L. Roters, A. Hucht, S. Lubeck, U. Nowak, K. D. Usadel
Published 1999-05-21Version 1
We analyze the depinning transition of a driven interface in the 3d random-field Ising model (RFIM) with quenched disorder by means of Monte Carlo simulations. The interface initially built into the system is perpendicular to the [111]-direction of a simple cubic lattice. We introduce an algorithm which is capable of simulating such an interface independent of the considered dimension and time scale. This algorithm is applied to the 3d-RFIM to study both the depinning transition and the influence of thermal fluctuations on this transition. It turns out that in the RFIM characteristics of the depinning transition depend crucially on the existence of overhangs. Our analysis yields critical exponents of the interface velocity, the correlation length, and the thermal rounding of the transition. We find numerical evidence for a scaling relation for these exponents and the dimension d of the system.
Comments: 6 pages, including 9 figures, submitted for publication
Journal: Physical Review E 60, 5202 (1999)
Monte Carlo Simulations of Some Dynamical Aspects of Drop Formation
Monte Carlo Simulations of Opinion Dynamics
Influence of the temperature on the depinning transition of driven interfaces
