Velocity-force characteristics of an interface driven through a periodic potential
Abstract
We study the creep dynamics of a two-dimensional interface driven through a periodic potential using dynamical renormalization group methods. We find that the nature of weak-drive transport depends qualitatively on whether the temperature T is above or below the equilibrium roughening transition temperature Tc. Above Tc, the velocity-force characteristics is Ohmic, with linear mobility exhibiting a jump discontinuity across the transition. For T Tc, the transport is highly nonlinear, exhibiting an interesting crossover in temperature and weak external force F. For intermediate drive, F>F*, we find near Tc- a power-law velocity-force characteristics v(F) Fσ, with σ-1 t, and well-below Tc, v(F) e-(F*/F)2t, with t=(1-T/Tc). In the limit of vanishing drive (F F*) the velocity-force characteristics crosses over to v(F) e-(F0/F), and is controlled by soliton nucleation.
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