English

Pattern Formation in Chemically Interacting Active Rotors with Self-Propulsion

Soft Condensed Matter 2016-08-19 v1 Statistical Mechanics Pattern Formation and Solitons

Abstract

We demonstrate that active rotations in chemically signalling particles, such as autochemotactic {\it E. coli} close to walls, create a route for pattern formation based on a nonlinear yet deterministic instability mechanism. For slow rotations, we find a transient persistence of the uniform state, followed by a sudden formation of clusters contingent on locking of the average propulsion direction by chemotaxis. These clusters coarsen, which results in phase separation into a dense and a dilute region. Faster rotations arrest phase separation leading to a global travelling wave of rotors with synchronized roto-translational motion. Our results elucidate the physics resulting from the competition of two generic paradigms in active matter, chemotaxis and active rotations, and show that the latter provides a tool to design programmable self-assembly of active matter, for example to control coarsening.

Keywords

Cite

@article{arxiv.1605.05982,
  title  = {Pattern Formation in Chemically Interacting Active Rotors with Self-Propulsion},
  author = {Benno Liebchen and Michael E. Cates and Davide Marenduzzo},
  journal= {arXiv preprint arXiv:1605.05982},
  year   = {2016}
}
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