Geometry induced quantum Hall effect and Hall viscosity
Abstract
For a particle confined to the two-dimensional helical surface embedded in four-dimensional (4D) Euclidean space, the effective Hamiltonian is deduced in the thin-layer quantization formalism. We find that the gauge structure of the effective dynamics is determined by torsion, which plays the role of U(1) gauge potential, and find that the topological structure of associated states is defined by orbital spin which originates from 4D space. Strikingly, the response to torsion contributes a quantum Hall effect, and the response to the deformation of torsion contributes Hall viscosity that is perfectly presented as a simultaneous occurrence of multiple channels for the quantum Hall effect. This result directly provides a way to probe Hall viscosity.
Cite
@article{arxiv.1912.09183,
title = {Geometry induced quantum Hall effect and Hall viscosity},
author = {Yong-Long Wang and Hong-Shi Zong and Hui Liu and Yan-Feng Chen},
journal= {arXiv preprint arXiv:1912.09183},
year = {2020}
}
Comments
10 pages, 4 figures