English

Intrinsic optical absorption in Dirac metals

Strongly Correlated Electrons 2023-03-16 v1 Mesoscale and Nanoscale Physics

Abstract

A Dirac metal is a doped (gated) Dirac material with the Fermi energy (EFE_\text{F}) lying either in the conduction or valence bands. In the non-interacting picture, optical absorption in gapless Dirac metals occurs only if the frequency of incident photons (Ω\Omega) exceeds the direct (Pauli) frequency threshold, equal to 2EF2E_\text{F}. In this work, we study, both analytically and numerically, the role of electron-electron (eeee) and electron-hole (eheh) interactions in optical absorption of two-dimensional (2D) and three-dimensional (3D) Dirac metals in the entire interval of frequencies below 2EF2E_\text{F}. We show that, for ΩEF\Omega\ll E_\text{F}, the optical conductivity, σ(Ω)\Re\sigma(\Omega), arising from the combination of eeee and certain eheh scattering processes, scales as Ω2lnΩ\Omega^2\ln\Omega in 2D and as Ω2\Omega^2 in 3D, respectively, both for short-range (Hubbard) and long-range (screened Coulomb) interactions. Another type of eheh processes, similar to Auger-Meitner (AM) processes in atomic physics, starts to contribute for Ω\Omega above the direct threshold, equal to EFE_\text{F}. Similar to the case of doped semiconductors with parabolic bands studied in prior literature, the AM contribution to σ(Ω)\Re\sigma(\Omega) in Dirac metals is manifested by a threshold singularity, σ(Ω)(ΩEF)d+2\Re\sigma(\Omega)\propto (\Omega-E_\text{F})^{d+2}, where dd is the spatial dimensionality and 0<ΩEFEF0<\Omega-E_\text{F}\ll E_\text{F}. In contrast to doped semiconductors, however, the AM contribution in Dirac metals is completely overshadowed by the eeee and other eheh contributions. Numerically, σ(Ω)\Re\sigma(\Omega) happens to be small in almost the entire range of Ω<2EF\Omega<2E_\text{F}. This finding may have important consequences for collective modes in Dirac metals lying below 2EF2E_\text{F}.

Keywords

Cite

@article{arxiv.2303.08705,
  title  = {Intrinsic optical absorption in Dirac metals},
  author = {Adamya P. Goyal and Prachi Sharma and Dmitrii L. Maslov},
  journal= {arXiv preprint arXiv:2303.08705},
  year   = {2023}
}

Comments

33 pages, 10 figures

R2 v1 2026-06-28T09:18:44.177Z