English

Quantum Boltzmann equation for bilayer graphene

Mesoscale and Nanoscale Physics 2020-01-22 v5 Strongly Correlated Electrons High Energy Physics - Theory

Abstract

A-B stacked bilayer graphene has massive electron and hole-like excitations with zero gap in the nearest-neighbor hopping approximation. In equilibrium, the quasiparticle occupation approximately follows the usual Fermi-Dirac distribution. In this paper we consider perturbing this equilibrium distribution so as to determine DC transport coefficients near charge neutrality. We consider the regime βμ1\beta |\mu| \lesssim 1 (with β\beta the inverse temperature and μ\mu the chemical potential) where there is not a well formed Fermi surface. Starting from the Kadanoff-Baym equations, we obtain the quantum Boltzmann equation of the electron and hole distribution functions when the system is weakly perturbed out of equilibrium. The effect of phonons, disorder, and boundary scattering for finite sized systems are incorporated through a generalized collision integral. The transport coefficients, including the electrical and thermal conductivity, thermopower, and shear viscosity, are calculated in the linear response regime. We also extend the formalism to include an external magnetic field. We present results from numerical solutions of the quantum Boltzmann equation. Finally, we derive a simplified two-fluid hydrodynamic model appropriate for this system, which reproduces the salient results of the full numerical calculations.

Keywords

Cite

@article{arxiv.1901.07039,
  title  = {Quantum Boltzmann equation for bilayer graphene},
  author = {Dung X. Nguyen and Glenn Wagner and Steven H. Simon},
  journal= {arXiv preprint arXiv:1901.07039},
  year   = {2020}
}

Comments

27 pages, 7 figures, fixed typos, add a section on a two-fluid model

R2 v1 2026-06-23T07:17:47.001Z