Open Momentum Space Method for Hofstadter Butterfly and the Quantized Lorentz Susceptibility

TL;DR

This paper introduces a new open momentum space method for calculating the Hofstadter butterfly in continuum and tight-binding models, revealing dual Chern numbers linked to quantized Lorentz susceptibility.

Contribution

The paper develops a generic $oldsymbol{k}oldsymbol{ullet} oldsymbol{p}$ open momentum space approach that simplifies Hofstadter butterfly calculations and uncovers a dual Chern number related to Lorentz susceptibility.

Findings

Efficient calculation of Hofstadter butterfly for Moiré and tight-binding models.

Identification of a dual Chern number $s_ u$ linked to quantized Lorentz susceptibility.

Spectral flows interpreted as edge states in momentum space.

Abstract

We develop a generic $\mathbf{k}\cdot \mathbf{p}$ open momentum space method for calculating the Hofstadter butterfly of both continuum (Moir\'e) models and tight-binding models, where the quasimomentum is directly substituted by the Landau level (LL) operators. By taking a LL cutoff (and a reciprocal lattice cutoff for continuum models), one obtains the Hofstadter butterfly with in-gap spectral flows. For continuum models such as the Moir\'e model for twisted bilayer graphene, our method gives a sparse Hamiltonian, making it much more efficient than existing methods. The spectral flows in the Hofstadter gaps can be understood as edge states on a momentum space boundary, from which one can determine the two integers ($t_\nu,s_\nu$) of a gap $\nu$ satisfying the Diophantine equation. The spectral flows can also be removed to obtain a clear Hofstadter butterfly. While $t_\nu$ is known as the Chern number, our theory identifies $s_\nu$ as a dual Chern number for the momentum space, which corresponds to a quantized Lorentz susceptibility $\gamma_{xy}=eBs_\nu$.