Crystals (Sep 2022)

Composition Engineering of (Lu,Gd,Tb)<sub>3</sub>(Al,Ga)<sub>5</sub>O<sub>12</sub>:Ce Film/Gd<sub>3</sub>(Al,Ga)<sub>5</sub>O<sub>12</sub>:Ce Substrate Scintillators

  • Oleg Sidletskiy,
  • Vitalii Gorbenko,
  • Tetiana Zorenko,
  • Yurii Syrotych,
  • Sandra Witkiwicz-Łukaszek,
  • Jiri A. Mares,
  • Romana Kucerkova,
  • Martin Nikl,
  • Iaroslav Gerasymov,
  • Daniil Kurtsev,
  • Alexander Fedorov,
  • Yuriy Zorenko

DOI
https://doi.org/10.3390/cryst12101366
Journal volume & issue
Vol. 12, no. 10
p. 1366

Abstract

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The paper addresses the development of composite scintillation materials providing simultaneous real-time monitoring of different types of ionizing radiation (α-, β-particles, γ-rays) in mixed fluxes of particles and quanta. The detectors are based on composite heavy oxide scintillators consisting of a thin single-crystalline film and a bulk single-crystal substrate. The film and substrate respond to certain types of ionizing particles, forming together an all-in-one composite scintillator capable of distinguishing the type of radiation through the different time characteristics of the scintillation response. Here, we report the structure, composition, and scintillation properties under different ionizing radiations of (Lu,Gd,Tb)3(Al,Ga)5O12:Ce films deposited using liquid phase epitaxy onto Gd3(Al1−xGax)5O12:Ce (GAGG:Ce) single-crystal substrates. The most promising compositions with the highest light yields and the largest differences in scintillation decay timing under irradiation with α-, β-particles, and γ-rays were selected. Such detectors are promising for environmental security purposes, medical tomography, and other radiation detection applications.

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