Disorder Driven Non-Anderson Transition in a Weyl Semimetal

TL;DR

This study provides the first experimental evidence of a non-Anderson disorder-driven phase transition in a Weyl semimetal, showing how increasing disorder suppresses surface states and induces a transition to a diffusive metal.

Contribution

It demonstrates the direct observation of a non-Anderson disorder-driven transition in a Weyl semimetal using angle-resolved photoemission spectroscopy, confirming theoretical predictions.

Findings

Strong disorder suppresses surface Fermi arcs

Transition from Weyl semimetal to diffusive metal observed

Vanishing bulk topological invariant signals phase transition

Abstract

For several decades, it was widely believed that a non-interacting disordered electronic system could only undergo an Anderson metal-insulator transition due to Anderson localization. However, numerous recent theoretical works have predicted the existence of a disorder-driven non-Anderson phase transition that differ from Anderson localization. The frustration lies in the fact that this non-Anderson disorder-driven transition has not yet been experimentally demonstrated in any system. Here, using angle-resolved photoemission spectroscopy, we present a case study of observing the non-Anderson disorder-driven transition by visualizing the electronic structure of the Weyl semimetal NdAlSi on surfaces with varying amounts of disorder. Our observations reveal that strong disorder can effectively suppress all surface states in the Weyl semimetal NdAlSi, including the topological surface Fermi arcs. This disappearance of surface Fermi arcs is associated with the vanishing of the bulk topological invariant, indicating a quantum phase transition from a Weyl semimetal to a diffusive metal. By analyzing the changes in the electronic structure of NdAlSi, as the surface degrades, we provide a physical picture of this non-Anderson transition from a Weyl semimetal to a diffuse metal. These observations provide the first direct experimental evidence of the non-Anderson disorder-driven transition, a discovery long anticipated by theoretical physicists. The finding dispels longstanding suspicions among researchers that non-Anderson transitions exist in real quantum systems.