Stress relaxation in a dilute bacterial suspension: The active-passive transition

Abstract

We analyse the time dependent non-linear rheology of a dilute bacterial suspension (e.g. E. coli) for a pair of impulsively started linear flows - simple shear and uniaxial extension. The rheology is governed by the bacterium orientation distribution which satisfies a kinetic equation that includes rotation by the imposed flow, and relaxation to isotropy via rotary diffusion and tumbling. The relevant dimensionless parameters are the Peclet number Pe γτ, which dictates the importance of flow-induced orientation anisotropy, and τ Dr, which quantifies the relative importance of the two intrinsic orientation decorrelation mechanisms (tumbling and rotary diffusion). Here, τ is the mean run duration of a bacterium that exhibits a run-and-tumble dynamics, Dr is the intrinsic rotary diffusivity of the bacterium and γ is the characteristic magnitude of the imposed velocity gradient. The solution of the kinetic equation is obtained numerically using a spectral Galerkin method, and yields the relevant rheological properties over the entire range of Pe. For simple shear, the stress relaxation predicted by our analysis at small Pe is in good agreement with the experimental observations of Lopez et al. (2015). However, the analysis at large Pe yields relaxations that are qualitatively different. The rheological response in the experiments corresponds to a transition from a nearly isotropic suspension of active swimmers at small Pe, to an apparently (nearly) isotropic suspension of passive rods at large Pe. In contrast, the computations yield the expected transition to a nearly flow-aligned suspension of passive rigid rods at high Pe. We probe this active-passive transition systematically, complementing the numerical solution with analytical solutions obtained from perturbation expansions about appropriate base states.