Single file dynamics of tethered random walkers

Abstract

We consider the single-file dynamics of N identical random walkers moving with diffusivity D in one dimension (walkers bounce off each other when attempting to overtake). Additionally, we require that the separation between neighboring walkers cannot exceed a threshold value and therefore call them ``tethered walkers'' (they behave as if bounded by strings which tighten fully when reaching the maximum length ). For finite , we study the diffusional relaxation to the equilibrium state and characterize the latter [the long-time relaxation is exponential with a characteristic time that scales as (N)2/D]. In particular, our approximate approach for the N-particle probability distribution yields the one-particle distribution function of the central and edge particles [the first two positional moments are given as power expansions in /4Dt]. For N=2, we find an exact solution (both in the continuum case and on-lattice) and use it to test our approximations for one-particle distributions, positional moments, and correlations. For finite and arbitrary N, edge particles move with an effective long-time diffusivity D/N, in sharp contrast with the 1/(N)-behavior observed when =∞. Finally, we compute the probability distribution of the equilibrium system length and the associated entropy. We find that the force required to change this length by a given amount is linear in this quantity, the (entropic) spring constant being 6kBT/(N2). In this respect, the system behaves like an ideal polymer. Our main analytical results are confirmed by Monte Carlo simulations.

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