Dynamic phase transition in the three-dimensional kinetic Ising model in an oscillating field

TL;DR

This paper investigates the dynamic phase transition in a 3D kinetic Ising model under oscillating magnetic fields, revealing it belongs to the same universality class as the equilibrium 3D Ising model through numerical simulations and finite-size scaling.

Contribution

It demonstrates that the non-equilibrium dynamic phase transition in the 3D kinetic Ising model shares the universality class with the equilibrium 3D Ising model, using numerical methods.

Findings

Critical exponents match those of the equilibrium 3D Ising model.

The phase transition exhibits universality class characteristics.

Finite-size scaling confirms the universality class.

Abstract

Using numerical simulations we investigate the properties of the dynamic phase transition that is encountered in the three-dimensional Ising model subjected to a periodically oscillating magnetic field. The values of the critical exponents are determined through finite-size scaling. Our results show that the studied non-equilibrium phase transition belongs to the universality class of the equilibrium three-dimensional Ising model.