Interface and contact line motion in a two phase fluid under shear flow

A coarse grained description of a two phase fluid is used to study the steady state configuration of the interface separating the coexisting phases, and the motion of the contact line at which the interface intersects a solid boundary. The fluid is set in motion by displacing two parallel, infinite solid boundaries along their own plane. Dissipative relaxation of the order parameter leads to interfacial slip at the contact line, even when no-slip boundary conditions for the fluid velocity are considered. This relaxation occurs within a characteristic length scale l that depends on the order parameter mobility, the equilibrium interfacial tension, the imposed wall velocity, the thermal correlation length, the equilibrium miscibility gap, and the mutual diffusion coefficient. Steady-state interface equations which describe the system on a length scale large compared to the correlation length are derived. Scaling forms which involve the ratio l/L, where L is the width of the fluid layer, and the capillary number follow from the interface equations. The scaling results are verified by direct numerical solution of the governing equations.