Charge-Informed Quantum Error Correction
Abstract
We investigate the statistical physics of quantum error correction in symmetry-enriched topological quantum memories. Starting from a phenomenological error model of charge-conserving noise, we study the optimal decoder assuming the local charges of each anyon can be measured. The error threshold of the optimal decoder corresponds to a continuous phase transition in a disordered two-dimensional integer loop model on the Nishimori line. Using an effective replica field theory analysis and Monte Carlo numerics, we show that the optimal decoding transition exhibits Berezinskii-Kosterlitz-Thouless universality with a modified universal jump in winding number variance. We further generalize the model beyond the Nishimori line, which defines a large class of suboptimal decoders. At low nonzero temperatures and strong disorder, we find numerical evidence of a disorder-dominated loop-glass phase which corresponds to a "confidently incorrect" decoder. The zero-temperature limit defines the minimum-cost flow decoder, which serves as the analog of minimum-weight perfect matching in topological codes. Both the optimal and minimum-cost flow decoders are shown to dramatically outperform the charge-agnostic optimal decoder in symmetry-enriched topological codes.
Keywords
Cite
@article{arxiv.2512.22119,
title = {Charge-Informed Quantum Error Correction},
author = {Vlad Temkin and Zack Weinstein and Ruihua Fan and Daniel Podolsky and Ehud Altman},
journal= {arXiv preprint arXiv:2512.22119},
year = {2025}
}
Comments
7+22 pages, 2+10 figures