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Main Authors: Lagoin, Marc, Lacherez, Juliette, de Tournemire, Guirec, Badr, Ahmad, Amarouchene, Yacine, Allard, Antoine, Salez, Thomas
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.08369
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author Lagoin, Marc
Lacherez, Juliette
de Tournemire, Guirec
Badr, Ahmad
Amarouchene, Yacine
Allard, Antoine
Salez, Thomas
author_facet Lagoin, Marc
Lacherez, Juliette
de Tournemire, Guirec
Badr, Ahmad
Amarouchene, Yacine
Allard, Antoine
Salez, Thomas
contents In the presence of a laminar shear flow, the diffusion of passive colloidal particles is enhanced in the direction parallel to the flow. This classical phenomenon is known as Taylor-Aris dispersion. Besides, microorganisms, such as active microswimmers, exhibit an effective diffusive behavior at long times. Combining the two ingredients above, a natural question then emerges on how the effective diffusion of active microswimmers is altered in shear flows -- a widespread situation in natural environments with practical implications, \textit{e.g.} regarding biofilm formation. In this Letter, we investigate the motility and dispersion of \textit{Chlamydomonas reinhardtii} microalgae, within a rectangular microfluidic channel subjected to a sinusoidal Poiseuille flow. Using high-resolution optical microscopy and a particle-tracking algorithm, we reconstruct individual trajectories in various flow conditions and statistically analyze them through moment theory and sliding windowed demodulation. We find that the velocity fluctuations and the dispersion coefficient increase as the flow amplitude is increased, with only weak dependencies on the flow periodicity. Importantly, our results demonstrate that the generalization of Taylor-Aris law to active particles is valid.
format Preprint
id arxiv_https___arxiv_org_abs_2507_08369
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Enhanced dispersion of active microswimmers in confined flows
Lagoin, Marc
Lacherez, Juliette
de Tournemire, Guirec
Badr, Ahmad
Amarouchene, Yacine
Allard, Antoine
Salez, Thomas
Statistical Mechanics
Biological Physics
Classical Physics
In the presence of a laminar shear flow, the diffusion of passive colloidal particles is enhanced in the direction parallel to the flow. This classical phenomenon is known as Taylor-Aris dispersion. Besides, microorganisms, such as active microswimmers, exhibit an effective diffusive behavior at long times. Combining the two ingredients above, a natural question then emerges on how the effective diffusion of active microswimmers is altered in shear flows -- a widespread situation in natural environments with practical implications, \textit{e.g.} regarding biofilm formation. In this Letter, we investigate the motility and dispersion of \textit{Chlamydomonas reinhardtii} microalgae, within a rectangular microfluidic channel subjected to a sinusoidal Poiseuille flow. Using high-resolution optical microscopy and a particle-tracking algorithm, we reconstruct individual trajectories in various flow conditions and statistically analyze them through moment theory and sliding windowed demodulation. We find that the velocity fluctuations and the dispersion coefficient increase as the flow amplitude is increased, with only weak dependencies on the flow periodicity. Importantly, our results demonstrate that the generalization of Taylor-Aris law to active particles is valid.
title Enhanced dispersion of active microswimmers in confined flows
topic Statistical Mechanics
Biological Physics
Classical Physics
url https://arxiv.org/abs/2507.08369