Probing imbalanced Weyl nodes in two-dimensional anisotropic Weyl semimetal via optical conductivity

TL;DR

This paper theoretically explores the electronic and optical properties of a two-dimensional anisotropic Weyl semimetal with tilted semi-Dirac spectrum, revealing how tilt-induced energy imbalance affects optical conductivity and topological phases.

Contribution

It introduces a novel analysis of imbalanced Weyl nodes in 2D anisotropic semimetals, linking tilt effects to optical signatures and topological phase stability.

Findings

Tilt along quadratic direction causes energy imbalance between Weyl nodes.

Optical conductivity signatures reveal the energy imbalance between nodes.

Imbalanced Weyl nodes prevent transition to Chern topological phase after gap opening.

Abstract

We present a theoretical investigation of the electronic band structure and optical properties of a two-dimensional anisotropic semimetal that is described by a tilted semi-Dirac type spectrum with a pair of Weyl nodes. We observe that a tilt along the quadratic direction can give rise to an energy imbalance between these nodes, contrary to the effect of tilt along the linear direction. We investigate the optical response of such system subjected to an external AC bias, aiming to probe the energy imbalance between the nodes. We show that the anisotropic interband optical conductivity gives a clear signature of imbalanced nodes by exciting electrons at two different chemical potentials at near zero frequency indicating, and the difference between these two chemical potentials is the direct measure of the energy imbalance. Subsequently, we also investigate the intraband DC conductivity by using the semi-classical Boltzmann transport theory which reveals that contrary to the tilted Dirac materials, tilt can convert semi-Dirac material from semimetallic phase to metallic phase. Furthermore, we periodically drive the system by external time-periodic perturbation to open up topological gap at those nodes. We also show that the presence of imbalanced Weyl nodes would prevent the SD material from switching to Chern topological phase even after opening topological gaps at the nodes as the bulk remains gapless. Such state cannot be probed by the usual anomalous Hall response as it will be overshadowed by the bulk contribution. Here, we show that those gaps at different chemical potential can be probed by optical excitation.