Analytic results are presented for the dynamic behavior of sliding charge-density waves (CDW's) and related extended nonlinear systems with randomness. It is shown that, in the limit of long times, a sliding configuration approaches a unique solution. In CDW models, the velocity of this asymptotic solution is periodic in time. These results explain previous numerical observations, simplify further analysis and simulation, and have direct experimental implications.PACS numbers: 71.45.LrThere are many physical systems, including interfaces in random media, flux lattices in type-II superconductors, and charge-density waves (CDW's), where many degrees of freedom interact strongly in a random environment. A common problem in such systems is determining the response to an external drive, e.g., current or electric field; this is the problem of collective transport in systems with quenched randomness [1]. A general difficulty in treating random systems is the existence of many metastable solutions, which can complicate both analysis and numerical computations. However, in some systems exhibiting collective transport, the dynamics, though still complex, is simpler than might be expected. I report here analytic results that explain this behavior, under certain conditions, using CDW transport as an example system and summarizing the extension to other systems below.An incommensurate charge-density wave in a solid can be modeled as an elastic medium that is subject to both spatially varying pinning forces, due to impurities, and a uniform external force, due to an electric field [2-4]. If thermal noise can be neglected, the possible dynamical behaviors of CDW's can be sharply divided into two types: pinned and sliding. For small drive fields, the impurities pin the CDW in one of many static configurations. If the field is then increased above a threshold value, the CDW slides with a nonzero average velocity, thereby contributing to the electric current. The equations of motion for the CDW are nonlinear and describe an extended system with quenched randomness. It therefore would not be surprising for the CDW to exhibit some sort of turbulent behavior in the sliding state, or, at least, that there would be an aperiodic attractor or multiple attractors for the CDW dynamics.However, as I show in this Letter for a broad class of models describing CDW's and related systems, sliding configurations approach, at long times, a solution that is unique up to time translation. Also, the transition between pinned and sliding states is nonhysteretic. These results are generally applicable when the equations of motion are first order in time, phase distortions are described by a single component, and the elastic force between phases on neighboring sites increases with the phase gradient (i.e., the interaction potential is convex). For the periodic pinning potential of the CDW model, the CDW sliding state has a particularly simple temporal behavior, with the CDW velocity at each point being periodic in time, though the spatial behavior is qu...
