The active trap model

TL;DR

This paper introduces an active generalization of the classical trap model to describe particle dynamics in active gels, revealing sub-diffusive behavior due to activity, with results supported by an exactly solvable harmonic trap case.

Contribution

It presents a novel active trap model that modifies classical diffusion behavior, demonstrating how activity induces sub-diffusion in particle motion within traps.

Findings

Mean square displacement becomes sub-diffusive under activity.

Sub-diffusive behavior depends on trap depth distribution.

Results are robust for more realistic trap shapes with strong activity.

Abstract

Motivated by the dynamics of particles embedded in active gels, both in-vitro and inside the cytoskeleton of living cells, we study an active generalization of the classical trap model. We demonstrate that activity leads to dramatic modifications in the diffusion compared to the thermal case: the mean square displacement becomes sub-diffusive, spreading as a power-law in time, when the trap depth distribution is a Gaussian and is slower than any power-law when it is drawn from an exponential distribution. The results are derived for a simple, exactly solvable, case of harmonic traps. We then argue that the results are robust for more realistic trap shapes when the activity is strong.