Z2 topological order and first-order quantum phase transitions in systems with combinatorial gauge symmetry

TL;DR

This paper investigates a generalized Z2 gauge symmetric model combining ferromagnetic and antiferromagnetic interactions, revealing first-order quantum phase transitions between topological and other phases through numerical simulations.

Contribution

It introduces a new model with combined interactions and demonstrates the stability of the Z2 topological phase and the nature of phase transitions using advanced computational methods.

Findings

Topological phase confirmed by simulations.

First-order transition between topological and paramagnetic phases.

First-order transition between topological and ferromagnetic phases.

Abstract

We study a generalization of the two-dimensional transverse-field Ising model, combining both ferromagnetic and antiferromagnetic two-body interactions, that hosts exact global and local Z2 gauge symmetries. Using exact diagonalization and stochastic series expansion quantum Monte Carlo methods, we confirm the existence of the topological phase in line with previous theoretical predictions. Our simulation results show that the transition between the confined topological phase and the deconfined paramagnetic phase is of first-order, in contrast to the conventional Z2 lattice gauge model in which the transition maps onto that of the standard Ising model and is continuous. We further generalize the model by replacing the transverse field on the gauge spins with a ferromagnetic XX interaction while keeping the local gauge symmetry intact. We find that the Z2 topological phase remains stable, while the paramagnetic phase is replaced by a ferromagnetic phase. The topological-ferromagnetic quantum phase transition is also of first-order. For both models, we discuss the low-energy spinon and vison excitations of the topological phase and their avoided level crossings associated with the first-order quantum phase transitions.