Asymmetric simple exclusion process on the percolation cluster: Waiting time distribution in side-branches

As the simplest model of interacting-particle transport in a randomly disordered medium, we consider the asymmetric simple exclusion process (ASEP) in which particles with hard-core interactions perform biased random walks, on the supercritical percolation cluster. In this process, the long time trajectory of a marked particle consists of steps on the backbone, punctuated by time spent in side-branches. We study the probability distribution in the steady state of the waiting time T_w of a randomly chosen particle, in a side-branch since its last step along the backbone. Exact numerical evaluation of this on a single side-branch of lengths L= 1 to 9 show that for large fields, the probability distribution of log T_w has multiple well separated peaks. We extend this result to a random comb, and to the ASEP on the percolation cluster. For the latter problem, we show that in the steady state, the fractional number of particles that have been in the same side-branch for a time interval greater than T_w varies as exp( - c √(ln T_w)) for large T_w, where c depends only on the bias field. The system shows dynamical heterogeneity, with particles segregating into pockets of high and low mobilities. These long timescales are not reflected in the eigenvalue spectrum of the Markov evolution matrix.