Oscillatory rheotaxis of artificial swimmers in microchannels

Ranabir Dey; Carola M. Buness; Babak Vajdi Hokmabad; Chenyu Jin; Corinna C. Maass

doi:10.1038/s41467-022-30611-1

Oscillatory rheotaxis of artificial swimmers in microchannels

Ranabir Dey^*
, Carola M. Buness
, Babak Vajdi Hokmabad
, Chenyu Jin
, Corinna C. Maass^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

Biological microswimmers navigate upstream of an external flow with trajectories ranging from linear to spiralling and oscillatory. Such a rheotactic response primarily stems from the hydrodynamic interactions triggered by the complex shapes of the microswimmers, such as flagellar chirality. We show here that a self-propelling droplet exhibits oscillatory rheotaxis in a microchannel, despite its simple spherical geometry. Such behaviour has been previously unobserved in artificial swimmers. Comparing our experiments to a purely hydrodynamic theory model, we demonstrate that the oscillatory rheotaxis of the droplet is primarily governed by both the shear flow characteristics and the interaction of the finite-sized microswimmer with all four microchannel walls. The dynamics can be controlled by varying the external flow strength, even leading to the rheotactic trapping of the oscillating droplet. Our results provide a realistic understanding of the behaviour of active particles navigating in confined microflows relevant in many biotechnology applications.

Original language	English
Article number	2952
Journal	Nature communications
Volume	13
Issue number	1
Early online date	26 May 2022
DOIs	https://doi.org/10.1038/s41467-022-30611-1
Publication status	Published - Dec 2022

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Dey-2022-Oscillatory-rheotaxis-of-artificialFinal published version, 2.41 MBLicence: CC BY

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title = "Oscillatory rheotaxis of artificial swimmers in microchannels",

abstract = "Biological microswimmers navigate upstream of an external flow with trajectories ranging from linear to spiralling and oscillatory. Such a rheotactic response primarily stems from the hydrodynamic interactions triggered by the complex shapes of the microswimmers, such as flagellar chirality. We show here that a self-propelling droplet exhibits oscillatory rheotaxis in a microchannel, despite its simple spherical geometry. Such behaviour has been previously unobserved in artificial swimmers. Comparing our experiments to a purely hydrodynamic theory model, we demonstrate that the oscillatory rheotaxis of the droplet is primarily governed by both the shear flow characteristics and the interaction of the finite-sized microswimmer with all four microchannel walls. The dynamics can be controlled by varying the external flow strength, even leading to the rheotactic trapping of the oscillating droplet. Our results provide a realistic understanding of the behaviour of active particles navigating in confined microflows relevant in many biotechnology applications.",

author = "Ranabir Dey and Buness, \{Carola M.\} and Hokmabad, \{Babak Vajdi\} and Chenyu Jin and Maass, \{Corinna C.\}",

note = "Funding Information: C.C.M., B.V.H. and R.D. acknowledge funding from the DFG SPP 1726 “Microswimmers”, grant number MA 6330/1-2, and C.C.M. and C.J. from the BMBF/MPG MaxSynBio initiative. R.D. also acknowledges support from IIT Hyderabad. Publisher Copyright: {\textcopyright} 2022, The Author(s).",

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AU - Maass, Corinna C.

N1 - Funding Information: C.C.M., B.V.H. and R.D. acknowledge funding from the DFG SPP 1726 “Microswimmers”, grant number MA 6330/1-2, and C.C.M. and C.J. from the BMBF/MPG MaxSynBio initiative. R.D. also acknowledges support from IIT Hyderabad. Publisher Copyright: © 2022, The Author(s).

PY - 2022/12

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N2 - Biological microswimmers navigate upstream of an external flow with trajectories ranging from linear to spiralling and oscillatory. Such a rheotactic response primarily stems from the hydrodynamic interactions triggered by the complex shapes of the microswimmers, such as flagellar chirality. We show here that a self-propelling droplet exhibits oscillatory rheotaxis in a microchannel, despite its simple spherical geometry. Such behaviour has been previously unobserved in artificial swimmers. Comparing our experiments to a purely hydrodynamic theory model, we demonstrate that the oscillatory rheotaxis of the droplet is primarily governed by both the shear flow characteristics and the interaction of the finite-sized microswimmer with all four microchannel walls. The dynamics can be controlled by varying the external flow strength, even leading to the rheotactic trapping of the oscillating droplet. Our results provide a realistic understanding of the behaviour of active particles navigating in confined microflows relevant in many biotechnology applications.

AB - Biological microswimmers navigate upstream of an external flow with trajectories ranging from linear to spiralling and oscillatory. Such a rheotactic response primarily stems from the hydrodynamic interactions triggered by the complex shapes of the microswimmers, such as flagellar chirality. We show here that a self-propelling droplet exhibits oscillatory rheotaxis in a microchannel, despite its simple spherical geometry. Such behaviour has been previously unobserved in artificial swimmers. Comparing our experiments to a purely hydrodynamic theory model, we demonstrate that the oscillatory rheotaxis of the droplet is primarily governed by both the shear flow characteristics and the interaction of the finite-sized microswimmer with all four microchannel walls. The dynamics can be controlled by varying the external flow strength, even leading to the rheotactic trapping of the oscillating droplet. Our results provide a realistic understanding of the behaviour of active particles navigating in confined microflows relevant in many biotechnology applications.

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Oscillatory rheotaxis of artificial swimmers in microchannels

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