Higher-order Topological Hyperbolic Lattices
Abstract
A hyperbolic lattice allows for any -fold rotational symmetry, in stark contrast to a two-dimensional crystalline material, where only twofold, threefold, fourfold or sixfold rotational symmetry is permitted. This unique feature motivates us to ask whether the enriched rotational symmetry in a hyperbolic lattice can lead to any new topological phases beyond a crystalline material. Here, by constructing and exploring tight-binding models in hyperbolic lattices, we theoretically demonstrate the existence of higher-order topological phases in hyperbolic lattices with eight-fold, twelve-fold, sixteen-fold or twenty-fold rotational symmetry, which is not allowed in a crystalline lattice. Since such models respect the combination of time-reversal symmetry and -fold (8, 12, 16 or 20) rotational symmetry, zero-energy corner modes are protected. For the hyperbolic \{8,3\} lattice, we find a gapped, a gapless and a reentrant gapped higher-order topological hyperbolic phases. The reentrant phase arises from finite-size effects, which open the gap of edge states while leave the gap of corner modes unchanged. Our results thus open the door to studying higher-order topological phases in hyperbolic lattices.
Cite
@article{arxiv.2209.02262,
title = {Higher-order Topological Hyperbolic Lattices},
author = {Yu-Liang Tao and Yong Xu},
journal= {arXiv preprint arXiv:2209.02262},
year = {2023}
}
Comments
16 pages, 18 figures