Steady-state density functional theory for thermoelectric effects
Abstract
The recently proposed density functional theory for steady-state transport (i-DFT) is extended to include temperature gradients between the leads. Within this framework, a general and exact expression is derived for the linear Seebeck coefficient which can be written as the sum of the Kohn-Sham coefficient and an exchange-correlation contribution. The formalism is applied to the single-impurity Anderson model for which approximate exchange-correlation functionals are suggested for temperatures both above and below the Kondo temperature. A certain structural property of the exchange-correlation potentials in the Coulomb blockade regime allows to recover an earlier result expressing the Seebeck coefficient in terms of quantities of equilibrium density functional theory. The numerical i-DFT results are compared to calculations with the numerical renormalization group over a wide range of temperatures finding a reasonable agreement while i-DFT comes at a much lower computational cost.
Cite
@article{arxiv.1909.11019,
title = {Steady-state density functional theory for thermoelectric effects},
author = {Nahual Sobrino and Roberto D'Agosta and Stefan Kurth},
journal= {arXiv preprint arXiv:1909.11019},
year = {2019}
}
Comments
7 pages, 8 figures, RevTeX4