A constitutive model for simple shear of dense frictional suspensions

Abstract

Discrete particle simulations are used to study the shear rheology of dense, stabilized, frictional particulate suspensions in a viscous liquid, toward development of a constitutive model for steady shear flows at arbitrary stress. These suspensions undergo increasingly strong continuous shear thickening (CST) as solid volume fraction φ increases above a critical volume fraction, and discontinuous shear thickening (DST) is observed for a range of φ. When studied at controlled stress, the DST behavior is associated with non-monotonic flow curves of the steady-state stress as a function of shear rate. Recent studies have related shear thickening to a transition between mostly lubricated to predominantly frictional contacts with the increase in stress. In this study, the behavior is simulated over a wide range of the dimensionless parameters (φ,σ, and μ), with σ = σ/σ0 the dimensionless shear stress and μ the coefficient of interparticle friction: the dimensional stress is σ, and σ0 F0/ a2, where F0 is the magnitude of repulsive force at contact and a is the particle radius. The data have been used to populate the model of the lubricated-to-frictional rheology of Wyart and Cates [Phys. Rev. Lett. 112, 098302 (2014)], which is based on the concept of two viscosity divergences or jamming\ points at volume fraction φ J0 = φ rcp (random close packing) for the low-stress lubricated state, and at φ J (μ) < φ J0 for any nonzero μ in the frictional state; a generalization provides the normal stress response as well as the shear stress. A flow state map of this material is developed based on the simulation results.