Topologically Ordered Steady States in Open Quantum Systems
Abstract
The interplay between dissipation and correlation can lead to novel emergent phenomena in open systems. Here we investigate ``steady-state topological order'' defined by the robust topological degeneracy of steady states, which is a generalization of the ground-state topological degeneracy of closed systems. Specifically, we construct two representative Liouvillians using engineered dissipation, and exactly solve the steady states with topological degeneracy. We find that while the steady-state topological degeneracy is fragile under noise in two dimensions, it is stable in three dimensions, where a genuine many-body phase with topological degeneracy is realized. We identify universal features of steady-state topological physics such as the deconfined emergent gauge field and slow relaxation dynamics of topological defects. The transition from a topologically ordered phase to a trivial phase is also investigated via numerical simulation. Our work highlights the essential difference between ground-state topological order in closed systems and steady-state topological order in open systems.
Keywords
Cite
@article{arxiv.2306.12482,
title = {Topologically Ordered Steady States in Open Quantum Systems},
author = {Zijian Wang and Xu-Dong Dai and He-Ran Wang and Zhong Wang},
journal= {arXiv preprint arXiv:2306.12482},
year = {2026}
}
Comments
24 pages, 7 figures