Microswimmers in vortices: Dynamics and trapping

TL;DR

This paper develops a theoretical model to analyze the behavior of microswimmers in vortices, revealing conditions for trapping and escape, and predicting depletion zone sizes consistent with experimental observations.

Contribution

It introduces a comprehensive deterministic and stochastic model for microswimmer dynamics in vortices, including phase space analysis and escape probability calculations.

Findings

Bounded and unbounded orbits identified near vortex centers.

A conserved quantity maps phase space and orbit types.

Predicted depletion zone size matches experimental data.

Abstract

Biological and artificial microswimmers often self-propel in external flows of vortical nature; relevant examples include algae in small-scale ocean eddies, spermatozoa in uterine peristaltic flows and bacteria in microfluidic devices. A recent experiment has shown that swimming bacteria in model vortices are expelled from the vortex all the way to a well-defined depletion zone (Sokolov and Aranson (2016) "Rapid expulsion of microswimmers by a vortical flow." Nature Comm. 7, 11114). In this paper, we propose a theoretical model to investigate the dynamics of elongated microswimmers in elementary vortices, namely active particles in two- and three-dimensional rotlets. A deterministic model first reveals the existence of bounded orbits near the centre of the vortex and unbounded orbits elsewhere. We further discover a conserved quantity of motion that allows us to map the phase space according to the type of the orbit (bounded vs unbounded). We next introduce translational and rotational noise into the system. Using a Fokker--Planck formalism, we quantify the quality of trapping near the centre of the vortex by examining the probability of escape and the mean time of escape from the region of deterministically bounded orbits. We finally show how to use these findings to formulate a prediction for the radius of the depletion zone, which compares favourably with the experiments of Sokolov and Aranson (2016).