@article{Chen2026, 
author = {Yuexing Chen and Dalin Shi and Xiang Ji and Peipei Wang and Zhichao Shang and Chengshan Ji and Xueqin Kang and Baojing Zhang and Yi Sun and Xuanru Ren and Peizhong Feng},
title = {Oxidation-driven glass evolution enabling self-sealing protection in HfB2-based boride–silicide coatings at high temperatures},
year = {2026},
journal = {Journal of Advanced Ceramics},
keywords = {oxygen permeability, high-temperature oxidation, self-sealing barrier, oxidation-driven glass evolution, in situ alloying},
url = {https://www.sciopen.com/article/10.26599/JAC.2026.9221326},
doi = {10.26599/JAC.2026.9221326},
abstract = {At high temperatures, oxidation is generally regarded as an unavoidable degradation process for ceramic protective coatings. Here, oxidation is shown to drive dynamic glass evolution and form a robust self-sealing barrier under extreme thermal conditions. An in situ alloyed boride–silicide composite coating is constructed, and the controlled incorporation of HfSi2 is found to change oxide-scale development by providing additional Hf and Si sources during oxidation and promoting the early formation and continuous reconstruction of a highly sealing Hf–Si–O glassy layer. The optimized coating exhibits exceptional oxidation resistance at 1700 °C, with the oxygen permeability and carbon loss rate reduced by 61.67% and 75.26%, respectively, corresponding to an average protection efficiency of 99.94%. Mechanistically, oxidation-driven glass evolution seals pores and microcracks and slows inward oxygen diffusion, whereas appropriate HfSi2 incorporation helps compact and stabilize the glassy layer, while excessive glass stiffening reduces high-temperature fluidity and weakens scale integrity. These findings provide a general design method for improving self-sealing oxidation protection at high temperatures.}
}