Dynamical off-equilibrium scaling across magnetic first-order phase transitions

TL;DR

This paper studies the non-equilibrium dynamics of a classical spin system with $O(n)$ symmetry during magnetic first-order and continuous phase transitions, deriving scaling laws for correlation functions and hysteresis loop areas.

Contribution

It develops a unified scaling framework for off-equilibrium dynamics across both continuous and discontinuous magnetic phase transitions, extending beyond the large-$n$ limit.

Findings

Derived off-equilibrium scaling relations for correlation functions.

Developed a scaling theory based on coherence length for first-order transitions.

Calculated hysteresis loop area scaling during phase transition cycles.

Abstract

We investigate the off-equilibrium dynamics of a classical spin system with $O(n)$ symmetry in $2< D <4$ spatial dimensions and in the limit $n\to \infty$. The system is set up in an ordered equilibrium state is and subsequently driven out of equilibrium by slowly varying the external magnetic field $h$ across the transition line $h_c=0$ at fixed temperature $T\leq T_c$. We distinguish the cases $T = T_c$ where the magnetic transition is continuous and $T<T_c$ where the transition is discontinuous. In the former case, we apply a standard Kibble-Zurek approach to describe the non-equilibrium scaling and formally compute the correlation functions and scaling relations. For the discontinuous transition we develop a scaling theory which builds on the coherence length rather than the correlation length since the latter remains finite for all times. Finally, we derive the off-equilibrium scaling relations for the hysteresis loop area during a round-trip protocol that takes the system across its phase transition and back. Remarkably, our results are valid beyond the large-$n$ limit.