Effects of stress-driven melt segregation on the viscosity of rocks

We present rheological data on samples of partially molten mantle rocks deformed in torsion at 1200 °C and 300 MPa in a gas-medium deformation apparatus. Samples in which stress-driven melt segregation occurs are significantly weaker than those with a homogeneous melt distribution, with strain rate increased by up to a factor of 6. The degree of melt segregation, which is influenced by the permeability of the sample material (and hence the compaction length), is controlled by changing chromite fraction as a minor solid second phase. In general, a higher degree of melt segregation causes a greater strain rate enhancement. Although we focus here on the steady-state rheological properties, a simple model of the evolution of melt segregation and rheological properties is presented. This model fits well the latter part of the stress–strain evolution but fails to fit the early, transient stages of deformation. One implication is that weakening occurs very quickly due to the emergence of smaller-scale melt bands. The model (constitutive and evolution equations) is designed to be incorporated into geodynamic-scale continuum models to explore the effects of segregation without resolving the length scales of the process directly.