构型熵在提高稀土锆酸盐CMAS耐蚀性中的作用

doi:10.7527/S1000-6893.2025.32302

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构型熵在提高稀土锆酸盐CMAS耐蚀性中的作用

张石华¹,丁坤英²,董仲伸³,于建海¹,孙宇博²,张涛²,袁嘉禧¹,陆锦涛¹

1. 中国民航大学天津市民用航空器适航与维修重点实验室
2. 中国民航大学
3. 中国南方航空股份有限公司工程技术分公司

收稿日期:2025-05-27 修回日期:2025-08-05 出版日期:2025-08-11 发布日期:2025-08-11
通讯作者: 丁坤英
基金资助:
国家重点研发计划资助;中国民航大学研究生科研创新项目

The role of configurational entropy in enhancing CMAS corrosion resistance of rare-earth zirconates

Received:2025-05-27 Revised:2025-08-05 Online:2025-08-11 Published:2025-08-11
Supported by:
National Key R&D Program of China

摘要/Abstract

摘要： 为研究稀土锆酸盐抗CMAS侵蚀性能的影响因素，制备了7种低、中、高熵稀土锆酸盐RExZO (RE= Y, Ho, Dy, Er, Gd, Yb, Tm, x = 1-7)，并系统研究其在1300 ℃下的CMAS侵蚀行为。结果表明，稀土锆酸盐材料在高温环境下与CMAS接触后会发生溶解破坏，并生成新的磷灰石相。高熵结构通过“溶解-再沉淀”机制形成了由磷灰石相和萤石相组成的致密反应层，使渗透深度最大值从RE1ZO的80.6 μm显著降低至RE7ZO的30.9 μm（降幅达61.7%）。由于受到离子半径大小的影响，被溶解的稀土元素会呈梯度扩散趋势进入磷灰石相和萤石相。相关性分析结果显示，侵蚀深度与光学碱度差值呈显著正相关，而与构型熵和原子尺寸无序度呈显著负相关(α ≤ 0.05)。结合第一性原理计算和XPS结果进一步证实，高构型熵降低了稀土锆酸盐吉布斯自由能和氧空位浓度，提高了元素结合能，从而增强了材料的结构稳定性。基于研究结论，可以得出设计高耐CMAS侵蚀性能稀土锆酸盐材料的优化策略：应优先考虑低光学碱度差值、高构型熵和高原子尺寸无序度的组合。

关键词: 稀土锆酸盐, 构型熵, CMAS腐蚀, 热障涂层, 高熵陶瓷

Abstract: To investigate the influencing factors of CMAS corrosion resistance in rare-earth zirconates, seven low-, medium-, and high-entropy rare-earth zirconates RExZO (RE = Y, Ho, Dy, Er, Gd, Yb, Tm; x = 1-7) were prepared, and their CMAS corrosion behaviors at 1300 °C were systematically studied. Results indicate that rare-earth zirconate materials undergo dissolution damage upon contact with CMAS at high temperatures, accompanied by the formation of a new apatite phase. The high-entropy structure facilitated the development of a dense reaction layer composed of apatite and fluorite phases through a "dissolution-reprecipitation" mechanism, significantly reducing the maximum infiltration depth from 80.6 μm for RE1ZO to 30.9 μm for RE7ZO (a 61.7% reduction). Influenced by ionic radius variations, dissolved rare-earth elements exhibited gradient diffusion into the apatite and fluorite phases. Correlation analysis revealed a significant positive relationship between corrosion depth and optical basicity difference, while showing significant negative correlations with configurational entropy and atomic size disorder (α ≤ 0.05). First-principles calculations and XPS results further confirmed that high configurational entropy reduces the Gibbs free energy and oxygen vacancy concentration of rare-earth zirconates while enhancing elemental binding energy, thereby improving structural stability. Based on these findings, an optimization strategy for designing CMAS-resistant rare-earth zirconates is proposed: priority should be given to material combinations featuring low optical basicity difference, high configurational entropy, and high atomic size disorder.

Key words: rare-earth zirconate, configurational entropy, CMAS corrosion, thermal barrier coating, high-entropy ceramic

中图分类号:

张石华丁坤英董仲伸于建海孙宇博张涛袁嘉禧陆锦涛. 构型熵在提高稀土锆酸盐CMAS耐蚀性中的作用[J]. 航空学报, doi: 10.7527/S1000-6893.2025.32302.

参考文献

[1]PADTURE N P, GELL M, JORDAN E H.Thermal Barrier Coatings for Gas-Turbine Engine Applications[J].Science, 2002, 296(5566):280-284 [2]HU X, XIE Y, LI F, et al.Research Progress on Environmental Corrosion Resistance of Thermal Barrier Coatings: A Review[J].Coatings, 2024, 14(10):1341- [3]NIETO A, AGRAWAL R, BRAVO L, et al.Calcia–magnesia–alumina–silicate (CMAS) Attack Mechanisms and Roadmap Towards Sandphobic Thermal and Environmental Barrier Coatings[J].International Materials Reviews, 2021, 66(7):451-492 [4]OZGURLUK Y, DOLEKER K M, AHLATCI H, et al.Investigation of Calcium–magnesium-alumino-silicate (CMAS) Resistance and Hot Corrosion Behavior of YSZ and La2Zr2O7/YSZ Thermal Barrier Coatings (TBCs) Produced with CGDS Method[J]. Surface and Coatings Technology, 2021, 411: 126969. [5]SHAN X, CHEN W, YANG L, et al.Pore Filling Behavior of Air Plasma Spray Thermal Barrier Coatings under CMAS Attack[J]. Corrosion Science, 2020, 167: 108478. [6]KRAUSE A R, GARCES H F, DWIVEDI G, et al.Calcia-magnesia-alumino-silicate (CMAS)-induced Degradation and Failure of Air Plasma Sprayed Yttria-stabilized zirconia Thermal Barrier Coatings[J]. Acta Materialia, 2016, 105: 355-366. [7]IQBAL A, MOSKAL G.Recent Development in Advance Ceramic Materials and Understanding the Mechanisms of Thermal Barrier Coatings Degradation[J].Archives of Computational Methods in Engineering, 2023, 30(8):4855-4896 [8]DREXLER J M, ORTIZ A L, PADTURE N P.Composition Effects of Thermal Barrier Coating Ceramics on Their Interaction with Molten Ca–Mg–Al–silicate (CMAS) Glass[J].Acta Materialia, 2012, 60(15):5437-5447 [9]ZHANG C, FAN Y, ZHAO J, et al.Corrosion Resistance of Nonstoichiometric Gadolinium Zirconate Coatings Against CaO-MgO-Al2O3-SiO2 Silicate[J].Journal of the European Ceramic Society, 2021, 41(6):3687-3695 [10]WU Y, ZHI W, LI Y, et al.Interactions Between Rare-earth Zirconates (RE2Zr2O7) and CMAS Silicate melts[J]. Corrosion Science, 2023, 224: 111526. [11]LI F, ZHOU L, LIU J X, et al.High-entropy Pyrochlores with Low Thermal Conductivity for Thermal Barrier Coating Materials[J].Journal of Advanced Ceramics, 2019, 8(4):576-582 [12]ZHAO Z, XIANG H, DAI F Z, et al.La02Ce0.2Nd0.2Sm0.2Eu0.2)2Zr2O7: A Novel High-entropy Ceramic with Low Thermal Conductivity and Sluggish Grain Growth Rate[J].Journal of Materials Science & Technology, 2019, 35(11):2647-2651 [13]ZHAO S, WANG Z, CAO J, et al.Study on High-entropy Rare-earth Zirconate Ceramics for Thermal Barrier Coatings: High-temperature Phase Stability, Thermophysical and Mechanical Properties[J]. Journal of Alloys and Compounds, 2025, 1010: 178047. [14]YAN R, LIANG W, MIAO Q, et al.Mechanical,Thermal and CMAS Resistance Properties of High-entropy (Gd02Y0.2Er0.2Tm0.2Yb0.2)2Zr2O7 Ceramics[J].Ceramics International, 2023, 49(12):20729-20741 [15]LIN G, WANG Y, YANG L, et al.CMAS Corrosion Behavior of a Novel High Entropy (Nd0.2Gd0.2Y0.2Er0.2Yb0.2)2Zr2O7 Thermal Barrier Coating Materials[J]. Corrosion Science, 2023, 224: 111529. [16]DENG S, HE G, YANG Z, et al.Calcium-magnesium-alumina-silicate (CMAS) Resistant High Entropy Ceramic (Y0.2Gd0.2Er0.2Yb0.2Lu0.2)2Zr2O7 for Thermal Barrier Coatings[J]. Journal of Materials Science & Technology, 2022, 107: 259-265. [17]TIAN Y, ZHAO X, SUN Z, et al.Improved Thermal Properties and CMAS Corrosion Resistance of High-Entropy RE Zirconates by Tuning Fluorite-pyrochlore Structure[J].Ceramics International, 2024, 50(11):19182-19193 [18]YANG L, GENG H, GUAN Z, et al.The Role of La and Nd in Enhancing CMAS Corrosion Resistance of High-entropy (La,Nd,Tm,Yb,Lu)2Zr2O7 Thermal Barrier Coating Materials[J].Journal of the European Ceramic Society, 2025, 45(12):117466- [19]FAN W, LIU Y, LV Z, et al.Thermophysical and Mechanical Properties of Dual-phase Medium- and High-Entropy Rare-earth Zirconate Ceramics[J].Ceramics International, 2023, 49(23):38000-38006 [20]CHE J, WANG X, LIU X, et al.Thermal Transport Property in Pyrochlore-type and Fluorite-type A2B2O7 Oxides by Molecular Dynamics Simulation[J]. International Journal of Heat and Mass Transfer, 2022, 182: 122038. [21]YANG H, LIN G, BU H, et al.Single-phase Forming Ability of High-entropy Ceramics from a Size Disorder Perspective: A Case Study of (La02Eu0.2Gd0.2Y0.2Yb0.2)2Zr2O7[J].Ceramics International, 2022, 48(5):6956-6965 [22]LUO L, YANG G, REN G, et al.Effect of Multi-component at the A Site on the Phase and Sintering Resistance of High Entropy Rare Earth Zirconates[J].Journal of the European Ceramic Society, 2024, 44(4):2550-2559 [23]KRESSE G, FURTHMüLLER J.Efficient Iterative Schemes for ab initiototal-energy Calculations using a Plane-wave Basis Set[J]. Physical Review B, 54(16): 11169-11186. [24]BL?CHL P E.Projector Augmented-wave Method[J]. Physical Review B, 50(24): 17953-17979. [25]PERDEW J P, BURKE K, ERNZERHOF M.Generalized Gradient Approximation Made Simple[J]. Physical Review Letters, 77(18): 3865-3868. [26]WALLE A, AATS M, CEDER G.The Alloy Theoretic Automated Toolkit: A User Guide[J].Calphad, 2002, 26(4):539-553 [27]MONKHORST H J, PACK J D.Special Points for Brillouin-zone Integrations[J].Physical Review B, , 13(12):5188-5192 [28]WANG V, XU N, LIU J C, et al.VASPKIT: A User-friendly Interface Facilitating High-throughput Computing and Analysis Using VASP Code[J].Computer Physics Communications, 2021, 267:108033- [29]MIRACLE D B, SENKOV O N.A Critical Review of High Entropy Alloys and Related Concepts[J].Acta Materialia, 2017, 122:448-511 [30]WEI X, MA Y, HONG F, et al.Structure and Properties of RE2HE2O7 Thermal Barrier Ceramics Designed with High-entropy at Different Sites[J].Bulletin of Materials Science, 2024, 47(4):274- [31]SUBRAMANIAN M A, ARAVAMUDAN G, SUBBA Rao G V.Oxide Pyrochlores — A Review[J].Progress in Solid State Chemistry, 1983, 15(2):55-143 [32]ZHOU M, ZHANG H, YANG G, et al.Reaction Mechanisms of (RE02Nd0.2Sm0.2Eu0.2Gd0.2)2Zr2O7 (RE = La or Yb) under CaO-MgO-Al2O3-SiO2 (CMAS) attack[J].Journal of the European Ceramic Society, 2024, 44(6):4055-4063 [33]WANG X, HE Z, YANG X, et al.Corrosion Resistance of High Entropy Rare Earth Zirconate Ceramic to CMAS[J].Ceramics International, 2025, 51(6):8129-8137 [34]WANG Y, MA Z, LIU L, et al.Reaction Products of Sm2Zr2O7 with Calcium-magnesium-aluminum-silicate (CMAS) and Their Evolution[J].Journal of Advanced Ceramics, 2021, 10(6):1389-1397 [35]XIANG H, XING Y, DAI F, et al.High-entropy Ceramics: Present Status,Challenges,and a Look Forward[J].Journal of Advanced Ceramics, 2021, 10(3):385-441 [36]DUFFY J A, INGRAM M D.An Interpretation of Glass Chemistry in Terms of the Optical Basicity Concept[J].Journal of Non-Crystalline Solids, 1976, 21(3):373-410 [37]KRAUSE A R, SENTURK B S, GARCES H F, et al.ZrO2·Y2O3Thermal Barrier Coatings Resistant to Degradation by Molten CMAS: Part I,Optical Basicity Considerations and Processing[J].Journal of the American Ceramic Society, 2014, 97(12):3943-3949 [38]SU Q, ZHANG Y, LI G, et al.Doped Effect of Gd and Y Elements on Corrosion Resistance of ZrO2 in CMAS Melt: First-principles and Experimental Study[J].Journal of the European Ceramic Society, 2021, 41(15):7893-7901 [39]SHPATAKOVSKAYA G V.Binding Energies in Electron Shells of Rare-Earth Atoms[J].Journal of Experimental and Theoretical Physics, 2020, 131(3):385-393 [40]HINUMA Y, TOYAO T, KAMACHI T, et al.Density Functional Theory Calculations of Oxygen Vacancy Formation and Subsequent Molecular Adsorption on Oxide Surfaces[J].The Journal of Physical Chemistry C, 2018, 122(51):29435-29444

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主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

构型熵在提高稀土锆酸盐CMAS耐蚀性中的作用

The role of configurational entropy in enhancing CMAS corrosion resistance of rare-earth zirconates

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