Driven Interface Depinning in a Disordered Medium
Abstract
The dynamics of a driven interface in a medium with random pinning forces is analyzed. The interface undergoes a depinning transition where the order parameter is the interface velocity , which increases as for driving forces close to its threshold value . We consider a Langevin-type equation which is expected to be valid close to the depinning transition of an interface in a statistically isotropic medium. By a functional renormalization group scheme the critical exponents characterizing the depinning transition are obtained to the first order in , where is the interface dimension. The main results were published earlier [T. Nattermann et al., J. Phys. II France {\bf 2} (1992) 1483]. Here, we present details of the perturbative calculation and of the derivation of the functional flow equation for the random-force correlator. The fixed point function of the correlator has a cusp singularity which is related to a finite value of the threshold , similar to the mean field theory. We also present extensive numerical simulations and compare them with our analytical results for the critical exponents. For the numerical and analytical results deviate from each other by only a few percent. The deviations in lower dimensions are larger and suggest that the roughness exponent is somewhat larger than the value of an interface in thermal equilibrium.
Cite
@article{arxiv.cond-mat/9603114,
title = {Driven Interface Depinning in a Disordered Medium},
author = {Heiko Leschhorn and Thomas Nattermann and Semjon Stepanow and Lei-Han Tang},
journal= {arXiv preprint arXiv:cond-mat/9603114},
year = {2009}
}
Comments
32 pages, 14 figures, REVTeX, to be published in Annalen der Physik