Confinement Reduces Surface Accumulation of Swimming Bacteria

Da Wei; Shiyuan Hu; Tangmiao Tang; Yaochen Yang; Fanlong Meng; Yi Peng

doi:10.1103/dvc8-tlh1

Confinement Reduces Surface Accumulation of Swimming Bacteria

Da Wei
, Shiyuan Hu
, Tangmiao Tang
, Yaochen Yang
, Fanlong Meng^*
, Yi Peng^*

^*Corresponding author for this work

School of Physics

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

Abstract

Many swimming bacteria naturally inhabit confined environments, yet how confinement influences their swimming behaviors remains unclear. Here, we combine experiments, continuum modeling, and particle-based simulations to investigate near-surface bacterial swimming in dilute suspensions under varying confinement. Confinement reduces near-surface accumulation and facilitates bacterial escape. These effects are quantitatively captured by models incorporating the force quadrupole, a higher-order hydrodynamic singularity, that generates a rotational flow reorienting bacteria away from surfaces. Under strong confinement, bacterial trajectories straighten due to the balancing torques exerted by opposing surfaces. These findings highlight the role of hydrodynamic quadrupole interactions in near-surface bacterial motility, with implications for microbial ecology, infection control, and industrial applications.

Original language	English
Article number	188401
Journal	Physical Review Letters
Volume	135
Issue number	18
DOIs	https://doi.org/10.1103/dvc8-tlh1
State	Published - 31 Oct 2025

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title = "Confinement Reduces Surface Accumulation of Swimming Bacteria",

abstract = "Many swimming bacteria naturally inhabit confined environments, yet how confinement influences their swimming behaviors remains unclear. Here, we combine experiments, continuum modeling, and particle-based simulations to investigate near-surface bacterial swimming in dilute suspensions under varying confinement. Confinement reduces near-surface accumulation and facilitates bacterial escape. These effects are quantitatively captured by models incorporating the force quadrupole, a higher-order hydrodynamic singularity, that generates a rotational flow reorienting bacteria away from surfaces. Under strong confinement, bacterial trajectories straighten due to the balancing torques exerted by opposing surfaces. These findings highlight the role of hydrodynamic quadrupole interactions in near-surface bacterial motility, with implications for microbial ecology, infection control, and industrial applications.",

author = "Da Wei and Shiyuan Hu and Tangmiao Tang and Yaochen Yang and Fanlong Meng and Yi Peng",

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doi = "10.1103/dvc8-tlh1",

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T1 - Confinement Reduces Surface Accumulation of Swimming Bacteria

AU - Wei, Da

AU - Hu, Shiyuan

AU - Tang, Tangmiao

AU - Yang, Yaochen

AU - Meng, Fanlong

AU - Peng, Yi

PY - 2025/10/31

Y1 - 2025/10/31

N2 - Many swimming bacteria naturally inhabit confined environments, yet how confinement influences their swimming behaviors remains unclear. Here, we combine experiments, continuum modeling, and particle-based simulations to investigate near-surface bacterial swimming in dilute suspensions under varying confinement. Confinement reduces near-surface accumulation and facilitates bacterial escape. These effects are quantitatively captured by models incorporating the force quadrupole, a higher-order hydrodynamic singularity, that generates a rotational flow reorienting bacteria away from surfaces. Under strong confinement, bacterial trajectories straighten due to the balancing torques exerted by opposing surfaces. These findings highlight the role of hydrodynamic quadrupole interactions in near-surface bacterial motility, with implications for microbial ecology, infection control, and industrial applications.

AB - Many swimming bacteria naturally inhabit confined environments, yet how confinement influences their swimming behaviors remains unclear. Here, we combine experiments, continuum modeling, and particle-based simulations to investigate near-surface bacterial swimming in dilute suspensions under varying confinement. Confinement reduces near-surface accumulation and facilitates bacterial escape. These effects are quantitatively captured by models incorporating the force quadrupole, a higher-order hydrodynamic singularity, that generates a rotational flow reorienting bacteria away from surfaces. Under strong confinement, bacterial trajectories straighten due to the balancing torques exerted by opposing surfaces. These findings highlight the role of hydrodynamic quadrupole interactions in near-surface bacterial motility, with implications for microbial ecology, infection control, and industrial applications.

UR - https://www.scopus.com/pages/publications/105022228945

U2 - 10.1103/dvc8-tlh1

DO - 10.1103/dvc8-tlh1

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SN - 0031-9007

VL - 135

JO - Physical Review Letters

JF - Physical Review Letters

IS - 18

M1 - 188401

ER -

Confinement Reduces Surface Accumulation of Swimming Bacteria

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