Scaling description of non-local rheology

The plastic flow of amorphous materials displays non-local effects, characterized by a cooperativity length scale xi. We argue that these effects enter in the more general description of surface phenomena near critical points. Using this approach, we obtain a scaling relation between exponents that describe the strain rate profiles in shear driven and pressure driven flow, which we confirm both in numerical models and experimental data. We find empirically that the cooperative length follows closely the characteristic length previously extracted in homogenous bulk flows. This analysis shows that the often used mean field exponents fail to capture quantitatively the non-local effects. Our analysis also explains the unusually large finite size effects previously observed in pressure driven flows.

Scaling description of non-local rheology

A cut-cell method for the numerical simulation of 3D multiphase flows with strong interfacial effects

Numerical simulation of immiscible incompressible viscous, viscoelastic and elastic multiphase flows

Scaling Description of Creep Flow in Amorphous Solids

Scaling Description of Creep Flow in Amorphous Solids

A cut-cell method for the numerical simulation of 3D multiphase flows with strong interfacial effects

Numerical simulation of immiscible incompressible viscous, viscoelastic and elastic multiphase flows