Compressibility regularizes the "μ(I)" rheology for granular flows

Abstract

The μ(I)-rheology has been recently proposed as a potential candidate to model the flow of frictional grains in a dense inertial regime. However, this rheology was shown to be ill-posed in the mathematical sense for a large range of parameters, notably in the slow and fast flow limits Barker2015. In this rapid communication, we extend the stability analysis to compressible flows. We show that compressibility regularizes mostly the equations, making them well-posed for all parameters, at the condition that sufficient dissipation is associated with volume changes. In addition to the usual Coulomb shear friction coefficient μ, we introduce a bulk friction coefficient μb, associated to volume changes and show that the equations are well-posed in two dimensions if μb>2-2μ (μb>3-7μ/2 in three dimensions). Moreover, we show that the ill-posed domain defined in Barker2015 transforms into a domain where the equations are unstable but stay well-posed when compressibility is taken into account. These results suggest thus the importance of compressibility in dense granular flows.