Rheology of suspensions of viscoelastic spheres: deformability as an effective volume fraction

Abstract

We study suspensions of deformable (viscoelastic) spheres in a Newtonian solvent in plane Couette geometry, by means of direct numerical simulations. We find that in the limit of vanishing inertia the effective viscosity μ of the suspension increases as the volume-fraction occupied by the spheres increases and decreases as the elastic modulus of the spheres G decreases; the function μ(,G) collapses to an universal function, μ(e), with a reduced effective volume fraction e(,G). Remarkably, the function μ(e) is the well-known Eilers fit that describes the rheology of suspension of rigid spheres at all . Our results suggest new ways to interpret macro-rheology of blood.