المؤلفون: O. Kurapova Yu., S. Golubev N., A. Glukharev G., V. Konakov G., О. Курапова Ю., С. Голубев Н., А. Глухарев Г., В. Конаков Г.

المساهمون: Исследование выполнено при поддержке гранта президента РФ для молодых ученых № 75-15- 2019-210. Исследования микроструктуры проведены с использованием оборудования ресурсного центра Научного парка СПбГУ «Инновационные технологии композитных наноматериалов». Данные СТА получены с использованием оборудования ресурсного центра Научного парка СПбГУ «Термогравиметрические и калориметрические методы исследования».

المصدر: NOVYE OGNEUPORY (NEW REFRACTORIES); № 2 (2020); 59-64 ; Новые огнеупоры; № 2 (2020); 59-64 ; 1683-4518 ; 10.17073/1683-4518-2020-2

مصطلحات موضوعية: zirconium dioxide, cerium dioxide, thermal barrier coatings, freeze drying, three-component ceramic, диоксид циркония, диоксид церия, термобарьерные покрытия, лиофильная сушка, трехкомпонентная керамика

وصف الملف: application/pdf

Relation: https://newogneup.elpub.ru/jour/article/view/1380/1170; Hardwicke, C. U. Advances in thermal spray coatings for gas turbines and energy generation: a review / C. U. Hardwicke, Y. C. Lau // J. Therm. Spray Technol. ― 2015. ― Vol. 22. ― P. 564‒576. https://dx.doi.org/10.1007/s11666-013-9904-0.; Miller, R. A. Thermal barrier coatings for aircraft engines: history and directions / R. A. Miller // Journal of thermal spray technology. ― 1997. ― Vol. 6, № 1. ― P. 35‒42. https://doi.org/10.1007/BF02646310.; Kumar, V. Progress update on failure mechanisms of advanced thermal barrier coatings: A review / V. Kumar, K. Balasubramanian // Progress in Organic Coatings. ― 2016. ― Vol. 90. ― P. 54‒82. https://doi.org/10.1016/j.porgcoat.2015.09.019.; Padture, N. P. Thermal barrier coatings for gasturbine engine applications / N. P. Padture, M. Gell, E. H. Jordan // Science. ― 2002. ― Vol. 296, № 5566. ― P. 280‒284. https://dx.doi.org/10.1126/science.1068609.; Jamali, H. Fabrication and evaluation of plasmasprayed nanostructured and conventional YSZ thermal barrier coatings / H. Jamali, R. Mozafarinia, R. ShojaRazavi [et al.] // Current Nanoscience. ― 2012. ― Vol. 8, № 3. ― P. 402‒409.; Lima, R. S. Nanostructured YSZ thermal barrier coatings engineered to counteract sintering effects / R. S. Lima, B. R. Marple // Materials Science and Engineering: A. ― 2008. ― Vol. 485, № 1/2. ― P. 182‒193.; Rezanka, S. Improved thermal cycling durability of thermal barrier coatings manufactured by PS-PVD / S. Rezanka, G. Mauer, R. Vaßen // Journal of Thermal Spray Technology. ― 2014. ― Vol. 23, № 1/2. ― P. 182‒189.; Hongming, Z. Effect of rare earth doping on thermophysical properties of lanthanum zirconate ceramic for thermal barrier coatings / Z. Hongming, Y. Danqing // Journal of Rare Earths. ― 2008. ― Vol. 26, № 6. ― P. 770‒774.; Mahade, S. Erosion performance of gadolinium zirconate-based thermal barrier coatings processed by suspension plasma spray / S. Mahade, N. Curry, S. Björklund [et al.] // Journal of Thermal Spray Technology. ― 2017. ― Vol. 26, № 1/2. ― P. 108‒115.; Zhang, J. Lanthanum zirconate based thermal barrier coatings: A review / J. Zhang, X. Guo, Y. G. Jung, L. Li, J. Knapp // Surface and Coatings Technology. ― 2017. ― Vol. 323. ― P. 18‒29.; Ejaz, N. Thermo-physical properties measurement of advanced TBC materials with pyrochlore and perovskite structures / L. Ali, A. Ahmad, M. Mansoor [et al.] // Key Engineering Materials. ― Trans. Tech. Publications. ― 2018. ― Vol. 778. ― P. 236‒244.; Vassen, R. Zirconates as new materials for thermal barrier coatings / R. Vassen, X. Cao, F. Tietz [et al.] // J. Am. Ceram. Soc. ― 2000. ― Vol. 83, № 8. ― P. 2023‒2028.; Zhao, M. Effect of lattice defects on thermal conductivity of Ti-doped, Y2O3-stabilized ZrO2 / M. Zhao, W. Pan // Acta Mater. ― 2013. ― Vol. 61, № 14. ― P. 5496‒5503.; Pitek, F. M. Opportunities for TBCs in the ZrO2‒YO1,5‒ TaO2,5 system / F. M. Pitek, C. G. Levi // Surface and Coatings Technology. ― 2007. ― Vol. 201, № 12. ― P. 6044‒6050.; Kim, D. J. Effect of tetravalent dopants on Raman spectra of tetragonal zirconia / D. J. Kim, J. W. Jang, H. L. Lee // J. Am. Ceram. Soc. ― 1997. ― Vol. 80, № 6. ― P. 1453‒1461.; Wang, J. Phase stability and thermo-physical properties of ZrO2‒CeO2‒TiO2 ceramics for thermal barrier coatings / J. Wang, J. Sun, Q. Jing [et al.] // J. Eur. Ceram. Soc. ― 2018. ― Vol. 38, № 7. ― P. 2841‒2850.; Shannon, R. D. T. Effective ionic radii in oxides and fluorides / R. D. T. Shannon, C. T. Prewitt // Acta Crystallographica Section B: Structural Crystallography and Crystal Chemistry. ― 1969. ― Vol. 25, № 5. ― P. 925‒946.; Han, Z. A comparison of thermal shock behavior between currently plasma spray and supersonic plasma spray CeO2‒Y2O3‒ZrO2 graded thermal barrier coatings / Z. Han, B. Xu, H. Wang, S. Zhou // Surface and Coatings Technology. ― 2007. ― Vol. 201, № 9‒11. ― P. 5253‒5256.; Pandolfelli, V. C. Sintering and microstructural studies in the system ZrO2‒TiO2‒CeO2 / V. C. Pandolfelli, M. Rainforth, R. Stevens // Journal of Materials Science. ― 1990. ― Vol. 25, № 4. ― P. 2233‒2244.; Krogstad, J. A. Opportunities for improved TBC durability in the CeO2‒TiO2‒ZrO2 system / J. A. Krogstad, M. Lepple, C. G. Levi // Surface and Coatings Technology. ― 2013. ― Vol. 221. ― P. 44‒52.; Картотека порошкограмм (powder diffraction file, PDF-2). Release 2007.; Kurapova, O. Y. Thermal evolution of the microstructure of calcia stabilized zirconia precursors manufactured by cryochemical technique / O. Y. Kurapova, D. V. Nechaeva, A. V. Ivanov, S. N. Golubev, V. M. Ushakov, V. G. Konakov // Reviews on Advanced Materials Science. ― 2016. ― Vol. 47. ― P. 95‒104.; https://newogneup.elpub.ru/jour/article/view/1380

الاتاحة: https://newogneup.elpub.ru/jour/article/view/1380
https://doi.org/10.17073/1683-4518-2020-2-59-64