Issue 12, 2024

The motion of micro-swimmers over a cavity in a micro-channel

Abstract

This article combines the lattice Boltzmann method (LBM) with the squirmer model to investigate the motion of micro-swimmers in a channel-cavity system. The study analyses various influential factors, including the value of the squirmer-type factor (β), the swimming Reynolds number (Rep), the size of the cavity, initial position and particle size on the movement of micro-swimmers within the channel-cavity system. We simultaneously studied three types of squirmer models, Puller (β > 0), Pusher (β < 0), and Neutral (β = 0) swimmers. The findings reveal that the motion of micro-swimmers is determined by the value of β and Rep, which can be classified into six distinct motion modes. For Puller and Pusher, when the β value is constant, an increase in Rep will lead to transition in the motion mode. Moreover, the appropriate depth of cavity within the channel-cavity system plays a crucial role in capturing and separating Neutral swimmers. This study, for the first time, explores the effect of complex channel-cavity systems on the behaviour of micro-swimmers and highlights their separation and capture ability. These findings offer novel insights for the design and enhancement of micro-channel structures in achieving efficient separation and capture of micro-swimmers.

Graphical abstract: The motion of micro-swimmers over a cavity in a micro-channel

Article information

Article type
Paper
Submitted
23 Nov 2023
Accepted
20 Feb 2024
First published
21 Feb 2024

Soft Matter, 2024,20, 2789-2803

The motion of micro-swimmers over a cavity in a micro-channel

X. Hu, W. Chen, J. Lin, D. Nie, Z. Zhu and P. Lin, Soft Matter, 2024, 20, 2789 DOI: 10.1039/D3SM01589K

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