TRANSPORT-PROPERTIES OF LIQUID-PHASE IN CAPILLARY-LIKE MEDIA AND ITS APPLICATION TO SINTERING OF METALLIC AND CERAMIC POWDERS

Intergranular mass transport in materials plays an important role in s uccessful bonding of particles, and controls the material's properties . This results from the processing conditions including the intergranu lar mass transport and interfacial reactions. The model of liquid mass transport of metals, molten salts, silicates, and molecular liquids, in capillary-like media is discussed. The model concentrates on the ro le of surface tension-to-viscosity ratio, gamma/eta, and volume diffus ion on the liquid flow in fine pores with diameters comparable to the liquid phase above its critical thickness. We have found the following relation between two parameters: D-cap = (y/eta)L alpha, where alpha and L are a specific permeability and the mean diffusive jump length o f atoms/ions/molecules, respectively. The specific permeability is rel ated to the hydraulic permeability, taken from Darcy's law, and depend s on capillary radius and liquid/solid contact angle. It is demonstrat ed that the specific permeability depends on the interfacial reactions and heterogeneity of the system. The mass transport in liquid layers seems to be initiated by atoms with low interatomic distances (low ato mic radii) in liquid metals or by the high non-bridging oxygen content in aluminosilicate melts.