Self-dual Higgs transitions: Toric code and beyond
Abstract
The toric code, when deformed in a way that preserves the self-duality symmetry exchanging the electric and magnetic excitations, admits a transition to a topologically trivial state that spontaneously breaks the symmetry. Numerically, this transition was found to be continuous, which makes it particularly enigmatic given the longstanding absence of a continuum field-theoretic description. In this work we propose such a continuum field theory for the transition dubbed the Chern-Simons-Higgs (CSH) theory. We show that our field theory provides a natural "mean-field" understanding of the phase diagram. Moreover, it can be generalized to an entire series of theories, namely the CSH theories, labeled by an integer . For each , the theory describes an analogous transition involving different non-Abelian topological orders, such as the double Fibonacci order () and the quantum double (). For , we conjecture that the corresponding CSH transition is in fact infrared-dual to the Ising transition, in close analogy with the particle-vortex duality of a complex scalar.
Cite
@article{arxiv.2601.20945,
title = {Self-dual Higgs transitions: Toric code and beyond},
author = {Wenjie Ji and Ryan A. Lanzetta and Zheng Zhou and Chong Wang},
journal= {arXiv preprint arXiv:2601.20945},
year = {2026}
}
Comments
5+4 pages