Active Brownian motion with memory delay induced by a viscoelastic medium
Abstract
By now active Brownian motion is a well-established model to describe the motion of mesoscopic self-propelled particles in a Newtonian fluid. On the basis of the generalized Langevin equation, we present an analytic framework for active Brownian motion with memory delay assuming time-dependent friction kernels for both translational and orientational degrees of freedom to account for the time-delayed response of a viscoelastic medium. Analytical results are obtained for the orientational correlation function, mean displacement and mean-square displacement which we evaluate in particular for a Maxwell fluid characterized by a kernel which decays exponentially in time. Further, we identify a memory induced delay between the effective self-propulsion force and the particle orientation which we quantify in terms of a special dynamical correlation function. In principle our predictions can be verified for an active colloidal particle in various viscoelastic environments such as a polymer solution.
Cite
@article{arxiv.2202.04403,
title = {Active Brownian motion with memory delay induced by a viscoelastic medium},
author = {Alexander R. Sprenger and Christian Bair and Hartmut Löwen},
journal= {arXiv preprint arXiv:2202.04403},
year = {2022}
}
Comments
9 pages, 5 figures