Issue 43, 2021

Diversity of self-propulsion speeds reduces motility-induced clustering in confined active matter

Abstract

Self-propelled swimmers such as bacteria agglomerate into clusters as a result of their persistent motion. In 1D, those clusters do not coalesce macroscopically and the stationary cluster size distribution (CSD) takes an exponential form. We develop a minimal lattice model for active particles in narrow channels to study how clustering is affected by the interplay between self-propulsion speed diversity and confinement. A mixture of run-and-tumble particles with a distribution of self-propulsion speeds is simulated in 1D. Particles can swap positions at rates proportional to their relative self-propulsion speed. Without swapping, we find that the average cluster size Lc decreases with diversity and follows a non-arithmetic power mean of the single-component Lc's, unlike the case of tumbling-rate diversity previously studied. Effectively, the mixture is thus equivalent to a system of identical particles whose self-propulsion speed is the harmonic mean self-propulsion speed of the mixture. With swapping, particles escape more quickly from clusters. As a consequence, Lc decreases with swapping rates and depends less strongly on diversity. We derive a dynamical equilibrium theory for the CSDs of binary and fully polydisperse systems. Similarly to the clustering behaviour of one-component models, our qualitative results for mixtures are expected to be universal across active matter. Using literature experimental values for the self-propulsion speed diversity of unicellular swimmers known as choanoflagellates, which naturally differentiate into slower and faster cells, we predict that the error in estimating their Lcvia one-component models which use the conventional arithmetic mean self-propulsion speed is around 30%.

Graphical abstract: Diversity of self-propulsion speeds reduces motility-induced clustering in confined active matter

Article information

Article type
Paper
Submitted
08 Jul 2021
Accepted
12 Oct 2021
First published
14 Oct 2021

Soft Matter, 2021,17, 9926-9936

Diversity of self-propulsion speeds reduces motility-induced clustering in confined active matter

P. de Castro, F. M. Rocha, S. Diles, R. Soto and P. Sollich, Soft Matter, 2021, 17, 9926 DOI: 10.1039/D1SM01009C

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