Hydrodynamic length-scale selection in microswimmer suspensions

Author(s)

Heidenreich, Sebastian; Klapp, Sabine H. L.; Bär, Markus; Dunkel, Joern

Abstract

A universal characteristic of mesoscale turbulence in active suspensions is the emergence of a typical vortex length scale, distinctly different from the scale invariance of turbulent high-Reynolds number flows. Collective length-scale selection has been observed in bacterial fluids, endothelial tissue, and active colloids, yet the physical origins of this phenomenon remain elusive. Here, we systematically derive an effective fourth-order field theory from a generic microscopic model that allows us to predict the typical vortex size in microswimmer suspensions. Building on a self-consistent closure condition, the derivation shows that the vortex length scale is determined by the competition between local alignment forces, rotational diffusion, and intermediate-range hydrodynamic interactions. Vortex structures found in simulations of the theory agree with recent measurements in Bacillus subtilis suspensions. Moreover, our approach yields an effective viscosity enhancement (reduction), as reported experimentally for puller (pusher) microorganisms.

Date issued

2016-08

URI

http://hdl.handle.net/1721.1/110385

Department

Massachusetts Institute of Technology. Department of Mathematics

Journal

Physical Review E

Publisher

American Physical Society

Citation

Heidenreich, Sebastian; Dunkel, Jörn; Klapp, Sabine H. L. and Bär, Markus. "Hydrodynamic length-scale selection in microswimmer suspensions." Physical Review E 94, 020601(R): 1-6 © 2016 American Physical Society

Version: Final published version

ISSN

2470-0045

2470-0053