A note on Stokes' problem in dense granular media using the μ(I)--rheology

Abstract

The classical Stokes' problem describing the fluid motion due to a steadily moving infinite wall is revisited in the context of dense granular flows of mono-dispersed beads using the recently proposed μ(I)--rheology. In Newtonian fluids, molecular diffusion brings about a self-similar velocity profile and the boundary layer in which the fluid motion takes place increases indefinitely with time t as t, where is the kinematic viscosity. For a dense granular visco-plastic liquid, it is shown that the local shear stress, when properly rescaled, exhibits self-similar behaviour at short-time scales and it then rapidly evolves towards a steady-state solution. The resulting shear layer increases in thickness as g t analogous to a Newtonian fluid where g is an equivalent granular kinematic viscosity depending not only on the intrinsic properties of the granular media such as grain diameter d, density and friction coefficients but also on the applied pressure pw at the moving wall and the solid fraction φ (constant). In addition, the μ(I)--rheology indicates that this growth continues until reaching the steady-state boundary layer thickness δs = βw (pw/φ g ), independent of the grain size, at about a finite time proportional to βw2 (pw/ g d)3/2 d/g, where g is the acceleration due to gravity and βw = (τw - τs)/τs is the relative surplus of the steady-state wall shear-stress τw over the critical wall shear stress τs (yield stress) that is needed to bring the granular media into motion... (see article for a complete abstract).