A Cartesian quasi-classical model to nonequilibrium quantum transport: The Anderson impurity model

Bin Li; Tal J. Levy; David W.H. Swenson; Eran Rabani; William H. Miller

doi:10.1063/1.4793747

A Cartesian quasi-classical model to nonequilibrium quantum transport: The Anderson impurity model

Bin Li, Tal J. Levy, David W.H. Swenson, Eran Rabani, William H. Miller

School of Chemistry

Tel Aviv University

Research output: Contribution to journal › Article › peer-review

Abstract

We apply the recently proposed quasi-classical approach for a second quantized many-electron Hamiltonian in Cartesian coordinates B. Li and W. H. Miller, J. Chem. Phys. 137, 154107 (2012)10.1063/1.4757935 to correlated nonequilibrium quantum transport. The approach provides accurate results for the resonant level model for a wide range of temperatures, bias, and gate voltages, correcting the flaws of our recently proposed mapping using action-angle variables. When electron-electron interactions are included, a Gaussian function scheme is required to map the two-electron integrals, leading to quantitative results for the Anderson impurity model. In particular, we show that the current mapping is capable of capturing quantitatively the Coulomb blockade effect and the temperature dependence of the current below and above the blockade.

Original language	English
Article number	104110
Journal	Journal of Chemical Physics
Volume	138
Issue number	10
DOIs	https://doi.org/10.1063/1.4793747
State	Published - 14 Mar 2013

All Science Journal Classification (ASJC) codes

General Physics and Astronomy
Physical and Theoretical Chemistry

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title = "A Cartesian quasi-classical model to nonequilibrium quantum transport: The Anderson impurity model",

abstract = "We apply the recently proposed quasi-classical approach for a second quantized many-electron Hamiltonian in Cartesian coordinates B. Li and W. H. Miller, J. Chem. Phys. 137, 154107 (2012)10.1063/1.4757935 to correlated nonequilibrium quantum transport. The approach provides accurate results for the resonant level model for a wide range of temperatures, bias, and gate voltages, correcting the flaws of our recently proposed mapping using action-angle variables. When electron-electron interactions are included, a Gaussian function scheme is required to map the two-electron integrals, leading to quantitative results for the Anderson impurity model. In particular, we show that the current mapping is capable of capturing quantitatively the Coulomb blockade effect and the temperature dependence of the current below and above the blockade.",

author = "Bin Li and Levy, {Tal J.} and Swenson, {David W.H.} and Eran Rabani and Miller, {William H.}",

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T1 - A Cartesian quasi-classical model to nonequilibrium quantum transport

T2 - The Anderson impurity model

AU - Li, Bin

AU - Levy, Tal J.

AU - Swenson, David W.H.

AU - Rabani, Eran

AU - Miller, William H.

PY - 2013/3/14

Y1 - 2013/3/14

N2 - We apply the recently proposed quasi-classical approach for a second quantized many-electron Hamiltonian in Cartesian coordinates B. Li and W. H. Miller, J. Chem. Phys. 137, 154107 (2012)10.1063/1.4757935 to correlated nonequilibrium quantum transport. The approach provides accurate results for the resonant level model for a wide range of temperatures, bias, and gate voltages, correcting the flaws of our recently proposed mapping using action-angle variables. When electron-electron interactions are included, a Gaussian function scheme is required to map the two-electron integrals, leading to quantitative results for the Anderson impurity model. In particular, we show that the current mapping is capable of capturing quantitatively the Coulomb blockade effect and the temperature dependence of the current below and above the blockade.

AB - We apply the recently proposed quasi-classical approach for a second quantized many-electron Hamiltonian in Cartesian coordinates B. Li and W. H. Miller, J. Chem. Phys. 137, 154107 (2012)10.1063/1.4757935 to correlated nonequilibrium quantum transport. The approach provides accurate results for the resonant level model for a wide range of temperatures, bias, and gate voltages, correcting the flaws of our recently proposed mapping using action-angle variables. When electron-electron interactions are included, a Gaussian function scheme is required to map the two-electron integrals, leading to quantitative results for the Anderson impurity model. In particular, we show that the current mapping is capable of capturing quantitatively the Coulomb blockade effect and the temperature dependence of the current below and above the blockade.

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M3 - مقالة

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JF - Journal of Chemical Physics

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A Cartesian quasi-classical model to nonequilibrium quantum transport: The Anderson impurity model

Abstract

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