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论 文 分 类 推 荐

本栏目按不同主题将本刊近年来发表的相关论文进行了分类,以便于读者查阅、引用 (分类不一定完全准确,仅供参考)

本刊2012年创刊以来发表的所有论文均可以在 SciOpen 网站免费下载


高熵陶瓷的制备工艺及性能


  1. H.M. Xiang, Y. Xing, F.Z. Dai, et al. High-entropy ceramics: Present status, challenges, and a look forward, Journal of Advanced Ceramics, 2021, 10 (3): 385-441.

  2. F.H. Cheng, F.N. Zhang, Y.F. Liu, et al. Ti4+-incorporated fluorite-structured high-entropy oxide (Ce,Hf,Y,Pr,Gd)O2-δ: Optimizing preparation and CMAS corrosion behavior. Journal of Advanced Ceramics, 2022, 11 (11): 1801-1814

  3. J.Y. Wu, X.H. Ma, X.X. Hu, et al. New class of high-entropy pseudobrookite titanate with excellent thermal stability, low thermal expansion coefficient, and low thermal conductivity, Journal of Advanced Ceramics, 2022, 11 (10): 1654-1670

  4. K.L. Wang, J.P. Zhu, H.L. Wang, et al. Air plasma-sprayed high-entropy (Y0.2Yb0.2Lu0.2Eu0.2Er0.2)3Al5O12 coating with high thermal protection performance, Journal of Advanced Ceramics, 2022, 11 (10): 1571-1582

  5. 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, 2022, 11 (9): 1479-1490

  6. Q.Q. Yang, X.G. Wang, W.C. Bao, et al. Influence of equiatomic Zr/(Ti,Nb) substitution on microstructure and ultra-high strength of (Ti,Zr,Nb)C medium-entropy ceramics at 1900℃, Journal of Advanced Ceramics, 2022, 11 (9): 1457-1465

  7. Z.L. Chen, Z.L Tian, L.Y. Zheng, et al. (Ho0.25Lu0.25Yb0.25Eu0.25)2SiO5 high-entropy ceramic with low thermal conductivity, tunable thermal expansion coefficient, and excellent resistance to CMAS corrosion, Journal of Advanced Ceramics, 2022, 11 (8): 1279-1293

  8. J.T. Zhu, M.Y. Wei, J. Xu, et al. Influence of order-disorder transition on the mechanical and thermophysical properties of A2B2O7 high-entropy ceramics, Journal of Advanced Ceramics, 2022, 11 (8): 1222-1234

  9. Y.Y. Chen, J.L. Qi, M.H. Zhang, et al. Pyrochlore-based high-entropy ceramics for capacitive energy storage, Journal of Advanced Ceramics, 2022, 11 (7): 1179-1185

  10. Y. Qin, J.X. Liu, Y.C. Liang, et al. Equiatomic 9-cation high-entropy carbide ceramics of the IVB, VB, and VIB groups and thermodynamic analysis of the sintering process, Journal of Advanced Ceramics, 2022,11 (7): 1082-1092

  11. D.B. Liu, B.L. Shi, L.Y. Geng, et al. High-entropy rare-earth zirconate ceramics with low thermal conductivity for advanced thermal-barrier coatings. Journal of Advanced Ceramics, 2022,11 (6) : 961-973

  12. K. Yuan, T.Z. Tu, C. Shen, et al. Self-ball milling strategy to construct high-entropy oxide coated LiNi0.8Co0.1Mn0.1O2 with enhanced electrochemical performance, Journal of Advanced Ceramics, 2022,11 (6) : 882-892

  13. S.C. Luo, W.M. Guo, K. Plucknett, et al. Low-temperature densification of high-entropy (Ti,Zr,Nb,Ta,Mo)C–Co composites with high hardness and high toughness, Journal of Advanced Ceramics, 2022,11 (5) : 805-813.

  14. Y.S. Xu, X. Xu, L. Bi, A high-entropy spinel ceramic oxide as the cathode for proton-conducting solid oxide fuel cells, Journal of Advanced Ceramics, 2022,11 (5) : 794-804.

  15. J.B. Ma, B. Zhao, H.M. Xiang, et al. High-entropy spinel ferrites MFe2O4 (M = Mg, Mn, Fe, Co, Ni, Cu, Zn) with tunable electromagnetic properties and strong microwave absorption, Journal of Advanced Ceramics, 2022,11 (5) : 754-768.

  16. M. Guo, Y.F. Liu, F.N. Zhang, et al. Inactive Al3+-doped La(CoCrFeMnNiAlx)1/(5+x)O3 high-entropy perovskite oxides as high performance supercapacitor electrodes, Journal of Advanced Ceramics, 2022,11 (5) : 742-753.

  17. M.D. Qin, H. Vega, D.W. Zhang, et al. 21-Component compositionally complex ceramics: Discovery of ultrahigh-entropy weberite and fergusonite phases and a pyrochlore-weberite transition, Journal of Advanced Ceramics, 2022, 11 (4): 641-655.

  18. Y. Xue, X.Q. Zhao, Y.L. An, High-entropy (La0.2Nd0.2Sm0.2Eu0.2Gd0.2)2Ce2O7: A potential thermal barrier material with improved thermo-physical properties, Journal of Advanced Ceramics, 2022, 11 (4): 615-628.

  19. L. Chen, B.H. Li, J. Guo, et al. High-entropy perovskite RETa3O9 ceramics for high-temperature environmental/thermal barrier coatings, Journal of Advanced Ceramics, 2022, 11 (4): 556-569.

  20. W.M. Zhang, H.M. Xiang, F.Z. Dai, et al. Achieving ultra-broadband electromagnetic wave absorption in high-entropy transition metal carbides (HE TMCs), Journal of Advanced Ceramics, 2022, 11 (4): 545-555.

  21. Y.J. Han, R.W. Yu, H.H. Liu, et al. Synthesis of the superfine high-entropy zirconate nanopowders by polymerized complex method, Journal of Advanced Ceramics, 2022, 11 (1): 136-144.

  22. Y. Dong, K. Ren, Q.K. Wang, et al. Interaction of multicomponent disilicate (Yb0.2Y0.2Lu0.2Sc0.2Gd0.2)2Si2O7 with molten calcia-magnesia-aluminosilicate, Journal of Advanced Ceramics, 2022, 11 (1): 66-74.

  23. W.M. Zhang, F.Z. Dai, H.M. Xiang, et al. Enabling highly efficient and broadband electromagnetic wave absorption by tuning impedance match in high-entropy transition metal diborides (HE TMB2), Journal of Advanced Ceramics, 2021, 10 (6): 1299-1316.

  24. Y.N. Sun, H.M. Xiang, F.Z. Dai, et al. Preparation and properties of CMAS resistant bixbyite structured high-entropy oxides RE2O3 (RE = Sm, Eu, Er, Lu, Y, and Yb): Promising environmental barrier coating materials for Al2O3f/Al2O3 composites, Journal of Advanced Ceramics, 2021, 10 (3): 596-613.

  25. Y.P. Zheng, M.C. Zou, W.Y. Zhang, et al. Electrical and thermal transport behaviours of high-entropy perovskite thermoelectric oxides, Journal of Advanced Ceramics, 2021, 10 (2): 377-384.

  26. Y. Zhang, S.K. Sun, W.M. Guo, et al. Optimal preparation of high-entropy boride-silicon carbide ceramics, Journal of Advanced Ceramics, 2021, 10 (1):173-180.

  27. M.D. Qin, Q.Z. Yan, Y. Liu, et al. A new class of high-entropy M3B4 borides, Journal of Advanced Ceramics, 2021, 10 (1): 166-172.

  28. W.M. Zhang, B. Zhao, H.M. Xiang, et al. One-step synthesis and electromagnetic absorption properties of high entropy rare earth hexaborides (HE REB6) and high entropy rare earth hexaborides/borates (HE REB6/HE REBO3) composite powders, Journal of Advanced Ceramics, 2021, 10 (1): 62-77.


 

   
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