Emergent asymmetry in confined bioconvection

TL;DR

This study investigates how confinement influences asymmetry in bioconvection patterns of swimming microorganisms, revealing that asymmetric solutions are often more stable and dominant, challenging symmetry assumptions in existing models.

Contribution

The paper demonstrates that confinement can induce and stabilize asymmetric bioconvection patterns, providing analytical and numerical evidence that asymmetry is plausible and often dominant in such systems.

Findings

Asymmetric solutions can be more stable than symmetric ones.

Confinement can drive asymmetry in bioconvection patterns.

Blip and varicose instabilities are present in accessible parameter ranges.

Abstract

Bioconvection is the prototypical active matter system for hydrodynamic instabilities and pattern formation in suspensions of biased swimming microorganisms, particularly at the dilute end of the concentration spectrum where cell-cell interactions typically are neglected. Confinement is an inherent characteristic of such systems, including those that are naturally-occurring or industrially-exploited, so it is important to understand the impact of boundaries on the hydrodynamic instabilities. Despite recent interest in this area we note that commonly-adopted symmetry assumptions in the literature, such as for a vertical channel or pipe, are uncorroborated and potentially unjustified. Therefore, by employing a combination of analytical and numerical techniques, we investigate whether confinement itself can drive asymmetric plume formation in a suspension of bottom-heavy swimming microorganisms (gyrotactic cells). For a class of solutions in a vertical channel we establish the existence of a first integral of motion, and reveal that asymptotic asymmetry is plausible. Furthermore, numerical simulations from both Lagrangian and Eulerian perspectives demonstrate with remarkable agreement that asymmetric solutions can indeed be more stable than symmetric; asymmetric solutions are in fact dominant for a large, practically-important region of parameter space. In addition, we verify the presence of blip and varicose instabilities for an experimentally accessible parameter range. Finally, we extend our study to a vertical Hele-Shaw geometry to explore whether a simple linear drag approximation can be justified. We find that although two-dimensional bioconvective structures and associated bulk properties have some similarities with experimental observations, approximating near wall physics in even the simplest confined systems remains challenging.