Universality and non-universality of mobility in heterogeneous single-file systems and Rouse chains

Abstract

We study analytically the tracer particle mobility in single-file systems with distributed friction constants. Our system serves as a prototype for non-equilibrium, heterogeneous, strongly interacting Brownian systems. The long time dynamics for such a single-file setup belongs to the same universality class as the Rouse model with dissimilar beads. The friction constants are drawn from a density () and we derive an asymptotically exact solution for the mobility distribution P[μ0(s)], where μ0(s) is the Laplace-space mobility. If is light-tailed (first moment exists) we find a self-averaging behaviour: P[μ0(s)]=δ[μ0(s)-μ(s)] with μ(s) s1/2. When () is heavy-tailed, () -1-α \ (0<α<1) for large we obtain moments [μs(0)]n sβ n where β=1/(1+α) and no self-averaging. The results are corroborated by simulations.