Anomalous field-induced growth of fluctuations in dynamics of a biased intruder moving in a quiescent medium

Abstract

We present exact results on the dynamics of a biased, by an external force F, intruder (BI) in a two-dimensional lattice gas of unbiased, randomly moving hard-core particles. Going beyond the usual analysis of the force-velocity relation, we study the probability distribution P( Rn) of the BI displacement Rn at time n. We show that despite the fact that the BI drives the gas to a non-equilibrium steady-state, P( Rn) converges to a Gaussian distribution as n ∞. We find that the variance σx2 of P( Rn) along F exhibits a weakly superdiffusive growth σx2 1 \, n \, (n), and a usual diffusive growth, σy2 2 \, n, in the perpendicular direction. We determine 1 and 2 exactly for arbitrary bias, in the lowest order in the density of vacancies, and show that 1 | F|2 for small bias, which signifies that superdiffusive behaviour emerges beyond the linear-response approximation. Monte Carlo simulations confirm our analytical results, and reveal a striking field-induced superdiffusive behavior σx2 n3/2 for infinitely long 2D stripes and 3D capillaries.