Optical conductivity of a Dirac-Fermi liquid

Abstract

A Dirac-Fermi liquid (DFL)--a doped system with Dirac spectrum--is an important example of a non-Galilean-invariant Fermi liquid (FL). Real-life realizations of a DFL include, e.g., doped graphene, surface states of three-dimensional (3D) topological insulators, and 3D Dirac/Weyl metals. We study the optical conductivity of a DFL arising from intraband electron-electron scattering. It is shown that the effective current relaxation rate behaves as 1/τJ (ω2+4π2 T2)(3ω2+8π2 T2) for \ω, T\ μ, where μ is the chemical potential, with an additional logarithmic factor in two dimensions. In graphene, the quartic form of 1/τJ competes with a small FL-like term, ω2+4π2 T2, due to trigonal warping of the Fermi surface. We also calculated the dynamical charge susceptibility, c( q,ω), outside the particle-hole continua and to one-loop order in the dynamically screened Coulomb interaction. For a 2D DFL, the imaginary part of c( q,ω) scales as q2ω|ω| and q4/ω3 for frequencies larger and smaller than the plasmon frequency at given q, respectively. The small-q limit of Im c( q,ω) reproduces our result for the conductivity via the Einstein relation.

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