Universal electric current of interacting resonant-level models with asymmetric interactions: An extension of the Landauer formula

Nishino, Akinori; Hatano, Naomichi; Ordóñez, Gonzalo

doi:10.1103/physrevb.91.045140

Cited by 8 publications

(12 citation statements)

References 42 publications

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“…NESS wavefunctions for the IRL and AIM have previously been obtained by Nishino and collaborators [8][9][10][11]; our more general approach recovers some of their results in special cases. We discuss these special cases in more detail below.…”

Section: Introductionsupporting

confidence: 70%

“…Refs. [8], [9], and [10] present the NESS wavefunction in the two lead case. The results seem to agree with ours for N = 2, 3 electrons (when we take the steady state limit of the wavefunction we find below); while the authors obtained the general N case as well, it is not written explicitly.…”

Section: E Time-evolving Wavefunction Of the Multi-lead Irlmentioning

confidence: 99%

“…Ref. [10] allows the tunnelings and Coulomb interactions to be leaddependent, which is a more general case than we consider here; also, Refs. [16], [17] present NESS wavefunctions for N = 2, 3 electrons with two leads and two quantum dots.…”

Section: E Time-evolving Wavefunction Of the Multi-lead Irlmentioning

confidence: 99%

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Many-body wavefunctions for quantum impurities out of equilibrium. II. Charge fluctuations

Culver,

Andrei

2020

Preprint

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We extend the general formalism discussed in the previous paper to two models with charge fluctuations: the interacting resonant level model and the Anderson impurity model. In the interacting resonant level model, we find the exact time-evolving wavefunction and calculate the steady state impurity occupancy to leading order in the interaction. In the Anderson impurity model, we find the non-equilibrium steady state for small or large Coulomb repulsion U , and we find that the steady state current to leading order in U agrees with a Keldysh perturbation theory calculation.

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Section: Introductionsupporting

confidence: 70%

Section: E Time-evolving Wavefunction Of the Multi-lead Irlmentioning

confidence: 99%

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Many-body wavefunctions for quantum impurities out of equilibrium. II. Charge fluctuations

Culver,

Andrei

2020

Preprint

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“…( 9) is still valid because it does not break our assumptions; we may even be able to derive microscopic expressions extending the Landauer-Büttiker formalism as in Refs. [51,52]. Using Christen and Büttiker's nonlinear scattering theory, in which electron-electron interactions are treated as mean-field charging effects [18,19,[35][36][37][53][54][55], we can construct the same formalism by replacing τ ( ) with τ ( , T L , T R , µ L , µ R ).…”

Section: Discussionmentioning

confidence: 99%

Thermodynamics of the mesoscopic thermoelectric heat engine beyond the linear-response regime

Yamamoto

Hatano

2015

Phys. Rev. E

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Mesoscopic thermoelectric heat engine is much anticipated as a device that allows us to utilize with high efficiency wasted heat inaccessible by conventional heat engines. However, the derivation of the heat current in this engine seems to be either not general or described too briefly, even inappropriate in some cases. In this paper, we give a clear-cut derivation of the heat current of the engine with suitable assumptions beyond the linear-response regime. It resolves the confusion in the definition of the heat current in the linear-response regime. After verifying that we can construct the same formalism as that of the cyclic engine, we find the following two interesting results within the Landauer-Büttiker formalism: the efficiency of the mesoscopic thermoelectric engine reaches the Carnot efficiency if and only if the transmission probability is finite at a specific energy and zero otherwise; the unitarity of the transmission probability guarantees the second law of thermodynamics, invalidating Benenti et al.'s argument in the linear-response regime that one could obtain a finite power with the Carnot efficiency under a broken time-reversal symmetry. These results demonstrate how quantum mechanics constrains thermodynamics.

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“…It is known as the scaling limit, and universal features of the steady-state current, such as the power-law behavior at large bias voltages, manifest themselves. 2-4, [6][7][8][9] In an earlier FRG approach, the current was computed from the self-energy employing the Meir-Wingreen formula. 30 In this subsection, it is discussed that an alternative FRG formulation can be developed in which a flow equation for the current is derived and solved.…”

Section: A a Consistency Check For The Currentmentioning

confidence: 99%

Current noise of the interacting resonant level model

2016

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We study the zero-frequency current noise of the interacting resonant level model for arbitrary bias voltages using a functional renormalization group approach. For this we extend the existing nonequilibrium scheme by deriving and solving flow equations for the current-vertex functions. On-resonance artificial divergences of the latter found in lowest-order perturbation theory in the two-particle interaction are consistently removed. Away from resonance they are shifted to higher orders. This allows us to gain a comprehensive picture of the current noise in the scaling limit. At high bias voltages, the current noise exhibits a universal power-law decay, whose exponent is, to leading order in the interaction, identical to that of the current. The effective charge on resonance is analyzed in detail, employing properties of the vertex correction. We find that it is only modified to second or higher order in the two-particle interaction.

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Universal electric current of interacting resonant-level models with asymmetric interactions: An extension of the Landauer formula

Cited by 8 publications

References 42 publications

Many-body wavefunctions for quantum impurities out of equilibrium. II. Charge fluctuations

Many-body wavefunctions for quantum impurities out of equilibrium. II. Charge fluctuations

Thermodynamics of the mesoscopic thermoelectric heat engine beyond the linear-response regime

Current noise of the interacting resonant level model

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