Band Topology or Geometry?

TL;DR

This paper explores the relationship between band topology and geometry in solid materials, showing how band geometry influences both topological and geometrical properties of edge states, even when symmetries are broken.

Contribution

It provides a unified framework linking band geometry to edge state properties, extending understanding beyond symmetry-dependent invariants.

Findings

Band geometry determines topological and geometrical edge state properties.

The framework applies even when symmetries are broken.

Provides a unified picture of band topology and geometry.

Abstract

The study of topology of energy bands in solid has always been interesting and fruitful. Historically, Thouless et al proposed the TKNN number or Chern number of the energy bands to explain the quantization of Hall conductance in the integer quantum Hall effect. Recently, Z2 topological insulators have been intensively studied and similarly topological crystalline insulators are proposed.These materials exhibit nontrivial charge or spin transport properties that is due to the existence of metallic edge states. The edge states are protect by the topology of the energy bands of the bulk material and the band topology are described by some invariants similar to the TKNN number. However, these invariants are crude and strongly dependent on the symmetry. Here we give an unified picture of the relationship of the edge states and the geometry of the energy bands. We show the band geometry determines not only the topological but also the geometrical properties of the edge states and the picture is applicable when the symmetries are broken.