The antioxidative protection mechanism of the ultra-high temperature radome composite material BNf/SiBN

Abstract

In the study, a BNf/SiBN composite was fabricated through precursor infiltration and pyrolysis (PIP) method. The oxidation resistance of the composite was investigated at different oxidation temperatures, focusing on the micro-structure evolution, the phase composition and oxidation kinetics of bare fibers versus fibers protected by the matrix under various oxidation states. The result indicates that the BNf/SiBN composite remains stable at 1100°C in air atmosphere, while the fibers protected by matrix maintain their complete structure even at 1500°C. Furthermore, we elucidated the oxidation mechanism of SiBN matrix: SiBN matrix undergoes a prior oxidation stage and transforms into amorphous SiO2 and B2O3 at high temperatures to impede the oxygen attachment to fibers while preserving the integrity of internal structure. The emergence of ultra-high temperature resistant BNf/SiBN composite and along with the exploration of oxidation behavior has opened up new approach for advancing radome material development.