Abstract
Dense suspensions of swimming bacteria are known to exhibit collective behaviour arising from the interplay of steric and hydrodynamic interactions. Unconfined suspensions exhibit transient, recurring vortices and jets, whereas those confined in circular domains may exhibit order in the form of a spiral vortex. Here we show that confinement into a long and narrow macroscopic ‘racetrack’ geometry stabilises bacterial motion to form a steady unidirectional circulation. This motion is reproduced in simulations of discrete swimmers that reveal the crucial role that bacteria-driven fluid flows play in the dynamics. In particular, cells close to the channel wall produce strong flows which advect cells in the bulk against their swimming direction. We examine in detail the transition from a disordered state to persistent directed motion as a function of the channel width, and show that the width at the crossover point is comparable to the typical correlation length of swirls seen in the unbounded system. Our results shed light on the mechanisms driving the collective behaviour of bacteria and other active matter systems, and stress the importance of the ubiquitous boundaries found in natural habitats.
Highlights
Spreading and survival of populations of bacteria often depend on their ability to behave collectively: cells aggregate into swarms to seek and migrate towards nutrient-rich regions [1, 2], organise into biofilms resistant to antibiotics [3, 4], respond to starvation by building fruiting bodies [5, 6] or opt for cannibalism [7]
Confinement stabilises a bacterial stream We inject a dense suspension of swimming B. subtilis into 20 mm high racetracks
We have shown that confining a dense bacterial suspension into a thin periodic racetrack leads to the spontaneous formation of a stable circulation along it
Summary
Spreading and survival of populations of bacteria often depend on their ability to behave collectively: cells aggregate into swarms to seek and migrate towards nutrient-rich regions [1, 2], organise into biofilms resistant to antibiotics [3, 4], respond to starvation by building fruiting bodies [5, 6] or opt for cannibalism [7]. In such organisations, the surrounding environment often plays a major role, through its chemical composition [2, 3] or geometrical constraints [4, 8]. Experimental realisations of confined active matter remain relatively rare [14,15,16, 27,28,29,30]
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