The rotation of a sedimenting anisotropic particle in a linearly stratified ambient

Abstract

We derive the torque on a spheroid of an arbitrary aspect ratio sedimenting in a linearly stratified ambient. The analysis demarcates regions in parameter space corresponding to broadside-on and edgewise (longside-on) settling in the limit Re, Riv 1, where Re = 0UL/μ and Riv =γ L3g/μ U, the Reynolds and viscous Richardson numbers, respectively, are dimensionless measures of the importance of inertial and buoyancy forces relative to viscous ones. Here, L is the spheroid semi-major axis, U an appropriate settling velocity scale, μ the fluid viscosity, and γ\,(>0) the (constant)\,density gradient characterizing the stably stratified ambient, with 0 being the fluid density taken to be a constant within the Boussinesq framework. A reciprocal theorem formulation identifies three contributions to the torque: (1) an O(Re) inertial contribution that already exists in a homogeneous ambient, and orients the spheroid broadside-on; (2) an O(Riv) hydrostatic contribution due to the ambient linear stratification that also orients the spheroid broadside-on; and (3) a hydrodynamic contribution arising from the perturbation of the ambient stratification by the spheroid whose nature depends on Pe; Pe = UL/D being the Peclet number with D the diffusivity of the stratifying agent. For Pe 1, the hydrodynamic contribution is O(Riv23) in the Stokes stratification regime characterized by Re Riv13, and orients the spheroid edgewise regardless of . The differing orientation dependencies of the inertial and large-Pe hydrodynamic stratification torques imply that the broadside-on and edgewise settling regimes are separated by two distinct -dependent critical curves in the Riv/Re32- plane. The predictions are consistent with recent experimental observations.