Interface Motion in Random Media at Finite Temperature

Abstract

We have studied numerically the dynamics of a driven elastic interface in a random medium, focusing on the thermal rounding of the depinning transition and on the behavior in the T=0 pinned phase. Thermal effects are quantitatively more important than expected from simple dimensional estimates. For sufficient low temperature the creep velocity at a driving force equal to the T=0 depinning force exhibits a power-law dependence on T, in agreement with earlier theoretical and numerical predictions for CDW's. We have also examined the dynamics in the T=0 pinned phase resulting from slowly increasing the driving force towards threshold. The distribution of avalanche sizes S\| decays as S\|-1-, with = 0.05 0.05, in agreement with recent theoretical predictions.

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