A model was developed in order to explore important issues, such as the effect of the rate of shear upon the mixing of liquid charges, the actual solute distribution at the start of diffusion annealing and the effect of a local reduction in liquid charge diameter upon the measurement of a liquid diffusion coefficient. A numerical simulation, using a grid sliding technique, was used to simulate the movable computational domain. The computed results showed that the shearing rate had only a small effect upon the initial distribution of the solute at the moment when the 2 liquid columns became aligned, and that the region over which the solute concentration changed, from that of the solvent charge to that of the solute-rich charge of the diffusion couple, would be very narrow. However, the simulated results revealed that strong convection was produced due to shearing, and that the disturbed region was much bigger than the zone over which the solute distribution was disrupted. The convection which was induced by shearing dissipated within 8s after the termination of the shearing action for a shear cell with a liquid column of 1.5mm diameter and shear at rates of 4 to 40mm/s. The simulated results also indicated that a small void (approximately one-sixth of the diameter cross-section) in the liquid solvent near to the sheared interface did not affect the development of the initial solute concentration profile and its subsequent change with diffusion through the interface.

Numerical Modeling of Transport in a Liquid Diffusion Couple Shear Cell. B.J.Yang, R.W.Smith: Journal of Physics - Condensed Matter, 2003, 15[23], 3855-65