Polymer translocation through nanopore assisted by an environment of active rods

Abstract

We use a combination of computer simulations and iso-flux tension propagation (IFTP) theory to investigate translocation dynamics of a flexible linear polymer through a nanopore into an environment composed of repulsive active rods in 2D. We demonstrate that the rod activity induces a crowding effect on the polymer, leading to a time-dependent net force that facilitates translocation into the active environment. Incorporating this force into the IFTP theory for pore-driven translocation allows us to characterise translocation dynamics in detail and derive a scaling form for the average translocation time as τ Lr / FSP , where Lr and FSP are the rod length and self-propelling force acting on the rods, respectively, and is the Flory exponent.