Visualizing interaction-driven restructuring of quantum Hall edge states

TL;DR

This study uses high-resolution STM to image and analyze how electronic interactions reshape quantum Hall edge states in graphene, revealing new phenomena and the limitations of mean-field theories.

Contribution

First direct microscopic imaging of interaction-driven restructuring of quantum Hall edge states, including fractional phases, using STM.

Findings

Interactions modify edge velocities and spatial profiles.

Discovery of edge valley polarization differing from bulk.

Spectroscopic evidence of interaction effects in fractional quantum Hall states.

Abstract

Many topological phases host gapless boundary modes that can be dramatically modified by electronic interactions. Even for the long-studied edge modes of quantum Hall phases, forming at the boundaries of two-dimensional (2D) electron systems, the nature of such interaction-induced changes has been elusive. Despite advances made using local probes, key experimental challenges persist: the lack of direct information about the internal structure of edge states on microscopic scales, and complications from edge disorder. Here, we use scanning tunneling microscopy (STM) to image pristine electrostatically defined quantum Hall edge states in graphene with high spatial resolution and demonstrate how correlations dictate the structures of edge channels on both magnetic and atomic length scales. For integer quantum Hall states in the zeroth Landau level, we show that interactions renormalize the edge velocity, dictate the spatial profile for copropagating modes, and induce unexpected edge valley polarization that differ from those of the bulk. While some of our findings can be understood by mean-field theory, others show breakdown of this picture, highlighting the roles of edge fluctuations and inter-channel couplings. We also extend our measurements to spatially resolve the edge state of fractional quantum Hall phases and detect spectroscopic signatures of interactions in this chiral Luttinger liquid. Our study establishes STM as a promising tool for exploring edge physics of the rapidly expanding 2D topological phases, including newly realized fractional Chern insulators.