Sedimentation of spheroidal bodies near walls in viscous fluids: glancing, reversing, tumbling, and sliding

TL;DR

This paper develops analytical and numerical methods to study the complex sedimentation behaviors of spheroidal particles near walls in viscous fluids, including glancing, reversing, tumbling, and sliding trajectories.

Contribution

It introduces a novel boundary integral formulation and analytical ODE models for spheroids near walls, extending understanding beyond spherical cases.

Findings

Analytical solutions match numerical simulations well.

Conditions for glancing and reversing trajectories are identified.

New trajectories like tumbling and sliding are characterized.

Abstract

The sedimentation of a rigid particle near a wall in a viscous fluid has been studied numerically by many authors, but analytical solutions have been derived only for special cases such as the motion of spherical particles. In this paper the method of images is used to derive simple ordinary differential equations describing the sedimentation of arbitrarily oriented prolate and oblate spheroids at zero Reynolds number near a vertical or inclined plane wall. The differential equations may be solved analytically in many situations, and full trajectories are predicted which compare favorably with complete numerical simulations. The simulations are performed using a novel double layer boundary integral formulation, a method of stresslet images. The conditions under which the glancing and reversing trajectories, first observed by Russel et al. (1977), occur are studied for bodies of arbitrary aspect ratio. Several additional trajectories are also described: a periodic tumbling trajectory for nearly spherical bodies, a linearly stable sliding trajectory which appears when the wall is slightly inclined, and three-dimensional glancing, reversing, and wobbling.