed in Refs. [ 2,11]. In this section, we confirm this fact by
calculating the torque by evaluating the spin polarization of theconduction electron spin in F region. (The spin accumulationwithout taking into account an interface is calculated inAppendix A.)
There are several ways to evaluate the damping of magneti-
zation. One way is to calculate the spin-flip probability of theelectron as in Ref. [ 11], which leads to damping of localized
spin in the presence of strong sdexchange interaction. The
second is to estimate the torque on the electron by use of the
equation of motion [ 32]. The relation between the damping
and spin current generation is clearly seen in this approach.In fact, the total torque acting on conduction electrons is (¯ h
times) the time derivative of the electron spin density,
ds
dt=i(/angbracketleft[H,d†]σd/angbracketright+/angbracketleftd†σ[H,d]/angbracketright). (65)
At the interface, the right-hand side arises from the interface
hopping. Using the hopping Hamiltonian of Eq. ( 41), we have
ds
dt/vextendsingle/vextendsingle/vextendsingle/vextendsingle
interface=i(/angbracketleftc†tσd/angbracketright−/angbracketleftd†σt†c/angbracketright), (66)
as the interface contribution. As is natural, the right-hand
side agrees with the definition of the spin current passingthrough the interface. Evaluating the right-hand side, we obtainin general a term proportional to n×˙n, which gives the
Gilbert damping, and a term proportional to ˙n, which gives
a renormalization of the magnetization. In contrast, awayfrom the interface, the commutator [ H,d] arises from the
kinetic term H
0≡/integraltext
d3r|∇d|2
2mdescribing electron propagation,
resulting in
dsα
dt=i(/angbracketleft[H0,d†]σd/angbracketright+/angbracketleftd†σ[H,d]/angbracketright)
=∇· jα
s, (67)
where jα
s(r)≡−i
2m(∇r−∇ r/prime)/angbracketleftd†(r/prime)σαd(r)/angbracketright|r/prime=ris the spin
current. Away from the interface, the damping therefore occurs
if the spin current has a source or a sink at the site of interest.
Here we use the third approach and estimate the torque
on the localized spin by calculating the spin polarizationof electrons as was done in Refs. [ 7,33]. The electron spin
polarization at position rin the ferromagnet at time tis
s
(F)(r,t)≡/angbracketleftd†σd/angbracketright, which reads in the rotated frame s(F)
α=
Rαβ˜s(F)
β, where
˜s(F)
β(r,t)=−itr[σβG<(r,r,t,t)], (68)
where G<
σσ/prime(r,r/prime,t,t/prime)≡i/angbracketleft˜d†
σ/prime˜dσ/angbracketrightis the lesser Green’s function
in F region, which is a matrix in spin space ( σ,σ/prime=±).
We are interested in the effect of the N region arising fromthe hopping. We must note that the hopping interaction ofEq. ( 48) is not convenient for integrating out N electrons,
since the ˜celectrons’ spins are time-dependent as a result of a
unitary transformation U(t). We thus use the following form
[Fig. 6(b)],
H
I=/integraldisplay
IFd3r/integraldisplay
INd3r/prime(c†(r/prime)U˜t(r/prime,r)˜d(r)
+˜d†(r)˜t∗(r/prime,r)U†c(r/prime)), (69)
namely, the hopping amplitude between ˜dandcelectrons
includes the unitary matrix U.
Let us briefly argue in the rotated frame why the effect
of damping arising from the interface. In the totally rotatedframe of Fig. 6(c), the spin of an F electron is static, while
that of N electron varies with time. When an F electron hopsto N region and comes back, therefore, the electron spin getsrotated with the amount depending on the time it stayed in Nregion. This effect is in fact represented by a retardation effectof the matrices UandU
−1in Eq. ( 69). If the off-diagonal
nature of UandU−1is neglected, the interface effects are all
spin-conserving and do not induce damping for F electrons(see Appendix B).
The spin density is calculated by evaluating the lesser
Green’s function in F. Including the effect of interface in termsof self-energy, it reads
G
<(r,t,r/prime,t)=gr/Sigma1rga+gr/Sigma1<ga+g</Sigma1aga, (70)
where the self-energy of an F electron arising from the hopping
to N region reads ( r1andr2are in F and a=r,a,<)
/Sigma1a(r1,r2,t1,t2)=/integraldisplay
INd3r/prime
1/integraldisplay
INd3r/prime
2˜t(r1,r/prime
1)U−1(t1)
×ga
N(r/prime
1,r/prime
2,t1−t2)U(t2)˜t†(r2,r/prime
2).(71)
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˜tU−1
gN
U˜t∗σg˜t
gN
˜t∗σgAs,t
˜s(F)==
FIG. 8. Diagrammatic representation of the spin accumulation in
a ferromagnetic metal induced as a result of coupling to the normal
metal [Eqs. ( 68)a n d( C1)]. Conduction electron Green’s functions in
a ferromagnet and normal metal are denoted by gandgN, respectively.
Time-dependent matrix U(t), defined by Eq. ( 10), represents the effect
of dynamic magnetization. Expanding UandU−1with respect to the
slow time dependence of magnetization, we obtain a gauge field
representation, see Eq. ( C3).
Expanding to the linear order in the spin gauge field arising
from the time dependence of unitary matrix U, we obtain
G<(r,t,r/prime,t)=2πiν Na2/integraldisplaydω
2πf/prime
N(ω)gr(r,ω)
טtAs,t˜t†ga(−r,ω). (72)
(Diagrammatic representation of the contribution is in Fig. 8.
For calculation detail, see Appendix C). For damping, off-
diagonal contributions, A±
s,t, are obviously essential. The result
of the spin density in F in the rotated frame, Eq. ( 68), is
therefore
˜s(F)
α(r,t)=2πiν Na2/integraldisplaydω
2πf/prime
N(ω)Aβ
s,ttr[σαgr(r,ω)
טtσβ˜t†ga(−r,ω)]
=2πiν Na2/integraldisplaydω
2πf/prime
N(ω)Aβ
s,t/summationdisplay
kk/primeei(k−k/prime)·r
×tr[σαgr(k,ω)˜tσβ˜t†ga(k/prime,ω)]. (73)
Evaluating the trace in spin space, we obtain
˜s(F)(r,t)=−νN[A⊥
s,tγ1(r)+(ˆz×A⊥
s,t)γ2(r)], (74)
where
γ1(r)≡/summationdisplay
σ˜t−σ˜t†
σgr
−σ(r)ga
σ(−r),
γ2(r)≡/summationdisplay
σ(−iσ)˜t−σ˜t†
σgr
−σ(r)ga
σ(−r). (75)
We consider an interface with infinite area and consider spin
accumulation averaged over the plane parallel to the interface.The wave vectors contributing are then those with finite k
x
but with ky=kz=0 and the Green’s function becomes one-
dimensional-like:
/summationdisplay
keik·rgr
σ(k)=im
kFσeikFσ|x|e−|x|/(2/lscriptσ), (76)
where /lscriptσ≡vFστσ(vFσ≡kFσ/m) is the electron mean free
path for spin σ. The induced spin density in the ferromagnetis finally obtained from Eq. ( 74)a s
s(F)(r,t)=m2νNa2
2kF+kF−/summationdisplay
σ[(n×˙n)Tσ,−σe−iσ(kF+−kF−)x
+˙n(−iσ)Tσ,−σe−iσ(kF+−kF−)x]
=m2νNa2
2kF+kF−/summationdisplay
σ{(n×˙n)[Re[T↑,↓] cos(( kF+−kF−)
×x)+Im[T↑,↓]s i n ( (kF+−kF−)x)]
+˙n[Im[T↑,↓] cos(( kF+−kF−)x)
−Re[T↑,↓]s i n ( (kF+−kF−)x)]} (77)
and the torque on the localized spin −Mn×s(F)is
τ(r,t)=−m2νNa2M
2kF+kF−/summationdisplay
σ{−˙n[Re[T↑,↓] cos(( kF+−kF−)x)
+Im[T↑,↓]s i n ( (kF+−kF−)x)]
+(n×˙n)[Im[T↑,↓] cos(( kF+−kF−)x)
−Re[T↑,↓]s i n ( (kF+−kF−)x)]}. (78)
A. Enhanced damping and spin renormalization
of ferromagnetic metal
The total induced spin accumulation density in a ferromag-
net is
s(F)≡1
d/integraldisplay0
−ddxs(F)(x)
=1
M{(n×˙n)[−Im[δ](1−cos˜d)+Re[δ]s i n ˜d]
+˙n[Re[δ](1−cos˜d)+Im[δ]s i n ˜d]}, (79)
where ˜d≡(kF+−kF−)d,dis the thickness of the ferromagnet
and
δ≡m2νNa2M
kF+kF−(kF+−kF−)dT↑,↓. (80)
As a result of this induced electron spin density, s(F),t h e
equation of motion for the averaged magnetization is modifiedto be [ 11]
˙n=−αn×˙n−γB×n−Mn×
s(F), (81)
where Bis the external magnetic field.
Let us first discuss the thick ferromagnet case, d/greatermuch
|kF+−kF−|−1, where the oscillating part with respect
to˜dis neglected. The spin density then reads s(F)/similarequal
1
M(−Im[δ](n×˙n)+Re[δ]˙n) and the equation of motion
becomes
(1+Imδ)˙n=− ˜αn×˙n−γB×n, (82)
where
˜α≡α+Reδ, (83)
is the Gilbert damping including the enhancement due to the
spin pumping effect. The precession angular frequency ωBis
modified by the imaginary part of T↑,↓, i.e., by the spin current
064423-11GEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
proportional to ˙n,a s
ωB=γB
1+Imδ. (84)
This is equivalent to the modification of the gyromagnetic ratio
(γ)o rt h e gfactor.
For most 3D ferromagnets, we may approximate
m2νNaM/epsilon1 F2
2kF+kF−(kF+−kF−)/similarequalO(1) (as kF+−kF−∝M), resulting in
δ∼a
dT↑,↓. As discussed in Sec. III, when the interface
spin-orbit interaction is taken into account, we have T↑,↓=
˜t0
↑˜t0
↓+i/tildewideγxz(˜t0
↑+˜t0
↓)+O((/tildewideγ)2), where ˜t0
σand/tildewideγxzare assumed
to be real. Moreover, ˜t0
σcan be chosen as positive and thus
T↑,↓>0. (˜t0
σhere is field representation, and has unit of
energy.) Equations ( 83) and ( 84) indicate that the strength of
the hopping amplitude ˜t0
σand interface spin-orbit interaction
/tildewideγxzare experimentally accessible by measuring the Gilbert
damping and shift of resonance frequency as has beenknown [ 2]. A significant consequence of Eq. ( 83) is that the
enhancement of the Gilbert damping,
δα∼a
d1
/epsilon1F2˜t0
↑˜t0
↓, (85)
can exceed in thin ferromagnets the intrinsic damping pa-
rameter α, as the two contributions are governed by different
material parameters. In contrast to the positive enhancementof damping, the shift of the resonant frequency or gfactor can
be positive or negative, as it is linear in the interface spin-orbitparameter/tildewideγ
xz.
Experimentally, the enhancement of the Gilbert damping
and frequency shift has been measured in many systems [ 12].
In the case of Ni 80Fe20(Py)/Pt junction, the enhancement of
damping is observed to be proportional to 1 /din the range of
2n m<d< 10 nm, and the enhancement was large, δα/α/similarequal4
atd=2n m[ 12]. These results appears to be consistent with
our analysis. Same 1 /ddependence was observed in the shift
of the gfactor. The shift was positive and the magnitude is
about 2% for Py/Pt and Py/Pd with d=2nm, while it was
negative for Ta/Pt [ 12]. The existence of both signs suggests
that the shift is due to the linear effect of spin-orbit interaction,and the interface spin-orbit interaction we discuss is one of thepossible mechanisms.
For thin ferromagnet, ˜d/lessorsimilar1, the spin accumulation of
Eq. ( 79) reads
s(F)=1
M((n×˙n)Re[δthin]+˙nIm[δthin]), (86)
where
δthin≡δ˜d=m2νNa2M
2kF+kF−T↑,↓. (87)
Equation ( 86) indicates that the roles of imaginary and real
part of T↑,↓are interchanged for thick and thin ferromagnets,
resulting in
˜α=α+Imδthin,ω B=γB
1−Reδthin, (88)
for thin ferromagnets. Thus, for weak interface spin-orbit inter-
action, a positive shift of the resonance frequency is expected(as Re δ
thin>0). A significant feature is that the damping
can be decreased or even become negative if strong interfacespin-orbit interaction exists with a negative sign of Im δthin.O u r
result indicates that the “spin mixing conductance” descriptionof Ref. [ 2] breaks down in thin metallic ferromagnets (and the
insulator case as we shall see in Sec. VII D ).
In this section, we have discussed spin accumulation and
enhanced Gilbert damping in a ferromagnet attached to anormal metal. In the field-theoretic description, the dampingenhancement arises from the imaginary part of the self-energydue to the interface. Thus a randomness like the interfacescattering changing the electron momentum is essential forthe damping effect, which sounds physically reasonable.The same is true for the reaction, namely, the spin currentpumping effect into the N region, and thus the spin currentpumping requires randomness too. (In the quantum mechanicaltreatment of Sec. II, change of electron wave vector at
the interface is essential.) The spin current pumping effecttherefore appears different from general pumping effects,where randomness does not play essential roles apparently[3].
The spin accumulation and enhanced Gilbert damping was
discussed by Berger [ 11] based on a quantum mechanical
argument. There, 1 /ddependence was pointed out and the
damping effect was calculated by evaluating the decay rateof magnons. A comparison of enhanced Gilbert dampingwith experiments was carried out in Ref. [ 2]b u ti na
phenomenological manner.
VI. CASE WITH MAGNETIZATION STRUCTURE
The field theoretic approach has an advantage that the
generalization of the results is straightforward. Here wediscuss briefly the case of a ferromagnet with spatially varyingmagnetization. The excitations in a metallic ferromagnetconsist of spin waves (magnons) and Stoner excitation. Whilespin waves usually have a gap as a result of magneticanisotropy, Stoner excitation is gapless for a finite wave vector,(k
F+−kF−)<|q|<(kF++kF−), and it may be expected
to have significant contribution for magnetization structureshaving wavelength larger than k
F+−kF−. Let us look into
this possibility.
Our result of spin accumulation in a ferromagnet, repre-
sented in the rotated frame, Eq. ( A3), indicates that when
the magnetization has a spatial profile, the accumulationis determined by the spin gauge field and spin correlationfunction depending on the wave vector qas
/summationdisplay
qA±
s,t(q)χ±(q,0), (89)
where
χ±(q,/Omega1)≡−/summationdisplay
kfk+q,±−fk,∓
/epsilon1k+q,±−/epsilon1k,∓+/Omega1+i0(90)
is the correlation function with finite momentum transfer
qand finite angular frequency /Omega1. For the case of free
electron with quadratic dispersion, the correlation functionis [34]
χ
±(q,/Omega1)=Aq+i/Omega1B qθst(q)+O(/Omega12), (91)
064423-12CONSISTENT MICROSCOPIC ANALYSIS OF SPIN . . . PHYSICAL REVIEW B 96, 064423 (2017)
where
Aq=ma3
8π2/bracketleftbigg
(kF++kF−)/parenleftbigg
1+(kF+−kF−)2
q2/parenrightbigg
+1
2q3((kF++kF−)2−q2)(q2−(kF+−kF−)2)
×ln/vextendsingle/vextendsingle/vextendsingle/vextendsingleq+(kF++kF−)
q−(kF++kF−)/vextendsingle/vextendsingle/vextendsingle/vextendsingle/bracketrightbigg
,
Bq=m2a3
4π|q|, (92)
and
θst(q)≡/braceleftbigg1(kF+−kF−)<|q|<(kF++kF−)
0 otherwise,(93)
describes the wave vectors where Stoner excitation exists.
As we see from Eq. ( 91), the Stoner excitation contribution
vanishes to the lowest order in /Omega1, and thus the spin pumping
effect in the adiabatic limit ( /Omega1→0) is not affected. Moreover,
the real part of the correlation function, Aq, is a decreasing
function of qand thus the spin pumping efficiency would
decrease when the ferromagnet has a structure. However, forrigorous argument, we need to include the spatial componentof the spin gauge field arising form the spatial derivative of themagnetization profile.
As for the effect of the Stoner excitation on spin damping
(Gilbert damping), it was demonstrated for the case of adomain wall that the effect is negligibly small for a wide wallwith thickness λ/greatermuch(k
F+−kF−)−1(Refs. [ 34,35]). Simanek
and Heinrich presented a result of the Gilbert damping as thelinear term in the frequency of the imaginary part of the spincorrelation function integrated over the wave vector [ 13]. The
result is, however, obtained for a model where the ferromagnetis an atomically thin layer (a sheet), and would not beapplicable for most experimental situations. A discussion ofthe Gilbert damping including a finite wave vector and theimpurity scattering was given in Ref. [ 36]. Inhomogeneity
effects of damping of a domain wall were studied recentlyin detail [ 37]. The effective Gilbert damping constant in
the presence of a domain wall was numerically studied inRefs. [ 38,39]. A quadratic dependence on the inverse of the
wall thickness appears to be consistent with the quadraticbehavior of A
qat small q, while the linear behavior found
for an out-of-plane extremely narrow wall [ 39] seems not to
be covered by the simple argument here.
VII. INSULATOR FERROMAGNET
In this section, we discuss the case of a ferromagnetic
insulator. It turns out that the generation mechanisms for spincurrent in the insulating and metallic cases are distinct.
A. Magnon and adiabatic gauge field
The Lagrangian for the insulating ferromagnet is
LIF=/integraldisplay
d3r/bracketleftbigg
S˙φ(cosθ−1)−J
2(∇S)2/bracketrightbigg
−HK, (94)
where Jis the exchange interaction between the localized spin
SandHKdenotes the magnetic anisotropy energy.We first study low-energy magnon dynamics induced by
slow magnetization dynamics. For separating the classicalvariable and fluctuation (magnon), the rotated coordinatedescription used in the metallic case is convenient. Formagnons described by the Holstein-Primakov boson, the uni-tary transformation is a 3 ×3 matrix defined as follows [ 40]:
S=U/tildewideS, (95)
where
U=⎛
⎝cosθcosφ−sinφsinθcosφ
cosθsinφ cosφ sinθsinφ
−sinθ 0 cos θ⎞
⎠
=/parenleftbige
θeφn/parenrightbig
. (96)
The diagonalized spin /tildewideSis represented in terms of annihilation
and creation operators for the Holstein-Primakov boson, band
b†,a s[ 41]
/tildewideS=⎛
⎜⎜⎝/radicalBig
S
2(b†+b)
i/radicalBig
S
2(b†−b)
S−b†b⎞
⎟⎟⎠. (97)
We neglect the terms that are third- and higher-order in boson
operators. Derivatives of the localized spin then read
∂μS=U(∂μ+iAU,μ)/tildewideS, (98)
where
AU,μ≡−iU−1∇μU (99)
is the spin gauge field represented as a 3 ×3 matrix. The spin
Berry’s phase of the Lagrangian ( 94) is written in terms of
magnons as (derivation is in Appendix D)
Lm=2Sγ2/integraldisplay
d3ri/bracketleftbig
b†/parenleftbig
∂t+iAz
s,t/parenrightbig
b−b†/parenleftbig←
∂t−iAz
s,t/parenrightbig/parenrightbig
b/bracketrightbig
,
(100)
namely, the magnons interact with the adiabatic component
of the same spin gauge field for electrons, Az
s,t, defined in
Eq. ( 14). As the magnon is a single-component field, the
gauge field is also single-component, i.e., a U(1) gauge field.This is a significant difference between insulating and metallicferromagnets; in the metallic case, a conduction electroncouples to an SU(2) gauge field with spin-flip components,which turned out to be essential for spin current generation. Incontrast, in the insulating case, the magnon has a diagonalgauge field, i.e., a spin chemical potential, which simplyinduces diagonal spin polarization. Pumping of magnon wasdiscussed in a different approach by evaluating the magnonsource term in Ref. [ 42].
The exchange interaction at the interface is represented by
a Hamiltonian
H
I=JI/integraldisplay
d3rIS(r)·c†σc, (101)
where JIis the strength of the interface sdexchange interaction
and the integral is over the interface. We consider a sharp in-terface at x=0. Using Eq. ( 95), the interaction is represented
064423-13GEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
in terms of magnon operators up to the second order as
HI=JI/integraldisplay
d3rI/braceleftbig
(S−b†b)c†(n·σ)c
+/radicalbigg
S
2[b†c†/Phi1·σc+bc†/Phi1∗·σc]/bracerightBigg
, (102)
where
/Phi1≡eθ+ieφ=⎛
⎝cosθcosφ−isinφ
cosθsinφ+icosφ
−sinθ⎞
⎠. (103)
Equation ( 102) indicates that there are two mechanisms
for spin current generation; namely, the one due to themagnetization at the interface (the term proportional to n)
and the one due to the magnon spin scattering at the interface(described by the term linear in magnon operators).
Let us briefly demonstrate based on the expression of
Eq. ( 102) that spin-flip processes due to magnon creation or
annihilation lead to generation of spin current in the normalmetal. At the second order, the interaction induces a factor onthe electron wave function ( /Phi1
∗(t)·σ)(/Phi1(t/prime)·σ) for magnon
creation and ( /Phi1(t)·σ)(/Phi1∗(t/prime)·σ) for annihilation (we allow
an infinitesimal difference in time tandt/prime). The factor for the
creation has charge and spin contributions, ( /Phi1∗(t)·σ)(/Phi1(t/prime)·
σ)=/Phi1∗(t)·/Phi1(t/prime)+iσ·(/Phi1∗(t)×/Phi1(t/prime)). For magnon anni-
hilation, we have ( /Phi1∗(t)×/Phi1(t/prime))∗, and thus the sum of the
magnon creation and annihilation processes leads to a factor
/summationdisplay
q[(nq+1)(/Phi1∗(t)×/Phi1(t/prime))+nq(/Phi1∗(t)×/Phi1(t/prime))∗]
=/summationdisplay
q{(2nq+1)Re[/Phi1∗(t)×/Phi1(t/prime)]
+iIm[/Phi1∗(t)×/Phi1(t/prime)]}. (104)
For adiabatic change, the amplitude is expanded as
(/Phi1∗(t)×/Phi1(t/prime))=2i(1+i(t−t/prime) cosθ˙φ)n−(t−t/prime)
×(n×˙n−i˙n)+O((∂t)2), (105)
where we see that a retardation effect from the adiabatic change
of magnetization (represented by the second term on the right-hand side) gives rise to a magnon state change proportionalton×˙nand˙n. The retardation contribution for the spin part
[Eq. ( 104)] is
(t−t
/prime)/summationdisplay
q[−(2nq+1)(n×˙n)+i˙n]. (106)
We therefore expect that a spin current proportional to n×˙n
emerges proportional to the magnon creation and annihilationnumber,/summationtext
q(2nq+1). (As we shall see below, the factor t−t/prime
reduces to a derivative with respect to the angular frequency of
the Green’s function.) A rigorous estimation using the Green’sfunction method is presented in Sec. VII C .
In Eq. ( 106), the last term proportional to ˙nis an imaginary
part arising from the difference of magnon creation andannihilation probabilities of vacuum, n
q+1 andnq.T h et e r m
is, however, an unphysical one corresponding to a real energyshift due to magnon interaction, and is removed by redefinitionof the Fermi energy.n
js
FIG. 9. Feynman diagrams for spin current pumped by interface
sdexchange interaction.
B. Spin current pumped by the interface exchange interaction
Here, we study the spin current pumped by the classical
magnetization at the interface, namely, the one driven bythe term proportional to Snin Eq. ( 102). We treat the
exchange interaction perturbatively to the second order asthe exchange interaction between a conduction electron andthe insulator ferromagnet is localized at the interface and isexpected to be weak. The weak-coupling scheme employedhere is in the opposite limit as the strong-coupling (adiabatic)approach used in the metallic ferromagnet (Sec. IV). A recent
experiment indicates that the insulator spin pumping effect isdriven by local magnetization induced in the normal metalby the magnetic proximity effect [ 8], supporting perturbative
treatment.
In the perturbative regime, the issue of adiabaticity needs
to be argued carefully. In the strong sdcoupling limit, the
adiabaticity is trivially satisfied, as the time needed for theelectron spin to follow the localized spin is the fastest timescale. In the weak-coupling limit, this time scale is long.Nevertheless, the adiabatic condition is satisfied if the electronspin relaxation is strong so that the electron spin relaxesquickly to the local equilibrium state determined by thelocalized spin. Thus the adiabatic condition is expected tobeM
Iτsf/¯h/lessmuch1, where MIandτsfare the interface spin
splitting energy, and the conduction electron spin relaxationtime, respectively. In the following calculation, we considerthe case of /epsilon1
Fτsf/¯h/greatermuch1, i.e., ¯ h(τsf)−1/lessmuch/epsilon1F, as the spin-flip
lifetime is by definition longer than the elastic electron lifetimeτ, which satisfies /epsilon1
Fτ/¯h/greatermuch1 in a metal. The perturbative
results therefore can apply to both adiabatic and nonadiabaticcases.
The calculation is carried out by evaluating the Feynman
diagrams of Fig. 9, similar to the study of Refs. [ 18,19].
A difference is that while Refs. [ 18,19] assumed a smooth
magnetization structure and used a gradient expansion, theexchange interaction we consider is localized.
The lesser Green’s function for a normal metal including
the interface exchange interaction to the linear order is
G
(1)<
N(r,t,r,t)=MI/integraldisplaydω
2π/integraldisplayd/Omega1
2π/summationdisplay
kk/primee−i/Omega1tei(k/prime−k)·r
×/bracketleftbig
(f(ω+/Omega1)−f(ω))gr
k/prime,ω+/Omega1ga
kω
−f(ω)gr
k/prime,ω+/Omega1gr
kω+f(ω+/Omega1)ga
k/prime,ω+/Omega1ga
kω/bracketrightbig
×(n/Omega1·σ), (107)
where MI≡JISis the local spin polarization at the interface.
Expanding the expression with respect to /Omega1and keeping
the dominant contribution at long distance, i.e., the terms
containing both gaandgr.U s i n g/summationtext
kga
kωeik·r/similarequalim
kFeikre−|x|
/lscript(≡
064423-14CONSISTENT MICROSCOPIC ANALYSIS OF SPIN . . . PHYSICAL REVIEW B 96, 064423 (2017)
ga(r)), the result of spin current is
j(1)
s(r,t)=−MIm
kF˙ne−|x|//lscript. (108)
The second-order contribution is similarly calculated to
obtain
G(2)<
N(r,t,r,t)/similarequal(MI)2/integraldisplaydω
2π/integraldisplayd/Omega1 1
2π/integraldisplayd/Omega1 2
2π
×/summationdisplay
kk/primek/prime/primee−i(/Omega11+/Omega12)tei(k/prime−k)·rf/prime(ω)gr
k/prime,ωga
kω
×/parenleftbig
/Omega11ga
k/prime/primeω+/Omega12gr
k/prime/primeω/parenrightbig/parenleftbig
n/Omega11·σ/parenrightbig/parenleftbig
n/Omega12·σ/parenrightbig
=−2πiν(MI)2|gr(r)|2(n×˙n)·σ. (109)
The corresponding spin current at the interface ( x=0) is thus
j(2)
s(x=0,t)=ν(MI)2m
kF(n×˙n), (110)
and the total spin current reads
js(x=0,t)=−MIm
kF˙n−2ν(MI)2m
kF(n×˙n). (111)
In the perturbation regime, the spin current proportional to ˙n
is dominant (larger by a factor of ( νM I)−1) compared to the
one proportional to n×˙n.
An expression of the spin current induced by the interface
exchange interaction was presented in Ref. [ 43] in the limit
of strong spin relaxation, MIτsf/lessmuch1, where τsfis the spin
relaxation time of electrons. By solving the Landau-Lifshitz-Gilbert equation for the electron spin, they obtained Eq. ( 111)
withνM
Ireplaced by MIτsf.
C. Calculation of magnon-induced spin current
Here, the magnon-induced spin current due to the magnon
interaction in Eq. ( 102) is calculated. As a magnon is a small
fluctuation of magnetization, the contribution here is a smallcorrection to the contribution of Eq. ( 111). Nevertheless, the
magnon contribution has a typical linear dependence on thetemperature, and is expected to be experimentally identifiedeasily.
The spin current induced in a normal metal is evaluated by
calculating the self-energy arising from the interface magnonscattering of Eq. ( 102). The contribution to the path-ordered
Green’s function of N electron from the magnon scattering tothe second order is
G
N(r,t,r/prime.t/prime)=/integraldisplay
Cdt1/integraldisplay
Cdt2/summationdisplay
r1r2gN(r,t,r1,t1)
×/Sigma1I(r1,t1,r2,t2)gN(r2,t2,r/prime,t/prime),(112)
where
/Sigma1I(r1,t1,r2,t2)≡iSJ2
I
2Dαβ(r1,t1,r2,t2)σαgN(r1,t1,r2,t2)σβ
(113)
represents the self-energy. Here,
Dαβ(r1,t1,r2,t2)≡−i/angbracketleftTCBα(r1,t1)Bβ(r2,t2)/angbracketright (114)Φ†
ΦgN jsgN
D
FIG. 10. Feynman diagrams for spin current pumped by magnons
at the interface. Green’s functions for magnons and electrons in thenormal metal are denoted by Dandg
N, respectively. /Phi1represents the
effects of magnetization dynamics [Eq. ( 103)].
is the Green’s function for a magnon dressed by the magneti-
zation structure [ /Phi1is defined in Eq. ( 103)],
Bα(r,t)≡/Phi1α(t)b†(r,t)+/Phi1†
α(t)b(r,t). (115)
The diagrammatic representation is in Fig. 10. In the present
approximation including the interface scattering to the secondorder, the electron Green’s function in Eq. ( 113) is treated
as spin-independent, resulting in a self-energy (defined oncomplex time contour)
/Sigma1
I(r1,t1,r2,t2)=iSJ2
I
2(δαβ+i/epsilon1αβγσγ)
×Dαβ(r1,t1,r2,t2)gN(r1,t1,r2,t2).(116)
We focus on the spin-polarized contribution containing the
Pauli matrix. The self-energy is then
/Sigma1I,γ(r1,t1,r2,t2)≡−SJ2
I
2/tildewideDγ(r1,t1,r2,t2)gN(r1,t1,r2,t2),
(117)
where/tildewideDγ≡/epsilon1αβγDαβ, and the lesser Green’s function,
Eq. ( 112), reads
G<
N=σγG<
N,γ, (118)
where (time and spatial coordinates partially suppressed)
G<
N,γ(r,t,r/prime.t/prime)≡/integraldisplay∞
−∞dt1/integraldisplay∞
−∞dt2/bracketleftbig
gr
N(t−t1)/Sigma1r
I,γ(t1,t2)
×g<
N(t2−t/prime)+gr
N/Sigma1<
I,γga
N+g<
N/Sigma1a
I,γga
N/bracketrightbig
.
(119)
The dominant contribution long distance is (see Appendix E
for detail)
G<
N,γ(r,t,r/prime,t)/similarequal/integraldisplaydω
2π/summationdisplay
kk/primegr
N,kωga
N,k/primeωeik·re−ik/prime·r/prime/tildewide/Sigma1I,γ
(120)
with
/tildewide/Sigma1I,γ/similarequali/Psi1γπν
/epsilon1FSJ2
I
2/summationdisplay
qk/prime/prime(1+2nq)(2fk/prime/prime−fk−fk/prime).(121)
The spin current pumped by the magnon scattering is therefore
jm
s(r,t)=πν
/epsilon1FSJ2
I
2|gr(r)|2/summationdisplay
q(1+2nq)(n×˙n).(122)
064423-15GEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
At high temperature compared to magnon energy, βωq/lessmuch1,
1+2nq/similarequal2kBT
ωq, and the magnon-induced spin current de-
pends linearly on temperature. The result ( 122) agrees with a
previous study carried out in the context of thermally inducedspin current [ 20].
D. Correction to Gilbert damping in the insulating case
In this section, we calculate the correction to the Gilbert
damping and gfactor of an insulating ferromagnet as a
result of the spin pumping effect. We study the torque onthe ferromagnetic magnetization arising from the effect ofconduction electrons of a normal metal, given by
τ
I=BI×n=MI(n×sI), (123)
where
BI≡−δHI
δn=−MIsI (124)
is the effective magnetic field arising from the interface
electron spin polarization, sI(t)≡−itr[σG<
N(0,t)]. The con-
tribution to the electron spin density linear in the interfaceexchange interaction, Eq. ( 101), is
s(1),α
I(t)=−i/integraldisplay
dt1MInβ(t1)tr[σαgN(t,t1)σβgN(t1,t)]<,
(125)
where the Green’s functions connect positions at the interface,
i.e., from x=0t ox=0, and are spin unpolarized. (The
Feynman diagrams for the spin density are the same as theone for the spin current, Fig. 9, with the vertex j
sreplaced by
the Pauli matrix.) The pumped contribution proportional to thetime variation of magnetization is obtained as
s(1)
I(t)=−MI˙n/integraldisplaydω
2π/summationdisplay
kk/primef/prime(ω)/parenleftbig
ga
N,k/prime−gr
N,k/prime/parenrightbig/parenleftbig
ga
N,k−gr
N,k/parenrightbig
=−MI(πν)2˙n. (126)
The second-order contribution similarly reads
s(2),α
I(t)=−i
2/integraldisplay
dt1/integraldisplay
dt2(MI)2nβ(t1)nγ(t2)tr[σαgN(t,t1)
×σβgN(t1,t2)σγgN(t2,t)]<
/similarequal−2(MI)2(πν)3(n×˙n). (127)
The interface torque is therefore
τI=−(MIπν)2(n×˙n)+2(MIπν)3˙n. (128)
Including this torque in the LLG equation, ˙n=−αn×˙n−
γB×n+τ,w eh a v e
(1−δI)˙n=−αI(n×˙n)−γB×n, (129)
where
δI=2μd(πM Iν)3,α I=α+μd(πM Iν)2,(130)
where μd∼dmp/dis the ratio of the length of magnetic
proximity ( dmp) and thickness of the ferromagnet, d.T h e
Gilbert damping constant therefore increases as far as theinterface spin-orbit interaction is neglected. The resonance
frequency is ω
B=γB
1−δI, and the shift can have both signs
depending on the sign of interface exchange interaction, MI.
There may be a possibility that magnon excitations induce
a torque that corresponds to effective damping. In fact, sucha torque arises if /angbracketleftb/angbracketrightor/angbracketleftb†/angbracketrightare finite, i.e., if the magnon
Bose condensation glows. Such condensation can in principledevelop from the interface interaction of magnon creation orannihilation induced by electron spin flip, Eq. ( 102). However,
conventional spin relaxation processes arising from the secondorder of random spin scattering do not contribute to suchmagnon condensation and additional damping.
Comparing the result of pumped spin current, Eq. ( 111), and
that of damping coefficient, Eq. ( 130), we notice that the “spin
mixing conductance” argument [ 2], where the coefficients for
the spin current component proportional to n×˙nand the
enhancement of the Gilbert damping constant are governed bythe same quantity (the real part of a spin mixing conductance)does not hold for the insulator case. In fact, our result indicatesthat the spin current component proportional to n×˙narises
from the second-order correction to the interaction (the seconddiagram of Fig. 9), while the damping correction arises from
the first-order process (the first diagram of Fig. 9). Although
the magnitudes of the two effects happen to be both secondorder of the interface spin splitting, M
I, the physical origins
appear to be distinct. From our analysis, we see that the spinmixing conductance description is not general and applies onlyto the case of a thick metallic ferromagnet (see Sec. VA for
the metallic case).
VIII. DISCUSSION
Our results are summarized in Table II. Let us discuss
experimental results in the light of our results. In the early fer-romagnetic resonance (FMR) experiments, consistent studiesofgfactor and the Gilbert damping were carried out on metallic
ferromagnets [ 12]. The results appear to be consistent with
theories (Refs. [ 2,11] and the present paper). Both the damping
constant and the gfactor have 1 /ddependence on the thickness
of the ferromagnet in the range of 2 nm <d< 10 nm [ 12].
The maximum additional damping reaches δα∼0.1a td=2
nm, which exceeds the original value of α∼0.01. The g-factor
modulation is about 1% at d=2 nm, and its sign depends on
the material; the gfactor increases for Pd/Py/Pd and Pt/Py/Pt,
while decreases for Ta/Py/Ta. These results appear consistentwith ours, because δω
Bis governed by Im T+−, whose sign
depends on the sign of interface spin-orbit interaction. Incontrast, damping enhancement proportional to Re
T+−is
positive for thick metals. However, other possibilities like theeffect of a large interface orbital moment playing a role in thegfactor, cannot be ruled out at present.
Recently, inverse spin Hall measurement has become com-
mon for detecting the spin current. In this method, however,only the dc component proportional to n×˙nis accessible so
far and there remains an ambiguity for qualitative estimatesbecause another phenomenological parameter, the conversionefficiency from spin to charge, enters. Qualitatively, the valuesofA
robtained by the inverse spin Hall measurements [ 44] and
FMR measurements are consistent with each other.
The cases of insulating ferromagnets have been studied
recently. In the early experiments, orders of magnitudesmaller values of A
rcompared to metallic cases were re-
ported [ 43], while those small values are now understood
as due to poor interface quality. In fact, FMR measure-ments on epitaxially grown samples like yttrium iron garnet
064423-16CONSISTENT MICROSCOPIC ANALYSIS OF SPIN . . . PHYSICAL REVIEW B 96, 064423 (2017)
TABLE II. Summary of essential parameters determining the spin current js, corrections to the Gilbert damping δα, and the resonance
frequency shift δωBfor metallic and insulating ferromagnets. Coefficients AiandArare for the spin current, defined by Eq. ( 1). Label “ −”
indicates that it is not discussed in the present paper. “∗” is for the strong spin relaxation case, the density of states νis replaced by the inverse
of electron spin-flip time τsf[43].
Ferromagnet (F) Ai Ar δα δω B Assumption Equations
ReT+− ImT+− Thick F ( 27)(63)(83)(84)
Metal Im T+− ReT+−
ImT+− ReT+− Thin F ( 88)
Insulator MIν (MIν)2(MIν)2(MIν)3Weak spin relaxation∗(111)(130)
–( MIν)2/summationtext
q(1+2nq) – – Magnon ( 122)
(Y3Fe5O12,YIG)/Au/Fe turned out to show Arof 1–5 ×
1018m−2(Refs. [ 45,46]), which is the same order as in the
metallic cases. Inverse spin Hall measurements on YIG/Ptreport similar values [ 47], and the value is consistent with
the first-principles calculation [ 48]. Systematic studies of
YIG/NM with NM =Pt, Ta, W, Au, Ag, Cu, Ti, V , Cr, Mn,
etc., were carried out with the result of A
r∼1017–1018m−2
(Refs. [ 49–52]). If we use a naive phenomenological relation,
Eq. ( 6),Ar=1018m−2corresponds to δα=3×10−4if
a=2˚A,S=1, and d=20˚A. Assuming interface sdex-
change interaction, the value indicates MIν∼0.01, which
appears reasonable at least by the order of magnitude fromthe result of x-ray magnetic circular dichroism (XMCD)suggesting spin polarization of interface Pt of 0 .05μ
Bwithin
a proximity length of less than 1 nm [ 53]. A recent experiment
indicates that the spin pumping effect of an insulator is inducedlocally in the normal metal as a result of the magnetic proximityeffect [ 8], supporting our perturbative treatment.
On the other hand, FMR frequency shift of insulators cannot
be explained by our theory. In fact, the shift for YIG/Pt isδω
B/ωB∼1.6×10−2, which is larger than δα∼2×10−3,
while our perturbation theory assuming weak interface sd
interaction predicts δωB/ωB<δ α . We expect that the discrep-
ancy arises from the interface spin-orbit interaction that wouldbe present at the insulator-metal interface, which modifies themagnetic proximity effect and damping torque significantly. Itwould be necessary to introduce an anomalous sdcoupling at
the interface like the one discussed in Ref. [ 54]. Experimen-
tally, the influence of interface spin-orbit interaction [ 55] and
proximity effect needs to be carefully characterized by using amicroscopic technique such as MCD to compare with theories.
IX. SUMMARY
We have presented a microscopic study of spin pumping
effects, the generation of spin current in a ferromagnet-normal metal junction by magnetization dynamics, for bothmetallic and insulating ferromagnets. As for the case of ametallic ferromagnet, a simple quantum mechanical picturewas developed using a unitary transformation to diagonalizethe time-dependent sdexchange interaction. The problem of
dynamic magnetization is thereby mapped to the one withstatic magnetization and off-diagonal spin gauge field, whichmixes the electron spin. In the slowly varying limit, the spingauge field becomes static, and the conventional spin pumpingformula is derived simply by evaluating the spin accumulationformed in the normal metal as a result of interface hopping.
The effect of interface spin-orbit interaction was discussed.A rigorous field theoretical derivation was also presented,and the enhancement of spin damping (Gilbert damping)in the ferromagnet as a result of spin pumping effect wasdiscussed. The case of an insulating ferromagnet was studiedbased on a model where the spin current is driven locallyby the interface exchange interaction as a result of magneticproximity effect. The dominant contribution turns out to be theone proportional to ˙n, while the magnon contribution leads to
n×˙n, whose amplitude depends linearly on the temperature.
Our analysis clearly demonstrates the difference in the spincurrent generation mechanism for metallic and insulatingferromagnets. The influence of atomic-scale interface structureon the spin pumping effect is an open and urgent issue, inparticular for the case of ferrimagnetic insulators which havetwo sublattice magnetic moments.
ACKNOWLEDGMENTS
G.T. thanks H. Kohno, C. Uchiyama, K. Hashimoto, and
A. Shitade for valuable discussions. S.M. thanks the Centerfor Spintronics Network (CSRN) for supporting collaborationworks. This work was supported by a Grant-in-Aid forExploratory Research (Grant No.16K13853) and a Grant-in-Aid for Scientific Research (B) (Grant No. 17H02929) fromthe Japan Society for the Promotion of Science, and a Grant-in-Aid for Scientific Research on Innovative Areas (Grant No.26103006) from The Ministry of Education, Culture, Sports,Science and Technology (MEXT), Japan.
A±s,t
˜s(F)
±gr∓
ga±
FIG. 11. Feynman diagram for electron spin density of ferromag-
net induced by magnetization dynamics (represented by spin gauge
fieldAs) neglecting the effect of normal metal. The amplitude is
essentially given by the spin-flip correlation function χ±[Eq. ( A3)].
064423-17GEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
APPENDIX A: SPIN DENSITY INDUCED BY MAGNETIZATION DYNAMICS IN F
Let us here calculate the spin density in a ferromagnet induced by magnetization dynamics neglecting the effect of interface,
HI. (Effects of HIare discussed in Sec. V.)
In the rotated frame, the spin density in F pumped by the spin gauge field is therefore (diagrams shown in Fig. 11)
˜s(F)
α(k,k/prime)≡−i/integraldisplaydω
2πtr[σαδG<(k,k/prime,ω)]
=−i/integraldisplaydω
2π/summationdisplay
k/prime/prime(fk/prime/prime+−fk/prime/prime−)/summationdisplay
±(±)A±
s,ttr[σαgr(k,k/prime/prime,ω)σ∓ga(k/prime/prime,k/prime,ω)]
=/braceleftBigg
∓i/integraltextdω
2π/summationtext
k/prime/prime(fk/prime/prime+−fk/prime/prime−)A±
s,tgr
∓(k,k/prime/prime,ω)ga
±(k/prime/prime,k/prime,ω)(α=±)
0( α=z). (A1)
Let us here neglect the effects of interface in discussing the
spin polarization of F electrons, then the Green’s functions aretranslationally invariant, i.e., g
a(k,k/prime)=δk,k/primega(k)(a=r,a).
Using the explicit form of the free Green’s function, ga
σ(k,ω)=
1
ω−/epsilon1k,σ−i0, and
/integraldisplaydω
2πgr
∓(k,k/prime/prime,ω)ga
±(k/prime/prime,k/prime,ω)=i
/epsilon1k,±−/epsilon1k,∓+i0,(A2)
the spin density in the rotated frame then reduces to
˜s(F)
±(k)=−A±
s,tχ±, (A3)
where
χ±≡−/summationdisplay
kfk,±−fk,∓
/epsilon1k,±−/epsilon1k,∓+i0(A4)
is the spin correlation function with spin flip, +i0 meaning
an infinitesimal positive imaginary part. Since we focus onthe adiabatic limit and spatially uniform magnetization, thecorrelation function is at zero momentum and frequencytransfer. We thus easily see that
χ
±=n+−n−
2M, (A5)
where n±=/summationtext
kfk±is the spin-resolved electron density.
The spin polarization of Eq. ( A3) in the rotated frame is
proportional to A⊥
s,t, and represents a renormalization of total
spin in F. In fact, it corresponds in the laboratory frame to
s(F)∝n×˙n, and exerts a torque proportional to ˙nonn.
It may appear from Eq. ( A5) that a damping of spin, i.e., a
torque proportional to n×˙n, arises when the imaginary part
for the Green’s function becomes finite, because1
Mis replaced
by1
M∓iηi, where ηiis the imaginary part. This is not always the
case. For example, nonmagnetic impurities introduce a finite
imaginary part inversely proportional to the elastic lifetime(τ),
i
2τ. They should not, however, cause damping of spin.
The solution to this apparent controversy is that Eq. ( A1)i s
not enough to discuss damping even including lifetime. Infact, there is an additional process called vertex correctioncontributing to the lesser Green’s function, and it gives riseto the same order of small correction as the lifetime does,and the sum of the two contributions vanishes. Similarly,we expect damping does not arise from the spin-conservingcomponent of spin gauge field, A
z
s,t. This is indeed true as
we explicitly demonstrate in Appendix B. We shall show inSec. Vthat damping arises from the spin-flip components of
the self-energy.
APPENDIX B: EFFECT OF SPIN-CONSERVING SPIN
GAUGE FIELD ON SPIN DENSITY
Here we calculate the contribution of spin-conserving spin
gauge field, Az
s,t, on the interface effects of spin density in F.
It turns out that a spin-conserving spin gauge field combinedwith interface effects does not induce damping. This result isconsistent with a naive expectation that only the nonadiabaticcomponents of spin current should contribute to damping.
The contribution to the lesser Green’s function in F from the
interface hopping (lowest, the second order in the hopping) atthe linear order in the spin gauge field reads (diagramaticallyshown in Fig. 12)
δG
<=δG<
(a)+δG<
(b)+δG<
(c),
δG<
(a)=gr(As,t·σ)gr/Sigma1r
0g<+gr(As,t·σ)gr/Sigma1<
0ga
+gr(As,t·σ)g</Sigma1a
0ga+g<(As,t·σ)ga/Sigma1a
0ga,
δG<
(b)=gr/Sigma1r
0gr(As,t·σ)g<+gr/Sigma1<
0g<(As,t·σ)ga
+gr/Sigma1a
0ga(As,t·σ)ga+g</Sigma1a
0ga(As,t·σ)ga,
δG<
(c)=gr/Sigma1rg<+gr/Sigma1<ga+g</Sigma1aga. (B1)
Here,
/Sigma1a≡˜tU−1ga
NU˜t†(a=a,r,<),
/Sigma1a
0≡˜tga
N (B2)
are the self-energy due to the interface hopping, where /Sigma1a
is the full self-energy including the time-dependent unitary
matrix U, which includes the spin gauge field. /Sigma1a
0is the
As,t
t t∗N
(a)As,tt∗t
N
(b)tU−1
N
Ut∗
(c)
FIG. 12. Diagrammatic representation of the contribution to the
lesser Green’s function for F electron arising from the interface
hopping (represented by tandt∗) and spin gauge field ( As,t). The
diagram (c) includes the spin gauge field implicitly in unitary matricesUandU
−1.
064423-18CONSISTENT MICROSCOPIC ANALYSIS OF SPIN . . . PHYSICAL REVIEW B 96, 064423 (2017)
contribution of /Sigma1awith the spin gauge field neglected. We here focus on the contribution of the adiabatic ( z) component, Az
s,t.
Using g<=F(ga−gr)f o rF( Fis a 2×2 matrix of the spin-polarized Fermi distribution function) and g<
N=fN(ga
N−gr
N) and
noting that all the angular frequencies of the Green’s function are equal, we obtain
δG<
(a)+δG<
(b)/similarequalAz
s,tσz/braceleftbig
−2F/bracketleftbig
(gr)3/Sigma1r
0−(ga)3/Sigma1a
0/bracketrightbig
−(F−fN)[(gr)2ga+gr(ga)2]/parenleftbig
/Sigma1a
0−/Sigma1r
0/parenrightbig/bracerightbig
. (B3)
The contribution δG<
(c)is calculated noting that
˜tU−1ga
NU˜t†=ga
N˜t˜t†−dga
N
dω˜t(As,t·σ)˜t†+O((As,t)2). (B4)
The linear contribution with respect to the zcomponent of the gauge field turns out to be
δG<
(c)/similarequalAz
s,tσz/braceleftbigg
F/bracketleftbigg
(gr)2∂
∂ω/Sigma1r
0−(ga)2∂
∂ω/Sigma1a
0/bracketrightbigg
+(F−fN)grga∂
∂ω/parenleftbig
/Sigma1a
0−/Sigma1r
0/parenrightbig/bracerightbigg
. (B5)
We therefore obtain the effect of spin-conserving gauge field as
δG<=Az
s,tσz∂
∂ω/braceleftbigg
F/bracketleftbig
(gr)2/Sigma1r
0−(ga)2/Sigma1a
0/bracketrightbig
+(F−fN)grga/parenleftbig
/Sigma1a
0−/Sigma1r
0/parenrightbig/bracerightbigg
, (B6)
which vanishes after integration over ω. Therefore the contribution from the spin-conserving gauge field and interface hopping
vanishes in the spin density, leaving the damping unaffected.
APPENDIX C: DERIV ATION OF EQ. ( 72)
We show here the details of the calculation of the induced spin density in the ferromagnetic metal, diagrammatically represented
in Fig. 8. Writing the spatial and temporal positions explicitly, the self-energy of F electrons arising from the hopping to N region
reads ( r1andr2a r ei nF )
/Sigma1a(r1,r2,t1,t2)=/integraldisplay
INd3r/prime
1/integraldisplay
INd3r/prime
2˜t(r1,r/prime
1)U−1(t1)ga
N(r/prime
1,r/prime
2,t1−t2)U(t2)˜t†(r2,r/prime
2), (C1)
where a=r,a,<. We assume the Green’s function in N region is spin-independent, i.e., we neglect higher-order contributions
of hopping. Moreover, we treat the hopping to occur only at the interface, i.e., at x=0. The self-energy is then represented
as
/Sigma1a(r1,r2,t1,t2)=a2δ(x1)δ(x2)˜tU−1(t1)U(t2)˜t†/summationdisplay
kga
N(k,t1−t2), (C2)
where ais the interface thickness, which we assume to be the order of the lattice constant. The diagrammatic representations of
Eqs. ( 68) and ( C1) are in Fig. 8. Expanding the matrix using a spin gauge field as U−1(t1)U(t2)=1−i(t1−t2)As,t+O((As,t)2),
we obtain the gauge field contribution of the self-energy as
/Sigma1a(r1,r2,t1,t2)=a2δ(x1)δ(x2)/integraldisplaydω
2πde−iω(t1−t2)
dω˜tAs,t˜t†/summationdisplay
kga
N(k,ω)
=−a2δ(x1)δ(x2)/integraldisplaydω
2πe−iω(t1−t2)˜tAs,t˜t†/summationdisplay
kd
dωga
N(k,ω). (C3)
The linear contribution of the lesser component of the off-diagonal self-energy is
G<(r,t,r/prime,t)=gr/Sigma1rga+gr/Sigma1<ga+g</Sigma1aga
=a2/integraldisplaydω
2π/summationdisplay
k/bracketleftbigg
gr(r,ω)dgr
N(k,ω)
dω˜tAs,t˜t†g<(−r,ω)
+gr(r,ω)dg<
N(k,ω)
dω˜tAs,t˜t†ga(−r,ω)+g<(r,ω)dga
N(k,ω)
dω˜tAs,t˜t†ga(−r,ω)/bracketrightbigg
. (C4)
For a finite distance from the interface r, the dominant contribution arises from the terms containing both gr(r,ω) andga(−r,ω),
as they do not contain a rapid oscillation like ei(kF++kF−)rande2ikFσr. Using an approximation/summationtext
kgr
N(k,ω)∼−iπν Nand partial
integration with respect to ω,E q .( C4) finally reduces to Eq. ( 72).
064423-19GEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
APPENDIX D: MAGNON REPRESENTATION OF SPIN BERRY’S PHASE TERM
Here we derive the expression for the spin Berry’s phase term of the Lagrangian ( 94) in terms of a magnon operator. The time
integral of the term is written by introducing an artificial variable uas [56]
/integraldisplay
dtL B=S/integraldisplay
dt˙φ(cosθ−1)=S−2/integraldisplay
dt/integraldisplay1
0duS·(∂tS×∂uS), (D1)
where S(t,u) is extended to a function of tandu, but only S(t,u=1) is physical. Noting that the unitary transformation matrix
element of Eq. ( 96) is written as
Uij=(ej)i, (D2)
where r1≡eθ,e2≡eφande3≡n, we obtain
S·(∂tS×∂uS)=/tildewideS·[(∂t+iAU,t)/tildewideS×(∂u+iAU,u)/tildewideS)]. (D3)
Evaluating to the second order in the magnon operators, we have
∂t/tildewideS×∂u/tildewideS=2iγˆz[(∂ub†)(∂tb)−(∂tb†)(∂ub)]. (D4)
Using the explicit form of AU,μ, the gauge field contribution is
∂u/tildewideS·[/tildewideS×iAU,t/tildewideS)]=S2γ[(∂ub†)(−sinθ˙φ+i˙θ)+(∂ub)(−sinθ˙φ−i˙θ)]−2Sγ2cosθ(∂tφ)∂u(b†b). (D5)
The terms linear in the boson operators vanish by the equation of motion, and the second-order contribution is
S·(∂tS×∂uS)=2Sγ2{i∂u[b†(∂tb)−(∂tb†)b]−∂u[cosθ(∂tφ)b†b]+∂t[cosθ(∂uφ)b†b]
+sinθ((∂tθ)(∂uφ)−(∂uθ)(∂tφ))b†b}. (D6)
Integrating over tandu, the total derivative with respect to tof Eq. ( D6) vanishes, resulting in
/integraldisplay
dt/integraldisplay1
0duS·(∂tS×∂uS)=2Sγ2/integraldisplay
dt{i[b†(∂tb)−(∂tb†)b]−cosθ(∂tφ)b†b+sinθ((∂tθ)(∂uφ)−(∂uθ)(∂tφ))b†b}.(D7)
The last term of Eq. ( D7) represents the renormalization of spin Berry’s phase term, i.e., the effect S→S−b†b, which we
neglect below. The Lagrangian for magnons thus reads
Lm=2Sγ2/integraldisplay
d3ri/bracketleftbig
b†/parenleftbig
∂t+iAz
s,t/parenrightbig
b−b†/parenleftbig←
∂t−iAz
s,t/parenrightbig/parenrightbig
b/bracketrightbig
, (D8)
namely, magnons interacts with the adiabatic component of the spin gauge field, Az
s,t.
APPENDIX E: DERIV ATION OF EQS. ( 120) AND ( 121)
For the self-energy type of the Green’s functions, depending on two times as g(t1−t2)D(t1−t2)[ E q .( 117)], the real-time
components are written as (suppressing time and suffix of N) (see Appendix F)
[g(t1−t2)D(t1−t2)]r=grD<+g>Dr=g<Dr+grD>,
[g(t1−t2)D(t1−t2)]a=gaD>+g<Da=gaD<+g>Da,
[g(t1−t2)D(t1−t2)]<=g<D<. (E1)
The Green’s function /tildewideDis that of a composite field Bαdefined in Eq. ( 115), and is decomposed to the elementary magnon Green’s
function Das
/tildewideDγ(r1,t1,r2,t2)=[/Phi1†(t1)×/Phi1(t2)]γD(r1,t1,r2,t2)−[/Phi1†(t2)×/Phi1(t1)]γD(r2,t2,r1,t1), (E2)
where
D(r1,t1,r2,t2)≡−i/angbracketleftTCb(r1,t1)b†(r2,t2)/angbracketright. (E3)
The spin-dependent factor in Eq. ( E2) is calculated for adiabatic dynamics as
/Phi1†(t1)×/Phi1(t2)=2in(t1)+(t2−t1)[/Psi1+i˙n]+O((∂t)2), (E4)
where
/Psi1≡2 cosθ˙φn+n×˙n. (E5)
064423-20CONSISTENT MICROSCOPIC ANALYSIS OF SPIN . . . PHYSICAL REVIEW B 96, 064423 (2017)
The real-time Green’s functions are therefore [ D(1,2)≡D(r1,t1,r2,t2)]
/tildewideD<
γ(r1,t1,r2,t2)=2in(t1)[D<(r1,t1,r2,t2)−D>(r2,t2,r1,t1)]+(t2−t1){/Psi1[D<(r1,t1,r2,t2)+D>(r2,t2,r1,t1)]
+i˙n[D<(r1,t1,r2,t2)−D>(r2,t2,r1,t1)]}, (E6)
/tildewideDr
γ(1,2)=θ(t1−t2)/parenleftbig/tildewideD<
γ(1,2)−/tildewideD>
γ(1,2)/parenrightbig
,/tildewideDa
γ(1,2)=−θ(t2−t1)/epsilon1αβγ(D<
αβ(1,2)−D>
αβ(1,2)),
and/tildewideD<
γis obtained by exchanging <and>in/tildewideD<
γ. Elementary Green’s functions are calculated as
D<(r1,t1,r2,t2)=−i/summationdisplay
qeiq·(r1−r2)nqe−iωq(t1−t2),D>(r1,t1,r2,t2)=−i/summationdisplay
qeiq·(r1−r2)(nq+1)e−iωq(t1−t2), (E7)
where ωqis the magnon energy and nq≡1
eβωq−1. In our model, the interface is atomically flat and has an infinite area, and thus
ri(i=1,2) are at x=0. The Fourier components, defined as ( a=r,a,<,> )
/tildewideDa
γ(x1=0,t1,x2=0,t2)≡/summationdisplay
q/integraldisplayd/Omega1
2πe−i/Omega1(t1−t2)/tildewideDa
γ(q,/Omega1), (E8)
are calculated from Eq. ( E6)a s
/tildewideD<
γ(q,/Omega1)=−i/braceleftbigg
2n(D<
−−D>
+)+d
d/Omega1/bracketleftbig
/Psi1(D<
−+D>
+)+i˙n(D<
−−D>
+)/bracketrightbig/bracerightbigg
,
/tildewideDr
γ(q,/Omega1)=−i/braceleftbigg
2n(Dr
−+Dr
+)+d
d/Omega1/bracketleftbig
/Psi1(Dr
−−Dr
+)+i˙n(Dr
−+Dr
+)/bracketrightbig/bracerightbigg
, (E9)
/tildewideDa
γ(q,/Omega1)=−i/braceleftbigg
2n(Da
−+Da
+)+d
d/Omega1/bracketleftbig
/Psi1(Da
−−Da
+)+i˙n(Da
−+Da
+)/bracketrightbig/bracerightbigg
,
where
Da
±≡1
/Omega1±ωq−i0,Dr
±≡1
/Omega1±ωq+i0
D<
−≡nq(Da
−−Dr
−),D>
+≡(1+nq)(Da
+−Dr
+). (E10)
The spin part of the Green’s function, Eq. ( 118), is
G<
N,γ(r,t,r/prime,t)=−SJ2
I
2/integraldisplaydω
2π/integraldisplayd/Omega1
2π/summationdisplay
kk/prime/summationdisplay
k/prime/primeq/bracketleftbig
gr
N,kω/parenleftbig/tildewideDr
γ(q,/Omega1)g>
N,k/prime/prime,ω−/Omega1+/tildewideD<
γ(q,/Omega1)gr
N,k/prime/prime,ω−/Omega1/parenrightbig
g<
N,k/primeω
+gr
N,kω/tildewideDr
γ(q,/Omega1)g>
N,k/prime/prime,ω−/Omega1ga
N,k/primeω+g<
N,kω/parenleftbig/tildewideDa
γ(q,/Omega1)g>
N,k/prime/prime,ω−/Omega1+/tildewideD<
γ(q,/Omega1)ga
N,k/prime/prime,ω−/Omega1/parenrightbig
ga
N,k/primeω/bracketrightbig
.(E11)
The contribution surviving at long distance is the one containing gr
N,ω(r) andga
N,ω(−r), obtaining Eq. ( 120), i.e.,
G<
N,γ(r,t,r/prime,t)/similarequal/integraldisplaydω
2π/summationdisplay
kk/primegr
N,kωga
N,k/primeωeik·re−ik/prime·r/prime/tildewide/Sigma1I,γ,
where
/tildewide/Sigma1I,γ≡−SJ2
I
2/integraldisplayd/Omega1
2π/summationdisplay
k/prime/primeq/bracketleftbig/parenleftbig
fk/prime/tildewideDr
γ(q,/Omega1)−fk/tildewideDa
γ(q,/Omega1)/parenrightbig
(fk/prime/prime−1)/parenleftbig
ga
N,k/prime/prime,ω−/Omega1−gr
N,k/prime/prime,ω−/Omega1/parenrightbig
+/tildewideD<
γ(q,/Omega1)/parenleftbig
fk/primegr
N,k/prime/prime,ω−/Omega1−fkga
N,k/prime/prime,ω−/Omega1+fk/prime/prime/parenleftbig
ga
N,k/prime/prime,ω−/Omega1−gr
N,k/prime/prime,ω−/Omega1/parenrightbig/parenrightbig/bracketrightbig
. (E12)
We focus on the pumped contribution, containing a derivative with respect to /Omega1in Eq. ( E9). The result is, using partial integration
with respect to /Omega1(/tildewide/Sigma1Iis a vector representation of /tildewide/Sigma1I,γ),
/tildewide/Sigma1I/similarequal−iSJ2
I
2/integraldisplayd/Omega1
2π/summationdisplay
k/prime/primeq/braceleftbigg
(fk/prime/prime−1)d
d/Omega1/parenleftbig
ga
N,k/prime/prime,ω−/Omega1−gr
N,k/prime/prime,ω−/Omega1/parenrightbig
(fk/prime[/Psi1(Dr
−−Dr
+)+i˙n(Dr
−+Dr
+)]
−fk[/Psi1(Da
−−Da
+)+i˙n(Da
−+Da
+)])+[/Psi1(D<
−+D>
+)
+i˙n(D<
−−D>
+)]d
d/Omega1/parenleftbig
(fk/prime/prime−fk)ga
N,k/prime/prime,ω−/Omega1−(fk/prime/prime−fk/prime)gr
N,k/prime/prime,ω−/Omega1/parenrightbig/bracerightbigg
. (E13)
064423-21GEN TATARA AND SHIGEMI MIZUKAMI PHYSICAL REVIEW B 96, 064423 (2017)
Usingd
d/Omega1ga
k/prime/prime,ω−/Omega1=(ga
k/prime/prime,ω)2+O(/Omega1) and an approximation, we obtain/summationtext
k/prime/prime(ga
k/prime/prime,ω)2/similarequal−πiν
2/epsilon1F,
/tildewide/Sigma1I/similarequalπν
/epsilon1FSJ2
I
2/integraldisplayd/Omega1
2π/summationdisplay
qk/prime/prime/parenleftbigg
/Psi1/braceleftbigg
(fk/prime/prime−1)[fk/prime(Dr
−−Dr
+)−fk(Da
−−Da
+)]+1
2(2fk/prime/prime−fk−fk/prime)(D<
−+D>
+)/bracerightbigg
+i˙n/braceleftbigg
(fk/prime/prime−1)[fk/prime(Dr
−+Dr
+)−fk(Da
−+Da
+)]+1
2(2fk/prime/prime−fk−fk/prime)(D<
−−D>
+)/bracerightbigg/parenrightbigg
. (E14)
As argued for Eq. ( 106), only the imaginary part of self-energy contributes to the induced spin current, as the real part, the shift
of the chemical potential, is compensated by redistribution of electrons. We therefore obtain Eq. ( 121).
We further note that the component of /Psi1proportional to n[Eq. ( E5)] does not contribute to the current generation, as a result
of gauge invariance. (In other words, the contribution cancels with the one arising from the effective gauge field for magnons).
APPENDIX F: DECOMPOSITION OF CONTOUR-ORDERED SELF-ENERGY
Here we derive the decomposition formula for the self-energy in Eq. ( E1). Obviously, we have
[gD]<=g<D<. (F1)
The retarded component is defined as
[gD]r≡[gD]t−[gD]<, (F2)
where the time-ordered one is written as
[g(t1−t2)D(t1−t2)]t≡θ(t1−t2)g>D>+θ(t2−t1)g<D<=grDr+grD<+g<Dr+g<D<. (F3)
We thus obtain
[gD]r=grDr+grD<+g<Dr. (F4)
Noting that grDa=0, we can write it as
[gD]r=grD<+g>Dr=g<Dr+grD>. (F5)
The advanced component is similarly written as
[gD]a=−gaDa+gaD<+g<Da=gaD>+g<Da=gaD<+g>Da. (F6)
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064423-23 |
PhysRevApplied.11.044028.pdf | PHYSICAL REVIEW APPLIED 11,044028 (2019)
Magnetization Dynamics Induced by Nanoconfined Magnetic-Field Pulse
Generated by Resonant Plasmonic Nanoantennas
B.C. Choi*
Department of Physics and Astronomy, University of Victoria, Victoria V8P 5C2, Canada
(Received 16 January 2019; revised manuscript received 14 March 2019; published 10 April 2019)
Finite-difference time domain (FDTD) calculations reveal that resonant plasmonic nanoantennas are
capable of generating intense magnetic field pulses in the midinfrared frequency region. The magnetic
field pulse generated by nanoantennas is spatially concentrated within a nanoscale region, with its intensityincreased by more than two orders of magnitude compared to that of the incident light. Given the highly
localized confinement of the intense magnetic field, the nanoantenna can be used as a nanoscale source of
magnetic field pulse at optical frequencies, which can locally manipulate the magnetism within a very shorttime scale. Micromagnetic numerical results demonstrate the excitation of the magnetization oscillation in
a ferromagnetic nanoelement, which is coherently coupled to the magnetic field. After the termination of
magnetization oscillation, propagating spin waves emerge from the excitation magnetic field region and
travel perpendicular to the static magnetization direction. The result demonstrates the potential of resonant
plasmonic nanoantennas in optically triggering magnetization dynamics and subsequently generating spinwaves in the GHz frequency domain. The result opens up an interesting perspective for applying plasmonic
nanoantennas in the ultrafast optical manipulation of magnetism on the nanometer scale.
DOI: 10.1103/PhysRevApplied.11.044028
I. INTRODUCTION
The study of nonequilibrium magnetization phenom-
ena in magnetic elements has attracted much attention
due to the fundamental interest in ultrafast magnetiza-
tion dynamics and a variety of potential applications,
including high-speed magnetoelectronic devices. Conven-
tionally, the magnetization dynamics in magnetic elements
have been triggered by applying magnetic field pulses
or spin torque [ 1,2]. With the latest advances in laser
technology, the possibility of the optical excitation of mag-
netism by employing high-power lasers has been exten-
sively explored. In their pioneering work of laser-induced
ultrafast demagnetization, Beurepaire et al. demonstrated
that ferromagnetic (FM) thin films excited by femtosecond
laser pulses underwent ultrafast demagnetization within
several hundred femtoseconds due to rapid energy trans-
fer from thermalized electrons to the spin system [ 3]. The
demagnetization was followed by a slow recovery over
the picosecond timescale as electrons equilibrate with the
phonons, and eventually to complete cooling via nanosec-
ond lattice diffusion. The timescale of the laser-induced
demagnetization process is orders of magnitude below the
limit imposed by conventional switching of magnetic ordervia magnetic field pulse, and has been the focus of con-
siderable research since its discovery. The laser-induced
ultrafast magnetization process is, however, incoherent in
*bchoi@uvic.canature, and it has been challenging to coherently controlmagnetic states.
Over the past years, significant research efforts have
been devoted to exploring new phenomena in the interac-
tion of light with magnetism. Recently, an increasing num-
ber of THz magnetization dynamics studies have emerged
in which the magnetic field component of optical pulses
directly couples to the magnetization via Zeeman cou-
pling [ 4]. Kampfrath et al., for example, reported on the
coherent control of spin waves in antiferromagnetic NiO
with highly intense terahertz pulses [ 5]. Recent work by
Shalaby et al. also demonstrated the magnetization dynam-
ics in ferromagnets triggered by intense THz magnetic
pulses, and found that the excited magnetization oscilla-
tion was phase locked to the magnetic field [ 6]. Another
rapidly emerging field of research is magneto-plasmonics,
which combines both magnetic and plasmonic functional-
ities [ 7]. Of particular relevance to information technol-
ogy is that the incorporation of plasmonic nanostructures
to magnetic systems can lead to a significant enhance-
ment of the magneto-optical (MO) response. Recently,
V. Bonanni et al . reported the magneto-plasmonic effect
in FM nanostructures, in which a strong and tunable
correlation between the localized surface plasmons and
magneto-optical effect was observed [ 8].
In this study, we explore an alternative venue for
optically manipulating magnetism by directly applying a
nanoconfined magnetic field pulse generated by plasmonicnanoelements. Plasmonic nanostructures, such as split-ring
2331-7019/19/11(4)/044028(6) 044028-1 © 2019 American Physical SocietyB.C. CHOI PHYS. REV. APPLIED 11,044028 (2019)
resonators [ 9–11], dielectric dimers [ 12], and nanoanten-
nas [ 13–16], have been widely studied due to their capabil-
ities to convert optical radiation to intense magnetic fields.
In particular, T. Grosjean et al. introduced an alternative
nanoantenna concept, which was based on the diabolo
nanostructure and could generate significantly enhanced
magnetic field in the optical frequency range [ 14]. In our
numerical study, the intense magnetic field pulses in the
midinfrared frequency region are generated by employing
plasmonic diabolo nanoantennas. The strongly confined
magnetic field is used to focus intense magnetic field
pulses on a FM nanowire to excite magnetization dynam-
ics. It is found that the local perturbation of the magnetic
order induced by the direct coupling between the magneti-
zation and nanoconfined magnetic field pulses leads to the
emission of propagating spin waves.
II. PLASMONIC NANOANTENNA FOR OPTICAL
MAGNETIC FIELD ENHANCEMENT
The properties of a plasmonic nanoantenna combined
with FM thin films are studied using finite-difference time
domain (FDTD) simulations, in which Maxwell’s equa-
tions are numerically solved by iteration over time [ 17].
The hybrid plasmonic-FM structure consists of a pair of
Ag nanoantennas, SiO 2spacer layers, and FM thin film. In
the modeling, a 10-nm thick Ni film is used as the magnetic
medium since the optical effect in nickel-rich Permalloy is
very similar to that in Ni in the visible and near-infrared
regions [ 18]. The dielectric permittivity values of Ni are
taken from Johnson and Christy data [ 19]. As shown in
the schematic in Fig. 1(a), the nanoantenna is based on
the diabolo structure, which is a pair of metallic triangular
nanostructures connected by a junction [ 16]. The bottom
nanoantenna is embedded in a SiO 2substrate, whereas
the top counterpart is surrounded by air. The geometry ofthe nanoantenna is 240 ×240×100 nm3, with the junc-
tion of 50 ×50×100 nm3. The 10-nm thick Ni layer is
placed between nanoantennas in which the 5-nm SiO 2
spacer layers electrically insulate the Ni layer from theAg antennas. The maximum magnetic field achievable for
the given geometry of nanoantenna is optimized by vary-
ing the SiO
2spacer layer thickness at a fixed Ni thickness
of 10 nm. The nanoantennas are illuminated with a plane
wave propagating downward along the −zdirection with
its electric field linearly polarized along the ydirection.
At resonance, free electrons in the metallic nanoantennas
are collectively excited by the electric field of the incident
light, and, consequently, a highly localized magnetic field
is generated by the electrical current flowing through the
junction. Figure 1(b) shows the spectral response of the
normalized magnetic field intensity |BR|2/|Bo|2.BRcorre-
sponds to the magnetic field at resonance generated inside
the magnetic medium between the nanoantenna junction,
whereas Bois the magnetic field of the incident light. It
is found that the nanoantennas support a strong magnetic
resonance, which occurs in the infrared regime with a cen-
tral wavelength of 2.74 µm. At the magnetic resonance,
the magnetic field intensity is enhanced by more than two
orders of magnitude compared to that of the incident light.
Figure 2(a)illustrates the spatial distribution of the nor-
malized magnetic field intensity, |BR|2/|Bo|2, calculated
inside the magnetic medium under the magnetic resonance
condition. A magnetic hotspot, where the intense mag-
netic field is spatially concentrated, is generated between
nanoantenna junctions. This strong confinement provides
an opportunity to focus intense magnetic fields into a small
region while overcoming the restriction of the diffraction
limit defined by the Rayleigh criterion in optical excita-
tions. Figure 2(b) represents the time trace of the normal-
ized magnetic field BRas compared to the optical magnetic
field component Boof the incident light. It reveals the
(a) (b)
FIG. 1. (a) Schematic diagram of a sandwich diabolo nanoantenna with w=240 nm, d=240 nm, h=100 nm, and j=50 nm. The
layer between diabolo nanostructures is composed of SiO 2(5 nm)/Ni (10 nm)/SiO 2(5 nm). A plane wave is incident from the top with
its electric field Ealong the ydirection. The magnetic field is generated in the junction along the xdirection. (b) Spectral response of
the normalized magnetic field intensity |BR|2/|Bo|2as a function of the wavelength of incident light. The intensity is calculated inside
the magnetic medium between the junctions. The magnetic resonance occurs in the infrared regime, centered at 2.74 µm.
044028-2MAGNETIZATION DYNAMICS INDUCED. . . PHYS. REV. APPLIED 11,044028 (2019)
(a) (b)
FIG. 2. (a) Spatial distribution of the normalized magnetic field intensity, |BR|2/|Bo|2,i nt h e xyplane inside the magnetic medium.
The position of the diabolo nanoantenna is indicated by the dotted line. Intense magnetic field is spatially concentrated between
nanoantenna junctions. (b) Temporal profile of the normalized magnetic field, BR/Bo, at resonance. Red curve represents the optical
magnetic field component Boof the incident light.
characteristic of damped harmonic oscillator with the fre-
quency of 108 THz, and its peak magnetic field is increased
more than 12 times compared to the optical magnetic field
of the incident light (shown as red). It is noteworthy that
the duration of the induced magnetic field BRis signifi-
cantly longer compared to that of the incident field Bo. This
is an intrinsic property of the plasmonic resonator, in which
the electric current continues to oscillate in the junction
even after the termination of the incident light. This res-
onating behavior of the plasmonic nanoantenna provides
both the magnetic field enhancement and the elongation
of the magnetic pulse duration. Given the strong confine-
ment of the intense magnetic field, the nanoantenna can
be used as a nanoscale-sized source of magnetic fields,
which can locally manipulate the magnetism on ultrashort
time scales. In order to explore this potential, the dynamic
properties of FM nanoelements in response to the appli-
cation of a locally confined magnetic field is numerically
investigated.
III. MAGNETIZATION EXCITATION BY
NANOCONFINED MAGNETIC FIELD PULSE
The ultrafast manipulation of the magnetization with
magnetic fields and its effect on the magnetization
dynamics on a longer time scale are studied using
micromagnetic finite-element modeling based on the Lan-
dau–Lifshitz–Gilbert equation [ 20,21]
dM/dt=− |γ/(1+α2)|(M×Beff)−|(αγ)/ [M S(1+α2)]|
×[M×(M×Beff)].
Here, γis the gyroscopic ratio and αis a phenomeno-
logical damping constant. Beffis the total effective field
acting on the magnetization M, which mainly includes
the applied external field, the exchange interaction, and
the demagnetizing field. In modeling, a 10-nm thick
Permalloy (Ni 80Fe20) waveguide with lateral dimensionsof 120 nm ×4µm is subdivided into homogeneously mag-
netized unit cells of the dimension 5 ×5×5n m3.T h e
unit cell size is comparable to the exchange length of
Permalloy [ 22]. The material parameters used in the mod-
eling are: saturation magnetization ( M S=800 emu/cm3),
exchange stiffness ( A=1.05×10−6ergs/cm), and damp-
ing constant ( α=0.008). The modeling is carried out at
0 K. A damping boundary condition, in which the damping
constant is gradually increased at both ends of the waveg-
uide, is applied in order to suppress the reflection of spin
waves [ 23]. A uniform bias magnetic field of 400 mT is
applied along the ydirection so that the magnetization in
the waveguide is aligned perpendicular to the long axis
of the magnetic element. In order to excite the magnetiza-
tion, the temporally varying magnetic field BR, which has
the same temporal profile as that in Fig. 2(b), is applied
along the xdirection in the middle of the waveguide. In
order to model the nanoconfinement of BR, the magnetic
field is focused within the area of 120 ×60 nm2in the
middle section of the magnetic waveguide. The position
of the localized BRregion is marked with a dashed box, as
shown in the inset of Fig. 3(b).BRis assumed to be uni-
form throughout the thickness of the magnetic film within
the area. The peak magnetic field of 50 mT is used in the
modeling, which is experimentally achievable by employ-
ing diabolo nanoantennas with laser fluence as low as
0.1 mJ/cm2. From a practical application point of view, it is
important to control the plasmonic enhanced electric fieldand heat generation in nanodevices under critical limits in
order to avoid an extreme influence of electromigration and
heat dissipation from the metallic element to the adjacent
SiO
2and FM layers [ 24]. FDTD calculation confirms a
considerable electric field enhancement, mainly at the end
sides of the nanoantenna elements, up to 8.8 MV/m with a
fluence of 0.1 mJ/cm2. This enhanced electric field, how-
ever, is much smaller compared to the previously reported
field of 100 GV/m, which was estimated in a tunneling gap
with dimensions of a few nanometers and did not cause
044028-3B.C. CHOI PHYS. REV. APPLIED 11,044028 (2019)
(a) (b)
FIG. 3. Temporal responses of out-of-plane magnetization
components M z(t) and in-plane components M x(t) for the time
intervals: (a) from 0 to 450 fs and (b) from 1 to 800 ps. A mag-netic field pulse is applied along the xdirection at t=0f s .C u r v e s
are vertically shifted for comparison. ( inset ) Dashed box marks
the position of the localized magnetic near field region, whilethe probing areas P
1and P2are represented with dotted circles
with diameters of 20 nm. P2is located 200 nm away from the
center of P1. Red and blue curves in (a) and (b) correspond to
the local magnetic responses averaged over the areas P1and P2,
respectively.
damage of nanodevices [ 25]. The plasmonic enhancement
of temperature in nanostructures is also calculated using
the general expression of heat generation [ 26]. The cal-
culation with the fluence value of 0.1 mJ/cm2predicts
a maximum temperature of 1030 K at electric hotspots,
which is well below the melting temperature of 1235 K for
Ag. The conductive heat transfer from Ag nanoantennas to
SiO 2and FM layers is investigated using the finite-element
analysis modeling software COMSOL MULTIPHYSICS [27].
The resulting temperature distribution indicates that the
temperature increase in the magnetic layer is negligible due
to the low thermal conductivity of the SiO 2layer [ 28].
Figure 3(a) shows the dynamic responses of the local
magnetization M x(t)a n d M z(t) for the first 450 fs after
applying BRat time t=0 fs. The response of the magneti-
zation is spatially averaged over the areas with a diameter
of 20 nm, which are located at P1, that is, within the exci-
tation field region, and at P2, that is, 200 nm away from the
center of P1along the long axis of the waveguide, respec-
tively. An important observation is the drastic difference
in the dynamic response between the components M xand
M zmeasured over P1, in which the out-of-plane magne-
tization component M zexhibits a large change whereas
the response of the in-plane component M xis insignifi-
cant. The change of the M ycomponent is also very small
and is not shown. The dominance of the M zcomponent
in the magnetization dynamics is attributed to the fieldconfiguration of M⊥B
R, in which the magnetization vec-
torMexperiences the Zeeman torque ( M×BR) that leads
to a significant out-of-plane magnetization contribution to
the dynamics. A distinct feature found in M z(t) is that themagnetization oscillation with the frequency of approxi-
mately 100 THz is directly coupled to the driving magnetic
field. The magnetization oscillates coherently with BR,
and the oscillation amplitude decays with decreasing field
amplitude of BR. This result is in a qualitative agreement
with the previous report by Shalaby et al. in which a THz-
induced coherent oscillation of the magnetization in 15-nm
thick Co film was observed [ 29]. The direct coupling of
the magnetization dynamics with BRis further corrobo-
rated by comparing the magnetic response averaged over
the probing area P2, which is located outside the spatially
confined magnetic field. As expected, no measurable mag-
netic response is found outside the BRregion due to the
absence of the Zeeman torque.
Interesting features of the magnetization dynamics
appear after the near complete relaxation of the BRfield-
driven coherent magnetization oscillation. Figure 3(b)
shows the temporal changes of M xand M zcomponents,
averaged over P1and P2, for longer time scales t>1p s .I n
contrast to the BRfield-induced magnetization dynamics
shown in Fig. 3(a), dynamic components of the magneti-
zation appear not only within the BRexcitation region, but
also in the adjacent region. Moreover, oscillatory behav-
iors become noticeable in both the M xand M zcomponents.
This implies that the BR-induced perturbation in the mag-
netic order within the P1region acts as the source of the
delayed magnetic response in the form of magnetization
precession in the vicinity of the excitation field region.
From a microscopic point of view, the observation of the
magnetization precession outside the BRfield region can
be interpreted to be the result of the excitation of propagat-
ing spin waves, in which the waves travel perpendicular to
the direction of the static magnetization. The spin waves
excited in this static magnetization-magnetic field con-
figuration correspond to the Damon-Eshbach (DE) mode
[30]. The spin wave excitation is attributed to the rapid
relaxational process of the magnetization dynamics from
BR-induced nonequilibrium state, in which the excess of
magnetic energy is transformed into spin waves. In gen-
eral, the magnetization relaxation from magnetic nonequi-
librium is accompanied by the change of the energy in the
magnetic system. It was discussed by Suhl and Safonov
that the energy released during relaxation can be accom-
modated by spin waves [ 31,32]. Since the modulation of
spin waves is mediated by the short-range exchange inter-
action of precessing magnetic moments, the characteristic
time of such a modulation is given by the precessional fre-
quency, which is typically in the range of a few gigahertz
in FM materials [ 33].
Further insight into the details of propagating spin
waves can be obtained by analyzing the spatiallydependent dynamic components of the magnetization.
Figure 4(a)shows the temporal scans of the M
xcomponent
averaged over the areas of 20 nm in diameter at vari-
ous distances from the BRexcitation region. The probing
044028-4MAGNETIZATION DYNAMICS INDUCED. . . PHYS. REV. APPLIED 11,044028 (2019)
(a) (b)
FIG. 4. (a) Temporal properties of spin waves measured at var-
ious probing positions along the long axis of the waveguide.
Numbers indicate the distance between BRexcitation and prob-
ing regions. A burst of spin waves is launched from the excitationregion and propagates along the waveguide. Curves are vertically
shifted for comparison. (b) Frequency spectrum reveals a main
peak corresponding the spin wave mode at 20 GHz. The peak at13 GHz is associated with the spin wave mode propagating along
the waveguide edge. ( Inset ) The FFT amplitude distributions are
shown for the frequencies of 13 and 20 GHz, respectively.
positions are equidistantly separated by 200 nm along the
long axis of the waveguide. At the probing position at a
distance of 200 nm from the center of the BRexcitation
region, one observes that a burst of spin waves is emit-
ted from the excitation field region and travels away with
time. The propagating spin waves lead to the formation of
a spin wave packet. The amplitude of spin waves gradu-
ally decreases due to the intrinsic damping of the magnetic
medium. The spin wave velocity of approximately 1 km/s
is estimated from the time delay of the shift of the wave
packets probed at different positions. One also observes
the formation of the higher-frequency wave packets with
very small amplitudes, which can be clearly seen at the
positions of 400 and 600 nm. The propagation veloc-
ity of these high-frequency spin waves is slightly higher
and estimated at approximately 1.2 km/s. These values
are in the comparable range as those previously reported
spin wave velocities measured in Permalloy microstrips
[34]. Figure 4(b) is the result of the fast Fourier trans-
form (FFT) analysis of the data shown in Fig. 4(a).T h e
frequency spectrum reveals a predominant peak at approx-
imately 20 GHz, which corresponds to the major spin wave
mode. The images shown in the inset of Fig. 4(b) are the
FFT amplitude distributions captured at frequencies of 13
and 20 GHz, respectively. The spin waves at 20 GHz are
strongly focused in the middle region of the waveguide.
In contrast, the spin wave mode at 13 GHz is localized
along the edges. The 13-GHz mode is associated with thespin waves propagating along the waveguide edge, which
is attributed to the presence of the narrow waveguiding
channels induced by the edge potential wells due to the
nonuniform distribution of the internal static magnetic fieldnear the edges [ 35]. The excitation of such an edge mode in
submicrometer magnonic waveguides has been previously
observed by Xing et al.[36].
IV . CONCLUSIONS
We demonstrate that plasmonic nanoantennas are capa-
ble of generating intense magnetic fields in the mid-IR
region. Since the magnetic fields are highly confined, they
are ideally suited as nanoscale-sized sources of magnetic
fields, which can effectively manipulate the magnetism
within a very short time scale. Micromagnetic numerical
results demonstrate the coherent oscillation of the magne-
tization upon excitation by nanoconfined magnetic fields,which is followed by the emission of propagating spin
waves with a few GHz frequencies. Considering the sig-
nificant current challenges of effectively coupling spins in
nanoscale magnetic elements to the magnetic component
of the electromagnetic fields, the result offers the strong
potential of plasmonic nanoantennas in the application of
spintronics.
ACKNOWLEDGMENTS
The author acknowledges funding from the NSERC
(Canada) Discovery Grants program. It is a pleasure to
acknowledge fruitful discussions with Professor Reuven
Gordon.
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044028-6 |
PhysRevB.103.094430.pdf | PHYSICAL REVIEW B 103, 094430 (2021)
Spin to charge conversion in Si/Cu/ferromagnet systems investigated by ac inductive measurements
Ei Shigematsu,1Lukas Liensberger,2,3Mathias Weiler ,2,3,*Ryo Ohshima ,1Yuichiro Ando,1
Teruya Shinjo,1Hans Huebl ,2,3,4and Masashi Shiraishi1,†
1Department of Electronics Science and Engineering, Kyoto University, 615–8510 Kyoto, Japan
2Walther-Meißner-Institut, Bayerische Akademie der Wissenschaften, 85748 Garching, Germany
3Physik-Department, Technische Universität München, 85748 Garching, Germany
4Munich Center for Quantum Science and Technology (MCQST), 80799 München, Germany
(Received 17 June 2020; revised 7 December 2020; accepted 2 March 2021; published 19 March 2021)
Semiconductor/ferromagnet hybrid systems are attractive platforms for investigation of spin conversion
physics, such as the (inverse) spin Hall effect. However, the superimposed rectification currents originating fromanisotropic magnetoresistance have been a serious problem preventing unambiguous detection of dc spin Hallelectric signals in semiconductors. In this study, we applied a microwave frequency inductive technique immuneto such rectification effects to investigate the spin to charge conversion in heterostructures based on Si, oneof the primitive semiconductors. The Si doping dependence of the spin-orbit torque conductivity was obtainedfor the Si/Cu/NiFe trilayer system. A monotonous modulation of the spin-orbit torque conductivity by dopingand relative sign change of spin to charge conversion between the degenerate n-a n d p-type Si samples were
observed. These results unveil spin to charge conversion mechanisms in semiconductor/metal heterostructuresand show a pathway for further exploration of spin-conversion physics in metal/semiconductor heterostructures.
DOI: 10.1103/PhysRevB.103.094430
I. INTRODUCTION
Spin to charge conversion [ 1–3] has been one of the central
research topics in spintronics, evoking both scientific interestand expectation for industrial applications. This phenomenonenables an observation of spin current as an electromotiveforce by using the spin-orbit interaction (SOI) and spin-dependent momentum scattering, even though spin currentis not a conservative quantity and one cannot measure it di-rectly. Therefore, spin to charge conversion has been regardedas an important research target in the field of spintronics,and its efficiency factors, i.e., spin Hall conductivity, spinHall angle, and Rashba-Edelstein length, have been identi-fied as crucial indices in spintronic materials. Most reportson spin to charge conversion are limited to metallic materi-als, some of which exhibit high conversion efficiency due totheir large SOI [ 4]. Besides investigations of primitive spin
conversion characteristics, control over the spin to chargeconversion properties is also an intriguing research issue. Inthis viewpoint, semiconductors are a promising research field,which unites flourishing spintronic physics with conventionalsemiconductor physics since carrier concentration in semicon-ductors can be modulated by doping and gating. For example,strong SOI in heavily doped semiconductor silicon [ 5] and
modulation of the inverse spin Hall effect in GaAs [ 6]w e r e
demonstrated.
*Present address: Technische Universität Kaiserslautern, 67663
Kaiserslautern, Germany.
†mshiraishi@kuee.kyoto-u.ac.jpA typical experimental implementation of spin to charge
conversion consists of (i) injection of spin current from aferromagnetic material and (ii) spin to charge conversion inan adjacent material. To realize this scheme, spin pumping indetector material/ferromagnet bilayer systems is widely em-ployed, where the detector material is spin Hall active. Variousnonmagnetic [ 2,7,8] or ferromagnetic materials [ 9–11] can be
used as a spin detector. Spin pumping is the phenomenonwhich induces spin current flow driven by exciting ferro-magnet resonance (FMR) in the magnetically ordered layer[2,12–14]. Most reports on spin-pumping experiments em-
ployed dc detection of spin to charge conversion electromotiveforces with in-plane magnetization of the ferromagnet. Thisexperimental scheme has been the basis for many reports onspintronic properties of various materials such as nonmagneticmetals [ 2,7,8], semimetals [ 15,16], semiconductors [ 5,6], and
topological insulators [ 17]. However, an influence of the rec-
tification effects in the ferromagnetic metal [ 18–21] hinders
precise evaluation of spin to charge-conversion-related dcsignals. Additionally, in some combinations of nonmagneticand ferromagnetic materials, a contribution of the thermo-electric signal caused by spin-wave dynamics gives rise tothermally induced spurious signals [ 22–24]. Complementary
to the dc voltage detection technique, a new method whichis immune to the aforementioned spurious signals, the acinductive method, was proposed by Berger et al. [25,26]. In
this experimental approach, a static magnetic field is appliedalong the normal of a thin-film nonmagnetic/ferromagneticbilayer and an ac magnetic field is applied using an adjacentmicrostrip line. An ac spin current is injected into the non-magnetic material, which gets converted into an ac electriccurrent via the spin to charge conversion. The generated ac
2469-9950/2021/103(9)/094430(8) 094430-1 ©2021 American Physical SocietyEI SHIGEMATSU et al. PHYSICAL REVIEW B 103, 094430 (2021)
TABLE I. Specifications of the silicon wafers regarding the ion implantation: dopant, acceleration voltage, and area dose. According to the
targeted doping concentration, we adjusted the acceleration voltage and area dose based on the SRIM simulations.
No. Dopant/targeted concentration [cm−3] Dose (10 keV) [cm−2] Dose (15 keV) [cm−2] Dose (30 keV) [cm−2]
1 Phosphorus /1×10201×10145×1014
2 Phosphorus /1×10191×10135×1013
3 Phosphorus /1×10181×10125×1012
4 Nondoped
5 Boron /1×10183×10125×1012
6 Boron /1×10193×10135×1013
7 Boron /1×10203×10145×1014
current causes inductive voltages in the microstrip line, which
result in perturbation of the transmission signal. By analyz-ing the transmission signal, the spin-orbit torque conductivity
(σ
SOT) in, e.g., Pt /Ni80Fe20(Permalloy, Py) and Cu/Py bi-
layers can be calculated in a self-consistent way [ 26]. The
spin-orbit torque conductivity quantifies the charge conver-sion efficiency starting from the precession dynamics of spinsin the ferromagnet, including all the intermediating processes:spin current generation, spin current transmission through theinterfaces, and spin to charge conversion.
We employed this method to investigate the spin to charge
conversion physics in semiconductor-metal-ferromagnet hy-brid devices. We thereby chose silicon, the vital material ofmodern electronics, and study the Si doping dependence ofthe spin-orbit torque conductivity of Si/Cu/Py trilayers.
II. EXPERIMENT
Dopant ions are implanted in commercially available
Silicon-on-Insulator (SOI) wafers, which consist of a Si baselayer (nominal resistivity is 1 ∼2/Omega1m) and a 200-nm-thick
SiO
2layer, and the top 100-nm-thick Si layer (nominal resis-
tivity is 30 ∼40/Omega1m). The acceleration voltage was set to be
10 and 30 keV for phosphorus, and 10 and 15 keV for boron,respectively. Each dose was determined by SRIM (Stoppingand Range of Ions in Matter) simulations beforehand to forma uniform doping profile along the depth direction. The de-tailed recipe of the ion implantation is presented in Table I.
The doped wafers were treated in a rapid thermal annealingsystem for activation of the dopants. The measured resistivityof each implanted wafer is shown in Fig. 1. The heavier
doping yielded the smaller resistivity in both phosphorus andboron doping. We cut the wafers into chips of 9 ×8m m
in size. After removing the natural oxidation layer by 10%hydrogen fluoride (HF) solution, a 3-nm-thick Cu interlayerand a 7-nm-thick Py layer were deposited by an electron-beamdeposition system. The inserted Cu layer prevents the inter-mixing between Si and Py, enabling more qualified interfacepreparation. Cu is also known for being a good conductorof spin current, the spin-diffusion length of which is ca. 500nm [ 27], which allows for a transparent spin current channel
between Py and Si. The observed effective magnetization ofthe Py layer is comparable to that of intrinsic Py.
After fabrication of the samples, we followed the measure-
ment procedure described in the literature [ 25]. As shown
in Fig. 2, the ground signal ground (GSG)-type coplanar
waveguide (CPW) was connected to the vector network an-alyzer (VNA, N5225B, Keysight Technologies). The sample
was placed on the CPW. A dc static magnetic field was appliedperpendicular to the sample plane by an electromagnet. Whilethe rf signal was transmitted from one port of the VNA to ex-cite the FMR of the Py layer, the dc magnetic field was sweptaround the FMR resonance field of Py. The transmission sig-nalS
21was measured at fixed frequency while stepping the dc
magnetic field. These experiments were carried out for fixedfrequencies from 10 to 30 GHz.
III. MODELING
The resonance field of the Py film follows the out-of-plane-
type Kittel equation,
ω
γ=μ0(Hres−Meff). (1)
Here, ω,γ,μ0,Hres, and Meffare angular frequency,
gyromagnetic ratio, vacuum permeability, resonance mag-netic field, and effective magnetization, respectively. Theaforementioned measurement scheme yields the complextransmission signal ( S
21) as a function of the external dc
magnetic field. Under the FMR condition of the Py layer,an ac spin current is injected into the adjacent nonmagneticlayers consisting of the Cu (3 nm) layer and the Si (100 nm)layer. When the ac spin current is converted to an ac chargecurrent in the direction parallel to the CPW, the correspondingcharge carriers give rise to an ac voltage response in the CPW.This can be understood as a change of the inductance of the
FIG. 1. Resistivity of the 100-nm-thick Si layers of the implanted
SOI wafers probed by four-terminal resistance measurements.
094430-2SPIN TO CHARGE CONVERSION … PHYSICAL REVIEW B 103, 094430 (2021)
FIG. 2. Schematic illustration of the setup for the complex trans-
mission measurement S21. The CPW is connected with the two ports
of the VNA using rf cables. The sample was placed on the CPW
facing the Py. In addition, the figure shows the lumped elementcircuit model of the system, where the rf cables, the CPW, and the
inductance lump of the sample are connected in series.
composite system of the CPW and the sample causing the
modulation of S21. By considering the continuity of voltage
and current in a lumped element model of the whole systemconsisting of the serially connected rf cables, one can formu-late an equation describing the inductive signal generation.Under the off-resonant condition, the continuity of the voltagebetween point A and point B in Fig. 2gives
v
i+vr−vt=jωLi. (2)
The continuity at the points A and B yields,
vi
Z0−vr
Z0=i, (3a)
vt
Z0=i, (3b)
respectively. Here, vi,vr, and vtare entering, reflecting, and
transmitting voltage amplitude (complex value). Landiare
the off-resonant inductance and the current in the region be-tween point A and point B. The characteristic impedance ofthe cables and the CPW is nominally 50 /Omega1. After solving these
equations, the transmission S
21is expressed as below,
S21=vt
vi=2Z0
2Z0+jωL. (4)
When Lchanges to L+/Delta1Lunder the resonance condition,
the perturbation of the transmission signal ( /Delta1S21) should be
obtained by the partial derivative and its ratio to the baselinebecomes a simple expression,
/Delta1S
21
S21=∂S21
∂L/Delta1L
S21=−jω/Delta1L
2Z0+jωL≈−jω/Delta1L
2Z0. (5)
Note that we neglected the relatively small contribution
of jωLin the denominator. One may be careful about the
dissipation and phase-delay factors through the CPW and thetwo rf cables. These factors, however, are constant in off-and on-resonant states of the ferromagnet and eliminated bydividing by S
21. The change in the inductance /Delta1Lis induced
by (i) the ac dipolar magnetic field under the FMR, (ii) the spinto charge conversion current in odd phase, and (iii) the Fara-day effect and the spin to charge conversion current in even
phase with time reversal. In Fig. 1(d) in Ref. [ 25], the phase
relation among the magnetic amplitude in the ydirection ( m
y),
the odd and even current ( jSOT
o,jSOT
e) via the spin to charge
conversion, and the Faraday current ( jF
e) are shown. Note that
jSOT
ois at the phase quadrature to that of jSOT
eandjF
e, hence we
can extract the inductance purely from jSOT
oby decomposing
an entire observed inductance into real and imaginary parts.The three components which contribute to the on-resonantinductance change have the same origin: precession of themagnetization. Therefore, /Delta1Lis proportional to the polder’s
susceptibility tensor χ(ω,H),
/Delta1L=˜Lχ(ω,H). (6)
The complex value, ˜L, is the normalized inductance, rep-
resenting the dipolar contribution and the spin to chargeconversion. The value of ˜Lcan be determined by a curve
fitting of the S
21spectra as a function of the magnetic field,
/Delta1S21
S21≈−jω˜Lχ(ω,H)
2Z0. (7)
From the spectrum fitting using the measured values of
/Delta1S21
S21(ω,H), one can determine ˜L(ω) and χ(ω,H). The
polder’s susceptibility tensor χ(ω,H) contains the resonance
field and the linewidth of the spectra, from which the magneticparameters of the Py layer were calculated. We emphasizethat the measurement observable is a frequency- and magneticfield-dependent complex microwave transmission. As suchonly signals in the microwave domain are analyzed and hencemake this technique immune to dc voltage signals, as observedin dc spin pumping and rectification experiments.
IV . RESULTS AND DISCUSSION
The gfactor and the effective saturation magnetization,
μ0Meff, of each sample determined by analyzing the reso-
nance field and frequency of the FMR [Fig. 3(a)] are shown
in Figs. 3(b) and3(c), respectively. Whereas the deviations
ofgfactor in all samples are within 0.5%, a notable de-
crease of μ0Meffwas observed for the highly doped samples,
which suggests effects of the adjacent conductive layer onthe saturation magnetization. The Gilbert damping constant,α, and the inhomogeneity broadening, μ
0/Delta1H0, were deter-
mined by the frequency dependence of the linewidth of thespectrum [Fig. 3(d)], where the measured linewidth equals
μ
0/Delta1H0+2αω/γ . As shown in Fig 3(e), the Gilbert damping
constant does not show a discernible trend with doping, but itis scattered within 20% range. Only the highly doped p-type
sample showed a relatively high μ
0/Delta1H0, as shown in Fig. 3(f).
Though some of the magnetic parameters thus exhibit dopingconcentration dependence, the normalization by χ(ω,H)i n
Eq. ( 7) accounts for the possible influence of the small modu-
lation in the magnetic dynamics on ˜L(ω).
Considering the geometry of the CPW, the sample and the
spacing between these two components, ˜Lis expressed as [ 25]
Re(˜L)=μ
0l
4/bracketleftbiggdFM
Wwgη2+η2L21
μ0lMs¯hω
eσSOT
Re/bracketrightbigg
, (8a)
Im(˜L)=μ0l
4·η2L21
μ0lMs¯hω
eσSOT
Im. (8b)
094430-3EI SHIGEMATSU et al. PHYSICAL REVIEW B 103, 094430 (2021)
FIG. 3. Magnetic parameters were obtained by the VNA-FMR for each sample with different doping condition of the Si layer. The
frequency dependence of the FRM resonance field is shown in (a) with the linear fittings, from which (b) gfactor and (c) the effective
magnetization μ0Meffwere determined. The frequency dependence of the linewidth is shown in (d) with the linear fittings, from which (e)
Gilbert damping constant and (f) the inhomogeneity broadening of linewidth, μ0/Delta1H0were determined.
Here, μ0,¯h,e,Msare vacuum magnetic permeability, the
Dirac constant, elementary charge, and the saturation mag-netization of the ferromagnetic film. The geometrical factors:l,W
wg,dFM,η,L21, are the length of the sample, the width
of the CPW signal line, the thickness of the ferromagneticfilm, the spacing loss factor, and the mutual inductance be-tween the CPW and the sample. The real and imaginaryspin-orbit torque conductivity, σ
SOT
ReandσSOT
Im, originate from
the frequency-dependent current generation in the sample.Following Ref. [ 25],σ
SOT
Re comes from the spin to charge
conversion in the even phase and the Faraday current, andσ
SOT
Im from the spin to charge conversion only in the odd
phase. Thus, σSOT
Imcorresponds to the dampinglike conversionfrom magnetization dynamics in the ferromagnetic metal to
charge currents oscillating at the precession frequency. Bothreal and imaginary parts of ˜Lare linear functions of frequency.
Therefore, we can determine σ
SOT
ReandσSOT
Imby linear fitting
of˜Lvs frequency.
In Figs. 4(a) and4(b), the frequency dependence of the
real and imaginary parts of the inductances ˜Lof each sample
are shown. The phase-error correction [ 25] by imposing the
prerequisite that ˜Lshould be a real-valued number at the zero-
frequency limit was already applied here. According to Eqs.(8), the coefficients of linear proportion consist of the geomet-
rical parameters, the magnetic properties of the Py film, andmore importantly, σ
SOT
ReandσSOT
Im. Because the geometrical
094430-4SPIN TO CHARGE CONVERSION … PHYSICAL REVIEW B 103, 094430 (2021)
FIG. 4. (a) Real and (b) imaginary parts of the normalized inductances as a function of the rf frequency measured with the sample group
of different doping conditions. The solid lines are linear fits. From the slopes of these fits, we can calculate the real and imaginary spin-orbittorque conductivities, σ
SOT
ReandσSOT
Im.
parameters are in the same range in the measured samples, a
rough estimation of σSOT
ReandσSOT
Imis given by the steepness
of the linear slopes of Re( ˜L) and Im( ˜L).
To determine the exact value of σSOT
ReandσSOT
Im, a compre-
hensive linear fitting was conducted for Re( ˜L) and Im( ˜L)b y
using the geometrical parameters and the effective saturationmagnetization, M
eff, obtained from the FMR resonance field,
as a saturation magnetization, Ms, appearing in Eqs. ( 8). We
note that the spacing dbetween the CPW and the sample
changes in each measurement, altering η(l,d) and L21(l,d)
defined in Ref. [ 25], but dis analytically determined by the
zero-frequency limit of Re( ˜L), which represents the dipolar
contribution from the magnetic precession of the Py film. Werepeated the determination process of σ
SOT
ReandσSOT
Imfor the
seven samples, with results shown in Figs. 5(a)and5(b).
We first focus on the results for the reference sample with
nondoped Si. Here, we find σSOT
Imof comparable magnitude
to that reported in Ref. [ 26] for a Py/Cu(4.5-nm) bilayer.
TheσSOT
Im for the reference sample may originate from (i)
the inverse spin Hall effect (ISHE) in the Cu interlayer and(ii) the self-induced ISHE [ 28] in the Py layer due to a pos-
sible imbalance of spin absorption at the top and the bottomsurface, and (iii) sizable spin-orbit torques in a ferromagnetitself [ 29–37]. We assume that this spin charge conversion
effect is present in all our samples. To discuss the influenceof doping on spin charge conversion in our Si/Cu/Py trilayers,we then calculate /Delta1σ
SOT
Re/Im=σSOT
Re/Im−σSOT
Re/Im(nondoped Si)
shown in Figs. 5(c) and5(d). The observed /Delta1σSOT
Re/Imare also
on the order of 104/Omega1−1m−1(e. g.,/Delta1σSOT
Imin the most heavily
doped p-type sample), which is in the same magnitude range
as Py/Cu systems [ 25]. Using the Pt-based systems, where
enhanced spin to charge conversion efficiency is expected,previous studies observed a significantly larger spin-orbit
torque conductivity [ 25,26].
We focus on /Delta1σSOT
Imoriginating from the spin to charge
conversion in the odd phase, i.e., with symmetry of theISHE. The calculated /Delta1σ
SOT
Im for each measured sample
is shown in Fig. 5(d). A decreasing trend of /Delta1σSOT
Im with
the transition from n-type to p-type doping was observed.
We note that /Delta1σSOT
Im with the opposite sign relative to that
in the nondoped samples was observed in the n-type and
p-type samples. The minimum change of /Delta1σSOT
Im between
them is 1 .4×104/Omega1−1m−1, considering the fit errors. The
doping concentration for these two samples, 1 ×1020cm−3,
exceeds the effective densities of states of Si in the con-duction band (2 .8×10
19cm−3) and valence band (2 .65×
1019cm−3)[38]. In these doping levels, no depletion layer be-
tween Si and Cu is formed at the Si/Cu interfaces in the n-type
andp-type samples allowing carriers to transverse through the
interface. In this situation [Fig. 6(a) forntype and Fig. 6(b)
forptype), the spin current in the Cu layer can travel through
the interface between the Cu layer and the degenerate Si. Inthis case, a possible ISHE in Si can contribute to spin chargeconversion. In the spin-scattering process associated with theISHE, the directions of the scattered charge are governed byits spin polarization irrespective of its charge. Therefore, whenthe carrier of the Si layer is switched by change of dopant,the sign of θ
SHis also switched. This mechanism can explain
the measured σSOT
Imin the n-type and p-type samples with the
doping concentration of 1 ×1020cm−3. Next, we focus on the
nondegenerate Si samples. Considering the work function ofCu (4.5 eV) [ 39] and the electron affinity (4.05 eV) [ 38]o fS i ,
the ideal band alignment model teaches us the barrier height is0.45 eV . Furthermore, experimental studies reported that the
094430-5EI SHIGEMATSU et al. PHYSICAL REVIEW B 103, 094430 (2021)
FIG. 5. (a) Real spin-orbit torque conductivity ( σSOT
Re) of the measured samples. (b) Imaginary spin-orbit torque conductivity ( σSOT
Im)o f
the measured samples. (c) Change of real spin-orbit torque conductivity ( σSOT
Re) from that of the nondoped sample. (d) Change of imaginary
spin-orbit torque conductivity ( σSOT
Im) from that of the nondoped sample. Beneath the xaxis, the dopant type and doping concentration of each
sample are described.
Fermi level located around the middle of the band gap of Si
in a Cu/Si system [ 40]. Hence, a schematic viewgraph at the
interface can be described as shown in Fig. 6(c) forn-type Si
and Fig. 6(d) forp-type Si. Existence of the depletion layer
FIG. 6. Spatial band diagrams of the interfaces between (a)
n-type degenerate Si/Cu, (b) p-type degenerate Si/Cu, (c) n-type
nondegenerate Si/Cu, (d) p-type nondegenerate Si/Cu. The Fermi
level of Si is indicated with dashed lines and the conduction/valenceband of Si is indicated with solid lines. In the degenerate cases,
carriers can flow into the Si side, where the ISHE takes place. In the
nondegenerate case, carriers are partially blocked at the interface.hinders the Ohmic conduction of spin current through the
Cu/Si interface, resulting in the decrease of the spin-mixingconductance, G
↑↓accompanied by a decrease of /Delta1σSOT
Im.I n
Fig. 5, magnitudes of the /Delta1σSOT
Im of the nondegenerate Si
samples ( n- and ptype, 1018and 1019cm−3) are smaller than
those of the degenerate samples, indicating insufficient ISHEcurrent generation in the Si layer due to the decreased G
↑↓.W e
note that a slight but clear shift of /Delta1σSOT
Imfrom the baseline
of nondoped Si can be seen with the p-type nondegenerate
samples, which is attributed to the fact that the SOI in p-Si is
stronger than that in n-Si at the same doping concentration as
suggested by its band structures.
Finally, we comment on doping dependence of σSOT
Reshown
in Fig. 5(a). According to Ref. [ 25],σSOT
Reequals σF
e−σSOT
e,
where σF
eis the Faraday conductivity and σSOT
eis the spin-
orbit torque conductivity, both of which appear in the evenphase expected for spin to charge conversion by the inverseRashba-Edelstein effect (IREE). Because the Faraday currentdensity depends on the total conductivity of the sample, irre-spective of the carrier type, σ
F
eshould be constant considering
the conductance difference of the stack of the 7-nm-thick Pylayer and the 3-nm-thick Cu layer to the 100-nm Si layer.Therefore, the deviations from the baseline of the /Delta1σ
SOT
Refor
the nondoped sample are tentatively attributed to σSOT
eby the
IREE. In Fig. 5(c), nonzero /Delta1σSOT
e within fit error is only
observed for the degenerate n-doped sample and could be
caused by a Rashba electric field at the Cu/Si interface. For thenondegenerate samples and the degenerate p-doped sample,
no significant change of σ
SOT
e is observed with doping. It
is most likely that the Rashba electric field intensity is not
094430-6SPIN TO CHARGE CONVERSION … PHYSICAL REVIEW B 103, 094430 (2021)
sufficiently strong in the Cu/Si interface for these samples to
induce observable σSOT
eby the IREE.
V . CONCLUSION
In this study, we conducted inductive ac measurements
of Si/Cu/Py trilayer samples with different doping con-centrations in Si. The obtained results indicated successfulmodulation of the spin-orbit torque conductivity of theSi/Cu/Py systems by controlling the Si carrier type and dopingconcentration. A doping dependence of σ
SOT
Im, compatible with
the ISHE in the Si, was observed in the transition from n-type
top-type doping. In the degenerate Si samples, the relative
sign of σSOT
Imchanged between n-type and p-type doping. Our
results are in qualitative agreement with the doping depen-dence of the formation of the depletion layer and its thickness,and by the impurity scattering rate of carriers. This system-atic study of σ
SOT
oof Si/Cu/Py systems with various doping
concentrations provides insight towards exploration for spincurrent physics of semiconductors and demonstrates the ap-
plication of a technique to experimentally determine spin tocharge conversion in ferromagnet/semiconductor hybrids.
ACKNOWLEDGMENTS
E.S. acknowledges the JSPS Research Fellowship for
Young Researchers. E.S. also acknowledges travel supportof Mazume Award (Dept. of Eng., Kyoto University). L.L.and M.W. acknowledge financial support by the Germanresearch foundation (DFG) via Project No. WE 5386/4-1, H.H. acknowledges financial support from the DeutscheForschungsgemeinschaft via Germany’s Excellence StrategyNo. EXC-2111-390814868. This work is partially supportedby a Grant-in-Aid for Scientific Research (S) No. 16H06330,a Grant-in-Aid for Young Scientists (A) No. 16H06089, JSPSKAKENHI Grant No. 17J09520, and Grant-in-Aid for Re-search Activity Start-up No. 20K22413. The ion implantationand the rapid thermal annealing was implemented with thesupport of Nano-technology Platform at Nagoya University.
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094430-8 |
PhysRevB.77.104433.pdf | Origin of the magnetic-field dependence of the nuclear spin-lattice relaxation in iron
G. Seewald, E. Zech, and H.-J. Körner
Physik-Department, Technische Universität München, D-85748 Garching, Germany
D. Borgmann
Institut für Physikalische und Theoretische Chemie, Universität Erlangen-Nürnberg, D-91058 Erlangen, Germany
M. Dietrich
Technische Physik, Universität des Saarlandes, D-66041 Saarbrücken, Germany
ISOLDE Collaboration
CERN, CH-1211 Geneva 23, Switzerland
/H20849Received 6 December 2006; revised manuscript received 23 January 2008; published 24 March 2008 /H20850
The magnetic-field dependence of the nuclear spin-lattice relaxation at Ir impurities in Fe was measured for
fields between 0 and 2 T parallel to the /H20851100 /H20852direction. The reliability of the applied technique of nuclear
magnetic resonance on oriented nuclei was demonstrated by measurements at different radio-frequency /H20849rf/H20850
field strengths. The interpretation of the relaxation curves, which used transition rates to describe the excitationof the nuclear spins by a frequency-modulated rf field, was confirmed by model calculations. The magnetic-field dependence of the so-called enhancement factor for rf fields, which is closely related to the magnetic-fielddependence of the spin-lattice relaxation, was also measured. For several magnetic-field-dependent relaxationmechanisms, the form and the magnitude of the field dependence were derived. Only the relaxation viaeddy-current damping and Gilbert damping could explain the observed field dependence. Using reasonablevalues of the damping parameters, the field dependence could perfectly be described. This relaxation mecha-nism is, therefore, identified as the origin of the magnetic-field dependence of the spin-lattice relaxation in Fe.The detailed theory, as well as an approximate expression, is derived, and the dependences on the wave vector,the resonance frequency, the conductivity, the temperature, and the surface conditions are discussed. The theoryis related to previous attempts to understand the field dependence of the relaxation, and it is used to reinterpretprevious relaxation experiments in Fe. Moreover, it is predicted that the field dependences of the relaxation inFe and Co, on one side, and in Ni, on the other side, differ substantially, and it is suggested that the literaturevalues of the high-field limits of the relaxation constants in Fe are slightly too large.
DOI: 10.1103/PhysRevB.77.104433 PACS number /H20849s/H20850: 76.60.Es, 75.50.Bb, 75.30.Ds, 76.80. /H11001y
I. INTRODUCTION
The magnetic-field dependence of the nuclear spin-lattice
relaxation in Fe, Co, and Ni had been an unsolved problemfor more than 30 years.
1–3The effect typically manifests it-
self at low applied magnetic fields by relaxation rates that are2–10 times larger than in the high-field limit, which is essen-tially reached within applied fields of the order of 1 T. Sincethere is a close relation between the spin-lattice relaxationand low-frequency magnetic-moment fluctuations,
4,5the lack
of an explanation would point to a fundamental deficiency inour understanding of the moment fluctuations in Fe, Co, andNi. This was the motivation to obtain more information onthe effect.
A phenomenological description of the effect had been
proposed by Kopp and Klein: According to their enhance-ment factor model /H20849EFM /H20850, the field-dependent part of the
spin-lattice relaxation is proportional to the square of theNMR enhancement factor.
6In this way, the magnetic-field
dependence of the relaxation is attributed to the magnetic-field dependence of the enhancement factor. The EFM pro-vided a description of the field dependence of the relaxationin polycrystalline samples,
6,7and it was consistent with the
main features of the field dependence in single-crystalsamples, in particular, with the occurrence of peaks for cer-
tain directions of the magnetic field.2
However, a critical experimental test of the EFM was still
missing, because in polycrystalline samples, the field depen-dence of the enhancement factor is not well known, and thefew relaxation experiments on single-crystal samples
8,9had
not been interpreted quantitatively by the EFM. In this work,a single-crystal sample was used and the magnetic field wasapplied along the /H20851100 /H20852direction. The field dependence of
the enhancement factor is well known for that geometry.Moreover, it was also determined experimentally. This en-abled us to establish the actual relationship between the re-laxation and the enhancement factor. It turned out to differfrom the postulated quadratic dependence on the enhance-ment factor.
In context with the field dependence of the spin-lattice
relaxation in Fe, Co, and Ni, several relaxation mechanismshad been discussed, but none of those could explain theeffect.
1,8,10–12It had been speculated that this failure might
not be due to the inadequacy of the proposed relaxation
mechanisms, but due to an incomplete knowledge of themagnetization behavior, the band structure, or the spin-wavedispersion.
9,13,14The precise data and the close examination
of those mechanisms in this work show, however, that thosespeculations are not true. In contrast, it turns out that anPHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
1098-0121/2008/77 /H2084910/H20850/104433 /H2084920/H20850 ©2008 The American Physical Society 104433-1important mechanism has been ignored so far, the relaxation
via eddy currents and Gilbert damping. The theory of thisrelaxation mechanism is derived and it is shown that it canexplain the observed field dependence.
Since the reliability of relaxation measurements by
nuclear magnetic resonance on oriented nuclei /H20849NMR-ON /H20850,
the technique that was used in this work, had been ques-tioned in the past,
3,7,14the theory of NMR-ON was also re-
examined. In particular, the practice to use transition rates todescribe the effect of a coherent rf field on the sublevelpopulations had been doubted. Therefore, model calculationsthat showed under which conditions that practice is justifiedwere performed. In addition, the reliability of the techniquewas tested by measurements at different rf-field strengths.
The relaxation measurements were performed on radioac-
tive
186Ir and189Ir nuclei, which were coimplanted into the
Fe sample. One part of the experiment, the determination ofthe electric-quadrupolar contribution to the relaxation by thecomparison of the relaxations of both isotopes, was alreadytreated in Ref. 15. The present work is mainly concerned
with the form and the magnitude of the field dependence of
the relaxation, which were deduced from the data on
186Ir.
II. ENHANCEMENT FACTOR
The NMR enhancement factor /H9257in ferromagnets is de-
fined as the ratio of the effective rf magnetic field at thenuclear site to the applied rf field.
16It takes into account that
the magnetization and the hyperfine field are slightly dis-placed toward the instantaneous direction of the rf field. Theresulting transverse component of the hyperfine field acts atthe nuclear site as an additional rf field, which is much largerthan the applied rf field. It can be shown that
/H9257=1+BHF
B/H9257/H11015BHF
B/H9257, /H208491/H20850
where BHFis the hyperfine field and B/H9257is the effective field
that holds the magnetization in its equilibrium position. Anappropriate expression to calculate B
/H9257as a function of the
applied magnetic field Bextis given in Refs. 8and17.
Within the EFM of Ref. 6, the relaxation rate Ris the sum
of a high-field limit and a field-dependent contribution that isproportional to
/H92572. To increase the flexibility of the model,
we assume that the latter contribution is proportional to /H9257/H9264,
where the exponent /H9264is not necessarily 2:
R/H20849Bext/H20850=R/H20849/H11009/H20850+/H20851R/H208490/H20850−R/H20849/H11009/H20850/H20852/H20875/H9257/H20849Bext/H20850
/H9257/H208490/H20850/H20876/H9264
. /H208492/H20850
The original idea behind the EFM was that the internal
fields that are responsible for the field-dependent part of therelaxation are similarly enhanced as the rf field. The weakpoint of that idea was that those internal fields had neverbeen specified. Nevertheless, it makes sense to try to de-scribe the field dependence in terms of
/H9257, since /H9257can be
viewed just as a synonym of B/H9257−1. In this sense, /H9257is relevant
for the long-wavelength magnetic excitations of the systemin several ways: For example,
/H9257is essentially equivalent to
the transversal susceptibility, which describes the displace-ment of the magnetization in response to forces that act on
the magnetization as a whole. However, /H9257is also inversely
proportional to the lowest frequency of the spin-wave spec-trum.
In this work, the magnetic field was applied along the
/H20851001 /H20852direction in the /H20849110 /H20850plane of a Fe single-crystal disk.
The rf field was also applied within the sample plane. Forthat geometry, B
/H9257is well known:
B/H9257=BaforBext/H33355Bdem/H208490/H20850,
B/H9257=Ba+Bext−Bdem/H208490/H20850forBext/H11022Bdem/H208490/H20850. /H208493/H20850
Here, Bais the anisotropy field /H208490.059 T in Fe /H20850andBdem/H208490/H20850is
the magnitude of the demagnetization field for the fully mag-netized sample.
The independence from B
extforBext/H33355Bdem/H208490/H20850is due to the
shielding of Bextby the demagnetization field: The shielding
is complete during the magnetization of the sample when thedomains with the magnetization parallel to B
extgrow at the
expense of the other domains. The magnetization of the
sample is completed at Bext=Bdem/H208490/H20850, which thus marks the
transition from the multidomain to the one-domain regime.
Two features of Eqs. /H208491/H20850and /H208493/H20850deserve special attention.
First, the frequency dependence of /H9257is neglected, because
the relevant electronic resonance frequency, which is of theorder of
/H20849
/H9253e/2/H9266/H20850/H20849B/H92574/H9266M/H208501/2/H3335610.6 GHz,
is much larger than the frequencies applied in this work.
Second, to obtain the correct dependence on Bdem/H208490/H20850, it must be
taken into account that, due to the skin effect, the magneti-zation Mis displaced by the rf field only in a very thin
surface layer. The demagnetization field in that layer is notdisplaced, since it originates largely from the rest of thesample. Therefore, the demagnetization field of the undis-turbed sample acts on Mof the surface layer like an external
field. This gives in the end the dependence on B
dem/H208490/H20850of
Eq. /H208493/H20850.
III. FIELD-DEPENDENT RELAXATION MECHANISMS
Spin-lattice relaxation rates in metals are specified by the
reciprocal value of the Korringa constant, R=/H20849T1T/H20850−1. Usu-
ally, the dominant relaxation mechanism is the scattering ofconduction electrons via the hyperfine interaction at thenuclear site,
18,19and Ris magnetic-field independent, be-
cause the involved matrix elements and densities of states arepractically field independent. In this section, we discuss sev-eral mechanisms by which the ferromagnetism can introducea field dependence. They have in common that they arisefrom the coupling of the nuclear spin to the magnetizationvector. Since, in this case, the susceptibility formalismproves to be convenient, it is discussed first.
A. Susceptibility formalism
1. Formalism
Within the susceptibility formalism,4,11,20SEEWALD et al. PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-2R=kB
/H6036K2
/H6036/H9275n/H20849/H6036/H9253e/H2085022V
/H208492/H9266/H208503/H20885Im/H20851/H9273/H20849q,/H9275n/H20850/H20852d3q. /H208494/H20850
Here, Kis the coupling constant between the nuclear and the
electronic spins, /H9273/H20849q,/H9275/H20850is the transversal dynamical suscep-
tibility in units of the induced magnetic moment per atomand magnetic-field unit, Vis the volume per atom,
/H9253eis the
gyromagnetic ratio of the electron spins, and /H9275nis the
nuclear precession frequency.
The magnitude of /H9275nis 2/H9266/H9263nand the sign is given by
sgn /H20849/H9275n/H20850= − sgn /H20849BHF/H20850sgn /H20849/H9253n/H20850, /H208495/H20850
whereas the nuclear resonance frequency /H9263nis defined in this
work as a positive quantity. /H9253nis the nuclear gyromagnetic
ratio. In connection with the sign of /H9275n, it should be noted
that the decisive sign is
sgn /H20849/H9275n/H9253e/H20850= − sgn /H20849BHF/H20850sgn /H20849/H9253n/H20850sgn /H20849/H9253e/H20850, /H208496/H20850
which is negative if the nuclear and the electronic spins pre-
cess in the same sense and positive if they precess in theopposite sense.
If several different coupling constants and electronic mag-
netic moments contribute to the spin-lattice relaxation, eachcontribution is given by an expression of the form of Eq. /H208494/H20850.
In this section, almost exclusively the contribution from thecoupling to the magnetization vector via the static hyperfineinteraction is discussed. R
swdenotes the respective contribu-
tion to the relaxation constant. The coupling constant in thecase of R
swis the static hyperfine coupling constant11,21,22
K=/H20849/H6036/H9275HF/H20850/S/H11015/H20849/H6036/H9275n/H20850/S, /H208497/H20850
where S=/H20849MV /H20850//H20849/H6036/H20841/H9253e/H20841/H20850is the electronic spin and /H9275HFis the
precession frequency due to the static hyperfine field. Forsimplicity, in this context,
/H9275HFis approximated by /H9275n, as-
suming BHF/H11271Bext. This is a good approximation for ferro-
magnetic transition metals, where the hyperfine fields are ofthe order of 10–100 T. The susceptibility in the case of R
sw,
/H9273/H20849q,/H9275/H20850=/H6036/H20841/H9253e/H20841S1
2/H20873/H11509
/H11509bx/H11032+i/H11509
/H11509by/H11032/H20874mx−imy
M, /H208498/H20850
describes the displacement of the magnetization in response
to a small, complex, space- and time-periodic, transversalfield b
/H11032that is proportional to exp /H20849iqr−i/H9275t/H20850. Here, mxand
myare the transversal components of the displaced magneti-
zation, which are also proportional to exp /H20849iqr−i/H9275t/H20850.
/H9273is obtained from the linearized equation of motion of m,
which turns out to be of the form
d
dtmx
M=+/H9275xmy
M−/H9253eby/H11032,
d
dtmy
M=−/H9275ymx
M+/H9253ebx/H11032. /H208499/H20850
This equation has the solution
mx
M=/H9275x/H9253ebx/H11032+i/H9275/H9253eby/H11032
/H9275x/H9275y−/H92752,my
M=−i/H9275/H9253ebx/H11032+/H9275y/H9253eby/H11032
/H9275x/H9275y−/H92752. /H2084910/H20850
Combining Eqs. /H208494/H20850,/H208497/H20850,/H208498/H20850, and /H2084910/H20850, one obtains
Rsw=kB/H9275nV
/H6036S/H208492/H9266/H208503sgn /H20849/H9253e/H20850/H20885Im/H20875/H9275x+/H9275y−2/H9275n
/H9275x/H9275y−/H9275n2/H20876d3q,
/H2084911/H20850
where /H9275xand/H9275yare functions of qand/H9275=/H9275n.
In this way, the susceptibility formalism relates all relax-
ation mechanisms that arise from the coupling to the magne-tization vector to the equation of motion of the magnetiza-tion. Note that this equation is naturally closely related to thespin-wave spectrum, since displacements of the magnetiza-tion that are proportional to exp /H20849iqr−i
/H9275t/H20850are just spin
waves. The problem is now to find the equation of motion.
2. Equation of motion of the magnetization
The magnetization precesses around an effective field that
is the sum of the magnetic field B, the anisotropy field Ba,
the exchange field, internal fields b/H20849j/H20850due to the coupling to
other excitation modes, and b/H11032:
d
dtM=/H9253eM/H11003/H20873B+Ba+D/H9004M
/H6036/H20841/H9253e/H20841M+/H20858
jb/H20849j/H20850+b/H11032/H20874,/H2084912/H20850
where Dis the spin-wave stiffness constant. This equation
must be solved together with Maxwell’s equations and theequations of motion of the other excitation modes.
If the two explicitly time-dependent Maxwell equations
are combined and the displacement current is neglected, oneobtains
−/H9004B+4
/H9266/H9268
c2d
dtB=4/H9266/H20851−/H9004M+/H11612/H20849/H11612M/H20850/H20852, /H2084913/H20850
where /H9268is the conductivity. Since b/H11032describes the hyperfine
interaction acting on the electron spin, it is not a “true” mag-netic field and does not appear in Maxwell’s equations. Tolinearize the equation of motion, MandBare decomposed
into large, static, and uniform zcomponents and small trans-
versal components mand b, which are proportional to
exp /H20849iqr−i
/H9275t/H20850. The longitudinal components are approxi-
mately given by
Mz=M,/H20849B+Ba/H20850z=B/H9257+4/H9266M. /H2084914/H20850
bandmare related by Eq. /H2084913/H20850. Making use of the period-
icities of those quantities, one obtains
bx=4/H9266mxq2/H92542cos2/H9258
q2/H92542−2isgn /H20849/H9275/H20850,
by=4/H9266myq2/H92542
q2/H92542−2isgn /H20849/H9275/H20850, /H2084915/H20850
where /H9254is the skin depth:ORIGIN OF THE MAGNETIC-FIELD DEPENDENCE OF … PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-3/H9254=c
/H208492/H9266/H9268/H20841/H9275/H20841/H208501/2. /H2084916/H20850
/H9258is the angle between qand the direction of the magnetiza-
tion, and xdenotes the transversal component parallel to q,
which gives
qx=qsin/H9258,qy=0 , qz=qcos/H9258. /H2084917/H20850
If Eqs. /H2084912/H20850,/H2084914/H20850, and /H2084915/H20850are combined, and if only
terms of first order in mare retained, one obtains the linear-
ized equation of motion /H208499/H20850with the parameters
/H9275x=/H9275x/H208490/H20850+/H20858
j/H9275x/H20849j/H20850,
/H9275y=/H9275y/H208490/H20850+/H20858
j/H9275y/H20849j/H20850. /H2084918/H20850
Here,
/H9275x/H208490/H20850=/H9253e/H20873B/H9257+Dq2
/H20841/H9253e/H20841/H6036/H20874,
/H9275y/H208490/H20850=/H9253e/H20873B/H9257+4/H9266Msin2/H9258+Dq2
/H20841/H9253e/H20841/H6036/H20874 /H2084919/H20850
are the parameters without eddy-current damping and cou-
pling to other excitation modes. One set of /H9275/H20849j/H20850’s,
/H9275x/H20849ed/H20850=/H9253e4/H9266M2
2+isgn /H20849/H9275/H20850/H92542q2,
/H9275y/H20849ed/H20850=/H9253e4/H9266M2/H20849cos/H9258/H208502
2+isgn /H20849/H9275/H20850/H92542q2, /H2084920/H20850
are the contributions from the eddy-current damping. The
other/H9275/H20849j/H20850’s are related to the internal fields from other exci-
tation modes by
/H9275x/H20849j/H20850=−/H9253eM
myby/H20849j/H20850,
/H9275y/H20849j/H20850=−/H9253eM
mxbx/H20849j/H20850. /H2084921/H20850
In Fe, D=280 meV Å2,/H9253e=184 GHz T−1,4/H9266M
=2.219 T, V=11.7 Å3, and S=1.06.23The expressions for
/H9275x/H208490/H20850and/H9275y/H208490/H20850are well known from treatments of the spectrum
of the spin-wave resonance frequencies,24–26which are given
by
/H20849/H9275x/H208490/H20850/H9275y/H208490/H20850/H208501/2
2/H9266.
Note the dependence of /H9275x/H208490/H20850and/H9275y/H208490/H20850onB/H9257. It is the source
of the field dependence of the spin-lattice relaxation for allthe relaxation mechanisms that are discussed below. Also
note that, in general,
/H9275x/H208490/H20850/HS11005/H9275y/H208490/H20850due to the demagnetization
fields of the spin waves in the xdirection. As a result, the
precession of the magnetization is, in general, elliptic.
The expressions for /H9275x/H20849ed/H20850and/H9275y/H20849ed/H20850should be comple-
mented by the qdependence of /H9254, since /H9268and/H9254become qdependent, when the wavelength becomes shorter than the
mean free path /H9011of the conduction electrons. /H9268and/H9254are
given in terms of the normal conductivity /H92680and the normal
skin depth /H92540, which represent the limit /H9011q/H112701, by the fol-
lowing relation, which is well known from treatments of theanomalous skin effect:
27,28
/H9268
/H92680=/H925402
/H92542=3
2/H20849/H9011q/H208502/H20877/H208511+ /H20849/H9011q/H208502/H20852arctan /H20849/H9011q/H20850
/H9011q−1/H20878./H2084922/H20850
At this point, it is also useful to introduce the length
scales /H9254mand ld./H9254m−1is defined as that qthat fulfills the
relation
q/H9254=/H208738/H9266M
B/H9257/H208741/2
. /H2084923/H20850
/H9254mcan be interpreted as an effective rf penetration depth that
takes the magnetic permeability into account. For q/H9254m/H112711,
the eddy-current term is a small modification of the equationof motion of the magnetization; for q
/H9254m/H333551, it dominates
that equation.
ld=/H20873D
/H6036/H20841/H9253e/H20841B/H9257/H208741/2
/H2084924/H20850
is a typical length scale of spatial variations of the direction
of the magnetization, as they occur, for example, at domain
walls. /H9275x/H208490/H20850and/H9275y/H208490/H20850are independent of qforqld/H112701 and are
proportional to q2forqld/H112711. Usually, ld/H11270/H9254m. For example,
forB/H9257=0.059 T and the parameters that are used in this work
to describe the relaxation of186IrFe, typical numbers are
/H9254m=0.14 /H9262m and ld=0.020 /H9262m.
3. Virtual excitation of spin waves
If/H9263nlies within the spin wave resonance spectrum, the
nuclear spins can emit and absorb spin waves. This relax-ation mechanism is discussed in Sec. III B. In contrast, if
/H9263n
is smaller than the lowest spin-wave resonance frequency,only a virtual excitation of spin waves takes place, which canbe viewed as a dynamic displacement of the magnetization inthe vicinity of the nuclear spin or as an admixture of spinwaves to the magnetic sublevels of the nuclear spin. It con-tributes to the relaxation, if the virtually excited spin wavesdecay to some other excitation mode that can be excited at
/H9263n. This relaxation mechanism can be viewed in different
ways: /H20849i/H20850It can be viewed as an excitation of the final exci-
tation mode, where the virtual excitation of spin waves actsas an additional, indirect coupling between the nuclear spinsand that mode. /H20849ii/H20850It can be viewed as an excitation of spin
waves, where the spin-wave resonance spectra are broadenedby the decay of the spin waves to the final excitation modeso that the tails of the spectra extend down to
/H9263n./H20849iii/H20850Within
the susceptibility formalism, the equation of motion of themagnetization is modified by the coupling of the spin wavesto the final excitation mode in such a way that the imaginarypart of the susceptibility no longer vanishes at
/H9263n.
Since there are several decay modes of the spin waves,
several relaxation mechanisms via the virtual excitation ofspin waves can be distinguished. To find potentially relevantSEEWALD et al. PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-4decay modes, one can proceed in different ways: In previous
work, it was looked for excitations that couple to the spinwaves and that have a resonance spectrum that extends downto zero. The obvious elementary excitations in this contextare sound waves and various single electron-hole excitations.The relaxation via the indirect coupling to those excitationsis discussed in Secs. III C and III D, respectively. As an al-ternative approach, in this work, we also consider the equa-tion of motion that is commonly used to describe the ferro-magnetic resonance. That equation contains two dampingterms, the eddy-current and the Gilbert damping. The relax-ation via those terms is discussed in Secs. III E and III F,respectively.
4. Approximations
The integrand of Eq. /H2084911/H20850,
F=I m/H20875/H9275x+/H9275y−2/H9275n
/H9275x/H9275y−/H9275n2/H20876,
can often be simplified. One starting point is the observation
that, often, the /H9275/H20849j/H20850’s are small with respect to the /H9275/H208490/H20850’s, or,
as far as the real parts are concerned, are already taken intoaccount by the
/H9275/H208490/H20850’s, since they are contained in the experi-
mental values of /H9253e,Ba, and D. In the case of the relaxation
via the real excitation of spin waves, the consequence is thatthe density of spin-wave states at
/H9275nis not decisively
changed by the /H9275/H20849j/H20850’s. The /H9275/H20849j/H20850’s essentially only ensure that
the imaginary parts of /H9275xand/H9275ydo not vanish, but the exact
form of those imaginary parts is not decisive. In this case, itis a good approximation to assume
/H9275x/H11015/H9275x/H208490/H20850−isgn /H20849/H9275n/H9253e/H20850/H9280x,
/H9275y/H11015/H9275y/H208490/H20850−isgn /H20849/H9275n/H9253e/H20850/H9280y, /H2084925/H20850
where /H9280xand/H9280yare arbitrarily small positive numbers. Tak-
ing the limit /H9280x,/H9280y→0, one obtains
F/H110152/H9266sgn /H20849/H9275n/H9253e/H20850/H9254/H20851/H20849/H9275x/H208490/H20850/H9275y/H208490/H20850/H208501/2−/H20841/H9275n/H20841/H20852ca2, /H2084926/H20850
where /H9254/H20851¯/H20852denotes the /H9254function and not the skin depth,
and
ca=1
2/H20875/H20873/H9275x/H208490/H20850
/H9275y/H208490/H20850/H208741/4
− sgn /H20849/H9275n/H9253e/H20850/H20873/H9275y/H208490/H20850
/H9275x/H208490/H20850/H208741/4/H20876. /H2084927/H20850
In the case of the relaxation via the virtual excitation of
spin waves, the nonvanishing spin-wave density of states at
/H9275nis due to the /H9275/H20849j/H20850’s. In this case, the form of the Im /H20851/H9275/H20849j/H20850/H20852’s
is decisive and must be taken into account. However, one canat least expand the real and the imaginary parts in the nu-merator and the denominator of Finto powers of
/H9275/H20849j/H20850//H9275/H208490/H20850
and retain only the lowest nonvanishing order. The result is
F/H11015/H20858
j−cx2Im/H20851/H9275x/H20849j/H20850/H20852−cy2Im/H20851/H9275y/H20849j/H20850/H20852
/H20849/H9275x/H208490/H20850/H208502, /H2084928/H20850
where
cx=/H9275x/H208490/H20850/H20849/H9275y/H208490/H20850−/H9275n/H20850
/H9275x/H208490/H20850/H9275y/H208490/H20850−/H9275n2,cy=/H9275x/H208490/H20850/H20849/H9275x/H208490/H20850−/H9275n/H20850
/H9275x/H208490/H20850/H9275y/H208490/H20850−/H9275n2. /H2084929/H20850
Whether the condition /H9275/H20849j/H20850/H11270/H9275/H208490/H20850is fulfilled depends on
the/H9275/H20849j/H20850’s and on q. For q/H9254m/H333551, it is not fulfilled, because
/H9275/H20849ed/H20850is of the order of or larger than /H9275/H208490/H20850. However, for
q/H9254m/H112711, it is fulfilled, at least for the spin-wave damping
mechanisms and parameters that are considered in this work,and Eqs. /H2084926/H20850and /H2084928/H20850are expected to be good approxima-
tions.
Further possibilities to simplify Fconcern the coefficients
c
xandcyin Eq. /H2084928/H20850. For many isotopes in Fe, it is a good
approximation to take the limit /H9275n/H11270/H9275x/H208490/H20850, which leads to
cx/H110151,cy/H11015/H9275x/H208490/H20850
/H9275y/H208490/H20850. /H2084930/H20850
However, for the relatively high resonance frequency of
186IrFe in this work, deviations of the order of several per-
cent are expected. A further simplification can be achieved, if
one takes the limit /H9275n/H11270/H9275x/H208490/H20850/H11270/H9275y/H208490/H20850, which leads to
cx/H110151,cy/H110150. /H2084931/H20850
That limit applies only in the range qld/H112701 and sin2/H9258
/H11271B/H9257//H208494/H9266M/H20850, which is, however, responsible for a major
part of the field dependence of the relaxation. Since it sim-plifies the discussion considerably, this approximation mayalso be applied beyond that range, but deviations from theexact result of the order of several percent are then to be
expected. A further limit of interest is
/H9275n/H11270/H9275x/H208490/H20850/H11015/H9275y/H208490/H20850, where
cx/H11015cy/H110151, /H2084932/H20850
because it is a good approximation for qld/H112711, that is, for the
vast majority of the wave vectors.
When the formalism is applied to the spin-lattice relax-
ation of impurity isotopes, the question arises to which ex-tent the modifications of the solid-state properties in the vi-cinity of the impurity must be taken into account. Theanswer follows from the involved length scales: The range ofthe modifications is typically of the order of a lattice constantor less. In contrast, the wave vectors that are responsible for
the field dependence of R
sware of the order of ld−1or less,
which corresponds to an effective range of the relevant in-teraction between the nuclear spin and the lattice of the orderofl
dor larger. The interaction thus takes place essentially in
the host and is expected to be only little affected by theimpurity. Accordingly, the
/H9275/H208490/H20850’s and /H9275/H20849j/H20850’s are approximated
in this work by their values in the undisturbed host. Rsw
depends on the impurity only via the hyperfine coupling con-
stant /H20849/H6036/H9275n/H20850/S.
B. Excitation of spin waves
If the nuclear resonance frequency /H9263nlies within the range
of the spin-wave resonance frequencies, Rswis essentially
due to the following mechanism: The nuclear spins emit andabsorb spin waves. In this work, a contribution from thisrelaxation mechanism can be excluded, since the lowestspin-wave frequency, /H20849
/H9253eBa/H20850//H208492/H9266/H20850=1.72 GHz, was muchORIGIN OF THE MAGNETIC-FIELD DEPENDENCE OF … PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-5larger than /H9263n. Nevertheless, the mechanism is of interest,
since under special conditions, much smaller spin-wave fre-quencies can occur.
8
If it is assumed that the majority of the wave vectors of
the emitted spin waves are much larger than /H9254m−1, which
should be a good approximation in many cases, Eqs. /H2084911/H20850and
/H2084926/H20850can be combined to
Rsw=kB4/H92662/H9263n
S/H20885Vca2
/H208492/H9266/H208503/H6036/H9254/H20851/H20849/H9275x/H208490/H20850/H9275y/H208490/H20850/H208501/2−/H20841/H9275n/H20841/H20852d3q,
/H2084933/H20850
where cais given by Eq. /H2084927/H20850. Without the factor ca2, which
arises from the ellipticity of the precession of the magneti-zation, the integral is just the density of spin-wave states ath
/H9263n. Since, often, relaxation constants are derived via Fer-
mi’s golden rule instead of via the susceptibility formalism,we mention that, in this case, the ellipticity of the precessionof the magnetization must already be taken into account
when the spin waves are quantized. Otherwise, the factor c
a2
is not reproduced.
To estimate the expected order of magnitude, Rswwas
calculated according to Eq. /H2084933/H20850forB/H9257=0, the most favor-
able case, and /H9263n=0.79 GHz of186IrFe. The result Rsw
=3.55 /H11003103/H20849sK /H20850−1is about 400 times larger than R/H20849/H11009/H20850for
that system. This shows that, if /H9263nlies within the spin-wave
resonance frequencies, Rswincreases the relaxation by orders
of magnitude. That increase is strongly field dependent, sincethis is the case at all only for special choices of the directionand the magnitude of B
ext.8
C. Excitation of sound waves
In this section, the following relaxation mechanism is dis-
cussed: The nuclear spins virtually excite spin waves, which,in turn, decay via the excitation of sound waves. R
phdenotes
the respective contribution to the relaxation constant. Thismechanism can also be described in terms of the mixing ofsound and spin waves in ferromagnets by themagnetostriction:
22,29,30The coupling of the nuclear spin to
the spin-wave component of the sound-wave-like mode leadsto spin-lattice relaxation via the excitation of the sound-wave-like modes.
To derive R
phwithin the susceptibility formalism, one has
to solve the coupled equations of motion of the amplitude m
of the displacement of the magnetization, which is propor-tional to exp /H20849iqr−i
/H9275t/H20850, and of the amplitude uof the dis-
placement of the atoms, which is also proportional toexp /H20849iqr−i
/H9275t/H20850. The equation of motion of uis assumed to be
of the form
Ad2
dt2u=− /H20849Av2q2/H20850u−/H9280d
dtu+f, /H2084934/H20850
where Ais the mass of the atom, vis the speed of sound, /H9280is
an arbitrarily small positive number, and fis the force, which
is also proportional to exp /H20849iqr−i/H9275t/H20850. For simplicity, it is as-
sumed that the velocity of sound is the same for all wavevectors and polarizations.Sound and spin waves are coupled by the magnetoelastic
energy, which is, for small displacements of the magnetiza-tion from the /H20851001 /H20852direction, of the form
B
2/H20849eyz/H9251y+exz/H9251x/H20850, /H2084935/H20850
where B2is the magnetoelastic coupling constant, the eij’s
are the components of the strain tensor, and the /H9251i’s are the
direction cosines of the magnetization. As a result, uandm
are coupled by the following energy per atom:
Eme=−iqB 2/H20875/H20849uy*cos/H9258/H20850my
M+/H20849ux*cos/H9258+uz*sin/H9258/H20850mx
M/H20876.
/H2084936/H20850
It leads to the coupling of the equations of motion by the
following forces and fields:
fj=−/H11509Eme
/H11509uj*, /H2084937/H20850
bj/H20849ph/H20850=−1
V/H20875/H11509Eme
/H11509mj/H20876*
. /H2084938/H20850
With the force from Eq. /H2084937/H20850, the solution of Eq. /H2084934/H20850is
uj=/H11509Eme//H11509uj*
A/H20849/H92752−v2q2/H20850+i/H9280/H9275. /H2084939/H20850
Combining Eqs. /H2084936/H20850,/H2084938/H20850, and /H2084939/H20850, one obtains b/H20849ph/H20850as a
function of m. Applying, in addition, Eq. /H2084921/H20850and MV
=/H6036/H20841/H9253e/H20841S, one obtains the following contribution of the sound
waves to the equation of motion of the magnetization:
/H9275x/H20849ph/H20850=sgn /H20849/H9253e/H20850q2B22cos2/H9258
/H6036S/H20851A/H20849/H92752−v2q2/H20850+i/H9280/H9275/H20852,
/H9275y/H20849ph/H20850=sgn /H20849/H9253e/H20850q2B22
/H6036S/H20851A/H20849/H92752−v2q2/H20850+i/H9280/H9275/H20852. /H2084940/H20850
To obtain a compact expression of Rph, some additional
assumptions are necessary: Neglecting all other dampingmechanisms of the spin waves, all
/H9275/H20849j/H20850’s can be set equal to
zero with the exception of the /H9275/H20849ph/H20850’s. Moreover, assuming
that the dispersion relation of the sound waves is not deci-sively changed by the damping and the mixing with the spin
waves, one can take the limits
/H9280→0 and B22//H20849Av2/H20850/H11270/H6036/H9275x/H208490/H20850.
Finally, assuming that qld/H112701, the q→0 limit of the /H9275/H208490/H20850’s
can be used. If those approximations are applied togetherwith Eq. /H2084911/H20850, the result is
R
ph=kB2/H92662VB22h/H9263n4
/H6036S2/H20849/H6036/H9253eB/H9257/H208502Av5/H20885
q→0/H20849cx2cos2/H9258+cy2/H20850d/H9024
4/H9266,/H2084941/H20850
where the integration is over all directions of q. In contrast to
similar expressions in the literature,22,29,30Eq. /H2084941/H20850takes the
elliptic precession of the magnetization into account.
The decisive point is the magnitude of the effect.
In Fe, B2=0.57 meV and vranges from 0.26 to 0.65
/H11003106cm s−1.23For B/H9257=0.059 T and /H9263n=0.79 GHz of
186IrFe, the prefactor in front of the integral in Eq. /H2084941/H20850SEEWALD et al. PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-6ranges from 4.1 /H1100310−5to 4.3/H1100310−3/H20849sK /H20850−1. This is more
than 3 orders of magnitude smaller than R/H20849/H11009/H20850of186IrFe.
Since the integral is of the order of unity, Rphis a negligible
contribution to the spin-lattice relaxation. This conclusionhas already been drawn in Ref. 1, although without explicit
derivation. An examination of the numerical factors showsthat this result is less due to the weakness of the magneto-elastic coupling than due to the small sound-wave density ofstates at small q’s as a result of the linear dispersion relation.
It should be added that two of the assumptions that were
used to derive Eq. /H2084941/H20850are not good approximations. First, a
uniform velocity of sound was assumed, although there is adistinct dependence of
von the polarization and the propa-
gation direction of the sound wave. The main effect of thatdependence is that, actually, the factor
v−5must be evaluated
for each polarization and wave vector separately and that thedifferent weighting of the polarizations must be taken intoaccount. Without detailed account of the sound-wave disper-sion, only an upper and a lower limit of R
phcan be obtained
by inserting the minimum and the maximum vinto Eq. /H2084941/H20850.
Second, the neglect of the eddy-current damping is not jus-tified. The wave vectors of the excited sound waves are inthe range q
/H9254m/H333551, where the eddy-current damping domi-
nates the dispersion relation of the spin waves. It can beshown that R
phis actually considerably smaller than implied
by Eq. /H2084941/H20850, because the spin-wave amplitude is suppressed
by the eddy-current damping. Thus, Eq. /H2084941/H20850is useful to
present, in a compact expression, the decisive factors that areresponsible for the negligibility of R
ph, but a more elaborate
expression would be needed to calculate Rph.
D. Indirect spin-wave mechanism
In this section, the following relaxation mechanism is dis-
cussed: The nuclear spins virtually excite spin waves, which,in turn, decay via the scattering of conduction electrons. R
in
denotes the respective contribution to the relaxation constant.
This relaxation mechanism is known as the indirect spin-wave mechanism, the Weger mechanism, or the second-orderspin-wave mechanism. It is the dominant contribution to thespin-lattice relaxation in the rare earths.
30Its contribution to
the spin-lattice relaxation in Fe has been discussed in Refs.1,11, and 21. To make the relationship to the other contri-
butions to R
swapparent, we rederive Rinwithin the formalism
that was developed in Sec. III A.
Since in transition metals the spin waves are excitations
of the conduction electrons, it is useful to remember that atsmall
/H9275’s and q’s, the spin waves, as collective rotations of
all spins, can be well distinguished from the scattering of theconduction electrons, which describes single electron-holeexcitations. To derive R
inwithin the susceptibility formalism,
one has to solve the coupled equations of motion of thetransverse magnetization mdue to the spin waves and of the
transverse magnetization m
/H20849s/H20850due to the single electron-hole
excitations. The equation of motion of m/H20849s/H20850is solved by
m/H20849s/H20850=/H9273/H20849s/H20850
Vb/H20849s/H20850, /H2084942/H20850
where /H9273/H20849s/H20850is the transversal susceptibility of the conduction
electrons and b/H20849s/H20850is the transversal field acting on m/H20849s/H20850. The
coupling energy per atom is of the form−JV2
/H9253e/H9253s/H60362mm/H20849s/H20850, /H2084943/H20850
where Jis the coupling constant per unit of the involved
spins and /H9253sis the gyromagnetic ratio of the conduction elec-
trons. With respect to this coupling term, the interaction viathe demagnetization field is negligible. The coupling givesrise to the fields
b
/H20849s/H20850=JS
/H20841/H9253s/H20841/H6036m
M,
b/H20849in/H20850=JV
/H9253e/H9253s/H60362m/H20849s/H20850, /H2084944/H20850
where b/H20849in/H20850is the field acting on m.
If Eqs. /H2084921/H20850,/H2084942/H20850, and /H2084944/H20850are combined, one obtains the
following contribution of the scattering of the conductionelectrons to the equation of motion of m:
/H9275x/H20849in/H20850=/H9275y/H20849in/H20850= − sgn /H20849/H9253e/H20850J2S
/H9253s2/H60363/H9273/H20849s/H20850. /H2084945/H20850
The respective contribution to the spin-lattice relaxation fol-
lows from Eqs. /H2084911/H20850and /H2084928/H20850, which is expected to be a good
approximation. The final result is
Rin=kB/H9275nJ2V
/H60364/H9253s2/H208492/H9266/H208503/H20885cx2+cy2
/H20849/H9275x/H208490/H20850/H208502Im/H20851/H9273/H20849s/H20850/H20852d3q. /H2084946/H20850
A comparison with Eq. /H208494/H20850shows that Kis replaced in Eq.
/H2084946/H20850by the factor J/H20849/H9275n//H9275x/H208490/H20850/H20850, which can thus be interpreted
as the q-dependent coupling constant of the indirect coupling
to the conduction electrons via the magnetization. The effec-tive range of that indirect coupling follows from the qde-
pendence of
/H9275x/H208490/H20850: It is of the order of ld.
To calculate Rin, one has to know Im /H20851/H9273/H20849s/H20850/H20852, which, in turn,
requires a detailed knowledge of the band structure. Sincethis is outside of the scope of this work, the magnitude of R
in
is left as an open problem. The estimates of Rinin Ref. 31are
of little use, because they are unrealistic at least in the fol-lowing two respects: First, those estimates are based on over-estimates of the spin-lattice relaxation via the direct scatter-ing of selectrons.
31,32Second, in the case of impurity
isotopes, those estimates are based on the assumption thatIm/H20851
/H9273/H20849s/H20850/H20852in Eq. /H2084946/H20850refers to the local susceptibility of the
conduction electrons at the impurity. However, since the in-direct coupling to the conduction electrons takes place essen-tially in the host, the appropriate Im /H20851
/H9273/H20849s/H20850/H20852is that of the un-
disturbed host.
Nevertheless, some conclusions are possible without cal-
culation. The decisive point in this work is the form of thefield dependence, which can already be deduced from
R
in/H11008/H20885Im/H20851/H9273/H20849s/H20850/H20852
/H20849/H9275x/H208490/H20850/H208502d3q, /H2084947/H20850
where cx=1 and cy=0 was assumed for simplicity. Since /H9275x/H208490/H20850
is appreciably field dependent only for small q’s, the knowl-
edge of the qdependence of Im /H20851/H9273/H20849s/H20850/H20852in the limit q→0 and
/H9275→0 is already sufficient in this context. Im /H20851/H9273/H20849s/H20850/H20852is a mea-ORIGIN OF THE MAGNETIC-FIELD DEPENDENCE OF … PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-7sure of the resonant absorption by the scattering of conduc-
tion electrons, if a field proportional to exp /H20849iqr−i/H9275t/H20850is ap-
plied. Therefore, it is proportional to the available phasespace for the scattering and to the square of the matrix ele-ment. For a given scattering mechanism and constellation ofthe involved bands, the resulting qdependence can reason-
ably well be predicted. In the following, several scenarios arediscussed. Since the occurrence of small momentum trans-fers is the prerequisite for an appreciable field dependence,only the most favorable situations in this respect are consid-ered.
/H20849i/H20850One scenario, the spin-flip scattering between bands
that are shifted in energy relative to each other by the ex-change splitting, has already been discussed in Refs. 1,11,
and21: In this case, there is a minimum momentum transfer
q
m.I m /H20851/H9273/H20849s/H20850/H20852is proportional to q−1forq/H11022qmand zero for
q/H11021qm. The field dependence is of the form
Rin/H110081
B/H9257+Bc. /H2084948/H20850
The constant Bcis given in terms of the exchange splitting JS
and the gradient /H11509/H9280//H11509qof the electron energy dispersion at
the Fermi energy by
Bc=D
/H6036/H9253e/H20849JS/H208502
/H20849/H11509/H9280//H11509q/H208502. /H2084949/H20850
Without detailed knowledge of the band structure, the fol-
lowing can be said about Bc:I fJSand /H20849/H11509/H9280//H11509q/H20850are of the
order of magnitude that can be expected for dbands in Fe, Bc
is of the order of 103T. If nearly-free-electron bands are
involved, Bccan be much smaller: Assuming a free electron
energy dispersion, a Fermi energy of 8 eV,33and JS
=0.15 eV,33one obtains Bc=0.5 T. However, this estimate of
Bcis already rather a lower limit.
/H20849ii/H20850In the case of spin-flip scattering between bands with
intersecting Fermi surfaces, the available phase space ap-proaches a nonzero value in the limit q→0. The matrix ele-
ment of the spin-flip operator may or may not vanish in thelimit q→0. In the latter case, Im /H20851
/H9273/H20849s/H20850/H20852is approximately con-
stant for small q’s. Applying Eq. /H2084947/H20850, it can be shown that in
this case, the field dependence is of the form Rin/H11008B/H9257−1 /2.
/H20849iii/H20850Scattering that involves a change of the orbital mag-
netic quantum number instead of a spin-flip can also contrib-ute to R
in. However, the required coupling between the mag-
netization and the orbital moment cannot be the spin-orbitcoupling, since it must be an electron-electron interaction.Instead, it may arise from the intra-atomic interaction be-tween the orbital moment that is admixed to the magnetiza-tion by the spin-orbit coupling and the orbital moment of thescattered electron. The most favorable constellation is thescattering into the same band. In this case, the availablephase space is proportional to q
−1, whereas the square of the
matrix element of the orbital moment raising operator is pro-portional to q
2. As a result, Im /H20851/H9273/H20849s/H20850/H20852/H11008q. Applying Eq. /H2084947/H20850,i t
can be shown that in this case,Rin/H11008log/H20875Bc
B/H9257/H20876, /H2084950/H20850
where Bcis at least of the order of 50 T.
For comparison, according to our measurements, the
field-dependent part of the spin-lattice relaxation can be well
described by a term that is proportional to B/H9257−/H9264, where /H9264is
close to 1.4, if B/H9257is of the order of 0.1 T. This observed field
dependence is much stronger than any of the predicted fielddependences of R
in. Therefore, the conclusion is that the in-
direct spin-wave mechanism cannot explain the magnetic-field dependence of the spin-lattice relaxation, at least notwith the scattering mechanisms and band structure constella-tions that are known to us.
Finally, it should be mentioned that, for simplicity, our
derivation of the field dependence of the indirect spin-wavemechanism neglects the following two effects, which maysomewhat modify the form of the field dependence: The el-lipticity of the precession of the magnetization is neglectedby the assumptions c
x=1 and cy=0. Moreover, in addition to
the contributions from the direct and from the indirect cou-pling to the conduction electrons, the superposition of bothcouplings also contributes to the spin-lattice relaxation. Thiscontribution, which is discussed in Refs. 1and 11,i sn e -
glected in this work. However, it can be shown that botheffects, at most, lead to an even weaker field dependence.Our conclusion that the field dependence of the indirect spin-wave mechanism is too weak is thus not affected.
E. Eddy-current damping
In this section, the following relaxation mechanism is dis-
cussed: The nuclear spins virtually excite spin waves, which,in turn, induce eddy currents, which, in turn, decay via theprocesses that are summarized by the term electrical resistiv-ity.R
eddenotes the respective contribution to the relaxation
constant. The contribution of the eddy currents to the equa-tion of motion of the magnetization has already been derivedin Sec. III A, where it is specified in terms of the
/H9275/H20849ed/H20850’s by
Eq. /H2084920/H20850. To obtain Red, one has to add the /H9275/H20849ed/H20850’s to the
/H9275/H208490/H20850’s, whereas the influence of other /H9275/H20849j/H20850’s can be neglected,
because for q/H9254m/H112711, all contributions to the relaxation add
independently, and for smaller q’s, the other /H9275/H20849j/H20850’s are negli-
gible with respect to the /H9275/H20849ed/H20850’s.
It follows that Redis given by Eq. /H2084911/H20850with
/H9275x=/H9253e/H20873B/H9257+Dq2
/H20841/H9253e/H20841/H6036+4/H9266M2
2+isgn /H20849/H9275/H20850/H92542q2/H20874,
/H9275y=/H9253e/H20873B/H9257+Dq2
/H20841/H9253e/H20841/H6036+4/H9266M2+isgn /H20849/H9275/H20850/H20849sin/H9258/H208502/H92542q2
2+isgn /H20849/H9275/H20850/H92542q2/H20874,
/H2084951/H20850
where /H9254is given as a function of qand/H9275=/H9275nby the Eqs.
/H2084916/H20850and /H2084922/H20850.
1. Approximate expression
To reproduce Redwithin 1%, the numerical evaluation of
the set of Eqs. /H2084911/H20850,/H2084916/H20850,/H2084922/H20850, and /H2084951/H20850is unavoidable. How-SEEWALD et al. PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-8ever, a less involved, though only approximate expression
was also derived. To understand the used approximations, itis useful to discuss first the qdependence of the integrand in
Eq. /H2084911/H20850. In the decisive range of q’s, that integrand is largely
given by Im /H20849
/H9275x−1/H20850, which is proportional to /H20849q/H9254/H208502for
q/H9254m/H112701, passes through a maximum at q/H9254m=1, and is pro-
portional to /H20849q/H9254/H20850−2/H208511+/H20849qld/H208502/H20852−2forq/H9254m/H112711. It follows that
Redis mainly due to momentum transfers in the range
/H9254m−1/H11021q/H11021ld−1.
The following three approximations were applied: First,
the integrand was approximated by Eq. /H2084928/H20850, the appropriate
expression for q/H9254m/H112711, and was integrated from q/H9254m=1 to
q=/H11009. Second, cx=1 and cy=0 was assumed, which corre-
sponds to taking the limits /H9275n/H11270/H9275x/H208490/H20850and/H9275x/H208490/H20850/H11270/H9275y/H208490/H20850. Third, /H9268
was approximated by its expression in the limit q/H9011/H112711:
/H9268/H11015/H926803/H9266
4/H9011q. /H2084952/H20850
This is justified for large resistivity ratios, the criterion being
/H9011/H11022/H9254m.
If all three approximations are combined, Redcan be ex-
pressed in closed form. For convenience, we give the finalresult in terms of the numerical values of the involved quan-tities:
R
ed/H110156.18/H1100310−3V4/H9266M
/H20849/H20841/H9253e/H20841/2/H9266/H20850S/H9263n2
B/H92572/H92680
/H9011
/H11003/H20877log/H208752.73/H11003105/H20849/H20841/H9253e/H20841/2/H9266/H20850
D/H208494/H9266M/H208502/3B/H92575/3
/H9263n2/3/H20873/H92680
/H9011/H20874−2 /3/H20876−1/H20878.
/H2084953/H20850
This expression applies if Ris expressed in /H20849sK /H20850−1,Vin Å3,
4/H9266Mand B/H9257in T,/H9263nin GHz, /H20849/H9253e/2/H9266/H20850in GHz T−1,Din
meV Å2, and /H20849/H92680//H9011/H20850in/H20849/H9262/H9024cm/H9262m/H20850−1. To examine the typi-
cal agreement of Eq. /H2084953/H20850with the exact expression, the re-
sults were compared for the parameter sets that were used in
this work to describe the relaxation of186Ir. The deviation
was in all cases less than 10%.
2. Properties
In the following, the properties of the spin-lattice relax-
ation via the eddy-current damping are discussed. The firstproperty is the magnitude of the effect. It can be inferredusing Eq. /H2084953/H20850. The main uncertainty arises from
/H92680//H9011. That
parameter, which is independent of the mean free path, isessentially the product of the mobility and the density of theconduction electrons. It is an intrinsic property of the host.Still, the best way to obtain a realistic estimate for Fe is toconsider the values for other metals: The order of magnitudeof
/H92680//H9011should be the same for transition metals as for other
metals, because the larger densities of electrons at the Fermienergy are expected to be compensated by correspondingly
smaller mobilities. For Al, Sn, Cd, Pb, Cu, Ag, and Au, val-ues of
/H92680//H9011between 5.7 and 20.4 /H20849/H9262/H9024cm/H9262m/H20850−1have been
reported.34Assuming that /H92680//H9011of Fe lies within that range,
Red=16–41 /H20849sK /H20850−1is obtained from Eq. /H2084953/H20850for/H9263n
=0.79 GHz and B/H9257=0.059 T, which applies to186Ir in Fe at
zero applied field. This has to be compared with the observedmagnitude of the field-dependent part of the relaxation inthat case, R/H208490/H20850−R/H20849/H11009/H20850=24 /H20849sK /H20850
−1.Redis thus of the right
order of magnitude to explain the field dependence of therelaxation.
The second property that we discuss is the independence
from the impurity. R
eddepends only on properties of the host
and/H9263n, but not on the element to which the particular isotope
belongs or on the lattice site that it occupies. That indepen-dence from the local electronic structure reflects the longeffective range of the interaction with the lattice, which alsomanifests itself in the dominance of small momentum trans-fers. However, it is not a distinctive feature of R
ed, since
every close relation between the relaxation and B/H9257, a quan-
tity that describes the response of the system to macroscopicperturbations, suggests a long-range interaction with theelectrons.
The third property that we discuss is the form of the
magnetic-field dependence. That dependence is actually a B
/H9257
dependence, since Bextenters only via that quantity. There is
a proportionality to B/H9257−2, which is, however, weakened by the
field dependences of /H9254mandld. That weakening, represented
by the B/H9257dependence of the log term in Eq. /H2084953/H20850, increases
with decreasing magnetic field but also depends on the otherparameters. For example, for the parameters that were used
in this work, R
edis proportional to B/H9257−1.47atB/H9257=0.059 T, to
B/H9257−1.59atB/H9257=0.12 T, and to B/H9257−1.75atB/H9257=1.0 T, if the field
dependence is described over small field ranges as a powerlaw in B
/H9257.
The fourth property that we discuss is the dependence on
the nuclear resonance frequency. Redis roughly proportional
to/H9263n2. This corresponds to the usual scaling of the nuclear
spin-lattice relaxation with the square of the relevant hyper-fine coupling constant, which is, in our case, the static hy-perfine interaction.
However, there are also slight, but distinct deviations
from R
ed/H11008/H9263n2. Three effects can be distinguished in this re-
spect: First, the skin effect, which suppresses displacementsof the magnetization with wavelengths larger than
/H9254, is less
effective at smaller frequencies. Due to that effect, whichgives rise to the
/H9263ndependence of the logarithmic term in Eq.
/H2084953/H20850,Red//H9263n2increases with decreasing /H9263n. Second, the inte-
grand of Eq. /H2084911/H20850becomes almost singular at /H9275n2=/H9275x/H208490/H20850/H9275y/H208490/H20850.
Therefore, Red//H9263n2increases when /H20841/H9275n/H20841approaches the range
of spin-wave precession frequencies at /H20849/H9275x/H208490/H20850/H9275y/H208490/H20850/H208501/2. Third,
there is an asymmetry with respect to the sign of the fre-quency: The relaxation is faster if the free precessions of thenuclear and the electron spins have the same sense. The rela-tive sense of those precessions was specified in terms of thesigns of
/H9253e,/H9253n, and BHFin connection with Eq. /H208496/H20850. The
combined effect of all three effects is illustrated in Fig. 1.
The fifth property that we discuss is the dependence on
the conductivity, which is the product of the host-specificparameter
/H92680//H9011and the mean free path /H9011, which varies withORIGIN OF THE MAGNETIC-FIELD DEPENDENCE OF … PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-9the temperature and the sample preparation. As can be seen
from Eq. /H2084953/H20850, the dependence of Redon/H92680//H9011is essentially
given by a proportionality to /H92680//H9011, which is only slightly
weakened by the /H92680//H9011dependence of the logarithmic term.
This reflects that the relaxation is proportional to the eddy-current damping, apart from small momentum transfers
/H20849q/H11021
/H9254m−1/H20850, where the damping becomes so large that it sup-
presses the susceptibility.
The dependence on /H9011is more complex, since the conduc-
tivity becomes independent of /H9011,i f/H9011becomes larger than
the wavelength. Therefore, /H9011must be compared with the
relevant length scales of the problem, ldand/H9254m. As long as
/H9011/H11270ld,Redis largely proportional to /H9011. In the range ld/H11021/H9011
/H11021/H9254m, the increase with /H9011becomes ever weaker, and in the
opposite limit, /H9011/H11271/H9254m,Redis independent of /H9011.
The resulting dependence of Redon/H9011is shown in Fig. 2.
There, the resistivity ratio /H92680//H92680/H20849300 K /H20850serves as the mea-
sure of /H9011. It can be seen that Redis rather insensitive to /H9011,a s
long as /H92680//H92680/H20849300 K /H20850/H1102230, which is fulfilled for well pre-
pared samples at low temperatures.The sixth property that we discuss is the temperature de-
pendence. The usual proportionality of the spin-lattice relax-ation in metals to Tis already taken into account by the
definition of R
ed. Additional temperature dependences arise
from the temperature dependences of /H9011,Ba, and D. Since the
last two parameters vary only weakly up to room tempera-ture, the temperature dependence of R
edis essentially deter-
mined by the temperature dependence of /H9011. Accordingly, the
curve in Fig. 2can also be viewed as a plot of the tempera-
ture dependence if /H92680/H20849T/H20850//H92680/H20849300 K /H20850is interpreted as a mea-
sure of T.
The basic effect is that /H9011andReddecrease with increasing
temperature. However, due to the insensitivity of Redto/H9011at
high resistivity ratios, the decrease of Redsets in later than
the decrease of /H9011. Taking the example of Fig. 2, the onset of
an appreciable temperature dependence of Redis expected at
/H92680/H20849T/H20850//H92680/H20849300 K /H20850/H1101130, which corresponds to T/H1101165 K.35At
room temperature, Redis already reduced by more than a
factor of 5.
The last property that we discuss is the influence of the
surface. Surface effects come into play when the distance tothe surface becomes smaller than the skin depth, which isnecessarily the case with NMR measurements. They arisebecause additional magnetic surface anisotropy terms and themissing magnetic volume anisotropy at the other side of thesurface modify the susceptibility, and because the truncationof the free path of the conduction electrons at the surfacemodifies the conductivity. We do not give a detailed treat-ment because the required mathematical techniques, such asthe Wiener-Hopf technique,
27are beyond our scope. More-
over, decisive parameters, such as the magnetic surface an-isotropy, are, in general, not known.
However, several general conclusions can already be
drawn assuming strongly simplified boundary conditions. Ifsurface effects on the conductivity are completely ignored,whereas the magnetic surface anisotropy is assumed to beeither absent /H20849free-spin boundary condition /H20850or so strong that
the magnetization at the surface cannot be displaced at all/H20849pinned-spin boundary condition /H20850, the problem can be solved
by the introduction of a mirror nuclear spin. The result is thatthe integrand in Eq. /H2084911/H20850must be multiplied by an extra
factor
1/H11006cos/H208492qd/H20850, /H2084954/H20850
where dis the distance to the surface, and the plus and the
minus signs apply to the free-spin and the pinned-spin limits,respectively. This shows that the surface contribution to R
ed
/H20849i/H20850can become of the same order of magnitude as the volume
contribution, /H20849ii/H20850can enhance or reduce the relaxation, and
/H20849iii/H20850depends on the surface conditions and thus on the
sample preparation.
With regard to the range of the surface effects into the
interior of the sample, the following can be said withoutdetailed theory: The characteristic length scales of the inter-action between the nuclear spin and the lattice are
/H9254mandld.
Accordingly, the surface effects are largest for d/H11021ld, dimin-
ish with increasing distance to the surface in the rangel
d/H11021d/H11021/H9254m, and can be neglected for d/H11022/H9254m.FIG. 1. Dependence of Red//H9263n2on/H9263nforB/H9257=0.059 T, /H92680//H9011
=6.7 /H20849/H9262/H9024cm/H9262m/H20850−1,/H92680=20 /H20849/H9262/H9024cm/H20850−1, and Fe as the host. /H9275/H110220
denotes that the electronic and the nuclear spins precess in the op-posite sense, and
/H9275/H110210 that they precess in the same sense.
FIG. 2. Dependence of Redon the resistivity ratio for B/H9257
=0.059 T, /H9263n=0.79 GHz, /H92680//H9011=6.7 /H20849/H9262/H9024cm/H9262m/H20850−1,/H92680/H20849300 K /H20850
=0.1 /H20849/H9262/H9024cm/H20850−1, and Fe as the host. The region of small resistivity
ratios is shown enlarged in the inset.SEEWALD et al. PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-10F. Gilbert damping
In this section, the following relaxation mechanism is dis-
cussed: The nuclear spins virtually excite spin waves, which,in turn, decay via the Gilbert damping. R
gidenotes the re-
spective contribution to the relaxation constant. Since themechanisms of the Gilbert damping are not known, in thisway, the relaxation mechanism is specified only in part, inpart it is described only phenomenologically. For example, itmay well be that the scattering of conduction electrons bythe spin waves is part of the Gilbert damping and that R
inis
part of Rgi. The advantage of the phenomenological concept
of the Gilbert damping is that it is the generally accepteddescription of the damping of the precession of the magne-tization, which has been applied, for example, to manyferromagnetic-resonance experiments.
The contribution of the Gilbert damping to dM /dtis
−G
/H9253eM2/H20873M/H11003dM
dt/H20874, /H2084955/H20850
where Gis the Gilbert damping parameter. Here, Gis as-
sumed to be independent of q. This is in accord with the use
ofGin the literature, where it is treated as a constant, irre-
spective of the length scales of the problem, such as the skindepth or the thickness of thin films. However, one should beaware that the qindependence of Gis not well established
and that a qdependence would distinctly alter the properties
ofR
gi.
In passing, we note that the form of the Gilbert damping
might appear somewhat peculiar, if compared, for example,to a Bloch-type damping: /H20849i/H20850The relaxation of a displace-
ment of the magnetization is proportional to the velocity andnot to the magnitude of the displacement. /H20849ii/H20850In the case of
an elliptic precession of the magnetization, the relaxation is,in general, not directed toward the equilibrium position. /H20849iii/H20850
If the magnetization precesses in a sense that is opposite tothe sense of the free precession, which may occur in re-sponse to an external rf field, the damping term increases thedisplacement of the magnetization. In this context, it is ofinterest that it can be shown that the eddy-current dampingalso shows all those peculiarities.
It can be shown that the contributions to
/H9275xand/H9275yfrom
the Gilbert damping are
/H9275x/H20849gi/H20850=/H9275y/H20849gi/H20850=−iG/H9275
/H9253eM. /H2084956/H20850
Since it turns out that Rgiis mainly due to momentum trans-
fers of the order of q/H11011ld−1, approximation /H2084928/H20850can be ap-
plied. The result is
Rgi=kB/H9275n2V
/H6036S/H208492/H9266/H208503G
/H20841/H9253e/H20841M/H20885cx2+cy2
/H20849/H9275x/H208490/H20850/H208502d3q. /H2084957/H20850
If/H9275n/H11270/H9275x/H208490/H20850, Eq. /H2084957/H20850can be further simplified. In that
limit, the integrand reduces to
/H20849/H9275x/H208490/H20850/H20850−2+/H20849/H9275y/H208490/H20850/H20850−2, /H2084958/H20850which can be integrated by standard integrals. The result is
Rgi/H11015kB/H60361/2V/H9275n2G
8/H9266S/H20849D/H9253e/H208503/2MB/H92571/2Fc/H20873B/H9257
4/H9266M/H20874, /H2084959/H20850
where
Fc/H20849x/H20850=1+ x1/2arcsin/H208731
/H208491+x/H208501/2/H20874. /H2084960/H20850
The characteristic length and wavelength scales of the in-
teraction between the nuclear spin and the medium are re-flected by the qdependence of the integrand in Eq. /H2084957/H20850,
which is largely proportional to /H208511+/H20849ql
d/H208502/H20852−2. It follows that
the length scale is essentially given by ldand that mainly
momentum transfers of the order of q/H11011ld−1are involved. In
comparison to Red, where the relevant length scales are /H9254m
andld, very small momentum transfers and very large dis-
tances are less involved.
The magnitude of Rgican be calculated taking G
=0.053–0.076 GHz from the literature.36For/H9263n=0.79 GHz
andB/H9257=0.059 T, which applies to186Ir in Fe at zero applied
field, one obtains Rgi=3.2–4.6 /H20849sK /H20850−1. The comparison with
the experimental relaxation constants, R/H208490/H20850−R/H20849/H11009/H20850
=24 /H20849sK /H20850−1and R/H20849/H11009/H20850=8 /H20849sK /H20850−1, shows that Rgiis a non-
negligible contribution to the field-dependent part of the re-laxation, although it is not the main contribution. Theelement- and lattice-site-specific local electronic structure atthe impurity does not enter except via the parameter
/H9275n. That
impurity independence results, as in the case of Red, from the
long range of the interaction between the spin and the me-dium.
The magnetic-field dependence of R
giis determined by
the factors B/H9257−1 /2and Fc/H20851B/H9257//H208494/H9266M/H20850/H20852in Eq. /H2084959/H20850. The last
factor distinctly weakens the proportionality to B/H9257−1 /2at mod-
erate field strengths. Between B/H9257=0.059 T and B/H9257=2 T, for
example, the field dependence of Rgican be well described
byB/H9257−/H9264with/H9264close to 0.40.
The dependence of Rgion the nuclear resonance fre-
quency largely follows Rgi/H11008/H9263n2. The deviations from that pro-
portionality are distinctly smaller than in the case of Red:A t
B/H9257=0.059 T, for example, Rgi//H9263n2increases by 5.9% between
/H9263n=0 GHz and /H9263n=1 GHz if the electronic and the nuclear
spins precess in the same sense and decreases by 3.6% if theelectronic and the nuclear spins precess in the opposite sense.
The temperature dependence of R
giis only weak up to
room temperature, since the parameters G,Ba,D,M,/H9253e, and
Vare only weakly temperature dependent. Surface effects are
introduced by the magnetic surface anisotropy and the miss-ing magnetic volume anisotropy beyond the surface. Theymay become as important as in the case of R
ed. However, the
distance to the surface where they become important is of theorder of l
dand thus much smaller than in the case of Red,
where it is of the order of /H9254m.
G. Domain walls
The nuclear spin-lattice relaxation in the domain walls is
known to be by up to 2 orders of magnitude faster than therelaxation in the domains.
21,37,38This had no consequencesORIGIN OF THE MAGNETIC-FIELD DEPENDENCE OF … PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-11for the experiments in this work, since the used measurement
technique is insensitive to the nuclei in the domain walls.Nevertheless, a short comment is appropriate, since this is acase where the ferromagnetism causes a strong enhancementof the relaxation and where the origin of this enhancement isthought to be known.
It has been proposed that the nuclear spins in the domain
walls couple to vibrations of the domain walls, which, inturn, are damped by eddy currents.
21,39Thus, it might be
possible to develop a unified treatment of the relaxation indomain walls and the relaxation via eddy currents. One dif-ficulty will be that in the case of the domain walls, theirspatial distribution and their restoring forces play an impor-tant role. The poor knowledge of those parameters will makea detailed comparison with the experiment difficult.
IV . RELAXATION MEASUREMENT BY NUCLEAR
MAGNETIC RESONANCE ON ORIENTED NUCLEI
In nuclear magnetic resonance on oriented nuclei /H20849NMR-
ON /H20850, the resonant depolarization of the radioactive probe
nuclei is detected via the resulting change in the anisotropicemission of the
/H9253radiation.40To measure the nuclear spin-
lattice relaxation by NMR-ON, the frequency modulation/H20849FM /H20850of the rf field is periodically switched on and off.
8,41
Due to the inhomogeneous broadening of the resonance, the
nuclear spins are excited only if the FM is enabled and relaxback to thermal equilibrium if it is switched off.
Essentially, three parameters can be obtained from a least
squares fit to the relaxation curve of the
/H9253anisotropy during
the FM on-off cycle: the relaxation constant R, the rf transi-
tion rate Rrf, which is defined below, and the fraction frfof
the probe nuclei that are excited by the FM. frf/H110211 occurs,
for example, if some probe nuclei are located on slightlydisturbed lattice sites, with resonance frequencies that lieoutside of the bandwidth of the FM.
At the low temperatures of NMR-ON experiments, a mul-
tiexponential relaxation behavior is observed, which can bedescribed by a set of rate equations /H20849the master equation /H20850for
the sublevel populations:
d
dtpm=/H20858
n/H20849Wm,npn−Wn,mpm/H20850, /H2084961/H20850
where pmis the population of the level with the magnetic
quantum number mandWm,nis the transition rate from the
level nto the level m. The transition rates are given by
Wm+1,m=cm,m+1/H20875h/H9263n
2kB/H208491−b/H20850R+Rrf/H20876,
Wm,m+1=cm,m+1/H20875h/H9263nb
2kB/H208491−b/H20850R+Rrf/H20876, /H2084962/H20850
where
cm,m+1=I/H20849I+1/H20850−m/H20849m+1/H20850,b= exp/H20873−h/H9263n
kBT/H20874,
and Iis the nuclear spin. When the FM is not applied,
Rrf=0. We only mention that actually more sophisticated ex-
pressions for the transition rates were used, which are givenin Ref. 42. However, the differences are not decisive in the
context of this work. The solution of the master equation andthe relationship between the sublevel populations and the
/H9253
anisotropy are described in detail in Refs. 3,41, and 43.
The description of the relaxation behavior of dilute
nuclear spins by transition rates is well established in theabsence of a rf field. The use of the rf transition rate R
rf,
however, has been discussed controversially: On one hand, ithas been argued that the effect of a coherent rf field cannotcorrectly be treated in that way.
2,3,12,14On the other hand, it
has been argued that in NMR-ON experiments, the coher-ence is sufficiently disturbed to justify such a treatment.
9,44,45
To clarify that point, in the remainder of this section, the
excitation process is analyzed in more detail.
Due to the FM, the rf field induces transitions between the
sublevels only during small time intervals when the rf fre-quency passes the resonance frequency of the particular spin.Fast passages, therefore, alternate with intervals of nearlyfree precession. Within the rotating frame, each passagecauses a rotation of the spins by an angle
/H9258around the yaxis,
whereas in the time until the next passage, the spins precessaround the zaxis by the angle
/H9278./H9258depends on the rf-field
strength. Usually, /H9258/H11270/H9266. In that limit, /H92582is proportional to
the applied rf power per FM bandwidth. /H9278is given by
/H9278=2/H9266/H20885
tptp+/H9004t
/H20851/H9263n−/H9263rf/H20849t/H20850/H20852dt, /H2084963/H20850
where /H9263rf/H20849t/H20850is the frequency of the rf field as a function of
the time, tpis the time of the passage, and /H9004tis the time
between successive passages. Contributions of the fast pas-sages to
/H9278are neglected here for simplicity, because they
change the dependences of /H9278on/H9263nand/H9263rfnot decisively.
To describe the sequence of the rotations of the spins, it is
convenient to expand the spin density matrix /H9267into irreduc-
ible tensor operators Tlmof rank land order maccording to
/H9267=/H20858
l=02I
/H20858
m=−ll
blmTlm, /H2084964/H20850
where the blm’s are complex coefficients.46,47The coefficients
blm/H20849j+1/H20850before the /H20849j+1/H20850th passage are then given in terms of
the coefficients before the jth passage by48
blm/H20849j+1/H20850= exp /H20849−im/H9278/H20850/H20858
m/H11032=−ll
dmm/H11032/H20849l/H20850/H20849/H9258/H20850blm/H11032/H20849j/H20850. /H2084965/H20850
Here, the dmm/H11032/H20849l/H20850/H20849/H9258/H20850’s are the elements of the reduced rotation
matrix, which are given, for example, in Ref. 48.
/H9278is the sum of its nominal value /H92780and of a fluctuating
part/H9278f, which varies from passage to passage, because the
instability of the rf generator leads to small fluctuations of /H9263rf
around its nominal value. For example, for a sawtooth modu-lation, Eq. /H2084963/H20850givesSEEWALD et al. PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-12/H92780=2/H9266/H9263n−/H9263c
/H9263FM, /H2084966/H20850
where /H9263FMis the modulation frequency and /H9263cthe center
frequency. Since the inhomogeneous broadening of /H9263nis usu-
ally much larger than /H9263FM, all values of /H92780between 0 and 2 /H9266
occur almost equally frequently. The mean square deviation/H9004
/H9278fof/H9278fcan be related to the full width of half maximum
/H9004/H9263rfof the frequency spectrum of the fluctuations of /H9263rf.I f
the correlation time of the fluctuations is much smaller than
both/H9263FM−1and /H20849/H9004/H9263rf/H20850−1, the spectrum is motion narrowed,49
and the following relation can be derived from Eq. /H2084963/H20850:
/H9004/H9278f=/H208732/H9266/H9004/H9263rf
/H9263FM/H208741/2
. /H2084967/H20850
This detailed description of the excitation process can be
used to calculate the temporal evolution of the density matrixafter the FM is switched on. Initially, the density matrix isdiagonal, which implies that only the b
l0’s are different from
zero. The subsequent changes of the blm’s from passage to
passage follow from Eq. /H2084965/H20850. To take the variation of /H92780
between 0 and 2 /H9266into account, one must either repeat the
calculation for different /H92780’s and take the average as the
density matrix of the entire spin system. Or one expands theb
lm’s into powers of exp /H20849i/H92780/H20850, calculates the temporal evolu-
tion of the expansion coefficients by a correspondingly ex-tended version of Eq. /H2084965/H20850, and takes the coefficients of the
zeroth power as the density matrix of the entire spin system.
To simulate the fluctuations of
/H9278f, before each passage, a
new value of /H9278fwas determined by a random number gen-
erator in such a way that the probability distribution of /H9278f
was Gaussian with mean square deviation /H9004/H9278f. For simplic-
ity, it was assumed that /H9278fis the same for all spins. Due to
the fluctuations of /H9278f, the excitation curves fluctuate too.
However, in the measurements, these fluctuations are re-duced, because the average over several FM on-off cycles istaken. Accordingly, the evolution of
/H9267was calculated a num-
ber of nrtimes with different random numbers, and the av-
erage was adopted as the final result.
In this way, the exact temporal evolution of the spin den-
sity matrix was calculated for different values of l,/H9258,/H9004/H9278f,
andnr. The comparison with the predictions of the rate equa-
tions /H2084961/H20850and /H2084962/H20850showed under which conditions those
equations are a good approximation. If the spin-lattice relax-ation is neglected, the rate equations, which describe only thediagonal part of
/H9267,47predict41
bl0/H20849t/H20850=bl0/H208490/H20850exp /H20849−klt/H20850,
kl=l/H20849l+1/H20850Rrf. /H2084968/H20850
This turned out to be a good approximation under the fol-
lowing conditions.
/H20849i/H20850The fluctuations of the bl0/H20849j/H20850’s due to the fluctuations of
/H9278fare roughly proportional to /H20849nlnr/H20850−1 /2, where nlis the num-
ber of the fast passages after which bl0is reduced by a factor
ofe.nlnrcan be interpreted as the number of /H9278f’s that con-
tribute to the essential part of the excitation curve. In orderthat the temporal evolution of b
l0is reasonably smooth and
well defined, that number must be large enough./H20849ii/H20850The coherence between the rf field and the spin sys-
tem is disturbed by the random variations of /H92780from spin to
spin and of /H9278ffrom passage to passage. In order that the
coherence gets essentially lost, /H9004/H9278fmust be at least of the
order of /H9266. In that case, the individual contributions to the
nondiagonal elements of /H9267cancel each other, and the diago-
nal elements decay, in the limit nr→/H11009, exponentially accord-
ing to
bl0/H20849j+1/H20850=bl0/H208491/H20850/H20851d00/H20849l/H20850/H20849/H9258/H20850/H20852j. /H2084969/H20850
/H20849iii/H20850In order that the respective decay constants are pro-
portional to l/H20849l+1/H20850and to the applied rf power, the condition
/H9258/H11270/H9266, which is equivalent to nl/H112711, must be fulfilled. In that
limit the decay constant of bl0can be approximated by
− log /H20851d00/H20849l/H20850/H20849/H9258/H20850/H20852
/H9004t/H11015l/H20849l+1/H20850/H92582
4/H9004t, /H2084970/H20850
which is identical to klof Eq. /H2084968/H20850,i fRrfis identified with
/H92582//H208494/H9004t/H20850.
A quantitative analysis revealed that the deviations from
prediction /H2084968/H20850of the rate equations are less than 3% of
bl0/H208490/H20850if/H9004/H9278f/H333560.55/H9266,nl/H3335610, and nlnr/H3335680. Typical num-
bers that apply to the experiments in this work are /H9004/H9263rf
=750 Hz, /H9263FM=100 Hz, /H9004/H9278f=2.2/H9266,nr=1000, and nl=20.
The conclusion is, therefore, that the interpretation of theNMR-ON relaxation curves in this work by the rate equa-tions is justified.
Finally, it should be mentioned that, in order to confine
the number of the parameters to a minimum, this analysis ofthe excitation process neglects several involvements: /H20849i/H20850The
spin-lattice relaxation is completely neglected. /H20849ii/H20850A single
resonance frequency for each spin is assumed. However, dueto the small electric hyperfine interaction in cubic ferromag-nets, the resonance is actually split into 2 Isubresonances.
/H20849iii/H20850
/H9278fis assumed to be the same for all spins. However,
since the moment of a particular fast passage is not exactlythe same for all spins,
/H9278factually also varies from spin to
spin, though much less than from passage to passage. /H20849iv/H20850
The actual pattern of the modulation of the rf frequency maybe more involved than a sawtooth modulation.
However, all those effects only further disturb the coher-
ence between the rf field and the spins. The agreement withthe rate equations should, therefore, be still better than dem-onstrated above.
V . EXPERIMENTAL DETAILS
The Fe sample was a circular single-crystal disk with
/H20849110 /H20850plane, 2.2 mm thick, and 12 mm in diameter. The pu-
rity of the sample and the flatness of the surface benefitedfrom the fact that the sample was originally prepared forexperiments on surface chemistry: For example, the bulkconcentration of sulfur was reduced by baking at tempera-tures of 970–1120 K in flowing hydrogen for three weeks.The segregation of contaminants at the surface was reducedin an UHV chamber by hundred cycles of heating /H208491000 K,
10–30 min /H20850and Ar
+sputtering /H20849500 K, 750 eV, 1 /H9262Ac m−2,
30–10 min /H20850. The final examination of the purity at the sur-ORIGIN OF THE MAGNETIC-FIELD DEPENDENCE OF … PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-13face by Auger-electron and photoelectron spectroscopies re-
vealed only about 0.4 at. % phosphorus, 0.4 at. % sulfur,3 at. % carbon, and 1 at. % oxygen.
Hg precursors of the probe nuclei
186Ir and189Ir were
coimplanted at the on-line mass separator ISOLDE at CERN
/H20849about 3 /H110031012nuclei of186Hg and 8 /H110031012of189Hg, im-
plantation voltage of 60 kV /H20850. To delimit the variation of
position-dependent parameters such as the demagnetizationfield or the rf-field strength, the Hg beam was confined by adiaphragm to a spot of 4 mm diameter in the center of thedisk. After the implantation, the sample was annealed forabout 1 /2 h at 970 K and slowly cooled down to room tem-
perature.
The sample was then loaded into a
3He-4He-dilution re-
frigerator and cooled down to temperatures in the 20 mKrange. The magnetic field was applied along the /H20851100 /H20852direc-
tion in the sample plane. The orientation of the crystallo-graphic axes relative to the magnetic field was accurate to 1°.The
/H9253anisotropy was measured by four Ge detectors, placed
at 0°, 90°, 180°, and 270° with respect to the direction of themagnetic field. The count rate ratio
/H9280=N/H208490°/H20850+N/H20849180 ° /H20850
N/H2084990 ° /H20850+N/H20849270 ° /H20850−1 /H2084971/H20850
was used to analyze the data. The temperature was primarily
determined by a60Co Co /H20849hcp /H20850nuclear orientation thermom-
eter. However, because of the low sensitivity of that ther-mometer at temperatures above 20 mK, in most relaxationmeasurements, the temperature was determined via the equi-
librium
/H9253anisotropy of186Ir, which was calibrated with re-
spect to the primary thermometer at lower temperatures.
The rf frequency was modulated in the following way: An
external triangular FM was applied with bandwidth of
/H110065 MHz and frequency /H9263FM/H208491/H20850=100 Hz. In addition, to rein-
force the disturbance of the coherence between the rf fieldand the spins, a second internal triangular FM was applied
with bandwidth of /H11006200 Hz and frequency
/H9263FM/H208492/H20850=1 Hz. The
half-width /H9004/H9263rfof the frequency fluctuations of the rf signal
generator in the external modulation mode was about750 Hz. This was measured at nominally zero applied modu-lation voltage by a rf frequency analyzer.
The magnetic dipolar and the electric-quadrupolar parts of
the relaxation were determined from the combined relaxation
data on
186Ir and189Ir, as discussed in Ref. 15. In this work,
only the magnetic relaxation constants of186Ir are quoted.
Anyway, for that isotope, the quadrupolar contribution to therelaxation was only of the order of 1%.
VI. MEASUREMENTS
The static hyperfine interactions were determined by
NMR-ON and modulated adiabatic fast passage on orientednuclei /H20849MAPON /H20850.
50,51Figure 3shows the NMR-ON spec-
trum at Bext=0.1 T. The magnetic resonance frequency and
the subresonance separation were /H9263n=794.68 /H2084920/H20850MHz and
/H9004/H9263Q= +0.838 /H208492/H20850MHz, respectively. Additional NMR-ON
spectra were measured at Bext=0.5 and 1.0 T. From the field
dependence of the resonance, Bdem/H208490/H20850=0.274 /H2084917/H20850T was de-duced. To excite all subresonances in the relaxation measure-
ments, the frequency was modulated, for example, atB
ext=0.1 T between 789.4 and 799.4 MHz.
The magnetization behavior was monitored via the /H9253an-
isotropy of186Ir, which remained constant at 95 /H208491/H20850%o fi t s
saturation value for Bext/H333550.25 T, increased slightly between
0.25 and 0.40 T, and remained at its saturation value forhigher fields. This confirmed that the magnetization was es-sentially aligned along the /H20851100 /H20852direction within the sample
plane. Other alignments of the magnetization apparently onlyoccurred at low fields in a small fraction of the sample. Thatfraction remained constant in the multidomain regime up to
B
ext=Bdem/H208490/H20850but disappeared at higher fields.
The angular-distribution coefficients of the most intense /H9253
transitions of186Ir, which were needed for the description of
the relaxation curves and for the thermometry via186Ir, were
determined by measurements of the /H9253anisotropy as a func-
tion of the temperature between 10 and 23 mK. For example,A
2=−0.311 /H208492/H20850and A4=−0.136 /H208494/H20850were obtained for the
297 keV transition at Bext=0.5 T. /H20849Here, Aicorresponds to
AiUiin the notation of Ref. 43./H20850
The reliability of the relaxation measurement technique
was tested by measurements at different rf-power levels. For
example, at Bext=0.5 T, the applied rf power Prfwas varied
in five measurements by a factor of 16. Thereby the relativeresonant reduction of the nuclear magnetization varied be-tween 9% and 71%, whereas the temperature varied betweenk
BT/h/H9263n=0.60 and kBT/h/H9263n=1.78. Figure 4shows three of
the relaxation curves. All relaxation curves could perfectlybe described by the theory. Moreover, the least squares fitresults for R,R
rf, and frfwere all consistent, demonstrating
the reliability of the measurement technique and of the inter-pretation of the relaxation curves. The fit results are shown inFig. 5as a function of P
rf.
Similarly consistent results were obtained at Bext=0.1 T,
where Prfwas varied in six measurements by a factor of 32.
The only deviation from the theory was that at the two high-est rf-power levels, the increase of R
rfwith Prfwas smaller
than expected. However, at those high power levels, the timescale of the excitation by the rf field was extraordinarilyshort, of the order of 2–3 periods of the FM. It is not sur-prising that in this case, the picture of a continuous excitationprocess begins to fail.
Further tests examined the disturbance of the coherence of
the rf field. According to Sec. IV , that disturbance manifestsFIG. 3. NMR-ON spectrum of186Ir at Bext=0.1 T. T
=46 /H208492/H20850mK, FM bandwidth /H110060.5 MHz. The interpretation of the
only partly resolved subresonance structure made use of the knowl-edge of the distribution of /H9004
/H9263Qfrom the MAPON measurements.SEEWALD et al. PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-14itself in fluctuations of /H9278=/H92780+/H9278f, the relative phase of sub-
sequent fast passages. As shown in Sec. IV , the fluctuationsare expected to be large enough that the excitation of thespins can be described by rf transition rates as in the case ofan incoherent irradiation. In this case, additional variationsof
/H9278should have no effect. This was confirmed in the fol-
lowing ways: /H20849i/H20850Relaxation measurements with and without
the second FM, which varies /H92780periodically by more than2/H9266, gave identical results. /H20849ii/H20850Applying only a single modu-
lation, the resonance effect was measured as a function of
/H9263FM. In this way, /H9004/H9278fwas varied according to Eq. /H2084967/H20850, but
the resonance effect remained essentially constant between
/H9263FM=50 Hz and /H9263FM=1 kHz.
Only for /H9263FM=5 kHz and larger /H9263FM’s the resonance effect
was significantly reduced as a result of the reduction of /H9004/H9278f.
The resonance effect was also reduced for /H9263FM=20 Hz and
smaller /H9263FM’s, because the time between the fast passages
became of the order of the relaxation time. A similar depen-dence of the NMR-ON resonance effect on
/H9263FMand a similar
interpretation had already been reported in Ref. 41for60Co
in Fe.
The magnetic-field dependences of the spin-lattice relax-
ation and the enhancement factor were determined by relax-ation measurements at 17 different fields between 0.05 and2.0 T. RandR
rf/Prf, which is, apart from a prefactor, equiva-
lent to /H92572, are shown as a function of Bextin Figs. 6and7,
respectively. frfwas in all cases consistent with the average
value frf=0.88 /H208492/H20850.
The field dependence of /H9257was described by Eqs. /H208491/H20850and
/H208493/H20850, assuming Ba=0.059 T. This resulted in a perfect descrip-
tion of the field dependence of Rrf/Prfover 3 orders of mag-
nitude. Only Bdem/H208490/H20850and the proportionality constant between
/H92572andRrf/Prfwere adjusted via least squares fit. The solidFIG. 4.186IrFe, Bext=0.5 T: NMR-ON relaxation curves at dif-
ferent rf-power levels /H20849and temperatures /H20850.Prfin arbitrary units. The
increase and the decrease of /H9280reflect the temporal evolution after
switching the FM on and off, respectively.
FIG. 5.186IrFe, Bext=0.5 T: R,Rrf/Prf, and frffrom measure-
ments at different rf-power levels. At the lowest power level, frfhad
to be taken from the other measurements, because frfandRrfproved
to be too correlated to determine both parameters independently.FIG. 6.186IrFe: Magnetic-field dependence of the nuclear spin-
lattice relaxation.
FIG. 7.186IrFe: Magnetic-field dependence of the square of the
enhancement factor.ORIGIN OF THE MAGNETIC-FIELD DEPENDENCE OF … PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-15line in Fig. 7shows the respective theoretical curve. If Ba
was also fitted to the data, Ba=0.0607 /H2084911/H20850T was obtained, in
agreement with the literature value.
Bdem/H208490/H20850=0.287 /H208492/H20850T was obtained from the fit to the field
dependence of /H92572, in agreement with the value that was de-
duced from the field dependence of /H9263n, but in disagreement
with the calculated value, Bdem/H208490/H20850/H110110.20 T. The deviation from
the calculated value could not be resolved. In any case, the
sharp bend of the field dependences at Bext=Bdem/H208490/H20850showed
that the assumption of a uniform value of Bdem/H208490/H20850for all probe
nuclei was essentially justified.
The field dependence of Rcould be described in different
ways. The EFM in the form of Eq. /H208492/H20850has the virtue that the
magnitude and the form of the field dependence can be char-acterized by a simple expression without binding oneself to aparticular explanation. The dashed line in Fig. 8shows the fit
of that model to the data. Using B
a=0.059 T, an almost per-
fect description was obtained with
R/H208490/H20850= 32.20 /H2084920/H20850/H20849sK /H20850−1,
R/H20849/H11009/H20850= 8.69 /H2084922/H20850/H20849sK /H20850−1,
/H9264= 1.39 /H208494/H20850.
If, as it is done in this work, the field dependence of the
relaxation is attributed to eddy-current and Gilbert dampings,Ris the sum of a field-independent part R/H20849/H11009/H20850and of the
field-dependent contributions R
edand Rgi. The data could
perfectly be described in this way. The solid lines in the Figs.6and8show the respective theoretical curve. The following
parameters were determined via least squares fit:
/H92680//H9011= 7.1 /H208496/H20850/H20849/H9262/H9024cm/H9262m/H20850−1,
G= 0.075 /H2084917/H20850GHz,
R/H20849/H11009/H20850= 7.4 /H208495/H20850/H20849sK /H20850−1.
The quoted errors already take the uncertainty in /H92680into
account. /H92680was assumed to be in the range
3.0–1000 /H20849/H9262/H9024cm/H20850−1, which corresponds to a residual resis-
tivity ratio between 30 and 104. The composition of the field-
dependent part of the relaxation changes strongly with thefield: At B
ext=0 T, for example, the quoted damping param-
eters imply Red=20.2 /H20849sK /H20850−1andRgi=4.6 /H20849sK /H20850−1, whereas
atBext=1 T, for example, Red=0.29 /H20849sK /H20850−1and Rgi
=1.60 /H20849sK /H20850−1.
In the past, the field dependence of the relaxation had
often been described by the EFM assuming /H9264=2, and Bahad
been fitted to the data. To assess the results that had beenobtained in this way, we also applied that traditional variantof the EFM. The following parameters were obtained vialeast squares fit:
B
a= 0.091 /H208494/H20850T,
R/H20849/H11009/H20850= 9.41 /H2084918/H20850/H20849sK /H20850−1.
The dotted line in Fig. 8shows the respective theoretical
curve. The field dependence of Ris remarkably well repro-duced, at least between 0 and 1 T, although Bais clearly
wrong.
VII. DISCUSSION
A. Origin of the magnetic-field dependence
For all the relaxation mechanisms that were discussed in
Sec. III, the magnetic-field dependence is actually a depen-dence on B
/H9257. The knowledge of the magnetic-field depen-
dence of B/H9257is thus indispensable for the comparison be-
tween experiment and theory. Therefore, the experimentaldetermination of the field dependence of B
/H9257in this work via
the quantity Rrf/Prfwas particularly important. It confirmed
thatB/H9257was indeed given by Eq. /H208493/H20850with Ba=0.0607 /H2084911/H20850T.
This showed, in particular, that the value of Baand the mag-
netization behavior were not modified at the site of the probenuclei by the presence of the impurity, by the closeness to thesurface, or by other effects.
The discussion of the various potentially field-dependent
relaxation mechanisms in Sec. III showed that most of themcan be excluded as the source of the observed field depen-dence: The direct excitation of spin waves is not possible,since the spin-wave frequencies are larger than
/H9263n. The exci-
tation of sound waves is negligible. The field dependences ofthe various variants of the indirect spin-wave mechanism aregiven in Sec. III D. They are all too weak to explain theobserved field dependence. A connection to domain wallscan also be excluded, since the domain walls just disappear
when the field dependence sets in at B
ext=Bdem/H208490/H20850.
In contrast, the relaxation via eddy-current and Gilbert
dampings explains both the magnitude and the form of thefield dependence. It provides a perfect description of thedata. The used values of the damping parameters
/H92680//H9011and
Gare well within the expected ranges, which were specifiedFIG. 8.186IrFe: Comparison of the field dependence of the spin-
lattice relaxation with the descriptions by R=R/H20849/H11009/H20850+Red+Rgi/H20849solid
line /H20850, by the EFM with Ba=0.059 T and /H9264=1.39 /H20849dashed line /H20850, and
by the EFM with Ba=0.091 T and /H9264=2 /H20849dotted line /H20850. In order to
show the low-field part more clearly, a double logarithmic scale wasused, and B
extwas converted into B/H9257, assuming Bdem/H208490/H20850=0.287 T and
Ba=0.059 T.SEEWALD et al. PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-16in Secs. III E and III F. This strongly suggests that the relax-
ation via eddy-current and Gilbert dampings is indeed thesource of the magnetic-field dependence of the nuclear spin-lattice relaxation in Fe. Of course, further, hitherto unknown,sources cannot completely be excluded, since
/H92680//H9011andG
had to be adjusted via least squares fit. One should also beaware that the used values of
/H92680//H9011andGmay not represent
the actual values of those damping parameters, because thesurface effects were not taken into account.
Having identified the relaxation mechanism that is re-
sponsible for the magnetic-field dependence, we can now usethe theory that has been worked out in Secs. III E and III F toestablish the connection to previous theoretical work, to re-interpret the results of other experiments, to compare thefield dependences in Fe, Co, and Ni, and to judge the validityof the literature values of R/H20849/H11009/H20850.
B. Previous concepts
The theory of the spin-lattice relaxation via eddy-current
and Gilbert dampings contains several concepts that havealready been suggested previously in the context with thefield dependence of the relaxation in Fe: For example, thevirtual excitation of spin waves, which was proposed to-gether with the indirect spin-wave mechanism, is also onestep in the relaxation via eddy-current and Gilbert damping.Moreover, the indirect spin-wave mechanism itself can beunderstood as one contribution to R
gi.
It also turns out that the original concept of the EFM, the
proportionality between the field-dependent part of the spin-lattice relaxation and the square of the enhancement factor,indeed applies in some sense to the relaxation via the virtualexcitation of spin waves. However, it is the enhancementfactor
/H9257/H20849q/H20850=BHF
B/H9257+/H20849Dq2/H20850//H20849/H6036/H20841/H9253e/H20841/H20850
of transversal fields with wave vector qthat enters quadrati-
cally via the factor /H20851/H9275x/H208490/H20850/H20852−2in Eq. /H2084928/H20850. The field dependence
thus essentially combines /H20851/H9257/H20849q/H20850/H208522terms from all momentum
transfers, whereas within the EFM, it is approximated by a
/H9257/H9264term, where /H9257is the q=0 limit of /H9257/H20849q/H20850. Since the field
dependence of /H9257/H20849q/H20850decreases with increasing q,/H9264is smaller
than 2. To which extent depends on the weighting of theindividual momentum transfers.This relationship to the EFM also reveals that the form of
the field dependence is indeed a signature of the proposedrelaxation mechanism: It was first a puzzle that the field-dependent part of the relaxation seemed to be proportional to
/H92572, as if only q=0 would contribute. That puzzle is now
solved: On one hand, our experiment shows that /H9264is indeed
smaller than 2. On the other hand, the eddy-current dampingimplies a particularly strong weighting of small momentum
transfers: Im /H20851
/H9275x/H20849ed/H20850/H20852and Im /H20851/H9275y/H20849ed/H20850/H20852are proportional to q−3for
q/H9254/H112711 and q/H9011/H112711. Such a strong preference of small q’s is
required to explain the strong field dependence with /H9264close
to 1.4. Moreover, it is not readily reproduced by other relax-ation mechanisms, as the discussion in Sec. III D showed:All discussed variants of the indirect spin-wave mechanismhave distinctly weaker field dependences, because the small
momentum transfers are less strongly weighted.
C. Other experiments
A major problem of the interpretation of previous experi-
ments is the fact that the field dependence of B/H9257is not well
known in most cases. B/H9257is reasonably well known only for
the experiments on Fe single crystals where the magneticfield was applied along the /H20851100 /H20852direction in the sample
plane. The data of those experiments were redescribed byboth R/H20849/H11009/H20850+R
ed+Rgiand the EFM. B/H9257was assumed to be
given by Eq. /H208493/H20850with Ba=0.059 T. Bdem/H208490/H20850was fitted to the
data. Table Isummarizes the results.
The form of the field dependences supports the interpre-
tation by Red+Rgi. The parameter /H9264is a measure of the re-
spective agreement with the theory. It is, within the error, inall cases close to 1.4, as expected for R
ed+Rgi. In contrast,
the magnitudes of the field dependences are inconsistent inso far as they cannot be described by the same set of damp-ing parameters
/H92680//H9011andG. This also manifests itself by the
differences in /H20851R/H208490/H20850−R/H20849/H11009/H20850/H20852//H9263n2, which cannot be explained
by the weak /H9263ndependence of /H20849Red+Rgi/H20850//H9263n2. This inconsis-
tency may be attributed to surface effects. This would implythat differences in the surface preparation or in the locationof the probe nuclei had changed the field-dependent part ofthe relaxation by up to a factor of 2.
Relaxation measurements on Fe single crystals were also
performed with the magnetic field applied along otherTABLE I. Parameters of the field dependence of the spin-lattice relaxation in Fe from different experi-
ments in the /H20851100 /H20852geometry. /H92680//H9011was determined by a fit of R/H20849/H11009/H20850+Red+Rgi, assuming a residual resistivity
ratio between 30 and 104.G=0.075 GHz was taken from the186Ir experiment, because the precision of the
data was not sufficient for its determination in the other cases. /H9264,R/H208490/H20850, and R/H20849/H11009/H20850were determined by a fit of
the EFM.
Isotope/H9263n
/H20849GHz /H20850 Ref./H92680//H9011
/H20851/H20849/H9262/H9024cm/H9262m/H20850−1/H20852 /H9264/H20851R/H208490/H20850−R/H20849/H11009/H20850/H20852//H9263n2
/H20851/H20849sK/H20850−1GHz−2/H20852R/H20849/H11009/H20850//H9263n2
/H20851/H20849sK/H20850−1GHz−2/H20852
110mAg 0.205 9 2.6/H208495/H20850 1.60 /H2084934/H20850 21.0 /H2084924/H20850 10.3 /H2084912/H20850
131I 0.683 8and9 5.2/H208496/H20850 1.36 /H2084917/H20850 30.9 /H2084919/H20850 8.3/H2084912/H20850
186Ir 0.795 This work 7.1 /H208496/H20850 1.39 /H208494/H20850 37.2 /H208495/H20850 13.8 /H208493/H20850
191Pt 0.320 52 2.7/H208493/H20850 1.13 /H2084930/H20850 21.9 /H2084920/H20850 9.9/H2084914/H20850ORIGIN OF THE MAGNETIC-FIELD DEPENDENCE OF … PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-17crystallographic directions.8,9,14In most cases, geometries
were investigated where B/H9257vanishes, at least nominally, for
certain values of the magnetic field. Those experimentsnicely demonstrated that it is indeed the quantity B
/H9257that has
to become small to obtain a large relaxation rate. However,quantitative conclusions are not possible, because the fielddependence of B
/H9257was not determined experimentally, nor
can it reliably be calculated. The problem with the calcula-tion is that, when B
/H9257becomes very small, the magnetization
behavior becomes extremely sensitive to misalignments andinhomogeneities, which are always unavoidable to some ex-tent.
Most of the previous relaxation experiments were per-
formed on cold-rolled polycrystalline foils of dilute Fe al-loys, where a well-founded description of the field depen-dence of B
/H9257is not feasible. Nevertheless, the previous
interpretation of those experiments is of interest, because itseemed to support the assumption
/H9264=2: The field depen-
dence of the relaxation could be described by the EFM and
/H9264=2, if B/H9257was parametrized by Ba+Bext, and Bawas ad-
justed via least squares fit.6,7,53,54However, Baand/H9264are
strongly correlated, and over a fairly large magnetic-fieldregion, a wrong choice of one of those parameters can becompensated by a wrong choice of the other parameter. This
was demonstrated in this work for
186IrFe: The field depen-
dence of Rcould almost equally well be described by /H9264
=1.39 and the “correct” Baor by /H9264=2 and a “wrong,” dis-
tinctly larger Ba. Therefore, the values of /H9264andBafrom the
previous interpretation of those experiments are meaningless.
The theory of Red+Rgiis also important for the under-
standing of experiments where the relaxation rates of differ-ent isotopes of the same element in the same sample arecompared, because it predicts deviations from the usually
expected proportionality to
/H9263n2, which is well established, for
example, for R/H20849/H11009/H20850.53An experiment of this kind on60Co
/H20849/H9263n=0.166 GHz /H20850and58Co /H20849/H9263n=0.442 GHz /H20850in Fe was re-
ported in Ref. 14. From the low-field measurements of that
work,
/H20849R/H11032//H9263n2/H20850/H2084958Co/H20850
/H20849R/H11032//H9263n2/H20850/H2084960Co/H20850= 0.70 /H2084912/H20850
can be deduced, where R/H11032denotes the field-dependent part of
R.B/H9257was presumably in the range 0.02–0.06 T. The devia-
tion from R/H11032/H11008/H9263n2is, at least in part, explained by the theory
ofRed+Rgi, according to which
/H20851/H20849Red+Rgi/H20850//H9263n2/H20852/H2084958Co/H20850
/H20851/H20849Red+Rgi/H20850//H9263n2/H20852/H2084960Co/H20850= 0.81 – 0.89,
if the damping parameters are similar to those of the186IrFe
experiment. Unfortunately, the statistical significance of thequoted data is poor and technical details of the respectivemeasurements have been questioned.
7
Relaxation measurements on different isotopes of the
same element in the same sample were also reported in Refs.15and 42. They were used to deduce the electric-
quadrupolar part of the spin-lattice relaxation, which ispossible, if the quadrupole moment of one of the isotopes is
sufficiently large. However, to separate the magnetic-dipolarand the electric-quadrupolar parts of the relaxation, a scaling
of the magnetic part with
/H9263n2was assumed. Therefore, the
deduced field dependences of the quadrupolar relaxation areinvalid. In contrast, the deduced high-field limits should es-sentially be correct.
In the case of the measurements of this work on
186Ir and
189Ir, the data were reanalyzed, taking the /H9263ndependences of
RedandRgiinto account. The revised result for the ratio of
the low-field and the high-field quadrupolar relaxation con-stants is R
q/H208490T /H20850/Rq/H208492T /H20850=0.97 /H2084915/H20850. Thus, there is no sig-
nificant field dependence of the quadrupolar relaxation, incontrast to our previous conclusion in Ref. 15.
This field independence of the quadrupolar relaxation is in
accord with the theory. Indeed, R
edandRgialso contribute to
the quadrupolar relaxation, because the magnetization is alsocoupled to the nuclear quadrupole moment via the spin-orbit-induced electric-field gradient, but the contributions are toosmall to be observable. The form of these contributions iswell known from the similar but much stronger contributionof the indirect spin-wave mechanism to the quadrupolar re-laxation in the rare earth metals:
30The net effect is that Red
and Rgimust be calculated for each transition probability
Wm+1,mseparately with /H9263nreplaced by the respective transi-
tion frequency /H9263m+1,mof the quadrupolar-split resonance
spectrum. In Fe, the effect is negligible, because the /H9263m+1,m’s
differ only slightly from /H9263n.
D. Magnetic-field dependence in Co and Ni
Distinct magnetic-field dependences of the nuclear spin-
lattice relaxation have also been observed in Co /H20849hcp /H20850,55
Co/H20849fcc/H20850,56and Ni.9A detailed comparison with the theory is
not possible, because the field dependence of B/H9257is not suf-
ficiently well known for those experiments. However, esti-mates of the typical magnitudes of R
ed,Rgi, and R/H20849/H11009/H20850can
show at least whether major differences to the situation in Feare to be expected. To estimate R
edandRgiin Co and Ni, D
andGwere taken from Refs. 36and57–59. As discussed
below, in the case of G, the room-temperature value should
be used, which is, for Co and Ni, distinctly smaller than thelow-temperature value.
/H92680//H9011should be of the same order
of magnitude in Fe, Co, and Ni. Data on R/H20849/H11009/H20850in Fe, Co, and
Ni are available, for example, from Refs. 3,9,53,55, and
60–63.
In the case of Co as the host, Red,Rgi, and R/H20849/H11009/H20850turn out to
be of the same order of magnitude as in Fe. Thus, decisivedifferences to the situation in Fe are not expected, apart fromdifferences in the field dependence of B
/H9257.
In contrast, for Ni as the host, Redis of the same order of
magnitude as in Fe, but Rgiis larger by a factor of 20 and
R/H20849/H11009/H20850by typically 1 order of magnitude, if the comparison is
made for the same values of /H9263nandB/H9257. Thus, if B/H9257is of the
order of 0.1 T, the relaxation is faster than in the high-field
limit by factors that are similar to those in Fe. However, inNi, this is largely due to R
giand not to Red. This has the
following consequences: The field dependence of the relax-ation is much weaker than in Fe, with
/H9264close to 0.4. More-SEEWALD et al. PHYSICAL REVIEW B 77, 104433 /H208492008 /H20850
104433-18over, this implies that even at relatively large fields of the
order of 1 T, a large fraction of the relaxation may be due tothe field-dependent part.
It was also calculated which value of R
giin Ni is expected
if the low-temperature value of Gis used in combination
with Eq. /H2084957/H20850. It turned out that the use of the low-
temperature value is in contradiction to the experiment: For
110mAg in Ni at Bext=0, for example, in this way, Rgi
=1.1 /H20849sK /H20850−1is predicted, which is much larger than the ob-
served relaxation constant of about R/H110110.2 /H20849sK /H20850−1in this
case.9In contrast, if the room-temperature value of Gis
used, Rgi=0.19 /H20849sK /H20850−1is predicted, which is of the right
order of magnitude. This finding confirms the following in-terpretation of the temperature dependence of G: According
to Refs. 58and64,Gis the sum of a largely temperature-
independent contribution and of a low-temperature contribu-tion, which is negligible for T/H11022150 K and which shows
similar temperature and wave-vector dependences as theconductivity. The wave-vector dependence implies that therespective contribution to R
giis several orders of magnitude
smaller than suggested by the literature values of G, because
the wave vectors that are relevant for Rgiare much larger
than those that are relevant for the ferromagnetic-resonanceexperiments that are used to determine G. The consequence
is that the low-temperature contribution to Gmakes only a
negligible contribution to the spin-lattice relaxation.E. High-field limits
The high-field limits of the spin-lattice relaxation are im-
portant for the comparison with the ab initio calculations,
because the available calculations only take account of es-sentially field-independent contributions. Most literature val-ues of R/H20849/H11009/H20850in Fe were deduced by the EFM assuming
/H9264=2.53If the data of this work are interpreted in this way,
one obtains R/H20849/H11009/H20850=9.41 /H2084918/H20850/H20849sK /H20850−1. This is close to R/H20849/H11009/H20850
=8.97 /H2084925/H20850/H20849sK /H20850−1, which follows from the literature value
for IrFe from Ref. 53, if that value is corrected for the qua-
drupolar contribution to the relaxation42and if a consistent
set of nuclear moments is used to convert that value to186Ir.
In contrast, if the data are interpreted by R/H20849/H11009/H20850+Red+Rgi,
the parameter R/H20849/H11009/H20850is about 20% smaller. This suggests that
the actual high-field limits are smaller than the literature val-ues by amounts of the order of 20%.
ACKNOWLEDGMENTS
We appreciate very much the effort which was put by the
Orsay group into the development of the liquid Pb target atISOLDE. We also wish to thank E. Smolic for experimentalhelp and H. D. Rüter for communication of unpublishedwork.
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104433-20 |
PhysRevB.101.134430.pdf | PHYSICAL REVIEW B 101, 134430 (2020)
Interplay of large two-magnon ferromagnetic resonance linewidths and low Gilbert damping in
Heusler thin films
W. K. Peria,1T. A. Peterson,1A. P. McFadden,2T. Qu,3C. Liu,1C. J. Palmstrøm,2,4and P. A. Crowell1
1School of Physics and Astronomy, University of Minnesota, Minneapolis, Minnesota 55455, USA
2Department of Electrical & Computer Engineering, University of California, Santa Barbara, California 93106, USA
3Department of Electrical and Computer Engineering, University of Minnesota, Minneapolis, Minnesota 55455, USA
4Department of Materials, University of California, Santa Barbara, California 93106, USA
(Received 6 September 2019; revised manuscript received 14 December 2019; accepted 7 April 2020;
published 28 April 2020)
We report on broadband ferromagnetic resonance linewidth measurements performed on epitaxial Heusler
thin films. A large and anisotropic two-magnon scattering linewidth broadening is observed for measurementswith the magnetization lying in the film plane, while linewidth measurements with the magnetization saturatedperpendicular to the sample plane reveal low Gilbert damping constants of (1 .5±0.1)×10
−3,( 1.8±0.2)×
10−3,a n d <8×10−4for Co 2MnSi/MgO, Co 2MnAl/MgO, and Co 2FeAl/MgO, respectively. The in-plane
measurements are fit to a model combining Gilbert and two-magnon scattering contributions to the linewidth,revealing a characteristic disorder length scale of 10–100 nm.
DOI: 10.1103/PhysRevB.101.134430
I. INTRODUCTION
The theoretical understanding of the damping mechanism
believed to govern longitudinal magnetization relaxation inmetallic ferromagnets, originally due to Kamberský [ 1,2], has
in recent years resulted in quantitative damping estimates forrealistic transition metal band structures [ 3–5]. Although of
great interest where engineering of damping is desired [ 6],
these calculations remain largely uncompared to experimentaldata. Kamberský damping may be characterized by the so-called Gilbert damping constant αin the Landau-Lifshitz-
Gilbert macrospin torque equation of motion, and formallydescribes how the spin-orbit interaction in itinerant electronsystems results in damping of magnetization dynamics [ 2].
Schoen et al. [7] have reported that αis minimized for Co-Fe
alloy compositions at which the density of states at the Fermilevel is minimized, in reasonable agreement with Kamber-ský model predictions [ 8]. Furthermore, half-metallic or near
half-metallic ferromagnets such as full-Heusler compoundshave been predicted to demonstrate an ultralow Kamberskýα(/lessorequalslant10
−3) due to their spin-resolved band structure near
the Fermi level [ 9]. Finally, anisotropy of the Kamberský
damping in single crystals has been predicted, which is morerobust for Fermi surfaces with single-band character [ 5,10].
The Gilbert damping constant is often reported through
measurements of the ferromagnetic resonance (FMR)linewidth /Delta1H, which may be expressed as a sum of individual
contributions
/Delta1H=2αf
γ+/Delta1H0+/Delta1HTMS, (1)
where the first term is the Gilbert damping linewidth ( f
is the FMR frequency; γis the gyromagnetic ratio), /Delta1H0
is a frequency-independent inhomogeneous broadening, and/Delta1HTMSrepresents an extrinsic two-magnon scattering (TMS)
linewidth contribution [ 11,12] that is, in general, a nonlinear
function of frequency. In recent years it has been realized thatTMS linewidths are pervasive for the conventional in-planegeometry of thin film FMR measurements, requiring eitherthe perpendicular-to-plane FMR geometry [ 13] (for which
TMS processes are suppressed) or sufficiently broadbandmeasurements [ 14] to extract the bare Gilbert α. For instance,
recent FMR linewidth studies on Heusler compounds havereported distinct TMS linewidths [ 15,16], which challenged
simple inference of the Gilbert α.
In this article, we present FMR linewidth measurements
for epitaxial Heusler thin films for all principal orientations ofthe magnetization with respect to the symmetry axes. For thein-plane configuration, large and anisotropic TMS-dominatedlinewidths are observed. In the perpendicular-to-plane con-figuration, for which the TMS process is inactive [ 11], the
Gilbert αand inhomogeneous broadening are measured. We
find evidence of a low ( ∼10
−3) Gilbert αin these Heusler
thin films, accompanied by a large and anisotropic TMScontribution to the linewdith for in-plane magnetization. Weconclude by discussing the interplay of low Gilbert αand
large TMS, and we emphasize the nature by which the TMSmay conceal the presence of anisotropic Kamberský α.
II. SAMPLES
The Heusler alloy films used for these measurements
were grown by molecular beam epitaxy (MBE) by coevap-oration of elemental sources in ultrahigh vacuum (UHV).The MgO(001) substrates were annealed at 700
◦C in UHV
followed by growth of a 20 nm thick MgO buffer layerby e-beam evaporation at a substrate temperature of 630
◦C.
The 10 nm thick Co 2MnAl and Co 2MnSi films were grown
2469-9950/2020/101(13)/134430(7) 134430-1 ©2020 American Physical SocietyW. K. PERIA et al. PHYSICAL REVIEW B 101, 134430 (2020)
FIG. 1. (a) Wide-angle x-ray diffraction φscans of /angbracketleft202/angbracketright(blue)
and/angbracketleft111/angbracketright(red) peaks for the CMS film. (b) Typical derivative
susceptibility line shapes for these samples at different microwave
excitation frequencies. The fits are shown as solid lines. (c) In-
plane hysteresis loops for CFA obtained with a vibrating-samplemagnetometer (VSM). (d) Atomic force microscopy (AFM) image
of surface topography for CFA. RMS roughness is 0.2 nm.
on the MgO buffer layers at room temperature and then
annealed at 600◦C for 15 min in situ in order to improve
crystalline order and surface morphology. The 24 nm thickCo
2FeAl sample was grown using the same MgO substrate
and buffer layer preparation, but at a substrate temperatureof 250
◦C with no postgrowth anneal. Reflection high energy
electron diffraction (RHEED) was monitored during and aftergrowth of all samples and confirmed the expected epitaxialrelationship of MgO(001) /angbracketleft110/angbracketright| | Heusler (001) /angbracketleft100/angbracketright.X -
ray diffraction (XRD) demonstrated the existence of a sin-gle phase of (001)-oriented Heusler, along with the pres-ence of the (002) reflection, confirming at least B2ordering
in all cases. In addition, for the Co
2MnSi film only, the
(111) reflection was observed, indicating L21ordering [see
Fig. 1(a)]. All of the films were capped with several nm of
e-beam evaporated AlO xfor passivation prior to atmospheric
exposure. The effective magnetization for the 24 nm thickCo
2FeAl film was determined from the anomalous Hall effect
saturation field to be 1200 emu /cm3, which is consistent
with measurements of Ref. [ 17]f o r L21-o r B2-ordered
films, along with 990 emu /cm3and 930 emu /cm3for the
Co2MnSi and Co 2MnAl films, respectively. Hereafter, we will
refer to the Co 2MnSi(10 nm) /MgO as the “CMS” film, the
Co2MnAl(10 nm) /MgO film as the “CMA” film, and the
Co2FeAl(24 nm) /MgO film as the “CFA” film.
III. EXPERIMENT
Broadband FMR linewidth measurements were performed
at room temperature with a coplanar waveguide (CPW)transmission setup, similar to that discussed in detail in
Refs. [ 18,19], placed between the pole faces of an electro-
magnet. A cleaved piece of the sample ( ∼2m m ×1m m )
was placed face down over the center line of the CPW. Arectifying diode was used to detect the transmitted microwavepower, and a ∼100 Hz magnetic field modulation was used
for lock-in detection of the transmitted power, resulting ina signal ∝dχ/dH(where χis the film dynamic magnetic
susceptibility). The excitation frequency could be varied from0 to 50 GHz, and a microwave power near 0 dBm wastypically used. It was verified that all measurements discussedin this article were in the small precession cone angle, linearregime. The orientation of the applied magnetic field couldbe rotated to arbitrary angle in the film plane (IP), or appliedperpendicular to the film plane (PP). We emphasize againthat TMS contributions are suppressed in the PP configuration[12]. The resonance fields were fit as a function of applied
frequency in order to extract various magnetic properties ofthe films.
The magnetic free energy per unit volume used to generate
the resonance conditions for these samples is given by
F
M=−M·H+K1sin2φcos2φ+2πM2
effcos2θ, (2)
where His the applied field, φandθare the azimuthal and
polar angles of the magnetization, respectively, K1is a first
order in-plane cubic anisotropy constant, and 4 πMeffis the
PP saturation field, which includes the usual demagnetizationenergy and a first order uniaxial anisotropy due to interfacialeffects. The parameters obtained by fitting to Eq. ( 2)a r e
shown in Table I. The uncertainty in these parameters was es-
timated by measuring a range of different sample pieces, andusing the standard deviation of the values as the error bar. Thelong-range inhomogeneity characteristic of epitaxial samplesmakes this a more accurate estimate of the uncertainty thanthe fitting error. The magnetic-field-swept FMR line shapeswere fit to the derivative of Lorentzian functions [ 19] in order
to extract the full width at half maximum linewidths /Delta1H
[magnetic field units, Fig. 1(b)], which are the focus of this
article. The maximum resonant frequency was determined bythe maximum magnetic field that could be applied for bothIP and PP electromagnet configurations, which was 10.6 kOeand 29 kOe, respectively. For the IP measurement, the angleof the applied field in the plane of the film was varied todetermine the in-plane magnetocrystalline anisotropy of oursamples, which was fourfold symmetric for the three filmscharacterized in this article. The anisotropy was confirmedusing vibrating-sample magnetometry (VSM) measurements,an example of which is shown in Fig. 1(c), which shows
IP easy and hard axis hysteresis loops for the CFA film.For the PP measurement, alignment was verified to within∼0.1
◦to ensure magnetization saturation just above the PP
anisotropy field, thus minimizing field-dragging contributionsto the linewidth.
IV . RESULTS AND ANALYSIS
A. Perpendicular-to-plane linewidths
First we discuss the results of the PP measurement. As
stated in Sec. III, the TMS extrinsic broadening mechanism
is suppressed when the magnetization is normal to the plane
134430-2INTERPLAY OF LARGE TWO-MAGNON FERROMAGNETIC … PHYSICAL REVIEW B 101, 134430 (2020)
TABLE I. Summary of the magnetic properties extracted from the dependence of the resonance field on applied frequency for both field in-
plane ( ||) and field perpendicular-to-plane ( ⊥) configurations, along with the Gilbert αand inhomogeneous broadening from the perpendicular-
to-plane configuration. 2 K1/Msand 4πMeffare the in-plane and perpendicular-to-plane anisotropy fields, respectively [see Eq. ( 2)], and gis
the Landé gfactor.
Sample 2 K1/Ms(Oe) 4 πM||
eff(kOe) 4 πM⊥
eff(kOe) g||g⊥α001(×10−3) /Delta1H0(Oe)
CMS 280 12.3 13.3 2.04 2.04 1 .5±0.19 ±1
CMA 35 11.3 11.7 2.06 2.08 1 .8±0.21 2 ±3
CFA 230 15.1 15.5 2.06 2.07 <0.8 100 ±6
CFA 500◦C anneal N /AN /A 15.1 N /A 2.07 1 .1±0.14 5 ±1
of the film. We can thus fit our data to Eq. ( 1) with /Delta1HTMS=
0, greatly simplifying the extraction of the Gilbert dampingconstant αand the inhomogeneous broadening /Delta1H
0.P r i o r
knowledge of /Delta1H0is particularly important for constraining
the analysis of the IP measurements, as we shall discuss.
The dependence of /Delta1Hon frequency for the CMS, CMA,
and CFA films in the PP configuration is summarized inFig. 2, in which fits to Eq. ( 1) are shown with /Delta1H
TMS
set to zero. For the CMS film, α001=(1.5±0.1)×10−3
and/Delta1H0=9 Oe, while for the CMA film α001=(1.8±
0.2)×10−3and/Delta1H0=12 Oe. Co 2MnSi 2/3Al1/3/MgO and
Co2MnSi 1/3Al2/3/MgO films (both 10 nm thick) were also
measured, with Gilbert damping values of α001=(1.8±
0.2)×10−3andα001=(1.5±0.1)×10−3, respectively (not
shown). For CFA, we obtained a damping value of α001=3×
10−4with an upper bound of α001<8×10−4and/Delta1H0=
100 Oe. These fit parameters are also contained in Table I.
The source of the large inhomogeneous broadening for theCFA film is unclear: AFM measurements [Fig. 1(d)] along
FIG. 2. Linewidths as a function of frequency with the field
applied perpendicular to plane, for which two-magnon scattering is
inactive. The black squares are data for the CMS film, the red circlesare for the CMA film, and the blue triangles are for the CFA film.
In addition, linewidths are shown for a CFA film that was annealed
at 500
◦Cex situ (magenta diamonds). Corresponding linear fits are
shown along with the extracted Gilbert damping factor α. The blue
dashed lines indicate an upper bound of α001=8×10−4and a lower
bound of α001=0f o rC F A .with XRD indicate that the film is both crystalline and smooth.
Note that the range of frequencies shown in Fig. 2are largely
governed by considerations involving the Kittel equation [ 20]:
measurements below 10 GHz were not used due to the increas-ing influence of slight misalignment on /Delta1H(through field
dragging) for resonant fields just above the saturation value. Apiece of the CFA sample was annealed at 500
◦Cex situ , which
reduced the inhomogeneous broadening to ∼45 Oe (still a
relatively large value) and increased the Gilbert dampingtoα
001=1.1×10−3(similar behavior in CFA was seen in
Ref. [ 21]). The constraint of α001<8×10−4is among the
lowest of reported Gilbert damping constants for metallicferromagnets, but the α∼10
−4range is not unexpected based
on Kamberský model calculations performed for similar full-Heusler compounds [ 9] or other recent experimental reports
[22,23]. It should be noted that Schoen et al. [7] have recently
reported α=5×10
−4for Co 25Fe75thin films, where spin
pumping and radiative damping contributions were subtractedfrom the raw measurement. Spin pumping contributions tothe intrinsic damping are not significant in our films, as noheavy-metal seed layers have been used and the films havethicknesses of 10 nm or greater. For the radiative dampingcontribution [ 13] in the geometry of our CPW and sample, we
calculate a contribution of α
rad/lessorsimilar1×10−4, which is below
the uncertainty in our damping fit parameter.
B. In-plane linewidths
With the intrinsic damping and inhomogeneous broadening
characterized by the PP measurement, we turn our attention tothe IP linewidth measurements, for which TMS contributionsare present. For hard-axis measurements, frequencies /lessorsimilar5 GHz
were not used due to the influence of slight magnetic fieldmisalignment on the linewidths. For easy-axis measurements,the lower limit is determined by the zero-field FMR frequency.Figure 3shows the dependences of the resonance fields and
linewidths on the angle of the in-plane field. An importantobservation seen in Fig. 3is that the linewidth extrema are
commensurate with those of the resonance fields and thereforethe magnetocrystalline anisotropy energy. This rules out field-dragging and mosaicity contributions to the linewidth, whichcan occur when the resonance field depends strongly on angle[24]. We note that similar IP angular dependence of the FMR
linewidth, which was attributed to an anisotropic TMS mech-anism caused by a rectangular array of misfit dislocations, hasbeen reported by Kurebayashi et al. [25] and Woltersdorf and
Heinrich [ 14] for epitaxial Fe /GaAs(001) ultrathin films.
134430-3W. K. PERIA et al. PHYSICAL REVIEW B 101, 134430 (2020)
FIG. 3. Azimuthal angular dependence of the linewidths (left
ordinate, blue circles) and resonance fields (right ordinate, black
squares) for (a) CMS, (b) CMA, and (c) CFA. The excitation fre-quency was 20 GHz for CMS, 15 GHz for CMA, and 20 GHz for
CFA. The solid lines are sinusoidal fits.
To further study the anisotropy of the IP /Delta1Hin our
films, we have measured /Delta1Hat the angles corresponding
to the extrema of HFMR (and/Delta1H)i nF i g . 3over a range
of frequencies. These data are shown in Fig. 4, along with
the PP ([001]) measurements for each sample. A distinguish-ing feature of the data shown in Fig. 4is the significant
deviation between IP and PP linewidths in all but one case(CMS/angbracketleft100/angbracketright). Large and nonlinear frequency dependence of
TABLE II. Summary of the fitting parameters used to fit the in-
plane data of Fig. 4(black squares and red circles) to Eqs. ( 1)a n d
(3). CFA refers to the unannealed Co 2FeAl sample.
Sample (field direction) α(×10−3) ξ(nm) H/prime(Oe)
CMS/angbracketleft110/angbracketright 1.6±0.24 0 ±25 55 ±30
CMS/angbracketleft100/angbracketright 1.5±0.14 0 ±25 30 ±15
CMA/angbracketleft110/angbracketright 3.1±0.27 0 ±20 30 ±5
CMA/angbracketleft100/angbracketright 4.7±0.45 5 ±10 90 ±5
CFA/angbracketleft110/angbracketright 2.0±0.32 0 ±10 175 ±60
CFA/angbracketleft100/angbracketright N/AN /AN /AFIG. 4. Linewidths along all three principal directions for CMS
(a), CMA (b), and CFA (c). Heusler crystalline axes are labeled by/angbracketleft100/angbracketright(black), /angbracketleft110/angbracketright(red), and [001] (blue). In all three cases, /angbracketleft110/angbracketright
is the in-plane easy axis and /angbracketleft100/angbracketrightis the in-plane hard axis. The
corresponding fits are shown as the solid curves, where the in-planelinewidths are fit using Eq. ( 3) and the out-of-plane linewidths are
fit to the Gilbert damping model. The fit parameters are given in
Table II.
the IP linewidths is strongly suggestive of an active TMS
linewidth broadening mechanism. In the presence of TMS,careful analysis is required to separate the Gilbert dampingfrom the TMS linewidth contributions. We therefore describethe TMS mechanism in more detail in the following sectionin order to analyze the IP linewidths in Fig. 4and extract the
Gilbert damping.
C. Two-magnon scattering model
The TMS mechanism leads to a characteristic nonlinear
frequency dependence of /Delta1H[11,12]. In Fig. 4,t h eI P
/Delta1His not a linear function of frequency, but possesses the
“knee” behavior characteristic of the frequency dependenceof linewidths dominated by the TMS mechanism. We havefit our data to the TMS model described by McMichaeland Krivosik [ 12], in which the TMS linewidth /Delta1H
TMS is
134430-4INTERPLAY OF LARGE TWO-MAGNON FERROMAGNETIC … PHYSICAL REVIEW B 101, 134430 (2020)
given by [ 26,27]
/Delta1HTMS=γ2ξ2H/prime2
df/dH|fFMR/integraldisplay
/Gamma10qCq(ξ)δα(ω−ωq)d2q,(3)
where /Gamma10qis the defect-mediated interaction term between
magnons at wave vector 0 and q,Cq(ξ)=[1+(qξ)2]−3/2is
the correlation function of the magnetic system with correla-tion length ξ, and H
/primeis the magnitude of the characteristic
inhomogeneity (units of magnetic field). The δαfunction in
Eq. ( 3) selects only the magnon scattering channels that con-
serve energy. In the limit of zero intrinsic damping, it is iden-tical to the Dirac delta function, but for finite αit is replaced
by a Lorentzian function of width δω=(2αω/γ )dω/dH.
The magnon dispersion relation determining ω
qis the usual
Damon-Eshbach thin film result [ 26,28] with the addition of
magnetocrystalline anisotropy stiffness field terms extractedfrom the dependence of the resonance field on the appliedfrequency for the IP configuration. The film thickness d
affects the states available for two-magnon scattering throughthe dispersion relation, namely, the linear term which givesrise to negative group velocity for small q(∝−qd). The IP
FMR linewidth data shown in Fig. 4were fit to Eq. ( 1)
[with Eq. ( 3)u s e dt oe v a l u a t e /Delta1H
TMS] with ξ,α, and H/primeas
fitting parameters (shown in Table II). The correlation length
ξremains approximately constant for different in-plane direc-
tions, while the strength H/primeis larger for the /angbracketleft100/angbracketrightdirections
in the CMA and CFA samples and the /angbracketleft110/angbracketrightdirections in
the CMS sample. Some degree of uncertainty results fromthis fitting procedure, because for linewidth data collectedover a limited frequency range, ξandαare not completely
decoupled as fitting parameters. In absolute terms, however,the largest systematic errors come from the exchange stiffness,which is not well known. The error bars given in Table II
were calculated by varying the exchange stiffness over therange 400 meV Å
2to 800 meV Å2, and recording the change
in the fit parameters. This range of values was chosen basedon previous Brillouin light scattering measurements of theexchange stiffness in similar Heusler compounds [ 29,30]. In
addition, we note that in Eq. ( 1)/Delta1H
0is taken to be isotropic,
with the value given by the PP linewidth measurements shownin Fig. 2. Although certain realizations of inhomogeneity
may result in an anisotropic /Delta1H
0(see Ref. [ 14] for a good
discussion), doing so here would only serve to create anadditional fitting parameter.
D. Effect of low intrinsic damping
The effect of low intrinsic damping on the two-magnon
linewidth can be seen in Fig. 5(a).A sαdecreases, with
all other parameters fixed, /Delta1HTMS steadily increases and
becomes increasingly nonlinear (and eventually nonmono-tonic) with frequency. In particular, a “knee” in the frequencydependence becomes more pronounced for low damping [see,e.g., Fig. 5(a) curve for α=10
−4]. The physics giving rise
to the knee behavior is illustrated in Fig. 5(b).T h eT M S
process scatters magnons from zero to nonzero wave vectorat small q. There is assumed to be sufficient disorder to allow
for the momentum qto be transferred to the magnon system.
There will always be, however, a length scale ξbelow which
the disorder decreases, so that the film becomes effectivelyFIG. 5. (a) Two-magnon scattering linewidth contribution for
values of Gilbert damping α=10−2,5×10−3,10−3,and 10−4.T h e
inset shows magnon dispersions for an applied field of H=1k O e .
(b) Contours of the degenerate mode wave number q2Min the film
plane as a function of wave vector angle relative to the magnetizationforf
FMR=16, 24, and 32 GHz. The dashed circle indicates the wave
number of a defect with size ξ=100 nm.
more uniform at large wave vectors. The corresponding FMR
frequencies are those for which the contours of constantfrequency (the figure eights in Fig. 5)i nqspace have extrema
atq∼ξ
−1. The TMS rate is also determined by the interplay
of the magnon density of states, the effective area in qspace
occupied by the modes that conserve energy, and the Gilbertdamping. The knee behavior is more pronounced for lowαdue to the increased weight of the van Hove singularity
coming from the tips of the figure eights, in the integrandof Eq. ( 3). Although a larger window of energies, set by the
width of δ
α, is available for larger α, this smears out the sin-
gularity in the magnon density of states, removing the sharpknee in the TMS linewidth as a function of frequency. ThePP measurement confirms that all of these epitaxial Heuslerfilms lie within the range α< 2×10
−3. Ferromagnetic films
with ultralow αare therefore increasingly prone to large
TMS linewidths (particularly for metals with large Ms). The
TMS linewidths will also constitute a larger fraction ofthe total linewidth due to a smaller contribution from the
134430-5W. K. PERIA et al. PHYSICAL REVIEW B 101, 134430 (2020)
Gilbert damping. In practice, this is why experimental re-
ports [ 7,22,23] of ultralow αhave almost all utilized the
PP geometry.
E. Discussion
The results of the IP linewidth fits to Eqs. ( 1) and ( 3)
are summarized in Table II. In the case of CMS, the high-
frequency slopes in Fig. 4(a) approach the same value along
each direction, as would be expected when the frequency islarge enough for the TMS wave vector to exceed the inverseof any defect correlation length. In this limit, αis isotropic
(within error limits).
Next, we discuss the CMA IP data shown in Fig. 4(b) and
Table II. It is clear from this figure that a good fit can be
obtained along both /angbracketleft100/angbracketrightand/angbracketleft110/angbracketrightdirections. In Table II
it can be seen that the value of the defect correlation length ξ
is approximately the same along both directions. However, thevalues of αwe obtain from fitting to Eqs. ( 1) and ( 3) do not
agree well with the PP value of α
001=1.8×10−3(Fig. 2).
Anisotropic values of αhave been both predicted [ 5,10] and
observed [ 31], and an anisotropic αis possibly the explanation
of our best-fit results. The in-plane /angbracketleft100/angbracketrightand [001] directions
are equivalent in the bulk, so the anisotropy would necessarilybe due to an interface anisotropy energy [ 31] or perhaps a
tetragonal distortion due to strain [ 32].
Finally, we discuss the CFA linewidths shown in Fig. 4(c)
and Table II. This sample has by far the largest two-magnon
scattering contribution, which is likely related to the anoma-lously large inhomogeneous broadening and low intrinsicdamping [see Fig. 5(a)] observed in the PP measurement. A
good fit of the data was obtained when the field was applied
along the /angbracketleft110/angbracketrightdirection. Notably, the IP /angbracketleft110/angbracketrightbest fit value
of 2.1×10
−3is nearly a factor of 3 larger than the α001upper
bound on the same sample (Table I), strongly suggesting an
anisotropic Gilbert α. A striking anisotropy in the IP linewidth
was revealed upon rotating the magnetization to the /angbracketleft100/angbracketright
orientation. For the /angbracketleft100/angbracketrightcase, which yielded the largest TMS
linewidths measured in this family of films, we were not able
to fit the data to Eq. ( 3) using a set of physically reason-
able input parameters. We believe that this is related to theconsideration that higher order terms in the inhomogeneousmagnetic energy (see Ref. [ 26]) need to be taken into account.
Another reason why this may be the case is that the model ofMcMichael and Krivosik [ 12] assumes the inhomogeneities to
be grainlike, whereas the samples are epitaxial [see Fig. 1(a)].
Atomic force microscopy images of these samples [Fig. 1(d)]
imply that grains, if they exist, are much larger than the defectcorrelation lengths listed in Table II, which are of order 10’s of
nm. We also note that there does not appear to be a correlationbetween the strength of two-magnon scattering H
/primeand the
cubic anisotropy field 2 K1/Ms, which would be expected for
grain-induced two-magnon scattering.
V . SUMMARY AND CONCLUSION
We conclude by discussing the successes and limitations of
the McMichael and Krivosik [ 12] model in analyzing our epi-
taxial Heusler film FMR linewidth data. We have shown thattwo-magnon scattering is the extrinsic linewidth-broadeningmechanism in our samples. Any model which takes this asits starting point will predict much of the qualitative behavior
we observe, such as the knee in the frequency dependenceand the large linewidths IP for low αfilms. The TMS model
used in this article (for the purpose of separating TMS andGilbert linewidth contributions) is, however, only as accu-rate as its representation of the inhomogeneous magneticfield and the underlying assumption for the functional formofC
q(ξ). Grainlike defects are assumed, which essentially
give a random magnetocrystalline anisotropy field. We didnot, however, explicitly observe grains in our samples withAFM, at least below length scales of ∼10μm [Fig. 1(d)].
Misfit dislocations, a much more likely candidate in ouropinion, would cause an effective inhomogeneous magneticfield which could have a more complicated spatial profileand therefore lead to anisotropic two-magnon scattering (seeRef. [ 14]). The perturbative nature of the model also brings
its own limitations, and we believe that the CFA /angbracketleft100/angbracketrightdata,
for which we cannot obtain a satisfactory fit, are exemplaryof a breakdown in the model for strong TMS. Future workshould go into methods of treating the two-magnon scatteringdifferently based on the type of crystalline defects present,which will in turn allow for a more reliable extraction of theGilbert damping αand facilitate the observation of anisotropic
Gilbert damping, enabling quantitative comparison to first-principles calculations.
Regardless of the limitations of the model, we emphasize
three critical observations drawn from the linewidth measure-ments presented in this article. First, in all cases we observelarge and anisotropic TMS linewidth contributions, whichimply inhomogeneity correlation length scales of order tensto hundreds of nanometers. The microscopic origin of theseinhomogeneities is the subject of ongoing work, but is likelycaused by arrays of misfit dislocations [ 14]. The relatively
large length scale of these defects may cause them to be easilyoverlooked in epitaxial film characterization techniques suchas XRD and cross-sectional HAADF-STEM, but they stillstrongly influence magnetization dynamics. These defects andtheir influence on the FMR linewidth through TMS compli-cate direct observation of Kamberský’s model for anisotropicand (in the case of Heusler compounds) ultralow intrinsicdamping in metallic ferromagnets. Second, we observed lowintrinsic damping through our PP measurement, which was<2×10
−3for all of our samples. Finally, we have presented
the mechanism by which FMR linewidths in ultralow dampingfilms are particularly likely to be enhanced by TMS, theanisotropy of which may dominate any underlying anisotropicKamberský damping.
ACKNOWLEDGMENTS
This work was supported by NSF under Grant No. DMR-
1708287 and by SMART, a center funded by nCORE, aSemiconductor Research Corporation program sponsored byNIST. The sample growth was supported by the DOE un-
der Grant No. DE-SC0014388 and the development of the
growth process by the Vannevar Bush Faculty Fellowship(ONR Grant No. N00014-15-1-2845). Parts of this work werecarried out in the Characterization Facility, University ofMinnesota, which receives partial support from NSF throughthe MRSEC program.
134430-6INTERPLAY OF LARGE TWO-MAGNON FERROMAGNETIC … PHYSICAL REVIEW B 101, 134430 (2020)
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PhysRevApplied.13.061002.pdf | PHYSICAL REVIEW APPLIED 13,061002 (2020)
Letter Editors’ Suggestion
Manipulation of Coupling and Magnon Transport in Magnetic Metal-Insulator
Hybrid Structures
Yabin Fan,1,*,‡P. Quarterman ,2,†,‡Joseph Finley,1Jiahao Han,1Pengxiang Zhang,1Justin T. Hou,1
Mark D. Stiles ,3Alexander J. Grutter,2and Luqiao Liu1
1Microsystems Technology Laboratories, Massachusetts Institute of Technology, Cambridge,
Massachusetts 02139, USA
2NIST Center for Neutron Research, National Institute of Standards and Technology, 100 Bureau Drive,
Gaithersburg, Maryland 20899, USA
3Physical Measurement Laboratory, National Institute of Standards and Technology, 100 Bureau Drive,
Gaithersburg, Maryland 20899, USA
(Received 9 March 2020; accepted 1 May 2020; published 15 June 2020)
Ferromagnetic metals and insulators are widely used for generation, control, and detection of magnon
spin signals. Most magnonic structures are based primarily on either magnetic insulators or ferromagneticmetals, while heterostructures integrating both of them are less explored. Here, by introducing a Pt/yttrium
iron garnet (YIG)/permalloy (Py) hybrid structure grown on a Si substrate, we study the magnetic cou-
pling and magnon transmission across the interface of the two magnetic layers. We find that within thisstructure, Py and YIG exhibit an antiferromagnetic coupling field as strong as 150 mT, as evidenced by
both magnetometry and polarized neutron reflectometry measurements. By controlling individual layer
thicknesses and external fields, we realize parallel and antiparallel magnetization configurations, whichare further utilized to control the magnon current transmission. We show that a magnon spin valve with
an on:off ratio of approximately 130% can be realized out of this multilayer structure at room temper-
ature through both spin pumping and spin-Seebeck-effect experiments. Owing to the efficient control ofmagnon current and the compatibility with Si technology, the Pt/YIG/Py hybrid structure could potentially
find applications in magnon-based logic and memory devices.
DOI: 10.1103/PhysRevApplied.13.061002
Heterostructures that integrate magnetic insulators and
ferromagnetic metals are drawing widespread attention
due to their rich magnonic physics. Specifically, stand-
ing spin waves (SSWs) and interlayer magnon-magnon
coupling have been detected in such hybrid structures [ 1–
3], with coupled layers of the magnetic insulator yttrium
iron garnet (YIG) and a soft ferromagnetic metal [such as
Co, (Co,Fe)B, and Ni]. In these structures, the dynamic
torques generated from interlayer exchange coupling can
lead to anticrossings between magnon modes unlocking
functionalities with critical implications both in the clas-
sical [ 4,5] and quantum domains [ 1–3,6]. In addition to
magnon-magnon coupling, the interlayer exchange inter-
action in YIG/ferromagnetic metal bilayers can enable
additional magnonic functions [ 7] such as the magnon
spin-valve effect [ 8,9]. In magnon spin valves, the trans-
mission coefficient of magnons propagating through the
heterostructure is tuned by the parallel and antiparallel
*yabin_fan@hotmail.com
†patrick.quarterman@nist.gov
‡These authors contributed equally to this work.orientations between the magnetization of two magneticlayers. One advantage of such a magnonic spin-valve
device is that information is encoded in the form of
magnons and a net charge current is not required in prin-
ciple, avoiding Joule-heating-related dissipation in con-
ventional spin-valve structures. In existing studies, YIG
layers epitaxially grown on Gd
3Ga5O12(GGG) substrate
are generally utilized. However, for practical device appli-
cations, spin-valve structures grown on silicon substrates
are preferred [ 10,11]. Stronger coupling between YIG and
ferromagnetic metals may provide easier customization of
the magnetization orientation in the magnon spin-valve
structures.
In this work, we demonstrate strong magnetic coupling
in the Si/Pt/YIG/permalloy (Py) multilayer structures. We
show that a pronounced antiferromagnetic coupling exists
between polycrystalline YIG and Py layers in the low-
field regime (defined as 0 to 50 mT), with the two layers
aligning along the same direction only when the external
field exceeds 150 mT. Moreover, through spin-pumping
and spin-Seebeck experiments, we demonstrate that this
YIG/Py hybrid structure could serve as an efficient magnon
spin valve. The YIG/Py hybrid structures grown on Si
2331-7019/20/13(6)/061002(6) 061002-1 © 2020 American Physical SocietyYABIN FAN et al. PHYS. REV. APPLIED 13,061002 (2020)
(a) (c)
(b)
FIG. 1. (a) Schematic of the Pt (10)/YIG(40)/Py(20)/Ru(3) hybrid structure grown on the Si/SiO 2substrate. (b) Atomic force
microscopy image of the YIG surface for the Si/Pt (10)/YIG(40)film, indicating a roughness of around 1 nm. (c) Vibrating sample
magnetometry measurements of the Si/Pt (10)/YIG(40)/Py(20)/Ru(3) sample and Si/Pt (10)/YIG(40)/MgO(3)/Py(20)/Ru(3) sample.
The inset shows results from the control samples of Si/Py (20)/Ru(3)and Si/Pt (10)/YIG(40). Schematics show the magnetization ori-
entation of the YIG and Py layers in the Si/Pt (10)/YIG(40)/Py(20)/Ru(3)hybrid structure in different magnetic field regions. M sis
integrated over the multilayer thickness.
represent a semiconductor industry-compatible technique
for implementing magnonic spin valves and thus have
broad application in ultralow-power magnonic devices and
circuits.
We first deposit Pt (10)/YIG(40)thin films (units in
nanometers) on Si/SiO 2substrates by magnetron sputter-
ing [12–15], followed by rapid thermal annealing (RTA) in
an oxygen environment. To characterize the film quality,
atomic force microscopy (AFM) measurements are per-
formed [Fig. 1(b)], which indicate a surface roughness of
approximately 1 nm. The polycrystalline nature of the YIG
layer is verified by x-ray diffraction (Fig. S1 within the
Supplemental Material) [ 16]. After annealing, a 20-nm Py
thin film is grown on top of the YIG layer, followed by a
3-nm Ru passivation layer [see Fig. 1(a)].
To characterize the magnetic properties of the hybrid
structure, we collect vibrating sample magnetometry
(VSM) data at room temperature with magnetic fields
applied within the sample plane. As shown in Fig. 1(c),
the M-H curve of the Pt/YIG/Py sample shows seg-
mented switching features. After the magnetization sharply
switches polarity near Bx=0 T, it does not immediately
reach the saturated magnetization state. Instead, it gradu-
ally increases, reaching saturation at around Bx=150 mT.
In order to understand this peculiar behavior, we measure
a set of control samples. For the control samples of
Py(20)and Pt (10)/YIG(40), the M-Hcurves exhibit typ-
ical easy-axis hysteresis loops with low coercive field and
square switching shape (the ratio of remanent over satu-
ration magnetization ,M r/M s≈1), as plotted in the inset
of Fig. 1(c). Comparing the magnetization of these threesamples, we find that in the low-field region, the net
magnetic moment Mtotalfrom the Pt/YIG/Py sample is
equal to the value of M(Py)- M(YIG), suggesting antifer-
romagnetic coupling between these two layers. When the
applied field is increased, the net moment Mtotalfrom the
hybrid structure gradually increases until it reaches the
sum of M(Py) and M(YIG) at approximately 150 mT,
where both the Py and YIG magnetizations align with
the field. To examine the detailed mechanisms of the
observed antiferromagnetic coupling, we grew a control
sample of Si/Pt (10)/YIG(40)/MgO(3)/Py(20), where the
MgO layer serves as a spacer to prevent direct exchange
coupling between the YIG and Py layers. In contrast to the
Pt/YIG/Py sample, the M-Hcurve of this control sample
shows full switching near Bx=0 T [Fig. 1(c)], which sug-
gests that exchange interaction rather than the dipolar field
is responsible for the observed coupling.
In order to directly measure the magnetization of
individual layers, we used polarized neutron reflectom-
etry (PNR) [ 17] to probe the depth dependence of
the composition and in-plane magnetization. Figure 2(a)
shows a typical set of PNR data obtained from the
Si/Pt(10)/YIG(40)/Py(20)sample under 4 mT of exter-
nal magnetic field (reached by first saturating to 700 mT
and then lowering the field). R++and R−−represent neu-
tron reflectivity for the non-spin-flip channels and Qis
the neutron-beam wave-vector transfer during the reflec-
tion. The solid lines represent theoretical reflectivity curves
generated from the scattering length density depth profiles
shown in Fig. 2(c). A series of data sets obtained under
fields from 700 to 1.5 mT are illustrated in Figs. S2
061002-2MANIPULATION OF COUPLING AND. . . PHYS. REV. APPLIED 13,061002 (2020)
(a)
(c)(b)
FIG. 2. (a) Polarized neutron reflectivity for the spin-polarized R++and R−−channels. Points represent experimental results and
solid lines are theoretical fits. Error bars indicate single standard deviation uncertainties. The results are obtained at room temperature
with a 4 mT in-plane field. (b) Spin asymmetry between the two channels for data shown in (a). (c) Structural (nuclear) and magnetic
scattering length density profiles for the multilayer structure under different in-plane field conditions.
and S3 within the Supplemental Material [ 16]. Figure
2(b) shows the calculated spin-asymmetry result, which is
defined as SA=(R++−R−−)/(R+++R−−) and highlights
the magnetic components of the reflectometry.
As described in the experimental methods section [ 16],
we obtain the scattering length density (SLD) profiles [Fig.
2(c)], which provide information on the orientation and
magnitude of in-plane magnetization as a function of depth
from the sample surface. Under high fields, YIG and Py
layers both align parallel to the applied field. Upon the
reduction of applied magnetic field, the Py magnetization
remains roughly unchanged while that from YIG decreases
significantly. When the field is lowered to 15 mT, the mag-
netization of the YIG layer aligns such that approximately
70% of its saturated magnetization ( M s) is antiparallel
to the magnetic field (and Py magnetization). The PNR
results, including the onset field for YIG magnetization
reversal as well as the relative magnitude of the magnetic
moment of the different layers during the switching, are in
good agreement with the M-Hcurve shown in Fig. 1(c).
We also use PNR to characterize the magnetization
switching process on the control sample of Si/Pt (10)/YIG(40)/MgO(3)/Py(20). Consistent with the VSM results,
with MgO insertion, the YIG and Py layers remain aligned
parallel to the applied magnetic field under both high-
and low-field regimes in this sample (Fig. S5 within
the Supplemental Material) [ 16], indicating the exchange
interaction as the coupling mechanism in Si/Pt/YIG/Py.
In addition to the Si/Pt (10)/YIG(40)/Py(20)sam-
ple, whose net magnetization is dominated by the
Py layer at low field, we also measure a sample of
Si/Pt(10)/YIG(40)/Py(2)/Ru(4), in which the magnetic
moment from YIG dominates. From both VSM and
PNR measurements, we observe that in contrast to the
Si/Pt(10)/YIG(40)/Py(20)sample, in this control sample
the YIG magnetization remains parallel to the external in-
plane field, while the Py magnetization aligns opposite to
the field direction in the low-field domain, as is shown in
Fig. S4 within the Supplemental Material. The full PNR
data with theoretical fits can be found in Sec. 4 within the
Supplemental Material [ 16].
Previously the magnon spin-valve effect has been real-
ized in magnetic multilayers. In these experiments, in order
to isolate the coupling between two ferromagnetic layers
061002-3YABIN FAN et al. PHYS. REV. APPLIED 13,061002 (2020)
and allow both parallel and antiparallel configurations, an
insertion layer made from an antiferromagnetic insulator or
a paramagnetic metal [ 8,9] has been employed. Because of
the intrinsic, antiferromagnetic coupling between the YIG
and the Py layers, their relative magnetic orientation can
be toggled between the two opposite states without the
need for a spacer layer. We perform both spin-pumping and
spin-Seebeck effect (SSE) measurements to study the mod-
ulation on magnon current transport in this hybrid structure
[Figs. 3(b) and3(d)].
As shown in Fig. 3(a), a spin-pumping device is fab-
ricated out of the Si/Pt (10)/YIG(40)/Py(20)/Ru(3)stack
with electrical contacts made only onto the Pt layer (see
Methods) [ 16]. The device is mounted onto a rf waveguide,and two dc electrodes are connected to the two sides of the
Pt layer to measure the magnon spin current injected into Pt
through inverse spin Hall effect (ISHE) [ 18–21]. As shown
in Fig. 3(b), spin-pumping signals are observed under the
driving rf frequencies between 3 and 9 GHz. By plot-
ting the relationship between rf frequency and resonance
field, we identify that the detected resonance signal corre-
sponds to the contribution from the Py layer. This is further
verified with separate ferromagnetic resonance measure-
ments, where no obvious resonance peaks are observed
from the YIG layer due to its polycrystalline nature (see
Sec. 7 within the Supplemental Material) [ 16]. Moreover,
a large dc resistance (up to 100 M /Omega1, see Fig. S6 within
the Supplemental Material) [ 16] is measured between the
(a) (b)
(c) (d)
FIG. 3. (a) Schematics of the Py spin-pumping process when the Py and the YIG magnetizations are in the antiparallel (upper
panel) and parallel (lower panel) configurations under the low-field and high-field regimes, respectively. (b) Spin-pumping voltages
measured from the ISHE in the Pt layer when the Py magnetization is excited to ferromagnetic resonance by external rf field in the
Si/Pt(10)/YIG(40)/Py(20)/Ru(3)hybrid structure. The spin-pumping voltages are normalized by the microwave power under different
frequencies. Inset: resonance field versus frequency. (c) Comparison of the field-dependent spin-pumping voltages measured in the
Si/Pt(10)/YIG(40)/Py(20)/Ru(3)structure and the control structure of Si/Pt (10)/Py(20)/Ru(3). (d) Spin-Seebeck voltages measured
in the Si/Pt (10)/YIG(40)/Py(20)/Ru(3)hybrid structure, when the top Py (20)/Ru(3)is in contact with a ceramic electrical heater
(maintained at 50 °C) and the bottom substrate is attached to a Peltier cooler (maintained at 25 °C). Spin-Seebeck data measured in a
Si/Pt(10)/YIG(40)control sample is also plotted.
061002-4MANIPULATION OF COUPLING AND. . . PHYS. REV. APPLIED 13,061002 (2020)
Py/Ru top layer and the Pt underlayer in our experiment,
suggesting that the thick YIG layer can completely iso-
late the direct electrical current flow from Py to Pt. This
allows us to exclude additional contributions from the rf
rectification effect within the Py layer [ 22–24]. Therefore,
the obtained signals can be directly attributed to the spin-
pumping mechanism without relying on detailed analysis
of the resonance lineshape [ 25].
We characterize the spin-pumping signal as a function of
the rf signal frequency (or equivalently, the resonance field
Bres). We note that under the lowest applied field (rf fre-
quency f=3 GHz), the spin-pumping voltage VSPremains
small. With the increase of f(from 3 to 9 GHz) and
Bres,VSPincreases from 15 to 34.2 nV/mW. To understand
the evolution of VSP, we carry out a control experiment
on a simple Pt/Py bilayer film. As is illustrated in Fig.
3(c), a different trend has been observed in the Pt/Py sam-
ple, where VSPdecreases with the increase of resonance
frequency. This latter trend is also consistent with previ-
ous reports [ 26–28] in similar spin-pumping experiments,
which can be explained by the reduction of precession
cone angle under a higher driven frequency (or equiv-
alently, a larger external magnetic field). The observed
monotonic increase of VSPas a function of frequency
in Si/Pt/YIG/Py hybrid structure is consistent with the
magnon spin-valve mechanism as schematically illustrated
in Fig. 3(a), where the antiparallel configuration between
the two magnetic layers blocks part of the magnon spin
transport by lowering the spin transmission coefficient at
the interface.
In addition to the spin-pumping experiment, we carry
out spin-Seebeck-effect measurements in which a tem-
perature gradient of 25 K is created along the vertical
direction in the Si/Pt/YIG/Py structure. As plotted in Fig.
3(d), the spin-Seebeck voltage VSSEdetected in the Pt layer
increases monotonically with the in-plane magnetic field
from 0 to 0.1 T, consistent with the scenario that the par-
allel configuration between Py and YIG magnetizations
allows more magnon transmission from Py through the
YIG layer than the antiparallel case. Importantly, we notice
that even in the low-field regime (from 0 to 50 mT), where
Py and YIG are mostly antiparallel, the VSSEin Pt/YIG/Py
is greater than the VSSEmeasured in a Pt/YIG control sam-
ple, suggesting that magnons generated from the Py layer
dominate.
The measured antiferromagnetic coupling between Py
and YIG corresponds to an interfacial exchange energy of
approximately 8.6 ×10−4J/m2, which is orders of mag-
nitude stronger than the value reported in single-crystal
YIG/Py hybrid structure [ 29]. The strong intrinsic antifer-
romagnetic coupling between Py and YIG layers in ourstructure directly facilitates the realization of magnonic
spin-valve effect. The elimination of extra spacer lay-
ers avoids additional spin scattering during magnon con-
versions, which not only enhances the efficiency butalso removes the constraints set by the spacer layer,
such as antiferromagnetic Néel transition temperature
[30–32]. In our spin-pumping experiment, the magnonic
spin-valve effect can be evaluated as (V↑↑
SP−V↑↓
SP)/V↑↓
SP=
130%, which is comparable to the value measured in the
YIG/CoO/Co structure reported previously [ 9], except that
our measurement is carried out at room temperature while
previous results are obtained under 160 K. In our experi-
ment, the magnon spin valve switches under high and low
magnetic field. Further nanoscale fabrication can intro-
duce shape anisotropy into the magnetic layers, which will
allow the realization of bistability between the parallel
and antiparallel states and work as a nonvolatile switch.
The fact that the magnonic spin valve operates efficiently
at room temperature and it can be integrated with other
Si-based electronics suggests that this material system
can provide a nice platform for realizing magnon-based
spin logic and memory devices. Additional references
cited within the Supplemental Material are included here
[33–35].
Acknowledgments. We thank Julie Borchers for invalu-
able discussions. This work is supported in part by the
National Science Foundation under Grant No. ECCS-
1808826 and by SMART, one of seven centers of
nCORE, a Semiconductor Research Corporation program,sponsored by National Institute of Standards and Tech-
nology (NIST). The authors also acknowledge sup-
port from AFOSR under award FA9550-19-1-0048. P.Q.
acknowledges support from the National Research Coun-
cil Research Associateship Program. Research performed
in part at the NIST Center for Nanoscale Science and
Technology.
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061002-6 |
PhysRevB.101.214432.pdf | PHYSICAL REVIEW B 101, 214432 (2020)
Enhanced skyrmion motion via strip domain wall
Xiangjun Xing ,1,*Johan Åkerman,2,3and Yan Zhou4,†
1School of Physics & Optoelectronic Engineering, Guangdong University of Technology, Guangzhou 510006, China
2Department of Physics, University of Gothenburg, Fysikgränd 3, 412 96 Gothenburg, Sweden
3Material & Nano Physics, School of ICT, KTH Royal Institute of Technology, 164 40 Kista, Sweden
4School of Science & Engineering, The Chinese University of Hong Kong, Shenzhen, Guangdong 518172, China
(Received 13 March 2020; revised manuscript received 23 May 2020; accepted 28 May 2020;
published 19 June 2020)
When magnetic skyrmions move under spin-orbit torque in magnetic nanowires, they experience a skyrmion
Hall effect, which pushes them towards the nanowire edge where they risk being annihilated; this puts an upperlimit on how fast they can be driven. However, the same magnetic multilayer harboring skyrmions can sustaina Néel-type strip domain wall along the nanowire length, potentially keeping the skyrmions separated fromthe edge. Here we study the interplay between current driven skyrmions and domain walls and find that theyincrease the annihilation current and allow the skyrmions to move faster. Based on the Thiele formalism, weconfirm that the emergent longitudinal repulsive force and the modified energy landscape linked to the domainwall are responsible for the enhanced skyrmion motion. Furthermore, we identify that the longitudinal repulsiveforce emerges because of the broken axisymmetry in the local magnetization in front of the skyrmion. Our studyuncovers key aspects in the interplay between two topological magnetic textures from different homotopy groupsand may inspire new device concepts.
DOI: 10.1103/PhysRevB.101.214432
I. INTRODUCTION
Magnetic skyrmions are localized topological solitons that
have a spin structure with integer topological charge [ 1–3].
Apart from the topological stability and accessible very smallsize, skyrmions exhibit emergent electrodynamics [ 4–11]. As
such, magnetic skyrmions have attracted intense researchactivities in the past few years in the hope to bring novel spin-based data storage and information processing applicationsto market. Flowing magnetic skyrmions tend to deflect theirtrajectories from the current direction, experiencing what iscalled a skyrmion Hall effect, owing to a transverse Mag-nus force associated with the nonzero topological charge[12–14]. Accordingly, in confined magnetic nanostructures,
e.g., nanowires, magnetic skyrmions usually move steadilyalong one of the two long edges, where the confining force andthe Magnus force are balanced at moderate current densities[10,12,15]. However, once the current density surpasses a
critical value, the skyrmions will touch the sample boundaryand be annihilated [ 16–18].
Apart from Néel skyrmions [ 12,13,19–23], chiral Néel
domain walls [ 24,25] can stably exist in magnetic multi-
layer nanowires with interfacial Dzyaloshinskii-Moriya inter-action (iDMI) [ 26–28] and perpendicular magnetic anisotropy
(PMA). Previous studies revealed that Slonczewski-type spin-transfer torque could drive the motion of Néel-type skyrmionsand domain walls very efficiently [ 10,21,24,25,29,30]. A re-
cent study [ 31] demonstrated that a Néel-type strip domain
*xjxing@gdut.edu.cn
†zhouyan@cuhk.edu.cnwall aligned along the nanowire length can be stabilized by
the Slonczewski-type spin torque if the current used is notexcessively large. Elongated strip domain walls in magneticnanowires have proven robust magnonic waveguides that en-hance spin-wave transmission [ 32]. A method of controllably
writing strip domain walls into magnetic nanowires has alsobeen established [ 31]. Using the strip domain wall as a buffer
layer, it appears possible to improve the dynamic behavior ofmagnetic skyrmions subject to Slonczewski-type spin torque.
In this work, we use micromagnetic simulations alongside
theoretical modeling to the current-driven motion of magneticskyrmions in a magnetic multilayer nanowire containing astrip domain wall (mediated skyrmions). For comparison, themotion of magnetic skyrmions in the same nanowire withoutincluding strip domain wall (bare skyrmions) is also consid-ered. To ensure the general validity of our results, we examinea wide range of values of those material parameters that aresensitive to the multilayer interfacial condition [ 19,20,33].
Throughout the considered range of material parameters,we find that the skyrmion motion under Slonczewski spintorque is enhanced by the domain wall and the accompanyingskyrmion Hall effect is suppressed. By virtue of the Thieleapproach [ 12,20,34], we clarify the mechanism behind the
observed behaviors. Our study opens a paradigm for theinterplay and manipulation of different topological magnetictextures.
II. RESULTS
A. Device structure, model, and simulations
The platform of this study is magnetic nanowires pat-
terned from an ultrathin multilayer film, which has a
2469-9950/2020/101(21)/214432(11) 214432-1 ©2020 American Physical SocietyXIANGJUN XING, JOHAN ÅKERMAN, AND YAN ZHOU PHYSICAL REVIEW B 101, 214432 (2020)
HM1/FM/AO(HM2)-like structure to generate iDMI and
PMA, where FM is a ferromagnetic layer, HM1 and HM2represent heavy-metal layers with strong spin-orbit coupling,and AO stands for a metal oxide layer. Experimentally, thepossible combinations of materials could be Pt /Co/AlO
x
[22,23,33], Pt/CoFeB/MgO [ 13,21,24,35], Ta/CoFeB /TaO x
[7,12,36], Pt/Co/Ta [ 21], etc. Depending on the interfacial
environment, layer thickness, and specific combination ofmaterials, the interface-sensitive material parameters, i.e., theiDMI and PMA can vary over a large range. Practically, mag-netic skyrmions can be written into the multilayer nanowirethrough a local nanocontact spin valve or magnetic tunneljunction [ 37], and strip domain walls can be injected into
the multilayer nanowire from the wire terminals using anestablished approach [ 31]. Overall, the architecture of an op-
erational device is analogous to that in Ref. [ 31], but here we
only consider straight magnetic nanowires and concentrate onthe magnetic dynamics induced by Slonczewski spin torque.As usual, the Slonczewski spin torque is provided by a verticalspin current resulting from the spin Hall effect or a magnetictunnel junction [ 7,10,21,23–25,29,30,31,35,38].
We perform micromagnetic simulations to find the solution
to the formulated question by numerically integrating the ex-tended Landau-Lifshitz-Gilbert equation with a spin-transfertorque [ 10,29,30],
∂m/∂t=−γ(m×H
eff)+α(m×∂m/∂t)+T,(1)
where mis the unit vector of the magnetization Mnormal-
ized by its saturation value Msandtis the time; Heff=
−(1/μ0)δE/δMis the effective field in the FM layer with μ0
denoting the vacuum permeability and Eis the total energy
incorporating the contributions of magnetostatic, PMA, ex-change, iDMI, and Zeeman interaction terms; Trepresents the
Slonczewski spin torque [ 39];γis the gyromagnetic ratio and
αis the Gilbert damping constant. For simplicity, we do not
take into account the out-of-plane fieldlike torque. Also, theZhang-Li torques were not included in our model since theyare negligible even for the current-in-plane geometry [ 31].
The finite-difference code MuMax3 [ 40] was used to im-
plement all the numerical calculations, in which only the FMlayer is explicitly addressed. We do not directly incorporatethe HM and AO layers in our simulations, but instead takeaccount of the physical effects arising from them. In a realdevice, the HM1 layer is responsible for the generation ofspin currents in the FM layer via spin Hall effect and forthe creation of iDMI together with the AO or HM2 layer viaforming asymmetric interfaces. The thickness of the FM layer,d
FM, is set to be 1 nm. The width of the nanowire is 100 nm in
most cases and other values are also considered for specialpurposes. The nanowire length varies with the wire widthbut has a minimum of 1 μm. We examine the equilibrium
magnetic configurations and their current-induced dynamicsin a device with either or both of the skyrmion and stripdomain wall over a broad range of K
uand D. The pre-
sented results are based on the following material parametersunless otherwise specified: saturation magnetization M
s=
580 kA m−1, exchange stiffness A=15 pJ m−1, perpendic-
ular magnetic anisotropy Ku=0.7M Jm−3, iDMI strength
D=3.0m Jm−2, and Gilbert damping constant α=0.3.
These parameters are typical experimental values reportedfor the HM1/FM/AO(HM2) multilayer systems [ 7,12,13,21–
24,33,35,36]. For computation, the FM layer is divided into an
array of 1 ×1×1n m3cubic cells, which are much smaller
than the exchange length lex=/radicalBig
2A/μ0M2
S≈8.4n m ( t h e
maximum length beyond which the short-range exchange
interaction cannot keep all the magnetic moments parallel),and open boundary conditions are assumed.
In this study, we suppose that the Slonczewski spin
torque stems from spin Hall effect [ 38], so that T=
−γτ
H(m×σ×m), where τH=¯hJ/Phi1H/2eμ0MsdFMand
σ=ˆJ׈z is the spin current polarization direction with ¯ h
denoting the reduced Planck constant, Jis the electrical cur-
rent density, /Phi1His the spin Hall angle, eis the elementary
charge, ˆJ is the unit vector in the electrical current direction,
and ˆ z is the unit vector along the +zaxis. For dynamic
simulations, the spin Hall angle /Phi1His set to be 0.13 [ 35,38]
and the electric current in the nanowire is along −x.I nt h e
multilayer structure, we assume that the FM layer is on top ofthe HM1 layer. Then, the electrons’ spin orientation σ=ˆJ׈z
will orient along +y. For each pair of K
uandD, the dynamic
simulations are done for a series of current densities with aninterval of 0 .1×10
11Am−2.
B. Domain-wall dynamics
To control the skyrmion motion under spin-orbit torque,
the strip domain wall must be stable against the same torque.Therefore, first of all, we need identify the stability window ofstrip domain wall with respect to the driving electric currentby multiple sets of simulations. Our calculations indicate that,for all the ( K
u,D) combinations, the strip domain wall is
not affected if the current density does not exceed 4 .0×
1012Am−2, and otherwise it will collapse once a much larger
current is applied. The two different situations are illustratedin Fig. 1.
Figures 1(a)and1(g) display the initial static strip domain
wall, which serves as the starting point of the dynamic sim-ulations. In two separate simulations, the initial strip domainwall is supplied with lower and higher currents, respectively,and the subsequent temporal evolutions of the domain wallare recorded. The corresponding results are presented inFigs. 1(b)–1(f) and1(h)–1(l). Clearly, at the lower current,
the strip domain wall maintains its original profile, whereas atthe higher current, the original narrow domain wall expandsimmediately after the current action, and meanwhile, its leftend starts to divide into two branches. Rapidly, the stripdomain wall develops a stripy substructure and the divisionextends deep into the interior of the nanowire.
As depicted in Figs. 1(a) and1(g), for the applied current
I, the electrons’ spin orientation σin the FM layer and the
magnetization orientation min the domain wall are parallel
at the center of the domain wall, and thus the torque T∼
m×σ×mvanishes therein regardless of the strength of the
current density [ 31]. However, in the upper and lower mag-
netic domains, the magnetic moments are aligned along the z
axis and thereby the torque T∼m×σ×m=ˆz׈y׈z=
ˆy. When the current becomes considerably large, the torque
will overcome the PMA and make the out-of-plane magneticmoments near the domain wall rotate to the yaxis, leading
214432-2ENHANCED SKYRMION MOTION VIA STRIP DOMAIN … PHYSICAL REVIEW B 101, 214432 (2020)
FIG. 1. Domain-wall dynamics under various current densities. (a)–(f) J=4.0×1012Am−2and (g)–(l) J=7.0×1012Am−2. The time
elapsed from current action is indicated in each plot. The arrows in green, magenta, and yellow denote the electric current direction, the
spin polarization direction of electrons, and the magnetization distribution in the strip domain wall, respectively. Ku=0.7M Jm−3andD=
3.0m Jm−2.B e l o w J=4.0×1012Am−2, the application of a current has no effect on the strip domain wall, but when J>4.0×1012Am−2,
the strip domain wall becomes unstable because of the large-angle precession of the magnetization in the magnetic domains triggered by the
spin torque. The color scale is used throughout this paper.
to the substructure inside the strip domain wall. Of course,
once the current direction reverses, the strip domain wall willimmediately collapse even for a small current density, becauseat this time the electron spins in the FM layer and the magneticmoments in the domain walls are in opposite directions, asdemonstrated in Ref. [ 31].
The threshold value J
cd=4.0×1012Am−2is consider-
ably large with regard to the skyrmion motion, since at Jcd
no skyrmions can stay in the nanowire for any ( Ku,D). In
fact, the maximal current density, which allows a skyrmionto stably exist in the nanowire, is slightly smaller than 1 .0×
10
12Am−2. This fact ensures that the strip domain wall can
act as a tool for mediating the skyrmion dynamics.
It is worth noting that, according to an early paper [ 41],
the Walker solution of a domain wall under an external fieldis unstable: a domain wall could move very slowly under afield, which is hard to detect in a micromagnetic simulation.If the same thing happens for a strip domain wall under acurrent, there will be a time scale beyond which the stripdomain wall itself may disappear. However, as shown aboveand in our previous paper [ 31], the conventional Walker-
type domain-wall motion cannot happen in the present study.Therefore, the stability problem of a domain wall identifiedin Ref. [ 41] is safely avoided. In fact, the dynamics of a
magnetic domain wall depends critically on the matching ofdomain-wall configuration and spin-orbit torques, as revealedin Ref. [ 29].
C. Bare skyrmion dynamics
We check the current-induced skyrmion dynamics in the
nanowire. Here, the starting point is a single static skyrmion.We carry out a series of simulations for each ( K
u,D)t os e e
the skyrmion dynamics under various current densities. Ineach simulation, the magnetization distributions are recorded
as time sequences with a fixed temporal interval. These dataallow us to identify how the skyrmion velocity depends onthe current density, and at which current density the skyrmionis annihilated due to the skyrmion Hall effect. Two sets ofrepresentative results are shown in Fig. 2.
Figures 2(a) and 2(g) display the initial steady-state
skyrmion that situates near the left end of the nanowire. Atthe time t=0 ns, an electric current is sent to the nanowire
and then the skyrmion motion is initiated. Figures 2(b)–2(f)
depict the skyrmion dynamics for a lower subthreshold currentdensity, at which the skyrmion moves through the nanowireand stops in front of the right edge, whereas at a highersuprathreshold current density, the skyrmion’s topologicalstructure is destroyed when it contacts the sample bound-ary, as shown in Figs. 2(h)–2(l). Eventually, this skyrmion
is expelled from the nanowire. The dynamics of the bareskyrmion, demonstrated here, well agrees with what is knownin previous research [ 10,15,17,18,30]. Apparently, in both
cases, the skyrmion transverse displacement accompanies itslongitudinal drift motion along the nanowire.
For the subthreshold current densities, the confining force
from the sample boundary equilibrates with the Magnusforce imposed by the current, and thereafter the skyrmionmoves steadily along the nanowire. Nevertheless, for thesuprathreshold current densities, the confining force is notstrong enough to counteract the Magnus force, resulting in anet force that drives the skyrmion to move outward. Accordingto the Thiele equation, the longitudinal skyrmion velocityv
xand the Magnus force Fgsatisfy the relations vx∝Jand
Fg∝J, respectively [ 12,30]. In this context, the permitted
maximal Magnus force determines the critical current density,which in turn defines the maximum skyrmion longitudinalvelocity.
214432-3XIANGJUN XING, JOHAN ÅKERMAN, AND YAN ZHOU PHYSICAL REVIEW B 101, 214432 (2020)
FIG. 2. Skyrmion motion along a nanowire without including strip domain wall. Two situations are considered: one corresponds to small
current density and the other to big current density. (a)–(f) J=1.0×1011Am−2and (g)–(l) J=2.4×1011Am−2. The time elapsed from
current action is indicated in each plot. The arrows in green denote the electric current. Ku=0.7M Jm−3andD=3.0m Jm−2. At small current
densities, the skyrmion moves through the entire length of the nanowire and stops in the right terminal, whereas at big current densities, theskyrmion moves through only a short distance and then is expelled from the side edge of the nanowire.
D. Mediated skyrmion dynamics
To extend the upper theoretical limit of the skyrmion
velocity, one has to suppress or avoid the skyrmion trans-verse motion. To this end, several classes of strategies havebeen proposed that use specially designed potential barriers[18,42], modified effective spin torque [ 17,43], or topologi-
cally compensated hybrid skyrmions, e.g., magnetic bilayerskyrmions [ 16,22], antiferromagnetic skyrmions [ 44–47], and
skyrmionium [ 48], to suppress the skyrmion Hall effect.
These approaches can indeed give rise to increased skyrmionvelocities, however, their realization requires rare materials,complex structures, and/or delicate operation. Especially theadoption of antiferromagnetic skyrmions imposes a difficultyin the detection of information bits [ 22]. Therefore, other
alternative ideas should be exploited for the development offast spintronic devices. The skyrmion motion driven by theSlonczewski spin torque through the mediation of a stripdomain wall manifests intriguing features, which are com-peting for use in spintronic technology and offer a basis forcomprehending the dynamics of interacting magnetic textures.
Figures 3(a) and3(g) show the coexisting skyrmion and
strip domain wall in the steady state prepared for the dynamicstudy. In the following, two situations are considered: onecorresponds to the subthreshold current densities [Figs. 3(b)–
3(f)], and the other to the suprathreshold current densities
[Figs. 3(h)–3(l)]. In either case, the skyrmion moves forward
and simultaneously the strip domain wall maintains its majorstructure. Specifically, the skyrmion moves along the stripdomain wall and just locally distorts the domain-wall string.The whole process seems like a ball sliding along an elasticbelt. The strength of the applied current distinguishes twokinds of dynamic behaviors. For a subthreshold current den-sity, the skyrmion can safely pass through the nanowire withits size fixed, but for a suprathreshold current density, theskyrmion approaches the domain wall and contracts gradually,
vanishing when its radius shrinks to zero.
Whether the skyrmion can move steadily with a stable size
relies on if the confining force can cancel out the Magnusforce experienced by the skyrmion. For the Magnus force onthe mediated skyrmion, the relation F
g∝J[12,30] still holds,
and accordingly, the higher the applied current, the larger theMagnus force. In this way, a larger current density will lead toa shorter distance and a stronger repulsive force between theskyrmion and domain wall. In principle, the threshold currentdensity can be defined as the value at which the strip domainwall is maximally distorted by the skyrmion and meanwhilethe skyrmion reaches its minimal stable size, and additionallythe repulsive force is just able to offset the Magnus force.Once a bigger current is used, the Magnus force will con-tinue to increase but the repulsive force will not, producinga nonzero net force that destroys the skyrmion. At smallercurrent densities, the repulsive force can always offset theMagnus force with the skyrmion stabilized in the transversedirection, enabling the steady drift motion of the skyrmionalong the strip domain wall. In this respect, the strip domainwall serves to generate a confining force, playing the samerole as the sample boundary. However, there are some funda-mental differences between the strip domain wall and sampleboundary, which will be discussed in the following sections.
E. Skyrmion velocity versus current density
Now, we would like to describe the skyrmion motion quan-
titatively in terms of the skyrmion velocity versus current den-sity (Fig. 4). Without loss of generality, multiple sets of differ-
ent (K
u,D) were considered. Figure 4(a) shows the skyrmion
velocity as a function of the current density for all the con-sidered parameter combinations. For a direct comparison, the
214432-4ENHANCED SKYRMION MOTION VIA STRIP DOMAIN … PHYSICAL REVIEW B 101, 214432 (2020)
FIG. 3. Skyrmion motion along a nanowire including strip domain wall. Two situations are considered: one corresponds to small current
density and the other to big current density. Panels (a)–(f) J=1.0×1011Am−2and panels (g)–(l) J=4.8×1011Am−2. The time elapsed
from current action is indicated in each plot. The arrows in green, magenta, and yellow denote the electric current direction, the spin polarization
direction of electrons, and the magnetization distribution in the strip domain wall, respectively. Ku=0.7M Jm−3andD=3.0m Jm−2.A ts m a l l
current densities, the skyrmion steadily slides along the domain-wall string and eventually stops near the right terminal, whereas at big current
densities, the skyrmion gradually shrinks during sliding along the domain-wall string and finally vanishes when its radius reduces to zero.
data are divided into two groups: one group is for the mediated
skyrmion and the other for the bare skyrmion. Two strikingcharacteristics are visible from this figure: the curves for themediated skyrmion lie above those for the bare skyrmion andthe upper curves extend to the higher-current density region.To make it clear, we plot the curves for each ( K
u,D) in sepa-
rate panels [Figs. 4(b)–4(h)]. In each curve, the rightmost data
point corresponds to the skyrmion motion at the current den-sity just below the threshold value, above which the skyrmioncannot move steadily in the nanowire and will be annihilated.Then, the mentioned features of the curves reveal the follow-ing aspects: first, at an identical current density, the mediatedskyrmion has a higher velocity than the bare skyrmion, andsecond, the mediated skyrmion can withstand stronger cur-rents than the bare one. Consequently, the maximum velocityof the mediated skyrmion corresponding to the threshold cur-rent density is approximately twice that of the bare skyrmionat its own threshold current density irrespective of the ( K
u,D),
as shown in Figs. 4(b)–4(h) and separately in Fig. 4(i).
The simulation results in Figs. 1–4substantiate that the
strip domain wall can indeed act as a buffer layer to me-diate the skyrmion dynamics, and, furthermore, the medi-ated skyrmion moves faster and permits using much strongercurrents compared to the bare skyrmion. Nevertheless, thesenumerical results do not reflect what governs the observedbehaviors. Next, we resort to the Thiele force equation to gainsome insights.
F. A Thiele model of the skyrmion motion
Assuming that the skyrmion has a rigid structure and pro-
jecting the extended Landau-Lifshitz-Gilbert equation ontothe skyrmion translational mode, one obtains the generalizedThiele equation as follows [ 12,30]:
G×v−α↔
D·v+4πB↔
R·J+Fp=0, (2)
which describes the balance of the Magnus force Fg, dissipa-
tive force FD, driving force FST, and confining force Fpacting
on the skyrmion. In this work, we concentrate on the steady-state drift motion of a skyrmion along a nanowire, i.e., v=
(v
x,vy)=(vx,0).G=(0,0,−4πQ) is the gyromagnetic
coupling vector with the topological charge Q=(1/4π)∫m·
(∂xm×∂ym)dxdy ,
↔
D=/parenleftbigg
D 0
0D/parenrightbigg
is a dissipation tensor, Bquantifies the efficiency of the spin
texture of a skyrmion absorbing the Slonczewski spin torque,
and↔
R=(cos 0 sin 0
−sin 0 cos 0) is an in-plane rotation matrix. J=
(J,0) is along the nanowire. Generally, Fprepresents the
force due to the confining potential associated with certaintype of magnetic features such as boundaries, impurities, andmagnetic objects [ 10,12,15,21,23,31]; here we intentionally
assume that it incorporates two in-plane components, i.e.,F
p=(Fx,Fy). Then, substituting these quantities into the
vector equation ( 2), one finds
−αDvx+4πBJ+Fx=0,
−4πQvx+Fy=0. (3)
After some simple algebra, one gets
Fy=4πQ
αD(4πBJ+Fx),
vx=1
αD(4πBJ+Fx). (4)
For the steadily moving bare skyrmion, the confining force
due to the sample boundary is simply along the yaxis,
214432-5XIANGJUN XING, JOHAN ÅKERMAN, AND YAN ZHOU PHYSICAL REVIEW B 101, 214432 (2020)
FIG. 4. Skyrmion velocity vs current density. The solid and empty symbols correspond to skyrmion motion in magnetic nanowires with
and without including a strip domain wall, respectively. The lines across symbols are only guides to eyes. A series of ( Ku,D) are considered
and the plots are shown in (a)–(h), respectively. Panel (i) plots the critical skyrmion velocity against critical current density, where the skyrmio n
is annihilated.
pointing from the sample boundary to skyrmion, i.e., Fp=
(0,Fy)=[0,F⊥
p(bSK)]. Thus, for the bare skyrmion, one has
F⊥
p(bSK)=4πQ
αD4πBJ,
vx(bSK)=1
αD4πBJ. (5)
For the steadily moving mediated skyrmion, the confining
force no longer simply points to the yaxis as for the bare
skyrmion, and instead it has both xandycomponents, i.e.,
Fp=(Fx,Fy)=[F/bardbl
p(mSK),F⊥
p(mSK)]. Then, for the medi-
ated skyrmion, one sees
F⊥
p(mSK)=4πQ
αD[4πBJ+F/bardbl
p(mSK)],
vx(mSK)=1
αD[4πBJ+F/bardbl
p(mSK)]. (6)It is easily noticed that, for the same current density
J,vx(mSK)=vx(bSK)+1
αDF/bardbl
p(mSK). This result explains
one of the main numerical findings, namely, the mediatedskyrmion has bigger velocities than the bare one (Fig. 4).
For the steadily moving mediated skyrmion, the longitudi-
nal repulsive force originates from the asymmetric distortionin the strip domain wall [refer to Fig. 5(a)]. Such asymmet-
ric distortion destroys the axisymmetric local magnetizationdistribution with respect to y, enabling the emergence of an x
component in the repulsive force. However, for the steadilymoving bare skyrmion, the local magnetization distributionfrom the skyrmion to the sample boundary always keepsaxisymmetric relative to y, when the skyrmion approaches the
boundary, not allowing the existence of a net x-directed com-
ponent in the repulsive force. As a result, the repulsive forcearising from the boundary always orients along y[Fig. 5(b)].
The detailed mechanism for the formation of the asymmetric
214432-6ENHANCED SKYRMION MOTION VIA STRIP DOMAIN … PHYSICAL REVIEW B 101, 214432 (2020)
FIG. 5. Force balance on a steadily flowing skyrmion. (a) Skyrmion motion along the strip domain wall. (b) Skyrmion motion along the
sample boundary. Fg,FD,FST,a n d F⊥
prepresent the Magnus, dissipative, driving, and confining forces, respectively. Jis the current density
andVdis the skyrmion drift velocity, i.e., vx=Vd. In (a), an extra longitudinal repulsive force F/bardbl
pis exerted upon the skyrmion by the domain
wall. (c) Magnetization distribution between the mediated skyrmion and sample boundary. “SK border,” “DW center,” and “Boundary” denote
the skyrmion border, domain-wall center, and sample boundary, respectively. (d) Magnetization distribution between the bare skyrmion and
sample boundary. “SK border” and “Boundary” denote the skyrmion border and sample boundary, respectively.
domain-wall distortion and the creation of the longitudinal
repulsive force is clarified, as shown in the SupplementalMaterial, Fig. S1 [ 49].
Generally, the forces exerted on a skyrmion by the phys-
ical boundary can be introduced in a first approximation asF
⊥
p(bSK)=Fy=−k(y−y0)[10,50], where k>0 and y0
is the skyrmion equilibrium position along the yaxis, by
assuming a harmonic potential. For the forces imposed ona skyrmion by the strip domain wall, we assume that theabove approximation still holds. Then, it is easy to obtainF
⊥
p(mSK)=Fy=−β(η−η0), where β> 0 and η=ySK−
yDWrepresents the interval along the yaxis between the
skyrmion ( ySKdenotes the ycoordinate of the skyrmion cen-
ter) and the strip domain wall ( yDWsignifies the ycoordinate
of the bottom of the bent domain wall) after a certain currentis applied, and η
0=η|J=0represents the initial equilibrium
interval without the current application.
Equation ( 6) suggests that F⊥
p(mSK)−4πQ
αD[F/bardbl
p(mSK)]=
(4π)2QB
αDJ, from which it is reasonable to suppose that
F/bardbl
p(mSK) follows a similar relation, i.e.,
F/bardbl
p(mSK)=Fx=−ζ(η−η0), (7)
where ζ> 0. Now, letting /Delta1vx=vx(mSK)−vx(bSK), one
has/Delta1vx=1
αDF/bardbl
p(mSK). Considering that D=π2dSK
8λDW(where
dSKandλDWare the skyrmion diameter and domain-wall
thickness, respectively) [ 12], one finally obtains the following
formula:
/Delta1vx=−8ζλDW
απ2dSK(η−η0), (8)
where λDW=√A/Keffwith Keff=Ku−1
2μ0M2
scan be cal-
culated directly from the material parameters, and dSK,η, andη0can be derived from the simulation results. Leaving ζas
the free parameter, we fit the simulated velocity differencebetween the mediated and bare skyrmions (shown in Fig. 4)
using Eq. ( 8). The fitting results are presented in Fig. 6,
which contains five sets of data corresponding to variouscombinations of K
uandD. Overall, the agreement between
theory and simulations is good, considering that there existsonly one free parameter; this fact indicates that the assumptionof the form of the longitudinal force [i.e., Eq. ( 7)] is a very
good approximation.
From Eqs. ( 5) and ( 6), for the same current density J,
F
⊥
p(mSK)=F⊥
p(bSK)+4πQ
αDF/bardbl
p(mSK), suggesting that the
repulsive force imposed by the strip domain wall is strongerthan that exerted by the sample boundary. In fact, the confin-ing potential on the mediated skyrmion can be much largerthan the one on the bare skyrmion, which makes the mediatedskyrmion be able to withstand a much stronger Magnus force.The mechanisms are clarified from comparing the ways ofannihilation of the mediated and bare skyrmions. For the an-nihilation of the mediated skyrmion, there exist three optionalroutes: ( 1) The skyrmion could at first push a portion of the
strip domain wall out of the boundary and then leave the sam-ple from the boundary. In this case, because the strip domainwall is an extended entity, when even a piece of it approachesto the boundary, a large number of magnetic moments willjoin the strong local interaction magnetostatically causing avery strong repulsive force between the domain-wall centerand sample boundary [Fig. 5(c)]. Consequently, driving the
domain wall to touch the boundary must overcome a hugeenergy barrier linked to the strong repulsive force. ( 2)T h e
skyrmion may penetrate the strip domain wall and merge intothe magnetic domain. However, the extending character of thestrip domain wall together with the self-locking feature of the
214432-7XIANGJUN XING, JOHAN ÅKERMAN, AND YAN ZHOU PHYSICAL REVIEW B 101, 214432 (2020)
FIG. 6. Comparison of the simulation and theoretic results of /Delta1vx=vx(mSK)−vx(bSK) as function of current density. Different
combinations of KuandDare considered as indicated in each panel from (a) to (e). The simulation results of /Delta1vxare derived from the
data in Fig. 4. The parameters used for the fittings are summarized in the Supplemental Material, Tables S1–S5 [ 49].
spin configuration between the skyrmion border and domain-
wall center lead to a still high-energy barrier [Fig. 5(c)]. (3)
The skyrmion may shrink gradually by contracting its bor-der and vanish finally by absorbing a magnetic singularity[10,51]. Owing to the relatively small size of a skyrmion, the
energy barrier associated with its annihilation is the lowestamong the three situations. Therefore, a mediated skyrmion isalways seen to annihilate through route 3.
Nevertheless, only two possible pathways exist for the
annihilation of the bare skyrmion. ( 4)A si nr o u t e3f o rt h e
mediated skyrmion, the bare skyrmion could also be anni-hilated by shrinking its size and then absorbing a magneticsingularity. Here, however, the energy barrier is relativelyhigh owing to the topological protection of the skyrmion andthe requirement to inject a topological singularity [ 10,51].
(5) Alternatively, the bare skyrmion could be annihilated by
touching the boundary. In this case, unlocking of the spin con-figuration between the skyrmion border and sample boundarycan be simply launched by the reversal of those magneticmoments situating on the boundary [Fig. 5(d)], such that
the entire skyrmion is easily erasable; the associated energybarrier is small. Thus, a bare skyrmion tends to be annihilatedthrough route 5.
Obviously, the three annihilation routes for the mediated
skyrmion require overcoming larger energy barriers comparedwith the two annihilation routes for the bare skyrmion, deter-mining that the mediated skyrmions have higher annihilationcurrent densities than the bare ones and naturally can experi-ence stronger Magnus forces.
III. DISCUSSION
To check the stability of the mediated skyrmion motion,
we numerically study the process in longer magnetic multi-layer nanowires. The computational results indicate that themediated skyrmion can propagate steadily over a considerablylarge distance with the shape and size fixed, as shown inFig. S2 of the Supplemental Material [ 49]. We also con-
sider the current-induced dynamics of an array of mediatedskyrmions (Fig. S3 [ 49]) and found that the entire array
moves concertedly when the interval is adequately large orthe applied current is exceedingly low. Compared with thebare-skyrmion array, the smallest interval between two adja-cent mediated skyrmions, which permits orderly motion, islarger, because, for the mediated-skyrmion array, a skyrmionis readily affected by its neighbors through bending of thedomain wall. The results presented in this study do not rely on
special material parameters and are universally valid for theHM1/FM/AO(HM2)-like multilayer system. As an example,the mediated skyrmion motion for a different ( K
u,D)i sd i s -
played in Fig. S4 [ 49], where the entire process is essentially
t h es a m ea si nF i g . 3. A skyrmion, once driven to move,
will adjust itself to a moderate stable size before reaching thesteady-state motion; this is especially clear for a big skyrmiona ss h o w ni nF i g .S 4[ 49]. These manifested characteristics
of mediated skyrmions form the basic prerequisite for anyrealistic implementation of a device using them.
The extended Thiele equation including F
/bardbl
pprovides in-
sight into the numerical results, both qualitatively and quanti-tatively; it clearly demonstrates that the longitudinal repulsiveforce functions as an active driving force for the mediatedskyrmion. According to Refs. [ 50,52], an inertia term is
expected to enter the Thiele equation because of the edgeconfining potential. Since the strip domain wall also imposesa confining potential on the skyrmion as the physical borders,the effect of the mass term must have been involved in oursimulation results. Despite the absence of the inertia term inour theoretical model, the agreement between the theory andsimulations seems good overall, as demonstrated in Fig. 6.
Therefore, in our opinion, the influence of the mass term isnegligible in this scenario, and the model without consideringthe inertia has captured the key physics in the dynamics of themediated skyrmion.
The proposed use of mediated skyrmions can suppress
skyrmion Hall effect, namely, increasing the skyrmion mobil-ity and expanding the effective working range of the current,and eliminate the random scattering of edge roughness onskyrmion motion. Nevertheless, it cannot avoid the skyrmionHall effect, and thus there still exists a threshold current den-sity∼1.0×10
12Am−2, above which the mediated skyrmion
will be annihilated. Analogously, a threshold current densityalso exists in most of the previously suggested schemes[16,18,42,48]; when the employed current density becomes
exceedingly large, the skyrmions will be destructed by theuncompensated Magnus force. Actually, recent literature [ 44]
argued that the skyrmion Hall effect will still occur in thecase of spin-polarized currents even for the skyrmions inantiferromagnets. Comparatively, our proposed scheme hasremarkable advantages: First, it simply requires writing astrip domain wall into the original skyrmion device withoutincorporating the fabrication of complex hard structures and isthus naturally reconfigurable. Second, apart from skyrmionic
214432-8ENHANCED SKYRMION MOTION VIA STRIP DOMAIN … PHYSICAL REVIEW B 101, 214432 (2020)
devices, the hardware is also applicable to domain-wall race-
track devices [ 53] and magnonic waveguides [ 32], without
significant variation in the key parts, implying good repro-grammability.
Although the scattering on skyrmion motion by edge pin-
ning sites can be prevented by using strip domain wall, ourpreliminary numerical calculations suggest that the impactof pinning centers [ 7,12,21,23] in the interior region of the
nanowire is unavoidable, since the randomly distributed point-like impurities pin the strip domain wall locally and modifyits profile (see the Supplemental Material, Fig. S5 and MoviesS1–S3 [ 49]).
While the nanowire width is not crucial for the steady-state
motion of a mediated skyrmion, the distance between the stripdomain wall and sample boundary has a decisive role. Anincreased spacing will result in enhanced distortion of thestrip domain wall and change the relative strength of F
/bardbl
pand
F⊥
p. For instance, in wider samples with a strip domain wall
situating along the central axis, the steadily moving mediatedskyrmion acquires higher velocities [as shown in Fig. 4(c)],
because the heavier local bending of the strip domain wall,permitted by the bigger spacing between the domain walland sample edge, results in a larger longitudinal componentof the repulsive force. Fortunately, one can displace the stripdomain wall using, for example, a magnetic field to reach anappropriate position.
Different from that of bare skyrmions, the motion of me-
diated skyrmions under spin-orbit torque is unidirectional. Areversed direction of the applied current will at first causethe strip domain wall to deform randomly, and then thechaotic domain-wall dynamics destructs the skyrmion leadingto erroneous operation.
IV . CONCLUSION
In conclusion, we point out theoretically the possibility to
control current-induced skyrmion dynamics utilizing a stripdomain wall. Through micromagnetic simulations, we studythe dynamics of strip domain wall, bare skyrmion, and coex-isting skyrmion and strip domain wall under spin-orbit torqueover a wide range of interface-sensitive material parameters.The computational results attest our theoretical conjectureand suggest that the skyrmion mediated by strip domain wallbecomes faster and more stable, which is explained by thegeneralized Thiele equation with a two-component confin-ing force. A symmetry analysis reveals that the longitudi-nal component of the confining force originates from localasymmetric distortion of the strip domain wall. The designof skyrmionic devices might benefit from these discoveries.More importantly, the study implies that, overall, the Thieleequation is robust in describing the dynamics of magnetic soli-tons [ 10], and specifically, the skyrmion velocity and Magnus
force can be harnessed by a longitudinal force regardless ofits origin.
ACKNOWLEDGMENTS
X.J.X. acknowledges support from the National Natural
Science Foundation of China (Grant No. 11774069). Y .Z.acknowledges support by the President’s Fund of CUHKSZ,
the Longgang Key Laboratory of Applied Spintronics, theNational Natural Science Foundation of China (Grants No.11974298 and No. 61961136006), the Shenzhen Fundamen-tal Research Fund (Grant No. JCYJ20170410171958839),and the Shenzhen Peacock Group Program (Grant No.KQTD20180413181702403).
X.J.X. initiated and designed the study. Y .Z. coordinated
the project. All authors contributed to the analysis of theresults and wrote the manuscript.
APPENDIX A: MICROMAGNETIC SIMULATIONS
The public-domain micromagnetic codes MuMax3 [ 40]
are used to implement the micromagnetic simulations, inwhich the Landau-Lifshitz-Gilbert equation is numericallyintegrated, by means of the explicit Runge-Kutta methodwith an adaptive time step, to find the equilibrium magneticconfigurations and trace the dynamics of the aimed magneticconfigurations under the applied current.
For the simulations of equilibrium magnetic configura-
tions, the original Landau-Lifshitz-Gilbert equation is modi-fied by including the iDMI in the free energy E. The RK23
(the Bogacki-Shampine version of the Runge-Kutta method)solver is chosen. In each simulation, the solver keeps advanc-ing until the MaxErr, /epsilon1=max|τ
high−τlow|/Delta1t(where τhigh
andτloware the estimated high-order and low-order torques
and/Delta1tis the time step), decreases to 10−9. The initial spin
configuration is a numerically conjectured structure, in whicha 20-nm-wide bubblelike spin texture centered at a site 40 nmfar from the nanowire’s left edge and 1 /4 the wire width far
from the top edge is accompanied by a domain wall alignedalong the nanowire’s central axis.
For the simulations of current-induced dynamics, the con-
ventional LLG equation is extended by the Slonczewski spin-transfer torque. The RK45 (the Dormand-Prince version ofthe Runge-Kutta method) solver is adopted, and in eachsimulation, the solver stops advancing when the MaxErrreaches 10
−5. The equilibrium spin configurations obtained
from static simulations are used as the input for dynamicsimulations.
APPENDIX B: THEORETICAL MODEL
The Landau-Lifshitz-Gilbert equation is well established
as a general-purpose tool for describing the spin dynam-ics of continuous ferromagnetic systems. From this generalequation, the special-purpose Thiele equation can be derivedto describe the characteristic of the mediated skyrmion dy-namics. Here, to capture the main feature and for simplicity,we regard a skyrmion as a rigid soliton with zero mass,i.e., neglecting the skyrmion’s structural deformation duringthe motion and the skyrmion mass due to the confiningpotential. In our model, the strip domain wall existing ina nanowire does not manifest itself explicitly in the Thieleequation but enters implicitly into the confining force F
p, and
thereby the derivation of the Thiele equation follows that inRefs. [ 12,30].
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214432-11 |
PhysRevB.77.094434.pdf | Creep of current-driven domain-wall lines: Effects of intrinsic versus extrinsic pinning
R. A. Duine *and C. Morais Smith†
Institute for Theoretical Physics, Utrecht University, Leuvenlaan 4, 3584 CE Utrecht, The Netherlands
/H20849Received 4 February 2008; revised manuscript received 3 March 2008; published 27 March 2008 /H20850
We present a model for the current-driven motion of a magnetic domain-wall line, in which the dynamics of
the domain wall is equivalent to that of an overdamped vortex line in an anisotropic pinning potential. Thispotential has both extrinsic contributions due to, e.g., sample inhomogeneities, and an intrinsic contributiondue to magnetic anisotropy. We obtain results for the domain-wall velocity as a function of current for variousregimes of pinning. In particular, we find that the exponent characterizing the creep regime strongly depends onthe presence of a dissipative spin transfer torque. We discuss our results in the light of recent experiments oncurrent-driven domain-wall creep in ferromagnetic semiconductors and suggest further experiments to corrobo-rate our model.
DOI: 10.1103/PhysRevB.77.094434 PACS number /H20849s/H20850: 72.25.Pn, 72.15.Gd, 75.60.Ch, 85.75. /H11002d
I. INTRODUCTION
The driven motion of line defects through a disordered
potential landscape has attracted considerable attention, forexample, in the context of vortices in superconductors,
1wet-
ting phenomena,2crack fronts,3and domain walls in
ferromagnets.4,5The competition and interplay among the
elasticity of the line, the pinning forces due to the disorderpotential, and thermal fluctuations lead to a wealth of physi-cal phenomena. Topics discussed are, for example, the uni-versality class of the roughening of the line, the nature of thepinning-depinning transition at zero temperature,
6and the
slide, depinning, and creep regimes of motion of the line thatoccur for decreasing driving field.
1,7
The creep regime was experimentally observed with the
field-driven motion of domain walls in ferromagnets.4,5This
low-field regime is characterized by a nonlinear dependence
of the domain-wall drift velocity /H20855X˙/H20856on the external mag-
netic field Hext, which is given by
/H20855X˙/H20856/H11008exp/H20877−Ec
kBT/H20873Hc
Hext/H20874/H9262f/H20878, /H208491/H20850
where Ecis a characteristic energy scale and Hcis a critical
field. The thermal energy is denoted by kBTand the exponent
/H9262f=/H208492/H9256−1/H20850//H208492−/H9256/H20850is given in terms of the equilibrium wan-
dering exponent /H9256of the static line.1,4,7The phenomenologi-
cal creep formula /H20851Eq. /H208491/H20850/H20852, which is an Arrhenius law in
which the energy barrier diverges for a vanishing drivingfield, is “glassy.” The underlying assumption is that there is acharacteristic length scale that determines the displacementof the domain-wall line. The validity of Eq. /H208491/H20850was con-
firmed both numerically
8and with functional renormaliza-
tion group methods.9It turns out that Eq. /H208491/H20850is also valid in
situations where roughening plays no role. For example, forad-dimensional manifold driven through a periodic potential
ind+1 dimensions, we have
/H9262f=d−1 /H20849ford/H113502/H20850.1More-
over, in the regime where the line defect moves via variable-range hopping, we have that
/H9262f=1 /3 if the motion is in two
dimensions.1,10,11
In addition to magnetic-field-driven motion, a lot of re-
cent theoretical and experimental research was devoted tomanipulating domain walls with electric current
12–21via theso-called spin transfer torques.22–25Domain-wall motion
driven by a current is quite distinct from the field-drivencase. For example, it has been theoretically predicted that, incertain regimes of parameters, the domain wall is intrinsi-cally pinned at zero temperature, which means that thereexists a nonzero critical current even in the absence ofdisorder.
12In clean samples, the phenomenology of current-
driven domain-wall motion turns out to crucially depend onthe ratio of the dissipative spin transfer torque parameter
26/H9252
and the Gilbert damping constant /H9251G.13Although theoretical
predictions27–30indicate that, at least for model systems, this
ratio differs from 1, it turns out to be difficult to extract itsprecise value from experiments on current-driven domain-wall motion to a large extent because disorder and nonzero-temperature effects
21,31complicate theoretical calculations of
the domain-wall drift velocity for a given current. This is thefirst motivation for the work presented in this paper.
Previous work on current-driven domain-wall motion at
nonzero temperature focused on rigid -domain walls. Tatara
et al.
32found that ln /H20855X˙/H20856was proportional to the current den-
sity j. The discrepancy between this result and experiments21
that did not observe this exponential dependence of wall ve-
locity on current motivated the more systematic inclusion ofnonzero-temperature effects on rigid-domain-wall motion by
Duine et al. ,
31who found that ln /H20855X˙/H20856/H11008/H20881jin certain regimes.
Although the latter was an important step in qualitativelyunderstanding the experimental results of Yamanouchi et
al.,
21,33a detailed understanding of these experiments is still
lacking and this is the second motivation for this paper. Forcompleteness, we also mention the theoretical work by Mar-tinez et al.,
34,35who considered thermally assisted current-
driven rigid-domain-wall motion in the regime of large an-isotropy, where the chirality of the domain wall plays no roleand the pinning is essentially dominated by extrinsic effects.Furthermore, Ravelosona et al.
36observed the thermally as-
sisted domain-wall depinning, and Laufenberg et al.37deter-
mined the temperature dependence of the critical current fordepinning the domain wall.
In this paper, we present a model for a current-driven
elastic -domain-wall line transversely moving in one dimen-
sion in the presence of disorder and thermal fluctuations .A
crucial ingredient in the description of current-driven motionPHYSICAL REVIEW B 77, 094434 /H208492008 /H20850
1098-0121/2008/77 /H208499/H20850/094434 /H208496/H20850 ©2008 The American Physical Society 094434-1is the chirality of the domain wall, which acts like an extra
degree of freedom. This enables a reformulation of current-driven domain-wall motion as a superfluid vortex line trans-versely moving in an anisotropic potential in two dimensions
/H20849see Fig. 1/H20850, which we present in detail in Sec. II. By using
this physical picture, in Sec. III, we analyze the differentregimes of pinning within the framework of collective pin-ning theory.
1We present results on the velocity of the
domain-wall line as a function of current, both in the regimewhere intrinsic pinning due to magnetic anisotropy domi-nates and in the extrinsic-pinning-dominated regime. Finally,in Sec. IV , we discuss our theoretical results in relation torecent experiments on current-driven domain walls inGaMnAs.
33In our opinion, although these experiments re-
main not fully understood, we suggest that they may be ex-plained by assuming a specific form of the pinning potentialfor the domain-wall line. We propose further experimentsthat could corroborate this suggestion.
II. DOMAIN WALL AS A VORTEX LINE
The equation of motion for the magnetization direction /H9024
in the presence of a transport current jis, to the lowest order
in temporal and spatial derivatives, given by
/H20873/H11509
/H11509t+vs·/H11612/H20874/H9024−/H9024/H11003/H20849H+Hext+/H9257/H20850
=−/H9251G/H9024/H11003/H20873/H11509
/H11509t+/H9252
/H9251Gvs·/H11612/H20874/H9024. /H208492/H20850
The left-hand side of this equation contains the reactive26
spin transfer torque,38which is proportional to the velocity
vs=Pj//H20849e/H9267s/H20850. The latter velocity characterizes the efficiency
of spin transfer. Here, Pis the polarization of the current in
the ferromagnet, eis the carrier charge, and the spin densityis denoted by /H9267s/H110132/a3, with aas the lattice constant. The
other terms on the left-hand side of Eq. /H208492/H20850describe preces-
sion around the external field Hextand the effective field H
=−/H9254E/H20851/H9024/H20852//H20849/H6036/H9254/H9024/H20850, which is given by a functional derivative
of the energy functional E/H20851/H9024/H20852with respect to the magneti-
zation direction. The stochastic magnetic field /H9257incorporates
thermal fluctuations, and it has a zero mean and correlationsdetermined by the fluctuation-dissipation theorem,
39
/H20855/H9257/H9268/H20849x,t/H20850/H9257/H9268/H11032/H20849x/H11032,t/H11032/H20850/H20856=2/H9251GkBT
/H6036/H9254/H20849t−t/H11032/H20850a3/H9254/H20849x−x/H11032/H20850/H9254/H9268/H9268/H11032.
/H208493/H20850
It can be shown that this equation still holds in the presence
of current, at least to first order in the applied electric field30
that drives the transport current. The fluctuation-dissipationtheorem also ensures that in equilibrium the probability dis-tribution for the magnetization direction is given by theBoltzmann distribution P/H20851/H9024/H20852/H11008exp /H20853−E/H20851/H9024/H20852/k
BT/H20854. The right-
hand side of Eq. /H208492/H20850contains only dissipative terms. The
Gilbert damping term is proportional to the damping param-eter
/H9251G, and the dissipative26spin transfer torque is charac-
terized by the dimensionless parameter /H9252.13
We consider a ferromagnet with magnetization direction
/H9024=/H20849sin/H9258cos/H9278,sin/H9258sin/H9278,cos/H9258/H20850that depends only on the
xand zdirections. In addition, we take the current in the x
direction and the external magnetic field in the zdirection.
The size of the ferromagnetic film in the /H9251direction is de-
noted by L/H9251/H20849/H9251/H33528/H20853x,y,z/H20854/H20850and we assume that Ly/H11270Lz. The
latter assumption allows us to model the domain wall as aline. Furthermore, we take the ferromagnet to have an easy z
axis and a hard yaxis, with anisotropy constants Kand K
/H11036,
respectively. The spin stiffness is denoted by J. With these
assumptions, static domain walls have a width /H9261=/H20881J/Kand
are, for the simplest model, to be discussed in more detailbelow /H20851see Eq. /H2084910/H20850/H20852, described by the solutions
/H92580/H20849x/H20850
=cos−1/H20851tanh /H20849x//H9261/H20850/H20852and/H9278/H20849x/H20850=0. To arrive at a description of
the dynamics of the domain wall, we use two collective co-ordinates which may depend on the zcoordinate so that the
domain wall is modeled as a line. The collective coordinatesare the position of the wall X/H20849z,t/H20850and the chirality
/H92780/H20849z,t/H20850.
The latter determines the sense in which the magnetizationrotates upon going through the domain wall. The result ofRef. 31is straightforwardly generalized to the case of a
domain-wall line. This amounts to solving Eq. /H208492/H20850variation-
ally with the ansatz
/H9258dw/H20849x,t/H20850=/H92580/H20853/H20851x−X/H20849z,t/H20850/H20852//H9261/H20854and
/H9278dw/H20849x,t/H20850=/H92780/H20849z,t/H20850, which yields the equations of motion,
/H11509/H92780
/H11509t+/H9251G
/H9261/H11509X
/H11509t=−a3
2/H6036Ly/H9261/H9254V
/H9254X+/H9252vs
/H9261−Hext+/H9257X/H20849z,t/H20850,
1
/H9261/H11509X
/H11509t−/H9251G/H11509/H92780
/H11509t=a3
2/H6036Ly/H92612/H9254V
/H9254/H92780+vs
/H9261+/H9257/H9278/H20849z,t/H20850, /H208494/H20850
where the domain-wall energy,
V/H20851X,/H92780/H20852/H11013E/H20851/H9258dw,/H9278dw/H20852, /H208495/H20850
FIG. 1. /H20849Color online /H20850Mapping of current-driven domain-wall
dynamics to that of a vortex line. The position of the domain wallX/H20849z,t/H20850and its chirality
/H92780/H20849z,t/H20850become the position /H20849ux,uy/H20850of the
vortex via /H20849ux,uy/H20850/H11013/H20849 X//H9261,/H92780/H20850. The potential landscape for this vor-
tex is, in general, anisotropic. In particular, the tilting in the ux
direction is set by the external magnetic field and the dissipative
spin transfer torque. The tilting in the uydirection is determined by
the reactive spin transfer torque.R. A. DUINE AND C. MORAIS SMITH PHYSICAL REVIEW B 77, 094434 /H208492008 /H20850
094434-2and the stochastic forces are determined from
/H20855/H9257/H9278/H20849z,t/H20850/H9257/H9278/H20849z/H11032,t/H11032/H20850/H20856=/H20855/H9257X/H20849z,t/H20850/H9257X/H20849z/H11032,t/H11032/H20850/H20856
=/H20873/H9251GkBT
/H6036/H20874/H20873a3
/H92612Ly/H20874/H9254/H20873z−z/H11032
/H9261/H20874/H9254/H20849t−t/H11032/H20850.
/H208496/H20850
The above equations are derived using a variational methodfor stochastic differential equations based on their path-
integral formulation.31,40Their validity is confirmed a poste-
riori by noting that in equilibrium the probability distribution
function for the position and chirality of the domain wall isthe Boltzmann distribution. That is, the Fokker-Planck equa-tion for the probability distribution P/H20851X,
/H92780/H20852of the domain-
wall position and the chirality that follows from Eqs. /H208494/H20850and
/H208496/H20850is given by41
/H208491+/H9251G2/H208502/H6036Ly/H92612
a3/H11509P/H20851X,/H92780/H20852
/H11509t=/H20885dz/H9254
/H9254X/H20849z/H20850/H20873/H9251G/H9261/H9254V
/H9254X/H20849z/H20850−/H9254V
/H9254/H92780/H20849z/H20850/H20874P/H20851X,/H92780/H20852+/H20885dz
/H9261/H9254
/H9254/H92780/H20849z/H20850/H20873/H9261/H9254V
/H9254X/H20849z/H20850+/H9251G/H9254V
/H9254/H92780/H20849z/H20850/H20874P/H20851X,/H92780/H20852
+/H9251GkBT/H20885dz
/H9261/H20873/H92542
/H9254/H927802/H20849z/H20850+/H92612/H92542
/H9254X2/H20849z/H20850/H20874P/H20851X,/H92780/H20852. /H208497/H20850
Upon insertion of the Boltzmann distribution Peq/H20851X,/H92780/H20852
/H11008exp /H20853−V/H20851X,/H92780/H20852//H20849kBT/H20850/H20854into this equation, one straightfor-
wardly verifies that it is indeed a stationary solution.
By rewriting the equations of motion for the domain-wall
position and chirality in terms of the dimensionless coordi-nateu/H20849z,t/H20850/H11013/H20851 X/H20849z,t/H20850//H9261,
/H92780/H20849z,t/H20850/H20852, we find from Eq. /H208494/H20850that
the domain wall is described by
/H9280/H9251/H9251/H11032u˙/H9251/H11032/H20849z,t/H20850=−/H9251Gu˙/H9251/H20849z,t/H20850−/H9254V˜/H20851u/H20852
/H9254u/H9251/H20849z,t/H20850+/H9257/H9251/H20849z,t/H20850, /H208498/H20850
with/H9280/H9251/H9251/H11032as the two-dimensional Levi-Civita symbol. /H20849Sum-
mation over repeated indices /H9251,/H9251/H11032/H33528x,yis implied. Note
that/H9257/H9251=/H9257X,/H9278for/H9251=x,y./H20850The above equation of motion /H20851Eq.
/H208498/H20850/H20852corresponds to the overdamped limit of vortex-line dy-
namics in an anisotropic potential V˜/H20851u/H20852. The left-hand side of
Eq. /H208498/H20850corresponds to the Magnus force on the vortex. We
emphasize that a mass term is missing, which indicates thatwe are indeed dealing with the overdamped limit of vortexmotion. /H20849Note that the mass of the fictitious vortex is not
related to the Döring domain-wall mass
42that arises from
eliminating the chirality from the domain-wall description,which is valid provided the latter is small.
43As the dynamics
of the domain-wall chirality is essential for a current-drivendomain-wall motion, this latter approximation is not suffi-cient for our purposes. /H20850The right-hand side of the equation
of motion contains a damping term proportional to
/H9251Gand a
term representing thermal fluctuations. The force is deter-mined by the potential
V˜=a3V/H20851/H9261ux,uy/H20852
2/H6036Ly/H92612+/H20885dz
/H9261/H20875/H20873/H9252vs
/H9261−Hext/H20874ux+vs
/H9261uy/H20876./H208499/H20850
The tilting of this potential in the uxdirection is determined
by the parameter /H9252, the current vs, and the external field Hext.
The tilting in the uydirection is determined only by the cur-
rent. The model in Eqs. /H208498/H20850and /H208499/H20850, which is illustrated in
Fig. 1, is the central result of this paper. In the followingsection, we obtain the results from this model for the
domain-wall velocity in different regimes of pinning, spe-cializing to the case of a current-driven domain-wall motion/H20849H
ext=0/H20850.
III. DOMAIN-WALL CREEP
In this section, we obtain the results for the average drift
velocity of the domain wall as a function of applied current.First, we discuss the situation without disorder; hereafter, weincorporate the effects of disorder.
A. Intrinsic pinning
In this section, we make two assumptions that do not
necessarily imply each other from a microscopic point ofview. First, we consider a homogeneous system, i.e., a sys-tem without disorder potential V
pin=0. Second, we take /H9252
=0. As a result of these assumptions, the domain wall is
intrinsically pinned.12This comes about as follows. For the
magnetic nanowire model discussed in the previous section,the energy functional in the clean limit is given by
E/H20851/H9024/H20852=/H20885dx
a3/H20877J
2/H20851/H20849/H11612/H9258/H208502+ sin2/H9258/H20849/H11612/H9278/H208502/H20852
+K
2sin2/H9258+K/H11036
2sin2/H9258sin2/H9278/H20878. /H2084910/H20850
Upon insertion of the domain-wall ansatz into the above en-
ergy functional, we find that
V˜/H20851u/H20852=/H20885dz
/H9261/H20875J
2/H6036/H20873/H11509u
/H11509z/H208742
−K/H11036
4/H6036cos/H208492uy/H20850+vs
/H9261uy/H20876./H2084911/H20850
Because the above potential does not explicitly depend on z,
the domain wall remains straight at zero temperature, i.e.,
/H11509u//H11509z=0. By solving the equations of motion in Eq. /H208498/H20850for
the potential in Eq. /H2084911/H20850at zero temperature and for a straightCREEP OF CURRENT-DRIVEN DOMAIN-WALL LINES: … PHYSICAL REVIEW B 77, 094434 /H208492008 /H20850
094434-3domain wall, one finds that /H20855/H20841u˙/H20841/H20856/H11008/H20881vs2−/H20849/H9261K/H11036/2/H6036/H208502so that
the domain wall is pinned up to a critical current given by
jc=/H9261K/H11036e/H9267s/2/H6036P./H20849The brackets /H20855¯/H20856denote time and ther-
mal average. /H20850This intrinsic pinning is entirely due to the
anisotropy energy,12which is determined by K/H11036, and does
not occur for field-driven domain-wall motion or current-driven domain-wall motion with
/H9252/HS110050. Physically, it comes
about because, for the model of a domain wall that we con-sider here, the reactive spin transfer torque causes the mag-netization to rotate in the easy plane. This corresponds to aneffective field that points along the hard axis. Because theGilbert damping causes the magnetization to precess towardthe effective field, the current tilts the magnetization out ofthe easy plane. This leads to a cost in anisotropy energy,which stops the drift motion of the domain wall if the currentis too small. By solving the equations of motion for the po-tential in Eq. /H2084911/H20850at nonzero temperature in the limit of a
straight wall, one recovers the result of Ref. 31.
At nonzero temperature, the domain wall is, however, no
longer straight. Since only the chirality is important, ourmodel for current-driven domain-wall motion in Eq. /H2084911/H20850
then corresponds to the problem of a string in a tilted-washboard potential, which was studied before
44in different
contexts. At nonzero temperature, the string propagatesthrough the tilted-washboard potential by nucleating a kink-antikink pair in the zdirection of the domain-wall chirality
/H92780/H20849z,t/H20850. The kink and antikink are subsequently driven apart,
which results in the propagation of the string.
In the limit when the current is close to the critical 1, a
typical energy barrier is determined by the competition be-tween the elasticity of the string and the tilted potential.
1For
/H20849jc−j/H20850/jc/H112701, the cosine in the energy functional in Eq. /H2084911/H20850
may be expanded around one of its minima, which yields
V˜/H20851u/H20852=/H20885dz
/H9261/H20875J
2/H6036/H20873/H11509/H9254uy
/H11509z/H208742
+K/H11036
/H6036/H208811−/H20873j
jc/H208742
/H9254uy2+2vs
3/H9261/H9254uy3/H20876,
/H2084912/H20850
where we have omitted an irrelevant constant. In the above
expression, /H9254uydenotes the displacement from the minimum.
Note that we have dropped the dependence of the potentialonu
x, which is allowed because the potential is not tilted in
theuxdirection /H20849provided that /H9252=0/H20850.
The potential in Eq. /H2084912/H20850has a minimum for /H9254uymin
=0 /H20849by construction /H20850and a maximum for /H9254uymax
=−vsK/H11036/H208811−/H20849j/jc/H208502//H9261/H6036. The pinning potential energy barrier,
i.e., the pinning potential evaluated at the maximum, scalesas/H9004V/H11008/H208511−/H20849j/j
c/H208502/H208523/2. Consider now the situation that a seg-
ment of length Lof the string is displaced from the minimum
and pinned by the potential. The length Lis then determined
by the competition between the elastic energy /H11011J/H20849/H9254uymax/L/H208502,
which tends to keep the domain wall straight, and the pin-ning potential /H9004V. Equating these contributions yields the
following for the length L:
L/H11008/H208751−/H20873j
jc/H208742/H20876−1 /4
. /H2084913/H20850
The typical energy barrier that thermal fluctuations have to
overcome to propagate the domain wall is then given byevaluating Eq. /H2084912/H20850for a segment of this length. This yields
a typical energy barrier /H11008/H208511−/H20849j/jc/H208502/H208525/4. By putting these re-
sults together and assuming an Arrhenius law, we find thatthe domain-wall velocity is
ln/H20855/H20841u˙/H20841/H20856/H11008−1
kBTJLy
a3/H20881K/H11036
K/H208751−/H20873j
jc/H208742/H208765/4
/H2084914/H20850
for /H20849jc−j/H20850/jc/H112701.
In the regime of small currents j/H11270jc, the problem must be
treated in the so-called “thin-wall” approximation.45For the
case of a one-dimensional line, however, it turns out that thedependence of domain-wall velocity on current is qualita-tively similar to the rigid domain-wall situation.
B. Extrinsic pinning
We now add extrinsic pinning, i.e., a disorder potential
Vpinto the potential in Eq. /H2084911/H20850. Following Ref. 12,w ea s -
sume, in the first instance, that it only couples to the positionof the domain wall u
xand not to its chirality uy. This assump-
tion is made mainly to simplify the problem. By now con-sidering the general case that
/H9252/HS110050, we have
V˜/H20851u/H20852=/H20885dz
/H9261/H20875J
2/H6036/H20873/H11509u
/H11509z/H208742
−K/H11036
4/H6036cos 2 uy+Vpin/H20849ux,z/H20850
+/H9252vs
/H9261ux+vs
/H9261uy/H20876. /H2084915/H20850
We estimate a typical energy barrier using the collective pin-
ning theory.1,7Therefore, we assume that we are in the re-
gime where the pinning energy grows sublinearly with thelength of the wall, and that there exists a typical length scaleLat which domain-wall motion occurs.
1/H20849Note that we con-
sider Las dimensionless since the coordinate uis dimension-
less. /H20850The energy of a segment of this length that is displaced
is given by
E/H20849L/H20850=/H9280elux2
L+/H9252vs
/H9261Lux+vs
/H9261Luy. /H2084916/H20850
The first term is the elastic energy with /H9280el=J/2/H6036/H92612. The
second and third terms correspond to the dissipative and re-active spin transfer torques, respectively. Note that since thedissipative spin transfer torque acts like an external magneticfield, we are able to incorporate it in the above energy. Thepotential V
pin/H20849ux,z/H20850leads to a roughening in the uxdirection.
Following standard practice,1,4,7we assume a scaling law
ux/H20849L/H20850=ux0L/H9256, with /H9256as the equilibrium wandering exponent,
which is already mentioned in the Introduction, and ux0as a
constant. The displacement in the uydirection is not rough-
ened because we have assumed that Vpin/H20849ux,z/H20850does not de-
pend on uy, i.e., the domain-wall chirality. Rather, the dis-
placement in this direction is determined by the minima ofthe potential in Eq. /H2084911/H20850and we have u
y=uy0independent of
Lforj/H11270jc. Note that in this limit the elastic energy due to
displacement in the uydirection can also be neglected.1
Hence, we find thatR. A. DUINE AND C. MORAIS SMITH PHYSICAL REVIEW B 77, 094434 /H208492008 /H20850
094434-4E/H20849L/H20850=/H9280elux02L2/H9256−1+/H9252vs
/H9261ux0L/H9256+1+vs
/H9261Luy0. /H2084917/H20850
Minimizing this expression with respect to Lthen leads to a
typical energy barrier. By assuming an Arrhenius law,1,4,7we
find the following for the domain-wall velocity:
ln/H20855/H20841u˙/H20841/H20856/H11008−/H9280el
kBT/H20873jc
j/H20874/H9262c
. /H2084918/H20850
For/H9252=0, we have /H9262c=/H208492/H9256−1/H20850//H208492−2/H9256/H20850. For /H9252/HS110050, we find
/H9262c=/H208492/H9256−1/H20850//H208492−/H9256/H20850. In particular, for /H9256=2 /3, which is appli-
cable to domain walls in ferromagnetic metals,4we have
/H9262c=1 /2 for /H9252=0 and /H9262c=1 /4 for /H9252/HS110050. Since the dissipa-
tive spin transfer torque, which is proportional to /H9252, acts like
an external magnetic field on the domain wall /H20851see Eq. /H208498/H20850/H20852,
we recover the usual results for a field-driven domain-wallmotion
4from our model. This result is also understood from
the fact that an external magnetic field does not tilt thedomain-wall potential in the chirality direction, as opposedto a current, so that the domain-wall chirality plays no role ina field-driven domain-wall creep. We observe that if wewould take the potential for the chirality of the domain wallto be a disorder potential instead of the washboard potential,we would find that
/H9256=3 /5 and /H9262c=1 /7 for both /H9252=0 and
/H9252/HS110050. Finally, we note that Eq. /H208494/H20850, or equivalently Eq. /H208498/H20850,
contains a description of Walker breakdown46in the clean
zero-temperature limit and is also able to describe the tran-sition from the creep regime to the regime of precessionalfield-driven domain-wall motion, which was recentlyobserved.
47
IV. DISCUSSION AND CONCLUSIONS
In very recent experiments on domain walls in the ferro-
magnetic semiconductor GaMnAs, Yamanouchi et al.33ob-
served field-driven domain-wall creep with exponent /H9262f/H112291
and current-driven creep with /H9262c/H112291/3 over 5 orders of mag-
nitude of domain-wall velocities. The fact that these two ex-ponents are different could imply that
/H9252is extremely small
for this material. For /H9252=0 and the specific pinning potentialdiscussed in the previous section, it is, however, impossible
to find a single roughness exponent that yields both /H9262f=1
and/H9262c=1 /3./H20849Note that the theoretical arguments in Ref. 33
give/H9262f=1 and /H9262c=1 /2./H20850
Although it is extremely hard to determine the micro-
scopic features of the pinning potential, we emphasize that ifpinning is not provided mainly by pointlike defects /H20849as con-
sidered in this paper and argued by Yamanouchi et al.
33to be
the case in their experiments /H20850but consists of random ex-
tended defects, the creep exponents would dramatically
change. Indeed, the latter type of disorder, which could occurin samples if there are, e.g., steps in the height of the film,allows for a variable-range hopping regime for creep, inwhich the exponent
/H9262=1 /3 in the two-dimensional case.
Moreover, upon increasing the driving force, a crossover oc-curs in the so-called half-loop regime, where the exponent
/H9262=1.1,10An alternative explanation for the experimental re-
sults of Yamanouchi et al.33would be that /H9252/HS110050 so that the
behavior for field- and current-driven motion is similar. If thepinning potential is random and extended, it would be pos-sible that the current-driven experiment is probing thevariable-range hopping regime with
/H9262=1 /3, whereas the
field-driven case probes the half-loop regime with /H9262=1. This
scenario would also reconcile the results of Ref. 33with
previous ones,21which yielded a critical exponent of /H9262
/H112290.5, as the latter could be in a different regime of pinning.
In conclusion, further experiments are required to clarify thisissue. The conjecture of pinning by extended defects may beexperimentally verified by increasing the driving in thecurrent-driven case and checking if the exponent crossesover from
/H9262=1 /3t o/H9262=1, while remaining in the creep
regime. Finally, since the exponent /H9262=1 /3 strictly occurs for
variable-range hopping in two dimensions, we note that themapping presented in this paper is crucial in obtaining thisresult.
ACKNOWLEDGMENTS
It is a great pleasure to thank G. Blatter, J. Ieda, S.
Maekawa, and H. Ohno for useful remarks.
*duine@phys.uu.nl; http://www.phys.uu.nl/~duine
†c.demorais@phys.uu.nl; http://www.phys.uu.nl/~demorais
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094434-6 |
PhysRevB.95.144412.pdf | PHYSICAL REVIEW B 95, 144412 (2017)
Synchronization of spin torque nano-oscillators
James Turtle,1,*Pietro-Luciano Buono,2,†Antonio Palacios,1,‡Christine Dabrowski,2,§Visarath In,3,/bardbland Patrick Longhini3,¶
1Nonlinear Dynamical Systems Group, Department of Mathematics, San Diego State University, San Diego, California 92182, USA
2Faculty of Science, University of Ontario Institute of Technology, 2000 Simcoe Street North, Oshawa, Ontario, Canada L1H 7K4
3Space and Naval Warfare Systems Center Pacific, Code 71730, 53560 Hull Street, San Diego, California 92152-5001, USA
(Received 12 October 2016; revised manuscript received 17 March 2017; published 12 April 2017)
Synchronization of spin torque nano-oscillators (STNOs) has been a subject of extensive research as various
groups try to harness the collective power of STNOs to produce a strong enough microwave signal at thenanoscale. Achieving synchronization has proven to be, however, rather difficult for even small arrays while inlarger ones the task of synchronization has eluded theorists and experimentalists altogether. In this work we solvethe synchronization problem, analytically and computationally, for networks of STNOs connected in series. Theprocedure is valid for networks of arbitrary size and it is readily extendable to other network topologies. Theseresults should help guide future experiments and, eventually, lead to the design and fabrication of a nanoscalemicrowave signal generator.
DOI: 10.1103/PhysRevB.95.144412
I. INTRODUCTION
The synchronization phenomenon of spin torque nano-
oscillators (STNOs) has been the subject of extensive researchfor many years due to the potential of networks of STNOsto generate microwave signals at the nanoscale [ 1–3]. In the
last few years, Adler-type [ 4] injection locking has emerged as
the most promising method to achieve synchronization, eitherthrough an external microwave current [ 5–7] or through a
microwave magnetic field [ 8,9]. In particular, it was shown
recently that a record number of five nanocontact STNOs[10] can synchronize via spin-wave beams [ 11]. Non-Adlerian
approaches to synchronization of nanopillar STNOs havealso been considered. Georges et al. [12] found the critical
coupling strength and minimum number of STNOs for theonset of synchronization analytically by describing the STNOsas phase oscillators in the framework of Kuramoto [ 13]. Later,
Iacocca and Akerman [ 14] provided conditions for the onset
of phase instability that may be caused, surprisingly, by strongcoupling in identical STNOs. It is well known, however,that amplitude can affect synchronization, especially near theonset of a Hopf bifurcation [ 15]. In fact, in STNOs amplitude
and phase are intrinsically coupled by the dependence of theeffective field on the magnetization [ 16]. Thus, if the Hopf
bifurcation parameter is of the same scale as the couplingparameter then the amplitude is no longer negligible and theKuramoto model reduction is no longer valid. Furthermore,when the amplitude dynamics are not negligible and the naturaloscillation frequencies are not homogeneous, synchronizationmay be enhanced regardless of the topology of the network[17]. Consequently, a complete understanding of synchro-
nization of nanopillar-based STNOs, via non-Adlerian type,requires an analysis that incorporates the amplitude dynamics.
*jturtle@predsci.com
†Pietro-Luciano.Buono@uoit.ca
‡apalacios@mail.sdsu.edu
§christinedabrowski15@gmail.com
/bardblvisarath@spawar.navy.mil
¶patrick.longhini@navy.milIn 2005, back-to-back publications in Nature Letters (Kaka
[2], a collaboration between NIST and Hitachi GST and
Mancoff [ 18] from Freescale Semiconductor) showed that two
STNOs tend to phase lock when they are in close proximityof one another. The coupling in these cases resulted from spinwaves propagating through the continuous free layers, leadingto phase locking. Soon after, Grollier et al. [1] investigated
computationally the behavior of a one-dimensional (1D) seriesarray of N=10 electrically coupled STNOs. Their study
showed that the ac produced by each individual oscillator leadsto feedback between the STNOs, causing them to synchronize,and that, collectively, the microwave power output of thearray increases as N
2. In a follow-up study, Persson et al.
[3] mapped out numerically the region of synchronization of
the 1D serially connected array considered by Grollier et al.
for the special case of N=2 STNOs. Their work shows
that the region of parameter space where synchronizationexists is rather small, thus explaining the difficulty (alreadyobserved by experimentalists) to achieve synchronization.Liet al. [19] showed that this difficulty was due, mainly,
to the coexistence of multiple stable attractors, suggestingthat the synchronization regime is highly sensitive to initialconditions. Persson et al. [3] also investigated numerically the
effect of including a time delay between the magnetization-induced change in voltage and the current variation. Theyhighlight that this increases significantly the parameter regionof synchronization, especially with respect to differencesin anisotropy fields between the STNOs. We determinenumerically that the synchronization for 1000 STNOs is robustto nonhomogeneities in the anisotropy field on the order of4–5%, as Persson et al. also observes in the absence of delay.
It will be worthwhile to investigate in future work the effectsof time delay and to find out whether the synchronization isrobust to larger anisotropy in the network.
O nas i n g l eS T N O[ s e eF i g . 1(a)], an originally unpolarized
electric current I, in amperes, is applied to the fixed magnetic
layer whose magnetization is represented by ˆM.A st h e
electrons pass through the layer, their spins become aligned tothat of the fixed layer, thus creating a spin-polarized current.
Then the polarized current exerts a torque on the magnetization
of the free layer, which can lead to steady precession. We
2469-9950/2017/95(14)/144412(8) 144412-1 ©2017 American Physical SocietyJAMES TURTLE et al. PHYSICAL REVIEW B 95, 144412 (2017)
I0
RCIjR1RNR2
Mˆ Mˆ Mˆ
FIG. 1. Left: Schematic representation of a nanopillar STNO. A
spin-polarized current can exert a torque on the magnetization of the
free layer and lead to steady precession. Right: A circuit array ofSTNOs connected in series.
consider a circuit array of Nidentical STNOs coupled in series
[see Fig. 1(b)] and study the conditions to synchronize the
individual precessions. Our approach employs the dc current,I
dc, flowing in each STNO and the angle θhof the applied
magnetic field as the bifurcation parameters. No injection ofac current is required. The all-to-all coupling of the networkof identical STNOs implies a complete permutation symmetrywhich we exploit using equivariant bifurcation theory [ 20].
We search for fully synchronized periodic oscillations in
the network of NSTNOs, first by finding implicit analytical
expressions for Hopf bifurcation curves, in ( I
dc,θh) space, at
a synchronized equilibrium that yield symmetry-preservingin-phase oscillations (see Fig. 2). We calculate the stability of
the synchronization manifold near a synchronous equilibriumand combine Hopf criticality results to determine regions ofparameter space where the fully synchronized periodic stateis asymptotically stable near bifurcation. More importantly,the results are valid for networks of arbitrary size N.N o r m a l
hyperbolicity [ 22,23] guarantees the synchronization manifold
is robust to small nonhomogeneities in the STNOs. Numerical
simulations show that synchronization is preserved to approx-
imately ±5% variations in anisotropy strength. Results are
illustrated with arrays of up to N=1000 nano-oscillators
(see Fig. 3). The analysis also captures symmetry-breaking
patterns of oscillations, but we do not pursue the study ofthose cases here. These patterns are described as “multiplesynchronization attractors” in Ref. [ 24].
II. LOCI OF STABLE SYNCHRONIZED OSCILLATIONS
The free-layer magnetization vector, ˆm=[m1,m2,m3]T,
for an individual nanopillar oscillator is governed bythe Landau-Lifshitz-Gilbert-Slonczewski (LLGS) [ 25–28]
equation
dˆm
dt=−γˆm×−→Heff+αˆm×dˆm
dt−γμI ˆm×(ˆm׈M),
(1)
where γis the gyromagnetic ratio, αis the Gilbert damping
term,μcontains material parameters, and /vectorHeffis the effective
magnetic field. The term /vectorHeffconsists of an anisotropy
field, /vectorHan=κ(ˆm·ˆe||)ˆe||, where κis the strength of the
anisotropy (we set κ=45 Oe in our simulations [ 21]) ande||=
[sinθ||cosφ||,sinθ||sinφ||,cosθ||]Tis a preferred direction of
FIG. 2. Top: Loci of Hopf bifurcations of synchronized oscilla-
tions. Bottom: Stability of synchronization manifold (red, supercriti-
cal Hopf and stable synchronization manifold; black, subcritical Hopf
and unstable synchronization manifold; and blue, supercritical Hopf
and unstable synchronization manifold). The combined results ofthese two plots reveal the optimal region to synchronize a series array
of nanopillar STNOs: the first quadrant of parameter space ( I
dc,θh).
Parameters [ 21]a r eN1=1,N2=0,γ=2.2×105mA−1s−1,α=
0.008,κ=45 Oe, μ=0.992,ha=300 Oe, β/Delta1R=5.95×10−4.
FIG. 3. Locking into synchronization with N=1000 STNOs.
Start at high Idcand let the system lock into the common equilibrium.
Then sweep down Idcuntil the common equilibrium vanishes and
synchronized oscillations appear. Top inset: Zoom-in on the top partof the oscillation showing a high level of synchronization between
all the STNOs. Bottom inset: Zoom-in on the set of random initial
conditions for the N=1000 STNOs and evolution for small time
values showing rapid convergence to a synchronized equilibrium.
144412-2SYNCHRONIZATION OF SPIN TORQUE NANO-OSCILLATORS PHYSICAL REVIEW B 95, 144412 (2017)
magnetization. /vectorHdis a demagnetization field and we set /vectorHd=
−4πS0(N1m1ˆx+N2m2ˆy+N3m3ˆz), where S0=8400/4πis
the constant magnitude of the average magnetization vectorS(t) (in units of oersted) so that ˆm=S/S
0,N1,N2, and
N3are dimensionless constants satisfying N1+N2+N3=1,
and{ˆx,ˆy,ˆz}are the orthonormal unit vectors. /vectorHapplis an
applied magnetic field given by /vectorHappl=ha[0,sinθh,cosθh]T,
which we assume to lie on the yzplane at some angle θh
instead of the zaxis, and note that hais in units of oersted.
ˆMis the fixed-layer magnetization vector that defines the
spin-polarization direction of the current. In what follows weassume θ
||=0 so that e||=[0,0,1], which produces an easy
axis in the zdirection. Finally, we assume the direction of
polarization of the spin-polarized current to remain constantalong the zdirection, i.e., ˆM=ˆz.For an array of STNOs, coupling occurs if the input current
Iis replaced by I
j. First, we assume the STNOs to be
identical. Later, we consider the effects of nonhomogeneitiesas perturbations of the synchronization manifold. ApplyingKirchhoff’s laws we obtain the current through the jth STNO:
I
j=Idc/parenleftBigg
1+N/summationdisplay
i=1β/Delta1Ricosθi(t)/parenrightBigg
, (2)
where Idcis a constant dc, β/Delta1Riis a parameter that depends on
the resistances in the parallel and antiparallel magnetizationstates, and θ
i(t) is the angle between the magnetization of
the fixed and free ferromagnetic layers. We substitute Eq. ( 2)
into Eq. ( 1) and, for convenience, we convert to complex
stereographic coordinates through the change of variablesz
j=(mj1+imj2)/(1+mj3). Direct calculations yield
˙zj=γ(1+iα)
1+α2/bracketleftBigg
iha3zj+ha2
2/parenleftbig
1+z2
j/parenrightbig
+iκ1−|zj|2
1+|zj|2zj−μIDCzj−μIDCβ/Delta1RN/summationdisplay
k=11−|zk|2
1+|zk|2zj
−4πS0
1+|zj|2/parenleftbiggN1−N2
2/parenleftbig
z3
j−¯zj/parenrightbig
+/parenleftbigg
1−3N1+3N2
2/parenrightbigg
(zj−zj|zj|2)/parenrightbigg/bracketrightBigg
, (3)
where ha2=hasin(θh) andha3=hacos(θh).
For the special case N1=N2=0.5, Eq. ( 3)i sm o r e
amenable to analysis, and thus we can find, via MAPLE , implicit
analytic expressions for the Hopf loci that yield synchronizedperiodic states for arbitrary arrays of size N. Although the
synchronized periodic oscillation is unstable, we can stilluse these analytical expressions to follow, via the automaticnumerical continuation software
AUTO [29], the movement
of the Hopf loci as a function of the continuation parameters, where N
1=0.5+sandN2=0.5−s.F o rs=0.5, we
arrive at the physically relevant configuration of easy-planeanisotropy or x-axis demagnetization. The Hopf loci curves for
s=0.5 are shown in Fig. 2(top) for various sizes of networks.
In addition, we determine the criticality of each Hopf loci pointthrough the Lyapunov constant formula [ 30] as well as the local
asymptotic stability of the synchronization manifold near theHopf point, via
AUTO . This process yields, for s=0.5, the red
Hopf loci curves located in the first quadrant of ( Idc,θh) space
from which stable synchronized periodic solutions bifurcate(see Fig. 2, bottom).
Observe that the location of these curves implies that
less current is required to synchronize larger arrays. Thisobservation suggests that synchronization in series arrays ofnanopillar STNOs depends more on the dynamical parametersthan on the coupling strength. Similar results have beenobserved in studies of power grids, which can also be treatedas Kuramoto oscillator networks [ 31].
We wish to emphasize that the aim of this paper is strictly the
theoretical analysis to determine regions of existence of stablesynchronization. Effects of noise, such as linewidth reduction,are briefly addressed in Sec. VII, but a detailed analysis is
ongoing and deferred to a future publication. Next we presentan outline of the analysis that was carried out to obtain theimplicit solutions of the Hopf loci.III. HOPF BIFURCATION CURVES
This section summarizes the mathematical analysis of how
one can exploit the symmetry of the network to obtain themain results shown in Fig. 2. Details of these calculations can
be found in Appendix.
Due to the all-to-all coupling that appears in Eq. ( 3)a s
a consequence of Kirchhoff’s law, and the assumption ofidentical STNOs, any permutation of the STNOs in the arrayleaves the coupling term invariant; thus, the series array hassymmetry group S
N, the group of all permutations of N
objects. To find analytical expressions for the Hopf loci ofsynchronized solutions we study the linearized system nearthe origin. Let z=(z
1,..., z N)∈CNand denote Eq. ( 3)b y
˙zj=fj(z). Since we assume all the STNOs to be identical, we
havef1=f2=···= fN. We rewrite the system of Eq. ( 3)i n
abbreviated form
˙z=f(z), (4)
where f=[f1,..., f N]T.L e t z0=(z0,..., z 0) be an equilib-
rium solution of Eq. ( 4) with isotropy subgroup SN[20]. Then
the linearization at z0is given by
L:=⎡
⎢⎢⎢⎢⎣AB ··· B
B.........
.........B
B··· BA⎤
⎥⎥⎥⎥⎦, (5)
where A=(df
jj)z=z0andB=(dfjk)z=z0are 2×2 Jacobian
matrices of fj, with j/negationslash=k. Using symmetry methods, we
block-diagonalize Lto a form which respects symmetry-
invariant subspaces. Let Pbe the change-of-coordinates
matrix. Applying PtoL, we obtain a block diagonalization of
144412-3JAMES TURTLE et al. PHYSICAL REVIEW B 95, 144412 (2017)
the linear part of the coupled STNO array,
/tildewideL:=P−1LP=diag{A+(N−1)B,A−B,..., A−B}.
(6)
From the diagonal structure, the eigenvalues of the blocksare also eigenvalues of /tildewideL. It follows that Hopf bifurcations in
Eq. (4) occur if and only if A+(N−1)BorA−Bhave purely
imaginary eigenvalues. In the former case, the eigenspaceassociated with A+(N−1)Bisv
0=[v,..., v ]Tand the
symmetry group SNacts trivially on v0. This corresponds
to a symmetry-preserving Hopf bifurcation in which allSTNOs oscillate in synchrony, i.e., the same wave form, sameamplitude, and same phase. In the latter case, the eigenvalueshave, generically, multiplicity N−1 (from the N−1 blocks
A−B) and the emerging patterns of oscillations arise via
symmetry-breaking Hopf bifurcations [ 20]. For instance, the
case reported in Ref. [ 24], in which two pairs of STNOs are
in phase with one another and half a period out-of-phase withrespect to each pair, corresponds to a Hopf symmetry-breakingpattern that emerges from the A−Bblock with N=4. A
complete description of the possible patterns of oscillationsthat can appear for each value of Ncan be found via equivariant
Hopf bifurcation [ 20]. The emphasis of this paper is, however,
on the symmetry-preserving synchronization state.
Combining the equilibrium conditions with the trace
condition of purely imaginary eigenvalues for the blockA+(N−1)Band using polar coordinates, z
0=r(cosθ+
isinθ), we get the following set of equations as a function of
(r,cosθ,Idc,θh):
Re(fj)=0
Im(fj)=0
Tr(A+(N−1)B)=0. (7)
To find the desired analytical expressions for the Hopf
boundary curves, we solve Eqs. ( 7) implicitly for the state
variables ( r,θ) as functions of the parameters Idcandθh.W e
setN1=N2=0.5 as a starting point to facilitate the analysis.
Through a series of substitutions we are able to reduce thissystem of three equations with four unknowns, ( r,θ,I
dc,θh),
to a single expression with two variables ( r,θh). To plot the
boundary curves, we first extract the coordinate points fromthe solution sets, and back-substituting gives the actual pointvalues ( I
dc,θh) along the curves. Varying Nwe can then trace
the movement of the synchronous Hopf bifurcation curves.We verify along the curves obtained that det( A−B)>0
and det( A+(N−1)B)>0. The results just described are
then extended using
AUTO to the case N1=1,N2=N3=0
by continuing the Hopf loci curves in ( Idc,θh) space using
N1=0.5+sandN2=0.5−sand letting the continuation
parameter sevolve from 0 to 0.5.
IV . STABILITY
The Hopf bifurcation can be supercritical or subcritical,
leading to stable or unstable synchronized oscillations, re-spectively. Which one appears is determined by the Lyapunovconstant [ 30]. If the Lyapunov constant is negative, the Hopf
bifurcation is supercritical, whereas if it is positive, it leads to asubcritical Hopf bifurcation. Now, the stability property of thesynchronization manifold is determined by the eigenvalues
transverse to the manifold. Those eigenvalues are given byN−1 copies of the eigenvalues of the block A−Band since
the synchronization manifold is computed near an equilibrium,then normal hyperbolicity follows from the eigenvalues of theA−Bblock. The actual calculations of the Lyapunov constant
and that of the transverse eigenvalues are technical and lengthyand appear in Appendix under nonlinear analysis.
V . LOCKING INTO SYNCHRONIZATION
Numerical simulations indicate the common equilibrium
state of large arrays has a large basin of attraction for largevalues of dc, about 15 mA. This suggests a possible strategyto achieve synchronization in actual experiments: start theexperiments at high I
dccurrent and let the system lock into
the common equilibrium. Then sweep down Idcuntil the
common equilibrium vanishes at a saddle-node bifurcationand stable synchronized oscillations appear, created via Hopfbifurcation from a coexisting common equilibrium found atlower I
dcvalues. This strategy was tested with nonhomo-
geneities introduced through variations in the anisotropy fieldconstant κ. As a consequence of the normal hyperbolicity of
the synchronization manifold, we expect the synchronizationstate to be robust under small perturbations, such as thenonhomogeneities in κ. Indeed, numerical simulations confirm
that the STNOs are able to synchronize with up to ±5%
variations in anisotropy strength if the values are chosenrandomly from a uniform distribution (see Fig. 3), and up
to±4% with a Gaussian distribution.
VI. FREQUENCY RESPONSE
We now employ the fast Fourier transform (FFT) to
characterize the frequency response in networks of Nnon-
identical oscillators coupled in series. The plots in Fig. 4show
the frequency of oscillation for N=1, 10, 100, and 1000.
The observed “dips” for small values of Idccorrespond to the
switch from out-of-plane oscillations to in-plane oscillations.
−0.5 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5246810121416182022
IDC (mA)Frequency (GHz)N=1
N=10
N=100
N=1000
FIG. 4. Frequency response of an array of NSTNOs connected
in series. The observed dips in frequency correspond to switching
between out-of-plane and in-plane oscillations. Parameters are thesame as in Fig. 2, with θ
h=3π/4.
144412-4SYNCHRONIZATION OF SPIN TORQUE NANO-OSCILLATORS PHYSICAL REVIEW B 95, 144412 (2017)
Forθh=0, the switch is characterized by a gluing bifurcation,
that is, a global bifurcation where a pair of homoclinic loops(symmetrically related in this case) are connected to a saddleequilibrium; see Ref. [ 32] for an example in the context of
STNOs. For θ
h=3π/4, which is the value used in Fig. 4,t h e
switch involves two homoclinic bifurcations. In both cases, theswitch from out-of-plane to in-plane oscillations explains whythe frequency approaches 0 Hz. In general, lines terminatingat nonzero frequency correspond to known Hopf bifurcations,and lines terminating at or near 0 Hz correspond to suspected(not verified for every value of N) homoclinic bifurcations.
These results suggest that the range of I
dcvalues for which
oscillations are present increases with the number of STNOs;however, the interval of possible frequencies decreases withincreased N.
VII. LINEWIDTH
We now consider (briefly) the effects of thermal noise on
the oscillations of the synchronized solutions by adding a
stochastic thermal field term /vectorHthto/vectorHeff[33,34] in the original
LLGS Eq. ( 1), becoming
dˆm
dt=−γˆm×(−→Heff+−→Hth)+αˆm×dˆm
dt
−γμI ˆm×(ˆm׈M), (8)
where−→Hth=[hx(t),hy(t),hz(t)]T, in which hx(t),hy(t), and
hz(t) are Gaussian distributed random functions, uncorrelated,
of zero mean. The added term also carries to the complexform of Eq. ( 3). Linewidth was computed as full width of
the power spectral decomposition (PSD) of the synchronizedoscillations, via FFT, at half maximum of main frequency inthe PSD. The computation was carried out as a function ofI
dc, on the same interval of the frequency response of Fig. 4,
and for a few different values of array size N. The results are
shown in Fig. 5.
The spikes in linewidth that are observed near the end
points of the interval of synchronization are due to the
0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5
IDC (mA)050100150200250300Linewidth (MHz)N=1
N=10
N=100
024
IDC (mA)5101520Frequency (GHz)
FIG. 5. Linewidth. The observed dips in frequency correspond to
switching between out-of-plane and in-plane oscillations. Parametersare the same as in Fig. 2, with θ
h=3π/4.oscillations having different characteristics. More specifically,
for small Idcthe spikes are due to a change to out-of-plane
oscillations and for large Idc(and large arrays) the spikes
are due to loss of synchronization; i.e., for large arrays thesynchronized oscillations give way to out-of-phase oscillationsbefore eventually converging to an equilibrium point. Butfor the most part of the interval of synchronization, thelinewidth remains relatively small. These results suggest,again, that the synchronized solution is significantly robustagainst the effects of noise. However, one would have to carryout a complete analysis of the stochastic properties of thecoupled network equations as a function of coupling strengthand noise intensity, for instance. We also wish to point outthat temperature is assumed to be implicitly included in thestochastic thermal field. Future experimental works shouldprovide a more explicit contribution of temperature variationsand material properties towards the stochastic field. Thoseissues are important but they are beyond the scope of thepresent work. Instead, our emphasis is, mainly, on findingthe conditions for the existence and stability of synchronizedoscillations in the deterministic system. We expect to carry outthe stochastic analysis in future work. In particular, it would beinteresting to obtain theoretical formulas (possibly asymptoticfor large N) for the half linewidth for serially coupled STNOs
using the theory developed by Slavin and Tiberkevich [ 34].
VIII. DISCUSSION AND CONCLUSIONS
To date, the strongest microwave power that has been
produced by a single STNO is on the order of 0.28 μW[35].
As mentioned in the introduction, Grollier et al. [1]s h o w e d
that for an array of N=10 electrically coupled STNOs, the
synchronized array microwave power output increases as N2.
Thus, if the N2law holds in general, 1000 synchronized
nano-oscillators, as simulated in this paper, should produceabout 0.28 W. Communication systems, which require poweron the order of milliwatts, e.g., wireless devices, radar, airtraffic control, weather forecasting, and navigation systems,would only require about 188 nano-oscillators.
In Ref. [ 32], we showed computationally the nature of the
bifurcations leading to these attractors and discovered thatchanging the angle of the applied magnetization field couldenlarge the basin of attraction of the synchronized oscillations.In this work we extended the bifurcation analysis of nanopillar-based STNOs connected in series arrays of arbitrary size.We use equivariant bifurcation theory to find the region ofexistence and stability of the synchronization manifold forwhich all STNOs oscillate with the same frequency, phase,and amplitude. Our approach to achieve synchronization,
via non-Adlerian dynamics, employs only the dc flowing in
each STNO and the angle of the applied magnetic field.The main results include implicit solutions of the Hopf locias a function of the dc and the applied magnetic field.Normal hyperbolicity of the synchronization manifold impliesrobustness of the synchronization state to small perturbations,such as those caused by nonhomogeneities or imperfectionsduring the manufacturing process. Computer simulations withnonidentical STNOs indicate robustness up to ±5% variations,
which is well within typical fabrication processes. It is ourhope that the theoretical results and simulations provided in
144412-5JAMES TURTLE et al. PHYSICAL REVIEW B 95, 144412 (2017)
this paper will help guide ongoing experiments. The STNOs
are currently fabricated using the 50-nm technology wherelarge arrays can be configured on a substrate. Each oscillatoris independently isolated and unconnected at the fabricationstage. Once the devices are finished, the STNOs are bondedand connected in a series array. The postfabrication bondingand connection will afford us the opportunity to verify theresults established in this paper.
ACKNOWLEDGMENTS
We acknowledge support from ONR Code 30. J.T. and A.P.
were supported in part by NSF Grant No. CMMI-1068831.P.L.B. (Discovery Grant) and C.D. (USRA) acknowledgefunding from NSERC Canada.
APPENDIX: HOPF CURVES
This appendix describes the mathematical analysis that was
carried out to obtain the boundary curves that lead an array ofSTNO into and out of synchronization, as is shown in Fig. 2in
the main text. We start by considering again the array dynamicsin stereographic coordinates captured by Eq. ( 3) with the full
network in abbreviated form given by Eq. ( 4).
1. Linear analysis
Letz0=(z0,..., z 0) be an equilibrium solution of Eq. ( 4)
with isotropy subgroup SN[20]. Then, as described in the text,
the linearization at z0is given by
L:=⎡
⎢⎢⎢⎢⎣AB ··· B
B.........
.........B
B··· BA⎤
⎥⎥⎥⎥⎦,
where A=(df
jj)z=z0andB=(dfjk)z=z0are 2×2 Jacobian
matrices of fj, with j/negationslash=k. To diagonalize L,w ee m p l o yt h e
SNisotypic decomposition of the phase space CN, which is
given by
CN=V1⊕CN,0,
where
V1={(z,..., z )|z∈C},
CN,0={(z1,..., z N)∈CN|z1+···+ zN=0}
are absolutely irreducible representations of SN[20]. Let
vj=[v,ζjv,ζ2jv,..., ζ(N−1)jv]T,
where ζ=exp (2πi/N ) andv∈R. The vector v0is a basis
forV1while the remaining vectors vj,j=1,..., N −1, form
a basis for CN,0.N o wl e t
P=[Re{v0},Im{v0},Re{¯v0},Im{¯v0},...,
Re{vN−1},Im{vN−1},Re{¯vN−1},Im{¯vN−1}]T.
Applying PtoL, we obtain the following block diagonal-
ization of the linear part of the coupled STNO array:
/tildewideL:=P−1LP=diag{A+(N−1)B,A−B,..., A−B}.
(A1)From the diagonal structure, the eigenvalues of the blocks
are also eigenvalues of /tildewideL. It follows that Hopf bifurcations in
Eq. (4) occur if and only if A+(N−1)BorA−Bhave purely
imaginary eigenvalues. In the former case, the eigenspaceassociated with A+(N−1)Bis
v
0=[v,..., v ]T,
where the symmetry group SNacts trivially. This corresponds
to a symmetry-preserving Hopf bifurcation in which allSTNOs oscillate in synchrony, i.e., with the same wave form,the same amplitude, and the same phase. In the latter case,the eigenvalues have, generically, multiplicity N−1 (from the
N−1 blocks A−B) and the emerging patterns of oscillations
arise via symmetry-breaking Hopf bifurcations [ 20]. Com-
bining the equilibrium conditions with the trace condition ofpurely imaginary eigenvalues for the block A+(N−1)B(or
equivalently A−Bfor symmetry-breaking Hopf bifurcation)
and using polar coordinates, z
0=r(cosθ+isinθ), we get the
following set of equations as a function of ( r,cosθ,Idc,θh):
Re(fj)=0,
Im(fj)=0,
Tr(A+(N−1)B)=0(A2)
and require
Tr(A−B)<0,
det(A−B)>0,
det(A+(N−1)B)>0,
on the solution set of Eqs. ( A2) to guarantee no eigenval-
ues with positive real parts. To find the desired analyticalexpressions for the Hopf boundary curves, we solve Eqs. ( A2)
implicitly for the state variables ( r,θ) as functions of the
parameters I
dcandθh.W es e t N1=N2=0.5 as a starting
point to facilitate analysis. Through a series of substitutionswe are able to reduce this system of three equations withfour unknowns, ( r,θ,I
dc,θh), to a single expression with two
variables ( r,θh). Using MAPLE ’simplicitplot function 16
times, curves are found in the ( r,θh) domain to account for
all possible solutions. Combining results produces the desiredzero solution set of Eqs. ( A2). To plot the Hopf curves, we
first extract the coordinate points from the solution sets, andback-substituting gives the actual point values ( I
dc,θ) along
the curves. Then we substitute these points to verify thatdet(A−B)>0 and det( A+(N−1)B)>0. By varying N
in the implicit solver, we are then able to trace the movement
of the synchronous Hopf bifurcation curves. As mentionedabove, the Hopf curves are extended using
AUTO to the
caseN1=1,N2=N3=0, and those are the curves plotted
in Fig. 2.
2. Nonlinear analysis
We set again N1=N2=0.5 as a starting point and assume
A+(N−1)Bhas a pair of purely imaginary eigenvalues and
translate the equilibrium z0of Eq. ( 4) to the origin using v=
z−z0, leading to
˙v=f(v+z0),
144412-6SYNCHRONIZATION OF SPIN TORQUE NANO-OSCILLATORS PHYSICAL REVIEW B 95, 144412 (2017)
where fjis given by
fj=γ(1+iα)
1+α2/bracketleftBigg
iha3(vj+z0)+ha2
2(1+(vj+z0)2)
+iκ1−|vj+z0|2
1+|vj+z0|2(vj+z0)−μIdc(vj+z0)
−μIdcβ/Delta1RN/summationdisplay
k=11−|vk+z0|2
1+|vk+z0|2(vj+z0)
+2πiS 0
1+|vj+z0|2(vj+z0−(vj+z0)|vj+z0|2)/bracketrightBigg
.
(A3)
To determine criticality of the Hopf bifurcation we set
g(v,v)=(1+|v+z0|2)−1and Taylor expand Eq. ( A3)a t
(0,0) up to cubic order [ 30], which yields
˙vj=H1(vj,vj,v,v)+N(vj,vj,v,v), (A4)
where N(vj,vj,v,v)=H2(vj,vj,v,v)+H3(vj,vj,v,v) with
H/lscripta homogeneous polynomial of degree /lscript. That is,
H1(v,v)=a10vj+a01vj+n/summationdisplay
k=1b10vk+b01vk,
H2(v,v)=a20v2
j+a11|vj|2+a02v2
j+n/summationdisplay
k=1b20v2
k
+b11|vk|2+b02vk+c110vjvk+c101vjvk,
H3(v,v)=a30v3
j+a21|vj|2vj+a12|vj|2vj+a03v3
j
+n/summationdisplay
k=1b30v3
k+b21|vk|2vk+b12|vk|2vk+b03v3
k
+/parenleftbig
c120v2
k+c111|vk|2+c102v2
k/parenrightbig
vj.
For brevity, we list only a few of the coefficients:
b10τ=μIdcβ/Delta1R(2g(0,0)2|z0|2),
a10τ=iha3+z0ha2+iκg(0,0)2(1−2|z0|2−|z0|4)−μIdc
−μIdcβ/Delta1Rg(0,0)2(N(1−|z0|4)−2|z0|2)
+2πiS 0g(0,0)2(1−2|z0|2−|z0|4)−b10τ,
b11τ=−2μIdcβ/Delta1Rz0(|z0|2−1)g(0,0)3,
c101τ=2μIdcβ/Delta1Rz0g(0,0)2,
a11τ=−4z0g(0,0)3/parenleftbigg
iκ+i
2−μIdcβ/Delta1R/parenrightbigg
−b11τ−c101τ,
where τ=(1+α2)/(γ(1+iα)).
We now rewrite Eq. ( A4) using the same matrix Pgiven
by the decomposition of CN=CN,0/circleplustextV1intoSNirreducible
representations and letting v=Pu, yielding
˙u=/tildewideLu+PTN(Pu,Pu),
where /tildewideL=PTLPare the linear terms given by
Eq. ( A1) and the nonlinear terms are N(v,v)=
(N(v1,v1,v,v),..., N(vN,vN,v,v))T.An important observation is that the center manifold is V1=
Fix(SN) and so the flow-invariant center manifold is in fact a
subspace for Eq. ( 4). Thus we can compute the criticality of the
Hopf bifurcation directly from the equation for ˙u1evaluated
atu/lscript=u/lscript=0f o r/lscript=2,..., N , which yields
˙u1=G10u1+G01u1+G20u2
1+G11|u1|2+G02u2
1
+G30u3
1+G21|u1|2u1+G12|u1|2u1+G03u3
1,(A5)
where
G10=a10+Nb 10,
G01=a01+Nb 01,
G20=[a20+N(b20+c110)]/√
N,
G11=[a11+N(b11+c101)]/√
N,
G02=(a02+Nb 02)/√
N,
G30=[a30+√
N(b30+c120)]/√
N,
G21=[a21+√
N(b21+c111)]/√
N,
G12=[a12+√
N(b12+c102)]/√
N,
G03=(a03+√
Nb 03)/√
N.
Now, at a Hopf bifurcation, Re( G10)=0 and the eigenval-
ues are ±iρwith
ρ:=/radicalbig
|G10|2−|G01|2.
We use the linear transformation
Q=/parenleftbiggG01 iIm(G10)−iρ
−iIm(G10)+iρ G01/parenrightbigg
and the change of coordinates [ w1,¯w1]=Q[u1,¯u1]Tto
diagonalize the linear part of Eq. ( A5)t od i a g ( iρ,−iρ). Let
/tildewideH/lscript(w1,w1)=Q−1H/lscript(Q(w1,w1)T)f o r/lscript=2,3, then
˙w1=iρw 1+ρ+Im(G10)
2G01ρ(/tildewideH2(w1,w1)+/tildewideH3(w1,w1))
−i
2ρ(/tildewideH2(w1,w1)+/tildewideH3(w1,w1)). (A6)
We denote by gijthe coefficients of the quadratic and cubic
terms; i+j=/lscriptand/lscript=2,3. For the quadratic terms, the
coefficients are
g20=[ρ+Im(G10)]
2G01ρ/bracketleftbig
4G20G2
01+G11(−2G10G01i+2iG01ρ)
+G02/parenleftbig
−G2
10+2G10ρ−ρ2/parenrightbig/bracketrightbig
−i
2ρ/parenleftbig
4G20G2
01+G11(−2G10G01i+2iG01ρ)
+G02/parenleftbig
−G2
10+2G10ρ−ρ2/parenrightbig/parenrightbig
,
g11=[ρ+Im(G10)]
2G01ρ/bracketleftbig
8G20G2
01+G11(−4G10G01i)
+G02/parenleftbig
−2G2
10+2ρ2/parenrightbig/bracketrightbig
−i
2ρ/parenleftbig
8G20G2
01+G11(−4G10G01i)
+G02/parenleftbig
−2G2
10+2ρ2/parenrightbig/parenrightbig
,
144412-7JAMES TURTLE et al. PHYSICAL REVIEW B 95, 144412 (2017)
g02=[ρ+Im(G10)]
2G01ρ/bracketleftbig
4G20G2
01+G11(−2G10G01i−2iG01)
+G02/parenleftbig
−G2
10−2G10ρ−ρ2/parenrightbig/bracketrightbig
−i
2ρ/parenleftbig
4G20G2
01+G11(−2G10G01i−2iG01)
+G02/parenleftbig
−G2
10−2G10ρ−ρ2/parenrightbig/parenrightbig
,
and the cubic coefficient is
g21=[ρ+Im(G10)]
2G01ρW−i
2ρW,
where
W:=/braceleftbig
12G30G3
01+G21/parenleftbig
−6G10G2
01i+2iG2
01ρ/parenrightbig
+G12[4G10G01(−G10+ρ)−2G10(G10−ρ)]
+2G01ρ(G10+ρ)
+G03/bracketleftbig/parenleftbig
G2
10−2G10ρ+ρ2/parenrightbig
(G10+ρ)i
+2i(ρ2−G2
10)(−G10+ρ)/bracketrightbig/bracerightbig
.3. Lyapunov constant and stability
Using the coefficients just listed above, we then obtain the
Lyapunov constant from the formula [ 30]
Re(c1)=Re/parenleftbiggi
2ρ/parenleftbigg
g20g11−2|g11|2−1
3|g02|2/parenrightbigg
+g21
2/parenrightbigg
.
(A7)
The Hopf bifurcation is supercritical if Re( c1)<0 and
subcritical if Re( c1)>0. However, this condition only de-
termines the stability of the synchronized periodic solutionon the center manifold. Thus, we also need to considerthe eigenvalues transverse to the center manifold. Thoseeigenvalues are given by N−1 copies of the eigenvalues of
the block A−Bwith real parts
1
2Tr(A−B)=Re(a10−b10).
It follows that the synchronized oscillations are asymptoticallystable if Re( a
10−b10)<0.
ForN1=N2=0.5, subcritical Hopf bifurcations are ob-
tained. We change the direction of demagnetization to N1=1,
N2=N3=0 by numerical continuation using AUTO and
we obtain that Hopf bifurcation curves in the first quadrantof (I
dc,θh) space are supercritical and the synchronization
manifold is asymptotically stable near z0. This leads to
an asymptotically stable periodic solution near bifurcation.See Fig. 2.
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144412-8 |
PhysRevB.102.144419.pdf | PHYSICAL REVIEW B 102, 144419 (2020)
Editors’ Suggestion
Evaluation of the switching rate for magnetic nanoparticles: Analysis, optimization, and
comparison of various numerical simulation algorithms
Elena K. Semenova , Dmitry V . Berkov , and Natalia L. Gorn
General Numerics Research Lab, Moritz-von-Rohr-Straße 1A, D-07745 Jena, Germany
(Received 4 August 2020; revised 22 September 2020; accepted 23 September 2020; published 14 October 2020)
In this paper, we present a detailed comparative study of various analytical and numerical methods intended
for the evaluation of the escape rate over high-energy barriers (transition rate or, equivalently, switching times)in magnetic systems, using the archetypal application-relevant model of a biaxial macrospin. First, we derivea closed-form analytical expression of the transition rate for such a particle, using the general formalismof Dejardin et al. [Phys. Rev. E 63, 021102 (2001) ], and define a parameter which determines whether the
system is in the low, intermediate, or high damping regimes. Then we carry out a comprehensive analysis ofthree numerical algorithms: time-temperature extrapolation method, “energy bounce” methods [S. Wang and P.Visscher, J. Appl. Phys. 99, 08G106 (2006) ], and the forward-flux sampling [R. J. Allen et al. ,P h y s .R e v .L e t t .
94, 018104 (2005) ], which appear to be the most promising candidates for evaluating the transition rate using
computer simulations. Based on underlying physical principles and peculiarities of magnetic moment systems,we suggest several optimization possibilities, which strongly improve the performance of these methods forour applications. For energy barriers /Delta1Ein the range 10 k
BT/lessorequalslant/Delta1E/lessorequalslant60kBTwe compare the switching times,
which correspondingly span more than 20 orders of magnitude, obtained with all the above-mentioned analyticaland numerical techniques. We show that although for relatively small barriers all methods agree well with eachother (and with straightforward Langevin dynamics simulations), for larger barriers the differences becomesignificant, so that only the forward-flux method provides physically reasonable results, giving switching timeswhich exceed the prediction of analytical approaches (interestingly, the ratio τ
FFS
sw/τan
swis nearly constant for
a very broad interval of switching times). The reasons for the corresponding behavior of numerical methodsare explained. Finally, we discuss the perspectives of the application of the analyzed numerical techniques tofull-scale micromagnetic simulations, where the presence of several contributions to the total system energymakes the situation qualitatively different from that for the macrospin approach.
DOI: 10.1103/PhysRevB.102.144419
I. INTRODUCTION
During the recent two decades, a large progress by the eval-
uation of escape rates over high-energy barriers in differentphysical systems in general and in magnetic systems in par-
ticular has been achieved. First of all, for systems of magnetic
particles with and without internal magnetization structureseveral methods for computing the height of energy barriersseparating their metastable energy minima have been imple-mented: minimization of the Onsager-Machlup functional [ 1]
for an interacting system of single-domain particles [ 2], string
method searching for the “minimal energy path” based on the
condition that the energy gradient component perpendicular
to this path should be zero along the whole path [ 3], and the
closely related “nudged elastic band” (NEB) method [ 4]. The
latter method, which is presently the most widely used, is the“micromagnetic” adaptation of the NEB algorithm of Jonssonet al. [5], with the main idea to connect the neighboring system
states along the transition path with artificial “springs” to
prevent a too large distance between these states during the
path-finding procedure.
However, knowledge of the energy barrier /Delta1Ealone is
obviously not enough to compute the average lifetime of asystem within an energy well (or, correspondingly, the es-
cape rate /Gamma1out of this well), the quantity of real interest for
applications. The simplest possibility to evaluate this rate isprovided by the Arrhenius law /Gamma1=ν
attexp(/Delta1E/kBT), where
the “attempt frequency” νattis usually interpreted as the os-
cillation frequency of the system near the energy minimum.The evaluation of this frequency by itself for systems withan internal magnetization structure is a highly nontrivial taskdue to the existence of internal eigenmodes in such systems(see, e.g., [ 6,7]). But, even with the properly evaluated ν
att,
the Arrhenius formula can not be considered as a satisfactoryapproach from a fundamental point of view, as stressed, e.g.,in [8,9], because it does not contain a dependence of the
switching rate on the system damping, which is mandatoryaccording to the fluctuation-dissipation theorem.
The problem of providing an analytical expression of the
escape rate, which would explicitly contain the damping pa-rameter, was first solved in the intermediate-to-high damping(IHD) regime by Brown [ 10] and later for very low damping
(VLD) by Klik and Gu ¨nther [ 11]. In the meantime, the correct
analytical description of the escape rate for a system withan arbitrary damping was provided in the classical paper ofMel’nikov and Meshkov [ 12], who have evaluated both the
2469-9950/2020/102(14)/144419(17) 144419-1 ©2020 American Physical SocietySEMENOV A, BERKOV , AND GORN PHYSICAL REVIEW B 102, 144419 (2020)
lifetime of a Brownian particle in a single energy well and
decay rates in a double-well potential in the correspondinggeneral case. The formalism and ideas from [ 11,12]w e r e
successfully applied to a single-domain magnetic particlein [13,14], resulting in an analytical formula for the escape
rate out of a single well and transition rates between twoenergy minima in a double-well magnetic system valid for alldamping regimes. The comprehensive treatment of this topiccan be found in the extensive review [ 9].
Although very useful, this analytical approach has sev-
eral limitations. Even for single-domain particles, the methodcannot take into account the so-called “back-hopping” trajec-tories, where the system magnetization returns back to theinitial local minimum shortly after crossing the saddle point,i.e., without reaching the (partial) thermodynamic equilibriumin the target minimum. Further, for magnetic systems with asymmetry lower than the perfect uniaxial anisotropy with twoequivalent minima, as it is the case, e.g., for particles in anexternal field (both along the easy axis [ 15] and oblique [ 16]),
or for particles with the anisotropy more complicated than auniaxial one [ 17], the treatment becomes increasingly com-
plicated, making corresponding final expressions difficult inpractical applications.
The really serious problem of the analytical treatment,
however, is that it cannot be applied to most application-relevant cases, where the particle size is larger than eitherthe exchange or demagnetizing characteristic micromagneticlength (for corresponding definitions and discussion see,e.g., [ 18]). For such systems, magnetization configuration be-
comes spatially nonhomogeneous, thus making the usage ofanalytical methods nearly impossible. For this reason, thereexists a pressing demand for numerical methods comput-ing not only the energy barrier, but the actual escape rate.Straightforward Langevin dynamics (LD), being a powerfultool for short-time simulations (see, e.g., [ 19–23], is obvi-
ously not applicable for studying magnetization transitionsbetween minima separated by high-energy barriers (about/Delta1E>10k
BT) because waiting times become macroscopi-
cally large.
Numerical methods for evaluating the escape rate in sys-
tems with high barriers usually employ the paradigm of a“gradual climbing” uphill the energy surface by computingthe probability p(λ
i−1→λi) to reach some intermediate in-
terface λifrom the previous interface λi−1. The subsequent
interfaces should be positioned relatively close to each other,either in the coordinate space or in the energy space, so that
p(λ
i−1→λi) can be computed reasonably fast and accurately
by standard LD simulations. Multiplication of these transitionprobabilities for all interface pairs between the two energyminima of interest should give (augmented by a properlydefined factor with the dimensionality 1 /t) the total transition
rate.
The most successful general-purpose representative of the
methods outlined above is the forward-flux sampling (FFS)(see [ 24–26] for specific issues and [ 27] for a comprehensive
review). In FFS, the interfaces are defined in the coordinatespace, usually by setting the desired values of the so-called“reaction coordinate” or an “order parameter,” which valuedefines whether the transition has occurred or not. In mi-cromagnetics, this method was applied for two very specificsystems in [ 28,29]. A related method, where the interfaces
were defined as the system energy values used to confinethe magnetization motion, is the “energy bounce” algorithmintroduced in [ 30]; this short paper contains only the basic
idea and the application example to a macrospin with onlyone value of the energy barrier.
Hence, it can be seen that as far as micromagnetic appli-
cations are considered, the methods for computing transitionrates over high barriers are at their infancy (what can be seenalready from a very small number of corresponding publi-cations). Physical understanding of their functioning whenapplied to micromagnetic simulations is insufficient, system-atic comparison of corresponding numerical results with theavailable analytical expressions is, up to our knowledge, notavailable, and the optimization of the algorithms with re-spect to the minimization of the computational time (whatis crucial for such time-consuming simulations) has not beenaccomplished. Further, the analysis of possible alternative al-gorithms capable of computing the switching time without agradual climbing from the minimum to the saddle point hasalso not been performed.
In our study, we intend to fill in the gaps outlined
above, performing detailed analytical and numerical studiesof magnetization transitions over energy barriers. We con-fine our study to purely classical processes, leaving aside thephenomenon of macroscopic quantum tunneling of magneti-zation; the latter is usually relevant at very low temperatures(according to various estimations, for T<T
qt, where Tqt∼
100 mK ÷10 K [ 31,32]), which are of no interest for appli-
cations we have in mind. This paper is organized as follows:In Sec. IIwe describe our biaxial macrospin model and derive
closed-form analytical expressions for its switching rate bothin the Arrhenius approximation and in the general formal-ism [ 13,14] for an arbitrary damping value. In Sec. IIIwe
present results of LD simulations, to be used as a referencefor further comparisons. In this section we also discuss indetail a very important question of distinguishing between“false” and “true” transitions, when the magnetization pro-jection of interest changes its sign. In Sec. IVwe present
the most straightforward method for computing switchingrates for a system with arbitrarily high barriers using onlyLD simulations, our “time-temperature” extrapolation method(related to the idea suggested in [ 33]). In this method we
use the extrapolation of switching rates obtained at severalhigher temperatures toward the room temperature to obtainthe desired quantity. Next, in Sec. V, we perform the detailed
analysis of the energy bounce method (EBM) and introducetwo versions of this method, which enable to strongly reducethe corresponding computation time and to prepare EBM forusage in full-scale micromagnetic simulations. In addition, wediscuss again the criterion for filtering out the false switch-ings, as the dynamics in EBM is qualitatively different fromthat by nonconstrained LD simulations. Section VIis devoted
to our implementation of the FFS method, where we sug-gest the placement of interfaces in the energy space (insteadof using magnetization projections), allowing us to obtainthe best interface positions without any optimization, thusgreatly increasing the statistical accuracy of results. Finally, inSec. VIIwe compare the results obtained by all analytical and
numerical methods used in our study for energy barriers in
144419-2EV ALUATION OF THE SWITCHING RATE FOR MAGNETIC … PHYSICAL REVIEW B 102, 144419 (2020)
FIG. 1. Coordinate system and geometry of simulated
nanoelements.
the interval 10 kBT/lessorequalslant/Delta1E/lessorequalslant60kBT, so that the correspond-
ing switching times span over 20 orders of magnitude. Inthe Conclusion, we summarize our findings and discuss thecomparative quality of the studied methods and perspectivesof their application of all methods to full-scale micromagneticsimulations.
II. SIMULATED MODEL AND ANALYTICAL
APPROXIMATIONS FOR THE ESCAPE RATE
A. Macrospin approximation (MSA)
In this study, we simulate magnetization switching of el-
liptical nanoelements with the thickness h=3 nm, the short
axis b=40 nm, and different long axes a=50–100 nm.
Corresponding geometry together with Cartesian coordinatesassumed throughout the paper is shown in Fig. 1.W eu s e
magnetization M
s=800 G and Gilbert damping λ=0.01
and neglect the magnetocrystalline anisotropy (magnetic pa-rameters typical for Py). Shape anisotropy is introduced inthe standard way via the demagnetizing field tensor ˆNwith
diagonal components N
x,Ny, and Nz[23]; in our geometry, we
always have Nx<Ny<Nz. For all methods presented below,
we have determined the transition rate at room temperature(T=300 K).
In our simulations we use the macrospin approximation,
i.e., we assume that the magnetization of nanoellipses is ho-mogeneous in space and can only rotate as a whole. We pointout that from the physical point of view this approximationis not valid for nanoelements of these sizes, because at leastthe long axis of our ellipses greatly exceeds the single-domainparticle size for Py, which is estimated to be ∼10 nm. How-
ever, we shall employ the macrospin model in order to focusour study on fundamental questions important for all meth-ods intended for simulation of thermally activated switching,without yet being involved into the complicated problemsrelated to internal dynamic modes of a switching system; cor-
responding problems (arising by the application of methodsdiscussed below to full-scale micromagnetic simulations) willbe discussed in Sec. VII.
From the four standard contributions to the micromag-
netic energy (energy in an external field, magnetocrystallineanisotropy, exchange and magnetodipolar energy), only twoterms are present in frames of MSA: energy in an externalfield and the magnetodipolar energy, which in this approxi-mation is usually called the shape anisotropy energy. The firstterm is absent in our case, as we study magnetization switch-ing without an external field. The shape anisotropy energyis defined using the above-mentioned tensor ˆNand Cartesian
components of the unit magnetization vector mas
E
an=2πM2
sV/parenleftbig
Nxm2
x+Nym2
y+Nzm2
z/parenrightbig
, (1)
where Vdenotes the particle volume. Expression ( 1) (biaxial
anisotropy) is the simplest analytical approximation for theshape anisotropy energy of a flat elliptical magnetic nanoele-ments shown in Fig. 1; this shape is widely used for many
applications including, e.g., in-plane magnetic random accessmemory (MRAM) cells. In addition, this is the simplest pos-sible model where one has the easy-plane anisotropy (with0xyas the easy plane) and the energy barrier between the two
equilibrium states in this plane, along +xand−xdirections.
For analytical calculations of the switching rate, we shall
need the expansion of the density of this energy ( /epsilon1=E/V)
near the energy minima (where m
x=± 1) and the saddle
points (in-plane switching, hence, my=± 1) in terms of two
remaining magnetization projections. Using the relation m2
x+
m2
y+m2
z=1 for the elimination of mxin the first case and my
in the second case, we obtain
/epsilon1min(m)=/epsilon1(0)
min+2πM2
s/parenleftbig
Cyxm2
y+Czxm2
z/parenrightbig
, (2)
/epsilon1sad(m)=/epsilon1(0)
sad+2πM2
s/parenleftbig
Cxym2
x+Czym2
z/parenrightbig
, (3)
where Cαβ=Nα−Nβ(α,β=x,y,z); note that our constants
Cαβdiffer from the analogous constants ciin [9] by the factor
4πM2
s.
In this paper we shall study the escape rate from the
minimum corresponding to mx=+ 1 (the region around this
starting point is denoted as the basin A) to the minimum
with mx=− 1 (with the surrounding region denoted as the
basin B).
For the analysis of the behavior of different numerical
methods, we shall need the density of states (number of statesper unit energy interval) D(E). Analytical evaluation of this
dependence for a macrospin with a biaxial anisotropy is verytedious. For this reason, we have computed D(E) numerically
by evaluating the system energy ( 1) for all moment orienta-
tions on the ( θ,φ) grid in the spherical coordinate system
shown in Fig. 1, with the polar axis along the xaxis and
the azimuthal axis φ=0, along the yaxis of our coordinate
system. Correspondingly weighted ( w∝sinθ) energy val-
ues were assembled to a histogram. Resulting (normalized)D(E) for several macrospin sizes are shown in Fig. 2.N o t e
that the density of states for a biaxial macrospin divergesat the saddle-point energy E
sad=E(θ=π/2,φ=0o rπ)
(because at this point both partial energy derivatives are zero:∂E/m
x=∂E/mz=0); however, this divergence is not as
strong as for a uniaxial macrospin, where the saddle on theenergy surface is represented by the whole line θ=π/2.
In terms of this density of states, the probability p(E)t o
observe an energy Efor a system in thermodynamic equilib-
rium is
p(E)=D(E)e
−E/kBT. (4)
B. Arrhenius approximation of the escape rate
As mentioned in the Introduction, the simplest (and still
most widely used) analytical approximation for the escape
144419-3SEMENOV A, BERKOV , AND GORN PHYSICAL REVIEW B 102, 144419 (2020)
FIG. 2. Densities of states D(E) for macrospins with various
long ellipse axis aas shown in the legend.
rate resulting from the Arrhenius law is called the transition
state theory rate [ 34]:
/Gamma1Arr=ωatt
2πe−/Delta1E/kBT(5)
(kis Boltzmann constant). In MSA, both the energy barrier
/Delta1Eand the attempt frequency ωattentering this expression
can be evaluated analytically:
/Delta1E=KV=2πM2
sCyxπhab
4, (6)
ωatt=γ4πMs/radicalbig
CyxCzx (7)
(for the last expression see, e.g., [ 35]), where γis the gyro-
magnetic ratio.
Dependencies of these quantities on the long axis of our
elliptical nanoelement are shown in Fig. 3. Demagnetizing
factors required in ( 6) and ( 7) have been computed in our
paper [ 23] by comparing initial slopes of the hysteresis loop
calculated by full-scale micromagnetic simulations (using thecell size 2 ×2n m
2in plane) with the corresponding slope ex-
pected in MSA. As explained in detail in [ 23], demagnetizing
factors computed this way represent a better approximation
FIG. 3. Attempt frequency νatt=ωatt/2π(main plot) and energy
barrier ( 6) (inset) as functions of the long ellipse axis a(short axis
b=40 nm).to the demagnetizing factors of a flat elliptical nanoelement
than those computed from the axis ratios of the correspondingthree-dimensional (3D) ellipsoid. Note that the dependence/Delta1E(a) is slightly nonlinear because demagnetizing coeffi-
cients N
x(y,z)also depend of a; however, this effect is weak
compared to the linear dependence V∼a.
The switching time in this approximation is
τArr
sw=1
2/Gamma1Arr, (8)
where the additional factor1
2is due to the existence of two
saddle points in our system. Note that in the interval of thelong axis lengths a=50–110 nm studied here the switching
time spans about 25 orders of magnitude. The dependence oflog(τ
Arr
sw)v s ais also slightly nonlinear, not only due to the
nonlinearity of /Delta1E(a), but also due to the nonlinear depen-
dence νatt(a) (see Fig. 3).
C. Magnetization escape rate for a biaxial particle
by arbitrary damping
The Arrhenius expression has two well-known technical
drawbacks: (i) it does not take into account the curvature ofthe energy landscape around the saddle point and (ii) it doesnot consider the possibility of a reverse transition shortly afterthe particle has crossed the energy barrier (back hopping).However, a much more serious problem is that the Arrheniuslaw does not include the damping constant, meaning that inthis formalism the switching can occur without any damp-ing, which is clearly impossible (no coupling to thermal bathpresent, see [ 8] for details). Large effort has been undertaken
to derive physically meaningful expressions for various damp-ing regimes [ 8,12,36]; corresponding results for the magnetic
particle switching (where the precessional motion plays a veryimportant role) have been summarized in the comprehensivereview [ 9].
To proceed with our specific case, we shall need the general
analytical expression for the magnetization escape rate /Gamma1
an,
valid (in the limit of the high-energy barrier /Delta1E/greatermuchkBT)f o r
all values of the damping parameter α[9,14]:
/Gamma1an=/Omega1
ωsA(αS)/Gamma1Arr,τan
sw=1
2/Gamma1an. (9)
Here, the damped saddle angular frequency /Omega1
/Omega1=πM2
sV
kBT1
τN/bracketleftbigg/radicalbigg
(Cxy−Czy)2−4CxyCzy
α2−(Cxy+Czy)/bracketrightbigg
(10)
[CxyandCzyare defined after the Eq. ( 3)] contains the charac-
teristic diffusion time of the magnetization
τN=VM s
2γkBT1+α2
α. (11)
The undamped saddle angular frequency ωsis defined analo-
gously to the attempt frequency ( 7):
ωs=γ4πMs/radicalbig
−CxyCzy (12)
(note that Cxy=Nx−Ny<0).
144419-4EV ALUATION OF THE SWITCHING RATE FOR MAGNETIC … PHYSICAL REVIEW B 102, 144419 (2020)
Prefactor A, called the depopulation factor because the
decrease rate of the particle concentration within an energyminimum is proportional to A, has been derived in case of
an arbitrary damping for the first time by Melnikov andMeshkov [ 12] and has the form
A(αS)=exp/bracketleftbigg1
π/integraldisplay∞
0ln{1−e−αS(z2+1/4)}dz
z2+1/4/bracketrightbigg
.
(13)
For small α→0, the asymptotic behavior of this prefactor
isA(αS)→αS,s oE q .( 9) reduces to the result of Klik and
Gunther [ 11]. For large damping α→∞ we have A(αS)→1,
and Eq. ( 9) reproduces the escape rate in the intermediate-to-
high (IHD) damping range [ 37].
The dimensionless action Sin the depopulation factor ( 13)
is given in case of a magnetic particle by the integral ( p=
cosθ)[9,11]
S=Vp
kBT/contintegraldisplay
E=Esad/bracketleftbigg
[1−p2(φ)]∂/epsilon1
∂pdφ−1
1−p2∂/epsilon1
∂φdp/bracketrightbigg
,
(14)
where /epsilon1denotes the energy density, expressed as the func-
tion of spherical coordinates of the magnetic moment: /epsilon1=
/epsilon1(θ,φ). This integral should be taken along the trajectory
where the system energy Eis equal to the saddle-point energy
Esad; hence, the polar angle θcan be viewed as a function of
the azimuthal angle φ, so that p≡cosθ=p(φ).
To evaluate the action ( 14), we shall use the energy den-
sity expression ( 2) and introduce the reduced energy density
u(my,mz)a s
u(my,mz)=Cyxm2
y(θ,φ)+Czxm2
z(θ,φ) (15)
so that the action takes the form
S=2πM2
sVp
kBT/contintegraldisplay
E=Esad/bracketleftbigg
(1−p2)∂u
∂pdφ−1
1−p2∂u
∂φdp/bracketrightbigg
=2πM2
sVp
kBT[I1+I2]. (16)In the spherical coordinate system with the polar axis along
the Cartesian xaxis, and φdefined as the angle between the
projection of monto the yzplane and yaxis, we have mx=
cosθ,my=sinθcosφ,mz=sinθsinφ, so that the energy
density ( 15)i s
u(θ,φ)=sin2θ(Cyxcos2φ+Czxsin2φ)
=sin2θCyx(1+κsin2φ)
=Cyx(1−p2)(1+κsin2φ), (17)
where the ratio κ=(Czx−Cyx)/Cyx=Czy/Cyx>0i si n t r o -
duced.
The integration trajectory passes through the saddle point
(θ=π/2,φ=0) and hence the function u(θ,φ) along this
trajectory is equal to u=usad(π/2,0)=Cyx, leading to the
relation
(1−p2)(1+κsin2φ)=1. (18)
Using this condition by calculating partial derivatives ofthe energy density ( 17) and substituting them into the inte-
gral ( 16), we obtain
I
1=/contintegraldisplay
u=usad[1−p2(φ)]∂u
∂pdφ=− 4Cyx/integraldisplayπ
0p(φ)dφ, (19)
I2=−/contintegraldisplay
E=Esad1
1−p2∂u
∂φdp=−Cyxκ/contintegraldisplay
u=usadsin 2φdp
dφdφ.
(20)
Employing the same relation ( 18), we can find the derivative
dp
dφ=±√κcosφu
(1+κsin2φ)3/2, (21)
where the upper sign corresponds to the interval φ∈[0,π],
the lower sign to φ∈(π,2π). Substituting this derivative
into ( 20) and reducing integration limits over φto [0,π], we
obtain
I1+I2=− 4Cyx√κ/integraldisplayπ
0/bracketleftbiggsinφ
(1+κsin2φ)1/2+κsinφcos2φ
(1+κsin2φ)3/2/bracketrightbigg
dφ=− 4Cyx√κ(1+κ)I(κ) (22)
(the minus sign appears due to the chosen integration direction
along the trajectory and hence can be ignored, as we need onlythe absolute value of the action).
Forκ/greaterorequalslant0 the integral I(k)i n( 22) can be evaluated analyt-
ically: I(κ)=2/(1+κ). Hence, the final result for the action
Sis
S=16πM
2
sVp
kBT/radicalbig
CyxCzy. (23)
An important remark is in order. The depopulation factor
A[Eq. ( 13)] depends on the product αS. Hence, it is clear
already from the prefactor in the action expression ( 16) that
the parameter which defines whether we are in the region ofa small, intermediate, or large damping is notthe value of the
damping parameter αby itself, but the value of the product ofαand the relation of the energy barrier to the thermal energy
/Delta1E/k
BT(∼M2
sV/kBTin our case). We shall return to this
statement below by comparing the results obtained by variousmethods.
III. LANGEVIN DYNAMICS (LD) SIMULATIONS
The most straightforward method to determine the switch-
ing rate between the two metastable system states is thesimulation of the system dynamics in presence of thermalfluctuations using the corresponding stochastic equation ofmotion [ 38]. Taking into account that we are interested
in magnetic systems by temperatures much lower than theCurie temperature (so that the magnetization magnitude
144419-5SEMENOV A, BERKOV , AND GORN PHYSICAL REVIEW B 102, 144419 (2020)
M=const), we use the Landau-Lifshitz-Gilbert equation
dM
dt=−γ[M×(Hdet+Hfl)]
−γλ
Ms[M×[M×(Hdet+Hfl)]] (24)
to describe the system dynamics. Here, the fluctuation field
accounting for thermal fluctuations has the properties /angbracketleftHfl
ζ/angbracketright=
0 and /angbracketleftHfl
ζ(0)·Hfl
ψ(t)/angbracketright=2Dflδ(t)δζψ, where the fluctuation
power is Dfl=λ/(1+λ2)(kBT/γμ )(ζ,ψ=x,y,z),μbeing
the magnetic moment magnitude. The deterministic field Hdet
contains the contributions from all magnetic energy terms,
what in our case reduced to the anisotropy field only (we recallthat we simulate nanoelements in the absence of an externalfield). The constant γin (24) relates to the gyromagnetic ratio
γ
0and the damping αin the alternative form of this equa-
tion proposed by Gilbert ˙M=−γ0[M×(H−(α/Ms)˙M)]a s
γ≈γ0viaγ=γ0/(1+α2), and damping parameters λand
αare equal; for further details, see, e.g., [ 39].
We have performed LD simulations using our micromag-
netic package MICROMAGUS [40] where Eq. ( 24)i si n t e g r a t e d
using one of the adaptive step-size algorithms (Runge-Kuttaor Bulirsch-Stoer) for the stochastic differential equations(SDE) describing the dynamics of vector fields with theconstant vector magnitudes. The possibility to apply suchmethods to SDE ( 24) is justified in [ 41], where we have shown
that for M=const both Ito and Stratonovich stochastic calculi
lead to identical results. For generation of the thermal noisewe have used the version of the vector statistics (VS) Gaussianrandom numbers generator from Intel MKL library, whichemploys the inverse cumulative distribution function method(ICDF-type generator) to produce a sequence of independentGaussian random numbers with the prescribed mean and dis-tribution width; this generator is known for its high quality.Cross checks with other (simpler) random number generators,l i k et h o s ef r o m[ 42], have shown that final results remain the
same (in frames of statistical errors).
Simulation of magnetization switching using Langevin dy-
namics is possible only for systems with relatively smallenergy barriers (not higher than /Delta1E∼10k
BT) because sim-
ulation times grow exponentially with the energy barrier. Forthis reason we could perform LD studies only for macrospinscorresponding to nanoellipses with a=50 nm ( /Delta1E≈9k
BT)
anda=55 nm ( /Delta1E≈14kBT); we remind that T=300 K.
Taking into account that both energy minima for our sys-
tem are equivalent ( Hext=0), the average switching time τLD
sw
for LD simulations can be computed as
τLD
sw=tsim
Nsw, (25)
where tsimdenotes the (physical) simulation time and Nsw
the number of switching events between the energy minima
observed during the simulation run.
However, in order to calculate τLD
swproperly, we have to
correctly determine whether the true switching (defined asthe transition between two metastable energy minima withm
x=± 1) took place. For this purpose, it is not enough
to count the number of times when the dependence mx(t)
changes its sign [see Fig. 4(a)] (or, to be more careful, crosses
FIG. 4. Difference between “true” and “false” switchings (see
text for details). On (c) the 3D magnetization trajectory in the timeinterval 17 ns /lessorequalslantτ/lessorequalslant20 ns is depicted.
some negative threshold, say, mx=− 0.2, when coming from
positive values). For the correct determination of Nswwe have
to distinguish between true and false switchings.
A simple example where this difference is clear is illus-
trated in Figs. 4(a)–4(c). Here, a true switching has occurred
atτ≈13 ns; corresponding pieces on the dependencies mx(t)
(which changes sign during the switching) and mz(t)a r e
drawn in green. But, the (numerous!) sign changes of mx(t)
in the interval τ≈18–19 ns clearly do not correspond to
any real switching process. 3D representation of the corre-sponding piece of the magnetization trajectory, marked in redin Fig. 4(c), demonstrates that these sign changes of m
xare
due to the so-called out-of-plane (OOP) precession. By thisprecession kind the magnetization rotates in the high-energyregion of the energy landscape (because /bardblm
z/bardblis relatively
large), so that during this process no real switching betweenthe energy minima occurs. Hence, in Fig. 4during the time
interval 17 /lessorequalslantτ/lessorequalslant20 ns only one real switching is observed.
To distinguish between true and false switchings, one could
in principle perform the analysis of “candidate” cases, i.e.,events when the sign change of m
xhas been detected, using
the time dependencies of other magnetization projections.For example, for the particular case shown in Fig. 4,t h e m
z
projection does not change its sign during the whole time
interval marked in red, indicating that the magnetization pre-cession takes place only on one side of the easy plane ofthe nanoelement ( m
z/lessorequalslant0), meaning that the OOP precession
144419-6EV ALUATION OF THE SWITCHING RATE FOR MAGNETIC … PHYSICAL REVIEW B 102, 144419 (2020)
FIG. 5. Excitation of the macrospin before and its equilibration
after the true switching as mx(t) dependence (a) and 3D magnetiza-
tion trajectory (b) (the switching process itself is highlighted in dark
red). Only the switchings after which the macrospin spends in the
new basin more time than the equilibration time ( ≈3 ns) are counted
as true switching events.
(and not a true switching) is in process. However, consider-
ation of all particular cases would make the corresponding“projection-based” differentiating algorithm too complicatedand thus unreliable.
For this reason, we have adopted a more general method
to identify true switching events. The method is based onthe very definition of “switching” which is understood as atransition between two metastable states, whereby the systemunder study must spend sufficient time in the vicinity of eachstate in order to achieve a partial thermal equilibrium withincorresponding energy basins. If this is not the case, the switch-ing is considered as false.
The idea is illustrated in Figs. 5and 6. During a true
switching (Fig. 5) the magnetic moment is first excited by
thermal fluctuations so that it can overcome the energy barrier,and afterward the equilibration in the other energy well takesplace. This equilibration, as shown in Fig. 5(a), takes about
t
eq≈2 ns, whereby teqdepends mainly on the damping pa-
rameter λand slightly on the energy landscape near the energy
minima. Based on this finding, we consider a switching asbeing “true” when the time /Delta1t
wellspent by the system in the
target energy well after the switching is larger than teq.
To further support this idea, we have collected the his-
togram of time intervals between two subsequent sign
changes of mx(t). This histogram shows a huge peak for small
FIG. 6. (a) The region of the histogram of τswobtained from
LD simulations when alltime moments when mxchanges sign are
counted as switchings (note the log scale of the yaxis). (b) The region
of this histogram for t<1 ns. (c) A typical mx(t) dependence for a
false switching event [taken from the ρ(τsw) peak shown in (b)] and
(d) the corresponding 3D magnetization trajectory.
time intervals, as shown in Fig. 6(a) (note the logarithmic
scale of the yaxis!); this peak is presented in Fig. 6(b) in a
much higher resolution. The analysis of magnetization trajec-tories corresponding to the events attributed to this peak hasclearly demonstrated that these events typically represent an“excursion” of the magnetization toward the opposite energyminimum [see trajectories in Figs. 6(c) and 6(d)], and are
clearly “false” switchings. So, in further analysis we haveused the criterion /Delta1t
well>teqto identify real (true) switching
events in LD simulations.
In order to obtain a sufficiently accurate statistics, for
nanoelements with a=50 nm, we have simulated a col-
lection of 100 macrospins during tsim=150μs and for
elements with a=55 nm an ensemble of 400 macrospins
during tsim=5m s=5×106ns, applying the approach de-
scribed in our paper [ 23]. After subtracting false switching
events (using the criterion described above), we have ob-tained τ
LD
sw(a=50 nm) =2.36(±0.3)×103ns and τLD
sw(a=
55 nm) =1.3(±0.2)×105ns. Note that for a=50 nm the
switching time is ≈1.6 times and for a=55 nm about 1.4
times larger than the analytical values for these elements givenby (9). This difference is most probably due to the fact that the
approximation ( 9) does not take into “return” trajectories and
thus overestimates the transition rate.
IV . TIME-TEMPERATURE EXTRAPOLATION
METHOD (TTE)
The most straightforward idea which can be used to obtain
switching rates for systems with energy barriers unachievablefor standard LD simulations at room temperature is to per-form LD simulations at higher temperatures and extrapolateobtained switching rates to the temperature of interest. Fromthe quantitative point of view, this method (which we shallcall the time-temperature extrapolation method or TTE) em-ploys the assumption that the main temperature dependenceofτ
swis due to the exponential factor in the expression τsw=
τ0exp(/Delta1E/kBT) and all other dependencies on T, which may
be hidden in the prefactor τ0, are weak. This assumption
implies that we can try to overcome the inherent limitation
144419-7SEMENOV A, BERKOV , AND GORN PHYSICAL REVIEW B 102, 144419 (2020)
of the Langevin dynamics’ ability to model only systems with
relatively low barriers in the following way.
For a system with a high-energy barrier we should perform
LD simulations of the magnetization switching at several tem-peratures (all of them much larger than the temperature ofinterest), thus obtaining the dependence τ
sw(T) at relatively
high temperatures. Then we can use the analytical form τsw=
cexp(b/T) to extrapolate the obtained dependence τsw(T)
toward the desired low temperature (we note that a somewhatsimilar idea was used in [ 33] to obtain hysteresis loops in
a low-frequency external field at a low temperature by sim-ulating the loops in a high-frequency field at much largertemperatures).
The main physical deficiency of this idea is that by simu-
lations at elevated temperatures the system will spend most ofthe simulated time in regions of the energy landscape whichare inaccessible for this system at actual transition tempera-tures. However, as long as switching events remain relativelyrare (so that the system mostly stays in the vicinity of energyminima), we can hope that the accuracy of the extrapolatedresult is reasonable.
The precision of the proposed method crucially depends
on (i) the lowest temperature achievable in simulations forthe given energy barrier and (ii) on the statistical accuracy ofthe switching time values (obtained in LD simulations) whichwill be used in the subsequent extrapolation. For our nanoele-ments, the lowest temperature for which LD simulations havebeen performed was chosen from the requirement that duringthe simulation time of 1 ms approximately 500 switchingevents should occur. Corresponding lowest temperature in-creases from T
min=600 K for a=60 nm to Tmin=1800 K
fora=100 nm. For two smallest elements a=50 (55) nm
we have stopped to decrease TatTmin=400 (500) K in order
to check how the extrapolation results agree with direct LDsimulations available for T=300 K for these nanoelements.
For each temperature, LD simulations were performed
simultaneously for 100 nanoelements using our approachdescribed in [ 23]. For each macrospin size a, averaged
switching times obtained from these simulations τ
sw(T)
were fitted using the function τa(T)=caexp(ba/T) where
data points were weighted according to their statistical er-rors. An example of the corresponding fitting is shown inFig. 7.
FIG. 7. Simulated temperature dependence of the switching time
(open circles) and its fitting by the function τ=caeba/T(solid line)
for the macrospin corresponding to the nanoelement a=50 nm.
FIG. 8. Relation /Delta1E/kBT, obtained analytically using ( 6), com-
pared with the coefficients ba/Tobtained from the fitting of TTE
dependencies τa(T)=caexp(ba/T).
Interestingly, energy barrier /Delta1Eeff/kBT=ba/Tobtained
from this fitting was always somewhat smaller than the actualbarrier /Delta1E/k
BTevaluated from the analytical expression ( 6),
as shown in Fig. 8. As a consequence, for large barriers the
switching time evaluated by the TTE method is smaller thanthe analytical result ( 9), as it will be discussed in Sec. VII
Finally, switching times for all sizes at room temperature
were evaluated by extrapolating the fitting functions τ
a(T)t o
T=300 K as shown in Fig. 9by dashed green lines; switch-
ing times obtained this way are plotted in the same figure byred circles. Analysis of these results is postponed to Sec. VII,
FIG. 9. Extrapolation of switching time obtained for higher
temperatures using the LD dynamics (blue open circles) to T=
300 K (red open circles) for nanoelement sizes a=50–100 nm.
The extrapolated τswfor the macrospin with a=50 nm is τTTE
sw=
2.18(±0.2)×103ns, for a=100 nm it is τTTE
sw=1.2(±0.7)×
1023ns.
144419-8EV ALUATION OF THE SWITCHING RATE FOR MAGNETIC … PHYSICAL REVIEW B 102, 144419 (2020)
FIG. 10. Energy landscape with “bounce energy” contours Ebn.
where switching times obtained by all methods (analytical and
numerical) will be compared.
V . ENERGY BOUNCE METHOD
A. Basic idea and analysis of the original methodology
The main idea of the “energy bounce” algorithm [ 30]i st o
enable LD simulations of the switching rate for arbitrary high-energy barriers by forcing the point representing the systemstate in the phase space to climb an “energy ladder” fromthe energy minimum to the saddle point. For this purpose,the energy interval /Delta1Ebetween the minimum and the saddle
is divided into much smaller intervals (in our simulationswe have used δE=k
BT). Corresponding “splitting” of the
energy landscape is visualized in Fig. 10.
Now, we start LD simulations from the energy minimum
and continue until the energy histogram is computed with asufficient accuracy (the importance of this criterion will be ex-plained below). At the next stage, simulations start from somestate (achieved so far) with the energy E/greaterorequalslantE
min+δE=E(1)
bn
and all LD steps which would lead to a state with an energy
E<E(1)
bnare rejected, i.e., the system is allowed to move
only in its phase-space region defined by the condition E/greaterorequalslant
E(1)
bn. Again, these LD simulations run until the accumulated
energy histogram in this energy interval is sufficiently accu-rate (the duration of our LD simulations above each E
(i)
bnis
twalk=2000 ns). Then, at the next stage the minimal allowed
energy is again increased by δE(i.e., LD steps are rejected if
E<E(2)
bn=E(1)
bn+δE), etc.
This procedure is repeated until the bounce energy E(i)
bn
is only a few kBTlower than the saddle point, so that a
sufficient number of transitions over the saddle is observedby LD simulations above E
(i)
bn. In other words, for these values
ofE(i)
bnthe apparent escape time from the energy well A(see
Fig. 10)τ(i)
A,app=/Delta1t(i)
A/N(i)
swcan be computed with a reason-
able precision (here /Delta1t(i)
Ais the time spent in the well Aduring
LD simulations with E>E(i)
bn).
The key question here is how to connect the time /Delta1t(i)
A
spent by the system within Afor trajectory obeying the
condition E>E(i)
bn, with the time spent in this well for un-
constrained simulations. As the energy near the saddle can notbe achieved for unconstrained simulations within a reasonabletime, this connection can be established only recursively, i.e.,the time /Delta1t
(i)
Aspent in Aduring simulations with E>E(i)
bn
should be related to /Delta1t(i−1)
A during the previous stage (when
E>E(i−1)
bn). If we denote the corresponding proportionality
coefficient as Fi, i.e.,/Delta1t(i)
A=Fi/Delta1t(i+1)
A, then for the determi-
nation of the actual switching rate we obtain the expression
/Gamma1EnB
n=n−1/productdisplay
j=1FjN(n)
sw
/Delta1t(n)
A, (26)
where nis the total number of bounce energy levels used
to climb the path from the energy minimum to the saddlepoint.
Before proceeding to the detailed consideration of methods
for the computation of F
i, we emphasize that these coefficients
have to be determined with a very high precision, wherebysystematic errors are especially dangerous. This feature fol-lows directly from the basic expression ( 26), which involves
theproduct of all F
i, meaning that any systematic error by
their calculation will be exponentially amplified.
In the original version [ 30] it was suggested to determine
Fifrom the probability densities ρi(E|E>Ei
bn)≡ρi(E)t o
encounter the energy Eat the ith stage. Namely, in [ 30]i t
was assumed that the probability density ρi+1(E)i ss i m p l y
proportional to the corresponding probability density ρi(E).
This would mean that ρi(E)=Fiρi+1(E), where the “transfer
coefficient” Fidoes not depend on E(for E>E(i)
bn, i.e., if
the energy Eis accessible for both stages iandi+1). This
independence of FionEis the main assumptions in this
version of the energy bounce method. It can be verified onlyby the direct comparison of energy histograms obtained atstages iandi+1.
According to [ 30], the proportionality ρ
i(E)=Fiρi+1(E)
approximately holds except for the energies close to E(i+1)
bn.
Basing on this finding, and in order to increase the accuracy by
the calculation of Fi, Wang and Visscher [ 30] have suggested
to compute Fiusing the integral ratio
F(int)
i=/integraltext∞
E(i+1)
bn+/epsilon1offρi(E)dE
/integraltext∞
E(i+1)
bn+/epsilon1offρi+1(E)dE, (27)
where the lower limit of both integrals is larger than E(i+1)
bn
by an offset energy /epsilon1off(=kBTin [30]) to exclude the above-
mentioned histogram region near E(i+1)
bn.
Analyzing the energy histograms from our simulations, we
could confirm that the ratio ρi(E)/ρi+1(E) is approximately
constant, except for the regions near the bounce energies,where this ratio becomes singular [as shown in Fig. 12(b) ]
because ρ
i+1(E)→0f o r E→E(i+1)
bn(see Fig. 11). This
feature of accumulated histograms shows that the true ther-modynamic equilibrium is not achieved near the bounceenergies [we note that the density of state D(E) has no
zeros or singularities near E
(i)
bn]. In [ 30] it was suggested
that this is due to the finite size of the LD time step.Indeed, our studies have shown that the width of the dis-turbed area [where the accumulated energy histogram stronglydiffers from the true-equilibrium result, see Fig. 11(b) ] de-
creases when the LD step size becomes smaller. However,this decrease is very slow so that for any reasonable time
144419-9SEMENOV A, BERKOV , AND GORN PHYSICAL REVIEW B 102, 144419 (2020)
FIG. 11. (a) Energy histograms sampled at two subsequent val-
ues of the bounce energy. The offset /epsilon1offmarks the regions above
E(i+1)
bn where the histogram does not correspond to the thermody-
namic equilibrium due to the influence of the “hard” energy cutoff
atEbn. (b) Energy histogram sampled by simulations (yellow line)
compared to the exact analytical result ( 4) for the probability to
obtain the energy Ein a true equilibrium (blue line); the ratio of the
simulated histogram to the analytical result is shown by the greenline.
step the width of the out-of-equilibrium energy interval re-
mains substantial. To avoid this region, we have also usedthe offset energy /epsilon1
off=kBT(Fig. 11). Consequences of
the existence of this disturbed region for the switchingrate computed via the expression ( 26) will be discussed in
Sec. VII.
In addition to the problem discussed in the previous para-
graph, the ratio ρ
i(E)/ρi+1(E) exhibits a small systematic
decrease when the energy increases [see Fig. 12(b) ]. To study
whether this systematic decrease affects the computed switch-ing time, we have tested another method for the evaluation ofF
i, based as average ratio of histograms
F(av)
i=/angbracketleftbiggρi(E)
ρi+1(E)/angbracketrightbigg
Ei+1
bn+/epsilon1off<E<Ei+1max(28)
computed at the interval from the offset energy to the maximal
energy Ei+1
maxfor which ρi+1(E) becomes too small (typi-
cally less than 5% of its maximal value) so that the ratioρ
i(E)/ρi+1(E) becomes ill defined due to statistical fluctu-
ations of accumulated histograms. The product of Fi(see
Fig. 13) and switching times (shown in Fig. 17for two differ-
ent macrospin sizes) were very close to those obtained usingthe initial definition ( 27), showing the high robustness of both
methods for evaluating F
ifor a macrospin.
FIG. 12. (a) Energy histograms ρi(E) for subsequent stages of
the energy bounce method ( δE=kBT); (b) ratios ρ(i+1)(E)/ρi(E)
for some histogram pairs (for the macrospin with a=50 nm).
B. Alternative method to define transition coefficients
Unfortunately, the energy bounce algorithm based on
the evaluation of transfer coefficients Fiemploying energy
histograms (not to mention the assumption of their pro-portionality) cannot be used for full-scale micromagneticsimulations, where other energy contributions, in addition tothe shape anisotropy energy present for a macrospin, playan important role. The major problem is that the heightof an energy barrier in typical magnetic systems is deter-mined by either the magnetocrystalline anisotropy E
anor
the magnetodipolar energy Edip(which is responsible for the
shape anisotropy introduced ad hoc in the macrospin ap-
proach), whereby the energy itself is largely determined bythe exchange stiffness energy E
exch. The latter contribution is
especially high by simulations including thermal fluctuations
FIG. 13. (a) Product of coefficients Fias the function of the
bounce energy for various methods to evaluate Fi. (b) Ratios of the
products F(int)
iandF(av)
ito the product of F/Delta1t
i(for the macrospin with
a=100 nm).
144419-10EV ALUATION OF THE SWITCHING RATE FOR MAGNETIC … PHYSICAL REVIEW B 102, 144419 (2020)
(what is mandatory for studies of thermally activated switch-
ing), and may exceed both EanandEdipby several orders of
magnitude.
This feature of Eexch makes the usage of histograms of
the total energy completely impractical because the energy ofinterest, e.g., E
dipin case of shape-anisotropic particles, would
represent only a tiny contribution to this (noisy!) histogram.Further, the analysis of histograms of E
diponly would also
be not really helpful because in a strongly interacting systemno general statements concerning the statistical distributionof some part of the total energy (like the existence of theBoltzmann distribution) can be made, not to mention someproportionality assumptions like those used in [ 30].
For this reason, we suggest to use a qualitatively different
method to compute the coefficients F
i, which employs our def-
inition of Fias proportionality coefficients between the time
interval /Delta1t(i+1)
Aspent in Aduring simulations with E>E(i+1)
bn
and the corresponding interval /Delta1t(i)
Aduring the ith stage (when
E>E(i)
bn), i.e.,
F(/Delta1t)
i=/Delta1tA/parenleftbig
E>Ei+1
bn+/epsilon1off/parenrightbig
/Delta1tA/parenleftbig
E>Ei
bn+/epsilon1off/parenrightbig. (29)
Results of simulations where this definition of Fihas been
used turned out to be in a very good agreement with the orig-inal method ( 27) and its modification ( 28) for all macrospin
sizes studied in this paper, as shown in Fig. 13on an example
fora=100 nm.
The advantages of this method are twofold: (i) it is very
simple and much faster than histogram-based methods be-cause one does not need to accumulate energy histogramswith the high accuracy required for the precise determinationofF
i, and (ii) it can be applied to systems, where only one
contribution to the total energy should be monitored, no matterwhat the distribution of this energy term looks like. Usinga slightly modified definition ( 29)o f F
i, we could expand
the energy bounce method toward full-scale micromagneticsimulations using the magnetodipolar energy of the spatiallyaveraged nanoelement magnetization as the energy of interestentering ( 29). Corresponding results, being out of scope of
this publication, will be reported elsewhere.
Next, the problem how to determine another key quantity
in (26), the number of “true” switchings N
(n)
swover the barrier
when the system stays above the bounce energy level E(n)
bn,
should be considered. The method described in Sec. IIIwhich
is based on the criterion /Delta1twell>teqis not applicable here
because no real thermal equilibration occurs after switchingdue to the artificial restriction imposed on the system energy(E/greaterorequalslantE
(n)
bn).
For this reason, we have decided to consider a switching as
being “true” if after changing sign of mx, the system completes
at least one precession cycle around the new equilibrium
orientation of the magnetic moment.
This criterion was supported again by the analysis of his-
tograms of time intervals between subsequent sign changesofm
x, which always look like the example shown in Fig. 14:
a large peak at very small time intervals followed by smallerbut well-distinguished peaks for larger /Delta1t’s. The visualization
of magnetization trajectories corresponding to these peakshas shown that the first peak corresponds entirely to magne-
FIG. 14. Histogram of switching times for the macrospin with
a=70 nm for the bounce energy near the energy barrier ( Ebn=
/Delta1E−5kT). The first peak corresponds to the out-of-plane preces-
sion cycles [see Figs. 15(a) and15(b) ], so that these events are not
counted as switchings
tization “excursions” toward the opposite energy minimum,
where in most cases one cycle of the OOP precession isaccomplished [see Figs. 14(a) and14(b) ]. The next peaks con-
tained real switching events, where the number of precessioncycles around the energy minimum was equal to the sequencenumber of corresponding peak in the histogram (if the firstpeak is not counted) [see an example in Figs. 14(c) and14(d) ].
For these reasons, the switching was considered as being true,if the time spent in the energy basin after switching exceededthe time separating the OOP peak and the next peak on thehistogram ρ(/Delta1t
well); the corresponding threshold is shown in
Fig. 14by the red dashed line.
The remaining question is how to choose the total num-
ber of energy bounce levels nwhich is best suited for the
switching rate computation. This question is briefly addressedin [30], but a more detailed discussion is clearly necessary.
Namely, the stability of the evaluation of /Gamma1
EnBusing ( 26)a s -
sumes the existence of a delicate balance between the productofF
i’s and the number of switching events N(n)
swobserved dur-
ing LD simulations above the bounce energy E(n)
bn. Whereas
the product of Fi’s exponentially decreases with n, because
Fi<1 according to its definition (see Fig. 13), the number of
switchings N(n)
swshould exponentially increase with nbecause
we approach the saddle point. From the analytical point ofview, these two tendencies should exactly compensate eachother, providing the same answer for /Gamma1
EnBno matter how
many bounce levels we use.
However, in real simulations with the limited twalkfor each
E(i)
bna sufficiently large number of switchings ( Nsw>100)
necessary to establish the exponential trend N(n)
sw∝exp(n)
with a sufficient accuracy (Fig. 16) is observed only for high
bounce energies E(i)
bn/greaterorequalslant/Delta1E−5kT. On the other hand, the ith
bounce energy level should not be too close to the energybarrier because otherwise the very concept of switching asa rare transition over the barrier becomes invalid. These twoconditions leave a relatively narrow window of bounce en-ergies where we really have N
(n)
sw∝exp(n), as demonstrated
in Fig. 16. Only in this interval of Ebnthe switching time
τEnB
sw=1//Gamma1EnB
n[see ( 26)] is approximately independent on
144419-11SEMENOV A, BERKOV , AND GORN PHYSICAL REVIEW B 102, 144419 (2020)
FIG. 15. Typical mx(t) dependencies and 3D magnetization tra-
jectories for false (a), (b) and true (c), (d) switchings when Ebnis
close to the energy barrier. Events shown on (a) and (b) correspond to
the first peak and on (c) and (d) to the second peak on the histogramshown in Fig. 14.
the number of the bounce level n(see two examples in Fig. 17,
where the plateaus suitable for the determination of τsware
explicitly marked). These plateaus should be determined man-ually, making the application of the whole method rathernontrivial.
Further, in order to improve the statistics in determination
ofN
(n)
sw,w eh a v es e t twalk=500 ns for Ebn</Delta1E−5kBT, and
increased twalkto 105ns for Ebn/greaterorequalslant/Delta1E−5kBT.A tt h es a m e
time, the bounce energy step in this interval was decreased toδE=0.5k
BT.
Comparison between switching times obtained using dif-
ferent versions ( 27)–(29) for the evaluation of transfer
coefficients is given in Fig. 18. Overall, the agreement be-
tween all three versions can be considered as being fairlygood: we emphasize here that computed switching times covermore than 20 orders of magnitude, so that they had to bedivided by the exponential factor exp( /Delta1E/k
BT) to enable
a meaningful comparison between them on a single plot.Among all versions, our method ( 28) provides the best agree-
ment with the results of LD simulations available for smallbarriers. Switching times computed according to the moreuniversal method ( 29) (yellow curve) lie systematically some-
what lower than for other two versions (compare to Fig. 13).
However, this difference becomes smaller than statistical er-rors when the energy barrier increases (for /Delta1E/k
BT/greaterorequalslant30),
FIG. 16. Number of switchings as the function of the bounce
energy for the macrospin with the long axis a=100 nm.
FIG. 17. Switching times as functions of the last bounce energy
E(n)
bnfor the macrospin with a=50 nm (a) and with a=100 nm
(b) used for calculation of τswvia ( 26). Different line colors corre-
spond to two approaches ( 27)a n d( 29) for calculating Fi. Plateau
which can be used to establish τsware marked with curly brackets.
Dashed lines show the energy barriers /Delta1E.
i.e., this energy bounce version is clearly applicable for the
most interesting region of energy barriers.
The relation between switching times obtained with the
energy bounce method and other methods (analytical and nu-merical) for all macrospin sizes studied here will be discussedin Sec. VII.
VI. FORWARD-FLUX SAMPLING (FFS)
The forward-flux sampling method was initially suggested
as a method to evaluate switching rates between different
FIG. 18. Average switching time [divided by exp( /Delta1E/kBT)f o r
the presentation clarity] obtained from the three approaches ( 27)–
(29) used to compute τswin the energy bounce method as the function
of the energy barrier.
144419-12EV ALUATION OF THE SWITCHING RATE FOR MAGNETIC … PHYSICAL REVIEW B 102, 144419 (2020)
FIG. 19. Illustration of FFS method. Transition between wells A
andBover interfaces λi.
metastable configurations of complex molecules in biochem-
istry [ 24]. In principle, FFS can be adopted to any biological,
chemical, or physical applications where transitions rates overhigh-energy barriers have to be evaluated, including micro-magnetic problems (see, e.g., [ 29]).
A. General methodology of FFS
The idea of FFS can be understood from Fig. 19.B a s i n s
A and B (in the corresponding system coordinate space) sur-rounding the two corresponding metastable states of interestare confined by the interfaces λ
AandλB. Intermediate inter-
facesλi,i=1,..., n, are constructed in-between λAandλB
so that transitions between two the subsequent interfaces iand
i+1 can be expected during LD simulations of the system
within a reasonable time.
LD simulations are then started from the state mx=+ 1
and thermalization within the basin Ais carried out (i.e.,
simulations are performed until the average energy does notexhibit any systematic trend). Afterward, the flux per unit timeout of the basin Ais computed as the relation
/Phi1
A=NA→0//Delta1tA, (30)
where NA→0is the number of times when the system tra-
jectory coming from the basin Ahas reached (crossed) the
interface λ0during the simulation time interval /Delta1tA. System
states corresponding to these N0crossings are saved as poten-
tial starting states for the next stage.
Next, M0trial trajectories are started from the states chosen
randomly out of the set of above-mentioned N0saved states
on the interface λ0. If a trial trajectory returns into the basin
A, it is disregarded. If such a trajectory reaches the interface
λ1, the system state corresponding to this crossing point is
saved. If the total number of these crossing events is N1, then
the conditional probability that a trajectory starting from theinterface λ
0will reach the interface λ1isp(λ1|λ0)=N1/M0.
Repeating the same procedure starting from the subsequent
interfaces, we can then compute the required transition ratestraightforwardly as
/Gamma1
FFS=/Phi1Ap(λB|λ0)=/Phi1An/productdisplay
i=0p(λi+1|λi), (31)
where λn+1=λB; here, we have used the chain rule stating
that the conditional probability p(λB|λ0) equals to product
of corresponding conditional probabilities that a trajectorywill reach the interface λ
i+1when having started from theinterface λi[p(λi+1|λi)=Ni+1/Mi]. In our simulations which
results are presented below, we have used Natt=500 attempts
for each macrospin size and Mi=500 trial trajectories for
starting from each interface within the given attempt.
B. Positioning the interfaces based on the energy considerations
The FFS method as such does not contain any adjustable
parameters like, e.g., the offset energy in the energy bouncemethod. The procedure described above leads to the unbiasedestimation ( 31) of the escape rate. Hence, the primary question
is how to maximize the efficiency of FFS, meaning how tominimize the statistical error of the computed escape rate forthe fixed amount of the computer time spent by calculations.
This problem has been analyzed in details in several
publications [ 26,27] treating FFS in general, i.e., without a
reference to any specific physical system. This analysis hasled to the intuitively expected result that the best efficiency ofFFS is achieved when the flux between the two subsequent in-terfaces M
ip(λi+1|λi) is constant “along” the system, in other
words, does not depend on the interface number. Taking intoaccount that the number of trial “shots” from each interfaceis usually the same, we arrive at the statement that in order tominimize the statistical error, we should construct the set ofinterfaces so that the transition probability p
i≡p(λi+1|λi)=
const.
Several methods for the construction of the corresponding
set{λi}have been suggested [ 26,27]. All these methods are
iterative and provide some recipes how to shift the interfaces{λ
i}based on the transition probabilities piobtained on this
set.
In our case, a much simpler solution is possible. We con-
sider the escape of a physical system over an energy barrier,and thus have to our disposal the Boltzmann distribution p∝
exp(−E/k
BT) of the probabilities to find a system with an
energy Eat the temperature T. Hence, we can position the
interfaces employing the idea that the transition probabilitybetween the two subsequent interfaces is roughly proportionalto the energy difference between them: p
i∝exp[( Ei+1−
Ei)/kBT]. This relation is not exact, as there can be small
deviations due to the dependence of the density of systemstates on the system energy, but this correction is usually smallcompared to the exponential dependence of the probability onthe energy difference.
Using this proportionality, we introduce for the “uphill”
path the set of interfaces, which are equidistant in the energy
space . Namely, we first define the boundary λ
Aof the basin A
(from which we start the simulation) by the energy E(λA)=
Emin+kBT. Then we place the interface λ0used for the flux
calculation ( 30) one kBThigher: E(λ0)=E(λA)+kBT.F i -
nally, we place the uphill interfaces λi(i=1,..., n) so that
Eup(λi)≡Eup
i=E(λ0)+iδEif, where the number of inter-
faces nis chosen so that (i) the last uphill interface is placed
in the vicinity of the saddle point, but slightly beyond it, sothat Eup
n≈Esad=Emin+/Delta1E, whereas mx(λn)<0 and (ii)
the energy difference between the interfaces δEif≈kBT.
The positioning of interfaces on the downhill path is less
important because the flux toward the basin B after passingthe saddle point is large, so that corresponding conditionalprobabilities rapidly tend to 1.0. Hence, we use here only two
144419-13SEMENOV A, BERKOV , AND GORN PHYSICAL REVIEW B 102, 144419 (2020)
FIG. 20. Conditional probability pas the function of the inter-
face energy Efor the macrospin with a=50 nm (energy barrier
/Delta1E≈9kBT), obtained for 500 attempts and Ni=500 starting points
from each interface
additional interfaces with the energies Edown
1=Esad−kBT
andEdown
2=Esad−3kT.
Placing of interfaces in the energy space requires a
special discussion because usually the interfaces are posi-tioning in the coordinate space {x}of the studied system.
From the mathematical point of view, assignment of inter-faces in the energy space can be considered as a specificform of placing coordinate-based interfaces with coordi-nates defined via an implicit function E
if=Eif{x}. In our
specific case where the energy is given by the simpleexpression ( 1), this implicit function, together with the re-
lation /bardblm/bardbl= 1, defines closed ellipselike contours C
yxm2
y+
Czxm2
z=Eif/2πm2
sV,mx=± (1−m2
y−m2
z)1/2on the unit
sphere. The plus (minus) signs before the mxprojection cor-
respond to interfaces on the uphill (downhill) path. In case ofmore complicated systems, e.g., in full-scale micromagneticsimulations, the simple recipe of placing interfaces using thetotal energy does not work for the same reason as the usage ofthis total energy as energy bounce intervals (see discussion inthe Sec. VB). Corresponding extension of the interface posi-
tioning method will be discussed in the upcoming publication.
Using our methodology for the interface positioning, we
have introduced another optimization which strongly reducesthe total computation time. In the standard FFS version, thetrajectory is abandoned (the attempt is considered as failed),when after having started from some interface λ
i, it returns
to the initial basin A. We abandon a trajectory already when
the corresponding energy drops below E(λi)−5kTbecause
in this case it is exponentially unlikely that this trajectory everclimbs above the interface λ
i. For the highest-energy barrier
studied here ( /Delta1E≈60kBT), this optimization leads to ≈4×
acceleration of simulations.
An example for the dependence of the transition probabil-
itypibetween the interfaces on the interface number i(in
fact, on the interface energy Ei) is shown in Fig. 20. It can
be seen that for the uphill interfaces this probability is indeednearly independent on E
i, thus ensuring the smallest possible
statistical error by calculating the switching rate.
Switching times calculated using the FFS modified as de-
scribed above are presented in Fig. 21and will be discussed
in the next section.
FIG. 21. Switching times in dependence on the macrospin size
computed by all analytical and numerical methods (a) and ratio of
switching times for all methods to the switching time obtained in the
analytical approximation ( 9).
VII. RESULTS AND DISCUSSION: COMPARISON OF
ANALYTICAL AND NUMERICAL METHODS
Results for the switching time dependencies on the
macrospin size (long ellipse axis a) obtained with all an-
alytical and numerical methods presented in this paper arecollected in Fig. 21. First, we point out that in the interval
of energy barriers 9 </Delta1E/k
BT<70 studied here, switching
times span the interval of more than 20 orders of magnitude(from≈2μst o≈30 million years). For all methods τ
swgrows
(at least approximately) proportional to the relation /Delta1E/kBT,
so that the difference between τswmeasured by various meth-
ods is barely visible when τswis plotted as the function of size
[Fig. 21(a) , logarithmic scale].
For this reason, in Fig. 21(b) we have plotted the ratio
τsw/τan
swof switching time obtained by different methods to
the corresponding time calculated using the analytical ap-proximation ( 9), which is valid for /Delta1E/greatermuchk
BTand should
be applicable for arbitrary damping. This way we eliminatethe exponential dependence of τ
swon the energy barrier (or,
equivalently, on the long axis a), enabling the meaningful
comparison of various approaches.
First of all, we note a remarkable coincidence of the Arrhe-
nius approximations ( 5)–(8) with the more general analytical
result ( 9) in the whole range of switching times: τArr
sw/τan
sw≈1
[see the blue line in Fig. 21(b) ]. This agreement is due to
the fact that for our system the product of damping α=0.01
and the ratio 10 </Delta1E/kBT<60 lies in the range 0 .1<
α/Delta1E/kBT<0.6. As stated in Sec. II C, it is this product (and
144419-14EV ALUATION OF THE SWITCHING RATE FOR MAGNETIC … PHYSICAL REVIEW B 102, 144419 (2020)
not the damping value αby itself) which governs the transition
between various damping regimes. Hence, the values of theparameter which controls the transition from the low to thehigh damping regime lie for our macrospins in the interme-diate region, where a good agreement between the simpletransition state theory (Arrhenius law) and the sophisticatedanalytical result ( 9) is indeed expected (see, e.g., Fig. 9in [9]).
Next, we discuss the relation between switching times
obtained by different numerical methods and the analyticalapproximation ( 9).
For relatively small energy barriers ( /Delta1E/k
BT/lessorequalslant15),
where a comparison with straightforward LD simulations isstill possible, all numerical methods agree with LD resultswithin the statistical errors of the latter (only the TTE resultis slightly below the LD value). Further, all numerically com-puted switching times for these small barriers are larger thanthe analytical ones ( τ
num
sw/τan
sw>1f o r a/lessorequalslant55 nm, see Fig. 21).
This relation is in accordance with the well-known featureof analytical approximations: they overestimate the transitionrate (thus underestimating the switching time) because theydo not take into account the possibility that a system trajec-tory can return to the initial basin A shortly after crossingthe saddle (i.e., without visiting the basin B) [ 9]. Note that
these “back-hopping” events should not be mixed up with theout-of-plane precession analyzed in Sec. III.
When the energy barrier increases, results of numerical
methods exhibit considerably different trends.
Time-temperature extrapolation method. Relation of
switching times obtained via TTE to analytically computedtimes decreases with increasing /Delta1E, becomes smaller than
1.0 for /Delta1E/k
BT/greaterorequalslant20, and drops to τTTE
sw/τan
sw≈0.1f o r
the largest particles studied here with a=90 and 100 nm
(/Delta1E/kBT>50).
From the “technical” point of view, this decrease is due to
the fact that “effective” energy barriers obtained by the expo-nential fitting of TTE switching times (computed by highertemperatures) are systematically lower than actual barriers,and this difference increases with the barrier height, as shownin Fig. 8. The most probable physical explanation of this
behavior is that for larger energy barrier LD simulations inthe TTE method have to be conducted by higher temperatures,so that magnetic moments precess in the higher-energy rangethan by the room temperature. In this energy range the cur-vature of the energy landscape (i.e., the density of states) isconsiderably different from the curvature near the bottom ofthe energy minimum, which may result in a lower “effective”energy barrier.
Still, we point out that this conceptually very simple (so
that it can be easily extended to full-scale micromagnetics)and relatively fast method performs surprisingly well: In theinterval of τ
swcovering more than 20 orders of magnitude,
TTE switching times τTTE
sw differ in the worst case only by
one order of magnitude from results obtained by much moresophisticated methods.
Energy bounce method. For this method, relation of its
switching times to the analytical ones also decreases withthe energy barrier, although much slower than for TTE.Still, the ratio τ
EnB
sw/τan
swdrops below unity for /Delta1E/kBT/greaterorequalslant30
and achieves the value ≈0.5f o r a=100 nm ( /Delta1E/kBT≈
60). Taking into account that the switching time computednumerically should be larger than τan
sw(see the explanation
above), the reason for this systematic decrease of the ratioτ
EnB
sw/τan
swshould be found.
In the energy bounce expression for the switching rate ( 26),
the number of switching events N(n)
swat the nth stage of
the method is determined using the same criteria as for thestraightforward LD simulations without the bounce energy.Hence, the only possible source of the systematic underes-timation of the actual switching time in the energy bouncealgorithm is the systematic error by the computation of thetransition factors F
i.
To explain the appearance of such deviation by computing
Fi, we remind that these factors are evaluated using either
the ratio of energy histograms obtained for different bounceenergy levels E
(i)
bn(in the initial version) or the ratio of times
spent above these levels (in our version). In both versions,
the interval between Ebnand Ebn+/epsilon1offwhere the system
equilibrium is strongly disturbed is excluded (see Fig. 11)i n
order to compute these ratios as correct as possible.
However, in spite of the exclusion of this interval, the
introduction of artificial energy levels Ebn(and the prohibition
to visit the phase space with E<Ebn) still leads to systematic
errors by the computation of Fi’s. The reason for these errors
is that the true thermal equilibrium is disturbed for all ener-
gies above Ebn. This perturbation can be demonstrated using
thenormalized probability histograms shown in Fig. 11(b) .
Here, it can be seen that for E>Ebn+/epsilon1off, the probability
ρ(E|E(i)
bn) is always larger compared to the true-equilibrium
distribution ρ(E) because for energies close to E(i)
bn, the energy
bounce histogram is smaller than the actual ρ(E). This sys-
tematic deviation is different for different Ebnlevels due to the
energy dependence of the system density of states D(E) (see
Fig. 2). Hence, the coefficients Ficomputed as ratio of any
quantities derived from system trajectories above Ebn+/epsilon1off
also exhibit systematic deviation from the correct transfer
coefficients.
The effect considered above is small because the main
energy dependence of the probability p(E) is due to the
Boltzmann exponent exp( −E/kBT), and not to the depen-
dence D(E). Still, this small effect, accumulated in course of
subsequent multiplications of Fi’s, most probably leads to the
above-mentioned systematic underestimation of the switchingtime by the energy bounce method.
In spite of this underestimation, the energy bounce method
performs considerably better than the TTE method, leading
for the highest studied barrier to the underestimation of τ
sw
only by two times compared to the analytical approximation
and three times to the forward-flux method.
Forward-flux sampling. Among all numerical methods con-
sidered here, the FFS is the only one which uses neitherany far-reaching extrapolation from high- Tresults nor any
artificial boundaries restricting the system motion in the phasespace. All LD simulations in frames of FFS are conductedfor an undisturbed system, so that the method should be asreliable as the LD itself. The only problem of FFS is the re-quirement to achieve a high accuracy by the evaluation of thetransition probabilities between the interfaces p(λ
i+1|λi). As
explained above, we have solved this problem by positioninginterfaces in the energy space and thus could obtain switching
144419-15SEMENOV A, BERKOV , AND GORN PHYSICAL REVIEW B 102, 144419 (2020)
times with a very low statistical error, as demonstrated in
Fig. 21(see yellow lines).
Switching times computed by FFS coincide with the LD
results for low-energy barriers (within the statistical errors ofthe latter method). Further, τ
FFS
swlie systematically above the
analytical approximation ( 9), as it should be according to the
consideration of back-hopping trajectories (see above).
The significance of the back-hopping processes for our
system can be estimated from Fig. 20. Here, it can be seen
that the probability to go downhill from the interface λ7(for
which we have already mx<0, so that this interface is slightly
beyond the barrier) is ≈90%, meaning that about 10% of
trajectories starting at this interface, go back to the initialbasin A. Further, probability to go downhill from the interface
λ
8is only slightly larger than 90%, so that again ≈10% of
trajectories go back from this interface to the basin A. Finally,
we recall that the interface λ7is already beyond the barrier, so
that some back hopping may occur between the separatrix andthis interface (note that the back-hopping probability is largerfor trajectories in the immediate vicinity of the saddle point).Hence, we can conclude that the fraction of back-hoppingtrajectories is significant (in any case much larger than 20%),which makes the systematic increase of the FFS switchingtime in Fig 21(b) over the analytical expression plausible.
Interestingly, the ratio τ
FFS
sw/τan
swis nearly constant ( ≈1.5)
for a very broad interval of switching times considered here.It might be an indication that for the macrospin model, thefraction of trajectories which return to the initial basin aftercrossing once the saddle point depends only weakly on theenergy barrier height.
VIII. CONCLUSION
In this paper we have studied the dependence of the switch-
ing time for a bistable biaxial magnetic particle in dependenceof its in-plane size, which translates into the dependence onthe energy barrier separating two energy minima. We have ap-plied two analytical methods (a simple transition state theoryleading to the Arrhenius law and the sophisticated approachbased on the Melnikov-Meshkov solution of the Kramersproblem for an arbitrary damping) and four numerical tech-niques (straightforward LD simulations, the time-temperatureextrapolation method, the energy bounce method, and theforward-flux sampling).
Analyzing the results obtained by analytical methods, we
have shown that the parameter which governs the transitionfrom the low damping to the high damping regime is not thedamping λin the LLG equation by itself, but rather the prod-
uct of λand the reduced energy barrier /Delta1E/k
BT. Taking intoaccount that the damping for a typical magnetic material used
in applications is λ∼0.01 and the energy barrier required to
achieve a stability during a macroscopic time interval is /Delta1E∼
50kBT, we conclude that magnetization switching proceeds
usually in the intermediate damping regime λ/Delta1E/kBT∼1.
Our comparison of switching times obtained in the Arrheniusapproximation and in the Melnikov-Meshkov formalism con-firms this conclusion.
Comparison of numerical methods has shown that for low-
to-moderate energy barriers ( /Delta1E/lessorequalslant10k
BT) where direct LD
simulations are possible, results of all numerical methodsagree within statistical errors. However, when the energybarrier height increases, the relation of switching times ob-tained by the TTE and by the energy bounce methods toτ
an
swsystematically decreases (the decrease is slower for the
energy bounce method), so that for sufficiently high barriersthe analytically computed switching time becomes larger thanthe numerical one. We could show that this artificial trendis the consequence of physical principles the correspondingmethods are based on. Hence, the quality of results obtainedby the TTE and energy bounce method is limited.
For the forward-flux sampling, our recipe for choosing
the interfaces which are equidistant in the energy space (forthe evaluation of transition probabilities p
i) has led to nearly
interface-independent probabilities piwithout any a posteriori
optimization, assuring the high accuracy by the computationof switching times. Corresponding values τ
FFS
swcoincide with
LD results for low barriers and are higher than τan
swfor all en-
ergy barriers studied here, demonstrating that FFS representsa reliable technique for computing switching rate in magneticsystems, and that a very high accuracy can be potentiallyachieved by this method.
In this research, we have concentrated on the inherent
properties of various techniques to study the escape of mag-netic systems over energy barriers, and thus have performedour studies in frames of the macrospin approximation. Forreal applications, a full-scale micromagnetic framework isclearly necessary. The corresponding generalization of ourtechniques proposed in this paper, except of the TTE method,is highly nontrivial due to the contribution of other energyterms (mainly the exchange energy). This problem and itssolution will be discussed in details in the forthcoming publi-cation.
ACKNOWLEDGMENTS
Financial support of the Deutsche Forschungsgemeinschaft(German Research Society), DFG Project No. BE 2464 /18-1
is greatly acknowledged.
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144419-17 |
PhysRevB.95.184401.pdf | PHYSICAL REVIEW B 95, 184401 (2017)
Autoresonant magnetization switching by spin-orbit torques
Gyungchoon Go,1Seung-Jae Lee,2and Kyung-Jin Lee1,2,*
1Department of Materials Science and Engineering, Korea University, Seoul 02841, Korea
2KU-KIST Graduate School of Converging Science and Technology, Korea University, Seoul 02841, Korea
(Received 19 October 2016; revised manuscript received 14 February 2017; published 2 May 2017)
Autoresonance is a self-sustained resonance mechanism due to a driving force whose frequency monotonically
varies with time. We theoretically show that the autoresonance mechanism allows an efficient switchingof perpendicular magnetization by spin-orbit spin-transfer torques. We find that a threshold current for theautoresonant switching can be much smaller than that of conventional spin-orbit torque switching driven by a DCcurrent. Moreover, the suggested scheme allows fully deterministic switching without the help of any externalfield.
DOI: 10.1103/PhysRevB.95.184401
I. INTRODUCTION
Since Slonczewski and Berger’s seminal works [ 1,2],
numerous studies have been conducted on the spin-transfertorque [ 3–12], which is based on the transfer of spin angular
momentum from conduction electron spins to local magneti-zations. The spin-transfer torque offers a way to control themagnetization of a switchable layer with an electrical currentspin-polarized by a fixed ferromagnetic layer. As this switchingmechanism requires a current passing through both fixed andswitchable layers, it is realized by flowing an electrical currentperpendicular to the plane of layered structures (i.e., current-perpendicular-to-plane geometry). Together with the tunnelmagnetoresistance [ 13–17] as a reading scheme, the spin-
transfer torque provides the operation principle for magneticrandom access memories.
Recently, an alternative way to manipulate the magnetiza-
tion direction has been demonstrated in ferromagnet/heavy-metal bilayer structures [ 18,19]. Because of bulk [ 19–22]
or interfacial spin-orbit coupling effects [ 18,23–30], or both
[31–33], an in-plane current passing through bilayer structures
is converted into a spin current flowing perpendicular to thefilm plane, which exerts a torque, called spin-orbit torque, onlocal magnetization of a ferromagnetic layer. The spin-orbittorque consists of two vector components:
T
D=γcJˆm×[ˆm×(ˆj׈z)], (1.1)
TF=γdJˆm×(ˆj׈z), (1.2)
where TDis a damping-like torque, TFis a field-like torque,
γis the gyromagnetic ratio, ˆmis the unit vector along the
magnetization, ˆjis the unit vector along the current direction,
ˆzis the direction in which the structural inversion symmetry
is broken (i.e., thickness direction), and cJanddJare the
effective spin-orbit fields corresponding to damping-like andfield-like torques, respectively.
Spin-orbit torque switching of perpendicular magnetiza-
tion, which is of technological relevance, has been theoreticallyinvestigated considering the damping-like torque only [ 34,35]
and both torque components [ 36]. These theoretical studies
*kj_lee@korea.ac.krtogether with experimental ones [ 37,38] have found that the
switching current density for the spin-orbit torque is muchlarger than that for the conventional spin-transfer torque inthe current-perpendicular-to-plane geometry [ 39]. This large
switching current density of the spin-orbit torque switchingscheme is apparently detrimental for practical applications. Inthis work, as one of possible attempts to reduce the switchingcurrent, we theoretically investigate the autoresonance mech-anism [ 40] based on the spin-orbit torque.
Autoresonance is a self-sustained resonance mechanism
due to an external perturbation which has a monotonicallydecreasing (or increasing) frequency. Unlike usual resonant ex-citations with a fixed frequency, the phase of oscillator for theautoresonance is locked to that of an external perturbation. Thephase-locked excitation enables a highly efficient excitation ofthe oscillator even with a low-amplitude external perturbation.The autoresonance mechanism is applicable to magnetizationswitching: Klughertz et al. reported autoresonant magnetiza-
tion switching using time-dependent external magnetic fields[41,42]. In this paper, we theoretically study the autoresonant
magnetization dynamics driven by time-dependent spin-orbittorques. Our results show that the switching current densityfor the autoresonance mechanism can be remarkably reducedas compared to that of time-independent spin-orbit torques.
The paper is organized as follows. In Sec. II, we describe
the basic principle of autoresonant magnetization dynam-ics. In Sec. III, we provide a theoretical analysis of the
autoresonant magnetzation dynamics driven by spin-orbittorques. In Sec. IV, we show numerical simulation results
of the autoresonant magnetization excitations. In Sec. V,w e
conclude with a brief summary and discussion.
II. BASIC PRINCIPLE OF AUTORESONANT
MAGNETIZATION DYNAMICS
We consider a ferromagnet/heavy-metal bilayer system
where the ferromagnetic layer has perpendicular magneticanisotropy. Macrospin dynamics for this configuration isdescribed by the Landau-Lifshitz-Gilbert (LLG) equationincluding spin-orbit torque terms:
dˆm
dt=−γˆm×HK,effmzˆz+αˆm×dˆm
dt
+γcJˆm×[ˆm×(ˆj׈z)]+γdJˆm×(ˆj׈z),(2.1)
2469-9950/2017/95(18)/184401(7) 184401-1 ©2017 American Physical SocietyGYUNGCHOON GO, SEUNG-JAE LEE, AND KYUNG-JIN LEE PHYSICAL REVIEW B 95, 184401 (2017)
driving frequency
resonant frequency
tω(t)
tω(t)
tω(t)
(a) (b) (c)
FIG. 1. The autoresonance mechanism for different chirp rates. (a) An appropriate chirp rate makes an efficient excitation of magnetization.
(b) No autoresonance occurs for a too high chirp rate. (c) A low chirp rate results in a longer switching time.
where ˆm=(mx,my,mz),HK,eff [=(2K/M s−4πMs)≡
2Keff/Ms] is the effective perpendicular anisotropy field, K
stands for the magnetocrystalline anisotropy constant, Ms
is the saturation magnetization, αis the Gilbert damping
constant, cJ[=(¯h/2e)(θSHJ/M stF)] is the damping-like spin-
orbit effective field, dJ[=−β(¯h/2e)(θSHJ/M stF)] is the
field-like spin-orbit effective field, θSHis the effective spin
Hall angle, tFis the thickness of the ferromagnetic layer,
Jis the current density, and βis the ratio of dJtocJ.
From the precession torque term of Eq. ( 2.1), one finds
that the resonance frequency ω0of the system is γHK,effmz.
We note that ω0depends on mzand the resonance condi-
tion therefore changes as the magnetization switches froman equilibrium direction (i.e., m
z=+ 1) to the other (i.e.,
mz=− 1).
Following works of Klughertz et al. [41,42], we first
describe the basic principle of autoresonant magnetic ex-citation with an oscillating driving field with the angularfrequency ωand the chirp rate ξ(>0), e.g., c
J(t)=0 and
dJ(t)=d0cos(ωt−πξt2). For the autoresonant excitation,
we set the initial frequency of the chirped field to be abit higher than γH
K,eff, that is, the resonant frequency of
the initial magnetization (i.e., mz=1). Since the driving
frequency decreases with increasing t(i.e.,ξ> 0), the driving
frequency encounters the resonant frequency ω0at a time,
and the resonance starts. Because of the resonance, themagnetization excites rapidly and m
zdecreases accordingly,
which in turn results in a decreased ω0because ω0depends
onmz. At this moment, a small mismatch between the
driving frequency and ω0emerges. However, because the
driving frequency decreases monotonically with time, thismismatch soon disappears and the resonance restores again.Because of this repeated procedure (i.e., on-resonance →
off-resonace →on-resonance again), the time-average phase
of the magnetic excitation is locked to that of the driving field,called the autoresonance. Figure 1represents the autoresonant
magnetic excitations for different chirp rates. From Fig. 1, one
sees that there is an appropriate chirp rate for an efficientautoresonant excitation. If the chirp rate is too high, theautoresonance cannot occur [Fig. 1(b)]. If the chirp rate is
too low, the autoresonance occurs but the switching is delayed[Fig. 1(c)].
Therefore, the autoresonance mechanism with an appro-
priate chirp rate can reduce the threshold external field forthe magnetization switching. Considering spin-orbit torqueswitching where c
J/negationslash=0, it may also reduce the threshold
switching current compared to the case with time-independentspin-orbit torques since the autoresonant excitation maintainsthe resonance on average.
III. THEORETICAL ANALYSIS
In this section, we provide a theoretical analysis of
the autoresonance mechanism of magnetzation excitation inthe presence of both damping-like and field-like spin-orbit
torques. We note that our theoretical framework closely
follows those in Refs. [ 42,43].
We consider the circularly polarized AC current as
ˆj(t)=cosφ(t)ˆx+sinφ(t)ˆy,φ (t)=ωt−πξt
2.(3.1)
For a small damping ( α/lessmuch1), we rewrite Eq. ( 2.1)a s
dˆm
dt=−γˆm×{[HK,effmz−c/prime
J(mxcosφ+mysinφ)]ˆz
+(c/prime
Jmzcosφ+d/prime
Jsinφ+αHK,effmy)ˆx
+(c/prime
Jmzsinφ−d/prime
Jcosφ−αHK,effmx)ˆy}, (3.2)
where c/prime
J=cJ+αdJandd/prime
J=dJ−αcJ. Neglecting the
zcomponent of the oscillating field [ =c/prime
J(mxcosφ+
mysinφ)ˆz], which is irrelevant to the resonant excitation, we
have
dˆm
dt=−γˆm×{HK,effmzˆz+(c/prime
Jmzcosφ
+d/prime
Jsinφ+αHK,effmy)ˆx
+(c/prime
Jmzsinφ−d/prime
Jcosφ−αHK,effmx)ˆy}.
(3.3)
We introduce the dimensionless parameters as
˜HK,eff=γHK,eff
(2πξ)1/2,˜cJ=γc/prime
J
(2πξ)1/2,˜dJ=γd/prime
J
(2πξ)1/2,
τ=(2πξ)1/2t, ˜ω0=ω0/(2πξ)1/2, (3.4)
and complex variables
mx=A1A∗
2+A∗
1A2,m y=i(A1A∗
2−A∗
1A2),
mz=|A1|2−|A2|2, (3.5)
184401-2AUTORESONANT MAGNETIZATION SWITCHING BY SPIN- . . . PHYSICAL REVIEW B 95, 184401 (2017)
with|A1|2+|A2|2=1. With these parameters and variables,
we rewrite Eq. ( 3.3)a s
idA 1
dτ=1
2(˜ω0−2˜ω0|A2|2)A1+1
2[mz˜cJe−iφ+i˜dJe−iφ]A2
+iα˜ω0(|A1|2−|A2|2)|A2|2A1,
idA 2
dτ=−1
2(˜ω0−2˜ω0|A2|2)A2+1
2[mz˜cJeiφ−i˜dJeiφ]A1
−iα˜ω0(|A1|2−|A2|2)|A1|2A2. (3.6)
Introducing new complex amplitudes
¯A1=A1exp/parenleftbiggi
2/integraldisplay
˜HK,eff(τ)dτ/parenrightbigg
,
¯A2=A2exp/bracketleftbigg
−i/parenleftbigg
φ−i
2/integraldisplay
˜HK,eff(τ)dτ/parenrightbigg/bracketrightbigg
,(3.7)
and considering the weakly nonlinear excitation regime, i.e.,
¯A1≈1 and|¯A2|/lessmuch 1, Eq. ( 3.6) is further simplified as
idψ
dτ+(τ−|ψ|2+iλ/2)ψ=/bracketleftbigg/parenleftbigg
1−|ψ|2
˜ω0/parenrightbigg
μ−iν/bracketrightbigg
,
(3.8)
where ψ=(2 ˜ω0)1/2¯A2,μ=˜cJ(˜ω0/2)1/2,ν=˜dJ(˜ω0/2)1/2,
andλ=2α˜ω0. Equation ( 3.8) is a nonlinear Schrödinger-like
equation describing the autoresonance excitation with an
additional source term (1 −|ψ|2
˜ω0)μ, caused by the damping-like
spin-orbit torque. Without the additional term (i.e., μ=0), the
theoretical analysis for zero damping case gives the thresholdν
th
0/similarequal0.413 for the autoresonance [ 42].
In the following, we investigate the effect of damping-like
(μ) and field-like ( ν) torques on the autoresonant magnetiza-
tion excitation process. We note that the sign of the product μν
in experiments is usually negative in our convention [ 44,45].
In this paper, we thus focus on μν < 0 case and choose μ> 0
without loss of generality.
For zero damping case ( λ=0), decomposing Eq. ( 3.8)i n t o
real and complex parts, we have
˙a=−/parenleftbigg
1−a2
˜ω0/parenrightbigg
μsin/Phi1−νcos/Phi1,
˙/Phi1=τ−a2−/parenleftbigg
1−a2
˜ω0/parenrightbiggμ
acos/Phi1+ν
asin/Phi1,(3.9)
where ψ=aei/Phi1. When μ=0, Eqs. ( 3.9) are equivalent to
those describing the evolution of autoresonant pendulum withamplitude aand phase mismatch /Phi1between driving field and
excitation [ 43]. In terms of the oscillator action I≡a
2,w e
rewrite Eqs. ( 3.9)a s
˙I=− 2I1/2(μsin/Phi1+νcos/Phi1)+2I3/2
˜ω0μsin/Phi1,
˙/Phi1=τ−I−I−1/2(μcos/Phi1−νsin/Phi1)+I1/2
˜ω0μcos/Phi1.
(3.10)Using Eq. ( 3.10), we obtain
¨/Phi1=1+S/bracketleftbigg
2I1/2(μsin/Phi1+νcos/Phi1)−2I3/2
˜ω0μsin/Phi1/bracketrightbigg
−1
2˙I
I˙/Phi1, (3.11)
where
S=1−1
2I−3/2(μcos/Phi1−νsin/Phi1)−I−1/2
2˜ω0μcos/Phi1.
(3.12)
Henceforth, we consider the weak perturbation limit
(μ,ν/lessmuch˜ω0) for simplicity. We also assume that the system
comes in the phase-locked state ( /Phi1=/Phi10)a tt=τ0(<0) and
stays in this state for some finite time. By analyzing Eq. ( 3.10),
we find that /Phi10satisfies μcos/Phi10−νsin/Phi10=−/radicalbig
μ2+ν2.
Therefore, in the phase-locked state, Sis approximated as
S/similarequal1+1
2/radicalbig
μ2+ν2I−3/2. (3.13)
For the phase-locked state, we read from the second
equation of Eq. ( 3.10) that
I0−/radicalbig
μ2+ν2I−1/2
0=τ, (3.14)
where I0(>0) is the instantaneous equilibrium action which
increases with time (See Ref. [ 43] and references therein).
By using Eq. ( 3.13), we rewrite Eq. ( 3.11) in terms of the
equilibrium action I0as
¨/Phi1=−∂Vps
∂/Phi1−γeff˙/Phi1, (3.15)
where
Vps=−/Phi1+/parenleftBigg
2I1/2
0+/radicalbig
μ2+ν2
I0/parenrightBigg
(μcos/Phi1−νsin/Phi1),
(3.16)
andγeff=˙I0/(2I0).
Since the pseudopotential Vpshas both a /Phi1-linear term and
periodic terms (combination of trigonometric functions), itbehaves as a series of tilted wells [see Fig. 2(a)]. If the /Phi1-linear
term is smaller than the periodic terms, the potential well existsand the system is trapped there. As described in Ref. [ 43],
the existence of the potential well is the essential conditionfor the autoresonance. When this condition is satisfied, /Phi1
remains nearly constant and I
0grows without breaking the
phase-locking for a relevant time.
Let us find the threshold for being captured into the
autoresonance. By using the property of the trigonometricfunction, we rewrite Eq. ( 3.16)a s
V
ps=−/Phi1+μ/radicalbig
1+β2/parenleftBigg
2I1/2
0+μ/radicalbig
1+β2
I0/parenrightBigg
cos(/Phi1+δ),
(3.17)
where β=−ν/μ andδ=cos−1(1//radicalbig
1+β2).
From the slopes of linear and periodic terms in Eq. ( 3.17),
the necessary condition of the potential well existence isgiven as
˜μ/parenleftbig
2I1/2
0+˜μI−1
0/parenrightbig
>1, (3.18)
184401-3GYUNGCHOON GO, SEUNG-JAE LEE, AND KYUNG-JIN LEE PHYSICAL REVIEW B 95, 184401 (2017)
0 1 2 3 4 5 60
2
4
6Vps
Φμ = 0.2
μ = 0.5μ = 0.4μ = 0.3(a)
0 2 4 6 8 10 1204812
τI0μ = 0.29μ = 0.28
μ = 0.30μ = 0.27(b)
FIG. 2. (a) /Phi1dependence of pseudopotential Vpsforβ=1.
Forμ=0.2 (red dotted line) and μ=0.3 (blue solid line) the
potential well does not exist, whereas the potential well appears for
μ=0.4 (green dashed line) and μ=0.5 (purple dot-dashed line).
(b) Dynamics of I0forβ=1. For μ/greaterorequalslant0.3,I0monotonically
increases as τincreases. Although there is no potential well at μ=0.3
[see Fig. 2(a)], the autoresonance excitation occurs due to the inertia
effect (blue solid line). For (a), ˜I0=0.45 is used.
where ˜ μ=μ/radicalbig
1+β2. Differentiating the above condition
with respect to I0, we find the minimum value of I0to match
the condition Ic=˜μ2/3.
In order to obtain the threshold of μ, one needs to consider
the effect of inertia [ 43]. When the system slightly deviates
from the potential well existence condition [Eq. ( 3.18)],/Phi1
varies very slowly and I0increases accordingly (i.e., weak
resonance). If the pseudopotential well is established beforeloosing the weak resonance, the system can be trapped in thepseudopotential well. Taking into account this inertia effect,Eq. ( 3.18) is modified as
κ˜μ/parenleftbig
2I
1/2
0+˜μI−1
0/parenrightbig
>1, (3.19)
where κreflects the effect of inertia. Inserting Ic=˜μ2/3into
Eq. ( 3.19), we obtain the threshold for zero damping as
˜μth
0/similarequal/parenleftbigg1
3κ/parenrightbigg3/4
. (3.20)
Since it is difficult to fully solve the nonlinear equations ( 3.10),
we numerically obtain κ. By comparing Eq. ( 3.20) with the
numerical threshold value of Eq. ( 3.10), we obtain κ=1.08.
Thus we have
μth
0/similarequal0.413/radicalbig
1+β2. (3.21)The numerator of Eq. ( 3.21) is equivalent to the previously
known result [ 42]. Because we are dealing with the weak
excitation regime, the magnetization is forced by the vectorsum of damping-like torque ( μ) and field-like torque ( ν), which
is reflected by the coefficient 1 //radicalbig
1+β2.
Figure 2(b) shows the time evolution of I0forβ=1. The
system enters the autoresonance when μexceeds the threshold
(μth
0/similarequal0.292 for β=1). As shown in Fig. 2(a), there is no
potential well for μ=0.3. Due to the inertia effect, however,
the autoresonance excitation is allowed near this point (bluesolid line).
We next discuss the effect of damping on the autoresonant
spin-orbit torque switching. As the autoresonance is governedby the precession motion of magnetization, the damping tendsto disturb the autoresonant dynamics. As a result, the thresholdfor the autoresonant magnetic excitation increases with thedamping [ 42,43]. For a small damping (i.e., λ< 1),μ
thcan
be expanded as
μth=μth
0(1+pλ+qλ2), (3.22)
where the coefficients p=1.05 and q=0.83 are obtained by
numerical comparison between Eqs. ( 3.8) and ( 3.22). In terms
of the spin-orbit torque coefficient cJ, this corresponds to
cth
J/similarequal√
2(2πξ)3/4
γω1/2
0μth=√
2(2πξ)3/4
γ3/2H1/2
K,effμth. (3.23)
Equation ( 3.23) is the central result of our work.
Three remarks for Eq. ( 3.23) are in order. First, the threshold
value scales with ξ3/4, which is a representative characteristic
of the autoresonance phenomenon [ 40–43]. Second, the
obtained threshold is inversely proportional to H1/2
K,eff.T h i s
inverse proportionality is in contrast to conventional switchingmechanism driven by DC spin-transfer torque or spin-orbittorque, where the threshold current is proportional to H
K,eff
[3,4,34]. This feature would enable a significant decrease in the
threshold current for the autoresonant switching mechanismwhile keeping the thermal stability of magnetization. Third,Eq. ( 3.23) is valid only for a small damping. As we show
below, one has to numerically estimate the threshold for a highdamping.
As further analysis is difficult because of the complexity
of Eq. ( 3.16), we compute threshold AC currents for various
cases using numerical simulations in the next section.
IV . NUMERICAL SIMULATIONS
A. Single-domain nanomagnet at zero temperature
In this subsection, we consider the single-domain nano-
magnet without thermal fluctuations. We use parameters ofthe W /CoFeB structure in Refs. [ 46,47]:α=0.012,K
eff=
4.25×106erg/cm3,Ms=1240 emu /cm3. We assume γ=
1.76×107(Oe s)−1andξ=0.3×1018s−2. Figure 3shows
the numerically computed magnetization dynamics. We notethatm
zclosely follows the time-dependent change in the
angular frequency ω, which is a representative feature of
the autoresonant switching.
Figure 4(a) shows numerical results of the threshold cth
J
as a function of the damping α. In the low damping regime,
numerically obtained thresholds are in good agreement with
184401-4AUTORESONANT MAGNETIZATION SWITCHING BY SPIN- . . . PHYSICAL REVIEW B 95, 184401 (2017)
0 50 100 150 2001.0.50.0.51.
t(ns)mx
mzmy
ω(t)/ω 0
FIG. 3. Single-domain magnetization dynamics. Blue, green and
red (bold) lines represent mx,my,a n dmz, respectively. Purple line
represents the normalized angular frequency. In this plot, dJ=−cJ
(i.e.,β=1) is assumed.
theoretical ones [Eq. ( 3.23)]. We note that our theoretical
analysis is valid for the small damping case. There aretwo effects of damping. First, the damping enhances theminimum value of c
Jto be captured into the autoresonant
excitation. This is taken into account in our theoreticalanalysis [Eq. ( 3.22)]. Second, the damping interrupts the
phase-locked excitation. Therefore, for high damping, oncethe magnetization dynamics is captured into the phase-lockedexcitation, soon after it looses its phase-locking. This is notconsidered in our theoretical analysis. In the high dampingregime, c
th
Jis linearly proportional to α. Figure 4(b) shows the
dependence of cth
Jonβ(=−dJ/cJ). For a nonzero β, not
only damping-like torque but also field-like torque contributesto the autoresonant switching and c
th
Jtherefore decreases with
β. Figure 4(c) shows the chirp rate ( ξ) dependence of cth
J
and switching time. cth
Jdecreases with increasing ξand the
switching time shows 1 /ξdependence.
We note that the threshold cJfor the autoresonant spin-orbit
torque switching is on the order of 40 Oe (Fig. 4). On the other
hand, the threshold cJfor conventional DC spin-orbit torque
switching is about 3400 Oe [ 34,35] for the same parameter
set we use for numerical calculations of Fig. 4. Therefore,
the autoresonant switching is highly efficient to reduce theswitching current in comparison to the conventional DC spin-orbit torque switching. We also note that the autoresonantswitching process allows fully deterministic spin-orbit torqueswitching without help from an external field.
B. Micromagnetic simulation with thermal fluctuations
We use micromagnetic simulation to consider multiple
spins in a system at a finite temperature [ 48–51]. In this case,
the phase of each spin becomes randomized due to thermalfluctuations. For the autoresonant switching mechanism, suchphase randomization may disturb the resonance excitation.Therefore, it is important to check whether or not theautoresonant spin-orbit torque switching allows a reducedswitching current even for multiple spins subject to thermalfluctuations.
Based on micromagnetic simulations, we compute switch-
ing probabilities for a nanopillar sample with area π(15 nm)
2
and thickness 1.1 nm. We use following parameters: the0. 0.005 0.01 0.015 0.020204060
Simulation
Eq. (3.22)
αLinear fit(a)
c (Oe)Jth
0. 0.3 0.6 0.9 1.2 1.5020406080
β(b)
Simulation c (Oe)Jth
0 1 2 3 4 535404550
0306090(c)
c (Oe)Switching timeSwitching time (ns) (by simulation)cJthJth
ξ (10 s )18-2
FIG. 4. (a) αdependence of the threshold value. In this plot,
dJ=−cJis assumed. (b) βdependence of the threshold value. In
this plot, α=0.012 is assumed. (c) ξdependence of the threshold
value (black circle) and switching time (blue solid line). In this plot,
dJ=−cJandα=0.012 are assumed.
exchange stiffness constant Aex=1.6×10−6erg/cm, the
temperature T=300 K, the unit cell size =1n m ×1n m
×1.5 nm. Other parameters are the same as for the macrospin
simulation (Fig. 4). The switching probabilities are obtained
from 20 switching trials.
The simulation results are summarized in Fig. 5.W e
find that the threshold cJis on the order of 100 Oe. This
threshold obtained from micromagnetic simulation at T=
300 K is larger than that obtained from macrospin simulationatT=0 K (Sec. IV A ), but is still much smaller than that
of DC spin-orbit torque switching ( ≈3400 Oe). We also
find that the threshold value of c
Jdecreases as βincreases,
consistent with the macrospin results. Especially for β=1,
cth
Jis about 150 Oe, which corresponds to the current density
184401-5GYUNGCHOON GO, SEUNG-JAE LEE, AND KYUNG-JIN LEE PHYSICAL REVIEW B 95, 184401 (2017)
0 100 200 300 400 500 6000.0.20.40.60.81.
c (Oe)Switching probability
Jβ = 1.0
β = 0.2β = 0.6
β = 0.4β = 0.8
FIG. 5. Switching probabilities in the autoresonant spin-orbit
torque switching process with ξ=0.3×1018s−2. Each data point is
obtained from 40 trials. Parameters are T=300 K, α=0.012,Ku=
1.3×107erg/cm3,Ms=1240 emu /cm3,Aex=1.6×10−6erg/cm,
andγ=1.76×107(Oe s)−1.
ofJSO-STT
SW /similarequal2.1×107A/cm2fortF=1.1 nm and θSH=0.3
[46].
V . CONCLUSION
In this paper, we investigate spin-orbit-torque-driven au-
toresonant switching of perpendicular magnetization. We findtwo interesting features of the autoresonant switching incomparison to conventional DC spin-orbit torque switching.First, the threshold current for the autoresonance mechanism isan order of magnitude smaller than that of DC spin-orbit torqueswitching. However, the switching time for the autoresonanceprocess is on the order of 10 ns, which is longer than that ofDC spin-orbit torque switching [ 34,35,38,39]. This differentswitching time is caused by the fact that the autoresonant
switching inevitably involves multiple precession motion,whereas the DC spin-orbit torque switching requires only halfa precession. Second, the autoresonance mechanism allowsfield-free switching of perpendicular magnetization. We notethat conventional DC spin-orbit torque switching requiresan additional in-plane magnetic field for the deterministicswitching of perpendicular magnetization, which is detrimen-tal for device engineering. As a result, much effort has beenrecently expended in finding field-free switching schemes:Recent reports show that the field-free switching is possibleby breaking lateral symmetry [ 52] or exchange bias from an
antiferromagnetic layer [ 53–56]. The autoresonant switching
process provides an additional way for the field-free switching.In this respect, the present work may be expected to open upa future spintronics device which offers an efficient way forfield-free spin-orbit torque switching.
We end this paper by noting that, for autoresonant spin-
orbit-torque switching, low damping materials with large spinHall angle are favorable. Several low damping materials arefound in experiments for Permalloy [ 57], CoFe alloy [ 58],
Fe
1−xVx[59], and Heusler alloy films [ 60]. Also, some
materials with both large spin Hall angle and small dampingconstant are found in β-Ta/CoFeB [ 61],β-W/CoFeB [ 46],
AuPt/NiFe [ 62], and WO
x/CoFeB [ 63] bilayer structures.
ACKNOWLEDGMENTS
This work was supported by Samsung electronics. K.-J.L.
acknowledges support by the National Research Foundationof Korea (NRF) under Grants No. 2015M3D1A1070465 andNo. 2017R1A2B2006119. G.G. acknowledges support by theNRF under Grant No. 2016R1A6A3A11935881.
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184401-7 |
PhysRevB.45.295.pdf | PHYSICAL REVIEW B VOLUME 45,NUMBER 1 1JANUARY 1992-I
Ferromagnetic resonance studyofmagnetic order-disorder phasetransition
inamorphous Fe90—„CoZr,oalloys
S.N.KaulandP.D.Babu
Schoo!ofPhysics, Uniuersity ofHyderabad, Central Uniuersity P.O.,Hyderabad 500134,India
(Received 24April1991;revisedmanuscript received 22July1991)
Theutilityoftheferromagnetic-resonance (FMR)technique todetermine accurately thespontaneous
magnetization andinitialsusceptibility criticalexponents Pandy,whichcharacterize theferromagnetic
(FM)-paramagnetic (PM)phasetransition attheCurietemperature Tzforferromagnetic materials is
demonstrated through adetailed comparative studyonamorphous Fe90Zr, oalloy,whichinvolves bulk
magnetization andFMRmeasurements performed onthesamesampleinthecriticalregion.Magnetiza-
tiondatadeduced fromtheFMRmeasurements takenonamorphous Fe90„Co„Zrla alloyswithx=0,1,
2,4,6,and8inthecriticalregionsatisfythemagnetic equationofstatecharacteristic ofasecond-order
phasetransition. Contrary totheanomalously largevaluesoftheexponents Pandyreported earlier,
thepresent values,P=0.38%0.03andy=1.38+0.06,arecomposition indepen-dent andmatchverywell
thethree-dimensional Heisenberg values.Thefractionofspinsthatactually participates intheFM-PM
phasetransition, c,isfoundtoincrease withtheCoconcentration asc(x)—c(0)—=axandpossessa
smallvalueof11%forthealloywithx=O.The"peak-to-peak" FMRlinewidth (hH») varieswith
temperature inaccordance withtheempirical relationbH»(T)=EH(0)+ [A/M,(T)],whereM,isthe
saturation magnetization. BoththeLandesplitting factorgaswellastheGilbert damping parameter A,
areindependent oftemperature, but,withincreasing Coconcentration (x),A,decreases slowlywhileg
staysconstant atavalue2.07+0.02.
I.INTRODUCTION
Theferromagnetic- (FM)paramagnetic (PM)phase
transition inamorphous (a-)Fesp+Zrip and
Feso„(Co,Ni)„Zr, oalloyshasbecome acontroversial' is-
sueeversincethebulkmagnetization (BM)measure-
ments'inthecriticalregiononthesealloyshaveyielded
valuesforthespontaneous magnetization and"zero-
field"susceptibility criticalexponents Pandythatare
roughly1.4timeslargerthantherenormalization-group
estimates foranisotropic nearest-neighbor (NN)three-
dimensional (3D)Heisenberg ferromagnet primarily be-
causetheunphysically largevaluesforcriticalexponents
havebeentakentoreflectlargefluctuation intheex-
changeinteraction. Subsequently, anelaborate analysis'
(reanalysis) ofhigh-precision magnetization dataona
FescZrio (published'dataona-Fe»Zr9 anda-Fe92Zrs al-
loys)revealed that,contrary totheearlierfinding,'the
exponents P,y,and5(exponent forthecriticalisotherm)
possess valueswhicharefairlyclosetothe3DNN
Heisenberg values.Thisresultcastsseriousdoubtsabout
thegenuineness oftheanomalously largecritical ex-
ponent valuesreported fora-Fe90„(Co,Ni)„Zrio alloys
andhencenecessitates adetailed studyofthecriticalbe-
haviorinthesealloys.Inthispaperwedescribe anex-
periinental determination oftheexponents Pandy,
whichcharacterize theFM-PM phasetransition at
T&,theCurietemperature, forthea-Fe9Q CoZr,Qal-
loys.Although theferromagnetic-resonance (FMR)tech-
niqueassuchisoldandtherelated technique called
the"zero"-applied-field ferromagnetic-antiresonance
(FMAR) tnicrowave transmission technique hasbeensuc-cessfully usedinthepasttodetermine theexponent P
forcrystalline FeandNi,wedemonstrate thattheFMR
technique canyieldaccurate estimates oftheexponents P
andyforferromagnets through adetailed comparative
studyonthea-Fe9QZr,Qalloywhichinvolves bulkmagne-
tization andFMRmeasurements performed onthesame
sampleinthecriticalregion.
II.EXPERIMENTAL DETAILS
Amorphous Fe9Q„CoZr,Qalloyswithx=0,1,2,4,6,
and8wereprepared underargon(inert)atmosphere by
thesingle-roller melt-quenching technique intheformof
-2-mm-wide and(20—30)-pm-thick ribbons. Theamor-
phousstateoftheribbons wasconfirmed byx-ray-
diffraction andelectron microscopic methods. Usinga
PAR4500vibrating-sample magnetometer, magnetiza-
tion(M)versusexternal magnetic-field (H,„)isotherms
weremeasured at0.1-Kintervals inthecriticalregionon
several6-mm-long stripsofthea-Fe9QZr,Qalloystacked
oneabovetheotherinfieldsupto15kOedirected along
thelengthintheribbonplanesoastominimize the
demagnetization effects. Thesample temperature was
heldconstant towithin+25mKbyaLakeshore DRC
93Ctemperature controller andmonitored byaprecali-
bratedcopper-constantan thermocouple incontact with
thesample. Themicrowave power(P)absorption deriva-
tivedP/dHfora-Fe9Q CoZr,Qalloyswithx=0,l,2,
4,6,and8wasmeasured asafunction oftheexternal
staticmagnetic field(H)on4-mm-long strips,cutfrom
thealloyribbons, usinghorizontal-parallel (ii")and
vertical-parallel (ii")sample configurations (inwhichH
45295 1992TheAmerican Physical Society
296 S.N.KAULANDP.D.BABU
liesintheribbonplaneandisdirected alongthelength
andbreadth, respectively) atafixedmicrowave-field
frequency of-9.225GHzonaJEOLFE-3XEPR
spectrometer inthetemperature range—0.1~E=(T—Tc)/Tc~0.1at0.5-Kintervals. Acopper
constantan thermocouple situated justoutside themi-
crowave cavityafewcentimeters awayfromthesample
wasusedasatemperature-controlling sensor, andthe
temperature T'atthelocationofthissensorwasheld
constant towithin+0.1Kateverytemperature setting
byregulating theflowofcoldnitrogen gasaround the
sample, mounted inastress-free condition insidea
quartztube,bycontrolling thepowerinputtotheheater,
immersed inacontainer filledwithliquidnitrogen, with
theaidofaproportional, integral, andderivative (PID)
temperature controller. Thesampletemperature T,in
thiscasealsowasmeasured bymeansofaprecalibrated
copper-constantan thermocouple andwasfoundtobe
stabletowithinT+50mKwhenT*fluctuates between
T—0.1andT+0. 1Katagiventemperature T.No
changeinT,duetoeddycurrents wasdetected whenthe
microwave powerlevelisincreased fromzeroto1mW.
NotethatP=1mWforallthemeasured dP/dH-vs-H
isotherms andthattheFMRandBMmeasurements were
performed onthesamea-Fe90Zr, osample. Basedona
detailed compositional analysis andtheobserved depen-
denceofTconCoconcentration, weconclude thatthe
rounding ofthetransition inzerofieldshouldoccurfor
temperatures c&4X10 .Thusthedatatakeninthis
temperature rangearenotincluded intheanalysis. Re-
peatedFMRexperimental runsonthesamesamplehave
revealed thattheresonance fieldH„,(defined asthefield
wherethedP/dH=O linecutsthedP/dH vsHcurve)--
and"peak-to-peak" linewidth lelkHpparereproduced to
within+1%and+10%,respectively.3
=&23338
344"(
543
3645
3747
3850
239.52
24.O.55
4260
362
III.EXPERIMENTAL RESULTS:
DATAANALYSIS ANDDISCUSSION
A.Bulkmagnetization
Figure 1displays theM-vs-H,„isotherms takenonthe
amorphous (a-)Fe9QZr, oalloyinanarrow temperature
rangearoundCuriepointTcintheformofamodij7ed
Arrottplot[i.e.,M'~vs(H/M)'rj.Thevaluesofthe
exponents Pandyusedtoconstruct thisplotandgiven8l2
(H/M)'"
FIG.1.Modified Arrottplotconstructed usingthebulk
magnetization datatakenonthea-Fe9QZr, palloy.
TABLEI.Valuesfortheparameters thatcharacterize thecriticalbehavior neartheFM-PM phasetransition inamorphous
Fe9Q—„Co„Zr~p alloysandacomparison between theexperimentally determined andtheoretically predicted valuesforthecriticalex-
ponentsPandyandfortheuniversal criticalamplitude ratiopphp/ksTc.Thenumber intheparentheses denotes theuncertainty in
theleastsignificant figure,and(1),(2),and(3)denotethefirst,second, andthirdexperimental runsonthesamesample. BMstands
forbulkmagnetization, whereasFMRistheabbreviation forferromagnetic resonance.
Alloy
concentration
(x)/theory Method Tc(K) mp(G)hpImp hp(10G)pp(pg )pphpIkgTcp&p(pg )c(%)
3DHeisenbergFMR(1)
FMR(2)
FMR(3)
BM
FMR(1)
FMR(2)
FMR(1)
FMR(2)
FMR(1)
FMR(2)
FMR(1)
FMR(2)
FMR(1)
FMR(2)238.55{15)
238.50(15)
238.55(15)
238.50(5)
254.50(20)
254.80(20)
284.00(25)
284.50(25)
336.00(10)
335.85(10)
377.04(10)
377.10(10)
419.50{10)
419.55(10)0.380{30)
0.370(30)
0.380(30)
0.360(20)
0.380{30)
0.380(30)
0.375(25)
0.385(25)
0.386(20)
0.380(20)
0.375(25)
0.385(25)
0.384(20)
0.382(20)
0.365(3)1.40(6)
1.39(6)
1.38(6)
1.38(3)
1.38(6)
1.38(6)
1.38(5)
1.38(5)
1.38(5)
1.39(6)
1.38(5)
1.39(6)
1.38(6)
1.38(6)
1.386(4)870(30)
870(30)
865(30)
870(25)
1030(35)
1045(25)
1070(25)
1065(25)
1075(20)
1075(20)
1160(30)
1165(30)
1215(35)
1215(35)500(50)
525(50)
500(50)
500(50)
500(75)
430(50)
400(60)
450(50)
650(50)
650(50)
950(50)
950{50)
1200(50)
1200(50)4.4(6)
4.6(6)
4.3(6)
4.4(6)
5.1(9)
4.5(7)
4.3(8)
4.8(6)
7.0(6)
7.0(6)
11.0(9)
11.0(8)
14.6(7)
14.6(7)1.386
1.386
1.386
1.386
1.50
1.50
1.61
1.61
1.68
1.68
1.70
1.70
1.70
1.700.172(17)
0.180(20)
0.168(17)
0.172(16)
0.202(35)
0.178(22)
0.164(30)
0.182(22)
0.235(16)
0.235(16)
0.333(25)
0.333(25)
0.397(18)
0.397(18)
1.5812.7(16)
12.2(17)
13.0(15)
12.7(16)
11.7(18)
13.3{15)
11.3(10)
13.9(15)
11.3(10)
11.3(10)
8.0(6)
8.0(6)
6.8(5)
6.8(5)11.0(10)
11.0(11)
11.0(10)
11.0(10)
12.8(15)
11.3(10)
10.4(16)
11.6(10)
15.0(12)
15.0(12)
21.5(15)
21.2(15)
25.0(18)
25.0(18)
'Valuesobtained fromthebulkmagnetization measurements takenat4.2Kontheglassyalloysunderconsideration.
45 FERROMAGNETIC RESONANCE STUDYOFMAGNETIC ORDER-. .. 297
inTableIhavebeendetermined bythemodified asymp-
toticanalysis(AA-II;fordetailsseeRef.9),andthemag-
neticfieldHhasbeencorrected forthedemagnetizing
effects(i.e.,H=H,„H—~,,whereHz,isthedemagnet-
izingfieldestimated fromthe"low-field" magnetization
data}.Theisotherms areseentobeasetofstraight lines,
andthecritical isotherm atT=Tc=238. 50Kpasses
through theorigin,asexpected foracorrectchoiceofthe
exponents Pandy.46K
B.Ferromagnetic resonance
Thevariation ofdP/dH withHinthe~~"configuration
atafewselected valuesoftemperature inthecriticalre-
gionisdepicted fora-Fe90Zr, oinFig.2.Thesecurvesare
alsorepresentative ofthoserecorded fora-Fe90Zr, ointhe
()'configuration andforotheralloysinboth(("and()"
geometries. ItisevidentfromFig.2thatasthetempera-
tureisincreased throughTc,thepeakinthedP/dH-vs-
Hcurvesatalowerfieldvalue-800Oedevelops intoa
full-fledged resonance (secondary resonance) for
T~Tc+10K,whereas themain(primary) resonance
shiftstohigherfieldsandbroadens out.AdetailedFMR
study'carriedoutontheglassyalloysinquestion ina
widetemperature range77~T&500Krevealsthatthe
secondary-resonance (whosesignature isfirstnoticed in
themostsensitive settingofthespectrometer atatern-
perature closetoTcoraboveTc)exhibits a"cluster
spin-glass-like" behavior, whereas theprimary resonance
possesses properties characteristic offerromagnets
with"' (forxS2)orwithout' (forx~2}reentrant
spin-glass behavior atlowtemperatures. Sincethestudy
ofcriticalbehavior neartheFM-PM phasetransition in
a-Fe90„Co„Zr&0 alloysisofprimeconcern inthispaper
andthedatarecorded in~~"and ~~"configurations yieldex-
actlythesameresultssofarasthecriticalbehavior inthe
investigated glassyalloysisconcerned, henceforth we
dealwiththeprimary resonance partofthedP/dH-vs-H
curves,recorded inthe~~"configuration, only.Nowthat
inthecriticalregionhH-=H„,/4,theobserved value
ofH„,couldsignificantly differfromthe"true"reso-
nancecenter,andhenceadetailed line-shape analysisfor
eachresonance lineseparately iscalledfor.ThedP/dH
vs-Hcurvesrecorded atdifferent temperatures inthe~~"42K
36K
34K
30K
I I I I I I I I
00.51.01.52.02.53.03.540
H(kQe}I I
4.55.0
FIG.2.Powerabsorption derivative curvesfora-Fe90Zr, oat
afewrepresentative temperature valuesinthecriticalregion
recorded usingthe~~"sampleconfiguration. Solidcurvesdepict
theobserved variation ofdP/dH withH,whereas theopencir-
clesdenotethecalculated valuesbasedonEqs.(1)and(2)ofthe
text.Numbers ontheleft-hand sideofthecurvesareameasure
ofthesensitivity atwhichthespectraaretaken.
configuration havebeenfittedtothetheoretical expres-
sion''
dP
[(~2+~~2)1/2+ «]1/2
dHdH
withtherealandimaginary components ofthedynamic
permeability givenby
and[(H+H)(B+H )—I—(co/y)][(B+H )—I(co/y)]+—2I(B+H)(B+H+2H )
[(H+H)(B+H )—I2—(co/y)]+I(B+H+2H )2(2a}
—2I(B+H)[(H+H}(8+H )—I—(co/y)]+I(B+H+2H )[(B+H )—I—(co/y)]
[(H+H)(B+H )—I—(ei/y)]+I(B+H+2H )(2b)
derivedfordP/dH intheparallel geometry andobtained
bysolvingtheLandau-Lifshitz-Gilbert (LLG)equationof
motion inconjunction withMaxwell's equations, by
making useofanonlinear least-squares-fit computer pro-gramwhichtreatstheLandesplitting factorgandsatu-
rationmagnetization M,=(BH)/4m asfreefit—ting
parameters andusestheobserved valuesof
bH=1.45I=1.45ico/y M,(where )1,istheGilbert
298 S.N.KAULANDP.D.BABU 45
damping parameter, y=g~e~/2mc, andv=co/2~ isthe
microwave-field frequency), andvaluesofthe"in-plane"
uniaxial anisotropy fieldHzdeduced fromtherelations'
andres resKII= II(3a)
H„,=H„,+Haec (3b)
InEqs.(3a)and(3b),H,'i„andHi'„are theestimates for
theresonance fieldsinthe~~"and ~~"configurations, re-
spectively, obtained aftercorrectinq theobserved values
forthedemagnetization fieldsHfi,andH)~,m,deter-
minedfromthelow-field magnetization measurements
performed onthesamples usedforthepresentFMR
studywiththeexternal magnetic fieldapplied alongthe
easy(ff"-configuration) andhard(ff"-configuration) direc-
tionsintheribbonplane,andHII„istheresonance field
intheabsenceofHz.Intheline-shape calculations lead-
ingtoEqs.(1),(2a),and(2b),theexchange-conductivity
contribution hasbeendropped inviewofthewell-known
observation'''thatthiscontribution tothelinewidth
aswellastotheresonance fieldissosmallastofallwell
withintheerrorlimitsbecause thevaluesfortheex-
change stiffness parameter andconductivity bothareat
leastanorderofmagnitude smaller''thantheircorre-
sponding valuesforcrystalline metals.
Theoretical fits,depicted byopencirclesinFig.2,not
onlyassertthattheline-shape analysis yields"true"
valuesofthelinecentersfortheprimary resonance even
inthepresence ofasecondary resonance because the
baseline forthetworesonances isthesome(Fig.2),but
alsoindicate thattheLLGequation adequately describes
theresonant behavior inthecriticalregion.Inaddition,
theline-shape calculations revealthatthesplitting factor
ghasaconstant valueof2.07+0.02withintheinvestigat-
edtemperature range.Thatthegfactoristemperature
independent andtheLLGequation formsanadequate
description ofH„,(T)andhH(T)inthecriticalregion
forcrystalline ferromagnets alsohasbeenclaimed by
Rodbell' andbyHaraldson andPettersson,'butthis
claimhasbeenrefuted byBhagat andRothstein. The
present resultsare,however, consistent withourearlier
observation' thatM,(T)deduced inthisway'fromthe
FMRdataareinexcellent agreement withM(T)mea-
suredonthesamesampleatanexternal magnetic field
whosestrength iscomparable toH„,.
m=fz(h), (4)C.Critical exponents, amplitudes,
andscalingequation ofstate
IAHavingdetermined M,(T)andH„,(T)[=HJi„(T); the
superscript~~ishenceforth dropped forconvenience] toa
highprecision fromtheline-shape calculations, accurate
valuesofp,y,andTcareextracted fromthe
M(H,T)=M,(H„„T) databyidentifying H„,withthe
ordering fieldHconjugate toM(=M,),andusingthe
"range-of-fit" scaling-equation-of-state (SES}analysis,
whichisbasedonthemagnetic equationofstate,Fe9QZr»c&0p
p9+
+
+z&0
Tc=238. 0K+g&0p
+++ +
+ 0++
~+
++@&0
++ LZ3
+0+
++
g+c&0
Tc=239.0K
+++Tc=238.5K
P=038
y=138
I I I I
13151719
ln(H/icis")21
FIG.3.PlotsofIn(M/~s~s)against ln(H/~s~s+")for
different valuesofTcfora-Fe9OZr, o.
whereplusandminussignsrefertotemperatures above
andbelowTcandm=M/~s~~ andh:H/)Is)~+~ are—the
scaledmagnetization andscaledfield,respectively. Inthe
conventional SESmethod, M(H,T)data,inthecritical
region,aremadetofallontwouniversal curves,ffor
s(0andf+fors)0,through anappropriate choiceof
theparameters Tc,p,andyinanm-vs-hplot,butthis
choiceisbynomeansuniqueinthesensethatnearlythe
samequalityofdatacollapse ontothetwouniversal
curvescanbeachieved forawiderangeofparameter
values(tyPically, +2%forTcand+10%%uoforPandy}.
Thisproblem is,however, effectively tackled byemploy-
ingtherange-of-fit SESanalysis inwhichmoreand
moreofthedatatakenattemperatures awayfromTcare
excluded fromthem-vs-hplotsothattheexponents p
andybecome increasingly sensitive tothechoiceofTc
andthedataexhibitstrongdepartures fromthecurvesf(h}andf+(h)ifthechoiceoftheparameters differs
evenslightly fromthecorrect one.Thisprocedure,
therefore, goesonrefining thevaluesofthecriticalex-
ponents untiltheyapproach theasymptotic values.The
finalvaluesoftheparameters Tc,p,andyfora-Fe9OZr&o
soobtained aregiveninTableI.Figure3servestoillus-
tratetheeffectofthevariation inthevalueofT&onthe
qualityofdatacollapse. Similar effectsareobserved if
oneoftheexponents isvariedwhilekeepingTcandthe
otherexponent fixed.
Acomparison between thelnm-vs-lnh scalingplotsfor
a-Fe9oZr&o constructed usingtheBMandFMRdata
(recorded inthreedifferent experimental runs}takenon
thesamesampleisshowninFig.4.Aperfectagreement
between different setsofFMRdataandbetween there-
sultsofFMRandBMmeasurements isevidentfromthis
figure.However, amorerigorous meansofascertaining
45 FERROMAGNETIC RESONANCE STUDYOFMAGNETIC ORDER-. .. 299
FegPZC1O
~~~~~BMData
OOOOO FMRRun 1
clouuu FMRRun2
AAAAA FMRRun3
~O
—8-~
QD@&0
e&0c&0
c&0
~~~~
FMR BM
Tc=238.55238.50K
P=0.3800.360
y=1.3801.380
6I I I I I I I
121314151617181920
1n(H/(sI~'")
FIG.4.1n(M/~s ~s)-vs-1n(H/~s ~s+")plotsfora-Fe9OZr, ocon-
structed usingthebulkmagnetization dataandsaturation mag-
netization datadeduced fromFMRspectra employing line-
shapeanalysis.00
4.0
3.02468
h/m(10')101214
whether ornottheabovemethod yieldsaccurate values
forthecriticalexponents andT~isprovided byaSES
formthatdiffersfromEq.(4),i.e.,
m=+a++b+(h/m) (5)1.0
M,(s)=limM(H,s)=mo(—s)~,s(0H~O
and(6a)(wheretheplusandminussignsaswellasmandhhave
thesamemeaning asgivenabove}, because eventhe
slightest deviations ofthedatafromtheuniversal curvesf(h)andf+(h), whichdonotshowupclearly ina
lnm-vs-lnh plotbecauseoftheinsensitive natureofthe
double-logarithmic scale,become easilydiscernible
whenthesamedataareplotted intheformofanm-vs-
(h/m)plot.Another advantage inusingEq.(5)isthat
thecritical amplitudes mo=a'/ andho/mo=a+/b+,
definedby0.00 6810
h/m(10')1214
FIG.5.m-vs-h/m plotfora-Fe9O„Zr,oconstructed using
(a)bulkmagnetization dataand(b)saturation magnetization
datadeduced fromtheFMRspectratakeninthefirst(opencir-
cles),second(opensquares), andthird(opentriangles) experi-
mentalrunsonthesamesample. Thedataneartheoriginare
plottedonasensitive scaleintheinsetwithaviewtobringout
valuesoftheintercepts moandho/mponmandh/maxes
clearly.
~}M(H,s)
XoBHH=O=(ho/mo)sr,s)0
(6b)
aregivenbytheintercepts oftheuniversal curveswith
mandh/maxes,respectively, inanm-vs-h/m plot.
Suchplotsconstructed usingthechoiceofparameters
Tc,P,andygiveninTableIareshowninFigs.5(a)and
5(b).Consistency amongdifferent setsofdataisnowall
themoreobvious, particularly whentheBMandFMR
dataareplottedonahighlysensitive scaleandonlythose
BMdatathataretakenatfieldscomparable instrength
tothoseusedinFMRexperiments areincluded inFig.
5(a).Fromtheobservation thatnodeviations fromthe
universal curvesareevident evenatlowfieldsinFigs.5(a)
and5(b),weconclude thatthevaluesforthecriticalex-ponents andTzdetermined bytherange-of-fit SES
analysis arereasonably accurate. Moreover, thevalueof
thespecific-heat criticalexponenta=—0.14,computed
usingthepresently determined valuesoftheexponents p
andy(whichconform verywellwiththosepreviously re-
ported'forthisalloybasedontheBMmeasurements) in
thescalingrelationa=2(1—p)—y,andthepresent value
ofTc(Table I)agree closely withthose
(a=—0.13+0.06T=238.6+0.1K)extracted fromre-
centelectrical resistivity measurements' onasamplecut
fromthesamea-Fe9oZr, oribbonasthatusedinthis
work.TableIliststhevaluesofCurietemperature, criti-
calexponents pandy,critical amplitudes moand
(ho/mo}, andtheratiopoho/ksTc,deduced forthea-
Fe9OZr&o alloyfromtheBMdataandfromthedifferent
setsofFMRdatatakenonthesamesample, andcom-
S.N.KAULANDP.D.BABU 45
paresthemwiththetheoretical valuespredicted foran
isotropic NN3DHeisenberg ferromagnet. Anassess-
mentofthedatapresented inTableIrevealsthatare-
markably closeagreement existsnotonlybetween the
BMandFMRresults,butalsobetween thetheoretical
andexperimental valuesforthecriticalexponents. How-
ever,theobserved valueoftheratiopoho/k~TC isone
orderofmagnitude smallerthanthetheoretically predict-
edone.Sincehoispresumably aneffective exchange in-
m
C)
moteraction field,theproductofhoandanaverage effective
elementary moment (p,s)involved intheFM-PM phase
transition, i.e.,theeffective exchange energyp,go,isex-
pectedtoequalthethermal energyk&TcatTc.Obvi-
ously,thisisnotthecasefora-Fe90Zr, ounlessp,zistak-
entobeverymuchlargerthanpo(average magnetic mo-
mentperalloyatomat0K).Nowthattheexponents
possess3DHeisenberg values,theratiop,golk~Tc is
alsoexpected toequalthe3DHeisenberg estimateof
1.58.Thisispossible onlywhen JM,&assumes thevalues
giveninTableI.Moreover, iftheconcentration ofsuch
effective moments isc,thenc=po/p, &;Thevaluesofc
calculated inthiswayandincluded intheTableIstrong-
lyindicate thatonlyasmallfractionofmoments (i.e.,the
moments onFeatomsinthecaseofa-Fe9oZr, o)partici-
patesintheFM-PM phasetransition.
Having demonstrated thattheFMRtechnique isa
powerful toolforinvestigating thecritical behavior in
ferromagnets, accurate valuesforTc,thecritical ex-
ponentsPandy,critical amplitudes moand(ho/mo),
andconcentration ofeffective moments participating in
theFM-PM transition, c,havebeendetermined by
analyzing theFMRdatatakenonthealloyswithx=1,
2,4,6,and8usingthesamemethod asmentioned above.
Thevaluessoobtained arelistedinTableIandareused
toconstruct them-vs-h/m scaling plotsfortheCo-
containing glassyalloysshowninFig.6.Anumberofin-
teresting pointsemergefromacomparison ofthepresent
mo
069
h/m(lo')
F~90-x«xz«101215
1.8—FeA-4~
O
-2
mo
EOC)
mo
CQ25
15-M
O
2
02468
Coconcentration x10
2mo
'0 69
h/m(10')12'l5
FIG.6.m-vs-h/m plotsfora-Fe9p CoZr,palloyscon-
structed usingthesaturation magnetization datadeduced from
theFMRspectrarecorded atdifferent temperatures inthecriti-
calregion.FIG.7.Functional dependences ofCurietemperature T&,
magnetic moment peralloyatomat0K,pp,Gilbert damping
parameter A,,andthefractionofspinsparticipating intheFM-
PMphasetransition, c,ontheCoconcentration xfora-
Fe9p„Co„Zrlp alloys.Thesolidcurvesaretheleast-squares fits
tothedata,whereas thedashedcurvesserveasaguidetothe
eye.NotethattheerrorlimitsforA,aretypically +5%%uoofits
valueatagivenx.Theerrorlimitsfortheotherquantities are
giveninTableI.
45 FERROMAGNETIC RESONANCE STUDYOFMAGNETIC ORDER-.~. 301
resultswiththosepreviously obtained andwiththose
predicted bythetheory; namely, (i}contrary totheear-
lierfinding, theexponents Pandydonotdependonthe
alloycomposition andpossess3D-Heisenberg-like values;
(ii)thefractionofspinsthatactually participates inthe
FM-PM phasetransition, c,issmallfortheparentalloy
(x=0),butincreases withCoconcentration xas
c(x)—c(0)—=ax,withc(0)=11+1% anda—=0.23,in
theinvestigated composition range(Fig.7);and(iii)in
conformity withthepreviously reported' result,the
Curietemperature T&increases roughly linearly with
thecomposition x[i.e.,Tc(x)=Tc(0)+23.2x,with
Tc(0}=237.2K],whereas themoment peralloyatomat
0K,po,increases steeplywithxintherange0&x&2
andattainssaturation forxR4(Fig.7).
D.FMRlinemdth
Variation ofthepeak-to-peak FMRlinewidth LakHpp
withtemperature isdisplayed inFig.8.Aslopechange
in5Hz~(T) atTc(B=O)foralltheglassyalloysunder
consideration isindicative ofawell-defined magnetic
phasetransition atT&.Itshouldbeemphasized atthis
stagethatthevaluesofb,Harethesame(withinerror
limits)forboth ~~"and ~~"configurations atalltempera-
tureswithinthetemperature rangecovered inthepresent
experiments. Hence bH~~(T)observed inthe
configuration anddepicted inFig.8reproduces allthe
features b,H"(T)eventotheminutest detail.FMRmea-
surements carriedout,inthepast,overawiderangeof
microwave-field frequencies atconstant temperaturebH(T)=bH(0)+[A/Ms(T)] . (7)
Ifthefirstandsecondtermsontheright-hand sideofEq.
(7)areidentified withbHtandEH„„o, respectively, the
coefficient AinEq.(7},determined bytheleast-squares
methodfordifferent compositions, permitsastraightfor-
wardcalculation ofthedamping parameter A,.Notethat
Eq.(7)withthemeaning ofthetermsEH(0) and
A/M,(T)sameasabovehasbeenpreviously usedto(T&Tc)onalargenumberofamorphous ferromagnetic
alloysystems haverevealed thatthetwomaincon-
tributions tohHareEHI,whichisnearlyindepen-
dentofthemicrowave-field frequency v=co/2na. ndis
mostprobably causedbythetwo-magnon scattering from
spatially localized magnetization inhomogeneities,'''
andAHLz6=1. 45K,co/yM„which hasalineardepen-
denceonvandresultsfromaLLGrelaxation mecha-
nism.Insuchmaterials, hHisfoundtoremainpracti-
callyconstant''''overawiderangeoftempera-
tureswellbelowTc(T50.8Tc)andtheGilbert damping
parameter A,varieslinearly''''withM,.Anim-
mediate consequence oftheresultX~M,isthathH„~z
doesnotvarywithtemperature, sothatinviewofacon-
stantvalueofLalHppevenEHIshouldnotdependontem-
perature. Inthecritical region (—0.055s-0.05),
hH(T)foralltheamorphous alloysinquestion, with
theexception ofthosewithx=0and4,canbeverywell
described (Fig.9)bytheempirical expression
IFeao-xcoxzr101
-74~
x=40 ~gggs4
x=2C4
7-x=1gpQ~+p
~C++~'7tP 9P~
o~ -2DpQL)3
po&oooaoCO~(g)ooo™F000-XCOXZ110
~Q+0
x-I2~ ~p.m~-5~I
Ol
x-&
4-
X~2~~P
EO~~Q5-3
-5
X
ygjlxx4 4,44444 ~'4-4~~C]
acP~~~QP -3
X~8
2
—0.06I I
0.000.03
e=(T—Tc)/TcI—0.03 0.06
FIG.8.Variation ofthepeak-to-peak FMRlinewidth
(AH»)withtemperature inthecritical regionfora-
Fe90„Co„Zr» alloys.TheAH»(T) datatakeninthefirst,
second, andthirdexperimental runsonthesamesamplearede-
pictedbythesymbols opencircles, squares, andtriangles, re-
spectively.2.5I3.54.5
MB(10G)I
5.5
FIG.9.Peak-to-peak FMRlinewidth(hH„)plottedagainst
inverse saturation magnetization inthetemperature interval—0.05~c+0.05forFe90„Co„Zrlo alloys. Thesolidand
dashedstraight linesdrawnthrough thedatapoints(denoted by
thesymbols whichhavethesamemeaning asinFig.8)
represent theleast-squares fittotheAH»(T) databasedonEq.
(7)ofthetextinthetemperature intervals—0.05~a~0 and—0.05~c&0.05respectively.
302 S.N.KAULANDP.D.BABU 45
describe thetemperature dependence ofhHinFe-richPPa-Fe,ooB„alloys fortemperatures wellbelowTc.The
temperature-independent valuesofA,socomputed range
between2X10and3X10sec'andexhibitaweakde-
creasing trendwithCoconcentration asshowninFig.7.
Bycontrast, theintercept bH(0)doesnotshowanysys-
tematic trendwithx;i.e.,aminimum[bH;„(0)=20Oe]
intheEH(0)-vs-x curveatx=2isfollowed byamax-
imum[EH,„(0)-=140 Oe]atx=4.Different setsof
FMRdatatakenonthesamesampledemonstrate that
thevaluesforA,arereproduced towithin+10%.
Another important findingwhichmeritsattention isthat
thequalityoftheleast-squares fitstotheb,H(T)data
basedonEq.(7)improves, asinferred byalowervalue
forthesumofdeviation squares (y),iftherangeoftem-
peratures overwhichsuchfitsareattempted isconfined
totemperatures justbelowTc,i.e.,0.05~@.&0.Howev-
er,amarked improvement inthequalityofthesefits,
brought aboutbyawidelydifferent choiceoftheparame-
tersEH(0)andA[i.e.,b,H(0)decreases byafactorof
about1.5,whileA(andhence A,)increases bythesame
factor] isobserved forthealloyswithx=0and4only;
fortheremaining alloys,theslopeandintercept values
change onlyslightly fromtheirprevious estimates, with
theresultthatonlyamarginal decrease ingoccurs.
Theappearance ofthesecondary resonance atT=—Tcfor
a-Fe90Zr&o andatatemperature afewdegrees aboveTc
forthealloywithx=4asagainstattemperatures well
aboveTcforotheralloyscouldbeattherootofthe
uniquebehavior ofthealloyswithx=0and4.Acom-
pleteunderstanding ofthisaspectoftheFMRdatamust,
however, awaitadetailed investigation whichshedslight
ontheexactoriginofthesecondary resonance. The
presently determined valuesofthedamping parameter I,
areabout3timeslargerthanthosereported forawide
varietyofcrystalline''''andamorphous'fer-
romagnets attemperatures wellbelowtheCurietempera-
tureTc.Suchalargeenhancement inthevalueofXfor
temperatures closetoTcisnotuncommon.''More-
over,thefindingthatkdoesnotdependontemperature in
thecritical regionisaproperty whichtheinvestigated
glassyalloyssharewithcrystalline ferromagnets
detailed butaccurate measurements ofbH~„(T) inthe
criticalregionforamorphous ferromagnets arepresently
lacking.
Considering thewell-known''factthatthedynamic
permeability attainsitsmaximum valueatthefieldcorre-
sponding toferromagnetic resonance andthemicrowave
radiation penetrates onlyathinsurface layer(typical-
ly''10A)inaferromagnetic metal,FMRmeasure-
mentshavealsobeenperformed ontheBMsamples after
etching themwithnital(10%concentrated HNO3+
90%%uoC2H5OH) solution for30minsoastoensurethat
theresultsarerepresentative ofthebulk.Fromthe
weight-loss measurements, weinferthatthethickness of
thesample isreduced tonearlyhalfaftertheetchingtreatment. Apartfromasystematic downward shift(up-
wardshift)intheresonance field(saturation magnetiza-
tion)versustemperature curvefortheetchedsamples
withrespecttothesimilarcurveinthe"as-quenched"
samples, nochange inthevaluesquotedfordifferent
quantities inTableIhasbeendetected. Itshouldbeem-
phasized atthisstagethatthefullpotential oftheFMR
technique toyieldaccurate valuesforthecritical ex-
ponents canbeexploited onlywhenthistechnique isused
tostudythemagnetic order-disorder phasetransition in
goodqualitythinfilmssincetheskindepthinthatcaseis
comparable tothefilmthickness andtheconventional
methods tomeasure bulkmagnetization forsamples in
thin-film formlacktherequired sensitivity.
IV.CONCLUSION
Fromadetailed studyofcritical behavior inamor-
phousFe90CoZrioalloysusingbulkmagnetization
(forthealloywithx=0alone)andFMRtechniques, the
following conclusions canbedrawn.
(i)TheFMRtechnique canbeusedtodetermine the
criticalexponents Pandyforferromagnets toanaccura-
cywhichcompares wellwiththatachieved inthebulk
magnetization method.
(ii)Contrary totheearlierclaim, thecritical ex-
ponentsPandyarecomposition independent andpossess
valueswhichareclosetotherenormalization-group esti-
matesforaspinsystem withspinaswellasspatial
dimensionality ofthree.Alternatively, thetransition at
Tciswelldefined andthequenched disorder doesnot
alterthecriticalbehavior ofanordered3DHeisenberg
ferromagnet; i.e.,thewell-known Harriscriterion is
satisfied.
(iii)Thefractionofspinsthatactually participates in
theFM-PM phasetransition, c,increases from11%at
x=0to25%%uoatx=8andthefunctional dependence ofc
onxiswelldescribed bytheempirical relation
c(x)—c(0)-=ax.
(iv)bHz(T)closely followsarelationofthetype
bH(T)=AH(0)+ [A/M,(T)]inthecriticalregion.
(v)BoththeLandesplitting factorgandGilbertdamp-
ingparameter A,aretemperature independent withinthe
investigated temperature range,butwithincreasing Co
concentration A,decreases whilegremains constant atthe
value2.07+0.02.
ACKNO%'LED GMKNTS
Thefinancial support bytheDepartment ofScience
andTechnology, NewDelhi, underproject No.
Sp/S2/M21/86 tocarryoutthisworkisgratefully ac-
knowledged. Oneofus(P.D.B.)isthankful totheUni-
versityGrantsCommission, NewDelhi,forfinancial as-
sistance.
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resultsofFMRmeasurements performed inthesame
configuration atthreewidelyspacedvaluesofmicrowave fre-
quencyvorbymaking useoftheresonance conditions forthe
~~"andi"(thehorizontal-perpendicular samplegeometry, in
whichtheexternal staticmagnetic fieldisappliedperpendicu-
lartothesampleplane)configurations andtheFMRresults
obtained forthesesampleconfigurations atasinglevalueofv
hasnotfollowed inthisworkfortworeasons. First,thelack
ofexperimental facilities required forsuchanexperimental
investigation. Second, evenwithutmostcareexercised in
sample mounting anditspositioning intheexternal static
field,thelineshapeforthel"configuration andhencethe
valueofH„,couldnotbereproduced withashighanaccura-cyaswasachieved inthedetermination ofH~~,andH~~„
presumbly becauseoftheextreme sensitivity ofH„,tothean-
glebetween thefielddirection andsampleplane.Inviewof
thisobservation, weconsider aperfect agreement observed
between thevaluesofH„,extracted fromsomeexperimental
runsandthosecalculated usingthenumerical estimates ofg
andM„deduced fromthepresent line-shape analysisofthe
FMRspectratakeninthe
~~configuration, intheresonance
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|
PhysRevB.86.214416.pdf | PHYSICAL REVIEW B 86, 214416 (2012)
Temperature dependence of the frequencies and effective damping parameters
of ferrimagnetic resonance
F. Schlickeiser,1,*U. Atxitia,2,3S. Wienholdt,1D. Hinzke,1O. Chubykalo-Fesenko,3and U. Nowak1
1Fachbereich Physik, Universit ¨at Konstanz, D-78457 Konstanz, Germany
2Department of Physics, University of York, Heslington, York YO10 5DD United Kingdom
3Instituto de Ciencia de Materiales de Madrid, CSIC, Cantoblanco, 28049 Madrid, Spain
(Received 3 September 2012; published 17 December 2012)
Recent experiments on all-optical switching in GdFeCo and CoGd have raised the question about the importance
of the angular momentum or the magnetization compensation point for ultrafast magnetization dynamics. Weinvestigate the dynamics of ferrimagnets by means of computer simulations as well as analytically. The resultsfrom atomistic modeling are explained by a theory based on the two-sublattice Landau-Lifshitz-Bloch equation.Similarly to the experimental results and unlike predictions based on the macroscopic Landau-Lifshitz equation,we find an increase in the effective damping at temperatures approaching the Curie temperature. Further results forthe temperature dependence of the frequencies and effective damping parameters of the normal modes representan improvement of former approximated solutions, building a better basis for comparison to recent experiments.
DOI: 10.1103/PhysRevB.86.214416 PACS number(s): 75 .78.−n, 75.50.Gg
I. INTRODUCTION
The recent discovery of ultrafast, optomagnetic writing
schemes using circularly polarized laser pulses,1–3pure
thermal excitation,4,5or terahertz radiation6focuses much
attention on the understanding of antiferromagnetic andferrimagnetic materials since all these effects have been foundonly for materials with at least two sublattices. Switching withcircularly polarized light or just with the heat pulse has beenrestricted to ferrimagnets with a rare-earth component, as, e.g.,GdFeCo
1or TbCo.7The reason for this restriction is not fully
understood, though it has been speculated that the peculiaritiesof the dynamics of a ferrimagnet across the angular momentumcompensation temperature, where the effective damping andthe frequency of the normal modes are predicted to increaserapidly,
8plays a crucial role.
In general, ferrimagnetic materials with two sublattices
show two characteristic damped precession motions of thetotal magnetization around an external field H
0. As they can
be excited experimentally by oscillating magnetic fields, theyare called resonance modes. For one mode both sublatticesstay antiparallel to each other. The dynamics related to thismode can be described as an effective ferromagnetic systemand is called the ferromagnetic mode (FMM). The othernormal mode is caused by the antiferromagnetic couplingbetween the two sublattices. In this so-called exchangemode (EXM), the sublattices are tilted at a characteristicangle.
9The characteristic motion of both modes is shown in
Fig. 1.
The parameters that basically define the possible switching
time are the frequency and the effective damping of theresonance modes of the samples. Both need to be high inorder to enable fast magnetization reversal. The temperaturedependence of the dynamic behavior of ferrimagnets is ofspecial interest here since in earlier theories of ferrimagneticresonance
8,10–12based on the two-macrospin Landau-Lifshitz-
Gilbert (LLG) equation of motion, the FMM shows a diver-gence of (or at least a rapid increase in) the frequency andthe effective damping parameter at the angular momentumcompensation temperature T
A.Recently, the temperature dependence of these resonance
modes was investigated experimentally for amorphous, fer-rimagnetic GdFeCo by Stanciu et al.
13and for amorphous,
ferrimagnetic CoGd by Binder et al.14In both experiments it
was shown that both the frequency and the effective dampingparameter of the FMM increase significantly, approachingthe angular momentum compensation point T
A. Besides this
partial coincidence with the analytical prediction for thefrequency of the FMM, the experimental findings in Ref. 13
also feature some disagreement with earlier theories. Thecommon approximate solution by Wangsness
8predicts that the
frequency will go to 0 at the magnetization compensation pointT
M, while in the experiment its value remains finite, not even
with a minimum. For the experimentally observed effectivedamping parameter the disagreement with earlier theories iseven more pronounced. Unlike the theoretical predictions inthe experiment the effective damping is observed to increasesignificantly, approaching the Curie temperature T
C.
In this work, we present a more general analytical so-
lution based on the Landau-Lifshitz-Bloch15(LLB) equation
of motion for the temperature dependence of the frequencyand effective damping parameters of both modes and comparethem with our numerical findings from atomistic spin-modelsimulations. We show that the assumption of a temperature-independent sublattice damping parameter, confirmed experi-mentally for a wide range of temperatures
16far below TC, does
not hold in the high-temperature regime close to TC, and we
present the derivation of new temperature-dependent dampingparameters. Additionally, we recall the invalidity of somecommon approximate solutions at the compensation pointsand show the influence of the strength of a magnetocrystallineanisotropy on the properties of the resonance modes, enablingan understanding of the experimental findings.
II. NUMERICAL METHODS
A. Model
Our numerical results are based on a spin model where
we consider classical spins Sν,κ=μν,κ/μν,κon two different
214416-1 1098-0121/2012/86(21)/214416(7) ©2012 American Physical SocietyF. SCHLICKEISER et al. PHYSICAL REVIEW B 86, 214416 (2012)
(a)
MT
MRH0(b)
MT
MRH0
FIG. 1. (Color online) Schematic of the two resonance modes in
ferrimagnets. (a) For the ferromagnetic mode, the sublattices remain
antiparallel; (b) for the exchange mode, the sublattices are tilted at acharacteristic angle.
sublattices. Here, ν,κ=T,R with κ/negationslash=νrepresents either the
rare-earth-metal (R) or the transition-metal (T) sublattice, andμ
νis the atomic magnetic moment with μR/μT=2. The
position of the spins, which are localized regularly on thetwo intertwined sublattices of a simple cubic lattice, is chosensuch that nearest neighbors (nn’s) always belong to the othersublattice respectively. The contribution to the Hamiltonianfrom one single spin is
H
i
ν=−1
2/summationdisplay
j∈nnnJνSi
νSjν−1
2/summationdisplay
j∈nnJνκSi
νSjκ
−dz
ν/parenleftbig
Sz,i
ν/parenrightbig2−μνH0Si
ν. (1)
Here, the first sum represents the ferromagnetic coupling
between spins in the same sublattice [next-nearest-neighbor(nnn) interaction], while the second sum represents theantiferromagnetic interaction between spins in different sub-lattices (nn). Besides the exchange interaction with reducedvalues J
R/JT=0.2 and JRT/JT=− 0.1, we consider also
a magnetocrystalline anisotropy in the zdirection with the
anisotropy constant dz
ν(which is varied) as well as the Zeeman
energy from an external magnetic field H0.
Our numerical results for N=323spins are generated by
solving the stochastic Landau-Lifshitz17equation via Heun’s
method. The equation itself and the method used are describedin detail in Ref. 18. For the gyromagnetic ratios we use
γ
R/γT=0.75, and as the microscopic damping constant,
describing the coupling of the spin system to the heat bath,we use λ=0.01 for the nonanisotropic case and λ=0.001
for finite anisotropy. The heat bath is provided by the electronicdegrees of freedom as well as by the lattice and it defines thetemperature of our simulations in the canonical ensemble.
B. Equilibrium magnetizations and transverse relaxation
The sublattice equilibrium magnetizations are calculated as
the spatial and time average of the (easy axis) zcomponent of
the magnetic moments,
Me
ν=μν
Nνa3·/angbracketleftBiggNν/summationdisplay
i=1Sz,i
ν/angbracketrightBigg
, (2)
withν=R, T, and Nνdefining the number of unit cells
with volume a3in the system. The temperature dependencefit-functionstotalrare-earthtransition-metal
temperature kBT/JTmagnetization Me(T)/MT(0)
4 3.5TC3 2.52 1.5TATM 0.501
0.5
0
-0.5
-1
-1.5
-2
FIG. 2. (Color online) Temperature dependence of the equi-
librium magnetization of the sublattices. At the magnetizationcompensation point, T
M, the sublattice magnetizations cancel each
other, while at the angular momentum compensation point, TA,t h e
angular momenta of both sublattices are equal. Above the criticalpointT
Cthe system is paramagnetic.
of the resulting sublattice and total magnetizations, basically
determined by the respective exchange constants, are shownin Fig. 2. We note that, due to their coupling, the two
sublattices have the same critical temperature. In additionto this Curie temperature, ferrimagnets may have two othercharacteristic temperatures relevant to their magnetic behavior.At the magnetization compensation point T
Mthe sublattice
magnetizations cancel each other, so that the total magneti-zation M
e
total=Me
R+Me
Tis 0. This point can exist in ferri-
magnets where the sublattice with the larger zero-temperaturemagnetization has a weaker ferromagnetic coupling, so thatthe magnetization decays more rapidly compared to the othersublattice. Additionally, if both sublattices have different gyro-magnetic ratios there is an angular momentum compensationpointT
Awhere the angular momenta of both sublattices are
equal, Me
T/γT=Me
R/γR. The solid lines in Fig. 2correspond to
fit functions, which are important when numerical simulationsare compared with analytical predictions in the followinganalysis. They are obtained via a polynomial fitting procedurewhich includes the mean-field critical behavior close to theCurie temperature.
In our simulations the excitation of either the FMM or
the EXM is done separately, by first loading a multispin con-figuration from equilibrium calculations for that temperature(Fig. 2) and then tilting the spin system with respect to an
external magnetic field H
0. While the FMM is excited by
tilting the total system by 30◦with respect to the external
magnetic field, for the EXM the angles between each sublatticeand the external magnetic field are varied separately, sincethe characteristic angle between the sublattices (Fig. 1)i s
temperature dependent.
11In this work the external magnetic
field is always parallel to the zaxis. Therefore the time
development of the xandycomponents of the magnetization
for both modes follows a damped precession motion with
Mx,y(t)∝exp(−bt)·cos(ωt+φ), (3)
where brepresents the damping rate, ωis the frequency, and
φcorresponds to a phase shift. The different frequencies and
214416-2TEMPERATURE DEPENDENCE OF THE FREQUENCIES AND ... PHYSICAL REVIEW B 86, 214416 (2012)
damping rates for either the FMM or the EXM have been
obtained by fitting directly to the resulting time developmentof thexandycomponents of the magnetization. Alternatively,
we tried to obtain the parameters above from a Fouriertransformation of the time-dependent magnetization data.However, these results turned out to be less accurate, probablydue to the fact that our simulations are very time-consuming,and consequently, the number of oscillations is not sufficientfor an analysis via Fourier transformation.
III. PROPERTIES OF THE NORMAL MODES
A. Transverse relaxation within the Landau-Lifshitz (LL)
equation
Earlier analytical calculations of the normal modes have
been based on two coupled nonthermal equations of motionfor the macroscopic magnetizations of sublattices using certainapproximations.
8,10–12Here we want to go beyond these
restrictions, first avoiding approximations and in the nextsection including thermal effects via the LLB equation. Wewill see that the use of the LLB equation will only affect thetemperature dependence of the damping.
Considering, in a two-sublattice micromagnetic LL equa-
tion, only intersublattice exchange, the Zeeman energy, andthe magnetorystalline anisotropy, the effective fields of bothsublattices are given by H
eff
ν=H0+Hex
ν+Han
ν. With the
magnetic field and the magnetocrystalline anisotropy parallelto the zaxis, the effective field contributions become H
0=
H0ez,Hex
ν=−AMκ, and Han
ν=± 2Dz
νMe,z
νez. Here, Arep-
resents the interlattice micromagnetic exchange stiffness andD
z
νis the micromagnetic anisotropy constant. By comparing
these expressions with the corresponding effective fields Hi
ν=
−1/μν·∂Hi
ν/∂Si
νfor the spin model [Eq. (1)], we obtain
the relations between atomistic and micromagnetic parametersA=ηJ
RT/μTμRandDz
ν=dz
ν/μ2ν, withν,κ=T,R andκ/negationslash=ν
as well as ηrepresenting the number of nn’s. In what follows
we use unit vectors nν=Mν/Me
ν.
The equations of motion for the two sublattices read
˙nν
γν=− (nν×H/prime
ν)−αν[nν×(nν×H/prime
ν)]
+AMe
κ{(nν×nκ)+ανAMe
κ[nν×(nν×nκ)]},(4)
where Me
κrepresents the equilibrium magnetization of the re-
spective other sublattice, H/prime
ν=H0+Han
ν,γνare the atomistic
gyromagnetic ratios, and ανare the damping constants.
Close to equilibrium, with nT=nT(nx
T,ny
T,1) and nR=
nR(nx
R,ny
R,−1), we can consider ∂tnz
T(R)=0,Mz
ν≈Me,z
ν, and
neglect second-order terms, leading to
˙nx
ν
γν=/parenleftbig
−ny
ν∓ανnx
ν/parenrightbig/parenleftbig
H0±2Dz
νMe
ν/parenrightbig
−AMe
κ/parenleftbig
αν/parenleftbig
nx
ν+nx
κ/parenrightbig
∓/parenleftbig
ny
ν+ny
κ/parenrightbig/parenrightbig
(5)
and
˙ny
ν
γν=/parenleftbig
nx
ν∓ανny
ν/parenrightbig/parenleftbig
H0±2Dz
νMe
ν/parenrightbig
±AMe
κ/parenleftbig
(nx
ν+nx
κ/parenrightbig
−αν/parenleftbig
ny
ν+ny
κ/parenrightbig/parenrightbig
. (6)
Here, the upper algebraic sign is for the transition metal, while
the lower one is for the rare-earth metal. By transforminginto the variables of the rotating system n+
ν=nx
ν+iny
νand
n−
ν−=nx
ν−iny
νand assuming an exponential solution n±
ν=
n0±
νexp(i˜ωt), we obtain
/parenleftbig
±˜ω−γT/parenleftbig
H0+2Dz
TMe
T+AMe
R/parenrightbig/parenleftbig
1±iαT/parenrightbig/parenrightbig
n±
T
−γTAMe
R(1±iαT)n±
R=0,
(7) /parenleftbig
±˜ω−γR/parenleftbig
H0−2Dz
RMe
R−AMe
T/parenrightbig
(1∓iαR)/parenrightbig
n±
R
+γRAMe
T(1∓iαR)n±
T=0.
The solution for the frequencies corresponds to the real part
of the two independent solutions for the FMM and EXM,respectively, and the damping rate is given by the imaginarypart. The effective damping parameter is then given by the ratioof damping rate to frequency,
11αeff=bfm,ex/ωfm,ex.D u et o
their length, we do not write down these equations, but we willuse the full solution later for comparison with numerical dataand an improved analytical approach. Note, however, that theeffective damping is the same for both modes if the sublatticedamping parameters α
νare assumed to be equal.
Based on this approach several approximated solutions for
the frequencies and effective damping parameter have beenderived in the past. However, the most common solutions forthe frequencies, by Wangsness
10for the FMM,
ωFMM=γTγR/parenleftbig
Me
T−Me
R/parenrightbig
/parenleftbig
γRMe
T−γTMe
R/parenrightbigH0, (8)
and by Kaplan and Kittel9for the EXM,
ωEXM=A/parenleftbig
γTMe
R−γRMe
T/parenrightbig
, (9)
make use of two main approximations: first, they neglect
the influence of damping and anisotropy completely; andsecond, they include the assumptions AM
e
ν/greatermuchH0, which
fails close to the Curie temperature TC;A(Me
T−Me
R)/greatermuch
H0, which fails close to the magnetization compensation
point TM; and A(γTMe
R−γRMe
T)/greatermuchH0, which fails close
to the angular momentum compensation point. Thus, theseapproximations predict an erroneous behavior at and closeto these characteristic temperatures. Similar approximationsin calculations of the effective damping parameter
11and the
solution for the frequency of the finite-anisotropy case byWalker
19fail here correspondingly. Note that also the solution
of the effective damping parameter,11
αeff=Me
RγTαR+γRαTMe
T
Me
RγT−Me
TγR, (10)
predicts a divergence at TAand therefore zero switching time.
As we will show in the following, in the full analytical solutionneither the frequencies nor the effective damping parametersdiverge at T
A. Instead, we find only characteristic maxima at
or close to the angular momentum compensation point.
B. Temperature-dependent transverse relaxation within the
LLB theory for ferrimagnets
The recently published derivation of the LLB equation
for two-component systems in Ref. 21explicitly refers to
a disordered ferrimagnet. Since for this work we consideran ordered ferrimagnet, we briefly repeat the derivation and
214416-3F. SCHLICKEISER et al. PHYSICAL REVIEW B 86, 214416 (2012)
present the formula for the ordered case in the explicit
form. In the following we derive the macroscopic equationfor the thermally averaged spin polarization m
ν=/angbracketleftSν
i/angbracketrightin
each sublattice ν=T,R, following the theory of the LLB
equation for ferromagnets.15The derivation uses a mean-field
approximation (MFA). Since in the present article we are notinterested in longitudinal motion, observed on the time scale of100 fs to 1 ps, we focus our attention on the LLB equation withtransverse motion only. Additionally, the longitudinal normalmodes are decoupled from the transverse ones, which allowsfor their separate consideration. Such an approximation leadsto the following sets of coupled LLB equations:
15
˙mν=γν/bracketleftbig
mν×HMFA
ν/bracketrightbig
−/Gamma1ν
⊥[mν×[mν×mν,0]]
m2ν(11)
with
mν,0=B(ξν,0)ξν,0
ξν,0,ξν,0≡μνHMFA
ν
kBT, (12)
where HMFA
ν is the average mean field acting on the spin, and
the relaxation rates are given by
/Gamma1ν
⊥=γνλνkBT
μν/parenleftbiggξν,0
B(ξν,0)−1/parenrightbigg
, (13)
where B(ξ)=coth (ξ)−1/ξis the Langevin function. In
Eq.(11) the first term describes the magnetization precession
and the second term the transverse relaxation. The next step isto use the MFA in Eqs. (12). The MFA expression for fields
in a ferrimagnet are well known; see also recent results forFeCoGd.
20Defining H/prime
eff,T(R)=H+HA,T(R)as the sum of the
external and anisotropy fields in each sublattice, we can writethe average molecular field acting at each sublattice spin as
μ
RHMFA
R=μRH/prime
eff,R+J0,RmR+J0,TRmT, (14)
μTHMFA
T=μTH/prime
eff,T+J0,TmT+J0,TRmR, (15)
where J0,T=ηJT,ηis the number of nn’s of transition-metal
type for the transition-metal spin, and J0,TRandJ0,Rhave
similar definitions. The minimum condition for the free energy,∂F/∂m
R=0 and ∂F/∂mT=0, leads to the coupled Curie-
Weiss equations,
mR=B(ξR,0)ξR,0
ξR,0,mT,0=B(ξT,0)ξT,0
ξT,0, (16)
the self-consistent solutions of which are the equilibrium
magnetization of each sublattice.
We treat the most general case where the continuous
approximation in each sublattice can be used. In orderto simplify the problem we decompose the magnetizationvector m
νinto two components, mν=/Pi1ν+τν, where /Pi1ν
is perpendicular to mκ, so that it can be expressed as /Pi1ν=
−[mκ×[mκ×mν]]/m2
κ, andτνis parallel to mκ, so that it
can be expressed as τν=mκ(mν·mκ)/m2
κ, where κ/negationslash=ν.
Similarly, the MFA exchange field HMFA
EX,νin Eqs. (15) and
(14) can be written as the sum of the exchange field parallel
and perpendicular to magnetization of the sublattice ν,
HMFA
EX,ν=H/bardbl
EX,ν+H⊥
EX,ν=/tildewideJ0,ν
μνmν+J0,νκ
μν/Pi1κ,where we have defined a new function, /tildewideJ0,ν(mκ,mν),a s/tildewideJ0,ν=
J0,ν+J0,νκ(mν·mκ)/m2
κ. Note that /tildewideJ0,νis not a constant but
a function of both sublattices’ magnetizations.
In the following, we consider the case where the transverse
contribution in the exchange field is small in comparison to
the longitudinal one, |H/bardbl
EX,ν|/greatermuch| H⊥
EX,ν|, i.e., where the non-
collinearities between sublattices are small. Finally, HMFA
ν/similarequal
H/bardbl
EX,ν+H/prime/prime
eff,ν, where H/prime/prime
eff,ν=H+HA,eff,ν+H⊥
EX,ν.W en o w
expand mν,0up to the first order in H/prime/prime
eff,ν, under the assumption
|H/bardbl
EX,ν|/greatermuch| H/prime/prime
eff,ν|.F r o mE q s . (16) the value of mν,0in the
above conditions21can be substituted into Eq. (11), leading to
the following equation of motion:
˙mν=γν[mν×H/prime/prime
eff,ν]−/Gamma1ν
⊥Bνμν
mν˜J0,ν[mν×[mν×H/prime/prime
eff,ν]]
m2ν.
(17)
In the same approximation we have Bν/similarequalmν,B(ξ0,ν)/ξ0,ν/similarequal
(kBT)/˜J0,ν, and, finally,
/Gamma1ν
⊥=γναν
⊥kBT
μν/parenleftbiggξ0,ν
B(ξ0,ν)−1/parenrightbigg
/similarequalγναν
⊥/parenleftbigg˜J0,νmν
μνBν/parenrightbigg
,(18)
where αν
⊥=λν(1−kBT
/tildewideJ0,ν). Hence the final form of the LLB
equation is
˙mν=γν[mν×H/prime/prime
eff,ν]−γναν
⊥[mν×[mν×H/prime/prime
eff,ν]]
m2ν.(19)
The temperature dependence of the damping parameters is
obtained in the first order in deviations of magnetizationfrom their equilibrium value. Note that in Eq. (17) all the
terms are of the first order in the parameter H
/prime/prime
eff,ν/H||
EX,νso
that the damping parameters should be evaluated in the zeroorder in this parameter. As a result, the effective dampingparameter depends on the temperature Tvia the equilibrium
magnetization values as
/tildewideJ
0,ν/similarequalJ0,νme
ν−J0,νκme
κ
meν. (20)
Note also that the field H/prime/prime
effcould be substituted in the pre-
cession and the transverse damping terms with Heff(including
the exchange field coming from the opposite sublattice), sincethe action of the component of this field parallel to themagnetization m
νis 0. Note also that Eq. (19) does not have
exactly the LL form due to the presence of the m2
νterm in
the denominator. The difference between the LL and the LLBdamping is discussed for the ferromagnetic case in Refs. 22
and23.
For a comparision with the results in Sec. III A ,E q . (19)
can be written in terms of the variable n=m/m
e. After renor-
malizing the equation and linearizing it close to equilibriumat a given temperature, one gets a similar result as for the LLequation [Eqs. (5)and (6)] but with temperature-dependent
parameters,
˜α
T
⊥(T)=αT
me
T(T)/parenleftbigg
1−me
T(T)kBT
J0,Tme
T(T)−J0,TRme
R(T)/parenrightbigg
,(21)
214416-4TEMPERATURE DEPENDENCE OF THE FREQUENCIES AND ... PHYSICAL REVIEW B 86, 214416 (2012)
and
˜αR
⊥(T)=αR
me
R(T)/parenleftbigg
1−me
R(T)kBT
J0,Rme
R(T)−J0,RTme
T(T)/parenrightbigg
, (22)
where the parameters λR,λTwere substituted by αR,αTto
comply with the standard notations of the micromagneticequation. Here, similarly to the procedure described in Ref. 20,
we have renormalized the exchange parameters within theMFA. The replacement of Eqs. (21) and(22) in Eq. (7)leads
to an increase in the effective damping parameters for bothmodes at high temperatures, which agrees with the numericalfindings. It is that combination of equations that we call theanalytical solution in the following.
IV . RESULTS AND DISCUSSION
Let us start with a discussion of the zero-anisotropy case.
Since in our simulations an external magnetic field H0=
0.02JT/μTis constantly switched on, for zero anisotropy this
magnetic field will have to change its sign at the magnetizationcompensation point T
Min order to avoid a switching of the
whole system. This change leads to the discontinuity of theanalytical solutions [Eq. (7)] shown in Fig. 3atT
M.F o r
the frequencies [Fig. 3(a)] as well as the effective damping
parameters [Fig. 3(b)] we obtain a very good agreement
between analytical and numerical solutions in both modes andfor the whole temperature range. We note that the value of thefrequency of the FMM first tends to 0 below the magnetizationcompensation point T
M, where it starts to increase to its
exchange (EXM)ferromagnetic (FMM)frequency ωμT/JTγT0.3(a)
(b)0.25
0.2
0.15
0.1
0.05
0
αν
⊥=constEXMFMM
temperature kBT/JTeffective damping αeff
TC3 2.52 1.5TATM 0.500.15
0.1
0.05
0
FIG. 3. (Color online) Frequencies and effective damping param-
eters in the zero-anisotropy case. Temperature dependence of (a)
frequencies and (b) effective damping parameters αeff. Numerically
obtained data points are compared with analytical solutions. The
switching of the external magnetic field H0l e a d st oag a pi nt h e
solutions at the magnetization compensation point TM.maximum above the angular momentum compensation point
TA. After decreasing with higher temperatures the value of
the frequency of the FMM converges to a constant level.For the EXM the effect of changing the relative directionof the external field is stronger, since, in comparison tothe approximated solution
9[Eq. (9)], the value of the EXM
frequency is constantly shifted proportionally to the strengthofH
0. Above the angular momentum compensation point TA
the frequencies of both modes reach the same value, where
the FMM has its maximum and the EXM reaches a localminimum.
Note that there is an increase in the effective damping
parameter at high temperatures that is much stronger forthe EXM. Interestingly, without considering the temperaturedependence of the sublattice damping parameters [Eqs. (21)
and (22)] in the analytical solution [Eq. (7)] and assuming
simply the microscopic damping constant λ=0.01 to describe
the relaxation dynamics of the sublattice magnetizations, theeffective damping parameters α
efffor both modes are equal.
This solution, plotted as the dashed line in Fig. 3(b), does
not coincide with our numerical data. Only considering thetemperature dependence of the sublattice damping parameters,the effective damping parameters α
effof both modes become
different and describe the increase for both modes at hightemperatures correctly [Fig. 3(b)]. Note also that the influence
of the temperature dependence for ˜ α
T
⊥(T) and ˜ αR
⊥(T)i s
negligible at low temperatures but becomes very importantwith increasing temperatures.
For the finite-anisotropy case (Fig. 4)w eh a v eu s e dt h e
following values as atomistic damping parameters, external
(a)
EXMdz=0.01FMM dz=0.01frequency ωμT/JTγT0.35
0.3
0.25
0.2
0.15
0.1
0.05
0
(b)
EXMdz=0.01FMM dz=0.01αν
⊥=const
temperature kBT/JTeffective damping αeff
TC3 2.52 1.5TATM 0.500.014
0.012
0.01
0.008
0.006
0.004
0.002
FIG. 4. (Color online) Frequencies and effective damping param-
eters in the finite-anisotropy case. Temperature dependence of (a)
frequencies and (b) effective damping parameters αeff. Numerically
obtained data points are compared with analytical solutions.
214416-5F. SCHLICKEISER et al. PHYSICAL REVIEW B 86, 214416 (2012)
field, and anisotropy constant: λ=0.001,H0=0.01,JT/μT,
anddz=0.01JT. Here, we have used smaller atomistic
damping compared to the previous simulations, since theconsideration of an anisotropy leads to an increase in thediscrepancy between simulated and ideal damped modes, sothat more cycles had to be fitted in order to obtain goodresults. With anisotropy, consequently, the resulting anisotropyfield compensates the external field and avoids switching atthe magnetization compensation point T
Min our simulations.
Therefore we have not switched the direction of H0in
this case. For higher temperatures, however, due to thermalexcitation as well as the decaying anisotropy field, the systemstarts switching anyway. Therefore the effective dampingparameters could not be obtained for the high-temperaturerange.
For the frequencies [Fig. 4(a)] the consideration of a
uniaxial anisotropy leads to the fact that the minimum at themagnetization compensation point vanishes. Again, above theangular momentum compensation temperature T
Awe obtain
a maximum for the FMM frequency and a minimum for theEXM frequency. We note that the shift of this characteristicpoint from T
Ato higher values is proportional to the strength
of the external magnetic field as well as the anisotropy.
Regarding the effective damping parameters [Fig. 4(b)]a
finite anisotropy leads to a less pronounced maximum at TA.
Once again, the dashed line in Fig. 4(b) corresponds to the
analytical solution without consideration of the temperaturedependence of the sublattice damping, leading to the equalityof the effective damping parameters of both modes, notshowing the increase in α
efffor higher temperatures. Besides
the good agreement between numerical and analytical resultswhen the temperature dependence of the sublattice dampingis taken into account, we now also obtain a good agreementwith the experimental findings of Stanciu et al.
13Thus we are
able to reproduce these experimental findings qualitatively byconsidering a uniaxial, magnetocrystalline anisotropy as wellas temperature-dependent sublattice damping parameters asderived within the framework of the LLB equation. Thesecoinciding findings clearly demonstrate the failure of theanalytical solutions based on the LL and LLG equations ofmotion
8,10–12for high temperatures.
In Fig. 5the analytical solutions [Eqs. (7),(21), and (22)]o f
the frequencies of both modes as well as the effective dampingparameter for the FMM are shown for different strengthsof the uniaxial anisotropy. Here, with H
0=0.01JT/μTand
λ=0.01, we have also not switched the external field at
TM. First, we note that due to the temperature dependence
of the anisotropy field in the high-temperature regime, theinfluence of the strength of the anisotropy constant d
zbecomes
smaller with increasing temperatures. This effect leads to theconvergence of all sets of curves for different anisotropieswith increasing temperatures up to T
C, where the anisotropy
fields vanish and the different curves join. Second, we seethat the frequencies of both modes increase with increasinganisotropy. This effect is much stronger for the FMM.Additionally, the maximum of the frequency of the FMMas well as the minimum of the frequency of the EXM areshifted from the the angular momentum compensation point T
A
towards higher temperatures with increasing anisotropy. For
the effective damping parameter, with increasing anisotropy(a)
dz=0.04dz=0.02dz=0.01dz=0.005frequency(FMM) ωμT/JTγT0.12
0.1
0.08
0.06
0.040.02
0
(b)
dz=0.04dz=0.02dz=0.01dz=0.005frequency(EXM) ωμT/JTγT
0.3
0.25
0.2
0.15
0.1
0.05
0
(c)
dz=0.04dz=0.02dz=0.01dz=0.005
temperature kBT/JTeffective damping(FMM) αeff
TC3 2.52 1.5TATM 0.500.1
0.08
0.06
0.04
0.02
FIG. 5. (Color online) Frequencies and effective damping param-
eters in the finite-anisotropy case. Temperature dependence of (a) theferromagnetic mode frequency, (b) the exchange mode frequency,
and (c) the effective damping parameter α
effof the FMM for different
strengths of the magnetocrystalline anisotropy. Analytical results asexplained in the text.
we obtain a decrease and a washing-out of the maximum close
toTA.
V . CONCLUSIONS
A detailed investigation of the dynamics of ferrimagnets
was performed by means of computer simulations as wellas analytically. Formulas were derived for the frequenciesand effective damping parameters of bot, the FMM and theEXM. We show that a correct calculation does not predict anydivergence either of the effective damping parameters or ofthe frequencies close to the angular momentum compensationpoint, but only a finite maximum. Nevertheless, both thefrequencies and the effective damping parameters stronglydepend on the temperature, with that explaining the largevariations of relaxation times in ferrimagnets, especially inoptomagnetic experiments with pronounced heating effects.
Similarly to the experimental results (see Fig. 3 in
Ref. 13) and unlike predictions based on the macroscopic,
214416-6TEMPERATURE DEPENDENCE OF THE FREQUENCIES AND ... PHYSICAL REVIEW B 86, 214416 (2012)
two-sublattice LLG8,10–12equation, we find an increase in
the effective damping at a temperature approaching theCurie temperature. This stresses the importance and validityof the recently derived two-sublattice LLB equation forfinite-temperature micromagnetics. The latter builds a newbasis for finite-temperature micromagnetic calculations offerrimagnets.ACKNOWLEDGMENTS
This research received funding from the European Commis-
sion via the 7th Framework Programme grant FEMTOSPIN.The authors in Madrid also acknowledge funding by theSpanish Ministry of Science and Innovation under Grant No.FIS2010-20979-C02-02.
*Correspondence author: frank.schlickeiser@uni-konstanz.de
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214416-7 |
PhysRevLett.126.026601.pdf | Spin Fluctuations in Quantized Transport of Magnetic Topological Insulators
Yu-Hang Li1,*and Ran Cheng1,2,†
1Department of Electrical and Computer Engineering, University of California, Riverside, California 92521, USA
2Department of Physics, University of California, Riverside, California 92521, USA
(Received 1 October 2020; accepted 23 December 2020; published 13 January 2021)
In magnetic topological insulators, quantized electronic transport is intertwined with spontaneous
magnetic ordering, as magnetization controls band gaps, hence band topology, through the exchangeinteraction. We show that considering the exchange gaps at the mean-field level is inadequate to predict
phase transitions between electronic states of distinct topology. Thermal spin fluctuations disturbing the
magnetization can act as frozen disorders that strongly scatter electrons, reducing the onset temperature ofquantized transport appreciably even in the absence of structural impurities. This effect, which has hitherto
been overlooked, provides an alternative explanation of recent experiments on magnetic topological
insulators.
DOI: 10.1103/PhysRevLett.126.026601
The inquiry into topological materials has recently
mingled with the quest for low-dimensional magnets,giving birth to an emerging frontier known as magnetic
topological insulators (TIs) where a topologically nontrivial
band gap is controllable by spontaneous magnetic ordering[1–4]. Therefore, manipulating magnetization becomes a
new tuning knob of the quantized electronic transport. Forexample, in a TI with coexisting ferromagnetic order, thesystem should exhibit the quantum anomalous Hall (QAH)effect when a finite magnetization is established below theCurie temperature ( T
c)[5]. However, the QAH effect was
first realized in a magnetically doped TI in which themagnetic moments are embedded randomly [6], leading to
strong disorder effects that significantly reduce the electron
mobility and hence inhibit the appearance of quantizedtransport [7–10]. As a result, the actual onset temperature of
the QAH effect in such a material is much lower than themagnetic ordering temperature.
Removing this roadblock calls for magnetic TIs in which
the magnetic moments are arranged periodically on alattice. This can be achieved in either an intrinsic magnetic
TI[11–14]or a heterostructure with a TI sandwiched
between two magnetic thin films [15,16] . However, the
quantized transports in these systems turned out to be asvulnerable to an increasing temperature as those studied inmagnetic doped TIs [17]. While this discouraging obser-
vation might still be attributed to structural impurities, itremains an open question what is responsible for thedisappearance of QAH effect at a temperature far below T
c.
In this Letter, we introduce an alternative mechanism in
magnetic TIs that can substantially reduce the onset tempera-ture of quantized transport even in the absence of structuralimpurities. Contrary to the electrons governed by anformidably high Fermi temperature, spin fluctuations (SF)disturbing the magnetic order are very susceptible to thermalagitations [18]. Because spin fluctuations take place on a
timescale that is orders of magnitude larger than the electronrelaxation time [19], the electron dynamics can adjust
adiabatically to the instantaneous configuration of magnetic
moments, seeing the instantaneous spin fluctuations as arandom potential almost frozen in time. For this reason,
thermal spin fluctuations in the magnetic degree of freedom
can manifest as effective disorders affecting the electrontransport, even though magnetic atoms are arranged per-
fectly on a lattice free of structural impurities.
As schematically illustrated in Fig. 1(a), we model the
system as a magnetic trilayer where topological electrons
FMFM
TI
FMFM(a)
(b)(c)
FIG. 1. (a) Schematic of a magnetic TI in the presence of spin
fluctuations. (b) The mean field scaled by Ms≡hMðT→0Þifor
B→0and the susceptibility χas functions of temperature.
(c) Probabilities of different Szon an individual spin versus
temperature for S¼5=2.PHYSICAL REVIEW LETTERS 126, 026601 (2021)
0031-9007 =21=126(2) =026601(5) 026601-1 © 2021 American Physical Societyare confined between two magnets, which applies to not
only a heterostructure but also an intrinsic magnetic TI with
uniform magnetic ordering [20]. To ensure the relative
orientation of the two magnetic layers, we include an
auxiliary magnetic field Balong zaxis to stabilize the
system, but the B→0limit will be taken at the end. Now
let us quantify the magnetization dressed with spin fluc-tuations in an individual magnetic layer, which is supposed
to be independent of all other layers as schematically
illustrated in Fig. 1. Based on recent experiments
[12–14,16] , the magnet under consideration can be cap-
tured by the minimal Hamiltonian
H
M¼−JX
hijiSi·Sj−κX
iS2
i;z−gμBBX
iSi;z;ð1Þ
where J>0is the (intralayer) Heisenberg exchange
coupling, κis the uniaxial anisotropy, gis the Land´ e
factor, μBis the Bohr magneton, and hijienumerates all
nearest neighbors. The spin vector Siis dimensionless.
In the mean-field approximation [18], spins become
effectively decoupled while the exchange interaction that
entangles different spins recasts as an effective mean
field hMi¼JhP
iSi;ziT=ðgμBNÞwhere Nis the total
number of spins and h/C1 /C1 /C1iTdenotes the thermal average.
Consequently, the system becomes a paramagnet interact-
ing with a total magnetic field Btot¼BþhMias if there is
no exchange interaction. In the limit J≫κ, the effective
Zeeman energy is E¼−gμBðBþ<M> ÞP
iSiz, from
which the mean field hMican be solved self-consistently
[18]. Figure 1(b) shows the mean field hMiand
the susceptibility χ≡limB→0½hMðBÞi−hMð0Þi/C138=Bfor
S¼5=2as a function of temperature scaled by the
Curie temperature Tc¼aJS ðSþ1Þ=3kBon a simple
square lattice with the coordination number a¼4.A s
every spin is now isolated from all other spins, theprobability of an individual spin S
itaking Szperpendicular
to the plane is determined straightforwardly by the
Boltzmann distribution PðSzÞ¼expð−ε=kBTÞ=Zwhere ε¼
−gμBSzðBþhMiÞand the partition function Z¼
sinh ½ð2Sþ1Þy/C138=sinhywithy¼a J<M>= 2T. As plot-
ted in Fig. 1(c), the spin is fully polarized to Sz¼Sat
T¼0, whereas when T→Tcall possible quantized values
ofSztend to be equally probable, destroying the magneti-
zation completely at Tc.
The mean-field approach enables us to determine the
projection of a given spin Sionzdirection probabilistically.
With the spherical parametrization Si¼Sðsinθicosϕi;
sinθisinϕi;cosθiÞ, it amounts to determining θiprobabil-
istically. The azimuthal angle ϕi, on the other hand, cannot
be captured by the mean-field picture. Because we only
consider the incoherent thermal spin fluctuations, ϕi
should be uniformly distributed within the range ½0;2πÞ.
Moreover, because different modes of spin excitation
superimpose with completely random phases, ϕishouldbe independent of its neighbors. In other words, the variable
ϕis spatially uncorrelated, or hϕiðtÞϕjðtÞi∼δijat any
instant of time. In contrast, the temporal correlation of ϕis
much larger than the electron relaxation time. Specifically,
hϕiðtÞϕiðt0Þi∼e−jt−t0j=τs, where the characteristic decay
time τsmay depend on the mode of excitation, but a
qualitative estimation is that τs∼1=αωwhere αis the
Gilbert damping and ωis the frequency of ferromagnetic
resonance. So a typical value of τsis on the order of
10–100 ns. Comparatively, the electron relaxation time τe
determined by the Fermi energy is on the order of 1 –10 fs,
which is 7 orders of magnitude smaller than τs. A similar
argument applies to the correlation of θas well. Therefore,
while spin fluctuations are spatially uncorrelated, they
exhibit extremely long temporal correlation, which
amounts to a random potential frozen in time acting onthe electrons [21]. This justifies the adiabatic approxima-
tion essential to our following discussions.
Even though Dirac electrons and magnetic layers repeat
periodically in an intrinsic magnetic TI, the system can be
simplified as a trilayer heterostructure consisting of onlyone TI layer sandwiched between two magnetic layersas illustrated in Fig. 1(a) [20] . Under the basis ψ
k¼
ðct
k↑;ct
k↓;cb
k↑;cb
k↓ÞTwith ctðbÞ
kσannihilating an electron of
momentum kand spin σon the top (bottom) surface, the
magnetic TI can be described by the Hamiltonian
HMTI ¼HTIþHex, where [5,22,23]
HTI¼vFðkyτz⊗σx−kxτz⊗σyÞþmðkÞτx; ð2Þ
Hex¼JexX
iSi·σ: ð3Þ
Here, vFis the Fermi velocity, Jexis the exchange coupling
between the Dirac electrons and the magnetic moments,
mðkÞ¼m0þm1k2describes the overlap of Dirac electrons
in the top and bottom surfaces, and σandτare the vectors of
Pauli matrices acting on the spin and layer degree of freedom,
respectively. The lattice wave vectors kx;yare defined in the
first Brillouin zone of a L×Wsquare lattice with the lattice
constant a0≡1. Since the Fermi temperature TFis orders of
magnitude larger than Tc, the electron dynamics is effect-
ively in the zero temperature regime as we focus on T<T c
[24,25] . Unless otherwise stated, we will take vF¼1
as the energy unit and assume m1¼1,kBTc¼0.002,
Jex¼0.035,a n d S¼5=2. However, our theory is universal
and not limited to these special parameters.
To demonstrate the influence of spin fluctuations on the
electron transport more clearly, it is instructive to first lookinto the homogeneous case without any spin fluctuations, in
which S
zis described by the mean field while SxandSyare
completely ignored. In this situation, the lattice periodicityis restored in the exchange field, so we can transform the
exchange Hamiltonian in Eq. (3)into the momentum space,
andH
MTIðkÞ¼HTIþλτ0⊗σz, where λ¼gμBJexhMiisPHYSICAL REVIEW LETTERS 126, 026601 (2021)
026601-2the homogeneous exchange field that depends on tempera-
ture through the mean field hMi. Diagonalizing HMTIðkÞ
gives the band dispersion and the corresponding eigen-
states, based on which we can calculate the Chern numbers
characterizing different topological phases. At low temper-atures, λ>m
0, the system is a QAH insulator with a Chern
number C¼1. By contrast, the system becomes a normal
insulator (NI) with C¼0when λ<m 0at high temper-
atures. Setting λ¼m0solves the critical temperature Thm
for the homogeneous case. Therefore, the system under-
goes a topological phase transition at finite temperature
below Tconly if m0is less than the maximum exchange
field δ≡gμBJexMswithMs¼hMðT→0Þithe saturated
mean field. In Fig. 2, the critical temperature Thmfor the
homogeneous case is marked by the black arrows fordifferent ratios of m
0=δ.
Next, we turn to the transport property in the presence of
spin fluctuations, which, as discussed above, act on
electrons as a frozen random potential. In the considered
magnetic TI, the appearance of topological edge states canbe minimally revealed in a two-terminal junction, where the
longitudinal conductance is σ¼e
2=h(σ¼0) in the QAH
(NI) phase. We calculate σthrough the Landauer-Büttiker
formula [26] σ¼Tr½ΓLGrΓRGa/C138, where Γβ¼i½Σr
β−ðΣr
βÞ†/C138
with β¼LorR, and Gr¼ðGaÞ†¼ðEF−HMTI−
Σr
L−Σr
RÞ−1with EFthe Fermi energy and Σr
βthe self-
energy due to the coupling with metallic leads.To simulate the random potential, we generate a set of
L×W¼200×200 random numbers representing Sz¼
Scosθon each lattice according to the probability distri-
bution PðSzÞ¼expð−ε=kBTÞ=Zdetermined by the mean-
field approach. We also assign each spin a random phase ϕ
specifying its transverse component as discussed previ-ously. Then we calculate the conductance σunder this
particular configuration of random potential. Repeating this
procedure for 160 times, we obtain the ensemble average of
σ, which is shown in Figs. 2(a)–2(c) as a function of
temperature for different m
0. We see that σchanges from
e2=hto 0 (i.e., transition from the QAH to NI phase) at a
critical temperature TSFmanifestly below what it would be
without spin fluctuations (i.e., Thmdetermined by solving
λ¼m0), as indicated by the red arrows. The reduction of
critical temperature appears to be more striking for largerm
0in Fig. 2.F o r m0¼0.8δ[Fig. 2(c)],σeven becomes ill
quantized in the QAH phase due to the finite-size effect
[27]. If the system is infinite, σwould be a step function
across the critical point. Finite-size effects will be discussedin more detail later.
The topological phase transition between the QAH
insulator and the NI can be alternately characterized
by the current noise SðωÞ¼
1
2R
dτeiωτhδˆIðtÞδˆIðtþτÞþ
δˆIðtþτÞδˆIðtÞi, where δˆIðtÞ¼ ˆIðtÞ−hˆIðtÞiwith ˆIðtÞthe
current operator [28,29] . Using the nonequilibrium Green ’s
function [30], we calculate the zero-frequency current noise
S0. Figures 2(d)–2(f)show the ensemble average of S0
corresponding to Figs. 2(a)–2(c). The noise S0peaks at the
critical point and extends over a finite range of temperature
due to finite-size effects; it will become infinitely sharp atthe critical point if the system is infinite. We see that σand
S
0plotted in Fig. 2perfectly agree with the relation S0¼
2e3Vσð1−σÞ=hwhere Vis the bias voltage across the
junction, affirming that the QAH edge states can bedescribed by a one-channel ballistic tunneling model [29].
Without spin fluctuations, the mean field hMi, hence the
exchange field λ, decreases as temperature is raised. When
λbecomes comparable to m
0, the chiral edge states on
opposite transverse edges start to overlap, merging into thebulk states [27]. This destroys the electron transport
and diminishes the conductivity. Spin fluctuations as
random potential, on the other hand, brings about scatteringof the chiral edge states, which facilitates their overlapping
and merging into the bulk states, so the phase transition
takes place at a reduced temperature. This subtle mecha-nism can be unraveled by studying the nonequilibrium
current distribution inside the magnetic TI. Under a bias
voltage Vacross the system, the local current flowing
from site ito its neighbor jis given by J
ne
i→j¼
ImfTr½ˆtijðGrΓLGaÞji/C138g2e2V=h where ˆtijis the hoping
matrix [31].
Figure 3shows the distributions of nonequilibrium
currents in the TI at three representative temperatures for
m0¼0.5δ[(a)–(c)] and m0¼0.8δ[(d)–(f)], respectively.(a) (d)
(b) (e)
(c) (f)
FIG. 2. (a) –(c) Ensemble average of the two-terminal conduct-
ance σas a function of temperature for different m0and fixed
δ¼gμBJexMs(the maximum exchange field). (d) –(f) The
corresponding zero-frequency current noise S0. The red arrows
mark the critical temperature TSFobtained by the finite-size
scaling shown in Fig. 4. The black arrows mark where m0¼λ,
representing the critical temperature Thmin the absence of spin
fluctuations. The system size is L¼W¼200and the error bars
are magnified ten times for visual clarity.PHYSICAL REVIEW LETTERS 126, 026601 (2021)
026601-3AtT≪TSFandm¼0.5δ[Fig. 3(a)], the electron flow is
fully confined to one edge, so the conductance is quantized
—a hallmark of the QAH effect. For m¼0.8δ[Fig. 3(d)],
however, the edge current becomes much wider so that it
partially leaks into the opposite edge and flows backwards,
leading to an ill-quantized conductance as shown in Fig. 2(c).
At the true critical point T¼TSF[(b) and (e)] where λ>m 0,
spin fluctuations strongly scatter the electrons from one edgeto the other, because of which electrons cannot propagate in
one direction dictated by the applied bias voltage; they are
instead back-scattered to the left lead. Accordingly, the chiraledge states become indistinguishable from the bulk states.
AtT¼T
hm[(c) and (f)] where λ¼m0, the edge states
completely disappear and the conductance is identically zero.Integrating the current density over the full width Wyields a
conductance that quantitatively agrees with the results shown
in Fig. 2, confirming the validity of the nonequilibrium
distribution.
In Fig. 4, we draw a full phase diagram on the m
0−T
plane. Because the specific profiles of σandS0depend on
the system size, the actual critical temperature TSFcan be
extracted by finite-size scaling. To this end, for a given setof variables, we calculate σas a function of Tfor three
different system sizes and identify the intersection of the
three curves as T
SF(see the inset of Fig. 4). The criticaltemperature TSF(Thm) calculated in the presence (absence)
of spin fluctuations is depicted by red dots (dashed lime
curve). We see that both TSFandThmdecreases monoton-
ically with an increasing ratio of m0=δ. However, the
discrepancy ΔT¼Thm−TSF, which measures the reduc-
tion of critical temperature due to spin fluctuations, reachesmaximum around m
0=δ¼0.75;ΔTvanishes for both
m0=δ→0andm0=δ→1limits.
Finally, we check the consistency of our conclusion by
calculating the Hall conductance σxyusing the noncom-
mutative Kubo formula with periodic boundary conditions,in which the Chern number is obtained directly from thereal space rather than a momentum-space integral [32,33] .
For a system of L¼W¼50, we numerically calculate σ
xy
and superimpose the result in Fig. 4, where it exhibits a
phase boundary that matches TSFremarkably well.
We stress that the mechanism of spin fluctuations studied
in this Letter is entirely different from the ordinarymagnon-electron scattering. First of all, we have consideredthe adiabatic regime such that spin fluctuations are frozenin time, whereas magnons are propagating spin waves.
Second, spin fluctuations form a background random
potential that scatters the electrons passively, whilereversely, the excitation of spin fluctuations by electronsis ignored. Third, the physical picture of spin fluctuationspersists up to T
c, whereas magnons are well defined only at
low temperatures. In addition, the mechanism here is
intrinsic, different from structure impurities, which canbe removed by improving the material quality.
To close our discussion, we further remark that
if adjacent magnetic layers are antiferromagnetically(a)
(b)(d)
(e)
(f) (c)
FIG. 3. Nonequilibrium current distributions for m0¼0.5δ
(a)–(c) and m0¼0.8δ(d)–(f) at T¼0.02Tc,T¼Ttsf, and
T¼Thm. Red arrows indicate local current densities and direc-
tions.
FIG. 4. Phase diagram of the two-terminal conductance on them
0−Tplane. The inset illustrates how TSFis obtained from
finite-size scaling. The red dots plot TSFand the red curve is a
guide to the eye that marks the phase boundary in the presence ofspin fluctuations. The dashed lime curve marks T
hm, which is the
phase boundary in the absence of spin fluctuations. The back-ground color shows the Hall conductance calculated independ-ently for a system of L¼W¼50, which conforms with T
SF.PHYSICAL REVIEW LETTERS 126, 026601 (2021)
026601-4directed, the Dirac electrons will form an axion insulator
rather than a QAH insulator below Tc, which has been
realized in MnBi 2Te4[13]. Unlike the QAH insulators, the
topological behavior in an axion insulator does not mani-
fest in transport properties; instead, it leads to quantizedmagnetoelectrical responses [15,34 –36].H o w e v e r ,b y
performing a similar analysis of spin fluctuations, we find
that the coefficients of magnetoelectrical responses onlyexperience negligible changes.
In summary, we have demonstrated that spin fluctuations
can play the role of a frozen random potential that leads to asignificant reduction of the onset temperature of quantized
transport in a magnetic TI. Even in the absence of structural
disorders, considering the exchange gap at the mean-fieldlevel is insufficient to predict the critical temperature
correctly. Our result provides an alternative explanation
of the puzzling in recent experiments, and points out anunavoidable mechanism suppressing the quantized trans-
port even in clean magnetic TIs.
We acknowledge insightful discussions with C. Z. Chen
and Y. Z. You. This work was supported in part by theUniversity of California, Riverside.
*yuhang.li@ucr.edu
†rancheng@ucr.edu
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026601-5 |
PhysRevB.86.144417.pdf | PHYSICAL REVIEW B 86, 144417 (2012)
Investigation of spin wave damping in three-dimensional magnonic crystals using
the plane wave method
J. Romero Vivas,1,2S. Mamica,1M. Krawczyk,1,*and V . V . Kruglyak3
1Faculty of Physics, Adam Mickiewicz University in Poznan, Umultowska 85, Poznan, 61-614 Poland
2Electrolaer, Godard # 46, Col. Guadalupe Victoria., C.P . 07890, Mexico D.F ., Mexico
3School of Physics, University of Exeter, Stocker Road, Exeter, EX4 4QL, United Kingdom
(Received 21 August 2012; published 25 October 2012)
The Landau-Lifshitz equation with a scalar damping constant predicts that the damping of spin waves
propagating in an infinite homogeneous magnetic medium does not depend on the direction of propagation.This is not the case in materials with a periodic arrangement of magnetic constituents (known as magnoniccrystals). In this paper, the plane wave method is extended to include damping in the calculation of the dispersionand relaxation of spin waves in three-dimensional magnonic crystals. A model material system is introducedand calculations are then presented for magnonic crystals realized in the direct and inverted structure and fortwo different filling fractions. The ability of magnonic crystals to support the propagation of spin waves ischaracterized in terms of a figure of merit, defined as the ratio of the spin wave frequency to the decay constant.The calculations reveal that in magnonic crystals with a modulated value of the relaxation constant, the figureof merit depends strongly on the frequency and wave vector of the spin waves, with the dependence determinedby the spatial distribution of the spin wave amplitude within the unit cell of the magnonic crystal. Bands anddirections of exceptionally long spin wave propagation have been identified. The results are also discussed interms of the use of magnonic crystals as metamaterials with designed magnetic permeability.
DOI: 10.1103/PhysRevB.86.144417 PACS number(s): 75 .30.Ds, 75 .75.−c, 75.78.−n, 76.90.+d
I. INTRODUCTION
In photonics and phononics, periodic patterning has proven
itself as an effective way to obtain materials with custom-made properties. Analogously, materials with a periodicarrangement of magnetic constituents [i.e., magnonic crystals(MCs)], can show properties not found in bulk samples. Thesecrystals can be used for the fabrication of new devices inwhich spin waves (SWs) act as information carriers. Thus,the investigation of properties of three-dimensional (3D) MCswith nanoscale lattice constants is of both scientific andpractical interest. Reviews of possible applications of MCs
with modulation at different length scales can be found, for
example, in Refs. 1–5.
Loss is an unavoidable property of materials. Hence, it has
to be taken into account in the design of magnonic devicesand MCs. Studies of the damping of spin waves travelingin thin ferrite films have already been presented.
6,7Some
of the damping effects in one-dimensional MCs have alsobeen discussed in the literature.
8–10In two-dimensional (2D)
MCs, the considerations to include damping effects in the
plane wave method (PWM) have been published in Ref. 11.
As a continuation of that work, we have implemented losscalculations within the PWM in the case of 3D MCs with theaim of exploring the options for tailoring the intrinsic spinrelaxation. It was shown that 3D MCs with lattice constantsin nanoscale should have magnonic gaps when constituent
ferromagnetic materials are chosen properly.
12,13This gap
can be obtained for many crystal structures, including cubic,simple hexagonal, and close packed lattices.
12,14,15
The possibility for tailoring damping in magnetic ma-
terials is intensively studied in the literature. This direc-tion of research is developed not only in the context ofpotential applications [e.g., within spintronics (in particular,
spin transfer torque devices) and magnonic devices] butalso to understand fundamental experimental results in thephysics of magnetism.
16–21There are two contributions to
spin relaxation usually identified, intrinsic and extrinsic. Theformer is usually related to the spin-orbit coupling and isdescribed by the phenomenological Gilbert damping term.In principle, the damping constant can be anisotropic but in3D metallic ferromagnets under the conditions used in SWcalculations this anisotropy is usually averaged out.
22,23For the
extrinsic damping the main contribution is usually attributedto two-magnon scattering processes,
24,25which can be related
to the scattering on defects26including also their periodic
distribution.19,27The influence of the periodic modulation on
extrinsic damping processes (i.e., two-magnon scatterings)were studied in Ref. 27. It was shown that a periodic scattering
potential for magnons can result in a significant increase inthe spin relaxation rates and can enable the tailoring of theanisotropy of damping.
18,27In another study, the influence of
retardation effects on the effective damping was investigated.28
It was shown that the lifetime of SWs depends on theretardation time and long-living SWs for selected wave vectorswere found.
In this paper we show that 3D MCs offer the possibility of
tailoring the strength and anisotropy of the intrinsic dampingof SWs. We neglect the extrinsic damping as well as anycontribution from the surroundings
29as we assume that the
MCs fill the whole space. We also neglect magnetic relaxationdue solely to interfaces.
30The results of our calculations
using the above mentioned model are presented for 3D MCscomposed of ferromagnetic spheres in a ferromagnetic matrixin a simple cubic (sc) lattice. We assume that in each ofthe two constituent materials the coefficient of the Gilbert
144417-1 1098-0121/2012/86(14)/144417(9) ©2012 American Physical SocietyROMERO VIV AS, MAMICA, KRAWCZYK, AND KRUGLY AK PHYSICAL REVIEW B 86, 144417 (2012)
damping is isotropic, which is a common assumption in the
linear approximation used in our calculations.31
The layout of this work is as follows. Section IIpresents
the general theory of our calculation method. In Sec. III,w e
report the calculations using our method for a MC consistingof spherical scattering centers forming a sc lattice. We consideralso the effect of material and structural parameter values onthe wave damping in this section. The interpretation of thenumerical results with the effective and estimated dampingcoefficients is presented in Sec. IV. Finally in Sec. Vwe detail
how the anisotropy in the effective damping can be used as atool for designing practical devices.
II. CALCULATION METHOD
The equation of motion of the space- and time-dependent
magnetization vector M(r,t), [i.e., the Landau-Lifshitz-Gilbert
equation (LLG)], is the starting point for the study of spinwaves in the classical approach. When written in internationalsystem of units, it reads
∂M(r,t)
∂t=γμ 0M(r,t)×Heff(r,t)+α
MS/parenleftbigg
M×∂M(r,t)
∂t/parenrightbigg
.
(1)
In this equation γis the gyromagnetic ratio, Heffdenotes
the effective magnetic field acting on the magnetization. Weassume that the effective magnetic field is composed of threecontributions: bias external magnetic field, exchange field, andmagnetostatic field.
32MSis the saturation magnetization, μ0
denotes the permeability of vacuum and the last term on the
right describes damping. The dimensionless damping factor α
in the rightmost term is Gilbert’s phenomenological dampingparameter. The LLG equation is nonlinear and to obtain thespin wave spectrum we need to obtain a linear approximationof this equation: we decompose the magnetization vector intoa static part (parallel to the external bias magnetic field H
0
with a value equal to the MS) and a small dynamic part m(r,t)
(themvector is perpendicular to H0). In addition, because
we are considering a periodic system, the Bloch theorem isapplied. The Fourier transform is used to obtain a frequencydomain solution [i.e., we assume m(r,t)∝exp(i/Omega1t)]. This
method, called the plane wave method (PWM), has alreadybeen described in the literature, for details see, e.g., Refs. 12
and13. The methodology for extending the method to consider
damping has been described for the 2D case in Ref. 11.
Here, we implement the calculation of damping for 3Dstructures. In the traditional PWM, an eigenvalue problemis obtained and the eigenvalues represent the frequencies,/Omega1. In the implementation extended to consider damping
effects, a generalized eigenvalue problem is obtained and theeigenvalues can adopt complex values (i.e., /Omega1=/Omega1
/prime+i/Omega1/prime/prime)
where i is the imaginary unit. The real part of these eigenvalues,/Omega1
/primeis the frequency, and the imaginary part /Omega1/prime/primegives the inverse
of the SW lifetime (i.e., the decay rate).33In the calculations
we used 1331 plane waves to obtain reasonable convergencefor three low-frequency magnonic bands analyzed in thispaper.
The value of the decay rate alone could be used to evaluate
the damping at a specific frequency and direction in a wavevector space. On the other hand, considering Eq. (2), whichis a known result in the theory of ferromagnetic resonance
measurements, we can see that the Gilbert damping parameterin the LLG equation models damping as proportional to thefrequency
34
/Delta1BG=1.16α/Omega1/prime
γ, (2)
where the BGis a half width of a ferromagnetic resonance
line. It makes sense, therefore, to define a similar quantitythat is not proportional to the frequency and therefore allowsus to compare the damping modification in the spin wavepropagation for different magnonic bands. This quantity willdepend on the profile of the magnetization distribution butwill not be proportional to the frequency. This quantity, calledfigure of merit (FOM), was used already in Ref. 11as the ratio
of the real to the imaginary part of the eigenvalues
FOM=/Omega1
/prime
/Omega1/prime/prime.
The FOM allows us to compare the degree of damping
variation between bands and between different directions inspace.
In the following section, Sec. III, we define the physical
system used to exemplify the use of this 3D PWM includingdamping and provide representative results.
III. RESULTS OF THE PLANE WA VE METHOD
CALCULATIONS
The first system under study is a 3D MC obtained by arrang-
ing spherical ferromagnetic scattering centers (material A) in asimple cubic (sc) lattice, as shown in Fig. 1(a). The [001] axis
of the crystal is parallel to the zaxis. The assumed value of
the sc lattice constant is a=10 nm; the magnetic parameters
of the matrix material (i.e., material B) in Fig. 1(a) are sat-
uration magnetization M
S=0.194×106A/m and exchange
constant A=3.996×10−12J/m; the magnetic parameters of
the spherical scattering centers, material A, are MS=1.752×
106A/m and A=2.1×10−11J/m. The values assumed for
the Gilbert damping parameter were chosen arbitrarily asα
A=0.0019 and αB=0.064 for spherical scattering centers
and the matrix, respectively, unless stated otherwise. Thisstructure will be called direct crystal . We will study also the
aaA
B2R
xyz
H0(a) (b)
XMM’RX’
FIG. 1. (Color online) (a) The sc structure of the considered
MC (direct crystal). The MC consists of spherical scattering centers
(material A of radius R) immersed in the host matrix (material B).
The lattice constant is aand the external static magnetic field, H0is
directed along the zaxis. (b) The first BZ of the sc lattice. The dark
(orange) color shows the part of the BZ over which the calculations
of the magnonic structure are performed.
144417-2INVESTIGATION OF SPIN W A VE DAMPING IN THREE- ... PHYSICAL REVIEW B 86, 144417 (2012)
0100200300400500600
X’M’X ΓXM ΓRXband 1
band 2
band 3
0102030
X’M’X ΓXMΓRX)zHG(''(
MOF''
'(a) (b) (c)
)zHG('
15.81616.216.4
X’M’X ΓXM ΓRX
FIG. 2. (Color online) The frequency and decay rate of the SWs are shown for the direct MC (spheres of material A in matrix B) in (a) and
(b), respectively. A filling fraction of 0.2 was assumed in the calculations. (c) The figure of merit (FOM) is shown for the same structure.
corresponding inverted crystal (i.e., a crystal with scattering
centers made of materials B and A serving as the matrixmaterial). A constant external magnetic field μ
0H0=0.3 T is
applied in the zdirection to saturate the crystal. The dynamic
part of the precessing magnetization has only xandynonzero
components.
The magnonic band structure resulting from the numerical
solution of the eigenproblem for the direct MC is shown inFig. 2. The filling fraction, defined as a ratio of the volume of
scattering centers in the unit cell (it is a sphere in our case) tothe volume of the unit cell: f=4πR
3/3a3, was assumed to
bef=0.2. It corresponds to a sphere radius R=3.628 nm.
The magnonic band structure was calculated along a path inthe irreducible part of the first Brillouin zone (BZ). The pointsalong this path are defined in Fig. 1(b). We limit the spectra
presented in this paper to low frequencies only (i.e., to thefirst three bands). We show the frequency ( /Omega1
/prime) and decay rate
(/Omega1/prime/prime) in dependence on the wave vector in Figs. 2(a) and2(b),
respectively. We can see that there is not any magnonic bandgap in the frequency spectra. We also observe similar wavevector dependencies for the frequencies and decay rates. Thisimplies that the FOM should be quite uniform in the whole BZ.This is confirmed by Fig. 2(c) in which the FOM is shown along
the path in the first BZ. The FOM has values in the range from15.8 to 16.4. In this case the FOM can therefore be regarded asnearly isotropic for all of the considered low-frequency bands.Let us now increase the filling fraction in the direct
structure. In Figs. 3(a) and 3(b) we show the corresponding
magnonic band structure (i.e., the frequency and decay rate)respectively, for the direct MC with f=0.5 (R=4.92 nm).
We found the magnonic band spectrum to be quite different tothat for f=0.2. In particular, the first band is separated from
the upper bands in most of the first BZ except for the R-X
direction, thereby forming a partial band gap. The wave vectordependence of the decay rate for the first band follows thatof the frequency. Consequently, we obtain an almost constantFOM [note the scale of the vertical axis in Fig. 3(c)]. For the
second band, we found that around the /Gamma1point, where /Omega1
/primehas a
maximum, /Omega1/prime/primehas the minimum. As a result of this, the FOM
is very large near the center of the BZ, reaching nearly 160. Inthe rest of the BZ, the FOM is below 30. The FOM is stronglydependent on the value of the wave vector but remains almostindependent on the direction of propagation.
Thus, we have found that a partial band gap in the magnonic
spectrum and significant values of the FOM coexist at somepoints in the BZ. We have performed calculations for otherfilling fractions from 0 up to the value corresponding to theclose-packed structure ( f=0.523) for the direct crystal and no
full gap was found. Nevertheless, a full band gap is observedfor the inverted crystal structure. In Figs. 4(a) and 4(b) we
show/Omega1
/primeand/Omega1/prime/primeas a function of the wave vector along a path
in the first BZ for the inverted MC with filling fraction of 0.5.
0100200300400
X’M’X ΓXM ΓRX01020
X’M’X ΓXM ΓRX2060100140
X’M’X ΓXMΓRXband 1
band 2
band 3
)zHG(''FOM (''
' )zHG('(a) (b) (c)
FIG. 3. (Color online) The frequency and decay rate of SWs in the first BZ for a direct MC (spheres of material A in a matrix of material
B) are shown in (a) and (b), respectively. A filling fraction 0.5 was assumed in calculations. (c) Figure of merit (FOM) for the same structure.
144417-3ROMERO VIV AS, MAMICA, KRAWCZYK, AND KRUGLY AK PHYSICAL REVIEW B 86, 144417 (2012)
0100200300400
XM’X’ΓXMΓRX0510152025
XM’X’ΓXMΓRX2060200
XM’X’ΓXMΓRXband 1
band 2
band 3
100
Magnonic gap)zHG(''(
MOF''
' )zHG('(a) (b) (c)
FIG. 4. (Color online) The frequency and decay rate of SWs in the first BZ for an inverted MC (spheres of material B in a matrix of material
A) are shown in (a) and (b), respectively. A filling fraction of 0.5 was assumed in the calculations. (c) The FOM is shown for the same structure.
We found a complete magnonic band gap between the first and
second bands. We also found that, in this case, the FOM hasvery small values for the first band. These values are nearlyindependent on the propagation direction or the magnitude ofthe wave vector. On the other hand, the second band reachesa significantly higher value of the FOM at the /Gamma1point (up
to 250). This value is much larger than that observed for thedirect structure [Fig. 3(c)]. However, the FOM is again almost
isotropic and has a sharp peak exactly at the center of the BZ(i.e., because the dispersion curve is flat and the group velocityof SWs goes through zero).
From the results presented so far, we can see that significant
values of the FOM are associated with the second band (i.e.,two absolute magnonic band gaps are found). In the previouslypresented spectra, the lowest band is separated from the secondone by a magnonic gap. Figure 5shows the magnonic spectra
for the inverted crystal with a filling fraction of 0.2, with /Omega1
/prime
and/Omega1/prime/primeplotted as a function of the wave vector in panels (a)
and (b), respectively. Both band gaps are marked in yellowcolor in the figure. These two band gaps separate the secondband from the other magnonic bands. The imaginary partof the frequency shows features that are not present in theother crystals investigated here. For the second band, /Omega1
/primehas
a maximum at the /Gamma1point, and consequently, the FOM has a
minimum in the same point. The maximal values of the FOM,larger than 400, are found at corners and edges of the firstBZ [i.e., at the points M=π/a(1,1,0),M
/prime=π/a(1,0,1),
andR=π/a(1,1,1)]. At the borders of the first BZ along
the principal axis [ X=(1,0,0) and X/prime=(0,0,1)] we found
the FOM to reach only values that are smaller than 200. Wecan conclude that in this crystal, the FOM is anisotropic andstrongly dependent on the magnitude of the wave vector.
In summary, we have found:(i) A low value of the FOM is observed for the first
band both for direct and inverted crystals irrespectively of thefilling fraction. The FOM is almost isotropic and only weaklydependent on the absolute value of the wave vector. This meansthat this band can be described using effective parameters.
(ii) Only for the inverted crystal with f=0.2 we found
strong anisotropy in the FOM for the second band.
(iii) There is apparently a cause-and-effect relationship
between the isolation of the second band (due to the presenceof band gaps directly above and below) and the observation ofhigh values of the FOM.
0100200300
X'M'X ΓXMΓRX01234567
X'M'X ΓXMΓRX0100200300400500
X'M'X ΓXMΓRXband 1
band 2
band 3
400)zHG(''FOM (''
' )zHG('
Magnonic gap(a) (b) (c)
FIG. 5. (Color online) The real and imaginary parts of the frequency in the first BZ for inverted MC (spheres of material B in matrix of
material A) in (a) and (b), respectively. A filling fraction of 0.2 was assumed in the calculations. (c) The FOM is shown for the same structure.
144417-4INVESTIGATION OF SPIN W A VE DAMPING IN THREE- ... PHYSICAL REVIEW B 86, 144417 (2012)
0 0
010 10
1020 20
2030 30
300200400
05f= 0.2 f= 0.5
0
0200
200400
400latsyrc tceriD
latsyrc detrevnI
0 200 400(a)
(c)(b)
(d) pag cinonga
Mpag cinonga
M)zHG(
)zHG(''''
' (GHz) ' (GHz)
FIG. 6. (Color online) Decay rate of SWs versus its frequency for
wave vectors randomly chosen from the first BZ. Direct crystals (Aspheres in the B matrix) are shown in (a) and (b), inverted crystals
(B spheres in the A matrix) in (c) and (d). In (a) and (c) the results
forf=0.2 and in (b) and (d) for f=0.5 are shown. Magnonic
gaps are colored in yellow color. In (c) the second band with the
moonlike shape is marked by blue ellipse, as it is expected to have
strong anisotropy in damping.
IV . DISCUSSION
It has already been mentioned that MCs showing a strong
dependence of loss on the direction of the wave vector can beused to design effective magnonic waveguides.
11We would
like to focus on the anisotropy of lifetime of SWs from anotherpoint of view and to explain the physical mechanisms thatgovern the damping of SWs in MCs. To facilitate the analysis,we propose to plot the decay rate versus frequency of theSWs as calculated for wave vectors of random direction andmagnitude in the first BZ. Figure 6shows such plots for the
direct and inverted MCs with filling fractions f=0.2 and 0.5.
From these figures we find two linear dependencies: a linearfunction /Omega1
/prime/primevs./Omega1/primefor the first mode and a linear dependence
of the upper limit of /Omega1/prime/prime≡/Omega1/prime/prime
maxon/Omega1/primefor all the considered
structures.35
The linear relation between the decay rate of SWs and the
frequency for the first band can be described by the followingrelation: /Omega1
/prime/prime=FOM−1×/Omega1/prime. We found the inverse of FOM to
be the slope of the straight line obtained by regression of thedata presented in Fig. 6. To explain this feature let us consider
SWs propagating in uniform materials. To have a goodmodel for comparison we have to choose a proper structure.Because we are studying 3D MCs filling the whole space,the proper choice seems to be the ferromagnetic uniformlymagnetized sphere with free boundary conditions imposedon the dynamic component of the magnetization vector. Thesphere is considered in order to avoid shape anisotropy effects.If the sphere is small enough to separate higher harmonicsfrom the uniform excitation, such results should be useful forinterpretation of the dependencies found for low-frequencymodes in 3D MCs, at least. In uniformly magnetized spheres,FOM =1/α, where αis a Gilbert damping constant of the
uniform sphere.
33This means that the lifetime of SWs fromthe first band of 3D MCs behaves like the one from uniform
materials. This allows us to introduce the effective dampingof the low-frequency mode in 3D MCs as α
eff=1/FOM,
where the inverse of FOM is the slope of the line fitted tothe dependencies shown in Fig. 6for the first band. From the
PWM solutions we have found α
effequal: 0.062, 0.058, 0.052,
and 0.059 for the direct crystal f=0.2 and 0.5, and inverted
crystals with f=0.2 and 0.5, respectively. These values are
between the values of the Gilbert damping coefficient of theconstituent materials ( α
AandαB) but in fact all of them are very
close to the highest value (i.e., 0.064). This behavior would bereasonable if the SW modes from the first band in both kinds ofthe investigated crystals concentrated their amplitude mainlyin the material with higher value of damping. Two-dimensionalcolor maps of the modulus of the dynamical components of
the magnetization vector (i.e., |m|=√
m2
x+m2
y) are shown
in Fig. 7, confirming our hypothesis. The amplitude is shown
in two cross sections perpendicular to the zaxis: one plane
crossing the centers of the spheres [plane (001)] and thesecond crossing the space in the middle between the spheres[plane (002)]. Red color marks maximum values while bluecorresponds to zeros of the amplitude.
To have a quantitative measure of the damping of SW modes
we can integrate the mode profiles in Fig. 7weighted with
the respective damping. The derivation of the formula for anestimated damping α
estin one-dimensional periodic structures
can be found in Ref. 36. A similar procedure can be applied to
3D structures and the final expression will have a similar formwith integrals over volume of the material A or B in the unitcell, now in 3D,
α
est(k,n)=αsph
MS,sph/integraltext
sph|mk,n|2dv+αmat
MS,mat/integraltext
mat|mk,n|2dv
1
MS,sph/integraltext
sph|mk,n|2dv+1
MS,mat/integraltext
mat|mk,n|2dv,(3)
where the indices “sph” and “mat” make reference to the sphere
and matrix, respectively; mk,nis the dynamical component
of the magnetization vector for the band nand wave vector
k. This formula allows us to calculate an estimated value of
damping for each band ( n) and each wave vector ( k). The
calculated values of the estimated damping parameters for thefirst band in /Gamma1andRpoints in the BZ are collected together
with the effective damping constants obtained from the slopesin Fig. 6in Table I. For the direct crystal the damping constant
from both methods match very well. For the inverted crystal,there is significant variation of αin dependence on the wave
vector value [see also Fig. 5(c)] but the arithmetic average of
estimated values also match well with the α
eff.
Now we will discuss the results obtained for the second
band, where in the case of the inverted crystals, a large FOMwas found in the RandMpoints in the BZ. The amplitude of
the dynamical components of the magnetization vector and therespective estimated damping parameters are shown in Fig. 7
for the wave vector from the BZ center and BZ edge (i.e., forthe/Gamma1andRpoints) respectively, for the direct crystal ( f=
0.5) and inverted crystal ( f=0.2). The estimated damping
parameters α
estfrom the profiles are given also in this figure.
For the direct crystal we have found that the FOM reaches ahigh value at the /Gamma1point ( ∼=160) and a very small value for the
Rpoint (less than ∼=18), as shown in Fig. 3(c). The respective
damping values obtained from the profiles are 0.006 and 0.063,
144417-5ROMERO VIV AS, MAMICA, KRAWCZYK, AND KRUGLY AK PHYSICAL REVIEW B 86, 144417 (2012)
Direct crystal
= 0.5fInverted crystal
= 0.2fenalP(001)
enalP)200(R R
1st banddnab dn2enalP)100(
enalP)200(est,= 0.006
est,= 0.058est,= 0.016
est,= 0.045est,R= 0.063
est,R= 0.06est,R= 0.002
est,R= 0.0590max
FIG. 7. (Color online) The amplitude of the dynamical components of the magnetization vector across the planes perpendicular to the z
axis and crossing it at 0 [plane (001)] and at a/2 [plane (002)]. The profiles from the first and the second band in /Gamma1andRpoint are shown for
the direct crystal with f=0.5 (left columns) and for the inverted crystal and f=0.2 (right columns). The estimated value of the damping
constant of the related mode [calculated according to Eq. (3)] is also given for each profile.
for the /Gamma1andRpoints, respectively. For the inverted structure
a strong change in the FOM, which is eight times lower atthe/Gamma1point as compared to its value at the Rpoint can be
seen in Fig. 5(c). This fact is also supported by the damping
coefficient values obtained from the SW profiles: α
est(/Gamma1,2)=
0.016 and αest(R,2)=0.002 at /Gamma1andRpoint in the BZ,
respectively.
TABLE I. The effective damping parameters ( αeff)f o rt h efi r s t
band obtained by assuming a linear dependence /Omega1/prime/prime(/Omega1/prime) and fitting
the slope from Fig. 6are shown. The estimated damping coefficients
(αest) extracted according to Eq. (3)from the profiles of SWs at the
/Gamma1andRpoints in the first BZ for the first band shown in Fig. 7are
also presented.
Structure αeff αest(/Gamma1,1) αest(R,1)
Direct f=0.5 0.058 0.058 0.06
Inverted f=0.2 0.052 0.045 0.059We have already established the relation between the value
of the FOM, estimated values of the damping coefficients,and the distribution of the mode profiles over the constituentmaterials. It remains still unattended, however, how changesin the damping parameters of the constituent materials ( α
Aand
αB) influence the lifetime of the different modes. To get some
insight we propose to take a look at the frequency and decayrate as a function of the relative loss parameter (RLP), whichtakes values from 0 to 1 and we define as
α
sph=0.0659×RLP,
(4)
αmat=0.0659×(1.0−RLP),
where the coefficient 0.0659 is chosen equal to αA+αB.
According to this definition, for RLP =0 the SWs in spheres
will be undamped while the damping will reach its maximalvalue (i.e., 0.0659) in the matrix. For RLP =1, the reverse
situation occurs (i.e., no damping is present in the matrix)while it reaches its maximum value in the spheres. In Figs. 8(a)
and8(b) the frequency and decay rate of SW modes from the
144417-6INVESTIGATION OF SPIN W A VE DAMPING IN THREE- ... PHYSICAL REVIEW B 86, 144417 (2012)
04812
0 0 1 1140160180200220
0 1RL P RLP RLPΓ Γ ΓX
XXR RR
Γ
XR(a) (b)
00,020,040,06
est'xest(c) (d)
04812
0 1
RLP)zHG('')zHG('
FIG. 8. (Color online) (a) Frequency and (b) decay rate of the SWs are shown as a function of the RLP for the inverted crystal with filling
fraction 0.2 calculated with PWM. The frequencies from the second band for the /Gamma1,R,a n d Xpoints in the BZ are shown. (c) Estimated values
of the damping coefficient are shown in dependence on RLP for the /Gamma1,X,a n d Rpoints for the second band. αestare calculated according to
Eq.(3). (d) The product of αestand/Omega1/primeis shown for the /Gamma1,X,a n d Rpoints from the second band. There is a close relation between αest×/Omega1/prime
[shown in (d)] and /Omega1/prime/prime[shown in (b)].
second band for three points from the first BZ (i.e., for /Gamma1,X,
andR) are shown in dependence on the RLP. The calculations
were performed for the inverted crystal with filling fraction0.2. We have found that the frequency is virtually independenton the RLP [Fig. 8(a)]. This behavior can be expected due
to the fact that in thin films the dependence of damping onfrequency is a second-order effect.
33The decay rate is a linear
function of the RLP with negative slope depending on the wavevector: at the Rpoint the slope reaches its highest value while
at the /Gamma1point, it reaches its lowest value. We can understand
this behavior, because we already showed that the amplitudeof the SW modes for the second band is concentrated mainly inthe spheres. Consequently, it is expected to observe the lowestvalues of /Omega1
/prime/primefor RLP =1.
The RLP of the inverted crystal [the corresponding band
structure is shown in Fig. 5(a)] is 0.97. We see that for this
RLP, the imaginary part of a frequency at RandXhas almost
the same value but less than half of that at /Gamma1point. This
shows from another point of view the main features alreadyobserved in Fig. 5(c) (i.e., highest FOM at Rand smallest at /Gamma1).
Here we see that the anisotropy of the FOM is dependent onthe distribution of damping among the constituent materialsof the MC. In particular, no anisotropy is observed for thecase when RLP =0.5 (i.e., when the damping coefficients in
spheres and matrix are equal). This result can also be obtaineddirectly from the PWM [i.e., by plotting FOM (RLP) ≡/Omega1
/prime
(RLP) /Omega1/prime/prime(RLP)].
The linear dependencies presented in Fig. 8(b) provide
evidence that the estimated damping coefficient calculatedfrom the Eq. (3)should also preserve a linear dependence on
the RLP. The α
est(RLP) can be calculated from the SW profiles
obtained from PWM (the profiles have to be calculated onlyonce for selected RLP) according to Eq. (3)with damping
coefficients defined by Eqs. (4). The results for the second
band for a few selected points in the BZ are shown inFig. 8(c). We see that for RLP =0.5t h e α
estis the same
independently of the wave vector. To have a quantitativecomparison between α
estand the numerically calculated /Omega1/prime/prime
we need to multiply αestby/Omega1/prime. The product αest×/Omega1/primeis shown
in Fig. 8(c). A good qualitative agreement with /Omega1/prime/primeas shown
in part (b) of this figure is clear. Quantitatively, the differ-ences are largest near RLP =0 and decrease when the RLP
increases.
V . APPLICATION OF THE PROPOSED
THREE-DIMENSIONAL MAGNONIC
CRYSTAL
In Fig. 6(c) a shape similar to a crescent moon can be
observed for the second band lying between two magnonicband gaps. This is interesting because it means that, dependingon the direction, we can identify regions of low and highdamping for the same frequency and nothing in between. Forapplication as beam shaper, this is just what we need. Theregion in which this happens is easy to identify using theintroduced style of plotting. Also, it allows us to identifypropagation directions that correspond to low and highdamping at the same frequency. We can use Fig. 5for this
purpose, where the respective band structure is shown. We cannote that on the paths going through /Gamma1point (i.e., from X
/primeto
/Gamma1toXand from Mto/Gamma1toR, the decay rate is higher (and
consequently the FOM is smaller) than in the rest of the path.We can also notice that for frequencies above approximately200 GHz there is an allowed SW band only around the Rpoint.
In this point also the decay rate is very low, giving high FOM.This functionality can be combined with changes controlledby the external magnetic field, which would have the effect ofshifting up or down the range of frequencies where the abovementioned conditions are fulfilled.
If we want to use a mode for transmitting information, in
other words, if we want to use our infinite MC as a waveguide,a necessary condition for usefulness is to show that the groupvelocity (i.e., its magnitude) is greater than zero. The extremalvalues of the FOM are found for values of the wave vectors inthe BZ border ( R,X,o rMpoints) or at the BZ center ( /Gamma1point).
At these points the dispersion curves reach extreme values andthe group velocity is 0. To have a qualitative measure of theusefulness of a given mode we propose to look at the product ofthe group velocity and the FOM. A large value of this productwill occur at points with low loss and high group velocity. InFig.9we show the product, v
g×FOM (calculated directly from
the dispersion relation) for the second band along the path in
144417-7ROMERO VIV AS, MAMICA, KRAWCZYK, AND KRUGLY AK PHYSICAL REVIEW B 86, 144417 (2012)
XM’ X’ ΓXM Γ RX0246810vgFOM (10 )4m/s
FIG. 9. The absolute value of the product of a group velocity ( vg)
and FOM for the second band for the inverted crystal (with f=0.2)
along the path in the first BZ.
the first BZ for the inverted crystal with f=0.2. We see, that on
the path along, /Gamma1-RandX-Rthis product has maxima, which
define the optimal wave vectors for possible applications. Atthese points the group velocity of SWs is around 200 m /s.
This speed is rather low, but still a lifetime around 0.5 GHzwill allow a transport of the signal for a distance around2μm. This application would also face the challenge that the
anisotropy of the damping in 3D MCs will depend on theRLP as shown in Figs. 8(b) and 8(c). This means that
the properties depend on the distribution of damping among theconstituent materials. This however could also be consideredas an opportunity from the designer point of view.
In Ref. 37, Mruczkiewicz et al. showed that stacks of 2D
all-ferromagnetic magnonic crystals could be used to designmetamaterials with negative permeability at frequencies ofseveral tenths of GHz. In particular, negative permeability wasobserved in the vicinity of high-order resonances for whichthe magnonic mode amplitude was preferentially distributedwithin one of the two constituent materials. The resultspresented in this paper allow us to speculate that if this materialin which the magnonic amplitude is concentrated is in additioncharacterized by a low damping coefficient, then the resonancewill be even stronger and the quality factor will be evenhigher than that obtained in Ref. 37. A rigorous proof of this
hypothesis is however beyond the present study.VI. CONCLUSION
Using numerical calculations based on the PWM we have
shown that magnonic crystals enable us to tailor the effectiveintrinsic damping of spin waves. A proper choice of theMC structure and its filling fraction allows us to designa magnonic band structure with anisotropic and stronglywave-vector-dependent effective damping. We introduced theplots of the decay rate versus frequency for randomly chosenwave vectors from the first BZ. With the help of these plotswe have shown that it is possible to obtain for the samefrequency two different directions of SW propagation withlow and high damping, where propagation takes place at afinite group velocity.
We have proposed a qualitative explanation of the depen-
dencies observed in our numerical results based on the analysisof the SW amplitude distribution among the constituentmaterials. The formula for the estimated effective dampingcoefficient, introduced here for 3D MCs, is wave vector andband number dependent and describes adequately numericalresults. We have shown that the decay rate of SW in 3D MCsis a linear function of the relative loss parameter. This is animportant result, which allows for a reduction of the time ofcomputations. We have shown also that large values of theFOM in MCs coexist with magnonic gaps in the spin wavespectra as both effects are influenced by the distribution of theSW amplitude in the unit cell in a similar way. This modelallows us to understand the effective behavior of damping ofthe first mode in the magnonic spectrum, irrespective of thedirection and magnitude of the wave vector.
ACKNOWLEDGMENTS
The research leading to these results has received funding
from the European Community’s Seventh Framework Pro-gramme (Grant No. FP7/2007-2013) under Grant AgreementsNo. 247556 (People), NoWaPhen and No. 233552, DYNA-MAG project. V .V .K. also acknowledges funding receivedfrom EPSRC of the UK under Project No. EP/E055087/1.The calculations presented in this paper were performed inPoznan Supercomputing and Networking Center.
*krawczyk@amu.edu.pl
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31K. Gilmore, M. D. Stiles, J. Seib, D. Steiauf, and M. F ¨ahnle, Phys.
Rev. B 81, 174414 (2010).
32We use here the same formulations for the exchange and magneto-
static fields as in Ref. 12.
33A. G. Gurevich and G. A. Melkov, Magnetization Oscillations and
Waves (CRC Press, Boca Raton, 1996).
34K. Zakeri, J. Lindner, I. Barsukov, R. Meckenstock, M. Farle,
U. von H ¨orsten, H. Wende, W. Keune, J. Rocker, S. S. Kalarickal,
K. Lenz, W. Kuch, K. Baberschke, and Z. Frait, P h y s .R e v .B 76,
104416 (2007).
35For the inverted crystal with f=0.2 shown in the Fig. 6(c) due
to limiting range of presented points the linear dependence of theupper limit is not clear. But for higher frequencies (decaying rates)this linear dependence is still present.
36A. M. Zyuzin, A. G. Bazhanov, S. N. Sabaev, and S. S. Kidyaev,Phys. Solid State 42, 1279 (2000).
37M. Mruczkiewicz, M. Krawczyk, R. V . Mikhaylovskiy, and
V . V . Kruglyak, Phys. Rev. B 86, 024425 (2012).
144417-9 |
PhysRevLett.92.027201.pdf | Direct-Current Induced Dynamics in Co90Fe10=Ni80Fe20Point Contacts
W . H. Rippard, M. R. Pufall, S. Kaka, S. E. Russek, and T. J. Silva
National Institute of Standards and T echnology, Boulder, Colorado 80305, USA
(Received 23 June 2003; published 15 January 2004)
W e have directly measured coherent high-frequency magnetization dynamics in ferromagnetic films
induced by a spin-polarized dc current. The precession frequency can be tuned over a range of severalgigahertz by varying the applied current. The frequencies of excitation also vary with applied field,
resulting in a microwave oscillator that can be tuned from below 5 to above 40 GHz. This novel method
of inducing high-frequency dynamics yields oscillations having quality factors from 200 to 800. W ecompare our results with those from single-domain simulations of current-induced dynamics.
DOI: 10.1103/PhysRevLett.92.027201 P ACS numbers: 75.47.–m, 75.75.+a, 85.75.–d
Since the initial predictions of Slonczewski [1] and
Berger [2] that a spin-polarized current can induce mag-netic switching and dynamic excitations in ferromagneticthin films, a great deal of work has focused on under-standing the interactions between polarized currents andferromagnetic nanostructures [3]. It was predicted, and
later confirmed, that this effect can lead to current-
controlled hysteretic switching in magnetic nanostruc-tures in moderate applied magnetic fields [4,5]. Thisbehavior is not only of scientific interest but also findspotential applications in devices such as current-controlled switching of magnetic random access memoryelements and has implications for the stability of mag-netic hard-disk read heads. Another prediction is that the
spin torque can drive steady-state magnetization preces-
sion in the case of applied fields large enough to opposehysteretic switching [1,2]. Numerous applications existfor such current-controlled microwave oscillators that areintegrable with semiconductor electronics [6]. However,with one recent exception in nanopillar devices [7], todate no direct measurements of these high-frequencydynamics have been reported [4,5,8]. Here we report
direct measurements of spin-torque induced magnetiza-
tion dynamics for in-plane and out-of-plane applied fieldsas a function of field strength Hand current I,a n d
compare the results with simulations based on the theo-retical model of Ref. [1].
Studies discussed here were performed on lithograph-
ically defined point contacts to spin valve mesas ( 8/.0022m/.0002
12/.0022m). The point contacts are nominally 40 nm diame-
ter circles, have resistances between 4 and 10/.0010 , and show
no indications of tunneling in their transport character-istics. Top and bottom electrical contacts to the devicesare patterned into 50/.0010 planar waveguides. Fabrication
details will be presented elsewhere. Specifically, thespin valve structures are Ta/.01332:5nm/.0134=Cu/.013350nm /.0134=
Co
90Fe10/.013320 nm /.0134=Cu/.01335n m /.0134=Ni80Fe20/.01335n m /.0134=Cu
/.01331:5nm/.0134=Au/.01332:5nm/.0134and show typical magnetoresis-
tance (MR) values of 80m/.0010 .T h eCo90Fe10is the ‘‘fixed’’
layer in terms of the spin torque due to its larger volume,exchange stiffness, and saturation magnetization com-pared withNi
80Fe20[9]. The device is contacted with
microwave probes and a dc current is injected through abias-tee, along with a 20/.0022Aac current (500Hz ), allow-
ing simultaneous measurement of the dc resistance, dif-ferential resistance, and microwave output. The devicesare current biased so that changes in the alignment
between theNi
80Fe20andCo90Fe10layers appear as volt-
age changes across the point contact. The high-frequencyvoltage signal is measured with either a 50 GHz spectrumanalyzer or a 1.5 GHz real-time oscilloscope. The band-width of the circuit is 0.1 to 40 GHz. Measurements wereperformed at room temperature. All results discussedhere occur for only one direction of current, correspond-ing to electrons flowing from the top contact into the
spin valve.
Figure 1(a) shows a differential resistance dV=dI curve
of a device taken with an in-plane field /.0022
0H/.01360:1T.T h e
nonhysteretic peak in the dV=dI curve, at I/.01364mA in
Fig. 1(a), has been taken as indirect evidence of current-induced magnetization dynamics [4,5,8]. Tsoi et al. dem-
onstrated changes in the dc transport properties of pointcontacts under the influence of external radiation, imply-
ing a relationship between spin dynamics and dc resis-
tance [8]. Here we observe these dynamics directly, asshown in Fig. 1(b). For low currents, no peaks are ob-served in the spectra. As Iis increased to 4 mA a peak
appears at f/.01367:9GHz .A sIis further increased, the
peak frequency decreases, a trend observed for all in-plane fields measured. This frequency redshift is linear inI(inset) and typically varies from /.00250:2GHz =mAat low
fields ( /.002550mT )t o/.00251GHz =mAat fields of /.00250:8T.A t
higher values of I, the excitations decrease in magnitude
until no peaks are observed, as shown in the I/.01369mA
spectrum. Assuming the high-frequency signals resultfrom a MR response, we estimate a maximum excursionangle between the layers of approximately 20
/.0014.A st h e
measured peak amplitude does not increase linearly withI(as it would for fixed excursion angle), we infer that the
orbit traversed by the magnetization changes with I.T h e
dynamics here are strongly correlated with the peak inthedV=dI curve. This is not the case for all devices:PHYSICAL REVIEW LETTERSweek ending
16 JANUARY 2004 VOLUME 92, N UMBER 2
027201-1 0031-9007 =04=92(2)=027201(4)$22.50 027201-1Typically the onset of the dynamics occurs only in the
vicinity of a feature (step, peak, or kink) in dV=dI ,a n d
the relative position of this onset varies with H.
To better understand the possible trajectories of these
excitations, we compare our results with simulations thatassume an isolated single-domain particle ( 40nm /.0002
40nm ) whose behavior is described by a modified
Landau-Lifshitz-Gilbert (LLG) equation proposed by
Slonczewski [1]. This only approximates the point contact
geometry, where the region undergoing dynamic excita-tions is coupled to a continuous film by intralayerexchange. For example, effects associated with the for-mation of domain walls between the region under thecontact area and the rest of the free layer are not included,nor are effects of spin-wave radiation damping [1]. Finite-temperature effects are included through a randomly
fluctuating field [10].
The simulations show two basic regimes of motion for
in-plane fields. At low current, when oscillations begin,the magnetization Mprecesses in a nearly elliptical mode
aboutHand the time-averaged magnetization hMilies
parallel to H.A s Iincreases, the trajectories become
nonelliptical and have greater excursion angles withrespect to H. However, Mcontinues to precess about
the applied field, while hMichanges from parallel to
antiparallel alignment with H. Within this regime, the
simulated excitation frequency decreases approximately
linearly with I, in agreement with the data shown in
Fig. 1(b). Furthermore, jdf=dI jincreases with increasing
H, also in agreement with our measurements. As Iisfurther increased, the second regime is reached and the
simulations show Mprecessing out-of-plane with the
precession frequency increasing with current. Con-
sequently, we infer that the observed excitations corre-
spond only to in-plane precession, perhaps due to a lack ofstability of the trajectories in our devices, or because thedevices are unable to support sufficient current densities.It may also indicate a need to incorporate micromagneticeffects in the modeling.
The measured linewidths are quite narrow, indicating
that the excitations can be considered coherent single-
mode oscillations. The peaks in Fig. 1(b) have full-width-
at-half-maximum (FWHM) of /.002520MHz and voltage
(power) quality factors Q/.0136f=/.0133FWHM /.0134of/.0025350/.0133600/.0134,
with particular values depending on I. The FWHMs of
the excitations only weakly depend on H, leading to
values of Q>500 forf>30GHz . Analogous line-
widths in ferromagnetic resonance (FMR) measurementswould give damping parameters of /.0011/.01361–5/.000210
/.02554, with
the particular value depending on H[11]. Our modeling
requires /.0011/.01360:5–1/.000210/.02553to produce similar linewidths
at300K . Either analysis gives values of /.0011much smaller
than values obtained through field-induced excitations ofNi
80Fe20thin films ( /.0011/.01360:01to 0.005) [12,13]. Line-
widths we have measured in nanopillar devices (notshown here) are about a factor of 5larger than those
measured in point contacts, showing that the narrowness
of these peaks is not a general result for current-induced
excitations. The lack of physical magnetic edges in pointcontact devices may account for their narrow linewidthsin comparison to nanopillars. Increased linewidths andeffective damping are often found in magnetic nano-structures, resulting from Mat the edges of patterned
devices lagging Mat the center of the device during
large-angle oscillations [13].
Figure 2(a) shows the measured frequencies as a func-
tion of in-plane field. The data correspond to the highest-frequency (lowest-current) excitation observed at a givenH. Below /.0022
0H/.013650mT no excitations are seen. Around
/.00220H/.01360:6Tthe excitation amplitude begins to drop and
by/.00220H>1Tis below our noise floor. The data are fit
using the Kittel equation for in-plane magnon generation,excluding dipole effects, appropriate for the thin-film
limit [14]:
f/.0133H/.0134/.0136/.0133g/.0022
B/.00220=h/.0134/.0137/.0133H/.0135Hsw/.0135Hk/.0135Meff/.0134
/.0002/.0133H/.0135Hsw/.0135Hk/.0134/.01381=2; (1)
where Hsw/.0136Dk2=/.0133g/.0022B/.00220/.0134,Dis the exchange stiffness,
gis the Lande ´factor, kis the magnon wave number, Meff
is the effective magnetization, Hkis the anisotropy field,
/.00220is the permeability of free space, his Planck’s con-
stant, and /.0022Bis the Bohr magneton. In fitting the data, k
andgare treated as free parameters while fixed values
of/.00220Meff/.01360:8Tand/.00220Hk/.01360:4mT are used, as de-
termined from magnetometry measurements. The fit
FIG. 1. (a) dV=dI vsIwith/.00220H/.01360:1T. (b) High frequency
spectra taken at several different values of current through thedevice, corresponding to the symbols in (a). V ariation of fwith
I(inset).PHYSICAL REVIEW LETTERSweek ending
16 JANUARY 2004 VOLUME 92, N UMBER 2
027201-2 027201-2yields g/.01361:78/.00060:01and a magnon wavelength of
/.0021/.0136390/.000680nm . W e note Eq. (1) is strictly valid only
in the limit of small amplitude spin-waves, a limit notstrictly met in the present measurements, as discussedabove. From both the above fit and from the linear portionof the data for /.0022
0H>0:4Twe determine g/.01361:78/.0006
0:01, smaller than the value of g/.01362:0determined on
analogous films by other methods [12,13]. However, nu-merical simulations of the LLG equation show that fittingEq. (1) to oscillations of large amplitude results in anapparently suppressed value of gas found here. It was
initially predicted that the lowest-order excited modewould have a wavelength of roughly twice the contactdiameter [1]. However, the excitation wavelengths deter-
mined from fits to these and other data are much larger
than the nominal or calculated contact sizes, which rangefrom 25 to 40 nm from a Sharvin-Maxwell calculation[15].W e infer that the excitations are ones with negligiblewave vector, i.e., the uniform FMR mode, although thisdoes not exclude the presence of excitations outside ourmeasurement bandwidth. Device-to-device variation ofthe measured fat a given His<10%, while the calcu-
lated contact size varies by 60%, consistent with the
excitation of a long-wavelength mode.
Spectra taken over a wider range of frequencies show a
peak at twice the frequency of the one discussed above asshown in Fig. 2(b). The frequencies, along with theirvariations with both IandH, differ by a factor of 2:00/.00060:01, and are observed in fields much larger than any
anisotropies in the film. W e have not observed higher-harmonic signals. The ratios of the fto2famplitudes
depend on both IandH, and show a nonmonotonic
dependence on Iand a slight increase with H(inset).
For precession symmetric about the fixed layer direction,the signal from a MR-derived voltage should be twice thephysical oscillation frequency of M. However, any mis-
alignment between the layers would result in the detec-tion of a signal at fas well as2f. W e estimate a
misalignment of a few degrees would give the fto2f
amplitude ratios observed. The limiting slope of the data
in Fig. 2(a) is 26GHz =T, in good agreement with the
value expected from Eq. (1) for a first harmonic signal,indicating that the lower-frequency peaks correspond tothe physical precessional frequency of M.
The devices also emit power at lower frequency.
Figure 3 shows I/.01365mA and11mA spectra of the
device along with the corresponding dV=dI curve. At
lowI, no signal is found, but as Iis increased to 8mA ,
a shoulder in the dV=dI curve appears and a signal is
observed, the strength of which increases with current. Inthis device, by I/.01368mA the coherent dynamics dis-
cussed above have already turned off. However, we havemeasured other devices where both the high-frequencysingle-mode oscillations and the low-frequency signalhave been simultaneously observed over a range of cur-
rents. From real-time measurements of the voltage fluc-
tuations in these devices and nanopillars, we find that thislow-frequency signal results from two-state switching inthe device, as has also been reported in Ref. [5]. Thespectral shape follows a Lorentzian function, as expectedfor stochastic switching between two well-defined energystates [16]. At higher currents this switching typicallyceases, although this is not always the case before the
highest Isupported by a contact ( /.002514mA ) is reached.
The dynamics change dramatically with applied field
direction. In Fig. 4(a) is a two-dimensional plot showingfas a function of Ifor the device discussed above, but
FIG. 3. Low-frequency power spectra for two different cur-
rents along with a fit to the data at I/.013611mA to a Lorentzian
function. The fitted center frequency is f0/.01360/.000650MHz .
(inset) The corresponding dV=dI curve.
FIG. 2. (a) In-plane fvsHdispersion curve along with a fit
to Eq. (1). Error bars (FWHM) are smaller than the data points.(b) Frequency spectra for I/.01365mA to 9 mA in 0.5 mA
steps with /.0022H/.01360:06T showing responses at both fand2f.
(Inset) fto2famplitude ratios as a function of Ifor two
different fields.PHYSICAL REVIEW LETTERSweek ending
16 JANUARY 2004 VOLUME 92, N UMBER 2
027201-3 027201-3with an out-of-plane field of 0.9 T. Along the xaxisI
varies from 4 to 12 mA and back to 4 mA. Avertical slicethrough the plot yields a frequency spectrum at a fixed I.
This field aligns the Ni
80Fe20layer with Hwhile canting
theCo90Fe10layer about30/.0014out of the film plane. For
/.00220H>0:6T, a blueshift in fwith increasing Iis seen.
More complicated behavior is also found, e.g., jumps in f
occur at I/.01366mA and 7.5 mA. These jumps are not
hysteretic and occur in all devices for out-of-plane fields.According to our modeling of this geometry, the Ni
80Fe20
magnetization precesses in a nearly circular orbit about
H, with frequency increasing with I, the trend seen in our
measurements. However, abrupt changes of fwith in-
creasing Iare not found in our modeling.
As shown in Fig. 4(b), dynamics persist to /.00220H/.0136
1:3T andf/.013638GHz , and spectrally can be well fit
with a Lorentzian function (inset). Even at these frequen-cies, the voltage (power) linewidths are /.002560MHz
(40MHz ), and have Q>650/.0133950/.0134. Because of band-
width limitations we were not able to follow the oscil-lations to higher frequencies. At least for point contacts,the two-state switching behavior found with in-plane
fields is largely suppressed in this geometry. As seen inFig. 4(b), the highest frequencies at a given field vary
linearly in Hwith a slope of 32GHz =Tand give g/.0136
2:1/.00060:01, differing from the value determined from the
in-plane measurements. It may be that His not yet large
enough for fto be a truly linear function of H, leading to
an inflated value of g. Finally, in contrast with FMR
measurements, we note the excited frequencies here in-crease continuously in fields ranging from H<M
NiFeto
H>MNiFe, and persist even for H/.0136MNiFe when the
FMR resonance frequency is nominally zero.
W e thank J. A. Katine for supplying nanopillar devices,
and M. D. Stiles and F . B. Mancoff for helpful discussions.This work was supported by the DARP A SPinS and NISTNano-magnetodynamics programs.
[1] J. C. Slonczewski, J. Magn. Magn. Mater. 159, L1 (1996);
195, L261 (1999).
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(2002); Y a. B. Bazaliy, B. A. Jones, and S. C. Zhang,J. Appl. Phys. 89, 6793 (2001); S. Zhang, P . M. Levy,
and A. Fert, Phys. Rev. Lett. 88, 236601 (2002); C. Heide,
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Silva, Appl. Phys. Lett. 82, 1260 (2003); Y . Ji, C. L.
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[6] J. C. Slonczewski, U.S. Patent No. 5695864, 1997.
[7] S. I. Kiselev et al. , Nature (London) 425, 308 (2003).
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Lett. 83, 323 (2003).
[10] W . F. Brown, Phys. Rev. 130, 1677 (1963); Jian-Gang
Zhu, J. Appl. Phys. 91, 7273 (2002).
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(1975).
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et al. , Phys. Rev. Lett. 81, 4512 (1998).
[14] Charles Kittel, Introduction to Solid State Physics (John
Wiley, New Y ork, 1986), 6th ed., p. 454.
[15] G. W exler, Proc. Phys. Soc. London 89, 927 (1966).
[16] S. Machlup, J. Appl. Phys. 25, 341 (1954).18202224
Current (mA)8 8 12 4 4Frequency (GHz)
0.50 0.75 1.00 1.25203040
(b) 32 ± 0.8 GHz/T Frequency (GHz)
Field (T)37.6 37.8 38.00.00.20.4∆f = 58 MHz
Freq. (GHz)(a)
0.0nV/Hz0.50.9
Ampl. (nV/Hz1/2)
FIG. 4 (color). (a) Plot of fvsIwith amplitude shown in a
linear color scale from 0 (blue) to 0:9nV=Hz1=2(red), discre-
tization results from measuring spectra in 500/.0022Aintervals.
(b) Out-of-plane fvsHdispersion curve. Data correspond to
the highest fat a given H. Error bars (FWHM) are smaller
than the data points. (inset) Spectral peak at 1.3 T and I/.0136
11mA along with a fit.PHYSICAL REVIEW LETTERSweek ending
16 JANUARY 2004 VOLUME 92, N UMBER 2
027201-4 027201-4 |
PhysRevB.91.214435.pdf | PHYSICAL REVIEW B 91, 214435 (2015)
Quantum mechanism of nonlocal Gilbert damping in magnetic trilayers
Ehsan Barati and Marek Cinal
Institute of Physical Chemistry of the Polish Academy of Sciences, Kasprzaka 44/52, 01-224 Warsaw, Poland
(Received 16 April 2015; published 30 June 2015)
A fully quantum-mechanical calculation of the Gilbert damping constant αin magnetic trilayers is done by
employing the torque-correlation formula within a realistic tight-binding model. A remarkable enhancement of α
in Co/NM 1/NM 2trilayers is obtained due to adding the caps NM 2=Pd, Pt, and it decays with the thickness of the
spacers NM 1=Cu, Ag, Au in agreement with experiment. Nonlocal origin of the Gilbert damping is visualized
with its atomic layer contributions. It is shown that magnetization in Co is damped remotely by strong spin-orbitcoupling in NM
2via quantum states with large amplitude in both Co and NM 2.
DOI: 10.1103/PhysRevB.91.214435 PACS number(s): 75 .78.−n,75.40.Gb,75.70.Tj
I. INTRODUCTION
Employing magnetic layered structures in spintronic de-
vices such as hard-disk read heads and magnetic random access
memories is the key ingredient in data storage technologyand its ongoing developments. This followed the discoveriesof interlayer exchange coupling [ 1,2], giant [ 3] and tunnel-
ing [ 4,5] magnetoresistance, and spin-transfer torque [ 6–8]
in trilayers built of ferromagnetic layers separated by non-magnetic spacers. Metallic trilayers are also commonly usedto investigate magnetization dynamics in view of potentialspintronic applications like racetrack memories [ 9] and spin
torque nano-oscillators [ 10]. The dynamical processes in mag-
netic nanodevices and, in particular, magnetization switchingare profoundly affected by magnetic damping due to spin-flipscattering and transfer of spin angular momentum.
Magnetic relaxation in ferromagnetic metals is governed
by the Gilbert damping, which enters the phenomenologicalLandau-Lifshitz-Gilbert (LLG) equation [ 11,12]. The Gilbert
damping plays a crucial role in magnetization dynamics ofmagnetic layered systems. In particular, it affects the thresholdspin current required for magnetization switching [ 13] and
the domain wall velocity in current-carrying domain wallstructures [ 9].
In the last two decades, extensive research activities
have been devoted to magnetization dynamics in magneticfilms [ 14–25]. The Gilbert damping constant αin ferromag-
net/nonmagnet (FM/NM) metallic bilayers is found to be ap-preciably enhanced in comparison with its bulk value [ 21,22].
The damping is also enhanced in FM /NM
1/NM 2trilayer
structures with spacer layers of NM 1=Cu due to adding
the NM 2=Pd, Pt, Ru, and Ta caps [ 16–18,21,23–25]. This
experimental evidence clearly shows that the enhancement ofthe Gilbert damping in magnetic layered systems is of nonlocalorigin.
An early theoretical paper on nonlocal magnetic damping
is due to Berger [ 26]. He argued that the exchange coupling
between itinerant spelectrons passing through the FM/NM
interface and delectrons in the FM yields an enhanced Gilbert
damping due to spin-flip electron transitions in which spinwaves are emitted or absorbed near the interface.
The enhanced Gilbert damping in FM/NM layered systems
is explained in a semiphenomenological way in Refs. [ 27,28]
by pumping spin angular momentum from the FM into theadjacent nonmagnetic (normal metal) layers. According tothe spin pumping theory, the predicted damping enhancement
in FM /NM
1/NM 2trilayers decays with the thickness of the
NM 1spacer with low spin-flip rate. Although this theory
gives a plausible general explanation of spin relaxationin magnetic layered systems, it does not provide a fullyquantum-mechanical description of this phenomenon. Sucha description can be achieved using Kambersk ´y’s torque
correlation model [ 29] on which the present calculations are
based.
Despite numerous experiments no quantum calculations of
magnetic damping in magnetic trilayer systems have been re-ported, except a recent paper [ 30] which addresses the Gilbert
damping only in NM /Py/NM symmetric trilayers within an
ab initio scattering formalism. In our recent work [ 31]t h e
damping constant in bulk ferromagnets, ferromagnetic films,and FM/NM bilayers was calculated with the torque corre-lation formula within a realistic tight-binding (TB) model.Therein, it has been shown that magnetic damping in Co /Pd
and Co /Pt bilayers has large nonlocal contributions from their
nonmagnetic parts adjacent to the ferromagnetic Co layer.This paper is devoted to FM /NM
1/NM 2trilayers in which
a significant damping contribution comes from the secondnonmagnetic part NM
2separated from the ferromagnetic layer
by a magnetically inactive spacer. The aim of the present workis to establish the quantum mechanism of the nonlocal Gilbertdamping in such trilayers.
Calculations have been performed for Co /NM
1/NM 2tri-
layers with NM 1=Cu, Ag, and Au as the spacer and NM 2=Pd
and Pt as the cap. The dependence of αon the spacer thickness
and the electron scattering rate is investigated. The nonlocalorigin of the Gilbert damping in such systems is visualizedvia atomic layer contributions to α. To better understand the
mechanism of the nonlocal damping we investigate the spatialdistribution of contributing electron states.
II. THEORY
A phenomenological description of magnetization dynam-
ics in magnetic systems is given by the LLG equation
∂m
∂t=−γm×Heff+αm×∂m
∂t(1)
that represents the time evolution of the unit vector mpointing
along magnetization M. The first term in Eq. ( 1), with the
gyromagnetic ratio γ, describes the Larmor precession of
1098-0121/2015/91(21)/214435(5) 214435-1 ©2015 American Physical SocietyEHSAN BARATI AND MAREK CINAL PHYSICAL REVIEW B 91, 214435 (2015)
magnetization around the effective magnetic field Heff, applied
externally and /or due to magnetic anisotropy. The second
term, proportional to the Gilbert damping constant α, describes
the relaxation of magnetization towards the direction of thefield.
A pioneering quantum-mechanical description of the
Gilbert damping dates back to 1976 when Kambersk ´yp r o -
posed his torque correlation model [ 29]. The expression for
αwithin this model takes the following form for a magnetic
layered system [ 31]
α=π
NFMμs1
/Omega1BZ/integraldisplay
dk/summationdisplay
n,n/prime|Ann/prime(k)|2Fnn/prime(k). (2)
It includes the integration over the wave vector kin the
two-dimensional (2D) Brillouin zone (BZ) of the volume /Omega1BZ
and the sum over band indices n,n/prime. The parameters μsand
NFMstand for the atomic magnetic moment (in units of the
Bohr magneton μB) and the number of atomic layers in the
ferromagnetic part of the system, respectively. The matrixelements A
nn/prime(k)=/angbracketleftnk|A−|n/primek/angbracketrightare found for the torque
A−=[S−,HSO] due to the spin-orbit (SO) interaction HSO
where the spin operator S−=1
2(σx−iσy) is given by the Pauli
matrices σx,σy. The factor Fnn/prime(k) is defined as the integral
over energy
Fnn/prime(k)=/integraldisplay∞
−∞d/epsilon1η(/epsilon1)L(/epsilon1−/epsilon1n(k))L(/epsilon1−/epsilon1n/prime(k)).(3)
Here, η(/epsilon1)=−dfFD/d/epsilon1 is the negative derivative of the
Fermi-Dirac function fFD(/epsilon1), and the two Lorentzians L
depend on the energies /epsilon1n(k),/epsilon1n/prime(k) of the electron states
|nk/angbracketright,|n/primek/angbracketright, respectively. The width of the Lorentz function
L(x)=(/Gamma1/2π)/(x2+/Gamma12/4) is the average electron scattering
rate/Gamma1, treated here as an independent parameter.
The present calculations are based on the TB model of the
electronic structure in magnetic layered systems [ 31,32]. The
TB Hamiltonian, including the SO interaction, is constructedwithin the Slater-Koster formalism [ 33,34]. The expression ( 2)
is employed to calculate αin FM /NM
1/NM 2trilayers with
out-of-plane magnetization; cf. Ref. [ 35] for a discussion on an
arbitrary direction of M. The calculations are done for a wide
range of scattering rates 0 .001 eV /lessorequalslant/Gamma1/lessorequalslant2.0 eV (expressed
as/planckover2pi1/τwith the lifetime τin Refs. [ 36,37]). The integral in
Eq. ( 3) is evaluated efficiently by summing over the Matsubara
frequencies and the poles of the two Lorentz functions [ 31].
Since the calculated αis weakly dependent on temperature T
entering fFD(/epsilon1)[31,37], finite T=300 K is used to obtain a
fast convergence of αwith (60)2kpoints in the 2D BZ. The
calculations are further speeded up by limiting the integrationto 1/8 of the 2D BZ.
III. RESULTS
In this paper, we particularly concentrate on calculation of
αin Co/NM 1/NM 2trilayers. The considered NM 1=Cu, Ag,
and Au spacers are poor spin sinks as possessing long spin-diffusion lengths λ
sd(Refs. [ 18,25,38,39]) and the NM 2=Pd
and Pt caps with short λsd(Ref. [ 25]) are known as perfect spin
sinks.FIG. 1. (Color online) The Gilbert damping constant αin an
Co(6 ML) film, Co(6 ML) /NM 1bilayers (NM 1=Cu, Ag and Au), and
Co(6 ML) /NM 1/NM 2(4 ML) trilayers (NM 2=Pd, Pt) vs NM 1
thickness; the scattering rate /Gamma1=0.01 eV .
In Fig. 1we depict the damping constant αversus the NM 1
spacer thickness in Co(6 ML) /NM 1/NM 2(4 ML) trilayers
for the scattering rate /Gamma1=0.01 eV . For comparison, αfor
the corresponding Co(6 ML) /NM 1bilayers and the Co(6
ML) film ( α/similarequal0.0026 for /Gamma1=0.01 eV) are also shown. The
calculated αin the Co /NM 1/NM 2trilayers declines almost
monotonically, while slightly oscillating, with increasing thethickness Nof the NM
1spacer layer; the oscillation periods
are 5 ML for Cu and 5–7 ML for Ag. These oscillations areattributed to quantum well states with energies close to theFermi level /epsilon1
F.
The damping constant αfound for the Co/Cu /Pt trilayer
is larger than that of the Co /Cu bilayer in accord with
experiment [ 18,23]. The enhancement is over threefold at
the Cu thickness of 3 and 5 ML and more than twofold for5M L<N/lessorequalslant70 ML. Using Pd as the cap instead of Pt also
results in significant damping enhancement though with muchsmaller values of αdue to the weaker SO coupling in Pd.
Almost the same results are obtained if Ag is used insteadof Cu as the spacer, whereas the Au spacer leads to a higherdamping due to its strong SO coupling.
The presently obtained 1 /N
Codependence of αon the
Co thickness NCoin Co/NM 1/NM 2trilayers (not shown)
is also in agreement with experiment on FM /Cu/NM 2het-
erostructures [ 16,17]. Other experimental reports on Py/Cu/Ta
trilayers [ 21] and an Cu /Py/Cu/Pt system [ 18]h a v es h o w n
that the contribution from the second nonmagnetic layer (i.e.,NM
2=Ta and Pt, respectively) vanishes for the spacer layer
thicker than its λsd. However, such spacers are too thick for
calculating αin the present model.
For a spacer with thickness Nmuch smaller than its
spin-diffusion length, the analytical formula for αderived in
the spin pumping theory [ 25,28] yields the following simple
dependence of α=A+B
N+ConN.H e r e A,B, andCare
expressed with NCo, the spin mixing conductance of the
Co/NM 1interface and the parameters of both nonmagnetic
metals: λsdand the electrical conductance. Our results for
214435-2QUANTUM MECHANISM OF NONLOCAL GILBERT DAMPING . . . PHYSICAL REVIEW B 91, 214435 (2015)
FIG. 2. Gilbert damping constant αin Co(6 ML) /Cu(NML)/
Pt(4 ML) trilayers against the scattering rate /Gamma1for different Cu spacer
thicknesses N.
Co/NM 1/NM 2trilayers (Fig. 1) are perfectly fitted with this
general formula within the considered range of the NM 1spacer
thicknesses (up to 70 ML ≈1 2 . 5n m )w h i c ha r es m a l l e rb ya t
least one order of magnitude than λsdof NM 1(200±50 nm
for Cu [ 18,25]).
Figure 2illustrates that the Gilbert damping in Co(6
ML)/Cu(NML)/Pt(4 ML) trilayers alters with the scattering
rate/Gamma1in a similar way for different thicknesses of the Cu
spacer. The minimum of αoccurs at /Gamma1∈[0.01 eV,0.1 eV] de-
pending on N. Such a minimum occurs for bulk ferromagnets
in the same range of /Gamma1[37,40]. As seen, the damping constant
is almost independent of the spacer thickness for /Gamma1/greaterorequalslant0.05 eV .
The experimentally observed decrease in αwith increasing N
is obtained for the range /Gamma1< 0.05 eV , including /Gamma1=0.01 eV
used in the present work.
We attribute the obtained enhancement of the Gilbert
damping in Co /NM 1/NM 2trilayers to the strong SO coupling
in the NM 2cap as well as the high density of states at /epsilon1Fin
NM 2. The effect of the former has already been confirmed
for Co /Pt bilayers by switching off the SO coupling in the Pt
cap [ 31]. The composition of the quantum states contributing
most to αis discussed in more detail below.
A deeper understanding of the nonlocal enhancement of
the Gilbert damping can be achieved by analyzing its spatialdistribution. In our recent paper [ 31], an analytical expression
for the damping constant α=N
−1
FM/summationtext
lαlrepresented by a
sum of contributions αlfrom individual atomic layers lhas
been derived and applied to ferromagnetic films and Co/NMbilayers. Therein, it has been shown how the Gilbert dampingwhich stems from the ferromagnetic (Co) part is also dampednonlocally in the nonmagnetic part of the bilayers. Here, theanalysis of layer contributions is utilized to investigate thenonlocal Gilbert damping in the Co /NM
1/NM 2trilayers.
Figure 3presents the layer contributions to the damping
constant for Co(6 ML) /NM 1/Pt(4 ML) trilayers with different
thicknesses of the NM 1spacer. It is seen that the distribution of
the Gilbert damping within such trilayer structures is similarfor different Cu spacer thicknesses. There are significant layercontributions in the Co part and almost no contributions fromatomic layers inside the Cu spacer. Dominating contributionsFIG. 3. Layer contributions to the damping constant αin
Co/NM 1/Pt trilayers (NM 1=Cu, Au) with different NM 1thick-
nesses; /Gamma1=0.01 eV .
come from the Pt layers in a similar way as previously reported
for Co /NM bilayers with NM =Pd and Pt [ 31]. As the Cu
spacer gets thicker the contributions from the Pt layer getsmaller, in accordance with experiment [ 18] and prediction of
the spin pumping theory [ 28]. However, even for the thickest
considered spacers (70 ML thick) the total contribution from
the Pt cap is larger than the contribution from the Co film.Such spatial distribution of the Gilbert damping is due to thelack and presence of dbands with energies very close to /epsilon1
F
in Cu and Pt, respectively, as well as the strong SO coupling
in Pt. Similar damping distributions (not shown) are obtainedfor Ag spacers and for the NM
2=Pd cap whose top of the d
band lies above /epsilon1Fas in Pt. Since the SO coupling in Pd is
weaker than in Pt the layer contributions inside the Pd cap aresmaller than in the Pt cap. This pattern is noticeably changed ifAu is used as the spacer instead of Cu since there are nonzerocontributions from the Au atomic layers at both the Co/Au andAu/Pt interfaces as well as the modified contributions from
the Co and Pt interface atomic layers.
The obtained results prove the nonlocal nature of the relax-
ation process in the investigated trilayers where magnetizationprecesses in the ferromagnetic Co film, but it is damped inthe distant nonmagnetic cap separated from the Co film by amagnetically inactive spacer. To understand this mechanismon an even more fundamental level we examine the quantumstates that contribute to the Gilbert damping.
The Gilbert damping in the torque-correlation model stems
from two kinds of electron transitions: intraband ( n=n
/prime)
transitions within a single energy band and interband ( n/negationslash=n/prime)
transitions between different energy bands [ 29,37]. The main
source of the damping enhancement in Co(6 ML) /Cu(N
ML)/Pt(4 ML) trilayers with /Gamma1=0.01 eV is the intraband
transitions though the interband transitions also give a signifi-cant contribution to the damping constant as shown in Fig. 4(a).
The spatial composition of quantum states contributing tothe intraband term of αis visualized in Figs. 4(b)–4(d).I ti s
found that, while large contributions come from states almostentirely localized inside the Co film, the majority of states thatsignificantly contribute to the Gilbert damping span throughout
214435-3EHSAN BARATI AND MAREK CINAL PHYSICAL REVIEW B 91, 214435 (2015)
FIG. 4. (Color online) (a) Intraband and interband terms of the
damping constant αin the Co(4 ML)/Cu( NML)/Pt(4 ML) trilayers
with/Gamma1=0.01 eV vs the Cu spacer thickness N; (b)–(d) contributions
to the intraband term of αin the trilayers with N=3,9,30 ML
from quantum states |nk/angbracketrightwith various fractions in the Co film and
the Pt cap. The inclined yellow lines correspond to states with a fixedfraction in the Cu spacer.
the whole trilayer. Such states have a substantial fraction in
each of its three constituent parts: Co, Cu, and Pt. In thetrilayers with the Cu spacer a few ML thick [Fig. 4(b)] these
fractions range from 0.2 to 1 in Co, from 0.0 to 0.8 in Pt, and upto 0.2 in Cu while summing up to 1 for each state. For thickerspacers the states giving predominant contributions to αhave
smaller fractions in Pt, and they tend to be split into two groups.AtN=30 ML the group of states with fractions between
0.1 and 0.5 in both Co and Pt gives a contribution of 0.010to the total α=0.022. These states are responsible for thedamping enhancement due to the combination of their sizable
amplitude in the Pt cap and the large SO coupling strength ofPt. The fraction of these states in Cu grows with increasingthe Cu spacer thickness however the average probability perCu atomic layer is similar for all investigated Cu thickness(3 ML, 9 ML, 30 ML) and it is around 0 .02 ML
−1. Thus, the
states leading to enhanced αin the Co /Cu/Pt trilayers with
thick Cu spacer are composed of bulklike spstates in Cu and,
attached to them, dstates in Co and Pt with amplitudes up to
a few times larger than in Cu.
IV . CONCLUSIONS
We present a quantum-mechanical calculation of the Gilbert
damping constant αin Co/NM 1/NM 2trilayers within the
torque-correlation model. The damping is found to be remark-ably enhanced due to adding Pt as the second nonmagneticlayer NM
2, and it decreases with increasing the thickness of the
NM 1=Cu, Ag, and Au spacers in agreement with experiment.
The analysis of atomic layer contributions to αelucidates the
nonlocal nature of the Gilbert damping in magnetic trilayers.The spatial decomposition of quantum states contributing tothe damping shows that its enhancement is due to delocalizedelectrons whose wave functions are sizable in all parts ofthe trilayers. The spins of such electrons contribute to themagnetization in the ferromagnetic Co layer, but they alsostrongly interact, via the SO coupling, with heavy atoms in thePt layer. Therefore, the precession of these spins is dampedefficiently, and this leads to enhanced damping of the totalmagnetic moment, although it is almost entirely confined tothe Co layer. This paper thus provides insight into quantummechanisms of magnetic damping in metallic layered systems.
ACKNOWLEDGMENTS
We acknowledge the financial support of the Foundation
for Polish Science within the International PhD Projects Pro-gramme, cofinanced by the European Regional DevelopmentFund within Innovative Economy Operational Programme“Grants for innovation”.
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214435-5 |
PhysRevB.100.235453.pdf | PHYSICAL REVIEW B 100, 235453 (2019)
Controlling spins with surface magnon polaritons
Jamison Sloan,1,*,†Nicholas Rivera,2,*John D. Joannopoulos,2Ido Kaminer,3and Marin Solja ˇci´c2
1Research Laboratory of Electronics, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, USA
2Department of Physics, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, USA
3Department of Electrical Engineering, Technion—Israel Institute of Technology, Haifa 32000, Israel
(Received 11 February 2019; revised manuscript received 11 November 2019; published 30 December 2019)
Polaritons in metals, semimetals, semiconductors, and polar insulators can allow for extreme confinement
of electromagnetic energy, providing many promising opportunities for enhancing typically weak light-matterinteractions such as multipolar radiation, multiphoton spontaneous emission, Raman scattering, and materialnonlinearities. These extremely confined polaritons are quasielectrostatic in nature, with most of their energyresiding in the electric field. As a result, these “electric” polaritons are far from optimized for enhancingemission of a magnetic nature, such as spin relaxation, which is typically many orders of magnitude slowerthan corresponding electric decays. Here, we take concepts of “electric” polaritons into magnetic materials, andpropose using surface magnon polaritons in negative magnetic permeability materials to strongly enhance spin
relaxation in nearby emitters. Specifically, we provide quantitative examples with MnF
2and FeF 2, enhancing
spin transitions in the THz spectral range. We find that these magnetic polaritons in 100-nm thin films can beconfined to lengths over 10 000 times smaller than the wavelength of a photon at the same frequency, allowingfor a surprising 12 orders of magnitude enhancement in magnetic dipole transitions. This takes THz spin-fliptransitions, which normally occur at timescales on the order of a year, and forces them to occur at sub-mstimescales. Our results suggest an interesting platform for polaritonics at THz frequencies, and more broadly, away to use polaritons to control light-matter interactions.
DOI: 10.1103/PhysRevB.100.235453
Polaritons, collective excitations of light and matter, offer
the ability to concentrate electromagnetic energy down tovolumes far below that of a photon in free space [ 1–6], holding
promise to achieve the long-standing goal of low-loss con-finement of electromagnetic energy at the near-atomic scale.The most famous examples are surface plasmon polaritons onconductors, which arise from the coherent sloshing of surfacecharges accompanied by an evanescent electromagnetic field.These collective excitations are so widespread in optics thattheir manipulation is referred to as plasmonics. Plasmonsenjoy a myriad of applications, particularly in spectroscopydue to their enhanced interactions with matter. This enhance-ment applies to spontaneous emission, Raman scattering,optical nonlinearities, and even dipole-“forbidden” transitionsin emitters [ 7–16]. Beyond plasmons in metals, polaritons in
polar dielectrics, such as phonon polaritons [ 17–20]a r en o w
being exploited for similar applications due to their ability toconcentrate electromagnetic energy on the nanoscale in themid-IR /THz spectral range.
The ability of nanoconfined polaritons to strongly enhance
electromagnetic interactions with matter can ultimately beunderstood in terms of electromagnetic energy density. Anelectromagnetic quantum of energy ¯ hω, confined to a volume
V, leads to a characteristic root-mean-square electric field of
order√
¯hω
/epsilon10V. In the case of field interaction with an electron in
an emitter, this characteristic field drives spontaneous emis-sion, and thus concentration of energy to smaller volumes
*These authors contributed equally to this paper.
†Corresponding author: jamison@mit.eduleads to enhanced emission. This well-studied phenomenonis best known as the Purcell effect [ 21]. Interestingly, if one
looks at the electromagnetic energy distribution of a highlyconfined plasmon or phonon polariton, one finds that an over-whelming majority of this energy resides in the electric field[22–24]. For a polariton with a wavelength 100 times smaller
than that of a photon at the same frequency, the magnitudeofEis then 100 times larger than that of μ
0cH. In sharp
contrast to free space wave propagation, the energy residingin the magnetic field is of the order of a mere 0 .01% of the
total energy ¯ hω. This largely suggests that such excitations
are relatively inefficient for enhancing spontaneous emissionprocesses which couple to the magnetic field, such as spin-fliptransitions or magnetic multipole decays. As such, enablingmagnetic decays at very fast rates represents a rewarding chal-lenge, as increasing rates of spontaneous emission can provideopportunities for detectors, devices, and sources of light.
The Purcell enhancement of magnetic dipole transitions
has been approached by a few basic means: The use ofhighly confined resonances at optical frequencies [ 25,26],
metamaterials [ 27,28], and for microwave frequencies, mate-
rials with simultaneously very high quality factors and highlyconfined fields. These advances are reviewed in Ref. [ 29].
Many of these methods have the benefit of compatibility withwell-known materials and use at optical frequencies, but thePurcell enhancements in these cases are typically very farfrom maximal Purcell enhancements that can be achievedwith “electric” polaritons at similar frequencies [ 14,16,30–
33]. This prompts the question: What kind of electromagnetic
response allows one to achieve a similar degree of very strongenhancement for magnetic transitions?
2469-9950/2019/100(23)/235453(11) 235453-1 ©2019 American Physical SocietyJAMISON SLOAN et al. PHYSICAL REVIEW B 100, 235453 (2019)
The duality between electric and magnetic phenomena,
combined with ideas from plasmonics and nano-optics, sug-gests a pathway for achieving strong magnetic transitionenhancement: Highly confined magnetic modes in materialswith negative magnetic permeability . In particular, plasmon
and phonon polaritons are associated with a negative dielec-tric permittivity /epsilon1(ω). By the well-established principle of
electromagnetic duality [ 34,35], if one replaces /epsilon1(ω) with the
magnetic permeability μ(ω), then the electric field Ein the
dielectric structure becomes the magnetic field Hin the dual
magnetic structure. Thus, to very efficiently enhance magneticdecays, one desires a material with negative μ(ω) which sup-
ports modes dual to “electric” surface polaritons. While likelynot the only example, AFMR is a well-studied example of aphenomenon which can provide precisely this permeability,and the corresponding modes are surface magnon polaritons(SMPs) [ 36–38].
Here, we use macroscopic quantum electrodynamics
(MQED) of magnetic materials to propose extreme enhance-ment of magnetic transitions in nearby quantum emitters byusing highly confined SMPs. We find enhancement of spinrelaxation rates by over 12 orders of magnitude, showingmagnetic Purcell enhancements as large as the highest limitspredicted for electric Purcell enhancements. We discuss howthe losses present in magnetic materials impact the magneticdecay rate and argue that even with these considerations,extremely large enhancements can be achieved. Such en-hancements could provide access to extremely fast magneticdipole decays, shortening radiative lifetimes on the order of ayear to submillisecond timescales.
The organization of this paper is as follows: In Sec. I,w e
review the classical electrodynamics of SMPs and derive thedispersion relation and mode profile of SMPs for the exam-ple of an antiferromagnetic thin film. We briefly review thepropagation properties of these modes and, in particular, notetheir extremely large confinement. In Sec. II,w eu s eM Q E D
to quantize the SMP modes and calculate the spontaneousemission rate of nearby magnetic dipole emitters into thesemodes. Finally, in Sec. III, we provide quantitative results
for the spontaneous emission by spin systems near existingmagnon-polaritonic materials, such as MnF
2and FeF 2.
I. SURFACE MAGNON POLARITON MODES
The spin interactions in solids which give rise to different
varieties of magnetic order have been studied extensively.Of particular note for our purposes is the study of the long-range order established by spin waves in (anti)ferromagnets[39–47]. These spin waves can be excited at the level of a
single quantum, and the quasiparticles associated with theseexcitations are magnons [ 37]. More recently, magnons have
attracted considerable attention for their ability to interactwith electric currents and electron spins, leading to the rapidlygrowing field of magnon spintronics [ 48–57].
We begin by reviewing the confined modes which exist on
thin films of materials with negative magnetic permeability,denoted μ(ω). The modes we describe are well-studied SMPs
[36,58–60] with Re μ(ω)/lessorequalslant0. At a microscopic level, the
modes correspond to ordered precession of the spins in anantiferromagnetic lattice and are also referred to as surfaceTABLE I. Anisotropy fields, exchange fields, sublattice mag-
netization, resonance frequencies, and damping constants (where
known) for antiferromagnetic materials that can support SMPs.
Parameters are taken from Refs. [ 66,69].
Material μ0HA(T)μ0HE(T)μ0HM(T)ω0(rad THz) τ(nsec)
MnF 2 0.787 53.0 0.06 1.69 7.58
FeF 2 19.745 53.3 0.056 9.89 0.11
GdAlO 3 0.365 1.88 0.062 0.23 –
spin waves [ 61]. The classical dynamics of spin-wave propa-
gation are governed by the Landau-Lifshitz-Gilbert equation,which accounts for damping [ 62,63]. These microscopic inter-
actions give rise to a magnetic susceptibility (or equivalentlya magnetic permeability) which dictates how macroscopicelectromagnetic fields propagate in the material. Given theclassical solutions to the Maxwell equations in a materialconfiguration, one can then quantize the magnon modes,allowing the use of quantum optics techniques to describethe interaction of magnon modes in the vicinity of emitters.We construct these classical solutions, quantize these modes,and then solve for magnetic dipole transition rates into thesemodes.
For the specific case of an antiferromagnetic material near
resonance, the frequency-dependent permeability which in-cludes material losses takes the form of a Lorentz oscillatorwhich depends on the microscopic magnetic properties ofthe antiferromagnetic crystal. Studies of the crystal structuresof important antiferromagnetic materials can be found inRef. [ 64]. The magnetic permeability function for antiferro-
magnetic resonance (AFMR) in the absence of an externalmagnetizing field from [ 65–67]i s
μ
xx=μyy=1+2γ2HAHM
ω2
0−(ω+i/Gamma1)2, (1)
with coordinates shown in Fig. 1.I nE q .( 1),ω0is the
resonance frequency, HAis the anisotropy field, HMis the sub-
lattice magnetization field, γis the gyromagnetic ratio, and
/Gamma1=1/τis a phenomenological damping parameter inversely
proportional to the loss relaxation time τ. Furthermore, in
the approximation of low damping, the resonant frequency isgiven as ω
0=γ√2HA(HA+HE), where HEis the exchange
field which is representative of the magnetic field required toinvert neighboring spin pairs. For antiferromagnetic materialssuch as MnF
2and FeF 2, the resonance frequencies ωtakes
values 1 .69×1012and 9.89×1012rad/s, respectively, and
have negative permeability over a relatively narrow bandwidthon the scale of a few GHz. Most importantly for our purposes,Reμ(ω)<0f o rω<ω
0<ω max, which will permit surface-
confined modes. Finally, we note that we have implicitly as-sumed that the magnetic permeability carries no dependenceon the wave vector through nonlocal effects. For wavelengthswhich substantially exceed the atomic lattice spacing, thisshould be an excellent approximation. A more detailed dis-cussion of nonlocality in terms of mean-field parameters fromLandau-Ginzburg phase transition theory can be found inRef. [ 68]. Table Ishows values of material parameters for a
variety of antiferromagnetic materials. Figure 2(a) shows the
real and imaginary parts of the magnetic permeability μ(ω)
235453-2CONTROLLING SPINS WITH SURFACE MAGNON … PHYSICAL REVIEW B 100, 235453 (2019)
FIG. 1. Electromagnetically dual relationship between surface plasmon polaritons on negative permittivity materials and surface magnon
polaritons on negative permeability materials. (a) Surface plasmon polariton represented as charge density oscillations in a negative /epsilon1material.
These quantum fluctuations can couple strongly to an electric dipole emitter near the surface to drive enhanced spontaneous emission.(b) Surface magnon polariton represented as a spin density oscillation in a negative μmaterial. These quantum fluctuations can couple strongly
to a magnetic dipole emitter near the surface to drive enhanced spontaneous emission. Both electric and magnetic surface polaritons can exhibit
strong mode confinement, helping to overcome the mismatch between mode wavelength and emitter size.
associated with the AFMR in MnF 2. We see that at the peak
of the resonance, Re( μ)≈−40 and Im( μ)≈90.
We now discuss the geometry of the thin-film configura-
tions we study. Antiferromagnetic fluorides exhibit a uniaxialpermeability structure with two orthogonal components ofthe permeability tensor given by μ(ω) above, and the other
orthogonal component as unity. We start by focusing oncrystal orientations in which μ=(μ(ω),μ(ω),1). It is also
worthwhile to note that experiments, specifically on nonre-ciprocal optical phenomena [ 70], have been performed on
these materials in a less conventional geometry where μ=
(μ(ω),1,μ(ω)). The in-plane anisotropy of this configuration
substantially complicates the dispersion relation and propaga-tion structure of the modes. As such, we focus primarily on theisotropic case but present results for the in-plane anisotropiccase near the end of the text.
For concreteness, we focus on MnF
2, a material which
has been studied in depth both in theory and experiment[71,72], and also exhibits a relatively low propagation loss.
We note that FeF
2is also a promising candidate with higher
resonance frequency, but also higher loss [ 73,74]. We solve
for SMPs supported by optically very thin (here, submicronthickness denoted by d)M n F
2films surrounded by air. For
the confined modes we consider, the effect of retardation isnegligible [ 75], and thus we can find the magnon modes using
a quasimagnetostatic treatment as described in Ref. [ 66]. In
the magnetostatic limit, the resulting “polaritons” are muchmore magnonlike than photonlike. Nevertheless, many ofthe applications which are considered in polaritonics arefeasible with these modes [ 2,4]. In the absence of retardation,
the electric field is negligible, and the magnetic field, sincethere are no free currents, satisfies ∇×H=0. Thus the
magnetic field can then be written as the gradient of a scalarpotential H=∇ψ
H. This scalar potential then satisfies a
scalar Laplace equation,
∂iμij(ω)∂jψH=0, (2)
where we have used repeated indices to denote summation. In
this paper, the absence of applied magnetic fields guaranteesthatμ
ijis diagonal, and so Eq. ( 2) contains only three terms.
Applying boundary conditions for the continuity of Bin the
zdirection and of Hin the xyplane at the two interfaces of afilm of thickness dgives the dispersion relation
qn=1
2d√−μ(ω)/bracketleftbigg
tan−1/parenleftbigg1√−μ(ω)/parenrightbigg
+nπ
2/bracketrightbigg
, (3)
where nis an integer, qnis the in-plane wave vector of mode n,
andμ(ω) is the permeability given in Eq. ( 1). We see that qn
is inversely proportional to the thickness of the slab d, which
is anticipated, as the thickness of the material sets the scaleof the wave solution in the zdirection. Identical to confined
modes on thin films of plasmonic materials (silver and goldfor instance), a thinner film results in a smaller wavelength.An extreme limiting case in plasmonics is graphene, in whichan atomically thin layer is capable of confining surface plas-mons with confinement factors of 200 [ 5]. Figure 2(c) shows
plots of the scalar potential ψ
Hassociated with SMP modes on
MnF 2, which is proportional to the magnetic field in direction
of propagation. The scalar potential solutions to the Laplaceequation take the form
ψ
n
H(r,ω)=/braceleftBigg
eiqn·ρe−qn|z||z|>d/2/parenleftbige−qnd
f(qnd)/parenrightbig
eiqn·ρf(qnz)|z|<d/2,(4)
where ρ=(x,y) is the in-plane position, f(x)=cos(x)f o r
even modes, and f(x)=sin(x) for odd modes. Taking the gra-
dient of the scalar potential gives the fully vectorial magneticfield, which reveals that the SMP mode propagates in the in-plane direction ˆ qwith circular polarization ˆ ε
q=(ˆq+iˆz)/√
2.
This polarization is well known to be typical of quasistaticsurface polariton modes, whether they are the transverse mag-netic modes associated with quasielectrostatic excitations ortransverse electric modes associated with quasimagnetostaticexcitations.
We now discuss the key properties of these surface
modes, including their dispersion, confinement, velocities,and quality factor resulting from material losses. In Fig. 2(b),
we plot the material-thickness-invariant dispersion relationω(qd). The dimensionless wave vector qdindicates how the
size of the in-plane wave vector compares to the thickness ofthe film. We note that we have incorporated the effect of lossinto the dispersion by finding solutions with real frequencyand complex wave vector. Our dispersion plots show the realpart of the wave vector. In the lossless limit, the dispersion
235453-3JAMISON SLOAN et al. PHYSICAL REVIEW B 100, 235453 (2019)
FIG. 2. Surface magnon polariton (SMP) modes on MnF 2. (a) Frequency-dependent permeability function for MnF 2calculated using
Eq. ( 1) and using the parameters given in Table I.F o rM n F 2, the resonance frequency is ω0=1.68×1012rad/s. For ω0<ω<ω max,
Re(μ)<0, allowing for surface modes. (b) Dispersion relation for MnF 2of thickness d, calculated in the quasimagnetostatic limit which
is valid in the range of thicknesses dwe consider. The first four modes are shown. (c) Visualization of fundamental and first harmonic mode
SMP through the field component Hxshown for a d=200-nm film of MnF 2atω/ω 0=1.005. The locations of these two modes are indicated
on the dispersion curve.
is asymptotic to a fixed frequency in the limit that q→∞ .
The introduction of loss causes the band to fold back on itself,placing a limit on the wave vectors which can be excited.Consequently, modes near the peak of this folded band exhibitthe highest attenuation.
The dispersion plot shows the first four bands—the
fundamental mode ( n=0) as well as three higher harmonics
(n=1,2,3). Due to the the reflection symmetry of the geom-
etry in the zdirection, two of these modes are even parity, and
two are odd parity. We can interpret the mode index as thenumber of half oscillations which the magnetic field makes inthezdirection of the film. Higher order modes will have larger
wave vectors. Once again, we can further understand thedispersion relation of these modes through analogy to existingpolaritonic systems. Specifically, MnF
2is a hyperbolic
material since μ⊥>0 while μ/bardbl<0 (where the directions ⊥
and/bardblare taken with respect to the zaxis). This is much like
the naturally occurring hyperbolic material hexagonal boronnitride, which has one component of its permittivity negative,while another component is positive [ 18,19]. As a result of
this, these systems have a multiply branched dispersion, andthe electromagnetic fields are guided inside the crystal. Thefirst two modes ( n=0,1) are shown in Fig. 2(c), where
we note the mode confinement to the slab, as well as theevanescent tails which enable interaction with surrounding
emitters.
The most impressive figure of merit of these modes is
the size of their wavelength in comparison to the free spacewavelength at a given frequency, also known as a confinementfactor or effective index of the mode. Figure 3(b) highlights
this, showing the confinement factor η=qc/ω=λ
0/λSMPfor
the first four modes ( n=0,1,2,3) on d=200 nm MnF 2as
a function of frequency. We see that the fundamental modereaches a peak confinement of η=2×10
4, while the first
harmonic is confined to twice that with η=4×104.
These values exceed by two orders of magnitude the
maximum confinement values that have been observed incommon plasmonic media such as thin films of silver, gold,or titanium nitride, or doped graphene. Furthermore, sincethe confinement scales linearly with q∼1/d, decreasing the
material thickness increases the achievable range of confine-ment factors. As a simple example of this, consider that amaterial thickness of d=50 nm would correspond to a wave
vector four times larger than for d=200 nm, in other words
a maximum fundamental mode confinement of 8 ×10
4, and a
confinement above 104for much of the surface magnon band.
An explanation for this high confinement in terms of most
basic principles is that the frequencies at which SMPs exist
FIG. 3. Propagation properties of SMP modes on MnF 2. The following dimensionless quantities are plotted for MnF 2with propagation loss
τ=7.58 nsec for the first four modes indexed by n=(0,1,2,3): (a) mode quality factor Q=Re(q)/Im(q) as a function of mode frequency,
(b) mode confinement factor η=qc/ωas a function of mode frequency, and (c) normalized group velocity vg/c=|dω/dk|/cas a function of
mode frequency.
235453-4CONTROLLING SPINS WITH SURFACE MAGNON … PHYSICAL REVIEW B 100, 235453 (2019)
(GHz-THz) are orders of magnitude lower than for plasmons
which typically exist in IR to optical regimes. Simultaneously,the scale of the wave vector qin both plasmonic and magnonic
media is set by the film thickness dfor electrostatic and mag-
netostatic modes, respectively (this means that plasmons andmagnons will have wave vectors of similar scale, regardlessof frequency). In other words, at a fixed material thickness,lower frequency surface magnons have substantially higherpotential for geometrical squeezing than surface plasmons.We note that this is not of purely formal interest, as whenconsidering the enhancement of spontaneous emission, onefinds that the enhancement is proportional to a power ofprecisely this confinement factor.
In addition to understanding the confinement of magnon
polaritons, it is also important to understand their propagationcharacteristics, such as propagation quality factor, and groupvelocity. Figures 3(a) and3(c) shows the quality factor Q=
Re(q)/Im(q), as well as the normalized group velocity v
g/c
as a function of frequency for the first four modes. We seethat propagation losses are lowest toward the middle of theallowed frequency band, showing quality factors greater than20 for the fundamental mode ( n=0). Additionally, we see
that the group velocity v
greaches its maximum near the lower
portion of the allowed frequency range, and goes toward zeroat the other end.
II. THEORY OF SPIN RELAXATION
INTO MAGNON POLARITONS
We now discuss how an an emitter with a magnetic dipole
transition placed above the surface of a thin negative per-meability material can undergo spontaneous emission intoSMPs which is much faster than the emission into free spacephotons. First, we consider the Hamiltonian which couplesthe magnetic moment of the emitter to the quantized mag-netic field. Fluctuations in the evanescent magnetic field fromSMPs can then cause the emitter to relax via the emission of aSMP. The rate at which this process occurs is calculated usingFermi’s golden rule. Finally, we discuss the effect of materiallosses on the total decay rate, and argue that for parameters ofinterest, the effect should be small.
We first discuss the mechanisms that can allow an emitter
to couple to highly confined SMPs. A magnetic field can cou-ple to both the electron spin angular momentum and orbitalangular momentum, as both angular momenta contribute tothe electron’s magnetic moment. We describe this interactionquantum mechanically with an interaction Hamiltonian H
int
between an emitter and a magnetic field [ 76,77]
Hint=−μ·B=−μB(L+gS)
¯h·B, (5)
where μis the total magnetic moment of the emitter, S=
¯h
2σis the spin angular momentum operator, Lis the orbital
angular momentum operator, g≈2.002 is the Landé g-factor.
In this Hamiltonian, we note that Bis the quantized magnetic
field operator associated with SMP modes.
To provide a fully quantum mechanical description of
the interactions, we use the formalism of macroscopic QED(MQED) to rigorously quantize the electromagnetic fieldmodes in a medium (in this case, a thin slab of negativepermeability material) This approach is similar to that in
Ref. [ 78], which was applied to quantize electromagnetic
fields in dielectric structures. We consider a geometry ofan e g a t i v e μmaterial which is translation invariant (i.e., a
slab geometry). In this case, the modes are labeled by anin-plane wave vector q. We can then construct an operator
which creates and annihilates excitations of the magnetic fieldwhich are normalized so each SMP carries energy ¯ hω
q.T h e
magnetic field operator in the evanescent region above the slab(z>d/2) takes the form
B(r)=/summationdisplay
q/radicalBigg
μ0¯hω
2ACq(ˆεqeiq·ρe−qzaq+ˆε∗
qe−iq·ρe−qza†
q),(6)
where a†
qandaqare creation and annihilation operators for
the SMP modes satisfying the canonical commutation relation[a
q,a†
q/prime]=δqq/prime,ˆεqis the mode polarization, Ais the area
normalization factor, and Cq=/integraltext
dzH∗(z)·d(μω)
dω·H(z)i sa
normalization factor ensuring that the mode H=∇ψHhas
an energy of ¯ hωq. The energy has been calculated according
to the Brillouin formula for the electromagnetic field energyin a dispersive medium in a transparency window [ 79,80].
As a point of comparison, we note that similar quantiza-tion schemes have been implemented for surface plasmon-polariton modes on graphene [ 22] and many other systems in
optics [ 78,81]. In this expression for the energy, we have also
used the fact that the modes are magnetostatic in nature, so thecontribution of the electric field to the energy associated withthem is negligible.
To establish the strength of the coupling between a mag-
netic dipole emitter and SMPs, we calculate spontaneousemission of a spin into a thin negative μmaterial such as
an antiferromagnet, using Fermi’s golden rule. The rate oftransition via the emission of a magnon of wave vector qis
given as
/Gamma1
(eg)
q=2π
¯h2|/angbracketleftg,q|Hint|e,0/angbracketright|2δ(ωq−ωeg). (7)
We specify the initial and final states of the system as
|e,0/angbracketrightand|g,q/angbracketright, respectively, where e and g index the excited
and ground states of the emitter, qis the wave vector of
the magnon resulting from spontaneous emission, ωqis its
corresponding frequency, and ωegis the frequency of the spin
transition. Note that Eq. ( 7) applies generally and can capture
any multipolar magnetic transition.
With the magnetic field quantized appropriately and the in-
teraction Hamiltonian established, obtaining the spontaneousemission rate proceeds in the usual way. Substituting Eq. ( 6)
into the Hamiltonian of Eq. ( 5), and then applying Fermi’s
golden rule as written in Eq. ( 7), we find that the spontaneous
emission rate /Gamma1
(eg)per unit magnon in-plane propagation
angleθis given by
d/Gamma1(eg)
dipole
dθ=μ2
Bμ0ωeg
2π¯hq3(ωeg)
Cq(ωeg)|vg(ωeg)|e−2q(ωeg)z0|Meg|2,(8)
where |vg|=|∇qω|is the magnitude of the SMP group veloc-
ity,μBis the Bohr magneton, and Meg=/angbracketleftg|ˆ/epsilon1q·(L+gS)|e/angbracketrightis
the matrix element which describes the transition. Also notethat here we have made the dipole approximation for magnetic
235453-5JAMISON SLOAN et al. PHYSICAL REVIEW B 100, 235453 (2019)
transitions, which comes from assuming that the evanescent
field of the emitted SMP varies negligibly over the size ofthe emitter, and can thus be assumed constant. However, ifone wishes to remove this simplifying assumption to considermagnetic multipole transitions, the matrix element can benumerically evaluated. To simplify the proceeding discussion,we focus on cases where the transition corresponds only toa change of spin of the electron in the emitter from |↑/angbracketright
to|↓/angbracketright, this matrix element is simply proportional to σ
eg=
/angbracketleft↓ |σ·ˆεq|↑ /angbracketright. Here, the angular dependence can come solely
from the magnon polarization. For a spin transition orientedalong the z(i.e., out-of-plane) axis, the transition strength
into modes at different θwill be the same, and thus the
distribution of emitted magnons isotropic. Spin transitionsalong a different axis will break this symmetry, resultingin angle-dependent emission. In any case, the total rate of
emission is obtained by integrating over all angles as /Gamma1
(eg)
dipole=/integraltext2π
0(d/Gamma1(eg)
dθ)dθ.
We now consider the effect of material losses, and argue
that the lossless approximation for decay rates presented hereshould provide a strong approximation for decay rates inthe presence of losses. The formalism of macroscopic QEDdetailed in Ref. [ 34] can be used to incorporate material
losses into spontaneous emission calculations. It was foundexplicitly in Ref. [ 14] that, in general, the presence of losses
does not drastically change the total decay rate of the emitter,unless the emitter is at distances from the material muchsmaller than the inverse wave vector of the modes that areemitted. For the case of relatively low losses, Fermi’s goldenr u l es h o w ni nE q .( 7) can be modified by replacing the delta
function density of states with a Lorentzian of width /Delta1ω≡
1/τ. The lossy decay rate is then obtained as a convolution of
this Lorentzian frequency spread with the lossless rate as
/Gamma1
(eg)
dipole−→/integraldisplay
/Gamma1(eg)
dipole/parenleftbigg1
π1/(2τ)
(ωeg−ω)2+(1/2τ)2/parenrightbigg
dω. (9)
In general, this correction from losses will be small provided
that the range of frequencies /Delta1ω coupled by Eq. ( 9)i s
small compared to the width of the magnon band, denoted/Delta1/Omega1. More succinctly, losses are negligible if /Delta1ω//Delta1/Omega1 /lessmuch1.
For the MnF
2considered here, /Delta1ω≈10−8s−1, and/Delta1/Omega1≈
1010s−1,s o/Delta1ω//Delta1/Omega1 ≈10−2, confirming that the Lorentzian
distribution behaves similarly to a delta function δ(ωeg−ω)
which does not mix frequencies. Having presented the generalframework for analyzing SMP emission, we now presentspecific results for SMP emission into a thin film of MnF
2.
III. TRANSITION RATE RESULTS
A. Dipole transition rates
We first discuss the transition rates and associated Purcell
factors of magnetic dipole emitters. For a z-oriented spin flip
of frequency ωegplaced a distance z0from the surface of a
negative μfilm, the spontaneous emission rate is given as
/Gamma1(eg)
dipole=μ2
Bμ0ωeg
¯hq2(ωeg)
C/prime(ωeg)|vg(ωeg)|e−2q(ωeg)z0, (10)
where C/prime(ω)=C(ω)/q(ω) is introduced to remove the wave-
vector dependence from the normalization. We also note that
FIG. 4. Dipole transition rate enhancement by SMPs. (a) Dipole
transition rate for a z-oriented spin flip as a function of normalized
frequency and distance z0from the emitter to the surface of a
d=200 nm MnF 2film. The transition rates decay exponentially
with increasing distance from the surface. (b) Line cuts of the
information shown in (a) for different fixed distances z0.T h ea x i s
on the left shows the total transition rate, while the axis on the
right shows the Purcell factor; in other words, the transition ratenormalized by the free space transition rate.
the group velocity |vg(ω)|∝1/q(ω), and thus the whole
expression, carries a wave-vector dependence of /Gamma1(eg)
dipole∝
q3(ωeg).
We now discuss the numerical values for spin-flip tran-
sition rates in nearby emitters which come directly fromEq. ( 10). We find these transition rates into SMPs to be orders
of magnitude faster than the rates of transition into free-spacephotons at the same frequency. Figure 4shows the emission
rate as a function of frequency ωand emitter distance z
0for
ad=200 nm MnF 2film. Figure 4(b) shows line cuts of
the dipole transition rate at various emitter distances z0.I n
this geometry, we find that for the highest supported magnonfrequencies, the total rate of emission may exceed 10
5s−1,
which corresponds to a decay time of 10 μs. This is 11 or-
ders of magnitude of improvement over the free-space decaylifetime of more than a week. We see that for sufficientlyclose distances z
0, the decay rate increases with ω, spanning
many orders of magnitude over a small frequency bandwidth.Furthermore, we see that with increasing distance z
0,t h e
total decay rate is suppressed exponentially by the evanescenttail of the surface magnon. More specifically, we see in theexponential dependence e
−2q(ωeg)z0that, for rate enhancement
to be effective, z0should be comparable to or ideally smaller
than 1 /q∼d. For a 200-nm film, enhancement begins to
235453-6CONTROLLING SPINS WITH SURFACE MAGNON … PHYSICAL REVIEW B 100, 235453 (2019)
saturate for z0<20 nm. In terms of a potential experiment,
these are promising parameters which could result in a totaltransition rate of 10
4s−1. Finally, we note that at distances z0
extremely near to the surface, effects such as material losses
or nonlocality may cause the behavior of the transition rateto deviate slightly from the predicted behavior. The exactmagnitude of such effects could be taken into account directlyby solving for the dispersion with the full, nonlocal, magneticsusceptibility which is presented in Ref. [ 68].
It is also worthwhile to consider not only the total transition
rates, but also the Purcell factors. The right side axis ofFig. 4(b) shows the Purcell factor for spin relaxation into
SMPs, computed as the ratio between the enhanced transi-tion rate and the free-space transition rate, and denoted asF
p(ω)=/Gamma1dipole//Gamma10. We note that while the transition rate
in the magnonic environment is technically the sum of theSMP emission rate and the radiative rate, in our systems theradiative rate is so small that it need not be considered.
Thinner films offer even more drastic capabilities for en-
hancement. The dipole transition rate and Purcell factor scaleasη
3, which means that shrinking the film thickness deven
by conservative factors can result in a rapid increase in themaximum transition rate achievable. This η
3scaling is exactly
the same scaling found for Purcell factors of electric dipoletransition enhancement in the vicinity of highly confined elec-trostatic modes such as surface plasmon polaritons [ 14,17,33].
Having established the duality between electric and mag-
netic surface polaritonics in the context of Purcell enhance-ment, other important conclusions about the scope and utilityof SMPs follow. Most notably, Purcell factors for higher ordermagnetic processes should scale with mode confinement iden-tical to those for the corresponding electric processes. Givenan emitter-material system that can support such processes,it should be possible to compute transition rates of higherorder processes such as magnetic quadrupole transitions andmultimagnon emission processes. Conveniently, electromag-netic duality implies that the confinement scaling properties ofall electric multipolar or multiphoton transitions into electricpolaritons are identical to those of their magnetic analogs. Forexample, the magnetic quadrupole transition Purcell factorshould scale as ∝η
5. For emission into modes confined to
factors of 1000 or more, this enhancement factor could easilyexceed 10
15, alluding to the possibility of making highly
forbidden magnetic quadrupole processes observable.
B. Emission with in-plane anisotropy
Thus far, we have considered geometries of MnF 2in which
the anisotropy axis of the crystal is out of the plane of a thinfilm (in the zdirection). Past work has brought both theoretical
interest as well as experimental studies on antiferromag-netic surface interfaces in which the magnetic permeabilityanisotropy axis lies in plane. In other words, the material hasnegative permeability in the out-of-plane direction as well asone in-plane direction, while having a permeability of 1 inthe other in-plane direction. This geometry gives rise to anrich anisotropic dispersion relation of SMP modes, which inturn result in a nontrivial angular dependence for processes ofspontaneous emission. We summarize those findings here.For the in-plane anisotropic geometry with μ=
(μ(ω),1,μ(ω)), the dispersion (obtained again by solving
Maxwell’s equations for a quasimagnetostatic scalarpotential) is given by solutions to
e
qd√β(θ,ω)=1−μ(ω)√β(θ,ω)
1+μ(ω)√β(θ,ω), (11)
where β(θ,ω)=cos2θ+sin2θ/μ(ω) andθis the in-plane
propagation angle measured with respect to the xaxis. When
β> 0, the mode function has a zdependence of cosh( qz)
or sinh( qz), dependent on the parity of the solution. When
β< 0, the modes have a cos( qz)o rs i n ( qz) dependence.
We note that the β< 0 solutions have a multiply branched
structure which correspond to higher harmonic modes, just aswith the in-plane isotropic case discussed throughout the text.Furthermore, recalling that μ< 0 and examining β(θ,ω), we
see that for angles of propagation near 0, βwill be positive,
while for angles of propagation near π/2,βis negative. Based
on the sign of β, we can classify the modes into two distinct
types. We refer to β> 0 modes as type-I modes and β< 0
modes as type-II modes. The fundamental type-I modes prop-agate in the range θ∈(0,θ
x), where θx=tan−1(√−μ(ω)),
while the type-II modes with n=1 propagate in the range θ∈
(θy,π/2), with θy=cos−1(1/√−μ(ω)). The angular prop-
agation ranges for the type-I modes and the lowest ordertype-II mode are nonoverlapping and the gap between θ
xand
θyincreases with ω.
The dispersion for even type-I and type-II modes are,
respectively, given as
qI=−1
2d√β(θ,ω)tanh−1/parenleftbigg1
μ(ω)√β(θ,ω)/parenrightbigg
, (12)
qn
II=1
2d√−β(θ,ω)tan−1/parenleftbigg1
μ(ω)√−β(θ,ω)+nπ
2/parenrightbigg
,
(13)
where nis an integer. We see that for even type-I modes,
only a single band of surface polariton modes exists, whilefor type-II modes, a richer structure with harmonics existsdue to the multivalued nature of the arctangent, just as inthe in-plane isotropic case. In Fig. 5, we see the isofrequency
contours for the dispersion in the case of in-plane anisotropy.We clearly observe that the mode structure is anisotropic,in that type-I modes behave differently than type-II modes.We comment briefly on the polarization of the modes. Thein-slab H-field polarization of the type-I and -II modes are,
respectively, given as
ˆε
q=/braceleftBiggˆqcosh( qz)+isinh( qz)ˆz√
2,type I
ˆqcos(qz)+isin(qz)ˆz√
2, type II .(14)
Applying the same formalism as before, the rate of emis-
sion into SMPs per unit angle by a z-oriented spin flip of
strength μBis given by
d/Gamma1(eg)
dθ=μ2
Bμ0ωeg
2π¯hq3(θ,ω eg)|σeg·ˆ/epsilon1q|2
Cq(θ,ω eg)|vg(θ,ω eg)|e−2q(θ,ω eg)z0.(15)
235453-7JAMISON SLOAN et al. PHYSICAL REVIEW B 100, 235453 (2019)
FIG. 5. Dispersion for anisotropic modes. Isofrequency contours
for MnF 2of thickness d=200 nm. The frequency labels are given
asω/ω 0,w h e r e ω0is the resonance frequency of the material. The
first type-I modes are shown in red, while the type-II modes with
n=1a r es h o w ni nb l u e .
The total rate is obtained by integrating over all angles:
/Gamma1(eg)=μ2
Bμ0ωeg
2π¯h/integraldisplay2π
0q3(θ,ω eg)|σeg·ˆ/epsilon1q|2
Cq(θ,ω eg)|vg(θ,ω eg)|e−2q(θ,ω eg)z0dθ.
(16)
In Fig. 6we see the lossless differential decay rate
d/Gamma1(eg)/dθplotted as a function of polar angle θfor a z-
oriented spin-flip transition at different emitter frequenciesω. We see that with increasing frequency, the angular spread
of type-I modes narrows, while the angular spread of type-IImodes increases. We can understand this behavior in termsof the availability and confinement of modes for differentpropagation angles θ. The most highly confined modes are
the type-I modes near the angular cutoff. As ωincreases the
FIG. 7. Magnetic dipole transition rate for in-plane anisotropic
MnF 2. Magnetic dipole transition rate for a z-oriented dipole transi-
tion a distance z0=5 nm from the surface into two different SMP
modes in a d=200-nm-thick anisotropic slab of MnF 2. The type-I
mode emits most strongly but over a narrower range of frequencies.
The cutoff frequency is the frequency at which the first type I mode
no longer satisfies the boundary conditions. The first-order type-II
mode is emitted more weakly but is supported over the entire rangeof frequencies for which μ(ω)<0.
confinement of type-I modes at low angles increases, while
the confinement of type-II modes decreases. This systemexhibits the interesting property that tuning the frequencyof the emitter over a narrow bandwidth dramatically shapesthe angular spectrum of polariton emission. An interestingconsequence is that for an emitter with a broadened spectralline (broader than 0 .001ω
0), the angular spectrum will be
a complicated mixture of the qualitatively different angularspectra in Fig. 6.
In Fig. 7, we see the total transition rate /Gamma1
(eg)for a dipole
emitter above MnF 2oriented with the anisotropy axis in the y
direction. While the transition rates of both modes are greatlyenhanced compared to the free-space transition rate of order10
−6s−1, the type-I mode benefits approximately two orders
of magnitude more than the first type-II mode. In particular,the Purcell factor for the type-I mode ranges from 10
10to 1012,
and is thus quite comparable to Purcell factors obtained forthe in-plane isotropic discussed previously. In this sense, wesee that extreme enhancement of magnetic dipole transition
FIG. 6. Angular distribution of SMP emission. Magnetic dipole transition rate per unit angle d/Gamma1(eg)/dθfor radiation into SMPs on a
200-nm-thick slab of MnF 2. The radial axis shows d/Gamma1(eg)/dθplotted on a log scale in units of s−1. The first type-I modes are shown in red
and the first type-II modes are shown in blue. Dashed lines indicate the angular cutoffs θxandθyfor each type of mode. Note that at low
frequencies, θxandθybecome very close. We additionally note that for ω/ω 0>1.0035, the type-I mode branch shown in red vanishes entirely,
leaving only the type-II modes.
235453-8CONTROLLING SPINS WITH SURFACE MAGNON … PHYSICAL REVIEW B 100, 235453 (2019)
rates is achievable in both crystal orientations. The dispersion
relation, however, is notably different in these cases. Asan additional degree of freedom, one can consider how thedispersion, and consequently the dipole emission rate, will beinfluenced by an applied magnetic field along the anisotropyaxis of a material such as MnF
2. In this case, an effective
Zeeman splitting causes the resonance frequency ω0to split
into two frequencies which move away from each other inlinear proportion to the applied field, as described, for exam-ple, in Ref. [ 82]. When the anisotropy axis lies in the plane
of the material, such an applied field results in nonreciprocalpropagation of waves due to the broken reflection symmetry.For these reasons, applied fields may be used to tune theAFMR frequencies or to shape the properties of the spinwaves emitted by magnetic dipole transitions. The net resultis a highly flexible platform for strong interaction betweenmagnetic transitions and matter.
IV . EXPERIMENTAL CONSIDERATIONS AND OUTLOOK
We have shown that highly confined SMPs, such as those
on antiferromagnetic materials, could speed up magnetic tran-sitions by more than ten orders of magnitude, bridging theinherent gap in decay rates which typically separates elec-tric and magnetic processes. We predict that these confinedmagnetic surface modes in systems with realizable parametersmay exhibit confinement factors in excess of 10
4.W ed e v e l -
oped the theory of magnon polaritons and their interactionswith emitters in a way that unifies this set of materials withother more well-known polaritonic materials, casting light onopportunities to use these materials to gain unprecedentedcontrol over spins in emitters.
To push the field of magnon polaritonics at THz fre-
quencies forward, it will be necessary to identify an idealexperimental platform for manipulating these modes and in-terfacing them with matter. For antiferromagnetic platforms,experiments will need to take place below the Néel tem-perature of the material to establish antiferromagnetic order.Importantly, we note that the only strict material requirementfor SMPs is that Re( μ)<0 over some frequency range,
presenting opportunities for other types of magnetic order,2D magnetic materials, or even metamaterials which exhibitnegative permeability. The other key consideration is whatclass of emitters may be well-suited to interact with thesepolaritonic modes. In terms of existing materials, a potentialemitter system which can interact with the antiferromagneticSMPs discussed here is ErFeO
3, which has several electric
and magnetic dipole transitions in the range between 0.25 and1.5 THz [ 83]. Recent work has also considered THz magnon
polaritons in TmFeO
3[84]. It could also prove interesting
to consider GHz-THz orbital angular momentum transitionsbetween high-energy levels in Rydberg atoms, Landau levels,or vibrational modes in molecules. In addition, one couldconsider THz transitions arising from impurity states in semi-conductors [ 85], which have the benefit of the tunability
over THz scale by the application of an external magneticfield.
The theoretical predictions made in this paper could be
verified by fluorescence spectroscopy measurements on a thinlayered sample as shown in Fig. 8. We represent the emitter
FIG. 8. Schematic for a potential fluorescence spectroscopy ex-
periment to observe enhancement of magnetic dipole (MD) tran-
sitions through surface magnon polaritons. We consider a lay-
ered sample which contains a thin negative permeability filmwhich supports SMPs and a material containing an appropriately
chosen emitter material. An external laser prepares the emitters
into an excited state via an IR /optical transition. This excited state
then decays via a THz transition into SMPs in the thin film and then
relaxes via a photon transition into the far field. The far-field signal
can be measured with a spectrometer to detect the Raman shift in thefluorescence frequency compared to the incident laser frequency.
as a three-level system, where the gap between the lower level
and the higher levels is in the optical /IR and is excited with
an external laser via an electric dipole transition. The excitedstate can then decay into SMPs in the material below via amagnetic dipole transition. Such a magnetic dipole transitionis usually very slow in free space, but as detailed in ourpaper, will occur orders of magnitude faster due to decayinto SMPs. The emitter state populations and transition ratescan then be monitored via spectroscopy of the optical photonemitted to free space. One would expect to see a decrease influorescence at the exciting laser frequency, in conjunctionwith the appearance of a new Raman peak, shifted fromthe exciting frequency by the THz SMP frequency. Similarschemes for monitoring Purcell enhancements in plasmonicshave been implemented in Ref. [ 86]. Time-resolved measure-
ments have also been made in Ref. [ 87] to directly measure
the decay in excited state populations which occurs throughPurcell-enhanced emission of polaritons. Alternatively, a sub-stantial rate increase in a THz MD transition due to SMPexcitation could influence rate dynamics in a way whichproduces optical /IR far-field decays at frequencies entirely
different from the exciting laser. Methods for analyzing suchmechanisms are detailed in Ref. [ 88].
Future work could also consider processes involving the
emission of multiple surface magnons using the frameworkpresented in Ref. [ 33] or mixed processes with the emission
of a magnon polariton in addition to one or more excitationsof another nearby material. In any case, SMPs provide an in-teresting degree of control over magnetic degrees of freedomin matter as well as a means to consider magnetic analogs atTHz frequencies of many famous effects in plasmonics andpolaritonics.
235453-9JAMISON SLOAN et al. PHYSICAL REVIEW B 100, 235453 (2019)
ACKNOWLEDGMENTS
The authors thank C. Roques-Carmes and N. Romeo for
help reviewing the paper. Research was supported as partof the Army Research Office through the Institute for Sol-dier Nanotechnologies under Contract No. W911NF-18-2-0048 (photon management for developing nuclear-TPV andfuel-TPV mm-scale systems), also supported as part of theS3TEC, an Energy Frontier Research Center funded by the USDepartment of Energy under Grant No. DE-SC0001299 (for
fundamental photon transport related to solar TPVs and solar-TEs). I.K. acknowledges support as an A. Fellow, supportedby the Azrieli Foundation, and was partially supported by theSeventh Framework Programme of the European ResearchCouncil (FP7-Marie Curie IOF) under Grant No. 328853-MC-BSiCS. N.R. recognizes the support of the DOE Computa-tional Science Graduate Fellowship (CSGF) No. DE-FG02-97ER25308.
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235453-11 |
PhysRevB.71.094410.pdf | Longitudinal complex magnetic susceptibility and relaxation times of superparamagnetic
particles with triaxial anisotropy
Yuri P. Kalmykov and Bachir Ouari
Laboratoire Mathématiques et Physique des Systèmes, Université de Perpignan, 52, Avenue Paul Alduy, 66860 Perpignan Cedex, France
sReceived 1 October 2004; revised manuscript received 18 November 2004; published 11 March 2005 d
The longitudinal relaxation time and spectrum of the complex magnetic susceptibility of single domain
ferromagnetic particles with triaxial sorthorhombic danisotropy are calculated by averaging the Gilbert-
Langevin equation for the magnetization of an individual particle and by reducing the problem to that ofsolving a system of linear differential-recurrence relations for the appropriate equilibrium correlation functions.The solution of this system is obtained in terms of matrix continued fractions. It is shown that in contrast to thelinear magnetic response of particles with uniaxial anisotropy, there is an inherent geometric dependence of thecomplex susceptibility and the relaxation time on the damping parameter arising from coupling of longitudinaland transverse relaxation modes. Simple analytic equations, which allow one to understand the qualitativebehavior of the system and to accurately predict the spectrum of the longitudinal complex susceptibility inwide ranges of the barrier height and dissipation parameters, are proposed.
DOI: 10.1103/PhysRevB.71.094410 PACS number ssd: 75.60.Jk, 75.50.Tt, 76.20. 1q, 05.40. 2a
I. INTRODUCTION
The single domain ferromagnetic particles, which are
characterized by an internal anisotropy potential, may haveseveral positions of local equilibrium of the magnetizationwith potential barriers separating them. If the particles aresmall s,100 Å d, thermal fluctuations may cause the magne-
tization vector Mto reorient itself over the barriers from one
equilibrium position to another. The instability of the mag-netization due to thermal agitation results in superpara-magnetism
1because each fine particle behaves like an enor-
mous paramagnetic atom having a magnetic moment,10
4–105Bohr magnetons. The superparamagnetism of
single-domain ferromagnetic nanoparticles is important inthe context of rock magnetism and technology because of theever decreasing size of the particles used in magnetic record-ing.
The pioneering theory of thermal fluctuations of the mag-
netization Mstdof a single domain ferromagnetic particle
due to Néel
2was further developed by Brown3,4using the
theory of the Brownian motion. Brown proceeded by takingas Langevin equation, Gilbert’s equation
5for the motion of
the magnetization augmented by a random field hstd, viz.:3,4
u˙std=hustd3fgHefstd−au˙std+ghstdgj, s1d
whereu=M/MSis the unit vector directed along M,MSis
the saturation magnetization, gis the gyromagnetic ratio, a
is the dimensionless damping sdissipation dparameter, Hef
=−]V/]M,Vis the free energy per unit volume scharacter-
izing the magnetic anisotropy and Zeeman energy density ofthe particle d, and a random field hstdwith white noise prop-
erties, accounting for the thermal fluctuations of the magne-
tization of an individual particle. Brown derived from theGilbert-Langevin Eq. s1d, the Fokker-Planck equation for the
distribution function WsM,tdof the orientations of the mag-
netization vector M:
4]
]tW=LFPW=1
2tNhbfa−1u·s„V3„Wd
+„·sW„Vdg+DWj, s2d
where L FPis the Fokker-Planck operator, „andDare the
gradient and Laplacian operators on the surface of unitsphere,uis the unit vector directed along M,
b=v/skTd,
vis the volume of the particle, Tis the temperature, kis
the Boltzmann constant, and tN=bMSs1+a2d/s2gadis the
free diffusion time of the magnetization. A detailed discus-
sion of the assumptions made in the derivation of the Fokker-Planck and Gilbert equations is given elsewhere se.g., Refs. 6
and 7 d.
For the purpose of mathematical simplification, the mag-
netization relaxation of superparamagnetic particles has usu-ally been considered for particles with uniaxial magnetic an-isotropy se.g., Refs. 3 and 7–13 d. For such particles, the free
energy density Vis given by
3
V=−K3cos2q, s3d
whereK3is the anisotropy constant and qis the polar angle.
For axially symmetric potential s3d, the longitudinal relax-
ation is governed by a single state variable q. The second
state variable, namely, the azimuthal angle wappears merely
as a steady precession of the vector M. The decoupling be-
tween the transverse and longitudinal modes results in anexact single-variable Fokker-Planck equation in the colati-tude
q,3,4that allows one readily to evaluate the magnetic
characteristics for uniaxial particles ssuch as the complex
magnetic susceptibility and relaxation times; see, e.g., Refs.4, 11, and 14 d.
Although use of the axially symmetric potential consider-
ably simplifies the analysis, the results obtained in this ap-proximation cannot, however, be applied to particles withnonaxially symmetric anisotropy, such as cubic or triaxialanisotropy. Nonaxially symmetrical anisotropy generates azi-muthally nonuniform energy distributions with saddle pointsthat leads to an effect, viz., strong intrinsic dependence ofPHYSICAL REVIEW B 71, 094410 s2005 d
1098-0121/2005/71 s9d/094410 s8d/$23.00 ©2005 The American Physical Society 094410-1magnetic characteristics on the value of the damping param-
eter aarising from coupling of the longitudinal and trans-
verse relaxation modes. For nonaxially symmetric potentials,Fokker-Planck Eq. s2dcan be solved by expanding Was a
series of spherical harmonics so yielding an infinite hierar-chy of differential-recurrence equations for the statisticalmoments saveraged spherical harmonics or appropriate cor-
relation functions d.
14,15The hierarchy of moment equations
can also be obtained by direct averaging Gilbert’s equationwithout recourse to the Fokker-Planck equation.
14The sys-
tem of moment equations can be solved by calculating theeigenvalues and eigenvectors of the system matrix se.g.,
Refs. 16 and 17 dor by a matrix continued fraction
method.
14,18The last approach has been used recently for the
study of the magnetization dynamics of particles with cubicanisotropy
19–21and uniaxial anisotropy in the presence of an
external dc magnetic field, which breaks the axialsymmetry.
22,23
In the present paper, we use the continued fraction method
to calculate the longitudinal complex magnetic susceptibilityand relaxation time of single domain particles with triaxialsi.e., orthorhombic danisotropy, where the free energy density
is given by
24
V=−K1sin2qcos2w−K2sin2qsin2w−K3cos2q+const,
s4d
sK1,K2,K3are the anisotropy constants d. In spite of the
practical importance of orthorhombic anisotropy, which mayyield an essential contribution to the free energy density ofmagnetic nanoparticles,
25,26the orthorhombic case is to some
extent incomplete. The only available appropriate formulafor the relaxation time of the magnetization of orthorhombiccrystals has been given by Smith and de Rozario
24in the
low-temperature limit and intermediate-to-high dampingfsIHDd
aø1g. A very similar problem of magnetization re-
versal in elongated particles swhere easy and hard-axis an-
isotropy terms present din the presence of a strong dc mag-
netic field has been treated by Braun27but also in the IHD
limit only. Some quantum and field effects for magnetic re-laxation of biaxial particles have been treated, for instance,in Refs. 28–30. Here we present the results of a study of thelongitudinal complex magnetic susceptibility
xisvdand re-
laxation time tiof single domain particles with triaxial an-
isotropy for wide ranges of the anisotropy energy and dissi-pation parameters. Numerical results obtained with the helpof matrix continued fractions are compared with asymptoticestimates based on Kramers’ escape rate theory.
4,14,27
II. LONGITUDINAL DYNAMIC SUSCEPTIBILITY AND
RELAXATION TIMES
According to linear response theory sRef. 14, Chap. 2 d,
the decay of the longitudinal component of the magnetiza-tion kM
ilstdof a single domain particle, when a small con-
stant external field H1,bsM·H1d!1, applied along the z
axisswhich is the easy axis of the particle dhas been switched
off at time t=0,iskMilstd=MSE
0pE
02p
cosqWsq,w,tdsinqdqdw=xiH1Cistd,
s5d
where
Cistd=kcosqs0dcosqstdl0
kcos2qs0dl0=o
kcke−lkts6d
is the normalized equilibrium autocorrelation function of the
longitudinal component of the magnetization, lkare the ei-
genvalues of the Fokker-Planck operator L FPfrom Eq. s2d,
okck=1,xi=bMS2kcos2ql0is the static longitudinal magnetic
susceptibility of the particle, and the brackets kl0designate
the equilibrium ensemble average defined as
kAl0=1
ZE
02pE
0p
Asq,wde−bVsq,wdsinqdqdw s7d
sZis the partition function d. The correlation function Cistd
completely determines the transient longitudinal relaxation
of the magnetization. Moreover, it allows one to evaluate theac response of the system to a small ac perturbing magneticfield, namely, the longitudinal complex susceptibility
xisvd
=xi8svd−ixi9svd, which is given by14
xisvd/xi=1−ivE
0‘
e−ivtCistddt. s8d
According to Eq. s8d, the behavior of xisvdin the frequency
domain is completely determined by the time behavior of
Cistd. In order to characterize quantitatively the time behav-
ior ofCistd, one may formally introduce two time constants.
These are the integral relaxation sor correlation dtime tide-
fined as the area under Cistd, viz.14
ti=E
0‘
Cistddt=o
kck/lk, s9d
and the effective relaxation time tiefgiven by
tief=−1/C˙is0d=So
kcklkD−1, s10d
fwhich yields precise information on the initial decay of
Cistdin the time domain g.
III. MATRIX CONTINUED FRACTION SOLUTION
We can calculate numerically the relaxation time tiand
the dynamic susceptibility xisvdby using the matrix contin-
ued fraction approach developed in Ref. 14. According to
this approach, the solution of the Gilbert-Langevin Eq. s1d
foranyanisotropy potential can be reduced to the solution of
an infinite hierarchy of differential-recurrence equations forthe statistical moments sequilibrium correlation functions d
c
l,mstd=kcosqs0dYl,mfqstd,wstdgl0fso that c1,0std/c1,0s0d
=Cistdggoverning the dynamics of the magnetization.14Here
Yl,msq,wdis the spherical harmonic defined as31Y. P. KALMYKOV AND B. OUARI PHYSICAL REVIEW B 71, 094410 s2005 d
094410-2Yl,msq,wd=s−1dm˛s2l+1dsl−md!
4psl+md!eimwPlmscosqd,
where the Plmsxdare the associated Legendre functions. For
the problem in question, one can obtain the differential-
recurrence equations for cl,mstdusing a general formula de-
rived in Ref. 32 ssee also Ref. 14, Chap. 7 d. Thus noting that
the free energy density Vfrom Eq. s4dis expressed in terms
ofYl,mas
V=˛2p
15sK2−K1dfY2,2sq,wd+Y2,−2sq,wdg
−4
3˛p
5SK3−K2+K1
2DY2,0sq,wd+const,
we have the 15th term differential-recurrence equation
tNd
dtcn,mstd=vn,mcn−2,mstd+wn,mcn−1,mstd+xn,mcn,mstd
+yn,mcn+1,mstd+zn,mcn+2,mstd+vn,m+cn−2,m+2std
+wn,m+cn−1,m+2std+xn,m+cn,m+2std
+yn,m+cn+1,m+2std+zn,m+cn+2,m+2std
+vn,m−cn−2,m−2std+wn,m−cn−1,m−2std
+xn,m−cn,m−2std+yn,m−cn+1,m−2+zn,m−cn+2,m−2std,
s11d
wherenø1,−nłmłnand the coefficients vn,m,vn,m±, etc.
are defined inAppendix A. Equation s11dcan be transformedinto the three-term vector recurrence equation
tNd
dtCnstd=Qn−Cn−1std+QnCnstd+Qn+Cn+1std,snø1d,
s12d
whereCnstdare the column vectors arranged in an appropri-
ate way from cn,mstd, viz.
Cnstd=1c2n,−2nstd
c2n,−2n+1std
A
c2n,2nstd
c2n−1,−2n+1std
c2n−1,−2n+2std
A
c2n−1,2n−1std2,snø1d,
andQn−,Qn,Qn+are the supermatrices given in Appendix A.
The exact solution of Eq. s12dfor the Laplace transform
C˜1ssd=e0‘C1stde−stdtcan be given in terms of matrix contin-
ued fractions14
C˜1ssd=tND1ssdHC1s0d+o
n=2‘Fp
k=2n
Qk−1+DkssdGCns0dJ,
s13d
where the infinite matrix continued fraction Dnssdis defined
as
Dnssd=I
tNsI−Qn−Qn+ I
tNsI−Qn+1−Qn+1+ I
tNsI−Qn+2−...Qn+2−Qn+1−, s14d
sthe fraction lines denote matrix inversion d, andIare the unit
matrices of appropriate dimensions. The initial conditionvectorsC
ns0din Eq. s13dmay be evaluated in terms of ma-
trix continued fractions Dns0d14ssee Appendix B d. Having
determined C˜1ssd, one may evaluate the relaxation time
ti=C˜s0d=c˜1,0s0d/c1,0s0ds 15d
as well as the spectrum of the correlation function C˜svd
=c˜1,0sivd/c1,0s0dand thus the complex susceptibility from
Eq.s8d. Moreover, by using matrix continued fractions, one
can also evaluate the smallest nonvanishing eigenvalue l1.23
The matrix continued fraction approach provides an effec-
tive method of computation of the susceptibility xisvdand
correlation time tisalgorithms for calculating matrix contin-ued fractions are discussed in Refs. 14 and 18 d. The advan-
tage of the matrix continued fraction approach is that it ap-plies to the case, where the magnetic anisotropy energy iscomparable to the thermal energy kT. Nevertheless, its appli-
cation is rather limited since the dependence of
xisvdandti
on the model parameters sdamping coefficient, anisotropy
constants dis not obvious by this method.
IV. ASYMPTOTIC FORMULAS
The qualitative behavior of xisvdandtican readily be
understood in the low temperature limit, where the magneti-
zation relaxation is determined by the smallest nonvanishingeigenvalue l
1.14Indeed, according to Eq. s9d, the correlation
time ticontains contributions from allthe eigenvalues lk.LONGITUDINAL COMPLEX MAGNETIC … PHYSICAL REVIEW B 71, 094410 s2005 d
094410-3The smallest nonvanishing eigenvalue l1is associated with
the slowest overbarrier relaxation mode and so with the long-time behavior of C
istd; the other eigenvalues lkcharacterize
high-frequency “intrawell” modes. In general, in order to
evaluate tinumerically, a knowledge of all the lkandckis
required. However, in the low temperature shigh barrier d
limit, l1!ulkuandc1<1@ckskÞ1dprovided the wells of
the potential remain equivalent sas for the triaxial potential d
so that
ti<1/l1. s16d
In other words, the inverse of the smallest nonvanishing ei-
genvalue closely approximates the correlation time tiin the
low temperature limit.
The smallest nonvanishing eigenvalue l1may be esti-
mated with the help of the Kramers escape rate theory33as
extended to the magnetic problem by Brown,3,4Smith and de
Rozario,24Klik and Gunther,6,34and Coffey et al.35We recall
that in order to estimate the characteristic time of reversal ofthe magnetic moment over the internal anisotropy potentialbarrier of a uniaxial particle, Brown
3adapted an ingenious
method originally proposed by Kramers33in connection with
thermally activated escape of Brownian particles out of apotential well. In the fsIHDd
aø1gformulas for the escape
rates of magnetic systems were derived by Smith and deRozario
24and Brown.4Moreover, in 1990, Klik and
Gunther6,34realized that the very low damping sVLD d,sa
!1dregime also applied to magnetic relaxation of single
domain ferromagnetic particles and derived the correspond-
ing VLD formula for the escape rate. The conditions of ap-plicability of these IHD and VLD solutions for superpara-magnets are defined by
aø1 and a,0.001, respectively.
For crossover values of damping, 0.001 ,a,1, Coffey et
al.35have derived a universal formula for bridging the VLD
and IHD escape rates as a function of the dissipation param-eter for single-domain ferromagnetic particles having a non-axially symmetric free-energy density sfor a review of appli-
cations of the Kramers method to magnetic problems seeRefs. 14, 15, 27, and 35 d.
Using the approach of Coffey et al.,
35the universal for-
mula for the relaxation times swhich is universal in the sense
that it is valid for all values of damping including IHD andVLD regions dis given by
36
l1−1,tIHDAs8as˛dd
A2s4as˛dd, s17d
where tIHDis the longest relaxation time of an orthorhombic
crystal derived by Smith and de Rozario24in the IHD limit
sin our notation d
tIHD
t0=pess1+a2d
as˛1+1/ df1−d+˛s1+dd2+4d/a2g,s18d
d=D/s,D=bsK2−K1d.0, and s=bsK3−K2d.0 are the di-
mensionless anisotropy and barrier height parameters, re-
spectively, t0=tNa/s1+a2d=bMS/s2gdis an a-independent
characteristic time, andAsaSd=expF1
pE
0‘
lnf1−exp h−aSsx2+1/4 djg
3sx2+1/4 d−1dxG.
Noting that AsaSd/a!Sasa!0,35Eq.s18dyields
tVLD
t0,pes
4as2˛ds1+dd, s19d
which is in agreement with estimations in the context of the
Klik and Gunther theory.34
In order to understand the qualitative behavior of the
complex susceptibility xisvd, one can use a simple analytical
equation derived in Refs. 37 and 38 ssee also Ref. 14, Chaps.
7–9d. According to Ref. 37, the correlation function Cistd
fwhich in general comprises an infinite number of decaying
exponentials, see Eq. s6dgmay be approximated in the IHD
limit by two exponentials only, viz.
Cistd<D1e−l1t+s1−D1de−t/tW, s20d
where D1andtWare expressed in terms of ti,tief, and l1
as14,37
D1=ti/tief−1
l1ti−2+1/ sl1tiefd,tW=l1ti−1
l1−/tief.
Thus the dynamic susceptibility xisvdgiven as an infinite
series of Lorenzians may be approximated by a sum of two
Lorentzians only
xisvd
xi<D1
1+iv/l1+1−D1
1+ivtW. s21d
The parameters D1andtWin Eq. s21dare determined in such
way37as to guarantee the correct asymptotic behavior of
xisvdin the extreme cases of very low and very high
frequencies14
xisvd
xi,51−ivE
0‘
Cistddt=1−ivti,v!‘
Cis0d
iv+fl=−i
vtief+fl,v!0.6
s22d
Equation s21dwas derived and tested for particles with
uniaxial sat all damping dand cubic anisotropy sat IHD values
of damping, aø1d.37Fora!1, where the interactions be-
tween the longitudinal and transverse modes cannot be ig-nored, Eq. s21dmay be used at
vtNł1.
In practical calculations, Eq. s21drequires a knowledge of
ti,tief, and l1.The smallest eigenvalue may readily be evalu-
ated from Eq. s17d. The effective relaxation time tiefis given
by an exact analytic equation37
tief=2tNkcos2ql0s1−kcos2ql0d−1, s23d
where kcos2ql0can be calculated from Eq. s7d. Unfortu-
nately, there is no simple equation for the correlation time tiY. P. KALMYKOV AND B. OUARI PHYSICAL REVIEW B 71, 094410 s2005 d
094410-4fEq.s16dis unreliable here as it yields tW=0g. However, one
can overcome this problem38by noting that the intrawell
relaxation time time tWcan be estimated in the low-
temperature limit, s@1, from the deterministic Gilbert equa-
tion as
tW,vwell−1=tN/s2s˛1+dd, s24d
where vwell=g/MS˛s]2V/]u12ds]2V/]u22dis the well angular
frequency. Noting Eqs. s21d,s22d, and s24d, one can evaluate
D1as
D1<1−tW/tief. s25d
Equations s21dands23d–s25dand allow one readily to calcu-
latexisvd.
V. RESULTS AND DISCUSSION
The greatest relaxation time predicted by the universal
Eq.s17dand the correlation time ticalculated numerically by
the matrix continued fraction method for triaxial anisotropyare shown in Figs. 1 and 2 sas a function of the damping
parameter
ad, and 3 sas a function of the barrier height pa-
rameter sd. Apparently, at high barriers, sø5, theasymptotic Eq. s17dprovides a good approximation of tifor
all values of asFigs. 1 and 2 dandDø1sFig. 3 d. We em-
phasize that Eq. s17dis not valid for d=D/s!0 correspond-
ing to uniaxial anisotropy. Here tNl1is given by Brown’s
formula3,4
tNl1,2s3/2e−s/˛p. s26d
The uniaxial asymptote Eq. s26dis shown in Fig. 3 for com-
parison. It follows that the triaxial anisotropy causes the vari-ous damping regimes sIHD andVLD dof relaxation to appear
unlike in an axially symmetric potential.
Results of the calculation from Eqs. s21dands23d–s25d,
and those obtained using matrix continued fractions are com-pared in Figs. 4–6. Here the imaginary part of the normal-
ized susceptibility
xi9svdsbMS2=1dis plotted for typical val-
ues of the model parameters s,D, and a.The results indicate
that a marked dependence of xisvdonaexists and that three
distinct dispersion bands appear in the spectrum. The char-
acteristic frequency and half-width of the low-frequencyband are completely determined by the smallest nonvanish-ing eigenvalue l
1. Thus the low frequency behavior of xisvd
is dominated by the barrier crossing mode. In addition, a far
weaker second relaxation peak appears at high frequencies.This high frequency relaxation band is due to the intrawellmodes. The characteristic frequency of this band is
vwell
,tN−1s2s˛1+dd. The third ferromagnetic resonance sFMR d
FIG. 1. ti/t0vsaforD=10 and various values of s. Solid
lines: exact matrix continued fraction solution; dashed lines: theVLD Eq. s19d; dotted lines: the IHD Eq. s18d; symbols: the univer-
sal Eq. s17d.
FIG. 2. ti/t0vsafors=10 and various values of D. Solid
lines: matrix continued fraction solution; dashed lines: the VLD Eq.s19d; dotted lines: the IHD Eq. s18d; symbols: the universal Eq.
s17d.
FIG. 3. ti/t0vssfora=0.1 and various values of D. Solid
lines: matrix continued fraction solution; symbols: the universal Eq.s17d; dotted line: Eq. s26d.
FIG. 4. −Im fxisvdgvsvtNfors=10, D=10, and various values
ofa. Solid lines 1–3: matrix continued fraction solution. Symbols:
Eqs. s21dands23d–s25d; dotted and dashed lines: Eq. s22d.LONGITUDINAL COMPLEX MAGNETIC … PHYSICAL REVIEW B 71, 094410 s2005 d
094410-5peak due to excitation of transverse modes having the peak
frequency close to the precession frequency vpr<gkHefl0of
the magnetization appears only at low damping sa!1dand
strongly manifests itself in the high frequency region. As a
decreases, the FMR peak shifts to higher frequencies since
vpr,a−1ssee Fig. 4 d.As one can see in Figs. 4–6 the agree-
ment between exact matrix continued fraction calculationsand the approximate Eq. s21dis very good in the low-
frequency region,
vtNł1, for all values of damping because
the low-frequency response is completely determined by theoverbarrier relaxation mode. The approximate Eq. s21d
yields a reasonable description of the high frequency relax-ation band at IHD values of damping s
aø1d, where one can
ignore the interactions between the longitudinal and trans-
verse modes. However, Eq. s21ddoes not allow one to de-
scribe the FMR peak which appears at very low damping,
a!1.
One may conclude that the longitudinal magnetic suscep-
tibility xisvdand relaxation time tiof systems of single do-
main particles with triaxial anisotropy may by evaluated ex-
actly in terms of matrix continued fractions sfor all values of
model parameters das well as in terms of simple analytic
equations sin the low-temperature limit d. In contrast touniaxial particles, where the damping only enters in the dif-
fusion time tN, for the particles with triaxial anisotropy, there
is an inherent geometric dependence of xisvdandti/tNon
the value of the damping parameter aarising from coupling
of the longitudinal and transverse relaxation modes. In thederivation of the above results, it was supposed that all par-ticles are identical. In order to take into account the polydis-persity of the particles of a real sample one must also aver-age the susceptibility over appropriate distribution functionsse.g., over that of particle volumes d. The approach developed
can be applied with small modifications to the evaluation ofthe transverse and nonlinear responses of orthorhombic crys-tals, to the estimation of the effect of an external dc magneticfield on the relaxation behavior of the magnetization of suchcrystals, etc.
ACKNOWLEDGMENTS
The support of this work by INTAS sProject No. 01-2341 d
is gratefully acknowledged. We thank Professor W. T. Cof-fey, Professor J. L. Déjardin, Dr. S. V. Titov, and Dr. P.-M.Déjardin for stimulating discussions and useful comments.
APPENDIX A: MATRICES Q n,Qn+,Qn−
The matrices Qn,Qn+,Qn−are defined as
Qn=SX2nW2n
Y2n−1X2n−1D,Qn+=SZ2nY2n
0Z2n−1D,
Qn−=SV2n0
W2n−1V2n−1D.
The dimensions of the matrices Qn,Qn+, andQn−are accord-
ingly equal to 8 n38n,8n38sn+1d, and 8n38sn−1d.I n
turn, the matrices Qn,Qn+,Qn−consist of submatrices. There
are five distinct types of three diagonal submatrices Vl,Wl,
XlYl, andZlwhich have the dimensions s2l+1d3s2l−3d,
s2l+1d3s2l−1d,s2l+1d3s2l+1d,s2l+1d3s2l+3d, and
s2l+1d3s2l+5d, respectively. The elements of these subma-
trices are given by
sVldn,m=dn−4,mvl,−l+m+3−+dn−2,mvl,−l+m+1+dn,mvl,−l+m−1+,
sWldn,m=dn−3,mwl,−l+m+2−+dn−1,mwl,−l+m+dn+1,mwl,−l+m−2+,
sXldn,m=dn−2,mxl,−l+m+1−+dn,mxl,−l+m−1+dn+2,mxl,−l+m−3+,
sYldn,m=dn−1,myl,−l+m−+dn+1,myl,−l+m−2+dn+3,myl,−l+m−4+,
sZldn,m=dn,mzl,−l+m−1−+dn+2,mzl,−l+m−3+dn+4,mzl,−l+m−5+,
where
FIG. 5. −Im fxisvdgvsvtNforD=10, a=0.01, and various
values of s. Solid lines 1–3: matrix continued fraction solution.
Symbols: Eqs. s21dand s23d–s25d; dotted and dashed lines: Eq.
s22d.
FIG. 6. −Im fxisvdgvsvtNfors=10, a=0.01, and various val-
ues of D. Solid lines 1–4: matrix continued fraction solution. Filled
circles: Eqs. s21dands23d–s25d; dotted and dashed lines: Eq. s22d.Y. P. KALMYKOV AND B. OUARI PHYSICAL REVIEW B 71, 094410 s2005 d
094410-6vn,m=Ss+D
2Dsn+1d
s2n−1d˛fsn−1d2−m2gsn2−m2d
s2n+1ds2n−3d,
vn,m−=vn,−m+=−D
4sn+1d
s2n−1d
3˛sn+m−3dsn+m−2dsn+m−1dsn+md
s2n+1ds2n−3d,
wn,m=−iSD
2+sDm
a˛n2−m2
4n2−1,
w−
n,m=−w+
n,−m
=−iD
4a˛sn+m−2dsn+mdfn2−sm−1d2g
4n2−1,
xn,m=−nsn+1d
2+SD
2+sDnsn+1d−3m2
s2n−1ds2n+3d,
xn,m−=xn,−m+=3D
4˛fn2−sm−1d2gfsn+1d2−sm−1d2g
s2n−1ds2n+3d,
yn,m=−iSD
2+sDm
a˛sn+1d2−m2
s2n+1ds2n+3d,
yn,m−=−yn,−m+
=iD
4a˛fsn+1d2−sm−1d2gs1+n−mds3+n−md
s2n+1ds2n+3d,
zn,m=−SD
2+sDn
s2n+3d˛fsn+1d2−m2gfsn+2d2−m2g
s2n+1ds2n+5d,
zn,m−=zn,−m+=D
4n
s2n+3d
3˛sn−m+4dsn−m+3dsn−m+2dsn−m+1d
s2n+1ds2n+5d.
APPENDIX B: CALCULATION OF C n0
The initial condition vectors Cns0din Eq. s13dmay be
evaluated by noting that the equilibrium averages kYl,ml0sat-isfy the following recurrence equation fcf. Eq. s11dg:
vn,mkYn−2,ml0+wn,mkYn−1,ml0+xn,mkYn,ml0+yn,mkYn+1,ml0
+zn,mkYn+2,ml0+vn,m+kYn−2,m+2l0+wn,m+kYn−1,m+2l0
+xn,m+kYn,m+2l0+yn,m+kYn+1,m+2l0+zn,m+kYn+2,m+2l0
+vn,m−kYn−2,m−2l0+wn,m−kYn−1,m−2l0+xn,m−kYn,m−2l0
+yn,m−kYn+1,m−2l0+zn,m−kYn+2,m−2l0=0.
Thus, one can transform the above equation into the tridiago-
nal vector recurrence equation
Qn−Rn−1+QnRn+Qn+Rn+1=0,snø1d, sB1d
whereR0=1/˛4pand
Rn=1kY2n,−2nl0
A
kY2n,2nl0
kY2n−1,−2n+1l0
A
kY2n−1,2n−1l02,nø1.
Equation sB1dhas a solution14
Rn=SnRn−1=SnSn−1flS2S1/˛4p,
where Sn=Dns0dQn−. Using the identity cn,ms0d
=dn+1,mkYn+1,ml0+dn,mkYn−1,ml0, where dn,m
=˛sn2−m2d/s4n2−1d,14the initial condition vectors Cns0d
are given by
Cns0d=F00
D2n−10GRn−1+F0D2nT
D2n0GRn
+F00
D2n+10GT
Rn+1.
Here the superscript Tdenotes matrix transposition. The di-
mension of the matrix Dliss2l+1d3s2l−1dand its elements
are given by sDldn,m=dn−1,mdl,−l+m.
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094410-8 |
PhysRevLett.92.086601.pdf | Theory of Current-Driven Domain Wall Motion: Spin Transfer versus Momentum Transfer
Gen Tatara
Graduate School of Science, Osaka University, T oyonaka, Osaka 560-0043, Japan
Hiroshi Kohno
Graduate School of Engineering Science, Osaka University, T oyonaka, Osaka 560-8531, Japan
(Received 22 August 2003; published 26 February 2004)
A self-contained theory of the domain wall dynamics in ferromagnets under finite electric current is
presented. The current has two effects: one is momentum transfer, which is proportional to the charge
current and wall resistivity ( eP0026w); the other is spin transfer, proportional to spin current. For thick walls,
as in metallic wires, the latter dominates and the threshold current for wall motion is determined by thehard-axis magnetic anisotropy, except for the case of very strong pinning. For thin walls, as in
nanocontacts and magnetic semiconductors, the momentum-transfer effect dominates, and the thresh-
old current is proportional to V
0=eP0026w,V0being the pinning potential.
DOI: 10.1103/PhysRevLett.92.086601 P ACS numbers: 72.25.Pn, 72.15.Gd
Manipulation of magnetization and magnetic domain
wall [1] by use of electric current is of special interestrecently [2–6], from the viewpoint of application to spin-
tronics, e.g., novel magnetic devices where the informa-
tion is written electrically, and also as a basic physics inthat it involves fascinating angular momentum dynamics.
Current-driven motion of a domain wall was studied in
a series of pioneering works by Berger [7–9]. In 1984, heargued that the electric current exerts a force on thedomain wall via the exchange coupling [8]. Later, in1992, he discussed that a spin-polarized current (spin
current) exerts a torque on the wall magnetization and
studied the wall motion due to a pulsed spin-polarizedcurrent [9]. These theoretical works are based on his deepphysical insight but seem to lack transparency as a self-contained theory. Also, their phenomenological charactermakes the limit of applicability unclear. In viewof recent precise experiments [4–6], a general theorystarting from a microscopic description is now needed.
In this Letter, we reformulate the problem of domain
wall dynamics in the presence of electric currentand explore some new features such as current-induceddepinning of the wall. W e start from a microscopicHamiltonian with an exchange interaction between con-duction electrons and spins of a domain wall [10]. With akey observation that the wall position Xand polarization
eP00I0
0(the angle between spins at the wall center and the
easy plane) are the proper collective coordinates [11] to
describe its dynamics, it follows straightforwardly thatthe electric current affects the wall motion in two differ-ent ways, in agreement with Berger’s observation. Thefirst is as a force on X, or momentum transfer, due to the
reflection of conduction electrons. This effect is propor-tional to the charge current and wall resistance and,hence, is negligible except for very thin walls. The other
is as a spin torque (a force on eP00I0
0), arising when an
electron passes through the wall. Nowadays it is alsocalled as spin transfer [2] between electrons and wallmagnetization. This effect is the dominant one for thick
walls where the spin of the electron follows the magne-tization adiabatically.
The motion of a domain wall under a steady current is
studied in two limiting cases. In the adiabatic case, weshow that even without a pinning force, there is a thresh-old spin current j
crsbelow which the wall does not move.
This threshold is proportional to K?, the hard-axis mag-
netic anisotropy. Underlying this is that the angular mo-mentum transferred from the electron can be carried byboth XandeP00I0
0, and the latter can completely absorb the
spin transfer if the spin current is small, js<jcrs.T h e
pinning potential V0affects jcrsonly if it is very strong,
V0*K?=eP00RR, where eP00RRis the damping parameter in the
Landau-Lifshits-Gilbert equation. In most real systemswith small eP00RR, the threshold would thus be determined by
K
?. Therefore, the critical current for the adiabatic wall
will be controllable by the sample shape and, in particu-lar, by the thickness of the film and does not suffer very
much from pinning arising from sample irregularities.
This would be a great advantage in application. Thewall velocity after depinning is found to be h_XXi//.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129
/.0133j
s=jcrs/.01342/.02551p
.
In the case of a thin wall, the wall is driven by the
momentum transfer, which is proportional to the charge
current jand wall resistivity eP0026w. The critical current
density in this case is given by jcr/V0=eP0026w.
W e consider a ferromagnet consisting of localized
spinsSand conduction electrons. The spins are assumed
to have an easy zaxis and a hard yaxis. In the continuum
approximation, the spin part is described by theLagrangian [12–14]
L
S/.0136Zd3x
a3/.0020
/.0022hS_eP00I0eP00I0/.0133coseP00R8/.02551/.0134/.0255Vpin/.0137eP00R8/.0138/.0255S2
2fJ/.0133/.0133reP00R8/.01342
/.0135sin2eP00R8/.0133reP00I0/.01342/.0134/.0135sin2eP00R8/.0133K/.0135K?sin2eP00I0/.0134g/.0021
;(1)PHYSICAL REVIEW LETTERSweek ending
27 FEBRUARY 2004 VOLUME 92, N UMBER 8
086601-1 0031-9007 =04=92(8) =086601(4)$22.50 2004 The American Physical Society 086601-1where ais the lattice constant, and we put S/.0133x/.0134/.0136
S/.0133sineP00R8coseP00I0;sineP00R8sineP00I0;coseP00R8/.0134,a n d Jrepresents the ex-
change coupling between localized spins. The longitu-
dinal ( K) and transverse ( K?) anisotropy constants
incorporate the effect of demagnetizing field. The con-stants J,K,a n d K
?are all positive. The term Vpinrepre-
sents pinning due to additional localized anisotropyenergy. The exchange interaction between localized spinsand conduction electrons is given by
H
int/.0136/.0255/.0001
SZ
d3xS/.0133x/.0134/.0133cy/.0027c/.0134x; (2)
where2/.0001andc(cy) are the energy splitting and annihi-
lation (creation) operator of conduction electrons, respec-tively, and /.0027is a Pauli-matrix vector. The electron part is
given by H
el/.0136P
keP00R5kcy
kckwith eP00R5k/.0136/.0022h2k2=2m.
In the absence of VpinandHint, the spin part has a static
domain wall of width eP002R/.0017/.0133J=K/.01341=2as a classical solution.
W e consider a wire with width smaller than eP002Rand treat
the spin configuration as uniform in the yzplane, perpen-
dicular to the wire direction x. The solution centered
atx/.0136Xis given by eP00R8/.0136eP00R80/.0133x/.0255X/.0134,eP00I0/.01360, where
coseP00R80/.0133x/.0134/.0136tanh/.0133x=eP002R/.0134,a n dsineP00R80/.0133x/.0134/.0136 /.0133cosh/.0133x=eP002R/.0134/.0134/.02551.T o
describe the dynamics of the domain wall, it is crucial to
observe that the weighted average of eP00I0, defined by
eP00I00/.0133t/.0134/.0017R/.0133dx=2eP002R/.0134eP00I0/.0133x; t/.0134sin2eP00R80/.0133x/.0255X/.0133t/.0134/.0134plays the role
of momentum conjugate to Xand, hence, must be treated
as dynamical [14]. Neglecting spin-wave excitations, weobtain the Lagrangian for X/.0133t/.0134andeP00I0
0/.0133t/.0134as
LS/.0136/.0255/.0022hNS
eP002RX_eP00I0eP00I00/.02551
2K?NS2sin2eP00I00/.0255Vpin/.0133X/.0134;(3)
where Vpin/.0133X/.0134is a pinning potential for X,a n d N/.0136
2AeP002R=a3is the number of spins in the wall. ( Ais the
cross-sectional area.) The equations of motion, derivedfrom the Lagrangian, L
S/.0255Hint, are given by
/.0022hNS
eP002R/.0018
_eP00I0eP00I00/.0135eP00RR_XX
eP002R/.0019
/.0136Fpin/.0135Fel; (4)
/.0022hNS
eP002R/.0133_XX/.0255eP00RReP002R_eP00I0eP00I00/.0134/.0136NS2K?
2sin2eP00I00/.0135Tel;z;(5)
where Fpin/.0136/.0255 /.0133 @Vpin=@X/.0134,
Fel/.0017/.0255/.0001
SZ
d3xrxS0/.0133x/.0255X/.0134/.0001n/.0133x/.0134; (6)
Tel/.0017/.0255/.0001
SZ
d3xS0/.0133x/.0255X/.0134/.0002n/.0133x/.0134: (7)
HereS0denotes S/.0133x/.0134with eP00R8/.0136eP00R80/.0133x/.0255X/.0134,eP00I0/.0136eP00I00,a n d
neP0022/.0017hcyeP002>eP0022ci(eP0022/.0136x; y; z ) is (twice) the spin density of
conduction electrons. Felrepresents a force acting on the
wall, or momentum transfer, due to the electron flow,
while Telis a spin torque, or spin transfer, which comes
from the directional mismatch between wall magnetiza-tionS0/.0133x/.0255X/.0134andn/.0133x/.0134. W e have added a damping term
(eP00RR), which represents a standard damping torque (Gilbert
damping), Tdamp/.0136/.0255eP00RR
SS/.0002_SS[1]. Note that the spin-
transfer effect acts as a source to the wall velocity via
vel/.0017/.0133eP002R=/.0022hNS/.0134Tel;z.
To estimate Felandvel, we calculate spin polarization
n/.0133x/.0134in the presence of a domain wall by use of a local
gauge transformation in spin space [15], c/.0133x/.0134/.0136U/.0133x/.0134a/.0133x/.0134,
where a/.0133x/.0134is the two-component electron operator in
the rotated frame, and U/.0133x/.0134/.0017m/.0133x/.0134/.0001/.0027is an SU(2)
matrix with m/.0133x/.0134/.0136fsin/.0137eP00R80/.0133x/.0255X/.0134=2/.0138coseP00I00;sin/.0137eP00R80/.0133x/.0255
X/.0134=2/.0138sineP00I00;cos/.0137eP00R80/.0133x/.0255X/.0134=2/.0138g. The expectation value
in the presence of electric current is written in termsof the Keldysh-Green function in the rotated frame.For instance, n
x/.0133x/.0134/.0136/.0137 /.01331/.0255coseP00R80/.0134cos2eP00I00/.02551/.0138~nnx/.0135/.01331/.0255
coseP00R80/.0134coseP00I00sineP00I00~nny/.0135sineP00R80coseP00I00~nnz, where ~nneP0022/.0133x/.0134/.0017
/.0255iTr/.0137G<xx/.0133t; t/.0134eP002>eP0022/.0138, G<
xeP002>;x0eP002>0/.0133t; t0/.0134/.0017ihay
x0;eP002>0/.0133t0/.0134ax;eP002>/.0133t/.0134i,
(eP002>; eP002>0/.0136/.0006 denotes spin) being the lesser component of
the Keldysh-Green function. After a straightforward cal-
culation, we obtain
Fel/.0136/.0255eP0025/.0022h2/.0001
L2X
kqeP002>u2qfkeP002>/.01332k/.0135q/.0134x
2meP002>eP00R4/.0133eP00R5k/.0135q;/.0255eP002>/.0255eP00R5keP002>/.0134;
(8)
and
vel/.0136/.0022heP002R2/.0001
NSL2X
kqeP002>u2qfkeP002>/.01332k/.0135q/.0134x
2mP
eP00R5k/.0135q;/.0255eP002>/.0255eP00R5keP002>;(9)
to the lowest order in the interaction (with wall) uq/.0017
/.0255Rdxe/.0255iqxrxeP00R80/.0133x/.0134/.0136eP0025=/.0137cosh/.0133eP0025eP002Rq=2/.0134/.0138. The distribu-
tion function fkeP002>specifies the current-carrying nonequi-
librium state, and Pmeans taking the principal value.
As is physically expected, Felis proportional to the
reflection probability of the electron and, hence, to the
wall resistivity, as well as to the charge current. In fact,
by adopting the linear-response form, fkeP002>’f0/.0133eP00R5keP002>/.0134/.0135
eE/.0001veP0028/.0133@f0=@eP00R5/.0134, as obtained from the Boltzmann equa-
tion ( f0: Fermi distribution function; E: electric field;
v/.0136/.0022hk=m;eP0028: transport relaxation time due to a single
wall), we can write as Fel/.0136enjRwin one dimension.
Here nandjare the electron density and current density,
respectively, and Rw/.0136/.0133h=e2/.0134/.0133eP00252=8/.0134/.0133eP00R62=1/.0255eP00R62/.0134/.0133u2
/.0135/.0135
u2/.0255/.0134is the wall resistance [16], with eP00R6/.0017/.0133kF/.0135/.0255
kF/.0255/.0134=/.0133kF/.0135/.0135kF/.0255/.0134and u/.0006/.0017ukF/.0135/.0006kF/.0255. More generally,
one can prove rigorously the relation [17,18]
Fel/.0136eNeeP0026wj/.0136enRwIA; (10)
using the Kubo formula, where eP0026w/.0017RwA=L is the resis-
tivity due to a wall [19], I/.0017jA,a n d Ne/.0017nLA is the
total electron number.
Equations (4) and (5) with (9) and (10) constitute a
main framework of the present Letter. W e next go on to
studying them in the two limiting cases: adiabatic wall
and abrupt wall.PHYSICAL REVIEW LETTERSweek ending
27 FEBRUARY 2004 VOLUME 92, N UMBER 8
086601-2 086601-2W e first study the adiabatic limit, which is of interest
for metallic nanowires, where eP002R/.0029k/.02551
F.I nt h i sl i m i t ,w e
take u2q!4eP0025
eP002ReP00R4/.0133q/.0134and by noting /.0133eP00R5k/.0135q;/.0255eP002>/.0255eP00R5keP002>/.0134q/.01360/.0136
2eP002>/.0001/.02220, we immediately see from Eq. (8) that Fel/.01360,
whereas
vel/.0136eP002R/.0022h
NS1
LX
keP002>eP002>kx
mfkeP002>/.01361
2Sa3
ejs (11)
remains finite. The spin transfer in this adiabatic limit is
thus proportional to spin current flowing in the bulk(away from the wall), j
s/.0017e/.0022h
mVP
kkx/.0133fk/.0135/.0255fk/.0255/.0134(V/.0017
LAbeing the system volume). In reality, the spin current
is controlled only by controlling charge current. In
the linear-response regime, it is proportional to the
charge current jasjs/.0136eP00R>j,eP00R>being a material constant.
This parameter can be written as eP00R>/.0136P
eP00RR/.0133eP002>eP00RR
/.0135/.0255
eP002>eP00RR/.0255/.0134=P
eP00RR/.0133eP002>eP00RR
/.0135/.0135eP002>eP00RR/.0255/.0134for a wire or bulk transport, and eP00R>/.0136P
eP00RR/.0133NeP00RR
/.0135/.0255NeP00RR/.0255/.0134=P
eP00RR/.0133NeP00RR
/.0135/.0135NeP00RR/.0255/.0134for a nanocontact and a
tunnel junction, where eP002>eP00RR
/.0006and NeP00RR
/.0006are band ( eP00RR)a n d
spin ( /.0006) resolved electrical conductivity and density of
states at the Fermi energy, respectively, of a homogeneous
ferromagnet. Experiments indicate that eP00R>is of the order
of unity in both bulk transport [20,21] and tunnel junc-tions ( /.00240:5[22]).
As seen from Eq. (15) below, the speed of the stream
motion of the wall is roughly given by v
el(except in the
vicinity of the threshold jcr). For a lattice constant a/.0024
1:5/.0023Aand current density j/.01361:2/.00021012/.0137A=m2/.0138[6], we
have a3j=e/.0024250/.0137m=s/.0138. This speed is expected for
strongly spin-polarized materials ( eP00R>/.00241) including tran-
sition metals, but is 2 orders of magnitude larger than theobserved value /.00243/.0137m=s/.0138[6]. This discrepancy may be
due to dissipation of angular momentum by spin-waveemission, which is now under investigation [17].
Let us study the wall motion in the absence of pinning,
F
pin/.01360, by solving the equations of motion, (4) and (5)
in the adiabatic case ( Fel/.01360). The solution with the
initial condition X/.0136eP00I00/.01360att/.01360is obtained as
eP0020cot/.0018eP00RR
eP002RX/.0019
/.0136/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129 /.0129
1/.0255eP00202p
coth/.0133eP00RIt/.0134/.01351 /.0133jeP0020j<1/.0134(12)
/.0136/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129 /.0129
eP00202/.02551p
cot/.0133eP00RIt/.0134/.01351 /.0133jeP0020j>1/.0134;(13)
where eP0020/.00172/.0022hvel=/.0133SK?eP002R/.0134 and eP00RI/.0136/.0137eP00RR=/.01331/.0135
eP00RR2/.0134/.0138/.0133SK?=2/.0022h/.0134/.0002/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129 /.0129
1/.0255eP00202p
.F o r jvelj<vcr/.0017SK?eP002R=2/.0022h(i.e., jeP0020j<1),
cot/.0133eP00RRX=eP002R /.0134remains finite as t!1 , and the wall is not
driven to a stream motion but just displaced by /.0001X/.0136
eP002R
2eP00RRsin/.02551eP0020. In this case, the transferred spin is absorbed by
eP00I00and ‘‘dissipated’’ through K?, as seen from Eq. (5),
and is not used for the translational motion of the wall(_XX); the wall is apparently ‘‘pinned’’ by the transverse
anisotropy. Thus, even without pinning force, the current
cannot drive the wall if the associated spin current is
smaller than the critical value [23]j
cr/.01331/.0134
s/.0136eS2
a3/.0022hK?eP002R: (14)
Above this threshold, js>jcr/.01331/.0134
s(jeP0020j>1), this process
with K?cannot support the transferred spin and the wall
begins a stream motion. The wall velocity after ‘‘depin-ning’’ is an oscillating function of time around the aver-
age value (Fig. 1)
h_XXi/.01361
1/.0135eP00RR21
2Sa3
e/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129 /.0129
j2s/.0255/.0133jcr/.01331/.0134
s/.01342q
; (15)
which is similar to the W alker’s solution for the field-
driven case [1,24]. (The bracket h/.0001 /.0001 /.0001i means time aver-
age.) The asymptotic behavior h_XXi/jsforjs/.0029jcr/.01331/.0134
sis
governed by the angular momentum conservation (withconstant dissipation rate).
W e now introduce a pinning potential V
pinand study
the ‘‘true’’ depinning of the wall by the spin-transfer
effect in the adiabatic limit. Since spin transfer acts as aforce on eP00I0
0, the depinning can be better formulated in
terms of eP00I00. W e consider a quadratic pinning potential
with a range eP0024,Vpin/.0136/.0133NV0=eP00242/.0134/.0133X2/.0255eP00242/.0134eP00R8/.0133eP0024/.0255jXj/.0134,
where eP00R8/.0133x/.0134is the Heaviside step function. Then the equa-
tion for eP00I00reads /.01331/.0135eP00RR2/.0134/.0127eP00I0eP00I00/.0136/.0255 eP00RR_eP00I0eP00I00/.0133eP002I/.0135eP0022cos2eP00I00/.0134/.0255
eP002I/.0137/.0133eP0022=2/.0134sin2eP00I00/.0135/.0133vel=eP002R/.0134/.0138, where eP0022/.0017SK?=/.0022hand eP002I/.0017
2V0eP002R2=eP00242/.0022hS. This equation describes the motion of a
classical particle in a tilted washboard potential ~VVwith
(modified) friction. For vel>vcr/.0133/.0136eP0022eP002R
2/.0134,l o c a lm i n i m a
disappear in ~VVandeP00I00is then ‘‘depinned.’’ Then the above
equation indicates that eP00I00starts to drift with average
velocity h_eP00I0eP00I00i/.0136/.0255 vel=/.0133eP00RReP002R/.0134(with oscillating components
neglected). The displacement of X/.0133t/.0134inside the pinning
potential is then obtained from Eqs. (4) and (5) as X’
/.0133vel=eP002IeP00RR/.0134/.0017Xmax. The depinning of the wall occurs when
Xmax>eP0024, which defines another critical current, jcr/.01332/.0134
s.
Thus, the critical spin current jcrswill be given by jcr/.01331/.0134
s
defined above if the pinning is weak ( V0&K?=eP00RR), while
it is given by
jcr/.01332/.0134
s/.00174e
a3/.0022heP00RRV0eP002R2=eP0024 (16)
if the pinning is strong ( V0*K?=eP00RR). Since eP00RRis usually
believed to be small [9], we expect that the criticalcurrent is mostly determined by K
?. This seems to be
consistent with the observations that the critical current is
FIG. 1. Time-averaged wall velocity as a function of spin
current, js, in the weak pinning case ( V0&K?=eP00RR).PHYSICAL REVIEW LETTERSweek ending
27 FEBRUARY 2004 VOLUME 92, N UMBER 8
086601-3 086601-3larger for a thinner film [6,9] and does not depend much
on pinning [25]. It would be interesting to carry outmeasurements on a wire with small K
?.
Let us go on to the opposite limit of an abrupt wall,
eP002R!0. As seen from Eq. (9), the spin-transfer effect
vanishes. The pinning-depinning transition is thus deter-mined by the competition between F
elandFpin,g i v i n g
the critical current density
jcr/.0136NV0
eP0024eNeeP0026w/.01362V0eP002R
ena3eP0024RwA: (17)
The average wall velocity after depinning is obtained as
h_XXi/.0136/.0133 eP002R2Nee=/.0022heP00RRNS /.0134eP0026wj. This velocity vanishes in the
limit eP002R!0due to the divergence of the wall mass Mw/.0136
/.0022h2N=K ?eP002R2.
For metallic nanocontacts, where eP0024/.0024eP002R/.0024aandna3/.0024
1, experiments indicate that the wall resistance can be of
the order of h=e2/.013626 k/.0010 [26]. Thus jcr/.0024/.01335/.00021010/.0002
Bc/.0137T/.0138/.0134 /.0137A=m2/.0138, where Bc/.0136V0eP002R=eP0022BeP0024Sis the depinning
field ( eP0022Bis Bohr magneton). Bc/.002410/.02553/.0137T/.0138(like in
Ref. [26]) corresponds to jcr/.00245/.0002107/.0137A=m2/.0138.
In conclusion, we have developed a theory of domain
wall dynamics including the effect of electric current.The current is shown to have two effects: spin transferand momentum transfer, as pointed out by Berger. For anadiabatic (thick) wall, where the spin-transfer effect dueto spin current is dominant, there is a threshold spincurrent j
crs/.0024/.0133eeP002R=a3/.0022h/.0134maxfK?;eP00RR V0eP002R
eP0024gbelow which the
wall cannot be driven. This threshold is finite even in the
absence of pinning potential. The wall motion is hence
not affected by the uncontrollable pinning arising fromsample roughness for weak pinning ( V
0&K?=eP00RR). In
turn, wall motion would be easily controlled by thesample shape through the demagnetization field andthus K
?. The wall velocity after depinning is obtained
ash_XXi//.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129/.0129 /.0129
/.0133js/.01342/.0255/.0133jcrs/.01342p
. In contrast, an abrupt (thin) wall
is driven by the momentum-transfer effect due to charge
current, i.e., by reflecting electrons. In this case, the
depinning current is given in terms of wall resistivityeP0026
wasjcr/V0=eP0026w.
The two limiting cases considered above are both
realistic. Most metallic wires fabricated by lithographyare in the adiabatic limit, as is obvious from the verysmall value of wall resistivity [27]. In contrast, a very thinwall is expected to be formed in metallic magnetic nano-
contacts with a large magnetoresistance [26]. A system of
recent interest is magnetic semiconductors [28], where theFermi wavelength is much longer than in metallic sys-tems. As suggested by the large magnetoresistance ob-served recently [29], magnetic semiconductors would besuitable for precise measurement in the thin wall limit.
The authors are grateful to T. Ono for motivating us
by showing the experimental data prior to publication.
W e also thank J. Shibata and A. Y amaguchi for valuablediscussions. G.T. is grateful to Monka-shou, Japan and
The Mitsubishi Foundation for financial support.
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[Eq. (14)] by use of phenomenological parameters under
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NeeP0026wis independent of L.
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27 FEBRUARY 2004 VOLUME 92, N UMBER 8
086601-4 086601-4 |
PhysRevLett.123.217201.pdf | Fast Domain Wall Motion Governed by Topology and Œrsted Fields
in Cylindrical Magnetic Nanowires
M. Schöbitz,1,2,3 ,*A. De Riz,1S. Martin,1,3S. Bochmann,2C. Thirion,3J. Vogel ,3M. Foerster ,4L. Aballe,4
T. O. Mente ş,5A. Locatelli ,5F. Genuzio ,5S. Le-Denmat,3L. Cagnon,3J. C. Toussaint,3D. Gusakova,1
J. Bachmann ,2,6and O. Fruchart1,†
1Univ. Grenoble Alpes, CNRS, CEA, Spintec, 38054 Grenoble, France
2Friedrich-Alexander-Universität Erlangen-Nürnberg, Inorganic Chemistry, 91058 Erlangen, Germany
3Univ. Grenoble Alpes, CNRS, Institut N´ eel, 38042 Grenoble, France
4Alba Synchrotron Light Facility, CELLS, 08290 Barcelona, Spain
5Elettra-Sincrotrone Trieste S.C.p.A., Basovizza, 34149 Trieste, Italy
6Institute of Chemistry, Saint Petersburg State University, St. Petersburg 198504, Russia
(Received 9 July 2019; published 21 November 2019)
While the usual approach to tailor the behavior of condensed matter and nanosized systems is the choice
of material or finite-size or interfacial effects, topology alone may be the key. In the context of the motion of
magnetic domain walls (DWs), known to suffer from dynamic instabilities with low mobilities, we report
unprecedented velocities >600m=s for DWs driven by spin-transfer torques in cylindrical nanowires made
of a standard ferromagnetic material. The reason is the robust stabilization of a DW type with a specific
topology by the Œrsted field associated with the current. This opens the route to the realization of predicted
new physics, such as the strong coupling of DWs with spin waves above >600m=s.
DOI: 10.1103/PhysRevLett.123.217201
It is well known that specific properties in condensed-
matter and nanosized systems can be obtained by eitheracting on the electronic structure by selecting an appropriatematerial composition and crystalline structure, or by makinguse of finite-size and interfacial effects, strain, gating with anelectric field, etc. [1]. These approaches have proven
suitable for tailoring charge transport, optical properties,
electric or magnetic polarization, etc., however, there arelimits regarding what can be achieved with materials, orrealized with device fabrication. An alternative strategyentails considering a specific topology in order to developthe desired properties of a system, yielding diverse appli-cations such as the design of wide-band-gap photoniccrystals [2]and the control of flow of macromolecules
[3], or novel theoretical methods such as for the description
of defects [4], or intringuing 3D vector-field textures such as
hopfions and torons [5]. As regards magnetism, unusual
properties resulting from topological features have beenpredicted, such as the existence of a domain wall (DW) in theground state of a Moebius ring [6], or the nonreciprocity of
spin waves induced by curvature and boundary conditions in
nanotubes [7].
Here, we show that topology plays a critical role in the
physics of DW motion in one-dimensional conduits,a prototypical case for magnetization dynamics. For the
sake of simplicity of fabrication and monitoring, DW
motion under magnetic field or spin-polarized current isusually conducted in planar systems, made of stacked thinfilms patterned laterally by lithography. In them, DWs aredynamically unstable above a given threshold of field or
current (Walker limit), undergoing transformations oftheir magnetization texture associated with a drastic dropin their mobility. Ways are being investigated to overcome
this limitation through the engineering of microscopic
properties. Two major routes are the use of theDzyaloshinskii-Moriya interaction in order to stabilizethe walls [8–10], or of natural or synthetic ferrimagnets
with vanishing magnetization to decrease the angularmomentum in order to increase spin-transfer torque effi-
ciency and boost the precessional frequency [11–13].
The three-dimensional nature of cylindrical nanowires
(NWs) gives rise to the existence of a DW with a specific
topology, which respects the rotational invariance and
circular boundary conditions. It is named the Bloch-pointwall (BPW) [14] and has been experimentally confirmed
only recently [15,16] . It was predicted that this wall can
circumvent the Walker limit, but field-driven motion
experiments disappointingly failed to confirm a topological
protection [17]. Here, we report experimental results on
current-induced DW motion in such NWs. We show thatalthough previously disregarded, the Œrsted field induced
by the current plays instead a crucial and valuable role in
stabilizing BPWs, contrary to the field-driven case. This
allows them to retain their specific topology and thus reachvelocities >600m=s in the absence of Walker breakdown,
which is quantitatively consistent with predictions.
DWs with two distinct topologies exist in NWs:
the transverse-vortex wall (TVW) and the BPWPHYSICAL REVIEW LETTERS 123, 217201 (2019)
0031-9007 =19=123(21) =217201(6) 217201-1 © 2019 American Physical Society[Figs. 1(a), 1(b) ]. The former has the same topology as all
DW types known in 2D flat strips [18]. The latter is found
only in NWs and exhibits azimuthal curling of magneticmoments around a Bloch point, a local vanishing ofmagnetization [19,20] . This unique topological feature of
NWs is at the origin of the predicted fast speed and stabilityduring magnetic-field or current-driven motion of BPWs.This is easily explained by considering the time derivativeof the magnetization vector _mat any point, described by the
Landau-Lifshitz-Gilbert equation [21].
_m¼−γ
0m×Hþαm×_m−ðu·∇Þmþβm×½ðu·∇Þm/C138;
ð1Þ
with γ0¼μ0jγj,γbeing the gyromagnetic ratio, α≪1the
Gilbert damping parameter, and βthe nonadiabaticity
parameter. H, the total effective field, is comprised of applied
fields and fields originating from magnetic anisotropy,exchange, and dipolar energy. The spin-polarized part ofthe charge current induces so-called spin-transfer torques,taken into account through u,w i t h juj¼Pðjμ
B=eM sÞ[21].
jandPare the charge current and its spin-polarization ratio,
respectively, μBis the Bohr magneton, ethe elementary
charge, and Msthe spontaneous magnetization.
In purely field driven cases, the applied field favors the
precession of maround the field direction. In flat strips, for
applied fields above a few mT this causes repeated DWtransformations from transverse to vortex walls for in-planemagnetization, and from N´ eel to Bloch walls for out-of-
plane magnetization. This so-called Walker breakdown [22]
is facilitated by the fact that all these DW configurationsshare the same topology [23–25]. The mobility is high below
the Walker threshold field (scaling with 1=α) and low above
(scaling with α). The same physics is expected in NWs for
the TVW, with the Walker field equal to zero due to therotational symmetry [7,14] . The phenomenology of current-
driven cases is similar: the adiabatic term favors motion, thenonadiabatic term favors azimuthal precession [third and
fourth terms in Eq. (1), respectively], and the DW velocity is
expected to be ≈ðβ=αÞubelow the Walker threshold and ≈u
above it [21,24] , again with a vanishing threshold for TVWs
in NWs [26].
In contrast to these cases, one expects that magnetization
cannot freely precess azimuthally in a BPW, since it wouldperiodically imply a head-on or tail-on configuration alongall three axes around the Bloch point, with an enormouscost in dipolar energy. Instead, the azimuthal rotationshould come to a halt and remain in a state essentiallysimilar to the static one [Fig. 1(b)]. This implies an absence
of Walker breakdown, both under field [7,14] and current
[27,28] , and steady-state motion of the wall. The steady
circulation is expected to be clockwise (CW) with respectto the direction of motion of the DW, while the counter-clockwise (CCW) circulation may undergo a dynamics-induced irreversible switching event to recover the CWcirculation and steady state. This picture is valid both for
BPWs in wires [14,27] , and vortex walls [7,28] in thick-
walled tubes. Thanks to this locked topology, the mobilityof the BPW is expected to remain high under both field andcurrent. Only when a speed around ≈1000 m=s is attained,
the speed is predicted to reach a plateau, with new physicsexpected to occur via interactions with spin waves, knownas the spin-Cherenkov effect [7]. However, so far there
exists no experimental report of the mobility of any of thesewalls under neither magnetic field nor current.
Our Letter is based on magnetically soft Co
30Ni70wires
with diameter 90 nm, electroplated in anodized aluminatemplates [29]. Following the dissolution of the latter,
isolated wires lying on a Si substrate are contacted withpads to allow for the injection of electric current. DWs weremonitored with both magnetic force microscopy (MFM)and x-ray magnetic circular dichroism photo-emissionelectron microscopy (XMCD-PEEM) in the shadow mode[Fig. 1(c)] to reveal the three-dimensional texture of
magnetization [16,30,31] . While in MFM, sharp ns-long
pulses could be sent, in XMCD-PEEM the shape of currentpulses was distorted to a minimum width of 10 –15 ns, due
to long cabling, UHV feedthroughs and the sample holder
contacts. Micromagnetic simulations were carried out withthe homemade finite-element code
FeeLLG ood[32], based on
the Landau-Lifshitz-Gilbert equation including spin-trans-fer torques. See Supplemental Material for additionaldetails on the methods [33].
Domain wall velocities were experimentally investigated
primarily with MFM imaging. Figure 2(b)shows an atomic
force microscopy (AFM) image of the left-hand side of thecontacted NW from Fig. 2(a). The corresponding MFM
image in Fig. 2(c)shows the initial magnetic configuration,
with two DWs located at 1.2 and 7.2μm from the edge of the
left contact. By applying a current pulse of duration 5.8 ns
and amplitude 2.2×10
12A=m2, the left hand DW moved
over a distance of ≈2μm [Fig. 2(d)], corresponding to an
average velocity of ≈350m=s. However, the right-hand
(a)
(c)(b)
Photons
16°Electrons
SubstrateXMCD-PEEM image
Wire Shadow area
FIG. 1. Schematic of (a) a TDW and (b) a BPW. (c) Schematic
of shadow XMCD-PEEM and the contrast resulting from a BPW.PHYSICAL REVIEW LETTERS 123, 217201 (2019)
217201-2DW remains pinned, highlighting a common and key issue
for inferring DW velocities from motion distances: pinning
on geometrical or microstructural defects hampers DWmotion [44]. Depinning not only requires a current density
above a critical value j
dp, but repinning can also occur at
another location with a deeper energy well, while the current
pulse is still being applied. This results in DW propagationwith an effective time span possibly much shorter than thenominal pulse duration. Consequently, the values for DW
velocity converted from motion distance and nominal pulse
length are a lower bound of an unknown higher velocity (seeSupplemental Material [33] for a quantitative discussion).
Furthermore, with such large current densities the effect of
Joule heating may not be neglected. However, measurementsof the NW resistance during the pulse showed that the
samples never exceeded the Curie temperature (see
Supplemental Material [33]) and that the results described
herein are not caused by thermal activation.
Figure 2(e) (open circles) shows the discussed lower
bound for DW velocity, as a function of applied current
density, inferred from a multitude of MFM images before
and after pulses with durations ranging from 5 to 15 ns.Consistent with the expected occurrence of re-pinning,lower velocities are inferred from longer pulse durations.Still, DW velocities up to >600m=s were observed for
applied current densities ≈2.4×10
12A=m2. This sets a
fivefold record for purely spin-transfer torque motion ofDWs in a standard ferromagnetic material, i.e., with large
magnetization, with reported values hardly exceeding
100m=s[45]. Similar or higher speeds have been mea-
sured recently, however, in low-magnetization ferrimag-
nets, thereby enhancing the efficiency of spin-transfer
torque [46]. Here, it is the topology of the wall that
enhances the DW speed, not a special material.Similarly, these DW velocity measurements are not dis-
torted by DW inertia, since simulations showed that this
effect will only come into play in subnanosecond pulseexperiments (see Supplemental Material [33]). The black
dotted lines in Fig. 2(e)act as a guide to the eye through the
speed predicted by the one-dimensional model below theWalker breakdown v¼ðβ=αÞu, for three different ratios
ofβ=α: 1, 2, and 3 (for Co
30Ni70Ms¼0.67MA=m2,
P≈0.7, resulting in u≈60.4m=s per 1012A=m2). This is
not intended as precise modeling, but rather to show that
the experiments are clearly not compatible with v¼u,
supporting the absence of Walker breakdown for the BPW.
Instead a value of β=α⪆3is inferred. Note, however, that
the adverse effects of DW pinning reappear in the form of a
threshold current density jdp≈1.2×1012A=m2required
to set any DW in motion. Even above this value, DW
motion was not fully reproducible, with some pinning sites
associated with a larger jdp.
To link unambiguously the measured velocity with theory,
the DW type must be identified. For this purpose, weemployed shadow XMCD-PEEM and imaged NWs beforeand after injecting a given current pulse [Figs. 3(a), 3(b) , and
full symbols in Fig. 2(e)]. Note that the values for speed are
lower than those measured with MFM, as expected for lesssharp pulse shapes with consequentially larger width.
Returning to the DW type, the first striking fact is the
following: from hundreds of DWs imaged after currentinjection, all were of the BPW type. These unambiguouslyappear as a symmetric bipolar contrast in the shadow [16],
corresponding to azimuthal rotation of magnetization as on
Figs. 3(a)–3(b). This sharply contrasts with all our previous
observations of NWs, imaged in the as-prepared state or
following a pulse of magnetic field, for which both TVWs
and BPWs had been found in sizable amounts [16,17] .T h e
second striking fact is that the sign of the BPW circulation is
deterministically linked to the sign of the latest current pulse,
provided that its magnitude is above a rather well-definedthreshold which, as shown in Fig. 3(c), lies around
1.4×10
12A=m2. In contrast with a one-time Walker event
discussed previously, this holds true irrespective of whether
or not the wall has moved under the stimulus of the currentpulse, and is independent of the pulse duration at the probedtimescales. We hypothesize that these two facts are related to
theŒrsted field associated with the longitudinal electric
current, its azimuthal direction favoring the BPW with a
(a)10 µm
j8 6 2 4 0µm
j
j (1012 A/m2)3.0 0 0.5 1.0 1.5 2.0 2.55 t < 10 ns
10 t < 15 ns
15 t < 25 ns
25 t < 35 ns
35 t nsvDW (m/s)
0100200300400500600700(b)
(c)
(d)
(e)
FIG. 2. (a) SEM, (b) AFM, and corresponding (c),(d) MFM
images of a 90 nm diameter Co 30Ni70NW with Ti =Au electrical
contacts. (c) Initial state, with two DWs. (d) Same wire, after a
current pulse with 2.2×1012A=m2magnitude and 5.8 ns
duration. (e) Domain wall velocity as a function of appliedcurrent density and duration (see inner caption), monitored withMFM (open circles) and XMCD PEEM (filled circles) from fourindividual NWs. The dashed lines are expectations from the one-dimensional model below the Walker breakdown, for v¼ðβ=αÞu
with β=α¼1,2 ,3 .PHYSICAL REVIEW LETTERS 123, 217201 (2019)
217201-3given circulation. Indeed, for a uniform current density j,
theŒrsted field is H¼jr=2at distance rfrom the NW
axis. For the present NWs with radius R¼45nm and j¼
1×1012A=m2this translates to 28 mT at the NW surface,
which is a significant value.
In order to support this claim, we conducted micro-
magnetic simulations including the Œrsted field, which had
not been considered in previous works. Starting from a DWat rest with R¼45nm, we used α¼1to avoid ringing
effects and obtain a quasistatic picture, suitable to describe
the PEEM experiments, for which the pulse rise time is
several nanoseconds. We evidenced that while the addedeffect of spin-transfer torques may alter the transformationmechanisms, it is of minor importance compared to theŒrsted field and considering or disregarding these torques
does not quantitatively impact switching. Accordingly,below we present only results disregarding these torques.With an applied Œrsted field, within the domains the
peripheral magnetization tends to curl around the axis,while it remains longitudinal on the NW axis. We firstconsider TVWs as the initial state and find that thesetransform into BPWs with CW circulations with respect tothe current direction, if the current density exceeds
0.4×10
12A=m2. The underlying process is illustratedon Fig. 4(a), displaying maps of the radial and azimuthal
magnetization components, mrandmφ, respectively, on
the unrolled surface of a NW as a function of time. These
highlight the locations of the inward and outward flux of
magnetization through the surface, signature of a TVW
[18]. While these local configurations are initially diamet-
rically opposite, they approach each other until they
eventually merge, expelling the transverse core of the wall
from the NW. This is associated with the nucleation of aBloch point at the NW surface, which later on drifts
towards the NW axis, ending up in a BPW. This process
is similar to the dynamical transformation of a TVW into aBPW upon motion under a longitudinal magnetic field [17],
and explains the absence of TVWs in our measurements,
for which the applied current densities were always larger
than 0.4×10
12A=m2. In order to understand the unique
circulation observed, we now consider a BPW as the initial
state. BPWs with a circulation matching that of the Œrsted
field do not change qualitatively, only their width increases
during the pulse. On the contrary, BPWs shrink if their
initial circulation is CCW, i.e., opposite to the Œrsted field.
Forj≤1.5×1012A=m2the CCW BPW reaches a narrow
yet stable state, and recovers its initial state after the pulse.
Beyond this value the circulation switches through a
transient radial orientation of magnetization [Fig. 4(b)].
After the switching of circulation, the BPW expands
and reaches a stable CW state. The value of the critical
current density required for circulation switching isin quantitative agreement with the experimental one
[Fig. 3(c),≈1.4×10
12A=m2], although the simulation
does not incorporate thermal activation and considersα¼1. This suggests that the switching process is robust
and intrinsic, in agreement with the narrow experimental
distribution of critical current. In our simulations the timerequired for switching is <10ns, though switching times
an order of magnitude faster are expected for realistic
values of α<0.1, which explains why no dependence on
the pulse width was observed in the experiments, where all
pulse widths were above 5 ns.
In experiments where the DW type was visible, DW
motion events were observed for applied current densities
larger than the critical current density required for the
circulation switching event. Thus, in these the circulation isalways CCW with respect to the propagation direction, i.e.,
CW with respect to the current direction, because the
charge of electrons is negative. Remarkably, this sense ofcirculation is opposite to the situation expected when
neglecting the Œrsted field, which would select the CW
circulation with respect to the propagation direction, asdictated by the chirality of the LLG equation [14,27,28] .
There must therefore be a competition for the circulation
sense and for the case of 90 nm diameter NWs, the Œrsted
field dominates. Despite this, we find in simulations that the
BPW motion still follows v≈ðβ=αÞuwhether or not the
Œrsted field is considered. Notice that the βparameter is
(a)
(b)
(c)1 µm
-2 2 1 0 -1
j (1012 A/m2)01 Pswitch(j)Wire 1
Wire 2
10 t < 20 ns
20 t < 30 ns
30 t < 40 ns
40 t ns
FIG. 3. (a), (b) Consecutive XMCD-PEEM images of a NW
with a tilted x-ray beam (orange arrow). The azimuthal circu-
lation of the four BPWs seen in the NW shadow is indicated by
the white arrows, consistent with the Œrsted field of the
previously applied current (blue and red arrows in the right-handschematic, respectively). From (a) to (b), a 15 ns and
1.4×10
12A=m2current pulse switches 75% of BPWs. DW
displacement from (a) to (b) cannot be discussed as directlyresulting from spin-transfer torque, and the density of current liesbelow the threshold for free motion (c) BPW switching proba-bility as a function of jfor two different wire samples (squares
and triangles). Pulse durations are categorized and color coded,see included labels. The gray region indicates the current densityrequired for switching in simulations.PHYSICAL REVIEW LETTERS 123, 217201 (2019)
217201-4expected to depend on the DW width, however, for
widths much smaller than the ones studied here [47].
The predictions of high mobility and possibly spin-Cherenkov effect are thus probably not put into question.
Surprisingly, the Œrsted field was previously only
considered in a single report for NWs of square crosssection [48]. No qualitative impact was found, likely
because a NW side of at most 48 nm was considered,
and a simple analytical model describing magnetization in
the domain and balancing Zeeman Œrsted energy with
exchange energy shows that the impact of the Œrsted field
scales very rapidly as R
3, a tendency confirmed by
simulations. The situation closest to the present case isthe report of flat strips made of spin-valve asymmetricstacks [49]. Such strips can be viewed as the unrolled
surface of a wire, the curling of the BPW translating into a
transverse wall, which tends to be stabilized during motiondue to the Œrsted field.
To conclude, we have shown experimentally and
by simulation that the Œrsted field generated by thespin-polarized current flowing through a cylindrical NW
has a crucial impact on DW dynamics, while it had been
disregarded so far. This Œrsted field robustly stabilizes
BPWs, in contrast with the field-driven case [17]. This
stabilization allows for the key features predicted for their
specific topology to apply [14,27,28] : we evidenced DW
velocities in excess of 600m=s confirming the absence of
Walker breakdown [7,50] and setting a fivefold record for
spin-transfer-torque-driven DW motion in large magneti-
zation ferromagnets [45]. This suggests that the experi-
mental realization of further novel physics is at hand, such
as the predicted spin-Cherenkov effect with strong coupling
of DWs with spin waves.
M. S. acknowledges a grant from the Laboratoire
d’excellence LANEF in Grenoble (ANR-10-LABX-51-01).
The project received financial support from the French
National Research Agency (Grant No. JCJC MATEMAC-3D). This work was partly supported by the French
RENATECH network, and by the Nanofab platform
(Institut N´ eel), whose team is greatly acknowledged for
technical support. We thank Jordi Prat for his technical
support at the ALBA Circe beam line and Olivier Boulle for
useful discussions.
*Corresponding author.
michael.schobitz@cea.fr
†Corresponding author.olivier.fruchart@cea.fr
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----(a)
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1
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---
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217201-6 |
PhysRevD.90.042005.pdf | Constraining the gravitational wave energy density of the
Universe using Earth ’s ring
Michael Coughlin1and Jan Harms2
1Department of Physics, Harvard University, Cambridge, Massachusetts 02138, USA
2INFN, Sezione di Firenze, Sesto Fiorentino 50019, Italy
(Received 5 June 2014; published 25 August 2014)
The search for gravitational waves is one of today ’s major scientific endeavors. A gravitational wave can
interact with matter by exciting vibrations of elastic bodies. Earth itself is a large elastic body whose
so-called normal-mode oscillations ring up when a gravitational wave passes. Therefore, precisemeasurement of vibration amplitudes can be used to search for the elusive gravitational-wave signals.
Earth ’s free oscillations that can be observed after high-magnitude earthquakes have been studied
extensively with gravimeters and low-frequency seismometers over many decades leading to invaluableinsight into Earth ’s structure. Making use of our detailed understanding of Earth ’s normal modes,
numerical models are employed for the first time to accurately calculate Earth ’s gravitational-wave
response, and thereby turn a network of sensors that so far has served to improve our understanding ofEarth, into an astrophysical observatory exploring our Universe. In this paper, we constrain the energy
density of gravitational waves to values in the range 0.035 –0.15 normalized by the critical energy density of
the Universe at frequencies between 0.3 and 5 mHz, using ten years of data from the gravimeter network ofthe Global Geodynamics Project that continuously monitors Earth ’s oscillations. This work is the first step
towards a systematic investigation of the sensitivity of gravimeter networks to gravitational waves. Further
advances in gravimeter technology could improve sensitivity of these networks and possibly lead togravitational-wave detection.
DOI: 10.1103/PhysRevD.90.042005 PACS numbers: 04.80.Nn, 91.30.Fn, 95.75.Wx
I. INTRODUCTION
So far, the strongest evidence for the existence of
gravitational waves (GWs) comes from the observationof the binary pulsar PSR B 1913 þ16[1]. The shrinking
of its orbit observed over three decades can be fully
explained by the emission of GWs and associated energy
loss according to the general theory of relativity. Dedicatedexperiments attempt to measure these waves as phasemodulation of laser beams (GEO600 [2], LIGO [3],
Virgo [4], KAGRA [5], eLISA [6],T O B A [7]), or through
their imprint on the polarization of the cosmic micro-wave background (BICEP2 [8],E B E X [9]). Furthermore,
searches for GWs can be performed in data of otherhigh-precision experiments including Doppler trackingof satellites [10], monitoring arrival times of pulsar
signals [11], or using the global positioning system [12].
Gravitational waves can also excite oscillations of elasticbodies. This principle is exploited for example in thedesign of spherical resonant GW detectors (MiniGRAIL
[13], Mario Schenberg [14]), and more famously in past
resonant-bar detectors (AURIGA [15], Allegro [16]). Also
oscillations of stars can be excited, and therefore observa-tion of these modes can be used to detect GWs [17].
All these experiments combined monitor a wide range ofGW frequencies starting from waves that have oscillatedonly a few times since the beginning of the Universe, upto a few 1000 Hz.Recently, the authors of this paper have presented
results from an observation of the free, flat surface
response of Earth to GWs [18]. As was explained there,
the method cannot be extended to frequencies below about
50 mHz since seismic motion starts to be globally
coherent at lower frequencies, and the GW response is
s t r o n g l ya f f e c t e db yE a r t h ’s spherical shape. The low-
frequency GW response is best described in terms of
Earth ’s normal-mode oscillations [19]. These oscillations
are continuously monitored by a global network of low-
frequency seismometers and gravimeters. Especially the
superconducting gravimeters of the Global Geodynamics
Project (GGP), which were used in this paper, provide
excellent sensitivity below 10 mHz with data records
reaching back more than 10 years [20].A sw i l lb es h o w n ,
the stationary noise background is almost the same for all
gravimeters and uncorrelated between different instru-
ments, which makes it possible to use a large fraction of
the data of the entire network to search for GW signals that
are significantly weaker than the stationary noise level by
means of a near-optimal correlation method. Whereas
previous GW searches using Earth ’s normal modes only
tried to explain excess energy in normal modes [21,22] ,
the work in this paper is the first to combine a near-
optimal analysis of gravimeter data with a detailed GWresponse model, which makes it possible to accurately
calibrate normal-mode amplitudes into GW strain.PHYSICAL REVIEW D 90,042005 (2014)
1550-7998 =2014 =90(4) =042005(8) 042005-1 © 2014 American Physical SocietyThe limits obtained in this study through normal-mode
observations are plotted in Fig. 1together with upper limits
set in other frequency bands. The upper limits in thef r e q u e n c yr a n g e0 . 3t o5m H za r ei m p r o v e db y2t o5orders of magnitude. A brief summary of normal-modeoscillations is given in Sec. II. In Sec. III, we outline the
theory of Earth ’s resonant (normal-mode) response to GWs.
A characterization of gravimeter data is presented in Sec. IV.
Finally, the GW search algorithm is discussed in Sec. V,
and new constraints are presented on the energy density of
GWs averaged over directions and wave polarizations.
II. EARTH ’S NORMAL-MODE OSCILLATIONS
Earth ’s free oscillations, called normal modes, can be
excited by gravitational waves. Earth ’s slowest normal-
mode oscillation occurs at about 0.3 mHz, and distinctmodes can still be identified up to a few millihertz. Athigher frequencies, the discrete vibrational spectrum trans-forms into a quasi-continuous spectrum of seismic vibra-tions that are increasingly dominated by local sources. Thedata used in this study were sampled once per minute, andlow-pass filtered suppressing signal response above about
5 mHz depending on the gravimeter. In addition, a few
gravimeters show resonant features above 5 mHz in theirresponse. Therefore, the upper frequency bound of the GWsearch was chosen to be 5 mHz to guarantee accuratecalibration of the data.
At frequencies below 5 mHz, the diameter of Earth is
much smaller than the length of GWs. In this so-called
long-wavelength regime, a GW can effectively be repre-sented by a quadrupole-force field that excites Earth ’s
normal modes. Normal modes are divided into toroidal
nTl
and spheroidal nSlmodes, where n; lare non-negative
integers that determine the radial and angular mode shape,respectively. The toroidal modes only produce tangential
displacement. Spheroidal modes show tangential and radial
displacement, and they also perturb Earth ’s gravity field.
Not all normal modes are equally responsive to a quadru-
pole force. In fact, only the quadrupole modes with l¼2
show significant GW response in the long-wavelengthregime [19]. The coupling mechanism of a GW to
oscillations of elastic bodies is governed by variations of
the shear modulus, including the shear-modulus change
across the free surface. Earth shows strong internal varia-
tions of the shear modulus. In the liquid outer core, theshear modulus vanishes, and therefore significant internal
contributions to Earth ’s GW response can be expected at
the inner-core boundary, as well as at the core-mantleboundary. Due to the complex internal structure of Earth,
normal modes also show a complex radial dependence of
their amplitudes. Modes with the high amplitudes at theinner-core boundary, core-mantle boundary, and free sur-
face couple strongly to GWs.
In order to calculate the response of Earth to GWs,
normal-mode amplitudes as a function of radius need to be
modeled numerically. For superconducting gravimeters,three contributions need to be modeled and added coher-
ently: seismic acceleration, perturbation of the gravity
potential, and lift against a static gravity gradient. For thiswork, normal-mode solutions were generated with the
numerical simulation tool Minos [25]. These solutions are
valid for a spherical, nonrotating, laterally homogeneousEarth, and here are based on the Earth model PREM [26]that
describes variations of mass density, seismic speeds, and
damping parameters from Earth ’s center to its surface. The
gravimeters are designed to measure radial ground motion
and gravity changes, which are caused only by spheroidal
modes. Therefore, one can focus on these modes for theGW search. Of all spheroidal quadrupole modes
nS2,o n l y1 4
have frequencies fnbelow 5 mHz as shown in Table I.
Even though Earth also responds to GWs at off-resonance
frequencies, the best sensitivity is obtained at normal-modefrequencies making use of the resonant signal amplification.
The GW response at normal-mode frequencies needs to take
into account the damping experienced by each mode inorder to obtain the correct signal amplification. The damping
is quantified by a mode ’s quality factor, which corresponds
to the ratio of a mode frequency to its natural spectrallinewidth. The quality factors of the 14 modes lie between
about Q¼100and 900. The mode frequencies and quality
factors used here were all taken from the numericalsimulation, but it should be emphasized that numerical
estimates of the mode frequencies are very accurate, at least
for the purpose of this paper, and also the quality factorsagree well with observation [27,28] .
The coupling strength α
nof a mode to a GW, see Eq. (3),
can be expressed by a dimensionless quantity. Its values for
the 14 quadrupole modes below 5 mHz are summarized in
Table I. They depend on the radial as well as tangential10−810−610−410−210010210−51001051010
LIGO
PulsarCassiniSeismic
Normal Modes
Frequency [Hz]ΩGW
FIG. 1 (color online). Current upper limits on GW energy
density. These limits were set by pulsar timing observations [23],
Doppler-tracking measurements of the Cassini spacecraft [10],
monitoring Earth ’s free-surface response with seismometers
(“Seismic ”)[18], and correlating data from the first-generation,
large-scale GW detectors LIGO [24]. The new limits resulting
from normal-mode measurements are shown as crosses.MICHAEL COUGHLIN AND JAN HARMS PHYSICAL REVIEW D 90,042005 (2014)
042005-2displacement of each mode, and also on shear-modulus
changes and mass density as functions of the distance toEarth ’s center. The coupling strength varies by more than
an order of magnitude without clear pattern. This is owed to
the complexity of mode solutions, which have greatly
varying sensitivity to shear-modulus changes at differentdepths. In addition to the coupling strengths, the second
important parameter characterizing each mode is its vertical
displacement u
nand gravity potential perturbation pnat the
surface, which govern the gravimeter signal. These ampli-
tudes are also summarized in Table I. The amplitudes of
displacement and gravity potential are normalized such thattheir relative contribution to the gravimeter signal can be
compared. It can be seen that the gravity perturbation is
significant only for the two modes
0S2and1S2.
A feature of normal modes that is not captured by the
Minos simulation is mode coupling due to Earth ’se l l i p -
ticity, rotation, and lateral heterogeneity. One effect is theso-called self-coupling, in which a quadrupole ( l¼2)
multiplet can split into up to five resolvable modes, which
are labeled by a third integer m¼−2;…;2[29]. Since
each mode can therefore potentially respond to a different
GW, mode splitting influences the overall GW response.
Another possibility is that two modes that happen to bevery close in frequency can couple and exchange energy.The latter situation is depicted in Fig. 2taking the mode
6S2as an example. The curves are the sum of response
functions of uncoupled oscillators normalized such thatthe peak value of each response corresponds to the mode ’s
Qvalue. Whereas the next highest quadrupole mode
7S2is
well isolated, mode6S2lies very close to other spheroidal
modes, which can couple and exchange energy. Although
the effect is minor on normal-mode frequencies and Q
values [30,31] , a consequence is that one cannot design
the GW search into too narrow frequency bands only
relying on simulation predictions. An extreme narrow-
band search needs to be based on a detailed characteri-zation of the quadrupole modes taking into account
observed mode (self-)coupling, which has not been done
in the work presented here. Concerning energy transferbetween coupled modes, the effect would generally lead toa decrease in GW response of a quadrupole mode
independent of the Qvalues of the coupled modes.
However, estimating the change in GW response that isconsistent with observed shifts of normal-mode frequen-
cies (based on a simple coupled harmonic oscillator
model), it can be concluded that the energy lost intoother modes through coupling is negligible. Therefore, the
main issue with mode coupling is that the GW search
needs to be designed with sufficient bandwidth aroundeach mode frequency so that it is guaranteed that the peak
response of the entire quadrupole multiplet lies within this
band. Further details about the impact of mode couplingon GW sensitivity are given in Sec. V.
III. THEORY OF EARTH ’S RESPONSE TO
GRAVITATIONAL WAVES
Two response mechanisms of an elastic body to GWs
have been described in detail in past publications. First,
Dyson calculated the amplitude of seismic waves producedby GWs incident on a free, flat surface [32]. He found that
the first time derivative of vertical surface displacement is
given by
_ξ
zð~r; tÞ≈−β2
α~e⊤z·hð~r; tÞ·~ez: ð1ÞTABLE I. Summary of mode parameters: mode frequencies fn, quality factors Qn, coupling strengths αn, radial surface displacement
un, perturbation of gravity surface potential pn(both normalized to the same, but arbitrary unit). The last row shows the upper limits on
the energy density ΩGWas plotted in Fig. 6.
nS2 0 1 2 3 4 5 6 7 8 9 10 11 12 13
fn[mHz] 0.309 0.679 0.938 1.11 1.72 2.09 2.41 2.52 3.21 3.23 4.03 4.06 4.33 4.84
Qn 510 310 95.9 365 433 317 92.9 340 316 445 203 126 229 878
αn −0.645−18.3−1.78−0.696−18.913.3 4.31 −34.5−3.97−6.54 15.8 −16.9 12.7 3.12
un 0.74 −0.14−0.06−0.19−0.18−0.11−0.019−0.086−0.050 0.13 0.073 0.057 −0.021 0.086
pn −0.43 0.028 5.7e-5 −4.9e-42.1e-4 4.7e-5 −3.1e-61.7e-5 5.3e-6 3.6e-6 2.0e-7 7.4e-7 1.0e-6 1.9e-8
ΩGW 0.039 0.039 0.040 0.048 0.041 0.045 0.042 0.044 0.035 0.036 0.15 0.12
2.3 2.35 2.4 2.45 2.50100200300400500600
0S150S161S11
2S104S55S4
6S27S2
Frequency [mHz]Mode amplitudes
FIG. 2 (color online). Simulated spectrum of spheroidal normalmodes around
6S2. The curves are sums of harmonic oscillator
response functions (solid: all spheroidal modes, dashed: allspheroidal quadrupole modes). The values of the red markerscorrespond to the modes ’Qvalues.CONSTRAINING THE GRAVITATIONAL WAVE ENERGY … PHYSICAL REVIEW D 90,042005 (2014)
042005-3Here, ~ezdenotes the normal vector of the surface, hthe
spatial part of the GW strain tensor, and α;βare the
compressional and shear-wave speed. It can already be seen
that the shear modulus μplays an important role in the
elastic-body response since
β2¼μ
ρ: ð2Þ
Accordingly, the GW response vanishes for vanishing shear
modulus. One has to keep in mind though that the equationsof elastic deformation used to derive this result are
neglecting contributions that can become important when
the shear modulus is sufficiently small. For example, theGW response model of a spherical body with vanishing
shear modulus has been used by Siegel and Roth [17] to
propose GW measurements by monitoring oscillations ofthe Sun.
The role of the shear modulus is also evident in the GW
response of an elastic spherical body. This case was studiedby Ben-Menahem [19]and is used here to calculate Earth ’s
resonant GW response. In the following, we will present the
most important results of his work with minor reformula-tions. In terms of the amplitudes of radial displacement
u
nlmðrÞ, and tangential displacement vnlmðrÞ, the couplingstrength of a GW to a normal quadrupole mode ( l¼2) can
be defined as
αn2m≡−R
β2cRRþ
0drr2μ0ðrÞðun2mðrÞþ3vn2mðrÞÞRR
0drr2ρðrÞðu2
n2mðrÞþ6v2
n2mðrÞÞ;ð3Þ
where Ris Earth ’s radius, βcis the shear-wave speed at
Earth ’s center, μ0ðrÞthe derivative of the shear modulus,
andρðrÞthe mass density. The upper integration limit Rþ
signifies that the shear-modulus change across the free
surface needs to be included. In the following, only the
radial order nwill be used to specify a quadrupole mode
whose properties are independent of the index mneglecting
mode coupling. The mode amplitudes unðrÞ;vnðrÞhave
arbitrary units, since units of the mode variables cancel inthe final result. They are considered unitless in this work. It
is only necessary that all mode variables including the
amplitude ϕ
nðrÞof the gravity potential are normalized
consistently.
The complete solution for the GW response also needs to
take into account the angular dependence of excited
oscillations. A simple first step is to consider the response
to a single, plus-polarized GW. For a spherical, laterallyhomogeneous Earth, the acceleration a
n2mmeasured by a
gravimeter in the long-wavelength regime can be written
an2mðfn;θ;ϕÞ¼ffiffiffiffiffiffiffiffi
24πp
15β2c
RQnαnhðfnÞδjmj;2Ym/C3
2ðθ;ϕÞ·/C18
unðRÞþ3ϕnðRÞ
Rð2πfnÞ2þ2g
Rð2πfnÞ2unðRÞ/C19
; ð4Þ
where hðfnÞis the GW strain amplitude, g¼9.81m=s2,
andδklthe Kronecker delta. For a quadrupole mode with
l¼2, the angular parameter can take the values
m¼−2;…;2. The expression in the brackets comprises
the three contributions to the gravimeter signal: radial
surface displacement, perturbation of the gravity potential,and lift against a static gravity gradient [33]. The second
contribution corresponds to the parameter p
nin Table I:
pn≡3ϕnðRÞ=ðRð2πfnÞ2Þ. The angle θdenotes the relative
angle between the direction of propagation of the GW and
the location of the gravimeter on Earth ’s surface in a
coordinate system with origin at the center of the Earth. Theangle ϕdescribes the rotation of this coordinate system
with respect to the polarization frame of the GW. Accord-
ingly, two modes, m¼/C6 2, of the quadrupole multiplet are
excited by each GW in this choice of coordinate system.
For the GW search carried out in this study, we also need
to know the correlation between two gravimeters due to an
isotropic GW background. Each GW that couples toquadrupole normal modes produces an angular surface
vibration pattern that can, in an arbitrarily oriented Earth-
centered coordinate system, be represented by a linearcombination of quadrupole spherical harmonics Y
m
2ðθ;ϕÞwith m¼−2;…;2[34]. The situation is illustrated in
Fig. 3. A plus-polarized GW propagates parallel to the
north –south axis. The red and blue colored shapes represent
Earth ’s induced quadrupole oscillation at its two maxima
separated by half an oscillation period. Since the signal
amplitude measured by gravimeters depends on theirlocation, coherence between two gravimeters also dependson location. For symmetry reasons, it is clear that for an
isotropic GW field, coherence integrated over all polar-
izations and propagation directions only depends on therelative position of the two gravimeters. This correlationfunction is known as overlap-reduction function, and
normalized such that it is unity for collocated gravimeters
[35]. In order to calculate it, the response as given by
Eq.(4)needs to be calculated in a rotated coordinate system
for one of the gravimeters. Since the GW correlation also
depends on the nature of the GW field, a specific model
needs to be chosen. Results in this paper are calculated foran isotropic, stationary field of GWs. Integration over allGW propagation directions and polarizations yields the
overlap-reduction function,
γ
12ðσÞ¼ffiffiffiffiffiffiffiffiffiffi
4π=5p
Y0
2ðσ;0Þ; ð5ÞMICHAEL COUGHLIN AND JAN HARMS PHYSICAL REVIEW D 90,042005 (2014)
042005-4where σis the angle subtended by the great circle that
connects the two gravimeters. All else being equal, the
gravimeter pairs that contribute most significantly to the
estimate of a GW energy density are either close to eachother or antipodal. Note that the overlap-reduction function
can be approximated as frequency independent since the
Earth is orders of magnitude smaller than the length of a
GW at mHz frequencies.
IV. GRAVIMETER DATA
In addition to disturbances from large earthquakes
including the subsequent ringdown of the normal modes
[36], or local short-duration disturbances, gravimeter data
also contain a stationary noise background consisting
of instrumental noise, hydrological, and atmospheric
disturbances [33]. The stationary noise level is very
similar in almost all instruments, with a median of a
fewðnm=s
2Þ=Hz1=2at 1 mHz. The medians of gravimeter
spectra recorded during the year 2012 are plotted in Fig. 4.
Four gravimeters show elevated medians, but in all these
cases it is not the stationary background being higher, but
instead the four instruments are frequently perturbed by
strong local events, which therefore contribute signifi-
cantly to the medians. A detailed study of gravimeter
noise for most of these sites can be found in [37].
A local disturbance can produce strong broadband noise
in gravimeters. Consequently, noise amplitudes at different
frequencies show partial correlation. This property was
exploited to subtract some of the background noise that
adds to the normal-mode signals, and thereby improvesensitivity to GWs. In this way, it was possible to suppress
the background noise at normal modes up to a factor 3(varying in time, and with different success for each normal
mode). Using off-resonance amplitudes for noise subtrac-
tion, it is possible to ensure that an insignificant amount ofGW signal is subtracted with the noise. Additional noise
reduction can be achieved in some gravimeters by direct
subtraction of gravity noise of atmospheric origin [38].F o r
this purpose, each superconducting gravimeter is equippedwith a pressure sensor. The idea is that the pressure data
contain direct information about corresponding atmos-
pheric density and therefore gravity perturbations. It isfound that the correlation between pressure and gravimeter
data is significant below about 1 mHz and weakly fre-
quency dependent. This can be exploited to coherentlysubtract gravity noise with a conversion factor around−0.35μgal=hPa, which needs to be optimized for each
gravimeter. The quality of pressure data is poor at some
gravimeter sites so that good noise reduction cannot begenerally achieved.
Another important property of gravimeter data is that
coherence between any two gravimeters of the GGPnetwork at frequencies between 0.3 and 5 mHz producedby environmental disturbances is insignificant provided
that times of high-magnitude earthquakes are excluded.
Even for superconducting gravimeters that contain twolevitated spheres, strong coherence is only observedbelow about 2 mHz after removing the highest 10 percentof loudest spectra as shown in Fig. 5. The lack of
environmental coherence is an important feature of thegravimeter network, which makes it a very efficient tool
to search for GWs, since significant correlations of
environmental origin would greatly limit the networksensitivity.
FIG. 3 (color online). Earth quadrupole oscillation. The red and
blue shapes correspond to the maxima of a quadrupole oscillationseparated by half an oscillation period. The green balls marklocations of some of the gravimeters of the GGP network. Herethe oscillation is induced by a GW propagating along the north-south axis.10−110010−1100101102103104
Frequency [mHz]Gravity [(nm/s2)/√ Hz]Ny−Alesund, Norway
Concepcion, Chile
Wuhan, China
Hsinchu, Taiwan
FIG. 4 (color online). Medians of gravimeter spectra measured
in 2012. All gravimeters used in this study show a comparablelevel of stationary background noise represented by their spectralmedians, except for the four gravimeters highlighted in the plot.CONSTRAINING THE GRAVITATIONAL WAVE ENERGY … PHYSICAL REVIEW D 90,042005 (2014)
042005-5V. SEARCH FOR A STATIONARY
GRAVITATIONAL-WAVE BACKGROUND
In this section, we outline the GW search method based
on correlation measurements between gravimeter pairs.
Depending on the relative position of two gravimeters onEarth ’s surface, correlation of gravimeter signals arising
from GWs is described by the overlap-reduction function in
Eq.(5). Once the expected correlation of GW signals
between different gravimeters is calculated, the measuredcorrelations are used to obtain an estimate of the energy
density of GWs following the method described in [39].
The upper limit on the GW energy density presented in thispaper was obtained as a near-optimal combination of
measured correlations using 10 years of data, forming
pairs with gravimeters of the GGP network. The totalamount of data is divided into stretches short enough so that
the spectral resolution is wider than the frequency spread of
a quadrupole multiplet as discussed in Sec. II. The length of
data stretches obtained in this way is different for each
normal mode. Each data stretch leads to a point estimate of
the GW energy density according to
ˆΩ
GWðfnÞ¼4π2
3H2
0ˆS12ðfnÞf3n
γ12: ð6Þ
Here, ˆS12ðfnÞis the measured cross-spectral density
between two gravimeters in units of GW strain spectraldensity. As pointed out before, the overlap-reduction
function γ
12can be approximated as frequency independent
for normal-mode observations.
Based on the conservative assumption that the l¼2
quadrupole mode splits into five distinct isolated modes(m¼−2;…;2) that all respond incoherently to GWs, the
GW response of a quadrupole mode is obtained by adding
contributions from different values of mincoherently.
Furthermore, two pairs of the 14 quadrupole modes are
too close in frequency to be resolvable with the chosen
frequency resolution ( n¼8, 9 and n¼10, 11, see Table I).
This means that in addition to the incoherent sum over amultiplet, contributions from the two quadrupole modes in
each of these pairs need to be summed incoherently leading
to a combined point estimate. Accurate knowledge of modesplitting would lead to sensitivity improvements. One
advantage would be that the bandwidth of the search could
be narrowed, which means that the measurement noisewould be decreased. The improvement factor depends on
theQvalues and difference in frequencies between modes
of a multiplet, and is likely modest. In addition, thesensitivity of our search was explicitly punished by a
factorffiffiffi
5p
, since we assumed conservatively that GW
signals in five submodes of a multiplet add incoherently.Therefore, if five modes were observed separately, thenthey could all be combined to set an upper limit for the
entire frequency range of the multiplet, which would then
be at least a factorffiffiffi
5p
lower than achieved in this paper.
The exact improvement depends on the gravimeter noise at
each submode (e.g. it is conceivable, but certainly highly
unlikely, that the gravimeter noise at one of the submodes issubstantially lower, therefore leading to a much better
upper limit).
The calculation of upper limits is based on a combination
of estimates from many data segments. It must take into
account the point estimates of energy density from eachdata segment as well as the corresponding measurement
error. A result is consistent with a nondetection, if after
combining point estimates and errors of all segments, thecombined estimate of the energy density is smaller thanthe combined measurement error (or similar thresholds can
be applied depending on confidence levels). Data quality
changes in nonstationary gravimeter data, and thereforesegments, are vetoed based on some criteria. For this study,
data segments that showed high values of the ratio “point
estimate over error ”were vetoed. High correlation can be
associated with increased gravimeter noise following large
earthquakes, but typically gravimeter correlations show a
higher number of transient features than gravimeter noise.For this reason, the veto is mostly on high-correlation
segments, which favors low point estimates while having a
smaller effect on average gravimeter noise. This causes theupper limits to be dominated by the errors. The final results
are presented as constraints on the energy density in GWs
separately for each mode. Figure 6shows the estimates of
the GW energy density with error bars. All estimates areconsistent with a nondetection, and the resulting energy
constraints are mostly determined by the error bars for
reasons explained above. The values are listed in Table I.
Energy densities can be translated into strain spectral
Frequency [mHz]Percentile
0.1 0.2 0.4 0.81 2 4102030405060708090100
Coherence
00.20.40.60.81
FIG. 5 (color online). Coherence of signals from two levitated
spheres in the same gravimeter at Wettzell, Germany. The result isshown as a function of percentile of gravimeter noise excludedfrom the coherence measurement. A percentile of 90 means that10% of the loudest spectra were excluded from the coherencemeasurement. Only the high- Qradial normal mode
0S0at about
0.81 mHz contributes significantly to coherence for all times.MICHAEL COUGHLIN AND JAN HARMS PHYSICAL REVIEW D 90,042005 (2014)
042005-6densities, which lie between hGW≤2.2×10−14Hz−1=2for
the mode0S2andhGW≤6.2×10−16Hz−1=2for0S13.E v e n
though these results demonstrate an improvement in
sensitivity by a few orders of magnitude over previous
searches in this frequency band (see Fig. 1), the new upper
limits are still not stringent enough to constrain cosmo-
logical models of GW backgrounds. A conservative esti-
mate of the energy density of GWs from inflation predicts avalue of order Ω
GW∼10−15, and a GW background from
cosmic strings is predicted at ΩGW∼10−7, both at normal-
mode frequencies [24]. Also a GW background from a
cosmological distribution of unresolved compact binary
stars such as white dwarfs and neutron stars is predicted at
lower values, ΩGW∼10−12, at normal-mode frequencies
[40]. Therefore, with achieved upper limits between
ΩGW¼0.035–0.15, the stationary gravimeter noise as
plotted in Fig. 4has to be lowered by 2 to 3 orders of
magnitude to be able to place first constraints on cosmo-
logical models.
VI. CONCLUSION
In this paper we showed that our understanding of
Earth ’s interior can be used to accurately calculate
Earth ’s resonant GW response. In this way, it was possible
to calibrate gravimeter data into units of GW strain, anddirectly obtain new upper limits on the GW energy densityin the range 0.035 –0.15 at frequencies between 0.3 and
5 mHz. This was achieved by correlating data of gravimeterpairs recorded over the past ten years.
Alternatively, one could make use of the same response
mechanism to search for individual astrophysical signalssuch as galactic white-dwarf binaries. Millions of binaries
are predicted to radiate quasi-monochromatic waves in this
frequency band [41]including already discovered systems
(see for example Roelofs et al. [42]). Again, about 3 orders
of magnitude sensitivity improvement are required to make
a detection likely. The integrated gravitational-wave signalshould be distinguishable from terrestrial sources since it is
modulated due to Earth ’s rotation. The additional challenge
here is that a continuous integration of the signal, as wouldbe favorable for this search, results in an extremely narrow
frequency resolution, which requires a more detailed
investigation of mode-coupling effects. The diversity innature of Earth ’s oscillations also makes it possible to test
alternative theories of gravity. For example, a scalar
component of the GW field could be searched in monopolemodes
nS0as has already been attempted by Weiss and
Block [21].
Further improvement in GW sensitivity may be achieved
with a new generation of gravimeters. Especially atom-
interferometric gravimeters are currently under active
development [43]. The open question is if there will be
some form of environmental noise limiting the sensitivity
of gravimeters irrespective of their intrinsic acceleration
sensitivity, and whether methods can be developed tomitigate this noise if necessary. Nonetheless, we havedemonstrated that gravimeter technology is a viable option
to detect GWs, and that ground-based GW detection seems
to be a possibility at frequencies, which are generallyconsidered accessible only for space-borne detectors.
ACKNOWLEDGMENTS
We want to thank David Crossley for helpful discussions
on gravimeter data and Jean-Paul Montagner, Guy Masters,
and Eric Clévédé for their help on normal-mode simula-
tions. Thanks also for constructive feedback from RanaAdhikari, Ray Weiss, and Stan Whitcomb on an earlier
version of the manuscript. M. C. was supported by the
National Science Foundation Graduate Research FellowshipProgram, under NSF Grant No. DGE 1144152. Uncorrected
gravimeter data (GGP-SG-MIN) used for this project
were downloaded from http://isdc.gfz ‑potsdam.de/index
.php?module=pagesetter&func=viewpub&tid=1&pid=54 .1 2 3 4−0.2−0.100.10.2
Frequenc y [mHz]ΩGW
FIG. 6. Point estimates of GW energy density and errors. Of the
14 original modes, only 12 are plotted here since two pairs,n¼8, 9, and n¼10, 11, have been merged to one value each
since the chosen frequency resolution cannot resolve them.CONSTRAINING THE GRAVITATIONAL WAVE ENERGY … PHYSICAL REVIEW D 90,042005 (2014)
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PhysRevLett.123.047204.pdf | Gigahertz Frequency Antiferromagnetic Resonance and Strong Magnon-Magnon
Coupling in the Layered Crystal CrCl 3
David MacNeill,1,*Justin T. Hou,2,*Dahlia R. Klein,1Pengxiang Zhang,2Pablo Jarillo-Herrero,1and Luqiao Liu2
1Department of Physics, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139, USA
2Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology,
Cambridge, Massachusetts 02139, USA
(Received 5 February 2019; published 24 July 2019)
We report broadband microwave absorption spectroscopy of the layered antiferromagnet CrCl 3.W e
observe a rich structure of resonances arising from quasi-two-dimensional antiferromagnetic dynamics.Because of the weak interlayer magnetic coupling in this material, we are able to observe both optical and
acoustic branches of antiferromagnetic resonance in the GHz frequency range and a symmetry-protected
crossing between them. By breaking rotational symmetry, we further show that strong magnon-magnoncoupling with large tunable gaps can be induced between the two resonant modes.
DOI: 10.1103/PhysRevLett.123.047204
Antiferromagnetic spintronics is an emerging field with
the potential to realize high speed logic and memory devices
[1–6]. Compared to ferromagnetic materials, antiferromag-
netic dynamics are less well understood [7–10], partly due to
their high intrinsic frequencies that require terahertz tech-
niques to probe [11–13]. Therefore, antiferromagnetic
materials with lower resonant frequencies are desired to
enable a wide range of fundamental and applied research [5].
Here, we introduce the layered antiferromagnetic insulatorCrCl
3as a tunable platform for studying antiferromagnetic
dynamics. Because of the weak interlayer coupling,
the antiferromagnetic resonance (AFMR) frequenciesare within the range of typical microwave electronics
(<20 GHz). This allows us to excite different modes of
AFMR and to induce a symmetry-protected mode crossingwith an external magnetic field. We further show that a
tunable coupling between the optical and acoustic magnon
modes can be realized by breaking rotational symmetry.Recently, strong magnon-magnon coupling between two
adjacent magnetic layers has been achieved [14,15] , with
potential applications in hybrid quantum systems [16–18].
Our results demonstrate strong magnon-magnon coupling
within a single material and therefore provide a versatile
system for microwave control of antiferromagnetic dynam-ics. Furthermore, CrCl
3crystals can be exfoliated down to
the monolayer limit [19] allowing device integration for
antiferromagnetic spintronics.
The crystal and magnetic structures of CrCl 3are shown in
Fig.1 [19 –26]. Spins within each layer have a ferromagnetic
nearest-neighbor coupling of about 0.5 meV , whereas spins
in adjacent layers have a weak antiferromagnetic coupling of
about 1.6μeV[25]. Therefore, we can consider each layer as
a two-dimensional ferromagnet coupled to the adjacent
layers by an interlayer exchange field of roughly 0.1 T
[25]. The weak interlayer coupling implies that the field and
FIG. 1. (a) Crystal structure of a single CrCl 3layer. Red and
purple spheres represent chlorine and chromium atoms respec-tively. (b) Magnetic structure of bulk CrCl
3below the Ne´ el
temperature, and without an applied magnetic field. Blue spheresrepresent the Cr atoms. Red arrows represent the magneticmoment of each Cr atom with parallel intralayer alignmentand antiparallel interlayer alignment. The net magnetizationdirection alternates between layers, having direction ˆm
A(ˆmB)
on layers in the A(B) magnetic sublattice. (c) Experimental
schematic featuring a coplanar waveguide (CPW) with a CrCl 3
crystal placed over the signal line. Hjj,H⊥, and Hzare the
components of the applied dc magnetic field. The microwave
transmission coefficient was measured as a function of appliedmagnetic field and temperature. (d) Typical microwave trans-mission at 5 GHz and 1.56 K as a function of magnetic fieldapplied parallel (blue) or perpendicular (red) to the in-plane rffield, showing resonances due to AFMR. The two traces weretaken from different CrCl
3crystals.PHYSICAL REVIEW LETTERS 123, 047204 (2019)
0031-9007 =19=123(4) =047204(6) 047204-1 © 2019 American Physical Societyfrequency required to manipulate the antiferromagnetic
order parameter (N´ eel vector) are orders of magnitude lower
than in typical antiferromagnets [27–29].
Magnetic resonance measurements of CrCl 3have a long
history, including one of the earliest observations of para-
magnetic resonance in a crystal [30]. However, the dynam-
ics below the N´ eel temperature remain largely unexplored.
To study this, we first synthesized bulk CrCl 3crystals
according to the method of McGuire et al. [19,31] . The
crystals are transferred to a coplanar waveguide (CPW)
and secured with Kapton tape [Fig. 1(c)]. The crystal caxis
is normal to the CPW plane. The CPW is mounted in a
cryostat and connected to a vector network analyzer by rf
cables for microwave transmission measurements. A dc
magnetic field is applied with the field directions illustrated
in Fig. 1(c). To study the response in the linear regime and
to prevent heating, we use a low power excitation signal
(estimated to be −35dBm at the sample).
We measure magnetic resonance by fixing the excitation
frequency and sweeping the applied magnetic field. Weobserve different resonant features in different field geom-etries [Fig. 1(d)]. Only one resonance is observed when the
dc magnetic field is applied perpendicular to the rf field(H
⊥), but two resonances show up when the dc magnetic
field is applied parallel to the rf field ( Hjj). We plot the
transmission as a function of excitation frequency and
applied magnetic field (Fig. 2). Under Hjj, two modes exist
with distinct field dependencies [Fig. 2(a)]: one starting
from finite frequency and softening with applied field, and
the other with frequency proportional to the applied field.Remarkably, the modes cross without apparent interactionleading to a degeneracy at their crossing point; as wediscuss below this crossing is protected by symmetry whenthe applied field lies in the crystal planes. With H
⊥, we see
only the linearly dispersing mode [Fig. 2(b)].
To understand the origin of the two modes, we model the
magnetic dynamics of CrCl 3in the macrospin approxima-
tion. We assume that the magnetization direction is uniformwithin each layer, and introduce unit vectors ˆm
Aand ˆmBto
represent the magnetization direction on the AandB
sublattices. The interlayer exchange energy is approxi-
mated as μ0MsHEˆmA·ˆmB, where HEis the interlayer
exchange field and Msis the saturation magnetization.
Omitting damping, we get a coupled Landau-Lifshitz-
Gilbert (LLG) equation [33]:
dˆmA
dt¼−μ0γˆmA×ðH−HEˆmB−MsðˆmA·ˆzÞˆzÞþτA;
dˆmB
dt¼−μ0γˆmB×ðH−HEˆmA−MsðˆmB·ˆzÞˆzÞþτB: ð1Þ
Here γis the gyromagnetic ratio and ˆzis the direction
perpendicular to sample plane (along the crystal caxis). τA
and τBare the torques which arise from the rf field of
the CPW.
The term proportional to Msrepresents an easy-plane
anisotropy arising from the demagnetization field of a
platelet shaped crystal. Previous studies have shown thatthe magnetic anisotropy of CrCl
3is well described by this
shape anisotropy [19,25] . Replacing Msby an effective
value would allow for an additional uniaxial magneto-crystalline anisotropy, but we confirm below that this effect
is small. We also neglect in-plane anisotropy as the energy
depends weakly on the in-plane orientation of the magneticmoments [19,25] .
FIG. 2. Microwave transmission as a function of frequency and in-plane magnetic field at 1.56 K with the magnetic field applied
(a) parallel and (b) perpendicular to the in-plane rf field (the data for the two panels were taken from different samples). The regions oflower transmission arise from magnetic resonance. Two modes are observed in the H
jjconfiguration: an optical mode that has finite
frequency at zero applied field, and an acoustic mode with frequency proportional to the applied field. Only the acoustic mode isobserved in the H
⊥configuration. Blue and red dashed lines in both panels are fits of the optical and acoustic mode frequencies to
Eqs. (2)and(3), respectively. Insets of (a) and (b) show the relative orientation of the dc magnetic field, the equilibrium sublattice
magnetizations, and the in-plane ( hIP) and out-of-plane ( hOP) components of the rf field. (c),(d) Schematic illustrations of the precession
orbits for the two sublattice magnetizations in the optical mode and the acoustic mode.PHYSICAL REVIEW LETTERS 123, 047204 (2019)
047204-2When the magnetic field His applied in the layer plane,
Eq.(1)is symmetric under twofold rotation around the
applied field direction combined with sublattice exchange[31]. In the linear approximation, this results in two
independent modes with even and odd parity under the
symmetry (optical mode and acoustic mode; see Fig. 2).
The optical and acoustic modes result in Lorentzianresonances centered around the frequencies ω
/C6. The
frequencies have magnetic field dependence [31,34,35] :
ωþ¼μ0γffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
2HEMs/C18
1−H2
4H2
E/C19s
; ð2Þ
and
ω−¼μ0γffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
2HEð2HEþMsÞp H
2HE: ð3Þ
We can fit the resonance frequencies using Eqs. (2)and
(3). These fits are shown by the dashed lines in Fig. 2(a)
with fit parameters of μ0HE¼105mT and μ0Ms¼
396mT at T¼1.56K, assuming γ=2π≈28GHz=T for
CrCl 3[36]. The observed saturation magnetization is close
to3μBper Cr atom, consistent with magnetometry [19,31]
and confirming that the out-of-plane crystalline anisotropyis small. Note that the acoustic mode changes its slope at
μ
0H≈200mT. This occurs because the moments of the
two sublattices are aligned with the applied field when H>
2HE[31]. In this case the crystal behaves as a ferromagnet
and the acoustic mode transforms into uniform ferromag-
netic resonance (FMR) described by the Kittel formula
ωFMR¼μ0γffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
HðHþMsÞp
. Figures 2(a) and 2(b) also
show fits of the data for H> 2HEto the Kittel formula
(dash-dotted line). (The data above and below H¼2HE
are fit simultaneously to extract a consistent parameter set.)The dependence on field geometry in Fig. 2can now be
understood as a consequence of selection rules. We can
state the rule as follows: an rf magnetic field will excite theeven (odd) parity mode if it is even (odd) under twofoldrotation around the applied field direction [31]. The rf
magnetic field generated from the CPW [Fig. 1(c)] has both
in-plane and out-of-plane components. Directly over thesignal line, the rf field points in the sample plane, while inthe gap between the signal line and ground, the rf field is
perpendicular to the sample plane. Our crystal is large
enough to cover both regions and experience both fielddirections. In the perpendicular geometry ( H
⊥), both the in-
plane and out-of-plane rf fields change sign under twofold
rotation around the applied field direction [inset of
Fig. 2(b)]. Therefore only the odd parity (acoustic) mode
will be excited. In the parallel field geometry ( Hjj), the in-
plane component is invariant under the twofold rotation and
excites the even parity (optical) mode, while the out-of-
plane component changes sign and excites the odd-parity(acoustic) mode [inset of Fig. 2(a)]. We will focus on
measurements in the parallel field geometry because it
allows simultaneous excitation of both modes.
We further study the evolution of the AFMR as a
function of temperature. As the temperature is increased
from 1.56 K [Fig. 2(a)] to 7 K [Fig. 3(a)], the optical
mode frequency decreases due to the reduction of H
Eand
Ms. The optical mode disappears entirely at 14 K,
implying that the sample is no longer antiferromagnetic,
consistent with magnetometry measurements [19,31] .A t
higher temperatures, the magnetic resonance frequencydepends linearly on the applied field with a slope of
30.4GHz=T and 28.8GHz=T at 21 K and 30 K, respec-
tively [Figs. 3(c) and3(d)]. This is electron paramagnetic
resonance arising from Cr
3þions [36]. In this temperature
range, the magnetization is proportional to the applied
field through M¼χðTÞH. Then the resonant frequency is
FIG. 3. Microwave transmission as a function of frequency and in-plane magnetic field at 7, 14, 21, and 30 K. At 7 K, the sample is
antiferromagnetic and both acoustic and optical modes are observed; μ0HE¼89mT and μ0Ms¼323mT are determined by fits to
Eqs. (2)and(3), which are smaller than those at 1.56 K [Fig. 2(a)]. Only one mode is observed at 14 K, and its frequency does not show a
purely linear field dependence. At 21 and 30 K, a single mode with linear field dependence is observed, arising from electronparamagnetic resonance.PHYSICAL REVIEW LETTERS 123, 047204 (2019)
047204-3ω¼μ0γffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
HðHþMðH;T ÞÞp
¼μ0γffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
1þχðTÞp
H[37].O u r
data correspond to χð21KÞ¼0.178 and χð30KÞ¼
0.056. For the temperature range 14 –20 K, the resonant
frequencies do not have a purely linear dependence onapplied field [Fig. 3(b)]. This is likely due to a nonlinear
relationship MðHÞasMapproaches its saturation value,
previously detected in magnetization and magneto-opticalexperiments [19,31,38] .
So far, we have discussed AFMR with an in-plane
applied magnetic field [34]. In this case, the system is
symmetric under twofold rotation around the applied field
direction combined with sublattice exchange. This pre-
vents hybridization between the optical and acoustic
modes, leading to a degeneracy where they cross [see
Figs. 2(a) and3(a)]. In principle, breaking this symmetry
can hybridize the two modes and generate an anticrossing
gap. One possible approach for inducing symmetry
breaking is to use different M
sfor the AandBsublattices
by stacking different 2D magnets. Here, we instead
employ an out-of-plane field to break the 180° rotational
symmetry. We measure the AFMR spectrum for a dc
magnetic field applied at a range of angles, ψ, from the
CPW plane. For ψ¼30°, the mode structure is largely
unchanged, except that a gap opens near the crossing
point [Fig. 4(b)]. Increasing the tilt angle increases the
gap size as shown in Fig. 4(c). Therefore, breaking the
rotational symmetry with an out-of-plane field introduces
a magnon-magnon coupling between the previously
uncoupled modes.
To quantitatively describe the magnon-magnon cou-
pling, we turn to the matrix formalism of the LLG equation
[31]. The result is high and low frequency branches of
antiferromagnetic resonance, continuously connected to the
even and odd parity modes. The evolution of both modes
and their mixing can be captured by the eigenvalue problemof a two-by-two matrix:/C12/C12/C12/C12ω
2aðH;ψÞ−ω2Δ2ðH;ψÞ
Δ2ðH;ψÞ ω2oðH;ψÞ−ω2/C12/C12/C12/C12¼0 ð4Þ
Here ω
a¼μ0γffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi
1þðMs=2HEÞp
Hcosψis the bare
acoustic mode frequency and ωo¼μ0γð2HEMs½1−
ðH2=H2
FMÞ/C138 þ fð sin2ψÞ=½1þðMs=2HEÞ/C1382gH2Þ1=2is the
bare optical mode frequency. HFMis the applied magnetic
field required to fully align the two sublattices, satisfy-
ing1=H2
FM¼cos2ψ=ð2HEÞ2þsin2ψ=ð2HEþMsÞ2.Δ¼
μ0γH½2HE=ð2HEþMsÞsin2ψcos2ψ/C1381=4represents the
magnon-magnon coupling term. The solutions of Eq. (4)
are the resonance frequencies of the LLG equation. Whenjω
o−ωaj≫Δ, the effect of the coupling term is negligible
and the solutions are approximately ω≈ωoandω≈ωa.
When the optical and acoustic modes become closer infrequency, they are hybridized by the coupling termopening a gap. This coupling is zero for ψ¼0° and only
becomes nonzero as we cant the applied field out-of-plane.
Note that when ψ¼90° the mode coupling is zero again
corresponding to rotational symmetry around the out-of-
plane direction [31]; this decoupling becomes relevant for
ψ>80° so we will focus on the regime ψ<80°.
The dashed lines in Figs. 4(a)–4(c) indicate fits to the
eigenvalues of Eq. (4), with fit parameters μ
0Ms¼409mT
and μ0HE¼101mT. The coupling strength g=2πis
determined as half of the minimal frequency spacing in
the fits. We determine the dissipation rates of the upperand lower branches, κ
UandκL, by Lorentzian fitting of
the frequency dependence of the transmission, using
vertical cuts on the 2D plots of 4(c). For ψ¼55°, we
obtain g=2π≈0.8GHz, κU=2π≈0.5GHz, and κL=2π≈
0.2GHz which indicates strong magnon-magnon coupling
asg>κUandg>κL[14]. The cooperativity is C¼g2=
ðκU×κLÞ¼6.4, which can be improved by using a more
homogeneous sample. Figure 4(e) shows the angular
dependence of g. By rotating the crystal alignment in an
FIG. 4. Microwave transmission as a function of frequency and applied field at 1.56 K; the field is applied at an angle of (a) ψ¼0°,
(b) 30°, and (c) 55° from the sample plane. When the field is applied in-plane, the mode crossing is protected by rotational symmetrycombined with sublattice exchange. Out-of-plane field breaks the symmetry and couples the two modes resulting in tunable gaps.(d) Microwave transmission vs applied field at ψ¼55° for various frequencies, showing the coupling gap. An extra small dip appears at
7.2 GHz, probably due to resonance peak splitting induced by inhomogeneities. (e) The coupling strength gincreases with ψ, and can be
tuned from 0 to 1.37 GHz.PHYSICAL REVIEW LETTERS 123, 047204 (2019)
047204-4applied field, we can tune the system from a symmetry-
protected mode crossing to the strong coupling regime.
In summary, we have measured magnetic resonance of
the layered antiferromagnet CrCl 3as a function of temper-
ature and applied magnetic field, with the magnetic fieldapplied at various angles from the crystal planes. We have
shown that CrCl
3possess a rich GHz-frequency AFMR
spectrum due to the weak interlayer coupling. We detectboth acoustic and optical branches of AFMR and show thatan applied magnetic field can induce an accidental degen-
eracy between them. Furthermore, by breaking rotational
symmetry we can induce a coupling between these modesand open a tunable gap. All of these effects are captured
with analytical solutions to the LLG equation. We also
expect interaction between the modes in the nonlinearregime. For example, three-magnon processes could be
triggered when the frequencies of the acoustic and optical
modes satisfy certain relationships.
There is also tremendous interest in isolating ultrathin
layered magnets using mechanical exfoliation [39,40] , and
incorporating them in van der Waals heterostructures
[41,42] . Because CrCl
3can be cleaved to produce air-
stable films down to the monolayer limit [19], we expect
our results to enable device-based antiferromagnetic spin-
tronics with microwave control of the N´ eel vector. Our
results apply broadly within the class of transition metal
trihalides, so that the frequency scale can be tuned by
varying the chemical composition and thickness [19].
Using van der Waals assembly, we can combine differentmagnetic materials to induce magnon-magnon coupling
without out-of-plane field by breaking sublattice exchange
symmetry.
Device fabrication, data analysis, and measurements by
the PJH group were primarily supported by the DOE Office
of Science, Basic Energy Sciences under Award No. DE-
SC0018935 (D. M.), as well as the Gordon and BettyMoore Foundations EPiQS Initiative through GrantNo. GBMF4541 to P. J.-H. Crystal growth was partly
supported by the Center for Integrated Quantum
Materials under NSF Grant No. DMR-1231319 (D. R. K.).D. R. K. acknowledges partial support by the NSF Graduate
Research Fellowship Program under Grant No. 1122374.
J. T. H., P. Z., and L. L. acknowledge support from NationalScience foundation under Grant No. ECCS-1808826.
*These authors contributed equally to this work.
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047204-6 |
PhysRevB.95.155139.pdf | PHYSICAL REVIEW B 95, 155139 (2017)
Temperature-dependent transport properties of FeRh
S. Mankovsky, S. Polesya, K. Chadova, and H. Ebert
Department Chemie, Ludwig-Maximilians-Universität München, 81377 München, Germany
J. B. Staunton
Department of Physics, University of Warwick, Coventry, United Kingdom
T. Gruenbaum, M. A. W. Schoen, and C. H. Back
Department of Physics, Regensburg University, Regensburg, Germany
X. Z. Chen and C. Song
Key Laboratory of Advanced Materials (MOE), School of Materials Science and Engineering,
Tsinghua University, Beijing 100084, China
(Received 9 June 2016; revised manuscript received 16 March 2017; published 25 April 2017)
The finite-temperature transport properties of FeRh compounds are investigated by first-principles density-
functional-theory-based calculations. The focus is on the behavior of the longitudinal resistivity with risingtemperature, which exhibits an abrupt decrease at the metamagnetic transition point, T=T
m, between ferro-
and antiferromagnetic phases. A detailed electronic structure investigation for T/greaterorequalslant0 K explains this feature
and demonstrates the important role of (i) the difference of the electronic structure at the Fermi level betweenthe two magnetically ordered states and (ii) the different degree of thermally induced magnetic disorder in thevicinity of T
m, giving different contributions to the resistivity. To support these conclusions, we also describe
the temperature dependence of the spin-orbit-induced anomalous Hall resistivity and Gilbert damping parameter.For the various response quantities considered, the impact of thermal lattice vibrations and spin fluctuations ontheir temperature dependence is investigated in detail. Comparison with corresponding experimental data shows,in general, very good agreement.
DOI: 10.1103/PhysRevB.95.155139
I. INTRODUCTION
For a long time the ordered equiatomic FeRh alloy has
attracted much attention owing to its intriguing temperature-dependent magnetic and magnetotransport properties. Thecrux of these features of this CsCl-structured material isthe first-order transition from an antiferromagnetic (AFM) toferromagnetic (FM) state when the temperature is increasedabove T
m=320 K [ 1,2]. In this context the drop in the
electrical resistivity that is observed across the metamagnetictransition is of central interest. Furthermore, if the AFMto FM transition is induced by an applied magnetic field,a pronounced magnetoresistance (MR) effect is found ex-perimentally with a measured MR ratio of ∼50% at room
temperature [ 2–4]. The temperature of the metamagnetic
transition as well as the MR ratio can be tuned by the additionof small amounts of impurities [ 2,5–8]. These properties make
FeRh-based materials very attractive for future applicationsin data storage devices. The origin of the large MR effectin FeRh, however, is still under debate. Suzuki et al. [9]
suggest that, for deposited thin FeRh films, the main mech-anism stems from the spin-dependent scattering of conductingelectrons on localized magnetic moments associated withpartially occupied electronic dstates [ 10] at grain boundaries.
Kobayashi et al. [11] have also discussed the MR effect in
the bulk ordered FeRh system, attributing its origin to themodification of the Fermi surface across the metamagnetictransition. So far only one theoretical investigation of theMR effect in FeRh has been carried out on an ab initio
level [ 12].II. COMPUTATIONAL DETAILS
The present study is based on spin-polarized electronic
structure calculations using the fully relativistic multiplescattering Korringa-Kohn-Rostoker (KKR) Green’s functionmethod [ 13,14] with the framework of spin density functional
theory. For the self-consistent calculations a parametrizationfor the exchange and correlation potential based on thegeneral gradient approximation (GGA) [ 15] has been used.
For the charge and potential representation the atomic sphereapproximation (ASA) has been applied. For the wave functionsand corresponding matrices of the KKR formalism the cutoffvalue l
max=3 has been used for the angular momentum
expansion.
The central advantage of the KKR formalism is that it gives
direct access to the retarded single-particle Green’s functionG
+(/vectorr,/vectorr/prime,E), which is given by [ 16–18]
G+(/vectorr,/vectorr/prime,E)=/summationdisplay
/Lambda1/Lambda1/primeZm
/Lambda1(/vectorr,E)τmn
/Lambda1/Lambda1/prime(E)Zn×
/Lambda1/prime(/vectorr/prime,E)
−δmn/summationdisplay
/Lambda1Zn
/Lambda1(/vectorr,E)Jn×
/Lambda1(/vectorr/prime,E)/Theta1(r/prime
n−rn)
+Jn
/Lambda1(/vectorr,E)Zn×
/Lambda1(/vectorr/prime,E)/Theta1(rn−r/prime
n), (1)
where the spatial vectors /vectorrand/vectorr/primeare assumed to be within the
atomic cell centered at sites /vectorRm,/vectorRn, respectively. Within the
fully relativistic formulation used here the combined quantumnumber /Lambda1=(κ,μ) stands for the relativistic spin-orbit and
magnetic quantum numbers κandμ, respectively [ 19].
2469-9950/2017/95(15)/155139(9) 155139-1 ©2017 American Physical SocietyS. MANKOVSKY et al. PHYSICAL REVIEW B 95, 155139 (2017)
Accordingly, Zn
/Lambda1andJn
/Lambda1are four-component wave functions
obtained as regular and irregular solutions to the single-siteDirac equation for the isolated potential well V
ncentered
at site n, respectively. The symbol “ ×” as a superscript of
Zn
/Lambda1andJn
/Lambda1indicates the left-hand-side solution to the Dirac
equation. Dealing with a magnetically ordered system withinthe framework of spin density functional theory, the potentialV
nis spin dependent. As a consequence Zn
/Lambda1=/Sigma1/Lambda1/primeZn
/Lambda1/prime/Lambda1(and
alsoJn
/Lambda1) stands for a superposition of various partial waves
with spin-angular character /Lambda1/prime[20,21]. Finally, the quantity
τnn/prime
/Lambda1/Lambda1/primeis the so-called scattering path operator that represents
the transfer of a wave coming in at site n/primewith character /Lambda1/primeto
a wave outgoing from site nwith character /Lambda1and all possible
scattering events taking place in between [ 17].
The scheme sketched above to calculate the retarded
Green’s function gives direct access to the density of states(DOS) n(E) via the expression
n(E)=−Im
π/integraldisplay
/angbracketleftG+(/vectorr,/vectorr,E)/angbracketrightcd3r. (2)
Information on the electronic structure more detailed than
that given by the DOS is given by the Bloch spectral function
(BSF) AB(/vectork,E). In terms of the retarded Green’s function, this
quantity is defined via
AB(/vectork,E)=−Im
π/summationdisplay
n,mexp[ı/vectork·(/vectorRn−/vectorRm)]
×/integraldisplay
/angbracketleftG+(/vectorr+/vectorRn,/vectorr+/vectorRm,E)/angbracketrightcd3r, (3)
where again the angular brackets specify an appropriate
configurational average. For a perfectly ordered system the
BSF would be a set of Dirac delta functions, AB(/vectork,E)=/summationtext
γδ(E−E/vectorkγ), and for E=EFit would trace out the Fermi
surface. For a system with thermally induced spin fluctuations
and lattice displacements the BSF has features with finite widthfrom which the mean-free-path length of the electrons can beinferred.
The present approach used for the electronic structure
calculations allows us to calculate the transport properties atfinite temperatures on the basis of the linear response for-malism using the Kubo-St ˇreda expression for the conductivity
tensor [ 22,23],
σ
μν=¯h
4πN/Omega1Tr/angbracketleftˆjμ[G+(EF)−G−(EF)]ˆjνG−(EF)
−ˆjμG+(EF)ˆjν[G+(EF)−G−(EF)]/angbracketrightc, (4)
where /Omega1is the volume of the unit cell, Nis the number
of sites, ˆjμis the relativistic current operator, and G±(EF)
are the electronic retarded and advanced Green’s functions,respectively, calculated at the Fermi energy E
F.I nE q .( 4)t h e
orbital current term has been omitted as it provides only smallcorrections to the prevailing contribution arising from the firstterm in the case of a cubic metallic system [ 24–26].
The Gilbert damping parameters αare calculated using a
Kubo-Greenwood-like equation [ 27]:
α
μμ=−¯hγ
πMsTr/angbracketleftˆTμImG+(EF)ˆTμImG+(EF)/angbracketrightc,(5)with the torque operator ˆTμgiven by the expression
ˆTμ=β[/vectorσ׈ez]μBxc(/vectorr), (6)
with ˆezbeing the direction of magnetization and Bxc(/vectorr) being
the spin-dependent part of the potential.
The angular brackets /angbracketleft ···/angbracketright c(if applicable) in all expressions
above specify the average over temperature-induced spinfluctuations and lattice vibrations treated within the alloyanalogy model described in the Appendix A.
III. RESULTS
First, we focus on the finite-temperature properties of the
electrical resistivity of FeRh. In order to take into accountelectron-phonon and electron-magnon scattering effects inthe calculations, the so-called alloy analogy model [ 27,28]
is used. Within this approach the temperature-induced spin(local moment) and lattice excitations are treated as local-ized, slowly varying degrees of freedom with temperature-dependent amplitudes. Using the adiabatic approximation inthe calculations of transport properties and accounting for therandom character of the motions, the evaluation of the thermalaverage over the spin and lattice excitations in Eq. ( 4)i s
reduced to a calculation of the configurational average overthe local lattice distortions (averaged within the unit cell)and magnetic moment orientations, /angbracketleft ···/angbracketright
c, using the recently
reported approach [ 27,28], which is based on the coherent
potential approximation (CPA) alloy theory [ 29–31].
To account for the effect of spin fluctuations, which
we describe in a way similar to what is done within thedisordered local moment (DLM) theory [ 32], the angular
distribution of thermal spin moment fluctuations is calculatedusing the results of Monte Carlo (MC) simulations. Theseare based on ab initio exchange coupling parameters and
reproduce the finite-temperature magnetic properties for theAFM and FM states in both the low-temperature ( T< T
m) and
high-temperature ( T> T m) regions very well [ 33]. The inset
in Fig. 1(a) shows the temperature-dependent magnetization
M(T) for one of the two Fe sublattices aligned antiparallel
(parallel) to each other in the AFM (FM) state, calculatedacross the temperature region covering both AFM and FMstates of the system. The different behavior of the magneticorderM(T) in the two phases has important consequences for
the transport properties, as discussed below.
Figure 1(a) shows the calculated electrical resistivity as a
function of temperature ρ
xx(T), accounting for the effects of
electron scattering from thermal spin and lattice excitations,and compares it with experimental data. There is clearly
a rather good theory-experiment agreement, especially con-
cerning the difference ρ
AFM
xx(Tm)−ρFM
xx(Tm) at the AFM/FM
transition, Tm=320 K. The AFM state’s resistivity increases
more steeply with temperature when compared to that of theFM state, which has also been calculated for temperaturesbelow the metamagnetic transition temperature (dotted line).Note that the experimental measurements have been performedfor a sample with 1% intermixing between the Rh and Fesublattices, leading to a finite residual resistivity at T→0
K, and as a consequence, there is a shift of the experimentalρ
xx(T) curve with respect to the theoretical one [ 34].
155139-2TEMPERATURE-DEPENDENT TRANSPORT PROPERTIES OF . . . PHYSICAL REVIEW B 95, 155139 (2017)
FIG. 1. (a) Calculated longitudinal resistivity (solid circles: AFM
state, open circles: FM state) in comparison with experiment [ 2]. The
dashed line represents the results for Fe 0.49Rh0.51, while the dash-
dotted line gives results for (Fe-Ni) 0.49Rh0.51with the Ni concentration
x=0.05 to stabilize the FM state at low temperature. The inset
represents the relative magnetization of one Fe sublattice as a function
of temperature obtained from MC simulations (AFM: solid circles,
FM: open circles) and the experimental magnetization curve M(T)
(dashed line). (b) Electrical resistivity calculated for the AFM (solid
symbols) and FM (open symbols) states accounting for all thermal
scattering effects (circles) as well as accounting for effects of latticevibrations (diamond) and spin fluctuations (squares) separately. The
inset shows the temperature-dependent longitudinal conductivity for
the AFM and FM states due to only lattice vibrations.
We can separate out the contributions of spin fluctuations
and lattice vibrations to the electrical resistivities, ρfluc
xx(T)
andρvib
xx(T), respectively. These two components have been
calculated for finite temperatures while keeping the atomicpositions undistorted to find ρ
fluc
xx(T) and with fixed collinear
orientations of all magnetic moments to find ρvib
xx(T), respec-
tively. The results for the AFM and FM states are shown inFig. 1(b), where again the FM (AFM) state has also been
considered below (above) the transition temperature T
m.F o r
both magnetic states the local moment fluctuations have adominant impact on the resistivity. One can also see that both
components, ρfluc
xx(T) and ρvib
xx(T), in the AFM state have a
steeper increase with temperature than those of the FM state.
The origin of this behavior can be clarified by referring
to Mott’s model [ 35] with its distinction between delocalized
spelectrons, which primarily determine the transport prop-
erties owing to their high mobility, and the more localizeddelectrons. Accordingly, the conductivity should depend
essentially on (see, e.g., [ 36]) (i) the carrier (essentially, sp
character) concentration nand (ii) the relaxation time τ∼
[V
2
scattn(EF)]−1, where Vscattis the average scattering potential
andn(EF) is the total density of states at the Fermi level. This
model has been used, in particular, for qualitative discussionsof the origin of the giant magnetoresistance (GMR) effectin heterostructures consisting of magnetic layers separatedby nonmagnetic spacers. In this case the GMR effect canbe attributed to the spin-dependent scattering of conductionelectrons, which leads to a dependence of the resistivitieson the relative orientation of magnetic layers, parallel orantiparallel, assuming the electronic structure of nonmagneticspacer remains unchanged. These arguments, however, cannotbe straightforwardly applied to CsCl-structured FeRh, eventhough it can be pictured as a layered system with one-atom-thick layers, since the electronic structure of FeRhshows strong modifications across the AFM-FM transition asdiscussed, for example, by Kobayashi et al. [11] to explain the
large MR effect in FeRh.
We use the calculated density of states at the Fermi level as a
measure of the concentration of the conducting electrons. Thechange in the carrier concentration at the AFM-FM transitioncan therefore be seen from the modification of the spDOS at
the Fermi level. The element-projected spin-resolved spDOS
n
sp(E), calculated for both FM and AFM states at different
temperatures, is shown in Fig. 2. At low temperature, for
FIG. 2. Comparison of the temperature-dependent densities of
states (DOSs) for the FM and AFM states of FeRh for T=40–400 K:
(a) Fe sDOS, (b) Fe pDOS, (c) Rh sDOS, and (d) Rh pDOS.
155139-3S. MANKOVSKY et al. PHYSICAL REVIEW B 95, 155139 (2017)
both Fe and Rh sublattices, the spDOS at EFis higher in
the FM state than in the AFM state, nFM
sp(EF)>nAFM
sp(EF).
This gives the first hint concerning the origin of the largedifference between the FM and AFM conductivities in thelow-temperature limit [see inset for σ
vib
xxin Fig. 1(b)]. In
this case the relaxation time τis still long owing to the
low level of both lattice vibrations and spin fluctuations,which determines the scattering potential V
scatt. For both
magnetic states the decrease in the conductivity with risingtemperature is caused by the increase of scattering processesand consequent decrease of the relaxation time. At the sametime, the conductivity difference, /Delta1σ(T)=σ
vib,FM
xx (T)−
σvib,AFM
xx (T), reduces with an increase in temperature. This
effect can partially be attributed to the temperature-dependentchanges in the electronic structure (disorder smearing of theelectronic states) reflected by changes in the density of statesat the Fermi level [ 34]( s e eF i g . 2). Despite this, up to the
transition temperature, T=T
m, the difference /Delta1σ(T) is rather
pronounced, leading to a significant change in the resistivityatT=T
m.
One has to stress that in calculating the contribution
of spin moment fluctuations to the resistivity, the different
temperature-dependent behaviors of the magnetic order in
the FM and AFM states must be taken into account. This
means that at the critical point, T=Tm, the smaller sublattice
magnetization in the AFM state describes a more pronounced
magnetic disorder when compared to the FM state, which leads
to both a smaller relaxation time and shorter mean free path.
The result is a higher resistivity in the AFM state.
The different mean-free-path lengths in the FM and AFM
states at a given temperature can be analyzed using the BSFA
B(/vectork,E), calculated for E=EF, since the electronic states at
the Fermi level give the contribution to the electrical conduc-tivity. For a system with thermally induced spin fluctuationsand lattice displacements the BSF has features with finite
width from which the mean-free-path length of the electrons
can be inferred. Figure 3shows an intensity contour plot for
the BSF of FeRh averaged over local-moment configurationsappropriate for the FM and AFM states just above and justbelow the FM-AFM transition, respectively. Figure 3(a)shows
the AFM Bloch spectral function, whereas Figs. 3(b) and3(c)
show the sharper features of the spin-polarized BSF of the FM
state, especially for the minority-spin states. This implies a
longer electronic mean free path in the FM state in comparisonto that in the AFM state, which is consistent with the drop inresistivity.
Finally, we discuss the behavior of the electrical resistivity
of FM-ordered FeRh in the vicinity to the Curie temperature.First of all, once the temperature has been raised above
the Curie temperature and the system is in a magnetically
disordered state, there is no longer a contribution from thespin fluctuations to the increase in the resistivity ρ(T) when
Tis increased further. The transition to the PM state results
therefore in an abrupt decrease of the rate of increase of ρ(T)
with temperature (see Fig. 1). This effect, observed also in
Fe and Ni, has been discussed previously [ 28]. Below T
C,
the sharp increase of the resistivity as the Curie temperature
is approached is a consequence of the fast increase in the
amplitude of transverse spin fluctuations in this temperatureregion. Figure 4demonstrates the impact of thermally induced
FIG. 3. Bloch spectral function (in units of states/Ry) of FeRh
calculated (a) for the AFM state at T=300 K and for the FM
state resolved into (b) majority-spin and (c) minority-spin electron
components, calculated for T=320 K. The finite width of this feature
determines the electronic mean free paths.
magnetic disorder on the electronic structure, leading to an
increase in smearing of the electron energy bands when thetemperature changes from 600 to 700 K. As discussed above,
155139-4TEMPERATURE-DEPENDENT TRANSPORT PROPERTIES OF . . . PHYSICAL REVIEW B 95, 155139 (2017)
FIG. 4. Element-resolved BSF on (a) Fe and (b) Rh sites in FeRh
calculated for the FM (left) and PM (right) states at finite temperatures
T=600 K and T=700 K, respectively; (c) comparison of the
element-resolved Fe (left) and Rh (right) DOS calculated for theFM (solid line) and PM (dashed line) states at finite temperatures
T=600 K ( M/M
0=0.66) and T=700 K ( M/M 0=0).
this observation is connected to the shortened lifetime of
the electronic states that causes an increase in the electricalresistivity. Clearly, the differences in the ρ(T) behavior in the
vicinity of T
Cfor different systems stem from specific features
of their electronic structures relevant to their PM states. For
example, there is (i) magnetic “local-moment” disorder in the
case of pure Fe, (ii) a Pauli paramagnetic state in the case ofpure Ni, and (iii) magnetic local-moment disorder on the Fesublattice and disappearance of spin polarization on the Rhsublattice in the case of FeRh. Figure 4(b) demonstrates the
induced spin splitting of the Rh electronic states in FeRh, inparticular around the Fermi level, at T< T
C(T=600 K,
left panel). This splitting disappears above TC(T=700 K,
right panel), so that the Rh DOS increases at the Fermi level[Fig. 4(c), right panel]. This leads in turn to the sharp increase
in the resistivity as the critical temperature is approachedsince ρ(T) is inversely proportional to the relaxation time
τ, i.e., ρ(T)∼[V
2
scattn(EF)] (see discussions above). It is
also worth mentioning the combined effect of both scattering
channels that arise from spin fluctuations and lattice vibrations.
The latter contribution is rather small (see Fig. 1), and
consequently, ρ(T) has a temperature dependence determined
essentially by the spin fluctuations. In the case of Fe [ 28],
on the other hand, both contributions are comparable, andlattice vibrations lead to a rather pronounced smearing of theelectronic states at E
Fwhen the temperature approaches TC,
which conceals the impact of the electron scattering from the
FIG. 5. (a) The temperature dependence of the anomalous Hall
resistivity for the FM state of (Fe 0.95Ni0.05)Rh in comparison with
experimental data [ 11]; (b) Gilbert damping parameter as a function of
temperature: theory accounting for all thermal contributions (squares)
in comparison with the experimental results for a thick-film system
(50 nm; open diamonds) [ 37] and for an FeRh thin film deposited
on a MgO(001) surface (upward and downward triangles). Upward
and downward triangles represent data for heating (h) and cooling (c)
cycles, respectively (for details see Appendix B). The inset represents
the results for the individual sources for the Gilbert damping, i.e.,
lattice vibrations (circles) and spin fluctuations (diamonds). The
totalαvalues calculated for the FeRh crystal without (cub) and
with tetragonal (tetra) distortions ( c/a=1.016) are shown by open
and solid squares, respectively. Gilbert damping for the FM phase
is shown by dashed lines in the temperature region below the
metamagnetic transition temperature.
spin fluctuations. As a result, the total ρ(T) has an almost
linear increase up to TC.
In particular concerning technical applications of FeRh, it
is interesting to study further temperature-dependent responseproperties. In Fig. 5(a) we show our calculations of the
total anomalous Hall resistivity for FeRh in the FM state,represented by the off-diagonal term ρ
xyof the resistivity
tensor, and compare it with experimental data [ 11]. As the
155139-5S. MANKOVSKY et al. PHYSICAL REVIEW B 95, 155139 (2017)
FM state is unstable in pure FeRh at low temperatures,
the measurements were performed for (Fe 0.965Ni0.035)Rh, for
which the FM state has been stabilized by Ni doping. Thecalculations have been performed both for the pure FeRhcompound and for FeRh with 5% Ni doping, (Fe
0.95Ni0.05)Rh,
which theory finds to be ferromagnetically ordered down toT=0 K. As can be seen, the magnitude of ρ
xy(T) increases in
a more pronounced way for the undoped system. Nevertheless,both results are in rather good agreement with experiment.
In addition to temperature-dependent transport properties
linear response calculations with the inclusion of relativisticeffects enable us to present results for Gilbert damping, whichplays a crucial role for spin dynamics. The experimental datashown in Fig. 5(b) by triangular symbols represent results
for rather thin FeRh films ( d=10 nm) deposited on top of
a MgO(001) substrate (see experimental details described inAppendix B). Upward and downward triangles in Fig. 5(b)
represent the Gilbert damping obtained for heating and coolingcycles, respectively. The FeRh unit cell with a lattice constant√
2 times smaller than that of MgO is rotated around the
zaxis by 45◦with respect to the MgO cell. Because of
this, a compressive strain occurs in the FeRh film. From theexperimental data [ 38], this implies a tetragonal distortion of
the FM FeRh unit cell with c/a=1.016.
Theαcalculations have been performed for the FM state
taking into account all temperature-induced effects, i.e., spinfluctuations and lattice vibrations [ 28,39]. As one can see in
Fig. 5(b), these results are in good agreement with the ex-
perimental value (shown by a diamond) for a thick (bulk) filmwhere αwas measured as 0.0012 at T=420 K [ 37]. However,
the calculated αvalues are smaller by a factor of 3 when
compared to the experimental data measured for the thinner10-nm film. Accounting for the tetragonal distortion results ina rather weak change for the calculated α, as can be seen in the
inset of Fig. 5(b) (solid squares). Therefore, the discrepancies
between theory and experiment have to be attributed partially
to surface and finite-size effects, as discussed, for example, byBarati et al. [40], which are not accounted for within the present
calculations. Another reason for the discrepancies can beassociated with the inhomogeneities presented in the sample.Note also that the measurements represented in Fig. 5(b)
have been performed in the vicinity of the metamagneticAFM-FM transition. In this temperature region the FM stateis not uniform, as discussed, for example, by Baldasseroniet al. [41], who observed the mixed-phase (FM +AFM) state
close to the T
mtransition temperature. Evidently, this can also
lead to an increase in the Gilbert damping in this temperatureregion when compared to the pure FM state considered in thecalculations.
The separate contributions to the Gilbert damping due to
spin fluctuations and lattice vibrations are shown in the insetof Fig. 5(b) for a range of temperatures extended to low tem-
peratures beyond those measured by experiment. As discussedin the literature, magnetization dissipation at low temperatureis well described via the breathing Fermi-surface model forpure elemental materials and ordered compounds [ 28,39,42].
In this regime the temperature dependence of the Gilbertdamping is directly connected to the relaxation time parameterof the electronic subsystem, which in turn is determined bythe dominating spin-conserving electron scattering that arisesfrom lattice vibrations, V
2
vib, and spin fluctuations, V2
flu.I n
this low-temperature regime (as discussed in Appendix C),
α∼[V2
vib+V2
flu]−1. The thermally induced increase in the
amplitude of lattice vibrations and spin fluctuations resultsin an increase in the effective scattering cross section for theelectrons and hence a decrease in the Gilbert damping. Basedon the expressions given in Appendix C, one can consider
individual contributions from different scattering channels atlow temperature. Thus, since α∼(α
−1
vib+α−1
fluc)−1, one can say
that the higher rate of decrease with rising temperature for α
is associated with the scattering mechanism which has thelarger scattering cross section. In particular, at T≈200 K,
the Gilbert damping associated with spin fluctuations isappreciably smaller than that due to lattice vibrations [seeinset in Fig. 5(b)]. This implies a large decrease at T< 200 K
ofα(T) with an increase in T, as seen in the inset in Fig. 5(b).
This clearly shows (see Appendix C) the dominant role of spin
fluctuations for the Gilbert damping in the low-temperatureregime, leading to a similar behavior for the total Gilbertdamping [squares in Fig. 5(b)]. Moreover, it can be seen
that the total αaccounting for both scattering channels is still
smaller in the low-temperature regime owing to the increasedeffective scattering cross section.
The “resistivitylike” behavior at higher temperatures, i.e.,
αgrowing with rising temperature, reflects the increasing role
of the interband transitions which determines a dominatingspin-flip dissipation mechanism [ 43]. In this regime, as seen
in Fig. 5(b), the increase in the total Gilbert damping with
rising temperature is predominantly determined by electronscattering from lattice vibrations, demonstrating the leadingrole of this scattering channel for the Gilbert damping at hightemperatures. Note that the spin fluctuations in the temperatureregion shown in Fig. 5(b)lead to a weak decrease of α(T) with
an increasing temperature, indicating a small contribution tothe spin-flip dissipation mechanism.
IV. SUMMARY
In summary, we have presented ab initio calculations for the
finite-temperature transport properties of the FeRh compound.A steep increase in the electric resistivity has been obtainedfor the AFM state, leading to a pronounced drop in resistivityat the AFM to FM transition temperature. This effect can beattributed partially to the difference in the electronic structureof FeRh in the FM and AFM states, as well as to a fasterincrease in the amplitude of spin fluctuations caused bytemperature in the AFM state. Further calculated temperature-dependent response properties such as the anomalous Halleffect (AHE) resistivity and the Gilbert damping parameter forthe FM system also show good agreement with experimentaldata. This gives additional confidence in the model used toaccount for thermal lattice vibrations and spin fluctuations.
ACKNOWLEDGMENTS
Financial support from the DFG via SFB 689 (Spin-
phänomene in reduzierten Dimensionen) and from the EPSRC(UK; Grant No. EP/J006750/1) is gratefully acknowledged.
155139-6TEMPERATURE-DEPENDENT TRANSPORT PROPERTIES OF . . . PHYSICAL REVIEW B 95, 155139 (2017)
APPENDIX A: TREATMENT OF THERMAL LATTICE
DISPLACEMENT AND SPIN FLUCTUATIONS
To account for the impact of the thermal lattice vibrations
and spin fluctuations, the alloy analogy model is used inthe present work. The multiple-scattering theory allows us to
describe the uncorrelated local thermal atomic displacements
and spin moment deviations from their equilibrium, withinthe single-site CPA alloy theory. This implies the reductionof the calculation of the thermal average to the calculationof a configurational average in full analogy with random alloysystems [ 28]. Within this approach the coherent scattering path
operator is defined as
τ
CPA=Nvf/summationdisplay
v=1xvxfτvf, (A1)
with summation over all types of local lattice vibrations and
spin fluctuations with the corresponding probabilities xvand
xf[28]. The underline indicates matrices with respect to the
combined index /Lambda1.T h eτvfoperators are defined through the
corresponding single-site scattering matrices tloc
vf[28]:
tvf=U(/Delta1/vectorRv)R(ˆef)tR(ˆef)−1U(/Delta1/vectorRv)−1. (A2)
HereR(ˆe) is a rotation matrix for the transformation from
the local to the global frame of reference. The so-called U-
transformation matrix U(/Delta1/vectorRq
v) for each atomic qsite in the
unit cell is given by [ 44,45]
ULL/prime/parenleftbig
/Delta1/vectorRq
v/parenrightbig
=4π/summationdisplay
L/prime/primeil+l/prime/prime−l/primeCLL/primeL/prime/primejl/prime/prime/parenleftbig/vextendsingle/vextendsingle/Delta1/vectorRq
v/vextendsingle/vextendsinglek/parenrightbig
YL/prime/prime(ˆs),
(A3)
where L=(l,m) represents the nonrelativistic angular mo-
mentum quantum numbers, jl(x) is a spherical Bessel function,
YL(ˆr) is real spherical harmonics, CLL/primeL/prime/primeis the corresponding
Gaunt number, and k=√
Eis the electronic wave vector. The
amplitude of atomic displacements |/Delta1/vectorRq
v|is represented by the
temperature-dependent rms displacement ( /angbracketleftu2/angbracketrightT)1/2according
to
Nv/summationdisplay
v=1xq
v/vextendsingle/vextendsingle/Delta1/vectorRq
v(T)/vextendsingle/vextendsingle2=/angbracketleftbig
u2
q/angbracketrightbig
T. (A4)
Basically, the mean-square displacement of the atom qalong
the direction μ(μ=x,y,z ) can be evaluated within phonon
calculations [ 46]. However, in the present work we have
used the approach based on Debye’s theory with the Debyetemperature /Theta1
Dtaken from experiment [ 47]. In this case
the individual mean-square displacements for different atomic
types in the unit cell are not well defined. Moreover, theirrelative magnitudes can change as a function of temperatureas a consequence of different ratios of the amplitude ofdisplacements for different types of atoms, associated withacoustic and optical phonon modes in the limit of smallwave vector /vectorq, as well as with the phonon modes with /vectorq
approaching the boundary of the Brillouin zone /vectorG/2 (see,
e.g., Ref. [ 46]). Because of the lack of such information,
we have used an approximation based on the averagedmean-square displacement. This implies that the mean-squaredisplacements for both types, Fe and Rh, are equal and are
given by the expression [ 48,49]
/angbracketleftbig
u
2
μ/angbracketrightbig
T=1
43h2
π2Mk B/Theta1D/bracketleftbigg/Phi1(/Theta1D/T)
/Theta1D/T+1
4/bracketrightbigg
, (A5)
with/Phi1(/Theta1D/T) being the Debye function. In spite of the
simplicity, this approach gives results in rather good agreementwith experimental data for disordered alloys as well as forordered compounds, as was shown previously [ 39,50]. As a
consequence of the above-mentioned temperature-dependentproperties of the mean-square displacements, the differencebetween the experimental and theoretical resistivities for theordered FeRh compound [see Fig. 1(a) in the main text] can
be partially attributed to the present simplification used for theevaluation of mean-square displacements.
APPENDIX B: EXPERIMENTAL DETAILS
OF GILBERT DAMPING
FeRh films were grown on (001)-oriented single-crystal
MgO substrates using dc magnetron sputtering. The basepressure of the chamber was 2 ×10
−5Pa. The substrates
were kept at 573 K for 30 min. Then 10-nm FeRh weredeposited with a growth pressure of 0.7 Pa Ar correspondingto stoichiometric Fe
51Rh49films [ 51]. The sputtering power is
30 W for 3-inch Fe 50Rh50targets. Afterwards, the films were
heated to 1023 K and annealed for 100 min. When the filmswere cooled down to room temperature, they were capped with5-nm Al in situ .
The experimental data were obtained by field-swept fer-
romagnetic resonance measurements of a 25-nm FeRh filmgrown on MgO(001) and capped by 5-nm Al in the out-of-plane configuration for frequencies from 5 to 24 GHz. Thetemperature was controlled by heating through the substrate,and the measured absorption spectra were fitted to a Lorentzianline shape [ 52] in order to obtain the linewidth /Delta1H.T h e
damping parameter αwas determined from the frequency
dependence of /Delta1H, as demonstrated by Mancini et al. [37]
and Heinrich et al. [53].
APPENDIX C
To discuss the temperature-dependent behavior of Gilbert
damping in more detail one can represent the expression in
Eq. ( 5) in terms of the Bloch spectral function A(E,/vectork,n),
following the corresponding discussions by Kamberský [ 54]
and Gilmore et al. [55]. According to these authors, the
leading contribution to the Gilbert damping in the low-temperature limit is associated with the intraband scatteringgiven by [ 54,55]
α
intra∼/summationdisplay
n/integraldisplayd3k
(2π)3|/Gamma1−
nn(/vectork)|2
×/integraldisplay
dEA (E,/vectork,n)A(E,/vectork,n)/parenleftbigg
−df(E)
dE/parenrightbigg
,(C1)
with
A(E,/vectork,n)=w/vectork,n
(E−E/vectork,n)2+w2
/vectork,n,
155139-7S. MANKOVSKY et al. PHYSICAL REVIEW B 95, 155139 (2017)
where /Gamma1−
nnis the matrix element of the transverse torque
operator and w2
/vectork,nis related to the imaginary part of the the
scattering self-energy [ 54]. In the present work we discuss
two contributions due to various electron scattering channels,i.e., due to lattice vibrations with Im /Sigma1
vib
/vectork,n∼(τvib
/vectork,n)−1and due
to spin fluctuations with Im /Sigma1flu
/vectork,n∼(τflu
/vectork,n)−1, and the relaxation
times, τvib
/vectork,nandτflu
/vectork,n, corresponding to the different scattering
channels. With this, w2
/vectork,ncan be represented by the effective
relaxation time ( τeff)−1=(τvib)−1+(τflu)−1.A sw a ss h o w n
in Refs. [ 54,55], after integration over the energies, Eq. ( C1)
can be reduced to
αintra∼τeff/summationdisplay
n/integraldisplayd3k
(2π)3|/Gamma1−
nn(/vectork)|2. (C2)
According to the discussions above, we have τflu∼
[V2
flun(EF)]−1andτvib∼[V2
vibn(EF)]−1, leading to the follow-
ing dependence: α∼τeff∼[V2
vib+V2
flu]−1. The expression in
Eq. ( C2) can also be reduced to the form used for discussions
of the Gilbert damping within the breathing Fermi-surfacemodel [ 55–57] that describes well the temperature-dependent
behavior α(T) in the low-temperature regime.The interband contribution in terms of Bloch spectral
function is given by the expression [ 54,55]
α
inter∼/summationdisplay
n/negationslash=m/integraldisplayd3k
(2π)3|/Gamma1−
nm(/vectork)|2
×/integraldisplay
dEA (E,/vectork,n)A(E,/vectork,m)/parenleftbigg
−df(E)
dE/parenrightbigg
.(C3)
At low temperature this contribution increases with tem-
perature as αinter∼τ−1
eff∼[V2
vib+V2
flu][54,55] and above a
certain temperature Tmbecomes the dominating part of the
Gilbert damping. This leads to the minimum for α(T)a t
Tm, which is determined by both VvibandVfluscattering
amplitudes in the case of the total αand by only VviborVflu
scattering amplitudes in the case of individual contributions
due to lattice vibrations and spin fluctuations, respectively,resulting in different positions of the minima in these threecases. Finally, it should be noted that the contributions to α
inter
due to lattice vibrations and spin fluctuations are additive,
in contrast to αintra. In this case, one gets an increase with
temperature of the total α(T) larger than in the case of separate
contributions due to different scattering channels.
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155139-9 |
PhysRevB.92.060411.pdf | RAPID COMMUNICATIONS
PHYSICAL REVIEW B 92, 060411(R) (2015)
Current-induced fingering instability in magnetic domain walls
J. Gorchon,1J. Curiale,1,2,3A. Cebers,4A. Lema ˆıtre,2N. Vernier,5M. Plapp,6and V . Jeudy1,7,*
1Laboratoire de Physique des Solides, Universit ´e Paris-Sud, CNRS, UMR 8502, F-91405 Orsay, France
2Laboratoire de Photonique et de Nanostructures, CNRS, UPR 20, F-91460 Marcoussis, France
3Consejo Nacional de Investigaciones Cient ´ıficas y T ´ecnicas, Centro At ´omico Bariloche-Comision Nacional de Energ ´ıa At ´omica,
Avenida Bustillo 9500, 8400 San Carlos de Bariloche, R ´ıo Negro, Argentina
4University of Latvia, Zellu-8, Riga LV-1002, Latvia
5Institut d’ ´Electronique Fondamentale, Universit ´e Paris-Sud, CNRS, UMR 8622, F-91405 Orsay, France
6Physique de la Mati `ere Condens ´ee, Ecole Polytechnique, CNRS, F-91128 Palaiseau, France
7Universit ´e Cergy-Pontoise, F-95000 Cergy-Pontoise, France
(Received 19 May 2015; published 25 August 2015)
The shape instability of magnetic domain walls under current is investigated in a ferromagnetic (Ga,Mn)(As,P)
film with perpendicular anisotropy. Domain wall motion is driven by the spin transfer torque mechanism. Acurrent density gradient is found either to stabilize domains with walls perpendicular to current lines or toproduce fingerlike patterns, depending on the domain wall motion direction. The instability mechanism is shownto result from the nonadiabatic contribution of the spin transfer torque mechanism.
DOI: 10.1103/PhysRevB.92.060411 PACS number(s): 72 .25.Dc,75.50.Pp,75.60.Ch,75.78.Fg
Interface instabilities are encountered in a great variety of
physical systems such as liquids [ 1], liquid-gas interfaces,
ferro- and ferrimagnetic films [ 2–4], electrically polarizable
and magnetic liquids [ 5–7], the intermediate state in type I
superconductors [ 8,9], etc. These instabilities originate from a
competition between the surface tension, which tends to favorflat interfaces, and a destabilizing interaction as a gradient ofexternal driving force (temperature, gravitational field, mag-netic field, etc.), or as long-range dipolar interactions [ 10,11]
for quasi-two-dimensional systems [ 12]. A crucial point for
understanding the interface dynamics as well as the formationof domain pattern is to determine the parameters controllingthe instabilities and their formation mechanism.
In ferromagnetic systems, it was shown recently that
domain walls (DWs) can be moved by a spin polarizedcurrent [ 13–16] through the so-called spin transfer torque
(STT) [ 17–20]. This has motivated an intense research
effort for elucidating the physics of STT and for potentialapplications in spin electronics [ 21,22]. The STT acts as a
driving force proportional to the current density. As expectedby analogy with the well-studied field-driven dynamics,essentially two dynamical regimes are observed. At lowdrive, DWs move in the pinning-dependent creep regime.Above a depinning threshold, the dynamics corresponds toflow regimes limited by dissipation [ 16]. Current-driven DW
dynamics is most generally studied in narrow tracks, whereDWs remain stable over the track width. However, field-and current-driven dynamics exhibit, in extended geometry,quite different behavior. A magnetic field acts essentially asa magnetic pressure pushing DWs with an average uniformvelocity. In contrast, the current-driven creep regime was foundto result in the formation of triangular domain shapes [ 23].
In the flow regime [ 24], the DW velocity was shown to
depend on the respective orientations of the DW and thecurrent flow. Those observations suggest a complex interplaybetween the DW shape and dynamics, and the STT magnitude.
*vincent.jeudy@u-psud.frIn this frame, it is particularly interesting to characterizethe shape stability of DWs driven by current. To addressthis issue, we investigated DW motion under current inwide geometries where instabilities induced by current and/ordipolar interactions can develop and be visualized. We useda (Ga,Mn)(As,P) thin film with perpendicular magnetizationdue to the extraordinary weak current density that is requiredfor DW motion, which gives us access to a wide range ofdynamical regimes [ 16,25]. To get a better understanding
of the role of current-induced motion on DW stability, weintroduce, on purpose, a progressive current density gradientby patterning our device in a semicircular geometry [ 26].
In this Rapid Communication, we show how the STT
mechanism affects the domain pattern and the DW shapestability. We found, in particular, that a current densitygradient, depending on the DW motion direction, stabilizes ordestabilizes the DW shape. A model, also taking into accountthe surface tension and dipolar interactions, grasps the mainfeatures of DW stability.
A5 0n mt h i c k( G a
0.95,Mn 0.05)(As 0.9,P0.1)fi l mw a sg r o w n
by low-temperature ( T=250◦C) molecular beam epitaxy
on a GaAs (001) substrate [ 25]. It was then annealed at
T=250◦C for 1 h. Its magnetic anisotropy is perpendicular
(saturation magnetization M=23±1k A/m) and its Curie
temperature Tcis 119 ±1 K. The semicircular geometry
(100μm radius) was patterned by electron beam lithography
and etching and then connected to a narrow (width w=2μm)
electrode at the straight edge center and to a semicircular elec-trode made of Ti (20 nm) /Au (200 nm) layers [see Fig. 1(a)].
The shape of the magnetic domains and of DWs is controlledby differential polar magneto-optical Kerr microscopy with a1μm resolution in a cryostat with a base temperature of 95 K
for all the experiments presented here [see Figs. 1(b)–1(d) ].
The two gray levels correspond to opposite magnetizationdirections perpendicular to the film. Due to the semicirculargeometry, the electrical current lines are radial. The currentdensity jdecays with the distance rfrom the narrow electrode
asj(r)≈I/πrh (Iis the injected current and h=50 nm
the film thickness) so that the absolute value of the gradient
1098-0121/2015/92(6)/060411(5) 060411-1 ©2015 American Physical SocietyRAPID COMMUNICATIONS
J. GORCHON et al. PHYSICAL REVIEW B 92, 060411(R) (2015)
FIG. 1. Current-induced modification of the magnetic domain
pattern. (a) Sample description. (b) Magnetic-field-driven domain
pattern corresponding to the initial magnetic state. (c), (d) Modifica-
tion of the domain pattern due to a dc current. The current flows fromthe narrow to the semicircular electrode ( j> 0) for 60 s. Its amplitude
was (c) I=2.16 mA and (d) I=2.98 mA. The domain pattern is
observed by magneto-optical Kerr microscopy. The two gray levels
reflect the two opposite magnetization directions perpendicular to the
(Ga,Mn)(As,P) film. T=95 K.
decreases progressively with ras|dj/dr |=|I|/(πhr2). In the
following, by convention, I>0 (i.e., j> 0) corresponds to a
current flow from the narrow to the semicircular electrode.
First evidences of domain wall shape instability are shown
in Fig. 2. A set of semiconcentric magnetic domains centered
on the narrow electrode [see Figs. 2(a)and2(e)] was prepared
using current-induced stochastic domain nucleation and DWpropagation (see Ref. [ 26] for details) starting from a uniform
magnetization state. Next, a dc current was injected betweenthe two electrodes for a fixed duration, after which an imagewas acquired. The sequence is repeated for Figs. 2(b)–2(d)
with increasing current (for 60 s at I=0.7, 1.1, and 1.2 mA)
and for Figs. 2(e)–2(g) with increasing duration (1 μs, 10μs,
and 100 μsa tI=−1.547 mA). The DW motion observed in
Figs. 2(b)–2(d) and2(e)–2(g) originates from the spin transfer
torque. In ferromagnets, the electrical current is spin polarizedand carriers crossing a DW exert a torque on the local magneticmoment, which results in DW propagation. In (Ga,Mn)(As,P)films with perpendicular anisotropy, DW motion is in theopposite direction to the current [ 16], as it can be observed. In
this experiment, different DW dynamical regimes are expectedto occur due to the decay of jwithr. Close to the narrow
electrode, the current density ( j≈I/hw =10–20 GA /m
2,
where w=2μm is the width of the narrow electrode) is
sufficiently large for the flow regime to be reached [ 16] while
pinning-dependent regimes are expected to occur in the otherparts of the device.
The most original of the results shown in Fig. 2is the
dependence of the shape of the domains on the current polarity.Forj> 0, the semicircular symmetry of the domains breaks.
In Fig. 2(b), the black domain next to the narrow electrode
expands toward the electrode by forming fingerlike shapes.
FIG. 2. (Color online) Instability of magnetic DW produced by
a gradient of current density. Left frames: Stability of a domain wall(dotted arcs) placed perpendicularly to a current density gradient.
A small tilt of an elementary wall length (blue segments) produces
an asymmetry of the forces due to spin transfer (thin black arrows).A current flow (thick green arrows) in the direction of the narrow
electrode ( j> 0, top frame) tends to destabilize the initial orientation
while it tends to be stabilized for j< 0 (bottom frame). (a)–(d)
DW shape instability for j> 0. (a) Initial state. (b)–(d) A 60 s dc
current flow produces a finger growth towards the narrow electrode.
Increasing the current magnitude [ I=0.70, 1.10, and 1.20 mA for
(b)–(d), respectively] enhances the distance at which the semicircular
DWs become unstable. (e)–(g) Stable radial DW growth for j< 0.
The sample that is initially in an homogeneous magnetic state issubmitted to a current pulse of amplitude −1.547 mA of increasing
duration [1 μs, 10μs, and 100 μs for (e)–(g), respectively]. The
propagation front remains almost semicircular. The weak anisotropyof magnetic domain growth is most probably associated with the
in-plane anisotropy of the (Ga,Mn)(As,P) single crystal. T=95 K.
As the current amplitude increases [Figs. 2(c) and 2(d)],
the instability process also takes place in domains locatedfarther away from the electrode. In contrast, for j< 0, the
semicircular geometry is conserved. The shape of the domainwalls is stable during the motion. We explain now, firstqualitatively, the contribution of the current density gradientto the domain wall stability. The left frames of Fig. 2give
a schematic description of this mechanism. Let us considera slightly tilted elementary DW segment. Due to the currentdensity gradient, the two segment ends experience a differentSTT amplitude. It is larger for the one closer to the narrowelectrode. This asymmetry is the driving mechanism for theDW stabilization or destabilization. When the jis negative, the
STT force points away from the narrow electrode and the DWsegment moves away from the electrode. However, the laggingsegment extremity experiences a stronger STT force than theopposite end, therefore acting as a restoring force. The DWremains stable during its motion. In turn, this mechanism isresponsible for the DW destabilization when j> 0 (opposite
DW motion direction) since the STT force is stronger forthe forward end. It eventually leads to domain growth alongthe current lines. This behavior shares similarities with theRayleigh-Taylor instability [ 1], when a heavier liquid is above
a lighter one.
This instability mechanism has dramatic consequences on
domain pattern formation up to very large radii and hence verylow DW velocities [see Figs. 1(b)–1(d) ]. Figure 1(b) shows
an initial demagnetized state (obtained before applying any
060411-2RAPID COMMUNICATIONS
CURRENT-INDUCED FINGERING INSTABILITY IN . . . PHYSICAL REVIEW B 92, 060411(R) (2015)
magnetic field or current). The magnetic domains with oppo-
site magnetization direction present a self-organized pattern,as usually observed in ferromagnetic films with perpendicularanisotropy. The typical domain width and spacing ( ≈10 and
≈20μm, respectively) results from a balance between the
positive DW energy and long-range magnetic interactionsbetween domains [ 27]. The domain shape corresponds to
randomly oriented corrugated lamellae.
After applying a positive dc current ( j> 0) for 60 s [see
Figs. 1(c) and1(d)], the domains tend to be aligned radially.
For the largest current value ( I=2.98 mA), the domain
pattern is modified over the full sample surface area, asobserved in Fig. 1(d). The DWs are aligned along the current
lines, a consequence of the gradient-induced destabilizationmechanism described earlier. We can get insight into theDW organization dynamics when injecting lower currentvalues. In that case, the domain pattern modification remainsspatially limited by a semicircular boundary centered onthe narrow electrode, as seen in Fig. 1(c) (I=2.16 mA).
Indeed, sufficiently far from the narrow electrode, DWsfollow dynamical regimes controlled by DW pinning andthermal activation. In those regimes, the DW velocity variesexponentially with the driving force. As the STT amplitudedecreases as |I|/r, the DW velocity considerably reduces
as it is located at a greater distance from the high currentdensity regions close to the narrow electrode. Therefore, for alimited current pulse duration (60 s), each given current valueIdefines a clear-cut semicircular boundary separating regions
with unmodified patterns (at a scale of the experimental spatialresolution ≈1μm) from regions presenting significant DW
displacements, as observed in Fig. 1(c).
At this point, we have shown how a current density gradient
can stabilize or destabilize a DW. However, we have notconsidered yet how this mechanism competes or cooperateswith the other mechanisms involved in DW stability, suchas dipolar interactions and the DW surface tension. To thatend, we extended the experiment described in Figs. 2(e)–2(h)
(I=−1.55 mA) to longer current pulses. As previously, the
sample was first prepared in a fully homogeneous magnetizedstate. Negative current pulses were injected for 10 ms, 690 ms,and 29.7 s durations. In this situation, the gradient acts asa stabilization contribution. For the shortest duration, thedomains present a semicircular shape [see Fig. 3(a)] that
reflects the current line symmetry, as already observed inFigs. 2(e)–2(h) . However, for the longest durations [see
Figs. 3(b) and3(c)], the semicircular shape of the domains
with the largest radius becomes unstable and fingerlike domaingrowth is observed. The finger width is close to the typicalsize of the domain patterns observed in the demagnetizedconfiguration [see Fig. 1(b)]. This behavior strongly points
toward dipolar interactions as the destabilization mechanism.For a different injected current I, the values of the critical
instability radius r
cat which the finger-shaped domains start
to grow were systematically deduced from images [such asthose presented in Figs. 3(a)–3(c)] obtained for a large set
of increasing pulse durations. As reported in Fig. 3(d),r
2
c
is found to vary linearly with I, i.e., the critical radius is
associated to a well-defined critical current density gradient|dj/dr |
c=|I|/(πhr2
c). Therefore, the DW shape instability
observed in Figs. 3(a)–3(c) occurs when the current density
FIG. 3. (Color online) Fingerlike magnetic domain growth re-
sulting from domain wall instability. The images were obtained for
a constant current ( I=−1.55 mA) directed towards the narrow
electrode ( j< 0) and for different durations [(a) 100 μs, (b) 690
ms, and (c) 29.7 s]. T=95 K. (d) Square of the critical instability
radius as a function of the bias current. The line corresponds to thebest fit of the theoretical prediction.
gradient becomes too weak to stabilize the DWs perpendicular
to current lines against the dipolar interactions.
To get more quantitative insight on the DW shape instabil-
ities, we have elaborated a model that describes the stabilitylimit of a flat DW subjected to an electrical current gradient.The model considers a ferromagnetic layer of thickness h,
aligned along the zdirection. A flat DW separating two
domains with opposite magnetization directions is parallelto the x-zplane. The DW is submitted to a current flow
exhibiting a gradient in the ydirection. The magnetization
vector is given as−→M=M(sinθcosϕ,sinθsinϕ,cosθ). In
the perturbed state, the DW position is given by the equationy=q(x,t). The DW shape stability analysis is based on the
Landau-Lifshitz-Gilbert equation and follows the calculationof Refs. [ 28,29]. The full calculation is detailed in the
Supplemental Material [ 30]. For a weakly perturbed DW, the
equations of motion are
γ/parenleftbigg
μ
0M+2ψ2M(q,h)
h/parenrightbigg
−2Aγ
M/Delta1∂2q
∂x2=˙ϕ−α˙q
/Delta1+βu
/Delta1(1)
and
μ0
2γMsin 2ϕ−2Aγ
M∂2ϕ
∂x2=−α˙ϕ+u
/Delta1−˙q
/Delta1, (2)
where γ,α, andβare the gyromagnetic factor, the Gilbert
damping parameter, and the so-called nonadiabatic term,respectively. /Delta1=√
A/K is the domain wall thickness param-
eter, where AandKare the spin stiffness and the anisotropy
constant, respectively. The parameter uis the spin drift velocity
defined by u=jPcgμB
2eM, where j,Pc,g,μB, and e(<0),
are the current density, the current spin polarization, theLand ´e factor, the Bohr magneton, and the electron charge,
respectively. In Eq. ( 1),ψ
2M(q,h) is a potential describing
060411-3RAPID COMMUNICATIONS
J. GORCHON et al. PHYSICAL REVIEW B 92, 060411(R) (2015)
the dipolar interaction between the DW magnetization and
the field created by the two magnetic domains with oppositemagnetization.
For a small perturbation δϕ,δq of the DW, the perturbation
of the spin drift velocity can be written as δu≈(du/dq )δq.
Assuming a steady DW motion ( ˙ ϕ=0) and looking for
solutions of the type δq∼δq
0exp(ikx), Eq. ( 1) leads to a
growth rate of the instability given by
d(δq0)
dt=μ0Mγ/Lambda12
αh2/bracketleftbigg
F+du
dqβ
μ0Mh2
γ/Lambda12/bracketrightbigg
δq0, (3)
where we have introduced the exchange length /Lambda1defined by
A=μ0M2/Lambda12/2, and the magnetic Bond number [ 31]Bm=
μ0(2M)2h/(4πσ) with the DW surface energy given by σ=
4√
AK.I nE q .( 3), the function Fis given by F=4Bm(γE+
log(kh/2)+K0(kh))−(kh)2, where K0(kh) is the McDonald
function and γE(=0.5772) is the Euler constant.
The differential equation ( 3) shows that a flat DW is
unstable [i.e., d(δq0)/dt > 0] if the term in brackets on the
right-hand side is positive. The instability thus results froma competition between the dipolar energy (the first terms offunction F), the DW surface tension [the term ( kh)
2inF], and
the STT gradient [ ∝du/dq in Eq. ( 3)]. One should note that
only the nonadiabiatic contribution ( ∝β) of the STT plays
a role in DW stability [ 30]. The fastest instability growth
rate corresponds to the function Fmaximum which is equal
toFmax=2Bmexp (1 −2γE−2/Bm) and to a wavelength
λ=πhexp (γE+1/Bm−1/2), in the limit of small kh.
For the semicircular geometry considered in this work, the
conservation of the current I=jπrh leads todu
dq=IPcgμB
πhr22|e|M.
For a current flow from the narrow electrode ( j> 0, i.e.,
du/dq > 0), the term in brackets in Eq. ( 3) remains positive
and the flat DW is always unstable. This corresponds to thecase presented in the top frames of Fig. 2for which both the
current density gradient and the dipolar interactions have adestabilizing contribution. For the opposite current direction(j< 0, i.e., du/dq < 0), the DW is only stable below a
critical radius given by r
2
c=IC
Fmax, where C=hβPcgμB
4πAγ|e|[see
Figs. 2(e)–2(g) and3(a)]. Above this critical radius, as the
stabilization contribution of the gradient becomes too weakto counteract the effect of dipolar interactions, the domainwall becomes unstable. This instability leads to the growth offingerlike domains, as observed in Figs. 3(b) and3(c).Comparing those predictions to the experimental results
requires the evaluation of the magnetic Bond number B
m. First,
Bmcan be estimated from the critical radius rc, measured in
Fig. 3(d). The data best fit gives a ratio r2
c/I=C/F max=
58±3μm2/mA. Assuming β=0.3[16],Pc=0.5,g=
2,μB=9.3×10−24JT−1,γ=1.76×1011Hz T−1, and
A=0.07±0.03 pJ/m[32], we have 1 /Fmax≈10 000 and
Bm≈0.25 [33].Bmcan also be deduced from the number n
of fingers observed in Figs. 3(b) and3(c). Indeed, assuming
nto remain constant after the onset of DW instability
(occurring for r=rc), the critical perturbation wavelength
readsλ=πrc/n, whose value was extracted from a statistical
analysis, λ=3±1μm. The prediction for λleads to Bm=
0.36±0.06, a value close to the previous estimation. Finally,
Bmcan also be estimated independently from micromagnetic
parameters (see Ref. [ 32]) since Bm=μ0(2M)2h/(4πσ) with
σ=4√
AK. The obtained Bond number equals 0 .3±0.1
and presents a good quantitative agreement with the twoprevious estimations. This unambiguously demonstrates thatthe domain wall fingering instability, observed for j< 0,
originates from a competition between the dipolar interactionsand the effect of the current gradient whose magnitude isshown to be proportional to the nonadiabatic contribution ofthe STT.
In conclusion, these results show that the domain wall
orientation with respect to a current flow is very sensitiveto current density gradients in current-induced DW motionexperiments. They unveil some potential weaknesses for futuredevices relying on complex circuits where these gradients areubiquitous, yet they also give us some interesting directions topropagate and manipulate DW over large surfaces, by takingadvantage of the gradient-controlled stability.
The authors wish to thank J. Miltat for his careful reading
of the manuscript and A. Thiaville for usefull discussions.This work was partly supported by the French projects DIMC’Nano IdF (R ´egion Ile-de-France), ANR-MANGAS (No.
2010-BLANC-0424), RTRA Triangle de la Physique GrantsNo. 2010-033TSeMicMagII and No. 2012-016T InStrucMagand the LabEx NanoSaclay, by the Argentinian project PICT2012-2995 from ANPCyT and UNCuyo Grant No. 06/C427,and by the French-Argentina project ECOS-Sud No. A12E03.This work was also partly supported by the French RENAT-ECH network.
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060411-5 |
PhysRevB.98.134450.pdf | PHYSICAL REVIEW B 98, 134450 (2018)
Nonabelian magnonics in antiferromagnets
Matthew W. Daniels,1,*Ran Cheng,1,2Weichao Yu ( /ZdZ1157/ZdZ1099/ZdZ17073),3Jiang Xiao ( /ZdZ14675/ZdZ8587),3,4,5and Di Xiao1
1Department of Physics, Carnegie Mellon University, Pittsburgh, Pennsylvania 15213, USA
2Department of Electrical and Computer Engineering, Carnegie Mellon University, Pittsburgh, Pennsylvania 15213, USA
3Department of Physics and State Key Laboratory of Surface Physics, Fudan University, Shanghai 200433, China
4Collaborative Innovation Center of Advanced Microstructures, Nanjing 210093, China
5Institute for Nanoelectronics Devices and Quantum Computing, Fudan University, Shanghai 200433, China
(Received 24 January 2018; revised manuscript received 13 August 2018; published 31 October 2018)
We present a semiclassical formalism for antiferromagnetic (AFM) magnonics which promotes the central
ingredient of spin wave chirality , encoded in a quantity called magnonic isospin, to a first-class citizen of
the theory. We use this formalism to unify results of interest from the field under a single chirality-centricformulation. Our main result is that the isospin is governed by unitary time evolution, through a Hamiltonianprojected down from the full spin wave dynamics. Because isospin is SU(2) valued, its dynamics on the Blochsphere are precisely rotations, which, in general, do not commute. Consequently, the induced group of operationson AFM spin waves is nonabelian. This is a paradigmatic departure from ferromagnetic magnonics, whichoperates purely within the abelian group generated by spin wave phase and amplitude. Our investigation ofthis nonabelian magnonics in AFM insulators focuses on studying several simple gate operations, and offeringin broad strokes a program of study for interesting new logic families in antiferromagnetic spin wave systems.
DOI: 10.1103/PhysRevB.98.134450
I. INTRODUCTION
Recent years have seen a surge of interest in the generation
and in-flight manipulation of magnons in antiferromagnets(AFMs). We now know that AFM magnons can couple to theangular momentum carried by electrons [ 1,2], photons [ 3–5],
and other spin carriers. Detection of magnon-mediated spinsignals from AFM insulators, typically measured through theinverse spin Hall effect, has also matured to the point ofexperimental implementation [ 6–8]. It has been shown that
AFM spin waves possess pointed dynamical distinctions fromtheir ferromagnetic (FM) counterpart [ 9–11], especially in the
presence of spin texture [ 12–17] or broken inversion symme-
try [ 11,12,18,19]. In particular, collinear AFMs possess two
degenerate spin wave eigenmodes of opposite chirality [ 20].
They are often referred to as right- and left-handed modes,according to the precessional handedness of the Néel vector(Fig. 1). This notion of spin wave chirality has proved to be a
useful narrative tool for understanding how AFM magnonicsdiffers from the ferromagnetic (FM) case.
As a patchwork of novel results begins to populate the
field of AFM magnonics, a coherent framework for under-standing their similarities, differences, and possible exten-sions becomes necessary. Our central thesis is that manyof these results can be understood in terms of spin wavechirality, through a spinor [SU(2)-valued] quantity we referto as the magnon isospin . One important corollary of this
formulation is that, because isospin dynamics proceeds byintrinsically noncommutative unitary rotations on the Blochsphere, implementations of magnonic computing in AFMs
*Corresponding author: danielsmw@protonmail.comwill in general be nonabelian. This fundamental departurefrom the behavior of FM magnonics calls for a seriousreinvestigation of primitive magnonic operations for AFMs;working only off analogies to extant ferromagnetic propos-als is a program restricted by commutativity, and inevitablylifts only into a small subset of available AFM computingschemes.
One practical disadvantage of FM magnonics has been
the need to constantly refresh the signal power in a device.This is particularly problematic in interferometric [ 21,22]
spin wave logic, where the Boolean output of FM magnoniclogic gates is encoded by setting a threshold amplitudefor the spin wave power. Phase interference techniques arethen used to achieve the desired magnon amplitude. Sincehalf of the desired outputs are represented by suppressingthe power spectrum of the magnon signal, this scheme in-curs significant energy inefficiencies and requires sources ofpower to constantly refresh the signal [ 23]. Isospin com-
puting resolves this problem neatly since we can encodeand manipulate data in the spin wave chirality rather thanthe spin wave amplitude. This improvement is reminis-cent of proposals for polarization-based optical computingschemes from the 1980’s [ 24]. A chief practical distinction
between AFM isospin computing and optical computing isthat the former can be carried out in nanoscale solid-statesystems.
Given the importance of the isospin in AFM magnonics,
we consider in this paper its dynamics for a broad class ofinteractions that may manifest in AFMs, and offer an exten-sible formalism by which others can easily incorporate theeffects of new physical interactions. In the development of thisformalism, we find that there are notable differences betweenbipartite and synthetic AFMs, and we discuss the advantages
2469-9950/2018/98(13)/134450(19) 134450-1 ©2018 American Physical SocietyDANIELS, CHENG, YU, XIAO, AND XIAO PHYSICAL REVIEW B 98, 134450 (2018)
SA
SB−
Right-HandedSA
SB+
Left-Handed
FIG. 1. Schematic representations of right- and left-handed
modes. Red and blue arrows demonstrate the spin precession on each
of the two sublattices. Because the ˆSzcomponents differ between the
sublattices during a spin wave precession, each eigenmode carries an
opposite sign of spin angular momentum.
and disadvantages of pursuing nonabelian magnonics in these
two types of systems. We then apply this formalism to anumber of examples, for the threefold purposes of illustratingits use, validating it against a set of known results, andgenerating results in a few interesting systems.
With several concrete results in hand, we then propose in
broad strokes a program of next-generation computing basedon nonabelian magnonics [ 25]. Although FM magnonics has
been studied extensively [ 21,22,26,27], we show that the
comparative richness of the AFM isospin offers dramaticallymore and different avenues for progress. The fact that isospinmanipulations do not commute offers, by purely algebraicconsiderations, a more bountiful landscape for compositionof logical operations than can be found in FMs.
We emphasize that the dual-sublattice nature of AFMs
does not merely amount to two copies of FM magnon sys-
tems. Although one may be able to import FM magnonicschemes into the AFM architecture, one could also lookto more spinful classes of physics for inspiration in appli-cation. Spintronic [ 11] and optical [ 12] analogies to AFM
magnonics have proved inspiring for novel device designs.We close by offering possibilities for future research in thisdirection.
II. FORMALISM
In this section, we review the AFM spin wave theory in the
sublattice formalism, as we expect many of our readers aremore familiar with the staggered-order-centric approach. Webegin by exploring spin wave chirality in a minimal model: acollinear AFM with easy axis anisotropy. The description ofeasy-axis AFMs such as MnF
2, FeF 2,o rC r 2O3may follow
from such a model. Using this familiar context, we reviewchirality and the way in which it encodes spin carried bythe magnon excitation. We then review a common formalismfor handling spin texture and introduce the texture-inducedgauge fields. Finally, we derive the spin wave equations ofmotion in the sublattice formalism by the variational principle.These subsections set the stage for our main results, which arepresented in the next section.
A. Sublattice-centric magnonics
In terms of the two sublattices, the free energy
of an easy-axis collinear AFM in the continuum limitis
F=Fexch+FEAA, (1a)
Fexch=1
2/integraldisplay
ZmA·mB−J∇mA·∇mBddx,(1b)
FEAA=−K
2/integraldisplay
(mA·ˆz)2+(mB·ˆz)2ddx. (1c)
Here, Kis the easy-axis anisotropy (EAA), while ZandJ
are the so-called homogeneous and inhomogeneous exchangeinteractions, respectively [ 28]. They have been chosen so that,
under the change of variables
m=m
A+mB
2and n=mA−mB
2, (2)
the exchange free-energy density becomes [ 29]
Fexch=Z|m|2+J
2|∇n|2+O(|m|4). (3)
The quantities mandnare the local magnetization and
the staggered order [ 30]. We have written in Eq. ( 1) a free
energy for the classic g-type antiferromagnet, but merely as a
convenient concretization. Our main result generalizes to anykind of collinear AFM order, and in particular we use resultsfor synthetic AFMs later in the paper.
On each sublattice of the AFM, the semiclassical spin
dynamics is governed by the Landau-Lifshitz equation
˙m
A=mA×1
SδF
δmA, (4a)
˙mB=mB×1
SδF
δmB, (4b)
where Fis the free-energy functional and S=s¯hthe spin
magnitude on a lattice site. Define ˆzas the easy-axis direction,
and take the Néel ground state as mA=ˆzandmB=− ˆz.
Spin wave fluctuations, at linear order in the cone angle bywhich precessing spins cant away from the ground state,reside entirely in the xyplane [ 31]. It is convenient to rewrite
fluctuations from equilibrium as α
±=(mx
A±imy
A)/√
2 and
β±=(mx
B±imy
B)/√
2. We will treat these four quantities
as independent variables [ 32]. Collecting the equations of
motion for this new basis [ 33] into matrix form, the spin wave
equations for /Psi1=(α+,β+,α−,β−)a r e
i(τz⊗σz)˙/Psi1=/parenleftbiggˆh 0
0 ˆh∗/parenrightbigg
/Psi1=H/Psi1, (5)
where τjare the Pauli matrices in isospin space and σjthe
Pauli matrices in the sublattice subspace. In other words, theσ
jmatrices distinguish α+fromβ+andα−fromβ−, while
τjdistinguish from α+fromα−andβ+fromβ−. Our use of
the term “isospin” will be introduced more fully at the end ofthis section. For the problem we outlined above, ˆhis a 2×2
Hermitian operator given by
ˆh=
1
2[(Z+2K)12+σx(Z+J∇2)]. (6)
For the simple free energy we have adopted in Eq. ( 1),
Eq. ( 5) apparently contains two copies of the same two-
level dynamics. These two copies are related by complexconjugation, which we write as the time-reversal operator T.
134450-2NONABELIAN MAGNONICS IN ANTIFERROMAGNETS PHYSICAL REVIEW B 98, 134450 (2018)
The mapping of the Landau-Lifshitz-Gilbert (LLG) equation
onto a Schrödinger equation is standard practice in theoreticalmagnonics [ 34,35], but note that our Eq. ( 5) differs from
the usual Schrödinger equation by the appearance of τ
z⊗σz
on the left-hand side. The mathematical and philosophical
details of Schrödinger equations with this structure have beenconsidered at length in Ref. [ 36].
Since the Hamiltonian ( 5) is block diagonal, let us first
focus on the subspace governing α
+andβ+. Assuming our
system is stationary and translationally invariant, we can makethe ansatz ψ=ψ
0ei(k·x−ωt). The resulting eigenproblem is
¯hωσ zψ=ˆhψ. (7)
For a generic 2 ×2 Hermitian operator ˆh=a12+bσx+
cσy+dσz,E q .( 7) has the solution [ 18]
ψ0=/parenleftBigg
coshϑ
2
−eiϕsinhϑ
2/parenrightBigg
andψ1=/parenleftBigg
−sinhϑ
2
eiϕcoshϑ
2/parenrightBigg
, (8)
where the angles ϑandϕare given through
a=/lscriptcoshϑ, (9a)
b=/lscriptsinhϑcosϕ, (9b)
andc=/lscriptsinhϑsinϕ. (9c)
The corresponding eigenvalues are
¯hω=± (d+/lscript)=±1
S/radicalbigg
1
2JZk2+ZK (10)
at leading order in K. The well-known resonant energy is
given then by ¯ hω0=√
ZK/S .
We note that the bosonic normalization condi-
tion [ 18,37,38]a2−b2−c2=± 1 implies that the space
of Hamiltonians, as well as the eigenvectors themselves, liveon the hyperboloid of two sheets SU(1,1). When d=0, as
in Eq. ( 6), the eigenvectors have particle-hole symmetry.
ψ
jexhibits eigenfrequency ( −)j|ω|. Analysis of the basis
functions shows that ψ0is a right-handed precession of mA
(and therefore n) while ψ1is a left-handed precession. We
say that they have opposite chirality, namely, right-handedand left-handed chirality.
Notice that the sister eigenproblem (for α
−andβ−)i nt h e
lower two rows of Eq. ( 5) has positive frequency solutions
corresponding to left-handed modes and negative frequencysolutions corresponding to right-handed modes. This inver-sion from the {α
+,β+}problem arises precisely due to the
conjugate basis. We will take the positive-energy solutionfrom each block,
/Psi1
0=⎛
⎜⎜⎝coshϑ
2
−eiϕsinhϑ
2
0
0⎞
⎟⎟⎠and/Psi11=⎛
⎜⎜⎝0
0
−sinhϑ
2
eiϕcoshϑ
2⎞
⎟⎟⎠,(11)
as a chirally complete basis for the positive energy, de-
generate Hilbert subspace of Eq. ( 5). Note that whereas
the solutions ( 8) obey /angbracketleftψi|σz|ψj/angbracketright=(−)jδij, the solutions
/angbracketleft/Psi1i|τz⊗σz|/Psi1j/angbracketright=δijare properly normalizable. We will of-
ten work directly in the /Psi10and/Psi11basis, writing |0/angbracketright=(1,0)
and|1/angbracketright=(0,1) as in Fig. 2. The use of bra-ket notation here
FIG. 2. Linear combinations of the right- and left-handed modes
|0/angbracketright∼=/Psi10and|1/angbracketright∼=/Psi11, respectively, produce an entire Bloch
sphere’s worth of possible isospin states. We have labeled selected
states by the polarization of the Néel order fluctuations in that state.
Right- and left-handed modes correspond to right- and left-handedprecession of n, while equal linear combinations produce linearly
polarized waves. The angle of linear polarization depends on the
relative phase of the spin waves between the sites. Note that X-a n d
Y-polarized states are orthogonal here, while in a traditional quantum
spin space |X/angbracketrightis orthogonal to |−X/angbracketright, not|Y/angbracketright. Since our formalism
parametrizes this space in terms of a two-level spinor, we refer to
it as a Bloch sphere. Students of optics, however, will recognize
that it is analogous to the Poincaré sphere that parametrizes opticalpolarization states.
is a formalism of convenience arising from the close math-
ematical similarities between our system and single-particlequantum mechanics. However, we emphasize early on thatthis is a purely notational convenience; it is impossible to re-alize many-body quantum phenomena, such as entanglement,in a purely semiclassical magnonic system.
Since cosh x> sinhxfor all real x, the magnitude of the
spin wave precession is clearly dominated by the Asublattice
in/Psi1
0and the Bsublattice in /Psi11. The physical spin fluctua-
tions can be recovered by taking mx
A=Re[(α++α−)/√
2],
my
A=Re[(α+−α−)/√
2i], and likewise with the Bsublat-
tice, so that
δm(0)
A=1√
2(cos(ωt),sin(ωt))coshϑ
2, (12a)
δm(0)
B=−1√
2(cos(ωt−ϕ),sin(ωt−ϕ))sinhϑ
2,(12b)
δm(1)
A=−1√
2(cos(ωt),−sin(ωt))sinhϑ
2, (12c)
δm(1)
B=1√
2(cos(ωt−ϕ),−sin(ωt−ϕ))coshϑ
2.(12d)
We see in Eqs. ( 12) that the right-handed modes dominate on
theAsublattice, as in Fig. 1. One can also see from Fig. 1
that these two modes carry opposite magnetization since the
ˆSzcomponent of the sublattices must differ if one of the
sublattices dominates. The reduction of magnetization on each
134450-3DANIELS, CHENG, YU, XIAO, AND XIAO PHYSICAL REVIEW B 98, 134450 (2018)
sublattice is simply given by the squared magnitude of the
lattice spin wave, so that the total magnetization induced by aspin wave is
m
z=−S/angbracketleft/Psi1|(12⊗σz)|/Psi1/angbracketright, (13)
which will be negative for right-handed waves proportional to
/Psi10and positive for left-handed waves proportional to /Psi11.T h i s
operator 12⊗σzcorresponds to a so-called nongeometric
symmetry [ 39]. It has sometimes been given as the definition
of spin wave chirality. In electromagnetic analogies for AFMspin wave dynamics it corresponds to optical helicity [ 39],
where the corresponding conserved quantity is the so-calledzilch [ 40].
So far, we have dealt only with a block-diagonal Hamil-
tonian. Restricting to the positive energy subspace, we seethatHhas no off-diagonal terms that connect /Psi1
0and/Psi11.
If such terms existed, we could manipulate the total spincarried by the spin wave in transit, rotating our spin wave statewithin the degenerate eigensubspace. We may imagine thatthe coefficients balancing these eigenvectors in a superposi-tion|η/angbracketright=η
0|0/angbracketright+η1|1/angbracketrightdefine a degree of freedom which we
refer to as the magnonic isospin [ 41].The desire to exploit
this internal degree of freedom motivates the remainder of thepaper .
B. Spin texture, characteristic length scales,
and perturbative parameters
In order to control η, we must find a way to break the
degeneracy between the right- and left-handed modes; thatis, we must break whatever symmetries are protecting eitherconservation of chirality (that is, the block diagonality of H)
or conservation of the relative phase between right- and left-handed modes. In this paper, the main tools we consider forthis purpose are spin texture and the Dzyaloshinskii-Moriyainteraction (DMI). The latter is well known and we introducethe appropriate free energies when they are needed. Spin tex-ture, however, is somewhat more subtle, so we briefly reviewtheoretical tools for handling it. These techniques have beenused to great success in describing transport effects arisingfrom both ferromagnetic [ 34,35,42,43] and antiferromagnetic
[44–46]t e x t u r e s .
To describe the spin texture in our formalism, we encode
the texture in a rotation matrix Rdefined by Rn=|n|ˆz.T h i s
rotation matrix induces a generator of infinitesimal spin rota-tions ( ∂
μR)RT, which itself can be regarded as a collection
of vector potentials Ax
μJx+Ay
μJy+Az
μJz=(∂μR)RT,t h e
decomposition being directed through the standard generators[47] of three-dimensional (3D) rotations J
j. Here, μis a
spacetime index, and the components Aj
μdefine the (1 +d)-
vectors Aj=(Aj
t,Aj).
Because our spin texture is described with respect to the
ˆzaxis, Azwill be of paramount importance. It gives rise
to an emergent magnetic field B=∇×Azthat produces a
Lorentz force on magnons in Eqs. ( 27), and the temporal
component Az
tlikewise produces an emergent electric field.
We will usually describe the influence of the other two po-tentials through the complex variable A
μ=(Ax
μ+iAy
μ)/√
2.
For more information on these fields, the reader is referredto Appendix B. For a full discussion of this gauge fieldformalism in the treatment of spin texture, the reader may
check Refs. [ 34,35].
We will soon need an approximation scheme to deal with
the many perturbative effects (anisotropy, DMI, etc.) of our
spin wave system. Since Aj
μis a derivative of the texture-
defining angles, let it define a characteristic length scale λof
the system,
/vextendsingle/vextendsingleAj
μ/vextendsingle/vextendsingle∼1
λ. (14)
In textured systems with DMI, the characteristic length scale
is proportional [ 48]t oJ/D , where Dis the DMI strength [ 49]
FDMI=DmA·(∇×mB). Therefore [ 50],
D/J∼/vextendsingle/vextendsingleAj
μ/vextendsingle/vextendsingle. (15)
In systems with easy-axis anisotropy, meanwhile, the well-
known characteristic length of a domain wall is√J/K , and
thus
K/J∼/vextendsingle/vextendsingleAj
μ/vextendsingle/vextendsingle2. (16)
Finally, the local magnetization [ 51]μ=(Rm)·(ˆx+
iˆy)/√
2 scales as a derivative of the staggered order, [ 28]
μ∼/vextendsingle/vextendsingleAj
μ/vextendsingle/vextendsingle. (17)
As it happens, the magnetization will, in our calculations,
never show up as a lone linear-order term; even so, thequadratic terms O(μ
2)=O(K/J ) must be preserved.
We have established a hierarchy of perturbative orders
based on a single parameter |A|. In our spin wave treatment,
we will keep terms up to order ∂A∼O(A2), that is, to linear
order in the emergent electromagnetic field B=∇×Az.
C. Matrix structure of the spin wave Hamiltonian
Once we add extra terms to the free energy (spin texture,
the Dzyaloshinskii-Moriya interaction, and so on) the equa-tion of motion becomes
i(τ
z⊗σz)˙/Psi1=/epsilon1d
nSδF
δ¯/Psi1−Az
t(12⊗σz)/Psi1 (18)
so that the spin wave Hamiltonian is given through H/Psi1=
δF/δ ¯/Psi1. Here, /epsilon1is the lattice constant, dis the dimensionality
of the lattice, and n=1+|μ|2is the effective index of
refraction for the spin wave speed, when viewed from theperspective of the wave equation governing staggered orderdynamics. Equation ( 18) prescribes the correct harmonic spin
wave theory for any free energy F, where the independent
variables {α
+,β+,α−,β−}are now defined as the purely in-
plane fluctuations of the sublattice spin wave modes after the
active rotation by Rof the ground-state texture. The detailed
derivation of Eq. ( 18) is given in Appendix A.
For concreteness, we now present the detailed matrix form
of the exchange interaction Hamiltonian. Beginning fromEq. ( 1b), we rotate the fields by Rand change variables to
the in-plane complex fluctuations α
+,β+,α−, andβ−.T h e
corresponding Hamiltonian for the homogeneous exchange
134450-4NONABELIAN MAGNONICS IN ANTIFERROMAGNETS PHYSICAL REVIEW B 98, 134450 (2018)
interaction is
Hhom=Z
2⎛
⎜⎜⎜⎝1−3|μ|21−|μ|2μ2−μ2
1−|μ|21−3|μ|2−μ2μ2
¯μ2−¯μ21−3|μ|21−|μ|2
−¯μ2¯μ21−|μ|21−3|μ|2⎞
⎟⎟⎟⎠, (19)
where the bar over ¯ μ(and, later, over ¯A) indicates complex conjugation. The inhomogeneous exchange interaction H
inhom ,
meanwhile, is given by J/(2n) times the matrix
⎛
⎜⎜⎜⎝−2|A|2(∇−iAz)2+/Delta1·∇−|A|20 −(μ∇)2+4iμA·∇+A2
(∇−iAz)2−/Delta1·∇−|A|2−2|A|2−(μ∇)2−4iμA·∇+A20
0 −(¯μ∇)2+4i¯μ¯A·∇+¯A2−2|A|2(∇+iAz)2+/Delta1·∇−|A|2
−(¯μ∇)2−4i¯μ¯A·∇+¯A20( ∇+iAz)2−/Delta1·∇−|A|2−2|A|2⎞
⎟⎟⎟⎠,
(20)
where /Delta1=2i(¯μA−μ¯A). These matrix Hamiltonians, and
the Hamiltonians corresponding to any other two-site inter-action, exhibit notable structural differences when the syn-thetic AFM case is considered instead. In the SupplementalMaterial, we have provided a Mathematica notebook that
automates the derivation of Hfor any free energy given
in terms of m
AandmB[52]. It also contains precomputed
Hamiltonians for anisotropy, DMI, external fields, and so on,which we use in our applied examples later in the paper.
III. NONABELIAN WA VE-PACKET THEORY
In this section, motivated by the need to derive ηdynamics
from Eq. ( 18) in the case of spatial inhomogeneity, we apply
the machinery of nonabelian wave-packet theory [ 53]. What
we call “wave-packet theory” was originally developed ina paper by Chang and Niu [ 54] to explain the Hofstadter
butterfly spectrum, after which their treatment was codifiedby Ref. [ 55]. Since then, the theory has been applied in a
variety of contexts, sometimes requiring extensions of thetheory to account for unique features of a particular physicalproblem [ 56–58].
The most relevant extension for our purposes, and indeed,
one of the most ambitious and interesting developments inwave-packet theory, is the treatment of multiple degeneratebands [ 53,59]. In this case, the theory is called nonabelian
wave-packet theory because, in dealing with a vector of mul-
tiple band energies at once, the “coefficients” must becomematrix valued (and therefore, generally speaking, an elementof a nonabelian matrix representation) in order to act on themultiband wave function. In this paper, we extend the non-abelian wave-packet theory to account for both the unusualτ
z⊗σzfactor in our Lagrangian and our explicitly ap r i o r i
nonabelian gauge field [ 60]. A detailed derivation involving
the internal workings of wave-packet theory is crucial forestablishing our main results. Since details of wave-packettheory, even in the abelian case, are not widely studied, wecarefully guide the interested reader through the derivation inAppendix D.
The basic idea of abelian wave-packet theory is to con-
sider a momentum-space superposition |W/angbracketright=/integraltext
w
qψqddq
of eigenvectors, where the eigenvectors are drawn from thespectrum of the Hamiltonian evaluated at some ( xc,qc)o n
a classical phase space. In nonabelian wave-packet theory,the eigenvector is expressed as a general state lying in thedegenerate subspace spanned by our right- and left-handedmodes
|W(x
c,kc)/angbracketright
=/integraldisplay
dqw(q,t)[η0(q,t)|/Psi10(q,t)/angbracketright+η1(q,t)|/Psi11(q,t)/angbracketright].
(21)
The coefficient wgives the shape of the wave packet, as in
Fig. 3. The vector |η/angbracketright=(η0,η1) is, again, called the isospin .
We demand that the otherwise generic wave packet possess
(1) a momentum space distribution localized enough to be
approximated as δ(q−qc),
(2) a well-defined mean position xc=/angbracketleftW|ˆx|W/angbracketright, and
(3) sufficient spatial localization that the environment
where the wave packet has appreciable support is approxi-mately translationally invariant.
These assumptions form a set of sufficient conditions under
which a wave function’s semiclassical dynamics can be for-mulated, using wave-packet theory, on a classical phase space/Gamma1/owner(x
c,qc). The nonabelian version, Eq. ( D13), includes an
η-valued fiber over /Gamma1.
By appealing to the time-dependent variational principle,
we can write the Lagrangian which generates the equation ofmotion ( 18), namely, L
WP=/angbracketleft/Psi1|L|/Psi1/angbracketrightwith
L=i(τz⊗σz)d
dt−H−Az
tσz. (22)
We then assume |W/angbracketrightas the solution for |/Psi1/angbracketright. Since the wave
packet is sufficiently [ 61] described by the 3-tuple ( xc,qc,η),
we can reduce LWPto a Lagrangian of the phase-space
variables xc,qc, andηthat specify |W/angbracketright. The result is
LWP=Ldt+LH+LEM,where (23a)
Ldt=/angbracketleft˜η|˙xc·ˆax+˙qc·ˆaq+ˆat+i∂t|˜η/angbracketright−˙qc·xc,(23b)
LH=− /angbracketleftη|H|η/angbracketright, (23c)
LEM=− ˙Az·/Gamma1q−χ/parenleftbig˙Az·xc+Az
t/parenrightbig
. (23d)
134450-5DANIELS, CHENG, YU, XIAO, AND XIAO PHYSICAL REVIEW B 98, 134450 (2018)
FIG. 3. Under the assumptions of wave-packet theory, the magnon wave packet has its magnitude w(q,t) strongly localized in real and
momentum space. Consequently, the wave function is sufficiently specified by its mean coordinates ( xc,kc) on phase space. The wave-packet
theory machinery uses this assumption to resolve the wave theory (left) described by Eq. ( 18) into a particle theory (right) described by the
classical Lagrangian ( 23). Not pictured is the isospin degree of freedom, which lives in an SU(2) fiber over the classical phase space. The full
semiclassical dynamics described by Eqs. ( 27) occurs on the induced fiber bundle.
Ldt,LH, andLEMderive from the time derivative, Hamilto-
nian, and emergent field terms from Eq. ( 22), respectively.
Here in the main text, we simply pause to describe the variousphysical variables in Eqs. ( 23) that fall out of the derivation.
First, let us define the 4 ×2m a t r i x
E=|0/angbracketright/angbracketleft/Psi1
0|+| 1/angbracketright/angbracketleft/Psi11|, (24)
where |0/angbracketrightand|1/angbracketrightare understood as the basis vectors (1,0)
and (0,1) for the isospin |η/angbracketright=η0|0/angbracketright+η1|1/angbracketright.Eis essentially
a change of basis matrix (which chooses /Psi10and/Psi11as
the canonical basis vectors), followed by a projection to theforward-time degenerate Hilbert subspace that they span. E
†
represents the embedding of the isospin dynamics into the
full spin wave dynamics, and as such the induced isospinHamiltonian is given by
H=EHE
†. (25)
Next, we define the various 2 ×2 matrices ˆaμ. These are the
matrix-valued Berry connections in isospin space
ˆaij
μ=/angbracketleftbig
/Psi1i
q/vextendsingle/vextendsingleiσz∂μ/Psi1j
q/angbracketrightbig
. (26)
These diagonal matrices will generate Berry curvatures (ef-
fective, emergent magnetic fields) in the equations of mo-tion [ 53]. The term /Gamma1
q=/angbracketleftη|τzˆaq|η/angbracketright−/angbracketleftη|τz|η/angbracketright/angbracketleftη|ˆaq|η/angbracketrightarises
uniquely due to the τz⊗σzmetric structure of our full four-
dimensional Hilbert space, and is absent from existing non-abelian wave-packet theories which deal only with Euclideanspaces. It gives rise to a nonlinear potential V
χ=δ/Gamma1q/δη.
Finally, the tilde decoration on ˜η=Gηrefers to a gauge trans-
formation G=exp[−i(τz⊗12)Az·x] discussed in Eq. ( D9).
Hamilton’s principle δS=0 gives us equations of motion for
the dynamical variables:
˙qc=χ(E+˙xc×B)−∂E
∂xc, (27a)
˙xc=∂E
∂qc+/angbracketleft/Omega1qq/angbracketright˙qc+/angbracketleft/Omega1qx/angbracketright˙xc+/angbracketleft/Omega1qt/angbracketright,(27b)
id
dtη=/bracketleftbig
H−At+τzAz
t+ˆVχ/bracketrightbig
η, (27c)
with At=˙xc·ˆax+˙qc·ˆaq+ˆat,Ethe linearly perturbed spin
wave energy (as in Ref. [ 53]), and /Omega1are the various Berrycurvature terms
/angbracketleftbig
/Omega1αβ
μν/angbracketrightbig
=/angbracketleftη|/parenleftbigg∂ˆaβν
∂αμ−∂ˆaαμ
∂βν/parenrightbigg
|η/angbracketright. (28)
Finally, the emergent electromagnetic fields are B=∇×Az
andE=∇Az
t, familiar to those who have studied magnetic
skyrmion physics [ 35,62].
The reduction of LWPto single-particle Lagrangian ( 23)i s
quite technical, and we relegate the derivation to Appendix D.
The process is illustrated schematically in Fig. 3. The equa-
tions of motion ( 27), as well as their derivation, are tightly
related to the results of Ref. [ 53]. The differences arise due
to the non-Euclidean metric τz⊗σzin the Lagrangian. This
geometry gives rise to the dynamical charge χ=/angbracketleftη|τz|η/angbracketright
coupled to the Lorentz force, and also gives rise to thenonlinear potential V
χ(through /Gamma1q).
Although Vχcan contribute at O(A2) in perturbation the-
ory in principle, it only contributes at third order or abovefor the interactions we consider concretely in this paper. Tocontribute in our formalism, it would require that ˆa
qmanifest
at leading order in the perturbation theory, or else that we goto higher order in the perturbation theory, as a nonabelianand non-Euclidean extension of second-order wave-packettheory [ 63,64]. If such a system could be identified, then the
physics of V
χ, which induces a Gross-Pitaevskii equation for
the isospin, could be quite interesting. In the coupling betweena wave packet and a rigid soliton, for instance, we see thatthis term produces at leading order a force proportional to ˙ χ.
Thus, a change in the spin carried by the magnon produces areal-space force on the soliton. We leave the search for sys-tems in which V
χcould produce significant effects to future
research.
Finally, let us caution the reader that Eq. ( 27c)g i v e st h e
dynamics of the isospin, which is defined with respect totheAandBsublattices, not with the laboratory frame. A
right-handed mode, for instance, is by our definition alwaysdominated by the Asublattice, which means that it carries
opposite spin on either side of a domain wall. To return tothe laboratory frame, one should apply the inverse rotationoperator R
−1to the spin texture. To extract the laboratory-
frame spin, then, lift R−1to SU(2) by the standard homomor-
phism [ 65] and apply it to the isospin. The (semiclassical) spin
134450-6NONABELIAN MAGNONICS IN ANTIFERROMAGNETS PHYSICAL REVIEW B 98, 134450 (2018)
z
x yVG=⇒expiπτz
2j = eiζDj
FIG. 4. The system under investigation in Sec. IV A . An in-plane easy-axis ( ˆz) AFM is oriented in a nanostrip geometry, perpendicular to
the easy axis ( ˆx). A section of the sample is subjected to a gate voltage VGapplied normal to the sample plane, in the ˆydirection. We show
in Eq. ( 32) that the resulting isospin dynamics corresponds to a rotation about σzon the Bloch sphere (Fig. 2). We define here the notation
Dj=diag(1 ,eiπ/2j), and is given by this applied DMI gate up to a dynamical phase eiζ. Note, as a reference, that τz=D0.
carried at time tby the magnon with isospin η(t) is then [ 66]
|s(t)/angbracketright=/parenleftBigg
ei(ψ+φ)cosθ
2ei(ψ−φ)sinθ
2
−e−i(ψ−φ)sinθ
2e−i(ψ+φ)cosθ
2/parenrightBigg
|η(t)/angbracketright,(29)
where the Euler angles defining the texture are evaluated at
xc(t). The observable magnetization carried by the isospin
is then mz=− /angbracketleft s|σz|s/angbracketright, the sign arising from the fact that
right-handed waves |0/angbracketrightcarry negative spin. Since we are
generally interested in systems with easy-axis anisotropy, thematrix transformation in Eq. ( 29) will typically result in a
simple sign m
z=∓ /angbracketleftη|σz|η/angbracketrightdepending on whether the local
Néel order along the easy axis is pointing along ±ˆz.
The key result of our wave-packet analysis, as regards the
remainder of this paper, is that the isospin ηobeys an emergent
Schrödinger equation, and its dynamics is therefore governedby unitary time evolution. By tailoring our Hamiltonian, wecan generate unitary rotations about multiple different axes inisospin space. We display a collection of different rotations inthe coming examples, which taken together will be sufficientto generate any generic rotation (in three Euler angles) of theisospin.
IV . APPLICATION TO SELECTED
MAGNONIC PRIMITIVES
In the previous section, we derived a set of semiclassi-
cal equations governing the isospin-coupled dynamics of amagnon wave packet. Now, we apply that formalism to twoAFM magnonic systems: a gated 1D wire and a 1D domainwall. We conclude by mentioning the effects of magneticfields and hard-axis anisotropy.
A. A gated AFM nanostrip: The magnon FET
In this section, we consider the application of a gate volt-
age across a one-dimensional (1D) AFM nanowire (extendedalong ˆx) with in-plane easy-axis anisotropy (along ˆz). The
gate voltage breaks inversion symmetry, and will thereforegenerate a nonzero DMI simply by symmetry considera-tions [ 21]. In comparison to the DMI statically generated by
inversion asymmetry due to interfacial or crystal structureeffects, though, one expects the DMI produced by the gateto be tunable, and therefore a useful knob to access in amagnonic computing scheme. The system has been outlinedschematically in Fig. 4.
Our motivation here is threefold. First, this gate will be
extremely important in our device proposals later in the paper,so it is worthwhile to present the theoretical treatment here.Second, this simple example which does notpossess any spin
texture will provide a transparent presentation to demonstratethe general solution method to the reader. Finally, solving
this problem, which has already been considered in the Néelvector picture, for the special case of linearly polarized waves,by Ref. [ 11], will serve as a validation of our theoretical
methods against the literature.
The free energy has four parts: homogeneous and inhomo-
geneous exchange, easy-axis anisotropy, and DMI. The firstt h r e eo ft h e s ea r et h es a m ea si sg i v e ni nE q s .( 1), and the
DMI term is
F
DMI=1
2/integraldisplay
D·[mA×∂xmB+mB×∂xmA]dx, (30)
where D=Dˆz. From the corresponding 4 ×4 Hamiltonian,
we construct the 2 ×2 isospin Hamiltonian by using the
embedding E†and Eq. ( 25). Writing out H=H0+Hjσj
explicitly for this problem, we find that it has an unimportant
[67] constant part as well as a σzcomponent:
Hz=J|D|k/epsilon1/parenleftbig
1−(k/epsilon1)2
2/parenrightbig
¯hs/radicalbig
2KJ+(Jk/epsilon1)2. (31)
If we assume both that K/J is small and that kis in a regime
where the distance between the split bands is constant in k,
namely, well above the resonance frequency, then the denom-inator of Eq. ( 31) can be approximated merely by ¯ hsJk/epsilon1 ,
canceling the linear contribution in the numerator and leavingonly the constant term with a weak quadratic correction.Making these approximations in Eq. ( 31), we arrive at an
isospin Hamiltonian
H
z=D/S. (32)
How does this Hamiltonian act on the isospin state? Since we
are dealing with a Schrödinger equation [Eq. ( 27c)], we need
only compute the unitary time evolution operator
U(t1,t0)=exp/bracketleftbiggiτz
¯hs/integraldisplayt1
t0Ddt/bracketrightbigg
(33)
=exp/bracketleftBigg
iτz
¯hs/parenleftbigg∂ω
∂k/parenrightbigg−1/integraldisplayx1
x0Ddx/bracketrightBigg
. (34)
This is a rotation operator in isospin space, rotating about
theˆzaxis on the Bloch sphere by a total angle proportional to
Dand the length of the gate, but inversely proportional to the
spin wave speed ∂kωand the spin magnitude S. The rate of
rotation on the Bloch sphere works out to
∇φ=1
sD
J. (35)
Note that we have cited the rate of rotation on the Bloch
sphere, where φis the azimuthal angle: this differs by a factor
134450-7DANIELS, CHENG, YU, XIAO, AND XIAO PHYSICAL REVIEW B 98, 134450 (2018)
of 2 from the polarization angle of the staggered order. X- and
Y-polarized states, which appear to be rotations of π/2a w a y
from each other in the trace of a spin excitation, are actuallyπaway from each other on the Bloch sphere (Fig. 2).
Because the rate of rotation scales with the DMI itself, the
rotation on a single gate can be manipulated online simplyby modulating the gate voltage. We concerned ourselves inRef. [ 11] [with which our result in Eq. ( 32) agrees] mostly
with a rotation between XandYpolarizations, but access to
generic rotations will be crucial for a mature implementationof nonabelian magnonics.
B. Domain-wall retarder
Since applied AFM magnonics has become fashionable
in the last decade, the AFM domain wall has undergonequite a bit of new analysis [ 12–14,16], and in decades past
was a prototypical nontriviality for the AFM nonlinear sigmamodel [ 68–71]. Many such studies have concluded that spin
waves passing through a domain wall experience a relativefrequency shift between the right- and left-handed compo-nents [ 14]. In systems with DMI, they can express even more
pronounced shifts between linearly polarized modes, givingrise to a retarding waveplate effect [ 12]. Our formalism allows
us to calculate this shift precisely, and in terms of the SU(2)isospin.
In this section, we consider a Bloch-type domain wall in
a synthetic AFM with easy-axis anisotropy and a bulk-typeDMI. Take the Walker solution for the 1D texture as
θ(x)=− 2a r c t a n/parenleftbigg
expx
λ/parenrightbigg
andφ(x)=−π/2,(36)
withλ=√J/K=O(A−1) the domain-wall width.
With this texture, we can immediately calculate the texture-
induced gauge fields from Eq. ( B2) (taking ψ=0 for con-
creteness): we have Az=0 and
Ax=1
λsinψsechx
λ(37a)
and Ay=1
λcosψsechx
λ(37b)
⇒A=i
λ√
2sechx
λ, (37c)
where we have suppressed the space-time index since there is
only one [ 72]. The bulk-type DMI is written as Dij=Dˆrij,
and minimization of DMI energy has been used to determineφ(x).
Using spin wave Hamiltonian Hfor synthetic AFMs de-
tailed in the Supplemental Material [ 52], we compute the
appropriate coefficients of the semiclassical dynamics inEqs. ( 27). The resulting isospin Hamiltonian has an again
unimportant 1
2component as well as a τxcomponent. The
τxterm is
Hx=DK(Z+2Jk2)
4/lscript√
JKsechx
λ. (38)
Since Hhas no other nontrivial component, we see imme-
diately that it will carry out a rotation of the isospin about ˆx
on the Bloch sphere, and will do so most strongly near thecenter of the domain wall due to the exponential localization
provided by sech( x/λ).
From there, we have E(since we have H),H(since we
have HandE), and we know that the B=E=0 by inspec-
tion of Az. The other Berry curvature terms are easily seen
to vanish as well. We immediately construct the semiclassicalequations ( 27) and integrate them with an adaptive-step size
Runge-Kutta-Fehlberg solver ( RKF45 ), using the parameters
for yttrium iron garnet to define our ferromagnetic layers[73]. Our results are displayed and discussed in Fig. 5.N o t e
that, deep within the domain wall, the “easy axis” is nolonger aligned with the textural slow mode, and the dispersionbecomes imaginary for modes below a critical energy. In thiscase, spin transferred to the domain wall is the dominant pro-cess, and our numerical calculations break down close to thisregime. Augmenting our theory with a collective coordinatetheory of the domain wall, effectively allowing it to absorbspin, may be used to address this problem. Here, however, wekeep the problem pedagogical by simply assuming that spinwaves are sufficiently high energy that the local Hamiltonianremains Hermitian.
In our analysis of the domain-wall retarder, we note an
important difference between the g-type and synthetic AFM
in action. Define C=σ
x⊗12, which exchanges each under-
lying basis field with its conjugate (time-reversed) partner.This operation corresponds to charge conjugation .Cchanges
the sign of the coupling between spin wave and the emergentelectromagnetic fields arising from spin texture and DMI.Together with time reversal (given by complex conjugation),the full chirality operator S=TC is a symmetry of the
degenerate Néel-state Hamiltonian H=ˆh⊕ˆh
∗. The breaking
ofSsymmetry by spin texture in the domain wall is what
allows the relative amplitudes of right- and left-handed modesto change in the overall wave function.
Now, define I=1
2⊗σx, which defines the sublattice
interchange operation. TI is also a symmetry of the de-
generate Hamiltonian. In the g-type AFM case, spin texture
will break TIsymmetry in general because an infinitessimal
misalignment is present in each unit cell [ 28]. In the synthetic
antiferromagnetic (SAF), however, the two sublattice sites ina unit cell are never misaligned, so that TIis preserved even
in the presence of spin texture.
Algebraically, the TIsymmetry of the SAF restricts off-
block-diagonal terms of the 4 ×4 spin wave Hamiltonian
to be purely real. Since the embedding Eis itself real, it
follows that the isospin Hamiltonian cannot have a nonzeroτ
ycomponent. The disentangling of TIfrom Ssymmetry in
SAFs should be seen as a virtue: it means that we can useSAFs to carry out rotations about precisely known axes. Bycontrast, the g-type calculation in Fig. 5shows that symmetry-
unconstrained rotations can be quite complex. Not only isthe axis of rotation not about a canonical basis vector, butthe axis of rotation changes dynamically as the wave packet
travels through the continuum of different local Hamiltonianspresented by the spin texture. Precise rotations appear tobe insufferably difficult to control in such an AFM, so ourprescription to experimentalists and device engineers is to usean SAF when precision is needed. However, SAFs presenttheir own challenges. Unlike pure g-type AFMs, SAFs present
a shape anisotropy that may make the realization of uniaxial
134450-8NONABELIAN MAGNONICS IN ANTIFERROMAGNETS PHYSICAL REVIEW B 98, 134450 (2018)
FIG. 5. Semiclassical dynamics of a single magnon passing through a Bloch-type domain wall. The horizontal axes represent time, given
in picoseconds. Left: integration of Eqs. ( 27) for a wave packet, initially with right-handed polarization η=|0/angbracketright, passing through a domain
wall in a synthetic AFM. The SAF material parameters were taken from YIG, and the initial frequency of the wave packet was tuned to result
in aπ/2 rotation on the Bloch sphere. The top plot gives the isospin expectation values; bottom, these have been rotated to give the true spin
current. Right: the same semiclassical dynamics, domain wall, and YIG parameters are simulated, but the system is assumed to be g-type
AFM. We merely substitute the ferromagnetic exchange for the inhomogeneous exchange, and antiferromagnetic for homogeneous exchange.
Because TIsymmetry is broken in the g-type configuration, the rotation is unavoidably more complex. Bottom: schematic illustration of a
g-type versus a synthetic AFM domain wall. We have illustrated Néel-type walls for simplicity, but the calculation was done for Bloch-type
walls.
perpendicular magnetic anisotropy (PMA) difficult to main-
tain. A possible solution would be to use a-type AFMs. These
materials are magnetically ordered at the lattice level, butare AFM ordered in layers, rather than by nearest neighbors.These may present the best of both worlds: their symmetryconstraints will disentangle different rotations, as with anSAF, but they would avoid shape anisotropy issues. Furthermaterials research in this direction is warranted.
We emphasize that although our wave-packet theory de-
scribes a single semiclassical particle, it nonetheless applies toa global spin wave state [ 74]. Our results for both the domain
wall and the magnon field effect transistor (FET) match themicromagnetic simulations of Refs. [ 12] and [ 11] to within
5% error in the driving frequency [ 75]. Formally, the global
wave function can be decomposed usefully into wave packetsthrough a Gabor transformation. Standard signal analysisindicates that this use of isospin wave packets as a basis forthe spin wave signal is accurate as long as the grid spacingneeded to sample the spatially inhomogeneous texture doesnot exceed the spread of wavelengths under consideration:/Delta1x
c/Delta1kc/lessorequalslant2π.C. Other gates
We have carried out explicit example calculations in the
previous sections because they can be immediately comparedto results in the literature, unifying these previous investiga-tions under a single formalism and allowing the reader to putour results in context.
However, our formalism is far reaching and several other
gates can be readily designed. From straightforward calcu-
lations of Hand H, one sees that a hard-axis anisotropy
will provide a rotation about σ
x[76]. Note that this actually
implies spin nonconservation since the magnetization (relativeto the local quantization axis) carried by a spin wave corre-sponds to the polar angle of its isospin. Such nonconservationmechanisms have been explored elsewhere [ 77]; here we
merely accept that they fall out of the isospin dynamical
equations. Meanwhile, an applied magnetic field parallel with
the AFM order will provide a rotation about σ
zsince it
breaks the chiral degeneracy but not the U(1) symmetry ofthe ground state. In this way, a parallel Bfield gives the
same effect as a normal Efield used to generate the DMI in
Sec. IV A .
134450-9DANIELS, CHENG, YU, XIAO, AND XIAO PHYSICAL REVIEW B 98, 134450 (2018)
eiπ τz τxτx τz
= iτy
FIG. 6. Applying different unitary gates to different branches
of a spin wave signal makes the entire Lie algebra of rotational
generators available from a set of two, as in the generation of σy
from the known σxandσzgates in the figure. By applying σxon
one branch and σzon another, one could for instance generate a
Hadamard gate. Note that in such a Hadamard gate, the designer
must take care to ensure that the overall dynamical phase betweenthe branches is equivalent, so as to avoid wave interference in the
output channel. Since the U(1) phase is abelian, though, one need not
worry about this in the iτ
ygate pictured above. Using a D1=−iτz
gate instead of a pure τzgate would generate the same, “extraneous”
π/2 phase on both branches.
A local modification of the easy-axis anisotropy can raise
or lower the local AFMR frequency, and can therefore beused to adjust the relative U(1) phase between two spinwave arms of a multichannel magnonic signal. For instance,such a modification could be used to generate the blue e
iπ
gate in Fig. 6. There, the sign provided by the U(1) relative
phase is crucial for computing the commutator, rather than theanticommutator, of σ
xandσz, without the eiπgate, the loop
in Fig. 6would simply produce total destructive interference,
annihilating the input signal. If one could implement this ina gate-controlled, switchable fashion, then electronic controlover the e
iπgate (EAA) and the σzgate (DMI) would turn
Fig. 6into a switchable σx↔σygate. The presence of an eiπ
gate allows multichannel schemes such as Fig. 6to explore the
full Lie algebra structure of SU(2). Options for implementinga switchable e
iπgate could include gate-controlled easy-axis
anisotropy or a perpendicular (to n) applied Bfield. An espe-
cially important use of this gate in a isospin computer would
be to compensate the accidental dynamical phase accumulated
during the execution of rotational gates.
If one is interested in investigating the effects of inter-
actions not considered here, one can simply derive the spinwave Hamiltonian in the four-dimensional basis we haveused in this paper and then project it to the operator spaceover the degenerate subspace. One immediately obtains thecorresponding isospin Hamiltonian. We have tried to cover themain classes of interactions in the Supplemental Material [ 52]
but more unique interactions such as compass anisotropy [ 78]
or honeycomb DMI [ 18] could provide useful interfaces to
other isospin operations.
V . DISCUSSION
Our objective to this point has been to present the reader
with a cohesive program for isospin magnonics. We startedby reviewing the idea of chirality and the isospin vectorthat parametrizes it. Our key foundational results were thesemiclassical equations ( 27) describing the isospin dynamics
of an AFM magnonic wave packet. With these equations inhand, we described a collection of physical gates, with a focus
on voltage gates and domain walls, that could manipulate theisospin in predictable, calculatable ways.
As this paper draws to a close, let us reflect on our
results and potential avenues for future research. From thecomputing standpoint, recognition of the chiral degree offreedom in AFM magnons is of paramount importance. Usingthe isospin vector as a data carrier represents a paradig-matic improvement, on multiple fronts, over the amplitude-modulating proposals that permeate FM magnonics. First,power management and energy efficiency concerns that arisewhen information is encoded in the FM spin wave powerspectrum become immaterial when the data are carried byAFM isospin. Many of the problems of architecture scal-ing, which plague FM magnonic computing, are significantlyalleviated in AFMs. Second, the isospin carries a higherdimensionality of information. We have seen that this con-siderably broadens the scope of magnon algorithmics. Forinstance, it may be possible to replicate semiclassical quantumcomputing gates in isospin logic. If one is willing to acceptthe use of 2 Nisospin signals in place of 2
Nqubits, and can
map between these schemes faithfully, then perhaps one can“classically simulate” nonentangling quantum circuits on aclassical magnonic platform. To this end, a great deal of studyis needed here to properly characterize the power and scopeof isospin computing.
Our key contribution to the field of magnonics is the
development of a generic, unified formalism for describingthe isospin dynamics in terms of unitary time evolution, aframework with which every physicist is intimately familiar.Together with our mechanical recipe ( A10) for generating
the isospin Hamiltonian from the free energy, we expect thatour theory provides a cohesive platform for future theoreticaland experimental investigations into the challenges of isospinmagnonics.
Among these challenges are both extensions and applica-
tions of our theoretical apparatus. The gates we investigated inSec. IVwere purely one dimensional, and from these simple
components one can produce quite sophisticated computingdevices. We have taken pains, however, to keep the spatialdimensionality of our theory generic; one can apply the re-sults of this paper to 2D and 3D systems. Even in quasi-1Dmagnetic strips, two-dimensional textures such as skyrmionsor magnetic vortices could produce interesting effects. Theinteractions between such solitons and AFM spin waves inopen systems is also an open question. Our theory could beused to address these issues.
There of course exist magnonic applications outside the
spin wave approximation that underlie the theory in thispaper. There, our technical theory may not be a suitabletool, but we hope that our phenomenological description ofthe SU(2) isospin, a concept which relies solely on a thefact that there are two sublattice degrees of freedom with arelative phase between them, will prove useful. Recently, forinstance, AFM auto-oscillators have been proposed [ 79,80].
The dynamical differences between AFM and FM (Klein-Gordon versus Schrödinger) suggest that existing theoriesof magnetic auto-oscillation [ 81] will need to be extended
for the AFM case. This has already been done in the caseof easy-plane oscillators, where the magnetization produced
134450-10NONABELIAN MAGNONICS IN ANTIFERROMAGNETS PHYSICAL REVIEW B 98, 134450 (2018)
by an oscillation is relatively fixed [ 82]. Other second-order
oscillator theories exist, but, especially once they becomecoupled, are often intractable [ 83,84]. They are also usually
considered as phase oscillators. Whether these are the mostnatural theories for describing isospin oscillators is an openquestion.
In the AFM case, for instance, will the concept of an auto-
oscillation bandwidth extend to neighborhoods on the isospinBloch sphere? Such questions, which inherently depend onnonlinearity, call for an understanding of isospin beyond theharmonic spin wave regime. Along a different direction, theadventurous theorist might consider extending our theory toan AFM of more than two sublattices, attempting to derivethe dynamics of an SU( N) isospin.
Practical questions remain about the classes of materials
that can reliably support the sort of dynamics we have es-poused in this paper. Although our theory readily applies touniaxial AFMs such as MnF
2, AFMs with biaxial or multiax-
ial anisotropy may not support low-lying circularly polarizedmodes. Circularly polarized modes may still be used as abasis, especially if the second anisotropy axis is weak, but asthe band splitting becomes greater and greater, our “nearlydegenerate” assumption breaks down. More thorough work isneeded in understanding isospin dynamics in this regime [ 77].
Finally, we note that ferrimagnets satisfy conceptual pre-
requisites for an SU(2) isospin, but are usually treated [inthe yttrium iron garnet (YIG) case, at least] merely as low-damping FMs. Given the importance of ferrimagnets to mod-ern magnonics, a theoretical extension of our formalism tothese systems could be of immense interest. Although thetwo modes in ferrimagnets would not be degenerate as theyare in AFMs, and therefore would require more energy forswitching, one might still in principle be able to carry outisospin logical operations. Research into such systems couldbe critical for applied isospin computing.
ACKNOWLEDGMENTS
We gratefully acknowledge X. Wu, Y . Gao, J. Lan, V .
Siddhu, and Z. McDargh for our insightful conversations.This work was supported by the National Science Founda-tion (NSF), Office of Emerging Frontiers in Research andInnovation, under Award No. EFRI-1433496 (M.W.D.), theNSF East Asia and Pacific Summer Institute under AwardNo. EAPSI-1515121 (M.W.D.), and the National NaturalScience Foundation of China under Grants No. 11722430 andNo. 11474065 (W.Y . and J.X.).
APPENDIX A: TEMPORAL DYNAMICS
FROM THE BERRY PHASE LAGRANGIAN
Although we introduced spin wave dynamics via Eq. ( 4), it
is possible to bypass the Landau-Lifshitz equation altogether.Instead, we can appeal directly to the Lagrangian of ourclassical field theory on α
pmandβ±, given by
L[α+,β+,α−,β−]=LBP−F, (A1)
where Fis the magnetic free energy and LBPis the so-called
Berry phase Lagrangian. The Berry phase Lagrangian is givenby
LBP=S
/epsilon1dA,B/summationdisplay
/Gamma1/integraldisplay/Omega1/Gamma1×m/Gamma1
1−/Omega1/Gamma1·dm/Gamma1
dtddx, (A2)
where /epsilon1is the lattice constant and /Omega1is the gauge-dependent
orientation of the local Dirac string [ 85–87]. If one takes the
variational derivative of LBPbyαandβ, we will find the
left-hand side of Eq. ( 5). Even though we have already arrived
at this result from the perspective of the Landau-Lifshitzequation, we repeat the derivation here using the Lagrangianpicture. We do so because the Lagrangian formalism should beof greater generality and modularity [ 88], so that others may
simply add terms to the Lagrangian and repeat the process weare about to demonstrate.
Define λ
A=/radicalbig
1−2|α|2,λB=/radicalbig
1−2|β|2, and λm=/radicalbig
1−2|μ|2(we use the convention that |α|2=α+α−and so
on). The basic idea in evaluating LBPis simply to make the
substitutions
RmA=ˆx√
2[α++α−+λA(μ+μ∗)]
+ˆy
i√
2[α+−α−+λA(μ−μ∗)]
+ˆz(λAλm−α−μ−μ∗α+), (A3a)
RmB=ˆx√
2[β++β−+λB(μ+μ∗)]
+ˆy
i√
2[β+−β−+λB(μ−μ∗)]
−ˆz(λBλm−β−μ−μ∗β+) (A3b)
into the Lagrangian and expand the result. The “monolithic
substitutions” ( A3) are derived in Appendix C. As long as the
Lagrangian is a linear operator on the spin wave fields α±and
β±, we end up with a collection of terms
LBP=LBP
0+LBP
1+LBP
2, (A4)
where we have collected terms at zeroth, linear, and quadratic
order in the spin wave fields. Linear spin wave theory, uponwhich our formalism is built, cannot support terms at cubicorder or higher, as these would constitute nonlinearities in theequations of motion.
Because we are interested in taking functional derivatives
with respect to the spin wave fields, we can immediatelyneglect the terms L
BP
0[89]. As for LBP
1, we see that functional
derivatives of this term would actually introduce inhomoge-neous terms in the equations of motion. The fastidious readerwill find in her derivations that we apparently dohave such
terms in our Lagrangian, which do not vanish ap r i o r i . Such
terms, if they properly belong to a physical description of thesystem, would seem to imply spontaneous emission of spinwaves since they will let ˙/Psi1take on a nonzero value even when
/Psi1is everywhere zero.
However, the reader is simultaneously invited to notice
that we have introduced more “perturbations” than we canactually control. The problem is that A, which we treat as
an independent field, encodes the ground state of the system,as predetermined by anisotropy and DMI. In fact, once the
134450-11DANIELS, CHENG, YU, XIAO, AND XIAO PHYSICAL REVIEW B 98, 134450 (2018)
boundary conditions are given, Ais strictly determined by
these parameters [ 90]. In equilibrium, one may compute A
in principle by minimizing the free-energy functional withrespect to the textural gauge fields/braceleftBigg
δF[D,K]
∂Aj
μ=0/bracerightBigg
μ,j⇒Aequilibrium [D,K]. (A5)
Formally, these equations should be solved simultaneously
with the actual spin wave equation. On physical grounds,though, we assume that these inhomogeneous terms alwaysvanish when the system under consideration is in equilibriumor else, the system would not in equilibrium, leading to acontradiction. The mathematical mechanism transmitting thisassumption is precisely the set of constraints ( A5). If the
system is not in equilibrium, say, if a soliton is moving,then generally speaking it should generate spin waves inho-mogeneously. Although our formalism allows for temporalbehavior of the underlying spin texture, we assume that itis always in quasistatic equilibrium , that is, we neglect any
inhomogeneous spin waves it generates.
After the above considerations are implemented, we find
that we need deal only with the harmonic Lagrangian
L
BP/mapsto→LBP
2. (A6)
Keeping only the quadratic terms in the spin wave modes,
keeping terms only to order O(|A|2) in our perturbative
expansion, and summing over the sublattices /Gamma1∈{A,B},w e
are left merely with
LBP
2=S/bracketleftbigg
Az
tα−α++in
2(α−˙α+−α+˙α−)/bracketrightbigg
−S/bracketleftbigg
Az
tβ−β++in
2(β−˙β+−β+˙β−)/bracketrightbigg
,(A7)
where n=1+|μ|2is the effective index of refraction be-
tween the local and vacuum values of the spin wave speed,as seen from the Klein-Gordon formulation (see Appendix E).
One readily observes the difference of a minus sign separatingsublattices AandB, as well as a minus sign between each
field and its conjugate partner. These signs are precisely ourτ
z⊗σzfactor from Eq. ( 5). Defining /Psi1=(α+,β+,α−,β−),
we find that setting δL/δ ¯/Psi1=0 results in
i(τz⊗σz)˙/Psi1=/epsilon1d
nSδF
δ¯/Psi1−Az
t(12⊗σz)/Psi1, (A8)
where /epsilon1is the lattice constant. Since we will only keep the
quadratic terms in Fby the arguments that lead to Eq. ( A6),
we know that δF/δ/Psi1∗is a linear operation on /Psi1that can be
written in the form
i(τz⊗σz)˙/Psi1=/epsilon1d
nSH/Psi1−Az
t(12⊗σz)/Psi1 (A9)
analogous to Eq. ( 5). In general, the spin wave Hamiltonian is
given by
H=⎛
⎜⎜⎜⎜⎝/angbracketleftbigδF
∂α−/vextendsingle/vextendsingleα+/angbracketrightbig/angbracketleftbigδF
∂α−/vextendsingle/vextendsingleβ+/angbracketrightbig/angbracketleftbigδF
∂α−/vextendsingle/vextendsingleα−/angbracketrightbig/angbracketleftbigδF
∂α−/vextendsingle/vextendsingleβ−/angbracketrightbig
/angbracketleftbigδF
∂β−/vextendsingle/vextendsingleα+/angbracketrightbig/angbracketleftbigδF
∂β−/vextendsingle/vextendsingleβ+/angbracketrightbig/angbracketleftbigδF
∂β−/vextendsingle/vextendsingleα−/angbracketrightbig/angbracketleftbigδF
∂β−/vextendsingle/vextendsingleβ−/angbracketrightbig
/angbracketleftbigδF
∂α+/vextendsingle/vextendsingleα+/angbracketrightbig/angbracketleftbigδF
∂α+/vextendsingle/vextendsingleβ+/angbracketrightbig/angbracketleftbigδF
∂α+/vextendsingle/vextendsingleα−/angbracketrightbig/angbracketleftbigδF
∂α+/vextendsingle/vextendsingleβ−/angbracketrightbig
/angbracketleftbigδF
∂β+/vextendsingle/vextendsingleα+/angbracketrightbig/angbracketleftbigδF
∂β+/vextendsingle/vextendsingleβ+/angbracketrightbig/angbracketleftbigδF
∂β+/vextendsingle/vextendsingleα−/angbracketrightbig/angbracketleftbigδF
∂β+/vextendsingle/vextendsingleβ−/angbracketrightbig⎞
⎟⎟⎟⎟⎠,
(A10)where the bra-ket notation simply indicates a functional inner
product under which the basis vectors corresponding to α±
andβ±are orthogonal. Since the formula we have given for
His explicit and straightforward [just make the substitutions
(A3) into the free energy and start taking functional deriva-
tives of the quadratic sector], we will not bore the reader withpages of algebra by deriving concrete manifestations of Hin
the main text. We have provided computer algebra code (in theWolfram language) that derives Hfor an assortment of useful
free energies in the Supplemental Material [ 52], with a focus
on those free energies needed to explore our various examplesin Sec. IV. We hope readers interested in their own systems
will use the recipe described above to generate their own spinwave Hamiltonians, which project onto a Hamiltonian H
governing the unitary dynamics of the isospin vector |η/angbracketrightin
Sec. III.
APPENDIX B: SPIN TEXTURE
A principal mechanism [ 91] by which we break U(1)
symmetry and mix the chiralities is through the introductionof a nonuniform ground state. To that end, we require a formalstructure for encoding information about the ground state inour dynamical equations.
Much of the contemporary literature dealing with spin
texture opts to assemble a local coordinate frame, generally{ˆe
r,ˆeθ,ˆeφ}, so that the linearization process we used to derive
Eq. ( 6) can be recycled in the {ˆeθ,ˆeφ}plane. This amounts to a
passive transformation, taking the oscillatory plane of the spinwave fluctuations to align with the local texture.
We instead opt to carry out the equivalent active trans-
formation , rotating each spin so that its spin wave plane
coincides with the global xyplane [ 34,35,44]. A thorough
introduction to this technique in the ferromagnetic case isgiven by Ref. [ 34]. In ferromagnets, one simply defines a
rotation matrix ˆR(x,t)b y ˆRm
0=ˆz, so that it sends the
ground-state configuration m(x,t) at each point to the global
ˆzaxis. This rotation matrix gives rise to a gauge field Aμ=
(∂μˆR)ˆRT. Formally, ωmay be regarded as a matrix-valued
[SO(3)-valued] one-form.
One can show in the lattice formalism that Arepresents the
infinitesimal rotation 1 +RiRT
j=expAijbetween two sites,
that is,Ais a generator of rotations. It can thus be decomposed
into the standard basis for SO(3):
Aμ=Ax
μˆJx+Ay
μˆJy+Az
μˆJz. (B1)
Defining R in terms of the Euler angles R=
e−iψˆJze−iθˆJye−iφˆJz, we can express the vector fields Aj
in terms of the spherical angles describing the spin texture.
This is why we have chosen to include minus signs in theexponentials defining R: they show that we first “undo” the
spherical angles by sending the azimuth to φ−φ=0 and
then sending the polar angle to zero. Taking this conventiongives us
A
x
μ=− sinψ∂μθ+cosφsinθ∂μφ, (B2a)
Ay
μ=− cosψ∂μθ−sinθsinψ∂μφ, (B2b)
Az
μ=− cosθ∂μφ−∂μψ. (B2c)
134450-12NONABELIAN MAGNONICS IN ANTIFERROMAGNETS PHYSICAL REVIEW B 98, 134450 (2018)
Since only two angles are needed to specify the state of each
spin, the third rotation by ψappears to by extraneous, though
certainly permitted since it leaves invariant the spin texturenow lying along ˆz. In this sense, it represent the U(1) gauge
freedom associated with the U(1) symmetry of a coherentspin. In practice, though, ψwill often notbe a gauge freedom
because the U(1) symmetry will often be broken by meansother than the immediate spin texture. If the spin texture hasany misalignment with the easy axis, that is, if there is any
deviation from the Néel ground state, then the anisotropyenergy will not be invariant under the rotation by ψ.D M Io r
hard-axis anisotropy vectors lying perpendicular to the groundstate would also break this symmetry.
The fact that we have chosen ˆzas the global axis to which
the texture is rotated means that we will mostly be concernedwith the J
zcomponent of the curvature form /Omega1=dA.T h e
main consequence is that it is the curl of Az, rather than the
curl of AxorAy, which will provide the emergent electromag-
netic field, familiar to students of magnetic skyrmions [ 62],
generated by a spin texture.
The reader may recall that A, and therefore the 3-tuple
(Ax,Ay,Az), was supposed to describe an infinitesimal ro-
tation between neighboring spins. Such a rotation belongsto a two-dimensional group, and should be describable byexactly two numbers; therefore, we should seek a singleconstraint among our three vector potentials A
j. By analyzing
the curvature form, one can quickly show that this constraintis
∇×A
z=Ax×Ay. (B3)
Because ˆzis privileged, it will be convenient to keep using Az
in our equations. For AxandAy, though, we define a more
concise complex field via
Aμ=Ax
μ+iAy
μ√
2. (B4)
Then, we see that we can substitute the right-hand side of
Eq. ( B3)f o r[ 92]
ˆz·(Ax×Ay)=Ax
xAyy−Ax
yAyx=2iA∗
xAy. (B5)
We conclude that A∗
xAy, and, therefore, A∗
yAx, is a physically
interesting quantity, as it encodes the same emergent electro-magnetic field as the curl of A
z.
What of the symmetric products A∗
μAμ? It turns out that
these elements are also gauge-invariant physical quantities. Inthe general case, one finds
A
∗
μAν=gμν+i
2Fμν, (B6)
defining Qμν=AμA∗
ν, (B7)
where gμν=Ax
μAxν+Ay
μAyνreduces in spherical angles of
the texture to
gμν=∂μθ∂μθ+sin2θ∂μφ∂νφ (B8)
⇒g=dθ2+sin2θd φ2. (B9)
In other words, gis just the first fundamental form on the
sphere. It is the differential line element ds2by which arclengths of the spin texture through spin space are measured.
The matrix gis the spherical metric.
Qμνis called the quantum geometric tensor . There is very
little “quantum” about it in our case, but the nomenclature isalready out there [ 10,93–95].
APPENDIX C: A MONOLITHIC SUBSTITUTION
FOR INTRODUCING THE SPIN WA VE FIELDS
In the antiferromagnetic case, we choose the rotation ma-
trix to send the staggered order to the global ˆz. Generally
speaking, mAandmBare not perfectly antiparallel, so after
this rotation we will still be left with in-plane components ofthe (rotated) local magnetization.
We have already alluded to the fact that our two-level
system does not fully describe the spin wave dynamics. This isbecause the basis fields a
x+iayandbx+ibyonly represent
circular modes. If we want to access modes with linearcomponents, say, fluctuations of a
xwithay=0, then our
Hamiltonian needs to couple to a linear combination of botha
x+iayand its complex conjugate.
To address this, we have introduced the fields
α+,α−,β+,andβ−to represent our spin wave fluctuations
on each sublattice. Now, let us fold these new variables intoour formalism. First, split each rotated field into its slow ( ˜m
0
A
and ˜m0
B) and fast ( αandβ) modes, which are perpendicular
by construction, and then split the slow modes into thelocal staggered order and local magnetization ( Rn=λ
mˆzand
˜m=Rm, withλm=√
1−m2) of the quasistatic equilibrium
spin texture. We have introduced factors of λA=/radicalbig
1−|α|2
andλB=/radicalbig
1−|β|2in order to maintain the normalization
of the slow modes ˜mAand ˜mBin the presence of spin wave
fluctuations. In other words, we have
RmA=λA(˜m+λmˆz)+α, (C1a)
RmB=λB(˜m−λmˆz)+β. (C1b)
A few notes about the quantities we have just defined. First,
˜mlies in the xyplane since ˜n=λmˆzis perfectly out of plane.
Second, though we have opted out of a concern for brevitynot to decorate nandmwith any kind of indicator, keep in
mind that these variables only encode the slow modes of the
system. All spin wave fluctuations of these quantities havebeen restricted by construction to the excitations αandβ.
Notice that we have chosen Rthrough the realignment
ofnto avoid choosing a preferred sublattice. Because each
m
0
Aandm0
Bis subtly misaligned from nin the presence of a
texture, however, our rotated spin wave fluctuations are αand
βhave small out-of-plane components. It would be convenient
instead to restrict them to the xyplane, so let us now compute
exactly what their out-of-plane component is. Since they areorthogonal to the sublattice slow modes by construction, wehave (on the Asublattice, for instance)
0=α·˜m
0
A=α·˜m+λmαz (C2)
so that αz=−λ−1
mα·˜mandβz=λ−1
mβ·˜m. Defining aandb
as the planar projections of the spin wave fields, we can thensimply write α=a−λ
−1
m(a·˜m)ˆzand so on.
134450-13DANIELS, CHENG, YU, XIAO, AND XIAO PHYSICAL REVIEW B 98, 134450 (2018)
Finally, we define complex variables α±=(ax±iay)/√
2,
β±=(bx±iby)/√
2, and μ=(˜mx+i˜my)/√
2. These four
complex variables will be treated as independent; with theunderstanding that the real part must be taken before extract-ing physical quantities from this complex formalism, fourreal degrees of freedom are maintained. Taking all of thesedefinitions together, we have our two monolithic substitutions
˜m
A=ˆx√
2[α++α−+λA(μ+μ∗)]
+ˆy
i√
2[α+−α−+λA(μ−μ∗)]
+ˆz(λAλm−α−μ−μ∗α+), (C3a)
˜mB=ˆx√
2[β++β−+λB(μ+μ∗)]
+ˆy
i√
2[β+−β−+λB(μ−μ∗)]
−ˆz(λBλm−β−μ−μ∗β+). (C3b)
With these quantities in hand, the free energy can be computed
explicitly, and by taking variations by αandβof the conse-
quent Lagrangian, we can ultimately determine the spin waveequation of motion.
APPENDIX D: A MORE DETAILED DISCUSSION
OF NONABELIAN WA VE-PACKET THEORY
Before computing a phase-space Lagrangian governing the
semiclassical dynamics, we establish some self-consistencyproperties of the wave packet that will provide for usefulidentities during our calculation.
1. Normalization condition
First, let us enforce a normalization condition on |W/angbracketright,
given by
/angbracketleftW|τz⊗σz|W/angbracketright=1. (D1)
This leads to a normalization condition for the η, namely, that
/angbracketleftW|τzσz|W/angbracketright=(−1)j/integraldisplay
dqdkw∗
kwqη∗
j,kηj,q/angbracketleftbig
ψj
k/vextendsingle/vextendsingleσz/vextendsingle/vextendsingleψj
q/angbracketrightbig
(D2)
=(−1)2j/integraldisplay
dq|wq|2|ηj|2(D3)
⇒1=/angbracketleftη|η/angbracketright. (D4)
Equation ( D4) suggests that, unlike |W/angbracketrightand|/Psi1/angbracketright,|η/angbracketrightwill
be subject to a traditional, Euclidean Schrödinger dynamics.Recall that the σ
zinner product in the two-level system did
not provide a useful normalization condition, as a result of theinternal hyperbolic geometry. It is only here in the four-levelsystem, where the signs from internal and external geometriescancel each other, that we arrive at a normalizable spin wavedensity (rather than spin density).
The calculational patterns from Eq. ( D2) detail the internal
derivations of wave-packet theory. We briefly outline thelogical flow of the computation for readers unfamiliar withthe formalism. The key stages needed to reduce any of our
wave-packet inner product are as follows:
(1) Use the fact that the wave vectors are “block-diagonal”
[in the sense of Eq. ( 11)] to reduce the τ
zt oas i n g l e( −)j, and
to avoid any cross terms between eigenvectors from differentbands.
(2) Establish an inner product of the internal band struc-
ture (e.g., /angbracketleftψj
k|σz|ψj
q/angbracketright). Extract the translation operators to
find a factor of exp[ i(q−k)x] and use the inner product, a
real-space integral over the sample, to produce a δd(q−k).
(3) Carry out one of the momentum-space integrals to
activate the Dirac delta function and reduce the problem toa single Brillouin zone.
(4) If the inner product from step 2 was a normalization
condition of the internal geometry, then it produced a ( −)
j
that, together with the sign from τ, cancels to give positive
unity. Otherwise, there is a nontrivial inner product /angbracketleftη|ˆO|η/angbracketright
that must be tracked.
(5) Integrate by parts, use product rules, and use the
normalization condition as necessary to manifest a factor of|w
q|2in the integrand. Interpret |wq|2/mapsto→δd(q−qc) to carry
out the final integral.
Before evaluating the Lagrangian proper, we have one
more useful identity to compute: the expectation value of theposition operator.
2. Position operator
Let us consider the self-consistency condition for the wave-
packet center. This means that we require the observable ˆxto
be diagonal in the wave-packet basis, with eigenvalue xcfor
wave packet |W(xc,qc,η,t)/angbracketright. Therefore,
/angbracketleftW|(τz⊗σz)ˆx|W/angbracketright=xc/angbracketleftW|(τz⊗σz)|W/angbracketright. (D5)
The bra-ket on the right then reduces to unity by the wave-
packet normalization.
Before we proceed, let us define the nonabelian Berry
connection
ˆaj
μ=/parenleftbigg/angbracketleftbig
/Psi10
q/vextendsingle/vextendsingleiσz∂μ/Psi10
q/angbracketrightbig
0
0 −/angbracketleftbig
/Psi11
q/vextendsingle/vextendsingleiσz∂μ/Psi11
q/angbracketrightbig/parenrightbigg
, (D6)
wherein μis a coordinate of the phase-space dynamics. We
will therefore be concerned alternatively with ˆax,ˆaq, and ˆat.
Calculating the left-hand side of Eq. ( D5) using the matrix
elements of the position operator from Ref. [ 96], we find [ 97]
xc=/angbracketleftW|(τz⊗σz)ˆx|W/angbracketright (D7)
=/angbracketleftη|ˆaq|η/angbracketright+∂γc
∂q. (D8)
In deriving Eq. ( D8), we see our first example of a noncancel-
lation between σzandτz. The Berry connection is not merely
the normalization condition /angbracketleft/Psi1|σz|/Psi1/angbracketright, and therefore cannot
produce the sign needed to cancel the ( −)jfactor. Instead,
these signs have all been contained within ˆa.
3. Extracting the electromagnetic Lagrangian
In Sec. II B, we introduced the collection of vector
potentials Ajwhich encode the spin texture. Generally
134450-14NONABELIAN MAGNONICS IN ANTIFERROMAGNETS PHYSICAL REVIEW B 98, 134450 (2018)
speaking, the introduction of spin texture breaks the contin-
uous translational symmetry of the (continuum limit of the)Néel ground state. Since the A
jare not necessarily gauge
invariant, though, one expects that the translational proper-ties of the vector potentials need not align in general withtranslational properties of the physical system. The situationis similar to introducing an electromagnetic vector potential instandard quantum mechanics; there, the canonical momentum
operator −i∂
xmust be adjusted to the mechanical momentum
operator, −i∂x−ieA, where only the latter is properly con-
served.
Even without explicitly computing the spin wave Hamilto-
nian, we expect that the kinetic energy term we explored inthe two-level system will appear to undergo a sort of Peierlssubstitution by A
z. With this in mind, we will now perform
a gauge transformation, removing the Azfrom the kinetic
energy terms and collecting it into a new Lagrangian termwhich will completely encapsulate the emergent electromag-netic interaction.
Define the matrix
G=exp[−i(τ
z⊗12)(Az·x)]. (D9)
Then, inserting factors of G†Ginto the Lagrangian, we have
/angbracketleftW|G†G/parenleftbigg
iτzσzd
dt−H−Az
tσz/parenrightbigg
G†G|W/angbracketright, (D10)
where the wave packets and Hamiltonian are, at this point, still
in the original gauge choice, and the brackets represent thematrix element of the operator on the diagonal in the wave-packet basis. To save space, we have removed the explicittensor product notation. We leave it to the reader to interpretτ
z/mapsto→τz⊗12andσz/mapsto→12⊗σzas the context demands.
The value of the transformation by Gis not only in an in-
ternal simplification of H, but also in elegantly extracting the
emergent electromagnetic Lagrangian early in the calculation.One readily sees after carrying out the time derivative that theLagrangian is
/angbracketleft˜W|/parenleftbigg
−(σ
z˙Az·ˆx)−Az
tσz+iτzσzd
dt−˜H/parenrightbigg
|˜W/angbracketright,(D11)
where ˜H=GHG†. Collecting the first two terms together, this
can be naturally split into three components:
L=LEM+Ldt+LH. (D12)
These components represent the emergent electromagnetic,
dynamical, and free-energy sectors of the spin wave equation.
The gauge transformation has also affected the wave packet
itself. Concretely, the wave packet is now
|˜W/angbracketright:=G|W/angbracketright=/integraldisplay
dqw(q,t)
×[˜η0(q,t)|/Psi10(q,t)/angbracketright+˜η1(q,t)|/Psi11(q,t)/angbracketright],(D13)
where |˜η/angbracketright=(˜η0,˜η1) locates the gauge-transformed wave
packet within the degenerate subspace.
From Eq. ( D11), we see the need to evaluate
−˙Az·/angbracketleft˜W|(12⊗σz)ˆx|˜W/angbracketright−Az
t/angbracketleft˜W|12⊗σz|˜W/angbracketright (D14)the first of which terms will invoke a calculation analogous to
those in Appendix D2.W eh a v e
/angbracketleft˜W|(12⊗σz)ˆx|˜W/angbracketright=/angbracketleftη|τzˆaq|η/angbracketright+/angbracketleftη|σz|η/angbracketright∂γc
∂q.(D15)
Substituting in the self-consistency condition ( D8)o nxcfor
theγcderivative, we end up with
LEM=− ˙Az·/Gamma1q−χ/parenleftbig˙Az·xc+Az
t/parenrightbig
, (D16)
where χ=/angbracketleftη|τz|η/angbracketright, and/Gamma1qis the covariance /angbracketleftη|τzˆaq|η/angbracketright−
/angbracketleftη|τz|η/angbracketright/angbracketleftη|ˆaq|η/angbracketright. Note that we have simplified these terms
back to η, rather than ˜η, since Gcommutes with τzand ˆaμ.
Interpreting χas a charge, the second half of Eq. ( D16)
is just the interaction Lagrangian for a charged particle in anelectromagnetic field [ 98]. Note that, in particle physics, there
is also a sense in which the electromagnetic charge is a τ
z
expectation value: one can rotate the isospin of a positively
charged proton, through some SU(2) “isospin” space, to theneutrally charged neutron. That we have a similar sort ofcontinuum-valued (emergent) charge is our motivation foremploying the “isospin” nomenclature in our definition of η.
4. Time derivative term
Although we have already encountered a few time deriva-
tives without comment in the wave-packet theory, a fewwords are certainly in order concerning the time variable. Itstreatment is one of the most delicate and subtle parts of wave-packet theory, and it is easy to make dangerous systematicerrors without a proper treatment. For the reader interested inreplicating our derivation, we have given some notes on thematter in Appendix D7.
The time derivative term L
dtin the Lagrangian is
i/integraldisplay
dqdk/angbracketleftbig
/Psi1i
q/vextendsingle/vextendsingle˜η∗
i,qw∗
q(τzσz)d
dt/parenleftbig
wk˜ηj,k/vextendsingle/vextendsingle/Psi1j
k/angbracketrightbig/parenrightbig
. (D17)
Since our eigenvectors are themselves block diagonal, and
sinceτz⊗σzas well as Gare both diagonal, we know there
can be no terms connecting i/negationslash=j.
The first term (on wk) in a product rule of expansion of
Eq. ( D17)i ss i m p l y ∂tγc. The next term, on ˜ ηj,k, gener-
ates the isospin dynamics, and the final term gives rise tomatrix-valued Berry connections. All together, these termsbecome
L
dt=/angbracketleft˜η|˙xc·ˆax+˙qc·ˆaq+ˆat+i∂t|˜η/angbracketright−˙qc·xc.(D18)
We have used the self-consistency condition to replace the
Berry phase term ∂tγcwithxc−/angbracketleftη|ˆaq|η/angbracketright.
5. Hamiltonian terms
Finally, we have the terms coming from the spin wave
Hamiltonian itself. These are
LH=− /angbracketleftW|H|W/angbracketright (D19)
=−1
ns/integraldisplay
dq|wq|2[˜η∗
i˜ηj/angbracketleft/Psi1i|˜H|/Psi1j/angbracketright].(D20)
Let us define the matrix
˜H=/parenleftBigg/angbracketleftbig
/Psi10
c/vextendsingle/vextendsingle˜H/vextendsingle/vextendsingle/Psi10
c/angbracketrightbig/angbracketleftbig
/Psi10
c/vextendsingle/vextendsingle˜H/vextendsingle/vextendsingle/Psi11
c/angbracketrightbig
/angbracketleftbig
/Psi11
c/vextendsingle/vextendsingle˜H/vextendsingle/vextendsingle/Psi10
c/angbracketrightbig/angbracketleftbig
/Psi11
c/vextendsingle/vextendsingle˜H/vextendsingle/vextendsingle/Psi11
c/angbracketrightbig/parenrightBigg
. (D21)
134450-15DANIELS, CHENG, YU, XIAO, AND XIAO PHYSICAL REVIEW B 98, 134450 (2018)
One may think of Has a projection of the original Hinto the
two-dimensional orthochronous degenerate subspace that weare now calling “isospin space,” the copy of SU(2) in which η
resides. Defining the embedding
E
†=|/Psi10/angbracketright/angbracketleft0|+|/Psi11/angbracketright/angbracketleft1| (D22)
which sends vectors in the isospin subspace to their represen-
tation in parent 4 ×4 Hilbert space space, His merely
˜H=E˜HE†. (D23)
This Hermitian matrix will govern the dynamics of |˜η/angbracketrightin
the semiclassical dynamics we are about to describe. Thetotal contribution from these energy terms to the wave-packetLagrangian is, simply,
L
H=− /angbracketleft ˜η|˜H|˜η/angbracketright. (D24)
6. Phase-space EOM
Let us take stock of our progress. We have a Lagrangian of
three terms, which have been reduced to
LEM=− ˙Az·/Gamma1q−χ/parenleftbig˙Az·xc+Az
t/parenrightbig
, (D25a)
Ldt=/angbracketleft˜η|˙xc·ˆax+˙qc·ˆaq+ˆat+i∂t|˜η/angbracketright−˙qc·xc,(D25b)
LH=− /angbracketleft ˜η|˜H|˜η/angbracketright. (D25c)
Now, we can take variations against xc,qc, and|η/angbracketrightto derive
semiclassical equations of motion (EOM).
First, let us find the force equation by taking a variation
against xc. For the Lorentz force term, we unsurprisingly have
δLA
δxμ
c=−χ/bracketleftbig
∂tAz
μ+∂xμ
cAz
t+˙xc·∂xμ
cAz−(˙xc·∇)Az
μ/bracketrightbig
(D26)
=χE+χ˙xc×B, (D27)
where we define the fields E=−∇Az
t−∂tAzandB=∇×
Azin the obvious ways. The time derivative term meanwhile
gives
δLdt
δxμ
c=− ˙qc+/angbracketleftbig
/Omega1xx
μν/angbracketrightbig˙xν
c+/angbracketleftbig
/Omega1xq
μν/angbracketrightbig˙qν
c+/angbracketleftbig
/Omega1xt
μ/angbracketrightbig
, (D28)
where
/angbracketleftbig
/Omega1αβ
μν/angbracketrightbig
=/angbracketleftη|/parenleftbigg∂ˆaβν
∂αμ−∂ˆaαμ
∂βν/parenrightbigg
|η/angbracketright (D29)
is the η-density trace of the nonabelian Berry curvature, as
discussed in Ref. [ 53].
Finally, we have a contribution from the gauged Hamilto-
nian. In most cases we consider in this paper, no such termssurvive at O(|A|
2); the terms that might nominally survive are
those wrapped encoded in LEM. Examples of terms that may
survive and not be included in LEMcould include spatially de-
pendent anisotropy or DMI, arising from, e.g., wedge-shapedlayers in magnetic heterostructures. Taking this term and theLorentz force together, the force equation is
˙q
c=Tr/bracketleftbigg
ˆρ/parenleftbigg
τz(E+˙xc×B)−∂E
∂xc/parenrightbigg/bracketrightbigg
, (D30)
where Eis the energy of the unperturbed degenerate bands,
and where we have defined the density operator
ˆρ=ρ0|0/angbracketright/angbracketleft0|+ρ1|1/angbracketright/angbracketleft1|. (D31)Now, we turn to the velocity equation. The results are
little different from what we would expect from standard non-abelian wave-packet theory, giving us the classical velocitytogether with Berry-curvature-induced transverse velocities
˙x
c=Tr[ ˆρ(∂qE+/Omega1qq˙qc+/Omega1qx˙xc+/Omega1qt)]. (D32)
Now, we turn to the most interesting equation of motion,
generated by the variation again /angbracketleftη|. This generates terms of
the form
δLEM
δ˜η∗=− ˙Az·δ/Gamma1q
δ˜η∗−(˙Az·xc)τz˜η−Az
tτz˜η, (D33)
δ/Gamma1q
δ˜η∗=τzˆaq˜η−τz(/angbracketleft˜η|ˆaq|˜η/angbracketright)˜η−χˆaq˜η, (D34)
δLdt
δ˜η∗=/bracketleftbigg
˙qc·ˆaq+i∂
∂t/bracketrightbigg
˜η, (D35)
δLH
δ˜η∗=− H˜η. (D36)
The final general equation of motion is
i/parenleftbiggd
dt+At/parenrightbigg
η=/bracketleftbig
H+τzAz
t+ˆVχ/bracketrightbig
η, (D37)
where H=EHE†(note that we have removed the gauge
transformation G),Ais the time-covariant connection on
phase space
At=˙qq·ˆaq+˙xc·ˆax+ˆat, (D38)
Aij
t=/angbracketleftbig
ψi
c/vextendsingle/vextendsingleiσzd
dt/vextendsingle/vextendsingleψj
c/angbracketrightbig
, (D39)
and ˆVχis a nonlinear term deriving from /Gamma1q.I ti sg i v e nb y
ˆVχ=− ˙Az·(τzˆaq−τzˆPηˆaq−ˆaqˆPητz), (D40)
where ˆPη=|η/angbracketright/angbracketleftη|is the projector onto the isospin state, and
as before the dot product (with ˙Az) is taken with the subscript
inˆaq. This potential is nonlinear in the sense that, through ˆPη,
it depends quadratically on the current state, and the resultingterm in the Hamiltonian has the schematic form |ψ|
2|ψ/angbracketright.
However, this nonlinear term balances precipitously on theedge of irrelevance. ˙A
zis itself O(A2), so this term survives
only if ˆaqisO(A0). Although there is no reason (to our
knowledge) this could not happen in principle, none of theconcrete systems we consider later in the paper can activatethis term. What is more, the term would seem only relevant inthe case of a moving spin texture, so that ˙A
zis nonzero. Such
a term may be of interest for those working in the dynamicsof AFM solitons, but we leave that to future research.
7. Notes on time derivatives in wave-packet theory
There are two variables, xandq, that have been float-
ing around as dummy variables of integration in some ofour calculations. Several functions, such as the wave-packetenvelope a
q=a(q,t) or the Bloch eigenvectors eiqxu(q,t),
are functions of both q(orx) and time. For these functions,
there is no difference between a total time derivative and apartial time derivative because qandxare clearly independent
134450-16NONABELIAN MAGNONICS IN ANTIFERROMAGNETS PHYSICAL REVIEW B 98, 134450 (2018)
variables (merely coordinates of a space) that do not, them-
selves, possess any temporal dynamics.
On the other hand, the gauge field Az=Az(xc,t)w a s
originally, and will always be, evaluated at xcin its spatial
argument. This xcis a dynamical variable, which does de-
pend on time and has dynamics. Our notation, which followsRef. [ 55], is that a partial time derivative of such a function
acts only on the second argument slot, where there is anexplicit time dependence. A total time derivative, on the otherhand, would include the time dependence through x
c, so that
d
dt=∂
∂t+˙xc·∂
∂xc. (D41)
So far, our discussion has perhaps clarified the notation, but
is by no means unusual. The delicacy of these operations inwave-packet theory occurs when evaluation of a wave-packetexpectation value promotes a function in the integrand, whereit may have possessed only an explicit time dependence, to afunction of q
c(t), due to the firing of the Dirac delta function
|aq|2. The question is as follows: Should the time derivative
under the integrand be lifted to a total time derivative or apartial time derivative once the function acquires a new timedependence in the phase-space coordinate arguments x
c(t)
andqc(t)?
The answer is that we must promote it to a partial time
derivative. The original, physical meaning of such a timederivative in the integrand was to ask how, at any given pointin space, a function changed with time. We are concerned withthe function’s temporal behavior , not the temporal behavior of
the combined wave-packet/function system. From a differentperspective, we note that we are certainly free to take the timederivative as early as possible. Suppose we “carry out” thetime derivative in the integrand by replacing ∂
tf(t,q) with
its formal derivative F(t,q). Now, Fis just a function which
we have determined in principle before ever introducing thephase-space path ( x
c,qc), so after firing the Delta function wesimply have F(t,qc(t)). Clearly, F(t,qc(t))=∂tf(t,qc(t)),
with the derivative only in the first argument.
APPENDIX E: STAGGERED ORDER
Suppose we changed the basis of Eq. ( 6) by a Hadamard
matrix
M=1
2/parenleftbigg
11
1−1/parenrightbigg
, (E1)
sending αandβtoδm=mx+imyandδn=nx+iny,
respectively. Neglecting anisotropy for the moment, the re-sulting Schrödinger equation on ˆhis
iσ
xd
dt/bracketleftbigg
δm
δn/bracketrightbigg
=1
2/bracketleftbig
Z+σz(Z−J∇2)/bracketrightbig/bracketleftbigg
δm
δn/bracketrightbigg
. (E2)
Neglecting the dynamics of δm, this can be solved by
taking a second time derivative and plugging the originalequation for ˙ninto the new equation for ¨n. The result is
0=/parenleftbigg1
c2d2
dt2−∇2/parenrightbigg
δn, (E3)
where c=√ZJ/ 2. Therefore, our σz-measured Schrödinger
dynamics given (in either of the equivalent 2 ×2 blocks) by
Eq. ( 5) are in fact equivalent (in this simple regime, at least)
to the Klein-Gordon–type second-order dynamics found morecommonly in the literature. It is no surprise that relativisticdynamics describes the system whose modes, as we have seen,are restricted to timelike points in a hyperboloid of two sheets.In the case where K=0, we actually have massless particles,
the hyperboloid of two sheets becomes a light cone. Addingthe anisotropy restores a mass term ( /square−m
2)δn=0t ot h e
Klein-Gordon equation, just as it opens a mass gap in ourhyperboloid.
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134450-18NONABELIAN MAGNONICS IN ANTIFERROMAGNETS PHYSICAL REVIEW B 98, 134450 (2018)
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