Unveiling the Chiral States in Multi-Weyl Semimetals through Magneto-Optical Spectroscopy

TL;DR

This paper explores the magneto-optical properties of multi-Weyl semimetals, revealing how tilting parameters and chiral states influence their optical responses and providing a theoretical framework for analyzing their quantum transport phenomena.

Contribution

It introduces a generic Landau-level expression and conductivity tensor analysis for multi-Weyl semimetals, highlighting the impact of tilting parameters on their magneto-optical responses and chiral state signatures.

Findings

Chiral states' signatures become more pronounced with higher Weyl node order.

Tilting parameter significantly affects Faraday rotation near tilted Dirac cones.

A robust theoretical framework for analyzing quantum transport in multi-Weyl semimetals.

Abstract

This study investigates the transport parameters in multi-Weyl semimetals, focusing on their magneto-optical properties and the role of chiral states. The tilting parameter is identified as a key factor in higher-order Weyl nodes, significantly influencing the magneto-optical response. We obtain a generic Landau-level expression for multi-Weyl semimetals, establishing a robust framework for analyzing their quantum transport properties. A comprehensive expression for the conductivity tensor components is presented, uncovering distinctive low-frequency peaks and other features shaped by the tilting parameter. Our findings reveal that the signatures of chiral states in the conductivity tensors become increasingly pronounced with the Weyl node order. Particularly, the tilting parameter is shown to impact Faraday rotation, at energies near the tilted Dirac cone energies. These results provide critical insights into the magneto-optical behavior of multi-Weyl semimetals and their potential for exploring topological phenomena.