@article{LUN2021, author = {Huilin LUN and Yi ZENG and Xiang XIONG and Ziming YE and Zhongwei ZHANG and Xingchao LI and Haikun CHEN and Yufeng LIU}, title = {Oxidation behavior of non-stoichiometric (Zr,Hf,Ti)Cx carbide solid solution powders in air}, year = {2021}, journal = {Journal of Advanced Ceramics}, volume = {10}, number = {4}, pages = {741-757}, keywords = {oxidation behavior, oxidation resistance, ultra-high temperature ceramics (UHTCs), (Zr,Hf,Ti)Cx carbides, free-pressureless spark plasma sintering}, url = {https://www.sciopen.com/article/10.1007/s40145-021-0469-y}, doi = {10.1007/s40145-021-0469-y}, abstract = {Multi-component solid solutions with non-stoichiometric compositions are characteristics of ultra-high temperature carbides as promising materials for hypersonic vehicles. However, for group IV transition-metal carbides, the oxidation behavior of multi-component non-stoichiometric (Zr,Hf,Ti)Cx carbide solid solution has not been clarified yet. The present work fabricated four kinds of (Zr,Hf,Ti)Cx carbide solid solution powders by free-pressureless spark plasma sintering to investigate the oxidation behavior of (Zr,Hf,Ti)Cx in air. The effects of metallic atom composition on oxidation resistance were examined. The results indicate that the oxidation kinetics of (Zr,Hf,Ti)Cx are composition dependent. A high Hf content in (Zr,Hf,Ti)Cx was beneficial to form an amorphous Zr-Hf-Ti-C-O oxycarbide layer as an oxygen barrier to enhance the initial oxidation resistance. Meanwhile, an equiatomic ratio of metallic atoms reduced the growth rate of (Zr,Hf,Ti)O2 oxide, increasing its phase stability at high temperatures, which improved the oxidation activation energy of (Zr,Hf,Ti)Cx.} }