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Communications in Mathematical Sciences
Volume 14 (2016)
Number 8
An analytic approach for the evolution of the static/flowing interface in viscoplastic granular flows
Pages: 2101 – 2126
DOI: https://dx.doi.org/10.4310/CMS.2016.v14.n8.a2
Authors
Abstract
Observed avalanche flows of dense granular material have the ability to present two possible behaviours: static (solid) or flowing (fluid). In such situations, an important challenge is to describe mathematically the evolution of the physical interface between the two phases. In this work we derive analytically a set of equations that is able to manage the dynamics of such an interface, in the thin-layer regime where the flow is supposed to be thin compared to its downslope extension. It is obtained via an asymptotics starting from an incompressible viscoplastic model with Drucker–Prager yield stress, in which we have to make several assumptions. Additionally to the classical ones that are that the curvature of the topography, the width of the layer, and the viscosity are all small, we assume that the internal friction angle is close to the slope angle (meaning that the friction and gravity forces compensate at leading order), the velocity is small (which is possible because of the previous assumption), and the pressure is convex with respect to the normal variable. This last assumption is for the stability of the double layer static/flowing configuration. A new higher-order non-hydrostatic nonlinear coupling term in the pressure allows us to close the asymptotic system. The resulting model takes the form of a formally overdetermined initial-boundary problem in the variable normal to the topography, set in the flowing region only. The extra boundary condition gives the information on how to evolve the static/flowing interface, and comes out from the continuity of the velocity and shear stress across it. The model handles arbitrary velocity profiles and is therefore more general than depth-averaged models.
Keywords
granular flows, viscoplastic flows, Drucker–Prager yield stress, static/flowing transition, interface dynamics, non-hydrostatic pressure
2010 Mathematics Subject Classification
35Q70, 35Q86, 35R37, 76A05
Published 26 October 2016