Diffusion in periodic, correlated random forcing landscapes

Abstract

We study the dynamics of a Brownian particle in a strongly correlated quenched random potential defined as a periodically-extended (with period L) finite trajectory of a fractional Brownian motion with arbitrary Hurst exponent H ∈ (0,1). While the periodicity ensures that the ultimate long-time behavior is diffusive, the generalised Sinai potential considered here leads to a strong logarithmic confinement of particle trajectories at intermediate times. These two competing trends lead to dynamical frustration and result in a rich statistical behavior of the diffusion coefficient DL: Although one has the typical value D typL (-β LH), we show via an exact analytical approach that the positive moments (k>0) scale like DkL [-c' (k β LH)1/(1+H)], and the negative ones as D-kL (a' (k β LH)2), c' and a' being numerical constants and β the inverse temperature. These results demonstrate that DL is strongly non-self-averaging. We further show that the probability distribution of DL has a log-normal left tail and a highly singular, one-sided log-stable right tail reminiscent of a Lifshitz singularity.