Aging and diffusion in low dimensional environments
Abstract
We study out of equilibrium dynamics and aging for a particle diffusing in one dimensional environments, such as the random force Sinai model, as a toy model for low dimensional systems. We study fluctuations of two times quantities from the probability distribution of the relative displacement in the limit of large waiting time using numerical and analytical techniques. We find three generic large time regimes: (i) a quasi-equilibrium regime (finite ) where satisfies a general FDT equation (ii) an asymptotic diffusion regime for large time separation where (iii) an intermediate ``aging'' regime for intermediate time separation ( finite), with . In the unbiased Sinai model we find numerical evidence for regime (i) and (ii), and for (iii) with and . Since in Sinai's model there is a singularity in the diffusion regime to allow for regime (iii). A directed model, related to the biased Sinai model is solved and shows (ii) and (iii) with strong non self-averaging properties. Similarities and differences with mean field results are discussed. A general approach using scaling of next highest encountered barriers is proposed to predict aging properties, and in landscapes with fast growing barriers. We introduce a new exactly solvable model, with barriers and wells, which shows clearly diffusion and aging regimes with a rich variety of functions .
Cite
@article{arxiv.cond-mat/9705249,
title = {Aging and diffusion in low dimensional environments},
author = {Laurent Laloux and Pierre Le Doussal},
journal= {arXiv preprint arXiv:cond-mat/9705249},
year = {2009}
}
Comments
43 pages, 19 .eps figures, RevTeX