Coulomb interaction and transient charging of excited states in open nanosystems Valeriu Moldoveanu,1Andrei Manolescu,2Chi-Shung Tang,3and Vidar Gudmundsson4 1National Institute of Materials Physics, P.O. Box MG-7, Bucharest-Magurele, Romania 2Reykjavik University, School of Science and Engineering, Kringlan 1, IS-103 Reykjavik, Iceland 3Department of Mechanical Engineering, National United University, Lienda, Miaoli 36003, Taiwan 4Science Institute, University of Iceland, Dunhaga 3, IS-107 Reykjavik, Iceland We obtain and analyze the e ect of electron-electron Coulomb interaction on the time dependent current owing through a mesoscopic system connected to biased semi-in nite leads. We assume the contact is gradually switched on in time and we calculate the time dependent reduced density operator of the sample using the generalized master equation. The many-electron states (MES) of the isolated sample are derived with the exact diagonalization method. The chemical potentials of the two leads create a bias window which determines which MES are relevant to the charging and discharging of the sample and to the currents, during the transient or steady states. We discuss the contribution of the MES with xed number of electrons Nand we nd that in the transient regime there are excited states more active than the ground state even for N= 1. This is a dynamical signature of the Coulomb blockade phenomenon. We discuss numerical results for three sample models: short 1D chain, 2D lattice, and 2D parabolic quantum wire. PACS numbers: 73.23.Hk, 85.35.Ds, 85.35.Be, 73.21.La I. INTRODUCTION Due to the increasing interest in ultra-fast electron dynamics considerable progress occurred recently in the theoretical description of time dependent mesoscopic transport. New methods and numerical implementations are rapidly evolving. Transient currents in open nanos- tructures are studied with Green-Keldysh formalism,1,2,3 scattering theory,4and quantum master equation.5,6,7,8 Most of the results were obtained for noninteracting elec- trons due to the well known computational diculties to include time-dependent Coulomb e ects. It is nevertheless clear that the electron-electron inter- action is important in such problems. An e ort to incor- porate it has been recently done by Kurth et al.9followed by My oh anen et al.10who have described correlated time- dependent transport in a short 1D chain de ned by a lattice Hamiltonian. The 1D sample was connected to external leads and the current was driven by a time- dependent bias. Those authors used a method based on the Kadano -Baym equation for the non-equilibrium Green's function combined with the time-dependent den- sity functional theory to include the Coulomb interac- tion in the sample. Once the Green's functions were calculated total average quantities of interest could be obtained, like charge density or current, both in the tran- sitory and in the steady state. However this method does not say much about the dynamics of speci c internal states of the sample system. In view of the spectroscopy of excited states11it is important to have a theoretical tool for understanding separately the charging and re- laxation of the ground states and excited states in meso- scopic systems in time-dependent conditions. Our alternative is to use the statistical, or density op- erator. The complete information about the time evo- lution of each quantum state of the sample is captured in the reduced density operator (RDO), which is the so-lution of the generalized master equation (GME). Once the RDO is de ned in the Fock space the inclusion of the Coulomb interaction becomes a known computational problem: obtaining the many-electron states (MES) of the sample. The RDO matrix is then calculated in the basis of the interacting MES. Let us enumerate some of the previous theoretical schemes to treat transport and electron-electron inter- action with the master equation. One of the rst at- tempts to derive a master equation for an interacting sys- tem with time-dependent perturbations belongs to Lan- greth and Nordlander for the Anderson model.12Gurvitz and Prager started from the time-dependent Shr odinger equation for the MES wave functions and ended up with Bloch-like rate equations for the density matrix of a quan- tum dot.13The electronic currents were calculated in the steady state and it was shown that the Coulomb interac- tion renormalizes the tunneling rates between the leads and the system. In the same context K onig et al.14de- veloped a powerful diagrammatic technique by expand- ing the RDO of a mesoscopic system in powers of the tunneling Hamiltonian. The time-dependence of the sta- tistical operator of the coupled and interacting system implies a quantum master equation for the so called pop- ulations. In this method the Coulomb interactions are treated exactly, which makes it appealing for studying various correlation e ects like cotunneling.15The con- nection between the real-time diagrammatic approach of K onig et al.14and the Nakajima-Zwanzig approach16,17 to the generalized master equation (GME) approach was made transparent by Timm.18 More recently Li and Yan19combined the n-resolved master equation and the time dependent density- functional method to write down a Kohn-Sham master equation for the reduced single-particle density matrix. Also, Esposito and Galperin,20using the equation of mo- tion for the Hubbard operators, have obtained a many-arXiv:1001.0047v1 [cond-mat.mes-hall] 30 Dec 20092 body description of quantum transport in an open sys- tem and established a connection between the GME and non-equilibrium Greeen's functions. They studied simple systems in the steady state regime: a resonant level cou- pled to a a single vibration mode, an interacting dot with two spins, and a two-level bridge. Another recent work by Darau et al.21implemented the GME for a benzene single-electron transistor and used exact MES to compute steady state currents within the Markov approximation.21 The stability diagram and the conductance peaks were obtained and a current blocking due to interferences be- tween degenerated orbitals was noticed. In our previous papers7,8we considered the GME method for the RDO of independent electrons in the Fock space. We discussed the transient transport through quantum dots and quantum wires. The contact between the leads and the sample was switched on at a certain ini- tial moment t0. We discussed extensively the occupation of the states within the bias window and the geometrical e ects on the transient currents. We described the cou- pling between the sample and the leads via a tunneling Hamiltonian in which we took into account the spatial extension of the wave functions of both subsystems in the contact region. In spite of earlier or more recent attempts a complete description of the Coulomb e ects in the time-dependent transport is still missing, especially in sample models larger than a few sites. In the present work we com- bine the GME method with the Coulomb interaction in the sample and we analyze the dynamics of the electrons starting with the moment when the leads are coupled to the sample until a steady state is reached. The Coulomb interaction is included in the Hamiltonian of the isolated sample and the interacting MES are calculated with the exact diagonalization method. This means the Coulomb interaction is fully included with no mean eld assump- tion or density-functional model. The number of single- electron states (SES) used to de ne the matrix elements of the Hamiltonian of interacting electrons is suciently large such that the MES of interest are convergent. Due to the nite bias window only a limited number of MES participate to the charge transport through the sample, i. e.only those energetically compatible with the elec- trons in the leads. Hence the MES of interest are selected by the chemical potentials in the leads. We calculate the RDO matrix elements in the subspace of these MES using the GME. The electron-electron interaction in the leads is neglected. It is well known that the Fock space increases expo- nentially with the number of SES. In addition the time dependent numerical solution of the GME is also com- putational expensive. So at this stage we are limited to describe only few electrons in the system: up to ve in a small system, but only up to three in a larger one. The paper is organized as follows. In Section 2 we brie y describe the GME, the inclusion of the Coulomb interaction, and the selection of the MES. Next, in Sec- tion 3, we show results for three models: a short 1Dchain, a 2D lattice of 12 10 sites, and a nite quantum wire with parabolic lateral con nement. Conclusions and discussions are presented in Section 4. II. GME METHOD AND COULOMB INTERACTION In this section we summarize the main lines of our method. The equations apply both to the lattice and continuous models. The time-dependent transport prob- lem is considered within the partitioning approach which is known both from the pioneering work of Caroli22and from the derivation of the GME. Prior to an initial time t0the left lead (L) having a \source" role, and the right lead (R) having a \drain" role, are not connected to the sample and therefore can be characterized by equilibrium states with chemical potentials LandRrespectively. Our aim is to compute the time dependent currents ow- ing through the sample and leads starting at moment t0, when the three subsystems are connected, until a station- ary state is reached. The generic Hamiltonian of the total system consisting of the sample plus the leads is: H(t) =HL+HR+HS+HT(t): (1) Hlwithl=L;R are the Hamiltonians of the leads. We denote by "qland qlthe single-particle energies and wave functions respectively, for each lead. Using the cre- ation and annihilation operators associated to the single- particle states, cy qlandcql, we can write Hl=Z dq"qlcy qlcql: (2) HSis the Hamiltonian of the sample. In the absence of the interaction the SES have discrete energies denoted asEnand corresponding one-body wave functions n(r). Using now the creation and annihilation operators for the sample SES, dy nanddn, we can write HS=X nEndy ndn+1 2X nm n0m0Vnm;n0m0dy ndy mdm0dn0:(3) The second term in Eq. (3) is the Coulomb interaction. In the SES basis the two-body matrix elements are given by: Vnm;n0m0=Z drdr0 n(r) m(r0)u(rr0)n0(r)m0(r0); (4) whereu(rr0) is the Coulomb potential. The third term of Eq. (1) is the so-called tunneling Hamiltonian describing the transfer of particles between the leads and the sample: HT(t) =X l=L;RX nZ dql(t)(Tl qncy qldn+h:c:):(5)3 HTcontains two important elements: (1) The time de- pendent switching functions l(t) which open the contact between the leads and the sample; these functions mimic the presence of a time dependent potential barrier. (2) The coupling Tl qnbetween a state with momentum qof the leadland the state nof the isolated sample, with wave function n. The coupling coecients Tl qndepend on the energies of the coupled states and, maybe more important, on the amplitude of the wave functions in the contact region. As we have shown in our previous work7,8 this construction allows us to capture geometrical e ects in the electronic transfer. A precise de nition of the cou- pling coecients is however model speci c, and will be mentioned in the next section. The evolution of our system is completely determined by the statistical operator W(t) associated to the total Hamiltonian H(t) de ned in Eq.(1). W(t) is the solution of the quantum Liouville equation with a known initial value, prior to the coupling of the sample and leads: i~_W(t) = [H(t);W(t)]; W (tt0) =LRS;(6) The isolated leads are described by equilibrium distribu- tions, l=e (HllNl) Trlfe (HllNl)g; l=L;R; (7) and the isolated sample by the density operator S. Af- ter the coupling moment the dynamics of the sample is conveniently described by the RDO which is de ned by averaging the total statistical operator over those degrees of freedom belonging to the leads: (t) = TrLTrRW(t); (t0) =S: (8) In the absence of the electron-electron interaction the MES eigenvectors of HSare bit-strings of the form ji= ji 1;i 2;::;i n:::i, wherei n= 0;1 is the occupation number of then-th SES. The set fgis a basis in the Fock space of the isolated sample and the RDO can be seen as a matrix in this basis. From Eqs. (6)-(8) we obtain in the lowest (2-nd) order in the coupling parameters Tl qnthe GME (see Ref. 7 for details): _(t) =i ~[HS;(t)] 1 ~2X l=L;RZ dql(t)([Tql; ql(t)] +h:c:);(9) where the coupling operator Tqlhas matrix elements (Tql)=X nTl qnhjdyji: (10) The operators qland qlare de ned as ql(t) =eitHSZt t0dsl(s)ql(s)ei(st)"qleitHS; ql(s) =eisHS Ty ql(s)(1fl)(s)Ty qlfl eisHSandflis the Fermi function of the lead l. In the presence of the electron-electron interaction in the sample the MES which are eigenstates of HSare lin- ear combinations of bit-strings: HSj ) =E j ), where j ) =P C ji,C being the mixing coecients which can be found together with the energies E by diagonalizing HS. (To distinguish better between the noninteracting and the interacting MES we use the right angular bracket for the former and the regular curved bracket for the later.) Using now the set f gas a basis, i. e.theinteracting MES, the GME has the same form as Eq. (9), where the matrix elements of all operators are now de ned in the interacting basis and the matrix elements of the coupling operators are (Tql) =X nTl qn( jdyj ): (11) Because the sample is open the number of electrons N contained in the sample is not xed. The Hamiltonian HSgiven in Eq. (3) commutes with the total \number" operatorP ndy ndn. ThusNis a \good quantum number" such that any state j ) has a xed number of electrons. So the MES can also be labeled as j ) =jN;i) with i= 0;1;2;:::an index for the ground and excited states of the MES subset with Nelectrons. The many-body energies can also be written as E =E(i) N. In the practical calculations Nvaries between 0 (the vacuum state) and Nmaxwhich is the total number of SES considered in the numerical diagonalization of HS. The total number of MES is thus 2Nmax. If the coupling between the leads and the sample is not too strong we expect that only a limited number of MES participate e ectively to the electronic transport. These states are naturally selected by the bias window [R;L]. In the following examples, by selecting suitable values of the chemical potentials in the leads, we will truncate the basis of interacting MES to a reasonably small subset such that we can solve numerically Eq. (9) with our available computing resources. To relate the bias window with the e ective MES we need to consider the chemical potential of the isolated sample containing Nelectrons, (i) N=E(i) NE(0) N1; (12) which is the energy required to add the N-th electron on top of the ground state with N1 to obtain the i-th MES withNparticles.23We expect the current associated to the MESjN;i) to depend on the location of the chemical potential(i) Nrelatively to the bias window. In particular it is clear that if at the coupling moment t0the sample is empty all MES with (i) NLwill remain empty both during the transient and the steady states, so they can be safely ignored when solving the GME.4 III. MODELS AND RESULTS We have numerically implemented the GME method both for lattice and continuous models. The sample mod- els are: a short 1D chain with 5 sites, a 2D rectangular lattice with 1210 = 120 sites, and a short quantum wire withe parabolic lateral con nement. In all cases the coupling functions have the form l(t) = 12 e t+ 1(13) with a constant parameter, such that at the initial mo- ment, which is t0= 0, we have l(0) = 0 (no coupling), and in the steady state, for t!1 ,l= 1 (full coupling). A. A toy model: short 1D chain In this model the two semi-in nite leads are attached to the ends of a 1D chain with 5 sites. The coupling between a lead state with wave function qland a sam- ple state with wave function nis given by the product between the wave functions at the contact site: Tl qn=Vl  ql(0)n(il); (14) where 0 is the contact site of the lead l=L;R, the end sites of the sample being iL= 1 andiR= 5. FIG. 1: (Color online) The equilibrium chemical potentials (0) Nfor 1N5 as a function of the interaction strength U. The dotted lines mark the chemical potentials of the leads selected in the transport simulations shown in the next gure, i. e.L= 5:25 andR= 4:75. The reason to call this a toy model is that we can ob- tain the complete set of 25= 32 MES, i. e.we do not need to cut the basis of the 5 SES. We also do not need to cut the MES basis, all matrix elements of the statisti- cal operator can be numerically calculated, even if not all of them might be important for the currents. In addition we will consider the strength of the Coulomb interaction as a free parameter U, whereas in a realistic systems this is xed by the electron charge and the dielectric con- stant of the material. Our goal is to have a qualitativeunderstanding of the underlying physics, and in particu- lar to show the presence of the Coulomb blocking e ects at certain values of Uor of the chemical potentials of the leads. The Coulomb matrix elements de ned in Eq. (4) are calculated as Vnm;n0m0=X i6=i0 n(i) m(i0)U jii0jn0(i)m0(i0):(15) In Fig.1 we show the equilibrium chemical potentials (0) Ncorresponding to ground states with 1 N5 par- ticles against the interaction strength U. One observes a linear dependence of (0) NonU, with slope increasing withN. Obviously the total Coulomb energy increases both withUandN. Let us now brie y review the Coulomb blockade scenario.24Suppose the isolated sample contains Nelec- trons and the chemical potentials of the leads are cho- sen such that (0) N< R< L< (0) N+1. Then the bias window [R;L] may include one or more of the excited con gurations with Nparticles. In general some states withNelectrons may have excitation energies exceed- ingLor even(0) N+1. This situation corresponds to the Coulomb blockade phenomenon. Indeed, the addition of the (N+ 1)-th electron is energetically forbidden. Con- sequently the current in the steady state should vanish. However, shorter or longer transient currents are gener- ated by all many-body con gurations in the vicinity of the bias window. Fig. 2(a) and 2(b) show the total currents in the left lead and the total charge residing in the sample for sev- eral values of the interaction strength. Uis measured in units of tS, the hopping parameter in the sample,7 and the time is expressed in units of ~=tSwhile the cur- rent is in units of etS=~. The coupling constant in Eq. (13) is = 1. The system is initially empty and thus (0) =j00000ih00000j. The chemical potentials of the leads, L= 5:25 and R= 4:75, are chosen such that in the absence of Coulomb interaction, i. e. forU= 0,(0) 4is located within the bias window. In this case we obtain in the steady state the mean number of electrons about 3.6 and a non-vanishing current in the leads. This is understand- able, since (0) 4=E4= 5, which is the 4-th level of the isolated sample. The occupation of this level in the steady state is about 0.6, the other states being either full or empty. Also in this case, the excited states have small contributions to the steady state current as the system tends to be in the ground state with N= 3 electrons. Those contributions may also depend on the coupling strength of individual states with the leads, but in gen- eral remain small.25 The situation may change for U6= 0. For the inter- acting system, e. g. forU= 0:3, the system settles down in the Coulomb blockade regime, the total current be- ing almost suppressed in the steady state. This happens because the interaction pushes the chemical potentials upwards such that for U= 0:3 both ground states with5 FIG. 2: (Color online) The total current entering the 5 1 sample from the left lead as a function of time for the di erent values of the interaction strength U. The chemical potentials of the leads L= 5:25 andR= 4:75. N= 3 andN= 4 electrons are outside the bias win- dow and cannot produce steady currents. When the in- teraction strength is further increased to U= 0:5 and U= 1 the steady state currents are gradually restored. This could look surprising, but one can see in Fig.1 that by increasing Uthe ground state con guration with 3 electrons approaches and enters the bias window. Con- sequently the transport becomes again possible. Note that while the steady state currents are not monotonous w.r.t.Uthe charge absorbed in the system continuously decreases, Fig. 2(b). In transport experiments the strength of the electron- electron interaction is indeed xed. The usual way to obtain the Coulomb blockade is to vary the chemical po- tentials of the leads relatively to the energy levels of the sample, or vice versa. In Fig. 3 we show the currents in both leads for di erent values of the chemical poten- tialR, while keeping xed L= 7. The strength of the Coulomb interaction is U= 1 and(0) 4almost equals L. The steady state value of the current decreases as Rincreases, because fewer states are included in the bias window. The Coulomb blockade onset occurs for R>5, when(0) 3drops below R. We observe that the FIG. 3: The time-dependent total currents in the left and right leads at di erent values of the chemical potential R. The current in the right lead starts at negative values. Other parameters: VL=VR= 0:750,U= 1:0. maximum value of the total current in the left lead does not change much when Rvaries. In contrast, the tran- sient current in the right lead is negative and increases in magnitude as Rincreases. This means that the right lead feeds the many-body con gurations that fall below R. The contribution of the excited states to the transient and steady state currents depends strongly on the bias window. In Fig. 4 we show the currents entering the sam- ple from the left lead, carried by the states with N= 2 andN= 3 electrons, for R= 3;4;5 (the cases with non- vanishing current in the steady state). We also show sep- arately the contribution to the currents associated to the ground state con gurations, related to (0) 2and(0) 3, and the complementary contribution of all the excited states with 2 and 3 particles. In this case the wave vectors of the ground states are mostly given by the non-interacting wave vectors:j11000iwith weight 97% and j11100iwith 98% forN= 2 andN= 3 respectively. ForR= 3 the steady state current of the ground state con guration is vanishingly small and so the total negative current associated to two-particle states comes mostly from the excited states. In the many-body energy spectrum of the isolated sample we obtain 5 excited con- gurations with (i) 22[R;L] = [3;7]. AsRmoves up the steady state current of the ground state with N= 2 becomes also negative. The combined contributions of the excited states vanishes at R= 5. As can be seen from Fig. 1 R= 5 is well above (0) 2, but very close to (0) 3. Consequently, the ground con guration with N= 2 is heavily populated in the steady state, whereas the ex- cited states have low probability and thus weak current. Actually, as we have checked, all the currents associated to each excited state with N= 2 vanish individually. In the transient regime however the N= 2 currents in all three cases are dominated by the excites states. The currents of the excited states having N= 3 elec-6 FIG. 4: The separate contributions to the current of the ground state with Nparticles and of allexcited states with Nparticles, for di erent values of R. For completeness we also include the total currents JLfor the same con gura- tions. The discussion is made in the text. Other parameters: VL=VR= 0:750,U= 1:0. trons are positive at R= 3, but change sign at R= 4. ForR= 5 their magnitude exceeds the contribution of the ground state which is always positive. A more de- tailed analysis of the currents carried by speci c excited states will be given for the 2D model. Finally, both in the transient and in the steady states the currents have small periodic uctuations determined by the permanent transitions of electrons between the states in the sample and the states in the leads and back.25They are best seen in Fig. 2(a). Such uctuations have also been obtained very recently by Kurth et al. us- ing combination of the non-equilibrium Green's functions and the time dependent density-functional theory of the Coulomb interaction.26 B. 2D lattice We show now results for a 2D rectangular lattice with 1210 sites. For a lattice constant of a= 5 nm this sample can be seen as a discrete version of a quantum dot of 60 nm50 nm. We used the lowest 10 SES of the non-interacting sample in the numerical diagonalization of the interacting Hamiltonian. This number is sucient to produce convergent results for the rst 50 MES for an interaction strength U= 0:8. The Coulomb matrix elements are calculated in the same way as for the 1Dcase, Eq. (15), except that now the site indices are two- dimensional, i. e.i= (ix;iy) andi0= (i0 x;i0 y). The two contact sites are chosen at diagonally opposite corners of the sample. The coupling coecients are cal- culated with Eq. (14), like for the 1D chain, and depend on the wave function of the particular SES at the con- tact sites. These coecients are illustrated in Fig. 5(a). The reduced density matrix is calculated using the rst 50 MES. This allowed us to take into account many-body con gurations with up to 3 electrons. In Fig. 5(b) we show the chemical potentials (i) Nfor the ground and excited states with N= 1;2;and 3 par- ticles. At the initial moment t0= 0 the system is empty. Based on the previous example, the main contribution to the currents in the steady states is expected from those MES with ground state chemical potentials located inside the bias window [ R;L]. One also observes excited con- gurations with Nparticles having chemical potentials larger than (0) N+1. FIG. 5: (Color online) (a) The coupling amplitudes jTqnj2 forn= 1;::;5 between single-particle states in the leads with momentum qand the lowest 5 single-particle states of the isolated dot. (b) The generalized chemical potentials for N- particle interacting con gurations. The red crosses mark (0) N while the other ones correspond to generalized potentials (i) N related to the i-th excited state of the Nparticle system. In the following we discuss the currents carried by the7 various many-body states involved in transport. In a rst series of calculations we selected the chemical potential R= 0:2 and used two values of the chemical potential of the left lead L= 0:4 andL= 0:6. ForR= 0:2 and L= 0:4 the bias window contains only the 1-st and the 2-nd excited con gurations with N= 1, Fig. 5(b). The ground states for N= 1 andN= 2 are instead located below and above the bias window, respectively. Conse- quently the steady state current is very small. When Lincreases to 0.6 the ground state con guration with N= 2 enters the bias window and the current increases, Fig. 6(a). To analyze the transient regime we split the current into contributions given by the ground state and excited states with 1 electron (see Fig. 6(b)). When L= 0:4 the 1-st and 2-nd excited state carry currents exceeding the current associated to the ground state, which survive all the way to the steady state. The current corresponding to the 2-nd excited state is smaller than the current of the 1-st excited state, but comparable to that of the ground state. This is explained by the strength of the coupling coecients shown in Fig. 5(a), the 2-nd single-particle state being stronger coupled to the leads. The remaining higher excited states give oscillating and fast decaying transient currents. In Fig. 6(c) L= 0:6 and therefore higher excited states enter the bias window; their tran- sient currents are still decaying but at a smaller rate. Comparing with Fig. 6(a) it in clear that the transient regime is dominated by excited states. Next we discuss currents associated with states having 2 and 3 electrons. We keep now xed R= 0:35 and again increase Lstarting with 0.6. Fig. 7(a) shows the total currents in the left lead for N= 2 andN= 3. As the bias increases the transient currents are enhanced, but they become comparable as the system approaches the steady state. In Fig. 7(b) the total current on three particle states shows a di erent behavior: the steady states value increases drastically when Lmoves up. To explain this one can look again at the diagram of the chemical potentials, Fig. 5(b). At L= 0:6 the 3-particle con gurations are above the bias window and as such they contribute less to the current. In contrast, as L increases the ground state con guration with N= 3 en- ters the bias window, the window is closer to the excited states, and thus the total current increases. Actually, for L= 0:8 and 0:9 the current for N= 3 does not reach the steady state in the time interval considered. Now we look at the contribution of the excited states withN= 2 for two cases, L= 0:6 andL= 0:9. Again, the inspection of the diagram in Fig. 5(b) predicts the results of Fig. 8. When L= 0:6 there is just one excited con guration within the bias window, in addition to the ground state. In Fig. 8(a) we see that in the steady state these two con gurations give signi cant contributions to the current, whereas the higher excited states play a role only in the transient regime. Fig. 8(b) shows that at L= 0:9 the currents of the excited states and of the ground state are decreasing, some of them reaching even FIG. 6: (a) The total currents in the left and right leads for L= 0:6 andL= 0:4, while keeping R= 0:2. (b) The partial currents in the left lead for single-particle states when L= 0:4 andR= 0:2. (c) The partial currents in the left lead for single-particle states when L= 0:6 andR= 0:2 negative values towards the steady state. This happens because the bias window includes now the ground state withN= 3 and the excited states with N= 2 deplete in the favor of the ground state. The sign of the current carried by states with Npar- ticles depends on the placement of the corresponding ground state chemical potential relatively to the bias win- dow. For example if we x L= 1:5 andR= 0:65 we8 FIG. 7: (a) The total current in the left lead carried by all many-body con gurations with N= 2, for increasing values ofL(i. e.0.6,0.7,0.8 and 0.9) and R= 0:2. (b) The same forN= 3. obtain(0) 2< L. Fig. 9(a) shows the N-particle cur- rents when the sample initially contains two electrons in the ground state. This initial state evolves faster to the steady state than the empty system. While for N= 3 the current in the left lead is positive, for both N= 2 andN= 1 the currents are negative. The charge re- siding on each N-particle state and the total charge are shown in Fig. 9(b). Since single-particle con gurations are unlikely their occupation vanishes. The total charge accumulated on the N= 3 states increases up to 2, while the total charge on the N= 2 states decreases from 2 to 0.75. The sign of the current for N= 2 becomes pos- itive when Ris lowered to 0.2, Fig. 9(c), and exceeds the current carried by the states with N= 3. This is because the 1-st and the 2-nd SES practically determine the ground state with two electrons and thus (0) 2, and also because the 1-st SES is strongly coupled to the leads. However, the current with N= 1 is still negative. FIG. 8: (a) The total current in the left lead carried by all many-body con gurations with N= 2 atL= 0:6. (b) The same forL= 0:9. Other parameters R= 0:35. C. Parabolic quantum wire In this subsection we apply the GME with Coulomb interaction to describe the transport through a short quantum wire of length Lx= 300 nm with a parabolic con nement in the y-direction perpendicular to the di- rection of transport. The contact ends of the isolated wire atLx=2 are described by hard walls. This is now a continuous model, where a large functional ba- sis is used to expand the eigenfunctions of the system in. In a similar manner we use a functional basis with complete truncated sets of continuous and discrete func- tions to expand the eigenfunctions of the semi-in nite parabolic leads in. To show that we can describe the com- bined geometrical e ects imposed on the system by it's geometry and an external perpendicular magnetic eld we place the quantum wire is in an external magnetic eld of strength 1 :0 T. The characteristic con nement energy is given by ~ 0= 1:0 meV. We assume GaAs parameters with m= 0:067me,= 12:4 meV. The magnetic length modi ed by the parabolic con nement isaw=p ~=(m w), with 2 w= 2 0+!2 c. and the cyclotron frequency !c=eB=(mc). AtB= 1:0 T, aw= 23:87 nm. The semi-in nite leads having the same9 FIG. 9: (a) The total current in the left lead carried by N- particle states and the total charge. for L= 1:5 and for R= 0:65. (b) The occupation number of the N-particle states. (c) The total current in the left lead carried by N- particle states for L= 1:2 andR= 0:2. (d) The occupation number of the N-particle states and the total charge.parabolic con nement and being subject to the same ex- ternal perpendicular magnetic eld have a continuous en- ergy spectrum with discrete Landau sub-bands. The Coulomb potential in Eq. (4) in the 2D wire is described by u(rr0) =e2 p (xx0)2+ (yy0)2+2; (16) with the small convergence parameter ( =aw) = 0:01 to facilitate the two-dimensional numerical integration needed for the matrix elements (4). After the GME (9) has been transformed to the in- teracting many-electron basis by the unitary transfor- mation obtained by the diagonalization of HS(3) we truncate the RDO (8) to 32 MES. For the bias range 0:0=LR1:7 meV used here 10 SES are sucient to obtain these lowest 32 states with good accu- racy. We will be omitting singly occupied states of high energy that should not be relavant for the parameters here. The natural strength of the Coulomb interaction will only give us MES that are occupied by one or two electrons in the energy range 0 to 6 meV covered by the 32 MES. Since in the partitioning approach [ HS;HL] = 0 we have to construct Tl qnas a non-local overlap ofnand L;R qon the contact regions Cl; l=L;R:8 Tl qn=Z Cldrdr0  ql(r)n(r)gl qn(r;r0) +h:c: :(17) gl qn(r;r0) =gl 0exp l 1(xx0)2l 2(yy0)2 expjEn"qlj l E : (18) As before"qlis the energy spectrum of lead l, andEn is the energy of the SES numbered by nin the quan- tum wire. The quantum number qfor the states in leads represents both the discrete Landau band number and a continuous quantum number that can be related to the momentum of a particular state. Here we use the pa- rameters1a2 w=2a2 w= 0:25, LR E= 0:25 meV, and gLR 0= 40 meV for B= 1:0 T. The domain of the over- lap integral for the leads is 2awinto the lead or the system forxandx0from each end of the wire at Lx=2 and between4awforyandy0, see Ref. (8) for an exact de nition. All the SES will be coupled to the leads, but the coupling strength will depend on the character of the SES, whether it is an edge- or bulk state and other ner geometrical details that is brought about by the magnetic eld. The right chemical potential Ris held at 1 :4 meV and the transport properties are calculated for di erent values of the bias  by varyingL. Figure 10 compares the total occupation of all one- electron and two-electron MES for the interacting system at two di erent values of the bias. At,  = 0:2 meV we see that almost solely10 FIG. 10: (Color online) The total charge residing in one- and two-electron states as a function of time for two di erent val- ues of the bias  .B= 1:0 T,Lx= 300 nm, ~ 0= 1:0 meV. one-electron states are occupied, while for  = 1:2 meV initially it is likely to have one-electron states occupied, but very soon the occupation of the two-electron states becomes as probable with the likelihood of the occupa- tion of the one-electron states fast reducing with time. We also have to admit here that even though the steady state value of the total current through the system can be deduced by the values of the current at 270 ps, the charging of the system takes much longer time, since we are using here a very weak coupling to the leads that mimics a tunneling regime. If we now use the average value of the current in the left and right leads at t= 270 ps as a measure of the steady state current we get the information displayed in Fig. 11, where the steady state value of the current is shown for the interacting system as a function of the bias and compared to the charge in the system. We have a clear Coulomb blocking in the interacting system. In the case of a non-interacting system the lack of a gap between the one- and two electron MES and a strong mixing of the energy regimes of two- and three-electron states the two- electron plateau only appears as a small shoulder. The FIG. 11: The total steady state current for interacting 10 SES, and the total charge at t= 270 ps. for di erent values of the bias  .B= 1:0 T,Lx= 300 nm, ~ 0= 1:0 meV. 32 MES selected here include no three-electron or MES with higher number of electrons. It should be mentioned here that a di erent choice of the right bias Rcan result in the system charging faster and thus at the same time the total current through it being smaller. This comes from the fact that the states have a di erent coupling to the leads and the time range shown here is very much in the transient- or it's long exponential decay regime. Figure 12 displaying the current in the right lead gives an idea how the Coulomb blocking plateau appears after the transition regime. The transition regime where the FIG. 12: The total current in the right lead for interacting and non-interacting 10 SES as a function of the bias  and time.B= 1:0 T,Lx= 300 nm, ~ 0= 1:0 meV. right current goes negative, i. e.where it supplies charge to the system is partially truncated from the gure.11 IV. SUMMARY AND CONCLUSIONS We calculated time-dependent currents in open meso- scopic systems composed by a sample attached to two semi-in nite leads, by solving the generalized master equation for the reduced density operator acting in the Fock space of the sample. This is the natural frame- work for including the Coulomb electron-electron inter- action in the sample, which is the main achievement of this work. The Coulomb interaction is treated in the spirit of the exact diagonalization method, i. e.in a pure many-body manner. The interacting many-body states of the sample are expanded in the basis of non-interacting \bit-string" states with unspeci ed number of electrons. We believe our method is a viable alternative to a recent approach based on a time-dependent density-functional model.9,10,26We used three sample models, a short 1D wire with 5 sites, but also a larger 2D lattice with 120 sites and a continuous model, whereas the cited group used much smaller samples even with no structure.26 Indeed, due to computational limitations we could use only a restricted, e ective number of many-body states in the GME, between 30-50 depending on the model, from the bottom of the energy spectrum. We chose the bias window [R;L] and the strength of the sample-leads coupling parameters VR;Lsuch that only the e ective states contribute to the transport of electrons through the sample, whereas the states with higher energy are unreachable by the electrons. Consequently the number of electrons in the sample can be only up to 3 or 4. We could calculate the contribution to the charge and currents in the sample and in the leads respectively, cor- responding to any particular many-body state. We use the 1D chain as a toy model to emphasize the dominant role of the excited states in the transient regime and the onset of the Coulomb blockade in the steady state. A similar 1D model with 4 sites 1D has been considered recently by My oh anen et al.10 As shown also in our previous works on time-dependenttransport in non-interacting systems the GME method includes information on the energy structure of the sam- ple, but also on the geometrical properties re ected in the wave functions and sample-lead contacts.7,8,25Here we illustrate these aspects, in the interacting case, for two nanosystems: a two-dimensional quantum dot described by a lattice Hamiltonian and a short parabolic quantum wire. The time-dependent occupation of speci c many- body states was thoroughly analyzed, for di erent values of the chemical potentials of the leads. It turned out that the excited states with Nelectrons contribute to the steady state currents if the ground state con guration withN+ 1 particles is not available for transport. How- ever, if(0) N<Rand at the same time (0) N+1lies within the bias window the excited states with Nparticles are active only in the transient regime and become de- populated in the steady state regime. This behavior is of interest in the excited-state spectroscopy experiments.11 To our knowledge the time-dependent currents associated to excited states have not been discussed theoretically so far. Acknowledgments The authors acknowledge nancial support from the Development Fund of the Reykjavik University Grant No. T09001, the Research and Instruments Funds of the Icelandic State, the Research Fund of the University of Iceland, the Icelandic Science and Technology Research Programme for Postgenomic Biomedicine, Nanoscience and Nanotechnology, the National Science Council of Tai- wan under contract No. NSC97-2112-M-239-003-MY3. V.M. also acknowledges the hospitality of the Reykjavik University, Science Institute and the partial nancial sup- port from PNCDI2 program (grant No. 515/2009) and grant No. 45N/2009. 1G. Stefanucci, S. Kurth, A. Rubio and E. K. U. Gross, Phys. Rev. B 77, 075339 (2008). 2V. Moldoveanu, A. Manolescu and V. Gudmundsson, Phys. Rev. B 76, 085330 (2007) 3X. Zheng, F. Wang, C. Y. Yam, Y. Mo, and G.H. Chen, Phys. Rev. B 75, 195127 (2007). 4V. Gudmundsson, G. Thorgilsson, C-S Tang, and V. Moldoveanu, Phys. Rev. B 77, 035329 (2008). 5U. Harbola, M. Esposito, and S. Mukamel, Phys. Rev. B 74, 235309 (2006). 6S. Welack, M. Schreiber, and U. Kleinekath ofer, J. Chem. Phys. 124, 044712 (2006) 7V. Moldoveanu, A. Manolescu and V. Gudmundsson, New J. Phys. 11, 073019 (2009). 8V. Gudmundsson, C. Gainar, C-S Tang, V. Moldoveanu, A. Manolescu, to appear in New J. Phys. 9S. Kurth, G. Stefanucci, C.-O. Almbladh, A. Rubio, andE. K. U. Gross, Phys. Rev. B 72, 035308 (2005). 10P. My oh anen, A. Stan, G. Stefanucci, and R. van Leeuwen, Phys. Rev. B 80, 115107 (2009), Europhys. Lett. 84, 67001 (2008). 11T. Fujisawa, D. G. Austing, Y. Tokura, Y. Hirayama, and S. Tarucha, J. Phys.: Condens. Matter 15, R1395 (2003). 12D. C. Langreth and P. Nordlander, Phys. Rev. B 43, 2541 (1991) 13S. A. Gurvitz and Ya. S. Prager, Phys. Rev. B 53, 15932 (1996). 14J. K onig, H. Schoeller, and G. Sch on, Phys. Rev. Lett. 76, 1715 (1996); J. K onig, J. Schmid, H. Schoeller, and G. Sch on, Phys. Rev. B 54, 16 820 (1996). 15D. Becker and D. Pfannkuche, Physical Review B 77 205307 (2008). 16S. Nakajima, Prog. Theor. Phys. 20, 948 (1958). 17R. Zwanzig, J. Chem. Phys. 33, 1338 (1960).12 18C. Timm, Phys. Rev. B 77, 195416 (2008). 19X. Q. Li and Y. J. Yan, Phys. Rev. B 75, 075114 (2007). 20M.Esposito and M. Galperin, Phys. Rev. B 79, 205303 (2009). 21D. Darau, G. Begemann, A. Donarini, and M. Grifoni, Physical Review B 79235404 (2009). 22C. Caroli, R. Combescot, P. Nozieres, and D. Saint-James, J. Phys. C 4, 916 (1971). 23E. Vaz, J. Kyriakidis, J. Chem. Phys. 129, 024703 (2008) 24L.P. Kouwenhouven et al., in Mesoscopic Electron Trans-port, edited by L.L. Sohn, L.P. Kouwenhouven, and G. Schn, NATO Advanced Study Institute, Series E, Vol. 345 (Kluwer, Dordrecht, 1997). 25V. Moldoveanu, A. Manolescu and V. Gudmundsson, Phys. Rev. B 80, 205325 (2009). 26S. Kurth, G. Stefanucci, E. Khosravi, C. Verdozzi, ad E. K. U. Gross, e-print arXiv:0911.3870 [cond-mat.mes-hall] (2009).