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Development and study of ZnO:In optical scintillation ceramic
Full text «Opticheskii Zhurnal»
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Publication in Journal of Optical Technology
Горохова Е.И., Еронько С.Б., Кульков А.М., Орещенко Е.А., Симонова К.Л., Черненко К.А., Веневцев И.Д., Родный П.А., Лотт К.П., Wieczorek H. Разработка и исследование сцинтилляционной оптической керамики ZnO:In // Оптический журнал. 2015. Т. 82. № 12. С. 78–85.
Gorokhova E.I., Eronko S.B., Kulkov A.M., Oreshchenko E.A., Simonova K.L., Chernenko K.A., Venevtsev I.D., Rodniy P.A., Lott K.P., Wieczorek H. Development and study of ZnO:In optical scintillation ceramic [in Russian] // Opticheskii Zhurnal. 2015. V. 82. № 12. P. 78–85.
E. I. Gorokhova, S. B. Eron’ko, A. M. Kul’kov, E. A. Oreshchenko, K. L. Simonova, K. A. Chernenko, I. D. Venevtsev, P. A. Rodnyĭ, K. P. Lott, and H. Wieczorek, "Development and study of ZnO:In optical scintillation ceramic," Journal of Optical Technology. 82(12), 837-842 (2015). https://doi.org/10.1364/JOT.82.000837
Samples of the optical scintillation ceramic ZnO:In with an indium concentration from 0.075 to 1.6 mass% have been obtained by uniaxial hot pressing. Studies have established that indium has a significant and nontrivial influence on the structure, the character of the microstructure, the spectral transmittance, and the x-ray luminescence spectra and kinetics of ZnO:In. The optimum dopant concentration has been determined at which an optical scintillation ceramic is formed that has relatively intense edge luminescence with its maximum at 388 nm and a decay time of about 1.1 ns.
ZnO:In, uniaxial hot pressing, optical scintillation ceramic
OCIS codes: 160.2540, 160.4760
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