Driven Shear Flow in Biological Magnetoactive Fluids

M. Marmol; C. Cottin-Bizonne; A. Cēbers; D. Faivre; C. Ybert

doi:10.1103/qrgn-m91t

Driven Shear Flow in Biological Magnetoactive Fluids

M. Marmol
, C. Cottin-Bizonne
, A. Cēbers
, D. Faivre^*
, C. Ybert^*

^*Šī darba korespondējošais autors

Fizikas nodaļa

Aix-Marseille Université
Universite Claude Bernard Lyon 1

Zinātniskās darbības rezultāts: Devums žurnālam › Zinātniskais raksts (žurnālā) › koleģiāli recenzēts

1 Atsauce (Scopus)

Kopsavilkums

Active fluids made of powered suspended entities spontaneously give rise to patterns and flows. Yet, how the swimmers activity can be harnessed by external cues into coherent macroscopic flows remains a question of biological and applied relevance. Here, we use magnetotactic bacteria, which respond both to chemical and magnetic signals, to control the onset of global scale shear flows. Shaping positional and orientational orders with external fields allows the force dipoles of each swimmer to combine into a finite active stress. Incorporated in a magnetoactive model, this driving contribution quantitatively captures the observed flows in steady state, while the time-dependent response to rotating fields unveils additional complexity.

Oriģinālvaloda	Angļu
Raksta numurs	248301
Žurnāls	Physical Review Letters
Sējums	135
Izdevuma numurs	24
DOIs	https://doi.org/10.1103/qrgn-m91t
Publikācijas statuss	Publicēts - 12 dec. 2025

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abstract = "Active fluids made of powered suspended entities spontaneously give rise to patterns and flows. Yet, how the swimmers activity can be harnessed by external cues into coherent macroscopic flows remains a question of biological and applied relevance. Here, we use magnetotactic bacteria, which respond both to chemical and magnetic signals, to control the onset of global scale shear flows. Shaping positional and orientational orders with external fields allows the force dipoles of each swimmer to combine into a finite active stress. Incorporated in a magnetoactive model, this driving contribution quantitatively captures the observed flows in steady state, while the time-dependent response to rotating fields unveils additional complexity.",

author = "M. Marmol and C. Cottin-Bizonne and A. Cēbers and D. Faivre and C. Ybert",

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T1 - Driven Shear Flow in Biological Magnetoactive Fluids

AU - Marmol, M.

AU - Cottin-Bizonne, C.

AU - Cēbers, A.

AU - Faivre, D.

AU - Ybert, C.

PY - 2025/12/12

Y1 - 2025/12/12

N2 - Active fluids made of powered suspended entities spontaneously give rise to patterns and flows. Yet, how the swimmers activity can be harnessed by external cues into coherent macroscopic flows remains a question of biological and applied relevance. Here, we use magnetotactic bacteria, which respond both to chemical and magnetic signals, to control the onset of global scale shear flows. Shaping positional and orientational orders with external fields allows the force dipoles of each swimmer to combine into a finite active stress. Incorporated in a magnetoactive model, this driving contribution quantitatively captures the observed flows in steady state, while the time-dependent response to rotating fields unveils additional complexity.

AB - Active fluids made of powered suspended entities spontaneously give rise to patterns and flows. Yet, how the swimmers activity can be harnessed by external cues into coherent macroscopic flows remains a question of biological and applied relevance. Here, we use magnetotactic bacteria, which respond both to chemical and magnetic signals, to control the onset of global scale shear flows. Shaping positional and orientational orders with external fields allows the force dipoles of each swimmer to combine into a finite active stress. Incorporated in a magnetoactive model, this driving contribution quantitatively captures the observed flows in steady state, while the time-dependent response to rotating fields unveils additional complexity.

UR - https://www.scopus.com/pages/publications/105024479727

U2 - 10.1103/qrgn-m91t

DO - 10.1103/qrgn-m91t

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SN - 0031-9007

VL - 135

JO - Physical Review Letters

JF - Physical Review Letters

IS - 24

M1 - 248301

ER -

Driven Shear Flow in Biological Magnetoactive Fluids

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