期刊
CERAMICS INTERNATIONAL
卷 48, 期 9, 页码 12608-12624出版社
ELSEVIER SCI LTD
DOI: 10.1016/j.ceramint.2022.01.129
关键词
High-entropy ceramic; Composite coating; Slurry painting; Gaseous reactive infiltration; Oxidation; Carbon/carbon composite
资金
- Innovation Talent Promotion Plan of Shaanxi Province for Science and Technology Innovation Team [2020TD-003]
- National Key R&D Program of China [2021YFA0715800]
- Science Center for Gas Turbine Project [P2021-A-IV-003-001]
- National Natural Science Foundation of China [52061135102, 91860203, 52130205, 52125203]
In this study, a novel high-entropy ceramic modified coating was deposited on C/C composites to enhance their oxidation resistance. The coating showed good adhesion to the substrate and significantly prolonged the oxidation protection time of C/C materials. Therefore, this coating has potential applications in improving the stability of C/C composites in high-temperature environments.
High-entropy ceramics, a novel type of multicomponent materials with broad application prospects, have stirred up world-wide interests for over a decade. In the current work, in-situ high-entropy (Hf0.25Zr0.25Ti0.25Cr0.25)B-2 ceramic modified SiC-Si (HETMB2-SiC-Si) coating was deposited on carbon/carbon (C/C) composites via gaseous reactive infiltration of Si assisted slurry painting (GRSI-SP) method, to improve the oxidation protective ability of C/C composites at 1973 K. The formation and oxidation mechanisms of the coating was explored by first-principles simulation, experiment and thermodynamic analyses. The coating prepared at 2373 K shows dense mosaic structure filled with HETMB2-rich Si-based multiphase. This coating adheres well with the C/C substrate, which is ascribed to the formed zigzagged SiC-Si transition layer. This coating protected C/Cs from oxidation for more than 205 h at 1973 K. The enhanced oxidation protective ability is mostly ascribed to the subsequently generated compact and stable Hf-Zr-Ti-Cr-Si-O composite oxidation scale. This research will start up novel research ares of developing high-entropy materials modified coatings with improved protective ability under extreme environments.
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