Enhanced strength and thermal oxidation resistance of shaddock peel-polycarbosilane-derived C-SiC-SiO2 composites

Biomorphic ceramic materials have potential high-temperature applications, owing to their low density, good corrosion resistance and excellent shape capability, but achieving both high specific strength and excellent thermal oxidation resistance is challenging. In this report, shaddock peel-derived C-SiC-SiO2 composites were successfully prepared by the polymer precursor infiltration (PPI) technique with an optimized heating program. The composites prepared at 1600 degrees C exhibit the highest compressive strength (-14.0 MPa) and specific strength (-1.5 x 107 N m/kg), while those sintered at 1200 degrees C exhibit the highest bending strength (-27.4 MPa). The composites exhibit good thermal oxidation resistance (up to 1400 degrees C) with a low weight loss ratio (<0.11 g/cm3), moreover, the compressive strength of the composites sintered at 1200 degrees C after thermal oxidation at 1400 degrees C surprisingly increased from 11.6 +/- 2.7 MPa to 21.5 +/- 3.5 MPa. The PPI technique provides a viable route to introduce Si source into natural materials and the shaddock peel-derived C-SiC-SiO2 composites are light ma-terials with high strength and excellent high-temperature thermal oxidation resistance.

Automated summary

Biomorphic ceramic materials show potential for high-temperature applications. The shaddock peel-derived C-SiC-SiO2 composites exhibit excellent physical and chemical properties.