Solution of the quantum Boltzmann equation in linear transport

B. A. Paez; A. Moreno; H. Méndez

doi:10.1142/s0218625x02004360

Solution of the quantum Boltzmann equation in linear transport

B. A. Paez
, A. Moreno
, H. Méndez

Department of Physics

Universidad Javeriana

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

Abstract

The one-dimensional quantum Boltzmann equation in linear transport approximation was solved using the nonequilibrium Green's function method, and based on the lifetime approximation. As an example, the effect of interactions with electric fields were included, and the thermoelectric power coefficient (α) was evaluated, based on calculations of the statistical density current in a stationary regime over the nonequilibrium distribution function, and by the Greens function method. Results are compared in order to explore the advantages of each one, in evaluating the other kinetic transport coefficients.

Original language	English
Pages (from-to)	1761-1763
Number of pages	3
Journal	Surface Review and Letters
Volume	9
Issue number	5-6
DOIs	https://doi.org/10.1142/s0218625x02004360
State	Published - 2002

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title = "Solution of the quantum Boltzmann equation in linear transport",

abstract = "The one-dimensional quantum Boltzmann equation in linear transport approximation was solved using the nonequilibrium Green's function method, and based on the lifetime approximation. As an example, the effect of interactions with electric fields were included, and the thermoelectric power coefficient (α) was evaluated, based on calculations of the statistical density current in a stationary regime over the nonequilibrium distribution function, and by the Greens function method. Results are compared in order to explore the advantages of each one, in evaluating the other kinetic transport coefficients.",

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AU - Moreno, A.

AU - Méndez, H.

PY - 2002

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N2 - The one-dimensional quantum Boltzmann equation in linear transport approximation was solved using the nonequilibrium Green's function method, and based on the lifetime approximation. As an example, the effect of interactions with electric fields were included, and the thermoelectric power coefficient (α) was evaluated, based on calculations of the statistical density current in a stationary regime over the nonequilibrium distribution function, and by the Greens function method. Results are compared in order to explore the advantages of each one, in evaluating the other kinetic transport coefficients.

AB - The one-dimensional quantum Boltzmann equation in linear transport approximation was solved using the nonequilibrium Green's function method, and based on the lifetime approximation. As an example, the effect of interactions with electric fields were included, and the thermoelectric power coefficient (α) was evaluated, based on calculations of the statistical density current in a stationary regime over the nonequilibrium distribution function, and by the Greens function method. Results are compared in order to explore the advantages of each one, in evaluating the other kinetic transport coefficients.

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DO - 10.1142/s0218625x02004360

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JO - Surface Review and Letters

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Solution of the quantum Boltzmann equation in linear transport

Abstract

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