Dynamics of a flexible helical filament rotating in a viscous fluid near a rigid boundary

Author(s)

Khalid Jawed, Mohammad; Reis, Pedro Miguel

Abstract

We study the effect of a no-slip rigid boundary on the dynamics of a flexible helical filament rotating in a viscous fluid, at low Reynolds number conditions (Stokes limit). This system is taken as a reduced model for the propulsion of uniflagellar bacteria, whose locomotion is known to be modified near solid boundaries. Specifically, we focus on how the propulsive force generated by the filament, as well as its buckling onset, are modified by the presence of a wall. We tackle this problem through numerical simulations that couple the elasticity of the filament, the hydrodynamic loading, and the wall effect. Each of these three ingredients is respectively modeled by the discrete elastic rods method (for a geometrically nonlinear description of the filament), Lighthill's slender body theory (for a nonlocal fluid force model), and the method of images (to emulate the boundary). The simulations are systematically validated by precision experiments on a rescaled macroscopic apparatus. We find that the propulsive force increases near the wall, while the critical rotation frequency for the onset of buckling usually decreases. A systematic parametric study is performed to quantify the dependence of the wall effects on the geometric parameters of the helical filament.

Date issued

2017-03

URI

http://hdl.handle.net/1721.1/115431

Department

Massachusetts Institute of Technology. Department of Civil and Environmental Engineering
Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Physical Review Fluids

Publisher

American Physical Society (APS)

Citation

Jawed, M. K. and P. M. Reis. “Dynamics of a Flexible Helical Filament Rotating in a Viscous Fluid Near a Rigid Boundary.” Physical Review Fluids 2, 3 (March 2017): 034101 © 2017 American Physical Society

Version: Final published version

ISSN

2469-990X

2469-9918