K. Mussawisade, T. Wichmann, K. W. Kehr
Published 1996-10-27Version 1
The temperature dependence of the diffusion coefficient of particles is studied on lattices with disorder. A model is investigated with both trap and barrier disorder that was introduced before by Limoge and Bocquet (1990 Phys. Rev. Lett. (65) 60) to explain an Arrhenian temperature-dependence of the diffusion coefficient in amorphous substances. We have used a generalized effective-medium approximation (EMA) by introducing weighted transition rates as inferred from an exact expression for the diffusion coefficient in one-dimensional disordered chains. Monte Carlo simulations were made to check the validity of the approximations. Approximate Arrhenian behavior can be achieved in finite temperature intervals in three- and higher-dimensional lattices by adjusting the relative strengths of the barrier and trap disorder. Exact Arrhenian behavior of the diffusion coefficient can only be obtained in infinite dimensions.
Comments: 18 pages LaTex, 3 embedded encapsulated Postscript figures, to be published in: J. of Phys.: Condensed Matter
Anomalous Behavior of the Diffusion Coefficient in Interacting Adsorbates
Diffusion coefficient of a Brownian particle in equilibrium and nonequilibrium: Einstein model and beyond
General technique of calculating drift velocity and diffusion coefficient in arbitrary periodic systems
