Nonequilibrium phase transition in the kinetic Ising model: Critical slowing down and the specific-heat singularity

Abstract

The nonequilibrium dynamic phase transition, in the kinetic Ising model in the presence of an oscillating magnetic field has been studied both by Monte Carlo simulation and by solving numerically the mean-field dynamic equation of motion for the average magnetization. In both cases, the Debye “relaxation” behavior of the dynamic order parameter has been observed and the “relaxation time” is found to diverge near the dynamic transition point. The Debye relaxation of the dynamic order parameter and the power law divergence of the relaxation time have been obtained from a very approximate solution of the mean-field dynamic equation. The temperature variation of appropriately defined “specific heat” is studied by the Monte Carlo simulation near the transition point. The specific heat has been observed to diverge near the dynamic transition point.