English

Aging and diffusion in low dimensional environments

Statistical Mechanics 2009-10-30 v1

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 (tw,t)(t_w, t) quantities from the probability distribution Q(z,t,tw)Q(z,t,t_w) of the relative displacement z=x(t)x(tw)z = x(t) - x(t_w) in the limit of large waiting time twt_w \to \infty using numerical and analytical techniques. We find three generic large time regimes: (i) a quasi-equilibrium regime (finite τ=ttw\tau=t-t_w) where Q(z,τ)Q(z,\tau) satisfies a general FDT equation (ii) an asymptotic diffusion regime for large time separation where Q(z)dzQˉ[L(t)/L(tw)]dz/L(t)Q(z) dz \sim \bar{Q}[L(t)/L(t_w)] dz/L(t) (iii) an intermediate ``aging'' regime for intermediate time separation (h(t)/h(tw)h(t)/h(t_w) finite), with Q(z,t,t)=f(z,h(t)/h(t))Q(z,t,t') = f(z,h(t)/h(t')) . In the unbiased Sinai model we find numerical evidence for regime (i) and (ii), and for (iii) with Q(z,t,t)ˉ=Q0(z)f(h(t)/h(t))\bar{Q(z,t,t')} = Q_0(z) f(h(t)/h(t')) and h(t)lnth(t) \sim \ln t. Since h(t)L(t)h(t) \sim L(t) 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, h(t)h(t) and f(x)f(x) 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 h(t)h(t).

Keywords

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