Quantum transport equations for low-dimensional multiband electronic systems. I
Abstract
A systematic method of calculating the dynamical conductivity tensor in a general multiband electronic model with strong boson-mediated electron-electron interactions is described. The theory is based on the exact semiclassical expression for the coupling between valence electrons and electromagnetic fields and on the self-consistent Bethe--Salpeter equations for the electron-hole propagators. The general diagrammatic perturbation expressions for the intraband and interband single-particle conductivity are determined. The relations between the intraband Bethe--Salpeter equation, the quantum transport equation and the ordinary transport equation are briefly discussed within the memory-function approximation. The effects of the Lorentz dipole-dipole interactions on the dynamical conductivity of low-dimensional models are described in the same approximation. Such formalism proves useful in studies of different (pseudo)gapped states of quasi-one-dimensional systems with the metal-to-insulator phase transitions and can be easily extended to underdoped two-dimensional high- superconductors.
Cite
@article{arxiv.1302.6062,
title = {Quantum transport equations for low-dimensional multiband electronic systems. I},
author = {I. Kupcic and Z. Rukelj and S. Barisic},
journal= {arXiv preprint arXiv:1302.6062},
year = {2013}
}
Comments
13 pages, 10 figures