Symmetry-protected self-correcting quantum memories

TL;DR

This paper shows that 3D spin-lattice models with certain generalized symmetries, specifically 1-form symmetries, can serve as self-correcting quantum memories, enhancing quantum information protection without active error correction.

Contribution

It demonstrates that 1-form symmetries enable self-correction in 3D models, exemplified by the 3D cluster state and gauge color code, linking symmetry and quantum memory stability.

Findings

1-form symmetries guarantee self-correction in certain 3D models

The 3D cluster state acts as a self-correcting quantum memory

Emergent 1-form symmetries can naturally occur in topologically ordered systems

Abstract

A self-correcting quantum memory can store and protect quantum information for a time that increases without bound with the system size and without the need for active error correction. We demonstrate that symmetry can lead to self-correction in 3D spin-lattice models. In particular, we investigate codes given by 2D symmetry-enriched topological (SET) phases that appear naturally on the boundary of 3D symmetry-protected topological (SPT) phases. We find that while conventional on-site symmetries are not sufficient to allow for self-correction in commuting Hamiltonian models of this form, a generalized type of symmetry known as a 1-form symmetry is enough to guarantee self-correction. We illustrate this fact with the 3D "cluster-state" model from the theory of quantum computing. This model is a self-correcting memory, where information is encoded in a 2D SET-ordered phase on the boundary that is protected by the thermally stable SPT ordering of the bulk. We also investigate the gauge color code in this context. Finally, noting that a 1-form symmetry is a very strong constraint, we argue that topologically ordered systems can possess emergent 1-form symmetries, i.e., models where the symmetry appears naturally, without needing to be enforced externally.