Heterogeneous bacterial swarms with mixed lengths

Shlomit Peled; Shawn David Ryan; Sebastian Heidenreich; Markus Bär; Gil Ariel; Avraham Be'Er

doi:10.1103/PhysRevE.103.032413

Heterogeneous bacterial swarms with mixed lengths

Shlomit Peled
, Shawn David Ryan
, Sebastian Heidenreich
, Markus Bär
, Gil Ariel
, Avraham Be'Er

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

26 Scopus citations

Abstract

Heterogeneous systems of active matter exhibit a range of complex emergent dynamical patterns. In particular, it is difficult to predict the properties of the mixed system based on its constituents. These considerations are particularly significant for understanding realistic bacterial swarms, which typically develop heterogeneities even when grown from a single cell. Here, mixed swarms of cells with different aspect ratios are studied both experimentally and in simulations. In contrast with previous theory, there is no macroscopic phase segregation. However, locally, long cells act as nucleation cites, around which aggregates of short, rapidly moving cells can form, resulting in enhanced swarming speeds. On the other hand, high fractions of long cells form a bottleneck for efficient swarming. Our results suggest a physical advantage for the spontaneous heterogeneity of bacterial swarm populations.

Original language	English
Article number	032413
Journal	Physical Review E
Volume	103
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevE.103.032413
State	Published - Mar 1 2021

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10.1103/PhysRevE.103.032413

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abstract = "Heterogeneous systems of active matter exhibit a range of complex emergent dynamical patterns. In particular, it is difficult to predict the properties of the mixed system based on its constituents. These considerations are particularly significant for understanding realistic bacterial swarms, which typically develop heterogeneities even when grown from a single cell. Here, mixed swarms of cells with different aspect ratios are studied both experimentally and in simulations. In contrast with previous theory, there is no macroscopic phase segregation. However, locally, long cells act as nucleation cites, around which aggregates of short, rapidly moving cells can form, resulting in enhanced swarming speeds. On the other hand, high fractions of long cells form a bottleneck for efficient swarming. Our results suggest a physical advantage for the spontaneous heterogeneity of bacterial swarm populations.",

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AU - Peled, Shlomit

AU - Ryan, Shawn David

AU - Heidenreich, Sebastian

AU - Bär, Markus

AU - Ariel, Gil

AU - Be'Er, Avraham

PY - 2021/3/1

Y1 - 2021/3/1

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AB - Heterogeneous systems of active matter exhibit a range of complex emergent dynamical patterns. In particular, it is difficult to predict the properties of the mixed system based on its constituents. These considerations are particularly significant for understanding realistic bacterial swarms, which typically develop heterogeneities even when grown from a single cell. Here, mixed swarms of cells with different aspect ratios are studied both experimentally and in simulations. In contrast with previous theory, there is no macroscopic phase segregation. However, locally, long cells act as nucleation cites, around which aggregates of short, rapidly moving cells can form, resulting in enhanced swarming speeds. On the other hand, high fractions of long cells form a bottleneck for efficient swarming. Our results suggest a physical advantage for the spontaneous heterogeneity of bacterial swarm populations.

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Heterogeneous bacterial swarms with mixed lengths

Abstract

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