Stability of arrays of bottom-heavy spherical squirmers (1901.08226v1)

Abstract: The incessant swimming motion of microbes in dense suspensions can give rise to striking collective motions and coherent structures. However, theoretical investigations of these structures typically utilize either computationally demanding numerical simulations, or simplified continuum models. Here we analytically investigate the collective dynamics of a dense array of steady, spherical squirmers. We first calculate the forces and torques acting on two closely-separated squirmers, through solving the Stokes equations to second-order in the ratio of mean spacing to squirmer radius. This lubrication analysis is then used to assess the stability of a dense, vertical, planar array of identical three-dimensional squirmers. The system of uniformly-spaced, vertically-oriented squirmers is stable if the gravitational torque experienced due to bottom-heaviness is sufficiently strong, and an intercellular repulsive force is included. The predictions of instability and possible long time behavior is qualitatively similar for monolayers confined between two parallel rigid planes as for unconfined monolayers. The predictions compare favorably with published numerical simulations, and reveal the existence of additional dynamic structures not previously observed; puller-type squirmers show a greater range of structures than pushers. The use of pairwise lubrication interactions provides an efficient means of assessing stability of dense suspensions usually tackled using full numerical simulations.