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High entropy defective fluorite structured rare-earth niobates and tantalates for thermal barrier applications

Zifan Zhao, Heng Chen, Huimin Xiang, Fu‐Zhi Dai, Xiaohui Wang, Wei Xu, Kuang Sun, Zhijian Peng, Yanchun Zhou

2020Journal of Advanced Ceramics217 citationsDOIOpen Access PDF

Abstract

Abstract Rare-earth tantalates and niobates (RE 3 TaO 7 and RE 3 NbO 7 ) have been considered as promising candidate thermal barrier coating (TBC) materials in next generation gas-turbine engines due to their ultra-low thermal conductivity and better thermal stability than yttria-stabilized zirconia (YSZ). However, the low Vickers hardness and toughness are the main shortcomings of RE 3 TaO 7 and RE 3 NbO 7 that limit their applications as TBC materials. To increase the hardness, high entropy (Y 1/3 Yb 1/3 Er 1/3 ) 3 TaO 7 , (Y 1/3 Yb 1/3 Er 1/3 ) 3 NbO 7 , and (Sm 1/6 Eu 1/6 Y 1/6 Yb 1/6 Lu 1/6 Er 1/6 ) 3 (Nb 1/2 Ta 1/2 )O 7 are designed and synthesized in this study. These high entropy ceramics exhibit high Vickers hardness (10.9–12.0 GPa), close thermal expansion coefficients to that of single-principal-component RE 3 TaO 7 and RE 3 NbO 7 (7.9×10 −6 -10.8×10 −6 C −1 at room temperature), good phase stability, and good chemical compatibility with thermally grown Al 2 O 3 , which make them promising for applications as candidate TBC materials.

Topics & Concepts

Materials scienceThermal barrier coatingVickers hardness testNatural bond orbitalYttria-stabilized zirconiaThermal stabilityCeramicCubic zirconiaFracture toughnessThermal conductivityMetallurgyMineralogyComposite materialMicrostructureChemical engineeringDensity functional theoryChemistryComputational chemistryEngineeringHigh-Temperature Coating BehaviorsAdvanced materials and compositesNuclear materials and radiation effects