Parity-Induced Thermalization Gap in Disordered Ring Lattices
Abstract
The gaps separating two different states widely exist in various physical systems: from the electrons in periodic lattices to the analogs in photonic, phononic, plasmonic systems, and even quasicrystals. Recently, a thermalization gap, an inaccessible range of photon statistics, was proposed for light in disordered structures [Nat. Phys. 11, 930 (2015)], which is intrinsically induced by the disorder-immune chiral symmetry and can be reflected by the photon statistics. The lattice topology was further identified as a decisive role in determining the photon statistics when the chiral symmetry is satisfied. Being very distinct from one-dimensional lattices, the photon statistics in ring lattices are dictated by its parity, i.e, odd or even sited. Here, we for the first time experimentally observe a parity-induced thermalization gap in strongly disordered ring photonic structures. In a limited scale, though the light tends to be localized, we are still able to find clear evidence of the parity-dependent disorder-immune chiral symmetry and the resulting thermalization gap by measuring photon statistics, while strong disorder-induced Anderson localization overwhelms such a phenomenon in larger-scale structures. Our results shed new light on the relation among symmetry, disorder, and localization, and may inspire new resources and artificial devices for information processing and quantum control on a photonic chip.
Cite
@article{arxiv.1803.10838,
title = {Parity-Induced Thermalization Gap in Disordered Ring Lattices},
author = {Yao Wang and Jun Gao and Xiao-Ling Pang and Zhi-Qiang Jiao and Hao Tang and Yuan Chen and Lu-Feng Qiao and Zhen-Wei Gao and Jian-Peng Dou and Ai-Lin Yang and Xian-Min Jin},
journal= {arXiv preprint arXiv:1803.10838},
year = {2019}
}
Comments
20 pages, 19 figures