• Title/Summary/Keyword: $Li_6Y_{0.5}Gd_{0.5}(BO_3)_3$

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Thermoluminescence Kinetics of LYGBO Crystal (LYGBO 단결정의 열형광 전자포획준위 인자)

  • Sunghwan, Kim
    • Journal of the Korean Society of Radiology
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    • v.17 no.1
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    • pp.17-23
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    • 2023
  • In this study, the thermoluminescence kinetics of electron trap in Li6Y0.5Gd0.5(BO3)3 (LY0.5G0.5BO) scintillator for neutron detection composed of Li, Gd, and B with a high neutron response cross-section were investigated. The thermoluminescence glow curve of the LY0.5G0.5BO scintillation single crystal was measured and analyzed using the peak shape method, the initial rise method, and the machine learning algorithm to evaluate the physical parameters of the electron trap. The glow curve of the LY0.5G0.5BO scintillation single crystal consisted of a single peak. As a result of analyzing this peak, the activation energy, emission order, and frequency factor of the electron trap were 0.61 eV, 1.1, and 1.7×107 s-1, respectively. In addition, the possibility of thermoluminescence analysis of scintillators using machine learning was confirmed.

Thermoluminescene Properties of Li6Gd(BO3)3:Ce3+ Scintillation Single Crystal (리튬 가돌리늄 보레이트 섬광단결정의 열형광 특성)

  • Kim, Sunghwan;Lee, Joonil
    • Journal of the Korean Society of Radiology
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    • v.8 no.7
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    • pp.455-459
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    • 2014
  • We grew the $Li_6Gd(BO_3)_3:Ce^{3+}$ scintillator and determined the scintillation and thermoluminescence properties for X-rays. The emission spectrum of $Li_6Gd(BO_3)_3:Ce^{3+}$ is located in the range of 370~500 nm, peaking at 423 nm an 455 nm, due to the $4f{\rightarrow}5d$ transition of $Ce^{3+}$ ions. The fluorescence decay time of the crystal is composed three components. The fast component is 60 ns (25%), the intermediate component is 787 ns (29%) and the slow component is $5.9{\mu}s$ (46%) of the crystal. The after-glow is caused by the electron and hole traps in the crystal lattice. We determined physical parameters of the traps in the crystal. The thermoluminescence trap are composed two traps. The determined activation energy (E), kinetic order (m) and frequency factor (s) of the first trap are 0.65 eV, 1.01 and $6.9{\times}10^8s^{-1}$. And, the determined activation energy, kinetic order and frequency factor of the second trap are 0.96 eV, 1.79 and $3.1{\times}10^{12 }s^{-1}$, respectively.