Geometry-driven collective ordering of bacterial vortices

Kazusa Beppu; Ziane Izri; Jun Gohya; Kanta Eto; Masatoshi Ichikawa; Yusuke T. Maeda

doi:10.1039/c7sm00999b

Geometry-driven collective ordering of bacterial vortices

Kazusa Beppu, Ziane Izri, Jun Gohya, Kanta Eto, Masatoshi Ichikawa, Yusuke T. Maeda

Condensed Matter Physics

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

46 Citations (Scopus)

Abstract

Controlling the phases of matter is a challenge that spans from condensed materials to biological systems. Here, by imposing a geometric boundary condition, we study the controlled collective motion of Escherichia coli bacteria. A circular microwell isolates a rectified vortex from disordered vortices masked in the bulk. For a doublet of microwells, two vortices emerge but their spinning directions show transition from parallel to anti-parallel. A Vicsek-like model for confined self-propelled particles gives the point where the two spinning patterns occur in equal probability and one geometric quantity governs the transition as seen in experiments. This mechanism shapes rich patterns including chiral configurations in a quadruplet of microwells, thus revealing a design principle of active vortices.

Original language	English
Pages (from-to)	5038-5043
Number of pages	6
Journal	Soft Matter
Volume	13
Issue number	29
DOIs	https://doi.org/10.1039/c7sm00999b
Publication status	Published - 2017

All Science Journal Classification (ASJC) codes

Chemistry(all)
Condensed Matter Physics

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10.1039/c7sm00999b

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title = "Geometry-driven collective ordering of bacterial vortices",

abstract = "Controlling the phases of matter is a challenge that spans from condensed materials to biological systems. Here, by imposing a geometric boundary condition, we study the controlled collective motion of Escherichia coli bacteria. A circular microwell isolates a rectified vortex from disordered vortices masked in the bulk. For a doublet of microwells, two vortices emerge but their spinning directions show transition from parallel to anti-parallel. A Vicsek-like model for confined self-propelled particles gives the point where the two spinning patterns occur in equal probability and one geometric quantity governs the transition as seen in experiments. This mechanism shapes rich patterns including chiral configurations in a quadruplet of microwells, thus revealing a design principle of active vortices.",

author = "Kazusa Beppu and Ziane Izri and Jun Gohya and Kanta Eto and Masatoshi Ichikawa and Maeda, {Yusuke T.}",

note = "Funding Information: This work was supported by PRESTO (no. 11103355, JPMJPR11A4) from JST, JSPS KAKENHI (no. JP16H00805, JP25103012: {"}Synergy of Fluctuation and Structure{"}, and no. JP26707020) from MEXT, and HFSP Research Grant (RGP0037/2015) Publisher Copyright: {\textcopyright} 2017 The Royal Society of Chemistry.",

year = "2017",

doi = "10.1039/c7sm00999b",

language = "English",

volume = "13",

pages = "5038--5043",

journal = "Soft Matter",

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publisher = "Royal Society of Chemistry",

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TY - JOUR

T1 - Geometry-driven collective ordering of bacterial vortices

AU - Beppu, Kazusa

AU - Izri, Ziane

AU - Gohya, Jun

AU - Eto, Kanta

AU - Ichikawa, Masatoshi

AU - Maeda, Yusuke T.

N1 - Funding Information: This work was supported by PRESTO (no. 11103355, JPMJPR11A4) from JST, JSPS KAKENHI (no. JP16H00805, JP25103012: "Synergy of Fluctuation and Structure", and no. JP26707020) from MEXT, and HFSP Research Grant (RGP0037/2015) Publisher Copyright: © 2017 The Royal Society of Chemistry.

PY - 2017

Y1 - 2017

N2 - Controlling the phases of matter is a challenge that spans from condensed materials to biological systems. Here, by imposing a geometric boundary condition, we study the controlled collective motion of Escherichia coli bacteria. A circular microwell isolates a rectified vortex from disordered vortices masked in the bulk. For a doublet of microwells, two vortices emerge but their spinning directions show transition from parallel to anti-parallel. A Vicsek-like model for confined self-propelled particles gives the point where the two spinning patterns occur in equal probability and one geometric quantity governs the transition as seen in experiments. This mechanism shapes rich patterns including chiral configurations in a quadruplet of microwells, thus revealing a design principle of active vortices.

AB - Controlling the phases of matter is a challenge that spans from condensed materials to biological systems. Here, by imposing a geometric boundary condition, we study the controlled collective motion of Escherichia coli bacteria. A circular microwell isolates a rectified vortex from disordered vortices masked in the bulk. For a doublet of microwells, two vortices emerge but their spinning directions show transition from parallel to anti-parallel. A Vicsek-like model for confined self-propelled particles gives the point where the two spinning patterns occur in equal probability and one geometric quantity governs the transition as seen in experiments. This mechanism shapes rich patterns including chiral configurations in a quadruplet of microwells, thus revealing a design principle of active vortices.

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JO - Soft Matter

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Geometry-driven collective ordering of bacterial vortices

Abstract

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