Relation between winding numbers and energy dispersions

TL;DR

This paper establishes a direct, experimentally accessible link between the winding number of Bloch vectors in two-band Hamiltonians and the gradient of energy dispersions, connecting topological invariants to measurable energy spectra.

Contribution

It reveals a novel relationship between the topological winding number and the energy dispersion gradient, enabling experimental probing of topological properties.

Findings

Winding number relates to energy dispersion gradient.

Energy gradient proportional to group velocity.

Provides a measurable link between topology and spectroscopy.

Abstract

Two-band Hamiltonians provide a typical description of topological band structures, in which the eigenfunctions can be characterized by a %Bloch vector field whose winding number that defines an integer topological invariant. This winding number is quantized and protected against continuous deformations of the Hamiltonian. Here we show that the Bloch vector and its winding number can be directly related to the gradient of the energy dispersion. Since the energy gradient is proportional to the group velocity, our result establishes an experimentally accessible correspondence between the Bloch vector field and angle-resolved photoemission spectroscopy measurements. We discuss a mapping between the gradient of the energy dispersion and the Bloch vector. This implies a direct and measurable relation between two-band Hamiltonians and their underlying topological structures.