Microstructure, thermophysical properties and oxidation resistance of SiCf/SiC–YSi2–Si composite fabricated through reactive melt infiltration

As an ideal component material for advanced aeroengines, SiC composite faces severe challenges of high temperatures and oxidation. Here, a high-densification SiCf/SiC–YSi2–Si composite was prepared through combining PIP with RMI of Si–13 at% Y alloy to achieve enhanced performance at high temperatures. Based on the analysis of the microstructure and thermophysical properties, it found that the introduction of the highly crystalline Si–Y alloy can improve the high-temperature thermal conductivity of the composite through phonon and electron conduction. In addition, Y migrates to the surface and forms yttrium silicate with increasing oxidation temperature, which facilitates the excellent long-term oxidation resistance of the composite at 1200–1300 °C. Thus, the composite retained its high strength (89.15% and 86.84%) after oxidation at 1200 °C and 1300 °C for 100 h. The experimental results clearly demonstrate that the introduction of the Si–Y alloy is an effective way of preparing high-performance SiC composites.