Issue 45, 2022

Curvature-controlled geometrical lensing behavior in self-propelled colloidal particle systems

Abstract

In many biological systems, the curvature of the surfaces cells live on influences their collective properties. Curvature should likewise influence the behavior of active colloidal particles. We show using molecular simulation of self-propelled active particles on surfaces of Gaussian curvature (both positive and negative) how curvature sign and magnitude can alter the system's collective behavior. Curvature acts as a geometrical lens and shifts the critical density of motility-induced phase separation (MIPS) to lower values for positive curvature and higher values for negative curvature, which we explain theoretically by the nature of parallel lines in spherical and hyperbolic space. Curvature also fluidizes dense MIPS clusters due to the emergence of defect patterns disrupting the crystalline order inside the clusters. Using our findings, we engineer three confining surfaces that strategically combine regions of different curvature to produce a host of novel dynamical behaviors, including cyclic MIPS on spherocylinders, directionally biased cyclic MIPS on spherocones, and position dependent cluster fluctuations on metaballs.

Graphical abstract: Curvature-controlled geometrical lensing behavior in self-propelled colloidal particle systems

Supplementary files

Article information

Article type
Paper
Submitted
27 Jul 2022
Accepted
22 Sep 2022
First published
27 Sep 2022

Soft Matter, 2022,18, 8561-8571

Author version available

Curvature-controlled geometrical lensing behavior in self-propelled colloidal particle systems

P. W. A. Schönhöfer and S. C. Glotzer, Soft Matter, 2022, 18, 8561 DOI: 10.1039/D2SM01012G

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