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A combined rheometry and imaging study of viscosity reduction in bacterial suspensions.

Vincent A MartinezEric ClementJochen ArltCarine DouarcheAngela DawsonJana Schwarz-LinekAdama K CreppyViktor ŠkultétyAlexander N MorozovHarold AuradouWilson C K Poon
Published in: Proceedings of the National Academy of Sciences of the United States of America (2020)
Suspending self-propelled "pushers" in a liquid lowers its viscosity. We study how this phenomenon depends on system size in bacterial suspensions using bulk rheometry and particle-tracking rheoimaging. Above the critical bacterial volume fraction needed to decrease the viscosity to zero, [Formula: see text], large-scale collective motion emerges in the quiescent state, and the flow becomes nonlinear. We confirm a theoretical prediction that such instability should be suppressed by confinement. Our results also show that a recent application of active liquid-crystal theory to such systems is untenable.
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