First-order phase transition in a 2D random-field Ising model with conflicting dynamics

Abstract

The effects of locally random magnetic fields are considered in a nonequilibrium Ising model defined on a square lattice with nearest-neighbors interactions. In order to generate the random magnetic fields, we have considered random variables \h\ that change randomly with time according to a double-gaussian probability distribution, which consists of two single gaussian distributions, centered at +ho and -ho, with the same width σ. This distribution is very general, and can recover in appropriate limits the bimodal distribution (σ 0) and the single gaussian one (ho=0). We performed Monte Carlo simulations in lattices with linear sizes in the range L=32 - 512. The system exhibits ferromagnetic and paramagnetic steady states. Our results suggest the occurence of first-order phase transitions between the above-mentioned phases at low temperatures and large random-field intensities ho, for some small values of the width σ. By means of finite size scaling, we estimate the critical exponents in the low-field region, where we have continuous phase transitions. In addition, we show a sketch of the phase diagram of the model for some values of σ.