Band Structure and topology of a periodically deformed Kitaev honeycomb model

TL;DR

This paper explores how periodic deformation and magnetic fields influence the band structure and topology of the Kitaev honeycomb model, revealing topological transitions and potential experimental signatures.

Contribution

It introduces a simplified solution for the deformed Kitaev model and analyzes the effects of deformation and magnetic fields on its topological properties.

Findings

Deformation reduces the Brillouin zone and creates new band gaps.

Magnetic fields induce band-gap closings and topological transitions.

The model exhibits nontrivial Chern numbers and potential thermal Hall responses.

Abstract

Motivated by the growing interest in spin liquids and topological phases, as well as the rise of deformation engineering, we study the combined effects of deformation and magnetic fields on the honeycomb Kitaev model. The Kitaev model, as one of the prototypical and exactly solvable spin liquid-hosting models, serves as a simple platform that demonstrates the rich physics one can expect at the intersection of deformation physics and quantum spin liquids. Our work builds on a simplified solution to the undeformed base model that we present. This simplified solution allows for a straightforward extension of our analysis to the deformed case. After incorporating periodic deformations into the Kitaev model (chosen for its similarity to moir\'e physics), we investigate the effects of a hexagonally symmetric deformation on the band structure. We find that deformation leads to a smaller Brillouin zone with new band gaps at the edges, indicating the potential for topological transitions. Finally, we introduce a magnetic field to break time-reversal symmetry and thereby allow for non-trivial topology. We find that, under specific parameter conditions, the magnetic field leads to multiple band-gap closings and openings. An investigation into topological properties reveals nontrivial Chern numbers and a plethora of topological transitions. Our results suggest possible thermal Hall or Nernst-type responses. We also suggest a potential bulk measurement approach for he Chern numbers and possible path to physical realization. Most importantly, our results serve as a demonstration of the rich phenomenology that can arise due to the interplay between deformation and spin-liquid physics.