Dissipative Chiral Channels, Ohmic Scaling and Half-integer Hall Conductivity from the Relativistic Quantum Hall Effect

TL;DR

This paper demonstrates the feasibility of observing the relativistic quantum Hall effect and measuring half-integer Hall conductivity in condensed matter systems, highlighting the role of dissipative chiral channels and Ohmic scaling in the transport mechanism.

Contribution

It introduces a new understanding of the transport mechanism behind the relativistic quantum Hall effect and proposes an experimental scheme using 3D topological insulators to measure half-integer Hall conductivity.

Findings

Half-integer Hall conductivity is linked to dissipative chiral channels.

Ohmic scaling of longitudinal conductance enables direct measurement of HIHC.

Proposed experimental setup for observing RQHE in 3D topological insulators.

Abstract

The quantum Hall effect (QHE), which was observed in 2D electron gas under an external magnetic field, stands out as one of the most remarkable transport phenomena in condensed matter. However, a long standing puzzle remains regarding the observation of the relativistic quantum Hall effect (RQHE). This effect, predicted for a single 2D Dirac cone immersed in a magnetic field, is distinguished by the intriguing feature of half-integer Hall conductivity (HIHC). In this work, we demonstrate that the condensed-matter realization of the RQHE and the direct measurement of the HIHC are feasible by investigating the underlying quantum transport mechanism. We reveal that the manifestation of HIHC is tied to the presence of dissipative half-integer quantized chiral channels circulating along the interface of the RQHE system and a Dirac metal. Importantly, we find that the Ohmic scaling of the longitudinal conductance of the system plays a key role in directly measuring the HIHC in experiments. Furthermore, we propose a feasible experimental scheme based on the 3D topological insulators to directly measure the HIHC. Our findings not only uncover the distinct transport mechanism of the HIHC for the RQHE, but also paves the way to the measurement of the HIHC in future experiments.