Decoherence and wavefunction deformation of $D_4$ non-Abelian topological order

TL;DR

This paper investigates the stability of $D_4$ non-Abelian topological order under decoherence, revealing robustness against anyon proliferation and phase transitions, with implications for quantum error correction and symmetry breaking.

Contribution

It extends the understanding of decoherence effects from Abelian to non-Abelian topological orders, introducing tractable models and phase diagrams for $D_4$ TO under various decoherence scenarios.

Findings

$D_4$ TO remains stable against certain decoherence effects.

Purity remains high even with strong decoherence.

Multiple anyon types can proliferate without destroying topological order.

Abstract

The effect of decoherence on topological order (TO) has been most deeply understood for the toric code, the paragon of Abelian TOs. We show that certain non-Abelian TOs can be analyzed and understood to a similar degree, despite being significantly richer. We consider both wavefunction deformations and quantum channels acting on $D_4$ TO, which has recently been realized on a quantum processor. By identifying the corresponding local statistical mechanical spin or rotor model with $D_4$ symmetry, we find a remarkable stability against proliferating non-Abelian anyons. This is shown by leveraging a reformulation in terms of the tractable O$(2)$ loop model in the pure state case, and $n$ coupled O$(2)$ loop models for R\'enyi-$n$ quantities in the decoherence case -- corresponding to worldlines of the proliferating anyon with quantum dimension $2$. In particular, we find that the purity ($n=2$) remains deep in the $D_4$ TO for any decoherence strength, while the $n \to \infty$ limit becomes critical upon maximally decohering a particular anyon type, similar to our wavefunction deformation result. The information-theoretic threshold ($n\to 1$) appears to be controlled by a disordered version of these stat-mech models, akin to the toric code case although significantly more robust. We furthermore use Monte Carlo simulations to explore the phase diagrams when multiple anyon types proliferate at the same time, leading to a continued stability of the $D_4$ TO in addition to critical phases with emergent $U(1)$ symmetry. Instead of loop models, these are now described by net models corresponding to different anyon types coupled together according to fusion rules.This opens up the exploration of statistical mechanical models for decohered non-Abelian TO, which can inform optimal decoders, and which in an ungauged formulation examples of non-Abelian strong-to-weak symmetry breaking.