Subsystem symmetry, spin glass order, and criticality from random measurements in a two-dimensional Bacon-Shor circuit

TL;DR

This paper investigates a 2D measurement-only random circuit inspired by the Bacon-Shor code, revealing a phase transition between spin glass orders and a critical point with unique entanglement scaling, and explores effects of breaking subsystem symmetries.

Contribution

It introduces a detailed phase diagram of a Bacon-Shor inspired circuit, highlighting a continuous phase transition and the impact of subsystem symmetry breaking on order and criticality.

Findings

Identifies a phase transition with L ln L entanglement scaling.

Shows subsystem symmetry leads to conserved quantities and spin glass order.

Demonstrates that breaking subsystem symmetry turns the transition into a crossover.

Abstract

We study a 2D measurement-only random circuit motivated by the Bacon-Shor error correcting code. We find a rich phase diagram as one varies the relative probabilities of measuring nearest neighbor Pauli XX and ZZ check operators. In the Bacon-Shor code, these checks commute with a group of stabilizer and logical operators, which therefore represent conserved quantities. Described as a subsystem symmetry, these conservation laws lead to a continuous phase transition between an X-basis and Z-basis spin glass order. The two phases are separated by a critical point where the entanglement entropy between two halves of an L X L system scales as L ln L, a logarithmic violation of the area law. We generalize to a model where the check operators break the subsystem symmetries (and the Bacon-Shor code structure). In tension with established heuristics, we find that the phase transition is replaced by a smooth crossover, and the X- and Z-basis spin glass orders spatially coexist. Additionally, if we approach the line of subsystem symmetries away from the critical point in the phase diagram, some spin glass order parameters jump discontinuously