English

Information Critical Phases under Decoherence

Quantum Physics 2025-12-29 v1 Disordered Systems and Neural Networks Statistical Mechanics

Abstract

Quantum critical phases are extended regions of phase space characterized by a diverging correlation length. By analogy, we define an information critical phase as an extended region of a mixed state phase diagram where the Markov length, the characteristic length scale governing the decay of the conditional mutual information (CMI), diverges. We demonstrate that such a phase arises in decohered ZN\mathbb{Z}_{N} Toric codes by assessing both the CMI and the coherent information, the latter quantifying the robustness of the encoded logical qudits. For N>4N>4, we find that the system hosts an information critical phase intervening between the decodable and non-decodable phases where the coherent information saturates to a fractional value in the thermodynamic limit, indicating that a finite fraction of logical information is still preserved. We show that the density matrix in this phase can be decomposed into a convex sum of Coulombic pure states, where gapped anyons reorganize into gapless photons. We further consider the ungauged ZN\mathbb{Z}_{N} Toric code and interpret its mixed state phase diagram in the language of strong-to-weak spontaneous symmetry breaking. We argue that in the dual model, the information critical phase arises because the spontaneously broken off-diagonal ZN\mathbb{Z}_{N} symmetry gets enhanced to a U(1) symmetry, resulting in a novel superfluid phase whose gapless modes involve coherent excitations of both the system and the environment. Finally, we propose an optimal decoding protocol for the corrupted ZN\mathbb{Z}_{N} Toric code and evaluate its effectiveness in recovering the fractional logical information preserved in the information critical phase. Our findings identify a gapless analog for mixed-state phases that still acts as a fractional topological quantum memory, thereby extending the conventional paradigm of quantum memory phases.

Keywords

Cite

@article{arxiv.2512.22121,
  title  = {Information Critical Phases under Decoherence},
  author = {Akash Vijay and Jong Yeon Lee},
  journal= {arXiv preprint arXiv:2512.22121},
  year   = {2025}
}
R2 v1 2026-07-01T08:41:44.223Z