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Related papers: Flagellar flows around bacterial swarms

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Unraveling bacterial strategies for spatial exploration is crucial for understanding the complexity in the organization of life. Bacterial motility determines the spatio-temporal structure of microbial communities, controls infection…

We systematically investigate how flagellar morphology governs the stability of bacterial Brownian motion, evaluating the effectiveness of a simplified chiral two-body model. This model, which effectively captures the specific bacterial…

Fluid Dynamics · Physics 2026-03-03 Baopi Liu , Bowen Jin , Lu Chen , Ning Liu

Escherichia coli and other bacteria use rotating helical filaments to swim. Each cell typically has about four filaments, which bundle or disperse depending on the sense of motor rotation. To study the bundling process, we built a…

Soft Condensed Matter · Physics 2009-11-10 MunJu Kim , James C. Bird , Annemarie J. Van Parys , Kenneth S. Breuer , Thomas R. Powers

We study the microscale propulsion of a rotating helical filament confined by a cylindrical tube, using a boundary-element method for Stokes flow that accounts for helical symmetry. We determine the effect of confinement on swimming speed…

Fluid Dynamics · Physics 2014-01-09 Bin Liu , Kenneth S. Breuer , Thomas R. Powers

Prior to pioneer surface adhesion, bacteria have to navigate in flows, often in confined environments. While much is known about their individual swimming dynamics, our understanding of their transport properties at the population level…

Biological Physics · Physics 2025-12-23 Lucie Klopffer , S. Becker , Laurence Mathieu , Nicolas Louvet

In bacterial chemotaxis, E. coli cells drift up chemical gradients by a series of runs and tumbles. Runs are periods of directed swimming, and tumbles are abrupt changes in swimming direction. Near the beginning of each run, the rotating…

Soft Condensed Matter · Physics 2009-11-07 Thomas R. Powers

The eukaryotic flagellum beats periodically, driven by the oscillatory dynamics of molecular motors, to propel cells and pump fluids. Small, but perceivable fluctuations in the beat of individual flagella have physiological implications for…

Cell Behavior · Quantitative Biology 2015-06-18 Rui Ma , Gary S. Klindt , Ingmar H. Riedel-Kruse , Frank Jülicher , Benjamin M. Friedrich

It is well known that flagellated bacteria swim in circles near surfaces. However, recent experiments have shown that a sulfide-oxidizing bacterium named Thiovulum majus can transition from swimming in circles to a surface bound state where…

Fluid Dynamics · Physics 2019-10-04 Debasish Das , Eric Lauga

Systems of self-propelled particles are known for their tendency to aggregate and to display swarm behavior. We investigate two model systems, self-propelled rods interacting via volume exclusion, and sinusoidally-beating flagella embedded…

Biological Physics · Physics 2010-09-28 Yingzi Yang , Vincent Marceau , Gerhard Gompper

Most motile bacteria swim in viscous fluids by rotating multiple helical flagellar filaments. These semi-rigid filaments repeatedly join ('bundle') and separate ('unbundle'), resulting in a two-gait random walk-like motion of the cell. In…

Fluid Dynamics · Physics 2020-11-18 Alexander Chamolly , Eric Lauga

Chiral particles are experimentally investigated while settling inwater with various turbulence intensity levels. The locations and orientations of the particles are tracked over time, allowing the close investigation of the particles'…

Fluid Dynamics · Physics 2026-01-06 Mees M. Flapper , John E. Sader , Detlef Lohse , Sander G. Huisman

Micro-organisms usually can swim in their liquid environment by flagellar or ciliary beating. In this numerical work, we analyze the influence of flagellar beating on the orbits of a swimming cell in a shear flow. We also calculate the…

Soft Condensed Matter · Physics 2017-11-21 Levan Jibuti , Walter Zimmermann , Salima Rafaï , Philippe Peyla

We experimentally study the emergence of collective bacterial swimming, a phenomenon often referred to as bacterial turbulence. A phase diagram of the flow of 3D E. coli suspensions spanned by bacterial concentration, the swimming speed of…

Soft Condensed Matter · Physics 2021-03-09 Yi Peng , Zhengyang Liu , Xiang Cheng

Trajectories and conformations of uni- and multiflagellar bacteria are studied with a coarse-grained model of a cell comprised of elastic flagella connected to a cell body. The elasticities of both the hook protein (connecting cell body and…

Biological Physics · Physics 2018-11-07 Frank T. M. Nguyen , Michael D. Graham

We derive from first principles a three-dimensional theory of self-propelled particle swarming in a viscous fluid environment. Our model predicts emergent collective behavior that depends critically on fluid opacity, mechanism of…

Soft Condensed Matter · Physics 2026-05-12 Yao-Li Chuang , M. R. D'Orsogna , T. Chou

We analyse the motion of a flagellated bacterium in a two-fluid medium using slender body theory. The two-fluid model is useful for describing a body moving through a complex fluid with a microstructure whose length scale is comparable to…

Fluid Dynamics · Physics 2024-12-11 Sabarish V. Narayanan , Donald L. Koch , Sarah Hormozi

We have measured the spatial distribution of motile Escherichia coli inside spherical water droplets emulsified in oil. At low cell concentrations, the cell density peaks at the water-oil interface; at increasing concentration, the bulk of…

To rotate continuously without jamming, the flagellar filaments of bacteria need to be locked in phase. While several models have been proposed for eukaryotic flagella, the synchronization of bacterial flagella is less well understood.…

Soft Condensed Matter · Physics 2022-05-27 Maria Tătulea-Codrean , Eric Lauga

Microscale fluid flows generated by ensembles of beating eukaryotic flagella are crucial to fundamental processes such as development, motility and sensing. Despite significant experimental and theoretical progress, the underlying physical…

Soft Condensed Matter · Physics 2014-03-11 Douglas R. Brumley , Kirsty Y. Wan , Marco Polin , Raymond E. Goldstein

The course of a peritrichous bacterium such as E. coli crucially depends on the level of synchronization and self-organization of several rotating flagella. However, the rotation of each flagellum generates counter body movements which in…

Biological Physics · Physics 2015-11-11 Tapan Chandra Adhyapak , Holger Stark