First-passage dynamics of obstructed tracer particle diffusion in one-dimensional systems

Abstract

The standard setup for single-file diffusion is diffusing particles in one dimension which cannot overtake each other, where the dynamics of a tracer (tagged) particle is of main interest. In this article we generalise this system and investigate first-passage properties of a tracer particle when flanked by crowder particles which may, besides diffuse, unbind (rebind) from (to) the one-dimensional lattice with rates k off (k on). The tracer particle is restricted to diffuse with rate kD on the lattice. Such a model is relevant for the understanding of gene regulation where regulatory proteins are searching for specific binding sites ona crowded DNA. We quantify the first-passage time distribution, f(t) (t is time), numerically using the Gillespie algorithm, and estimate it analytically. In terms of our key parameter, the unbinding rate k off, we study the bridging of two known regimes: (i) when unbinding is frequent the particles may effectively pass each other and we recover the standard single particle result f(t) t-3/2 with a renormalized diffusion constant, (ii) when unbinding is rare we recover well-known single-file diffusion result f(t) t-7/4. The intermediate cases display rich dynamics, with the characteristic f(t)-peak and the long-time power-law slope both being sensitive to k off.