Necessary and sufficient conditions for $\mathbb{Z}_2$-symmetry-breaking phase transitions

TL;DR

This paper establishes a geometric criterion involving the shape of equipotential surfaces that precisely characterizes the occurrence of $ ext{Z}_2$-symmetry-breaking phase transitions, linking topological changes to phase behavior.

Contribution

It introduces a necessary and sufficient geometric condition based on equipotential surface shapes for $ ext{Z}_2$-SBPTs, extending the topological hypothesis framework.

Findings

Dumbbell-shaped equipotential surfaces are linked to $ ext{Z}_2$-SBPTs.

The geometric condition applies to various models, including hypercubic and mean-field $ ext{phi}^4$ models.

The approach unifies topological and geometric perspectives on phase transitions.

Abstract

In a recent paper a toy model (hypercubic model) undergoing a first-order $\mathbb{Z}_2$-symmetry-breaking phase transition ($\mathbb{Z}_2$-SBPT) was introduced. The hypercubic model was inspired by the \emph{topological hypothesis}, according to which a phase transition may be entailed by suitable topological changes of the equipotential surfaces ($\Sigma_v$'s) of configuration space. In this paper we show that at the origin of a $\mathbb{Z}_2$-SBPT there is a geometric property of the $\Sigma_v$'s, i.e., dumbbell-shaped $\Sigma_v$'s suitably defined, which includes a topological change as a limiting case. This property is necessary and sufficient condition to entail a $\mathbb{Z}_2$-SBPT. This new approach has been applied to three models: a modified version introduced here of the hypercubic model, a model introduced in a recent paper with a continuous $\mathbb{Z}_2$-SBPT belonging to several universality classes, and finally to a physical models, i.e., the mean-field $\phi^4$ model and a simplified version of it.