Transitions in a Probabilistic Interface Growth Model

Abstract

We study a generalization of the Wolf-Villain (WV) interface growth model based on a probabilistic growth rule. In the WV model, particles are randomly deposited onto a substrate and subsequently move to a position nearby where the binding is strongest. We introduce a growth probability which is proportional to a power of the number ni of bindings of the site i: pi ni. Through extensively simulations, in (1+1)-dimensions, we find three behavior depending of the value: i) if is small, a crossover from the Mullins-Hering to the Edwards-Wilkinson (EW) universality class; ii) for intermediate values of , a crossover from the EW to the Kardar-Parisi-Zhang (KPZ) universality class; iii) and, finally, for large values, the system is always in the KPZ class. In (2+1)-dimensions, we obtain three different behaviors: i) a crossover from the Villain-Lai-Das Sarma to the EW universality class, for small values; ii) the EW class is always present, for intermediate values; iii) a deviation from the EW class is observed, for large values.