The kinetics and mechanism of interfacial reaction in sigma fibre-reinforced Ti MMCs

Abstract

Interfacial reaction between titanium matrix and reinforcement plays a crucial role in determining the mechanical properties of titanium metal matrix composite materials. In order to improve the mechanical properties of composite materials, it is essential to understand the thermodynamics and kinetics of such interfacial reactions. Ti-6Al-4V foils and C/TiBx-coated SiC fibres were used to fabricate composite materials by diffusion bonding. The interface formed after annealing at different temperatures has been characterized mainly by scanning and transmission electron microscopies to establish the reaction kinetics between the TiBxcoating and Ti matrix. It is found that the major reaction product is TiB needles, although a TiB2layer is also present as a transition phase during the initial stage of the reaction. Experimental results indicate that, at a temperature between 870 and 970 °C, the growth rate of TiB needles along the needle direction is more than six times of that of the TiB2layer. After a detailed analysis of the crystal structures and the growth morphologies of both TiB and TiB2, the diffusion mechanisms for B atoms in TiB and TiB2have been identified as vacancy diffusion. However, the low activation energy path for B diffusion in TiB is in the [010]TiBdirection, effectively one-dimensional, while that in TiB2is along 〈11̄00〉TiB2directions, which form a two-dimensional network. In addition, it is found that the estimated diffusion coefficient for B in TiB along the needle direction is about 45 times larger than that in TiB2, although the activation energies for B diffusion in both TiB and TiB2are effectively the same, being 187-190 kJ mol-1. Copyright © 1996 Elsevier Science Limited.