Dynamics of a Rigid Rod in a Glassy Medium
Abstract
We present simulations of the motion of a single rigid rod in a disordered static 2d-array of disk-like obstacles. The rotational, D R, and center-of-mass translational, D CM, diffusion constants are calculated for a wide range of rod length L and density of obstacles . It is found that D CM follows the behavior predicted by kinetic theory for a hard disk with an effective radius R(L). A dynamic crossover is observed in D R for L comparable to the typical distance between neighboring obstacles d nn. Using arguments from kinetic theory and reptation, we rationalize the scaling laws, dynamic exponents, and prefactors observed for D R. In analogy with the enhanced translational diffusion observed in deeply supercooled liquids, the Stokes-Einstein-Debye relation is violated for L > 0.6d nn.
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