Issue 45, 2022

Motility of acoustically powered micro-swimmers in a liquid crystalline environment

Abstract

Suspensions of microswimmers in liquid crystals demonstrate remarkably complex dynamics and serve as a model system for studying active nematics. So far, experimental realization of microswimmers suspended in liquid crystalline media has relied on biological microorganisms that impose strict limitations on the compatible media and makes it difficult to regulate activity. Here, we demonstrate that acoustically powered bubble microswimmers can efficiently self-propel in a lyotropic liquid crystal. The velocity of the swimmers is controlled by the amplitude of the acoustic field. Histograms of swimming directions with respect to the local nematic field reveal a bimodal distribution: the swimmers tend to either fully align with or swim perpendicular to the director field of the liquid crystal, occasionally switching between these two states. The bubble-induced streaming from a swimmer locally melts the liquid crystal and produces topological defects at the tail of the swimmer. We show that the defect proliferation rate increases with the angle between the swimmer's velocity and the local orientation of the director field.

Graphical abstract: Motility of acoustically powered micro-swimmers in a liquid crystalline environment

Supplementary files

Article information

Article type
Paper
Submitted
29 Aug 2022
Accepted
27 Oct 2022
First published
04 Nov 2022

Soft Matter, 2022,18, 8641-8646

Author version available

Motility of acoustically powered micro-swimmers in a liquid crystalline environment

J. Katuri, A. Snezhko and A. Sokolov, Soft Matter, 2022, 18, 8641 DOI: 10.1039/D2SM01171A

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