# Elastic gauge fields and zero-field 3D quantum Hall effect in   hyperhoneycomb lattices

**Authors:** Sang Wook Kim, Bruno Uchoa

arXiv: 1901.00573 · 2019-05-15

## TL;DR

This paper explores how elastic gauge fields in hyperhoneycomb lattices can induce 3D quantum Hall effects and flat Landau levels, with potential applications in tunable metamaterials and topological phases.

## Contribution

It derives elastic gauge fields in hyperhoneycomb lattices and demonstrates strain-induced Landau levels and topological Hall viscosity in 3D quantum anomalous Hall phases.

## Key findings

- Strain creates uniform Landau levels in 3D hyperhoneycomb lattices.
- Elastic Hall viscosity tensor components are quantized and related to lattice parameters.
- Uniaxial temperature gradients can tune Landau levels in metamaterials.

## Abstract

Dirac materials respond to lattice deformations as if the electrons were coupled to gauge fields. We derive the elastic gauge fields in the hyperhoneycomb lattice, a three dimensional (3D) structure with trigonally connected sites. In its semimetallic form, this lattice is a nodal-line semimetal with a closed loop of Dirac nodes. Using strain engineering, we find a whole family of strain deformations that create uniform nearly flat Landau levels in 3D. We propose that those Landau levels can be created and tuned in metamaterials with the application of a simple uniaxial temperature gradient. In the 3D quantum anomalous Hall phase, which is topological, we show that the components of the elastic Hall viscosity tensor are multiples of $\eta_{H}=\beta^{2}\sqrt{3}/\left(8\pi a^{3}\right)$, where $\beta$ is an elastic parameter and $a$ is the lattice constant.

## Full text

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## Figures

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## References

42 references — full list in the complete paper: https://tomesphere.com/paper/1901.00573/full.md

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Source: https://tomesphere.com/paper/1901.00573