Shear-Induced Wobbling and Motility Suppression in Swimming Bacteria

TL;DR

This study investigates how steady shear flow affects the wobbling motion of swimming extit{E. coli} bacteria near surfaces, revealing flow-dependent changes in wobbling amplitude and frequency that suppress bacterial motility.

Contribution

It uncovers the mechanical coupling between shear flow and bacterial wobbling, linking flow-induced torques to motility suppression near surfaces, which was previously unexplored.

Findings

Wobbling amplitude increases with flow strength then plateaus.

Wobbling frequency monotonically increases with flow.

Shorter bacteria show more pronounced wobbling variations.

Abstract

The intricate wobbling motion of flagellated bacteria, characterized by the periodic precession of the cell body, is a determinant factor in their motility and navigation within complex fluid environments. While well-studied in quiescent fluids, bacterial wobbling under ubiquitous flow conditions remains unexplored. In this work, we investigate the wobbling dynamics of \textit{Escherichia coli} swimming near surfaces under steady shear flow. Our experiments reveal that the wobbling amplitude intensifies with flow strength before reaching a plateau, with this amplification exhibiting a strong dependence on the swimming orientation relative to the flow direction. It turns out that the enhanced wobbling remains governed by the misalignment between the cell body and the flagellar bundle. Furthermore, we observe that the wobbling frequency increases monotonically with flow strength, and that shorter bacteria exhibit more pronounced variations in both amplitude and frequency. By linking the wobbling motion to the intrinsic body-flagella misalignment, we attribute the flow-enhanced precession to a combination of shear- and chirality-induced torques acting on the flexible flagellar hook. This mechanical coupling ultimately suppresses the net migration velocity as the flow rate increases. These findings elucidate the elastohydrodynamic mechanisms by which shear flow modifies bacterial locomotion near surfaces, with implications for microbial transport in physiological and ecological environments.