posted on 2018-12-10, 13:46authored byArnold J.T.M. Mathijssen, Amin Doostmohammadi, Julia M. Yeomans, Tyler Shendruk
One of the principal mechanisms by which surfaces and interfaces affect microbial
life is by perturbing the hydrodynamic flows generated by swimming. By summing
a recursive series of image systems, we derive a numerically tractable approximation
to the three-dimensional flow fields of a stokeslet (point force) within a viscous film
between a parallel no-slip surface and a no-shear interface and, from this Green’s
function, we compute the flows produced by a force- and torque-free micro-swimmer.
We also extend the exact solution of Liron & Mochon (J. Engng Maths, vol. 10 (4),
1976, pp. 287–303) to the film geometry, which demonstrates that the image series
gives a satisfactory approximation to the swimmer flow fields if the film is sufficiently
thick compared to the swimmer size, and we derive the swimmer flows in the
thin-film limit. Concentrating on the thick-film case, we find that the dipole moment
induces a bias towards swimmer accumulation at the no-slip wall rather than the
water–air interface, but that higher-order multipole moments can oppose this. Based
on the analytic predictions, we propose an experimental method to find the multipole
coefficient that induces circular swimming trajectories, allowing one to analytically
determine the swimmer’s three-dimensional position under a microscope.
History
School
Science
Department
Mathematical Sciences
Published in
Journal of Fluid Mechanics
Volume
806
Pages
35 - 70
Citation
MATHIJSSEN, A.J.T.M. ... et al., 2016. Hydrodynamics of micro-swimmers in films. Journal of Fluid Mechanics, 806, pp. 35-70.
This work is made available according to the conditions of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International (CC BY-NC-ND 4.0) licence. Full details of this licence are available at: https://creativecommons.org/licenses/by-nc-nd/4.0/
Acceptance date
2016-09-01
Publication date
2016-09-29
Notes
This paper was submitted for publication to the journal Journal of Fluid Mechanics and the definitive published version is available at https://doi.org/10.1017/jfm.2016.479