Non-diagonal anisotropic quantum Hall states
Abstract
We propose a family of Abelian quantum Hall states termed the non-diagonal states, which arise at filling factors for bosonic systems and for fermionic systems, with and being two coprime integers. Non-diagonal quantum Hall states are constructed in a coupled wire model, which shows an intimate relation to the non-diagonal conformal field theory and has a constrained pattern of motion for bulk quasiparticles, featuring a non-trivial interplay between charge symmetry and translation symmetry. The non-diagonal state is established as a distinctive symmetry-enriched topological order. Aside from the usual charge sector, there is an additional symmetry-enriched neutral sector described by the quantum double model , which relies on the presence of both the charge symmetry and the translation symmetry of the wire model. Translation symmetry distinguishes non-diagonal states from Laughlin states, in a way similar to how it distinguishes weak topological insulators from trivial band insulators. Moreover, the translation symmetry in non-diagonal states can be associated to the anyonic symmetry in , implying the role of dislocations as two-fold twist-defects. The boundary theory of non-diagonal states is derived microscopically. For the edge perpendicular to the direction of wires, the effective Hamiltonian has two components: a chiral Luttinger liquid and a generalized -state clock model. Importantly, translation symmetry in the bulk is realized as self-duality on the edge. The symmetric edge is thus either gapless or gapped with spontaneously broken symmetry. For , the respective electron tunneling exponents are predicted for experimental probes.
Cite
@article{arxiv.2009.08993,
title = {Non-diagonal anisotropic quantum Hall states},
author = {Pok Man Tam and Charles L. Kane},
journal= {arXiv preprint arXiv:2009.08993},
year = {2021}
}
Comments
25 pages, 10 figures, published version