Estimating the Steady State Diffusion Coefficient Using Data from the Transient Anomalous Regime

Abstract

When particles/molecules diffuse in systems that contain obstacles, the steady-state regime (during which the mean-square displacement scales linearly with time, < r2 > t) is preceded by a transient regime. It is common to characterize this transient regime using the concept of anomalous (sub)diffusion with the scaling law < r2 > tα, where the corresponding exponent α<1. We propose a new method to estimate the critical time t* that marks the transition between these two regimes. The method uses short-time data from the transient regime to estimate t*, which can then be used to estimate the steady-state diffusion coefficient D. In other words, we propose a procedure that makes it possible to estimate the steady state diffusion coefficient without reaching the steady-state. We test the procedure with various two-dimensional lattice systems.