On the relevance of q-distribution functions: The return time distribution of restricted random walker

Abstract

There exist a large literature on the application of q-statistics to the out-of-equilibrium non-ergodic systems in which some degree of strong correlations exists. Here we study the distribution of first return times to zero, PR(0,t), of a random walk on the set of integers \0,1,2,...,L\ with a position dependent transition probability given by |n/L|a. We find that for all values of a∈[0,2] PR(0,t) can be fitted by q-exponentials, but only for a=1 is PR(0,t) given exactly by a q-exponential in the limit L→∞. This is a remarkable result since the exact analytical solution of the corresponding continuum model represents PR(0,t) as a sum of Bessel functions with a smooth dependence on a from which we are unable to identify a=1 as of special significance. However, from the high precision numerical iteration of the discrete Master Equation, we do verify that only for a=1 is PR(0,t) exactly a q-exponential and that a tiny departure from this parameter value makes the distribution deviate from q-exponential. Further research is certainly required to identify the reason for this result and also the applicability of q-statistics and its domain.