[1] D NI, Y CHENG, J ZHANG et al. Advances in ultra-high temperature ceramics, composites, and coatings. Journal of Advanced Ceramics, 1(2022).
[2] H DU. Research progress on integrated thermal management and key technology of hypersonic vehicles. Equipment Environmental Engineering, 43(2023).
[3] V R REGHU, V SHANKAR, P RAMASWAMY. Challenges in plasma spraying of 8%Y2O3-ZrO2 thermal barrier coatings on Al alloy automotive piston and influence of vibration and thermal fatigue on coating characteristics. Materials Today: Proceedings, 23927(2018).
[4] J WANG, X LU, M HU et al. Phase stability, thermophysical properties, thermal shock behavior and CMAS resistance of Sc2O3-CeO2 co-stabilized ZrO2 TBCs. Surface and Coatings Technology, 467: 129679(2023).
[5] C LI, H FAN, L NI et al. Phase transformation and thermal conductivity of the APS Y2O3 doped HfO2 coating with hybrid structure. Ceramics International, 19633(2022).
[6] Y WU, D HONG, X ZHONG et al. Research progress on hafnium-based thermal barrier coatings materials. Ceramics International, 21133(2023).
[7] H WU, Y DUAN, K LIU et al. First-principles study of phase transition and band structure of ZrO2 under pressure. Journal of Alloys and Compounds, 645: 352(2015).
[8] G MANDAL, R JANA, P SAHA et al. Study of structural phase transition of HfO2 at high pressure. Materials Today: Proceedings, 2997(2016).
[9] L PAN, L HE, Z NIU et al. Corrosion behavior of ytterbium hafnate exposed to water-vapor with Al(OH)3 impurities. Journal of the European Ceramic Society, 612(2023).
[10] L HE, L PAN, W ZHOU et al. Thermal corrosion behavior of Yb4Hf3O12 ceramics exposed to calcium-ferrum-alumina-silicate (CFAS) at 1400 ℃. Journal of the European Ceramic Society, 4114(2023).
[11] X Y LIU, J W CHE, H YI et al. Influence of powder states on the composition and phase stability of LZ/YSZ composite thermal barrier coatings. Ceramics International, 20291(2018).
[12] D LIU, T WEN, B YE et al. Synthesis of superfine high-entropy metal diboride powders. Scripta Materialia, 167: 110(2019).
[13] B YE, T WEN, M C NGUYEN et al. First-principles study, fabrication and characterization of (Zr0.25Nb0.25Ti0.25V0.25)C high- entropy ceramics. Acta Materialia, 170: 15(2019).
[14] L SUN, X REN, T DU et al. High entropy engineering: new strategy for the critical property optimizations of rare earth silicates. Journal of Inorganic Materials, 339(2020).
[15] Y SUN, L YE, W ZHAO et al. Synthesis of high entropy carbide nano powders via liquid polymer precursor route. Journal of Inorganic Materials, 393(2021).
[16] G ANAND, A P WYNN, C M HANDLEY et al. Phase stability and distortion in high-entropy oxides. Acta Materialia, 146: 119(2018).
[17] M PIANASSOLA, K L ANDERSON, J SAFIN et al. Tuning the melting point and phase stability of rare-earth oxides to facilitate their crystal growth from the melt. Journal of Advanced Ceramics, 1479(2022).
[18] J SUN, L GUO, Y ZHANG et al. Superior phase stability of high entropy oxide ceramic in a wide temperature range. Journal of the European Ceramic Society, 5053(2022).
[19] Y LI, Y LIU, C GUO et al. Ablation resistance of ZrC-based composite coating with multi-layer structure for carbon/carbon composites above 2200 ℃. Corrosion Science.
[20] X GUO, Y ZHANG, T LI et al. High-entropy rare-earth disilicate (Lu0.2Yb0.2Er0.2Tm0.2Sc0.2)2Si2O7: a potential environmental barrier coating material. Journal of the European Ceramic Society, 3570(2022).
[21] J WANG, F WU, R ZOU et al. High-entropy ferroelastic rare-earth tantalite ceramic: (Y0.2Ce0.2Sm0.2Gd0.2Dy0.2)TaO4. Journal of the American Ceramic Society, 5873(2021).
[22] F ZHANG, M GUO, Y MIAO et al. Preparation and sintering behavior of high entropy ceramic (Zr1/7Hf1/7Ce1/7Y2/7La2/7)O2-δ. Journal of Inorganic Materials, 372(2021).
[23] Z ZHAO, H CHEN, H XIANG et al. 2O7: a defective fluorite structured high entropy ceramic with low thermal conductivity and close thermal expansion coefficient to Al2O3. Journal of Materials Science & Technology, 39: 167(2020).
[24] J GILD, M SAMIEE, J L BRAUN et al. High-entropy fluorite oxides. Journal of the European Ceramic Society, 3578(2018).
[25] A J WRIGHT, Q WANG, C HU et al. Single-phase duodenary high-entropy fluorite/pyrochlore oxides with an order-disorder transition. Acta Materialia, 211: 116858(2021).
[26] L ZHOU, F LI, J LIU et al. High-entropy thermal barrier coating of rare-earth zirconate: a case study on (La0.2Nd0.2Sm0.2Eu0.2Gd0.2)2Zr2O7 prepared by atmospheric plasma spraying. Journal of the European Ceramic Society, 5731(2020).
[27] DA COSTA, P CHAUDHURI, A GHOSH et al. Mechanical alloying synthesis of Sm3NbO7 defect fluorite and structural characterization by X-ray diffraction, Raman spectroscopy and DFT calculation. Ceramics International, 8936(2021).
[28] G FENG, X YAO, Y YU et al. Synthesis and performance characterization of Hafnium-based multilayer coating applied over carbon/carbon composites with sharp leading edge. Journal of Materials Science & Technology, 153: 254(2023).
[29] D HU, Y ZHANG, Z DONG et al. Relationship analyses on environmental factors-ablation performance based on ZrC-TaC system: oxygen partial pressure and gas flow scouring. Journal of the European Ceramic Society, 2331(2023).
[30] E R ANDRIEVSKAYA. Phase equilibria in the refractory oxide systems of zirconia, hafnia and yttria with rare-earth oxides. Journal of the European Ceramic Society, 2363(2008).
[31] M ANANDKUMAR, E TROFIMOV. Synthesis, properties, and applications of high-entropy oxide ceramics: current progress and future perspectives. Journal of Alloys and Compounds, 960: 170690(2023).
[32] D HU, Q FU, M TONG et al. Multiple cyclic ablation behaviors of multilayer ZrC-TaC coating with ZrC-SiC interface layer. Corrosion Science, 200: 110215(2022).
[33] Y ZE, D WANG, X XIONG et al. Ablation-resistant carbide Zr0.8Ti0.2C0.74B0.26 for oxidizing environments up to 3000 ℃. Nature Communications, 8: 15836(2017).
[34] S GU, S ZHANG, F LIU et al. New anti-ablation candidate for carbon/carbon composites: preparation, composition and ablation behavior of Y2Hf2O7 coating under an oxyacetylene torch. Journal of the European Ceramic Society, 5082(2018).
[35] Y YU, G FENG, Y JIA et al. Nanosized (Zr, Hf)O2 coating reinforced by AlN whiskers for the ablation protection of SiC coated C/C composites. Journal of the European Ceramic Society, 3959(2023).
[36] G FENG, H LI, X YAO et al. Investigation on the relationship between multilayer architecture and ablation behavior using an oxyacetylene torch. Corrosion Science, 198: 110104(2022).
[37] J ZHANG, Y ZHANG, T ZHANG et al. Cyclic ablation behavior and microstructure evolution of multi-layer coating on C/C composites under oxyacetylene torch. Ceramics International, 21709(2022).
[38] G FENG, H LI, X YAO et al. Ablation resistance of HfC- TaC/HfC-SiC alternate coating for SiC-coated carbon/carbon composites under cyclic ablation. Journal of the European Ceramic Society, 3207(2021).
[39] J REN, Y ZHANG, P ZHANG et al. Ablation resistance of HfC coating reinforced by HfC nanowires in cyclic ablation environment. Journal of the European Ceramic Society, 2759(2017).
[40] J LI, Y ZHANG, H WANG et al. Long-life ablation resistance ZrB2-SiC-TiSi2 ceramic coating for SiC coated C/C composites under oxidizing environments up to 2200 K. Journal of Alloys and Compounds.
[41] Y ZHANG, J SUN, L GUO et al. Ablation behavior under oxyacetylene torch of ZrC coating modified by SiC/TaC nanocomposites. Corrosion Science, 205: 110423(2022).
[42] Y ZHANG, H HU, P ZHANG et al. SiC/ZrB2-SiC-ZrC multilayer coating for carbon/carbon composites against ablation. Surface and Coatings Technology, 300: 1(2016).
[43] G FENG, L CHEN, X YAO et al. Design and characterization of zirconium-based multilayer coating for carbon/carbon composites against oxyacetylene ablation. Corrosion Science, 192: 109785(2021).