Microstructure and mechanical properties of MoSi2/TaSi2 two-phase alloys

Effects of pre-strain on the compressive mechanical behavior were investigated on the alloys with an aligned lamellar microstructure consisting Of C11(b) MoSi2 and C40 TaSi2 prepared through optical floating zone (OFZ) method and annealing in the two-phase MoSi2/TaSi2 region. Single crystals of C40 TaSi2 were successfully grown at solidification rate of 5 or 10 mm/h, and well-aligned lamellar microstructure can be achieved by selecting an MoSi2-17 mol% TaSi2 alloy. Firstly, compression tests were conducted to examine the effect of the angle phi between the aligned lamellae and the loading axis on strength and ductility. Results indicate that phi = 0, lamellae parallel to the axis, is a hard-orientation and phi = 54 and 40 (identically 45) are soft orientations. The alloy with phi = 0 shows higher strength but lower ductility than those with phi = 54 and 40 where ductility is evaluated in terms of brittle-to-ductile transition temperature (BDTT). Then effects of pre-straining at 1773 K on the mechanical behavior at 1573 K were investigated using soft-oriented lamellar alloys with 0 = 40 whose BDTT is determined at least lower than 1673 K. Pre-straining to a few to several percent at 1773 K improves ductility of the alloy at 1573 K and also raises 0.2% flow stress, compared with the absence of the pre-strain. We believe that dislocations can be generated and stored in the alloy at 1773 K, and these dislocations are mobile even at 1573 K, although the analyses of operative slip systems and characteristics of dislocations remain as future works. (C) 2006 Published by Elsevier Ltd.