Issue 4, 2023

Settling mode of a bottom-heavy squirmer in a narrow vessel

Abstract

The lattice Boltzmann-immersed boundary (IB-LB) method is used to numerically simulate the sedimentation motion of a single two-dimensional, bottom-heavy squirmer in a narrow vessel. The effects of the swimming Reynolds number Res = 0.1–3, eccentricity distance l = 0.15d–0.75d, and density ratio of squirmer to fluid γ = 1.1–2.0 on the settlement motion characteristics are investigated and analyzed. The results showed that four settling modes exist: vertical motion, unilateral oscillation, oscillation, and tilt. The bottom-heavy neutral squirmer and puller settle in the vessel during vertical motion when Res is 0.1–1.5. By increasing Res and swimming strength |β|, the bottom-heavy squirmer becomes more self-driven, shifting its settling mode from vertical motion to unilateral oscillation or oscillation. Increasing l or |β| does not affect the bottom-heavy neutral squirmer and puller's vertical settling mode but shifts the bottom-heavy pusher's settling mode from unilateral oscillation to oscillation or oscillation to unilateral oscillation. Similarly, altering γ or |β| has no impact on the eccentric neutral squirmer and puller's settling mode; however, pushers will switch from oscillation mode to attraction mode or from oscillation mode to tilt mode. Additionally, it was found that after the squirmer collided with the bottom wall, the bottom-heavy squirmer settled at the bottom of the vessel in a different state of motion.

Graphical abstract: Settling mode of a bottom-heavy squirmer in a narrow vessel

Article information

Article type
Paper
Submitted
03 Nov 2022
Accepted
19 Dec 2022
First published
19 Dec 2022

Soft Matter, 2023,19, 652-669

Settling mode of a bottom-heavy squirmer in a narrow vessel

Q. Tingting, L. Jianzhong, O. Zhenyu and Z. Jue, Soft Matter, 2023, 19, 652 DOI: 10.1039/D2SM01442D

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