Non-reciprocal Ising gauge theory

TL;DR

This paper introduces a minimal model of non-reciprocally coupled Ising gauge theories, revealing novel phenomena like quasiparticle confinement, self-avoiding trail dynamics, and long-lived metastable states influenced by non-reciprocity.

Contribution

It demonstrates how non-reciprocal coupling in Ising gauge theories leads to unique structural and dynamical behaviors, expanding understanding of frustrated non-reciprocal many-body systems.

Findings

Wilson loop exhibits linear asymptotic scaling with non-reciprocal coupling strength.

Deconfined excitations move on a critical percolation cluster following a self-avoiding trail.

Non-reciprocity tunes topological contributions and induces long-lived metastable states.

Abstract

Non-reciprocity and geometric frustration enable many-body systems to avoid crystalline order and instead exhibit complex, liquid-like behavior. Here we show that their interplay is richer than the sum of its parts, leading to surprising structural and dynamical phenomena. In our minimal model, two copies of Ising gauge theory are non-reciprocally coupled in a way that crucially preserves a local $\mathbb{Z}_2$ symmetry. We discover that the combined Wilson loop observable of the two copies exhibits linear asymptotic scaling, with a quasiparticle-pair confinement length tuned by the strength of the non-reciprocal coupling. Key dynamical features are revealed in the behavior of individual deconfined excitations due to strong interactions induced by the non-reciprocity, leading to motion on a critical percolation cluster that follows a self-avoiding trail. Mapping from this quasiparticle dynamics onto the magnetic noise spectrum, we discover that non-reciprocity tunes topological logarithmic contributions and causes long-lived metastable states due to quasiparticle trapping. Our work opens the way for broader investigations of geometrically frustrated non-reciprocity.