This title appears in the Scientific Report : 2018 
Clustering of microswimmers: interplay of shape and hydrodynamics
Theers, Mario
Westphal, Elmar (Corresponding author) / Qi, Kai / Winkler, Roland G. / Gompper, Gerhard (Corresponding author)
Theorie der Weichen Materie und Biophysik; IAS-2
JARA - HPC; JARA-HPC
Soft matter, 14 (2018) 42, S. 8590 - 8603
London Royal Soc. of Chemistry 2018
10.1039/C8SM01390J
30339172
Journal Article
Collective Dynamics of Microswimmers
Physical Basis of Diseases
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OpenAccess
OpenAccess
Please use the identifier: http://dx.doi.org/10.1039/C8SM01390J in citations.
Please use the identifier: http://hdl.handle.net/2128/19907 in citations.


The spatiotemporal dynamics in systems of active self-propelled particles is controlled by the propulsion mechanism in combination with various direct interactions, such as steric repulsion and hydrodynamics. These direct interactions are typically anisotropic, and come in different “flavors”, such as spherical and elongated particle shapes, pusher and puller flow fields, etc. The combination of the various aspects is expected to lead to new emergent behavior. However, it is a priori not evident whether shape and hydrodynamics act synergistically or antagonistically to generate motility-induced clustering (MIC) and phase separation (MIPS). We employ a model of prolate spheroidal microswimmers—called squirmers—in quasi-two-dimensional confinement to address this issue by mesoscale hydrodynamic simulations. For comparison, non-hydrodynamic active Brownian particles (ABPs) are considered to elucidate the contribution of hydrodynamic interactions. For spherical particles, the comparison between ABPs and hydrodynamic-squirmer ensembles reveals a suppression of MIPS due to hydrodynamic interactions. Yet, our analysis shows that dynamic clusters exist, with a broad size distribution. The fundamental difference between ABPs and squirmers is attributed to an increased reorientation of squirmers by hydrodynamic torques during their collisions. In contrast, for elongated squirmers, hydrodynamics interactions enhance MIPS. The transition to a phase-separated state strongly depends on the nature of the swimmer's flow field—with an increased tendency toward MIPS for pullers, and a reduced tendency for pushers. Thus, hydrodynamic interactions show opposing effects on MIPS for spherical and elongated microswimmers, and details of the propulsion mechanism of biological microswimmers may be very important to determine their collective behavior.