J. A. Drocco, C. J. Olson Reichhardt, C. Reichhardt
Published 2009-09-10Version 1
We demonstrate that the fluctuation theorem of Gallavotti and Cohen can be used to characterize the class of dynamics that arises in nonthermal systems of collectively interacting particles driven over random quenched disorder. By observing the frequency of entropy-destroying trajectories, we show that there are specific dynamical regimes near depinning in which this theorem holds. Hence the fluctuation theorem can be used to characterize a significantly wider class of nonequilibrium systems than previously considered. We discuss how the fluctuation theorem could be tested in specific systems where noisy dynamics appear at the transition from a pinned to a moving phase such as in vortices in type-II superconductors, magnetic domain walls, and dislocation dynamics.
Comments: 4 pages, 5 postscript figures
Journal: Eur. Phys. J. E 34, 117 (2011)
Derivation of a Fluctuation Theorem from the probabilistic definition of entropy
Comment on "Macrospopic Equation for the Roughness of Growing Interfaces in Quenched Disorder"
Dynamically Induced Locking and Unlocking Transitions in Driven Layered Systems with Quenched Disorder
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