Signatures of neutral quantum Hall modes in transport through low-density constrictions

TL;DR

This paper investigates how neutral quantum Hall modes influence transport properties in low-density constrictions, revealing their role in conductance fluctuations and edge equilibration in fractional quantum Hall systems.

Contribution

It introduces a detailed analysis of neutral modes in FQH constrictions, highlighting their impact on transport phenomena and conductance behavior.

Findings

Neutral modes cause universal conductance fluctuations.

Neutral modes influence edge state equilibration.

Neutral modes affect scattering strength across constrictions.

Abstract

Constrictions in fractional quantum Hall (FQH) systems not only facilitate backscattering between counter-propagating edge modes, but also may reduce the constriction filling fraction $\nu_c$ with respect to the bulk filling fraction $\nu_b$. If both $\nu_b$ and $\nu_c$ correspond to incompressible FQH states, at least part of the constriction region is surrounded by composite edges, whose low energy dynamics is characterized by a charge mode and one or several neutral modes. In the incoherent regime, decay of neutral modes describes the equilibration of composite FQH edges, while in the limit of coherent transport, the presence of neutral modes gives rise to universal conductance fluctuations. In addition, neutral modes renormalize the strength of scattering across the constriction, and thus can determine the relative strength of forward and backwards scattering.