Enhancing the elevated temperature strength of titanium matrix composites through a novel ( plus ) TRIPLEX heat treatment

In this work, an (alpha + beta) TRIPLEX heat treatment process was designed, as well as its impact on the microstructures and high-temperature mechanical properties of 2.5 vol% (TiB + TiC)/Ti-6Al-4Sn-7Zr-1Nb-1Mo-1W-0.2Si (wt.%) was carefully investigated. The results show that the microstructures of heat-treated TMCs consist of the primary alpha phase (alpha(p)) and the transformed beta (beta(t)) with a large number of nano-scale secondary alpha phases (alpha(s)). The TRIPLEX heat treatment encourages the effect of structural heredity, causing the residual alpha(p) lamellae to develop adequately and even mature into lamellae clusters with the same orientation, which induces a visible strengthening of the variant selection for the alpha phase. After the TRIPLEX heat treatment, the increase in content and size of silicides is mainly due to the process providing favorable sites and sufficient time for nucleation and growth. The longitudinal axes of some silicides exhibit an approximate 40 degrees angle or parallel arrangement with the beta/alpha(p) interfaces, which means that the silicides will grow preferentially along a specific orientation to minimize the strain energy. The (alpha + beta) TRIPLEX heat treatment significantly increases the high-temperature strength of the TMCs with no appreciable elongation loss (as-cast TMCs: UTS = 487.6 MPa, EL = 17.4%; HT-4#: UTS = 558.1 MPa, EL = 11.5%). The strength improvement of HT-4 # is mainly related to the combined effects of alpha(p) content reduction, alpha(s) precipitation, obstruction of dislocations by the beta(t)/alpha(p) interface, hetero-deformation strengthening, silicides precipitation strengthening, and alpha(2) dispersion strengthening.