Examination of radiation effects on Cs2LiYCl6:Ce3+ scintillators using a 100 MeV proton beam

Cs 2 LiYCl 6 :Ce 3+ scintillator is worthwhile to study, since it has good pulse shape discrimination capability which lead to thermal or fast neutron detection based on the reactions of the constituent elements of Li and Cl. In this study, the effects of proton dose on the scintillation performance...

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Bibliographic Details
Published inJournal of the Korean Physical Society Vol. 80; no. 5; pp. 382 - 387
Main Authors Nam, Uk-won, Youn, Sukwon, Park, Won-Kee, Pyo, Jeonghyun, Sohn, Jongdae, Moon, Bongkon, Ye, Sung-Joon, Kim, Sunghwan
Format Journal Article
LanguageEnglish
Published Seoul The Korean Physical Society 01.03.2022
Springer Nature B.V
한국물리학회
Subjects
Cerium
Discrimination
Fast neutrons
Gamma rays
Low earth orbits
Mathematical and Computational Physics
Neutrons
Original Paper - Particles and Nuclei
Particle and Nuclear Physics
Physics
Physics and Astronomy
Proton beams
Pulse shape
Radiation effects
Scintillation counters
Space exploration
Theoretical
Thermal neutrons
물리학
Proton
CLYC scintillator
Pulse shape discrimination
Neutron
Radiation damage
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Summary:Cs 2 LiYCl 6 :Ce 3+ scintillator is worthwhile to study, since it has good pulse shape discrimination capability which lead to thermal or fast neutron detection based on the reactions of the constituent elements of Li and Cl. In this study, the effects of proton dose on the scintillation performance of CLYC were measured to check its feasibility for space exploration. A 100 MeV proton beam generated by the Korean Multi-Purpose Accelerator Complex (KOMAC) was used for irradiation of the crystal. The pulse shape discrimination (PSD) for gamma-rays and thermal neutrons as a function of protons dose was used as a standard method for evaluation. After removing gamma-rays background from neutron signal by PSD, we examined the effect of the proton dose on the scintillator based on the electron equivalent energy induced by thermal neutron. When a proton beam was irradiated on the CLYC scintillator at 1 krad, we found a decrease in the light yield by approximately 50% and a rapid increase in the background radiations. Therefore, the detector for gamma-ray measurements was considered unsuitable in high-level proton fields, such as in a low-Earth orbit, owing to the activation problem in CLYC scintillators. However, given that the neutrons can be separated from gamma-rays by the PSD, conducting in situ calibrations using the peaks of the thermal neutron channels up to the maximum dose of the order of several krad through a neutron spectrometer is possible.
ISSN:0374-4884
1976-8524
DOI:10.1007/s40042-021-00348-z