分析 ToF 光谱对 BGO 闪烁器中切伦科夫和闪烁发射的影响方法

IF 4.6 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING IEEE Transactions on Radiation and Plasma Medical Sciences Pub Date : 2024-04-22 DOI:10.1109/TRPMS.2024.3391944
Go Kawata;M. Teshigawara
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引用次数: 0

摘要

为了定量了解现实闪烁探测器中的发射序列,我们开发了飞行时间(ToF)光谱模型。该模型用于仔细研究切伦科夫和闪烁光子发射过程。为了构建这个模型,我们首先确定了闪烁体中发生的几个主要物理过程,并选择了对光谱有重大影响的过程。每个过程的特征都被统计到模型中。重要的是,该模型还考虑到了入射伽马光子与电子之间相互作用点的差异,这也是一个影响因素。为了证实模型的有效性,我们进行了一次实验。一对 20 毫米长的锗酸铋氧化物探测器与一个硅光电倍增管配对使用。实验结果提供了闪烁光子的数量和闪烁衰减时间常数。切伦科夫发射的时间常数是从现有文献中推导出来的,大约一个切伦科夫光子被用来拟合实验获得的 ToF 光谱。利用实验中获得的参数值,该模型成功地再现了实验 ToF 光谱。不过,我们实验中估计的闪烁光子数量约为文献报道的产量的一半,而验证过程中使用的切伦科夫光子数量与其他研究小组报道的数量一致。我们的结果表明,将接受真实系统行为的现象学模型与演绎处理理想系统的粒子蒙特卡洛模拟相结合进行分析,是在准确理解真实系统的基础上开发探测器的有效方法。
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Analyze Methodology of ToF Spectrum on Cherenkov and Scintillation Emission in BGO Scintillator
A time-of-flight (ToF) spectrum model has been developed to quantitatively understand the emission sequences in realistic scintillation detectors. This model is used to carefully investigate the Cherenkov and scintillation photon emission processes. To construct this model, we initially identified several primary physical processes occurring within scintillators and selected those that significantly contribute to the spectrum. The characteristics of each process were statistically incorporated into the model. Importantly, the model also takes into account the variance in the interaction point between the incident gamma photon and the electron, which serves as a contributing factor. To confirm the model’s validity, an experiment was conducted. A pair of 20-mm long bismuth germanate oxide detectors, paired with a silicon photomultiplier, used for this purpose. Experimental results provided the number of scintillation photons and the scintillation decay time constants. The time constant for Cherenkov emission was derived from the existing literature, and approximately one Cherenkov photon was used to fit the ToF spectrum obtained by the experiment. The model successfully reproduced the experimental ToF spectra with validity using the parameter values obtained in the experiment. However, the estimated number of scintillation photons in our experiment was about half of the yield number reported in literatures, while the number of Cherenkov photons utilized in the validation process was in line with those reported by other groups. Our results suggest that a combined analysis of the phenomenological model that accepts the behavior of the real system and particle-based Monte-Carlo simulation that treats the ideal system deductively is a meaningful approach for detector development based on an accurate understanding of the real system.
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来源期刊
IEEE Transactions on Radiation and Plasma Medical Sciences
IEEE Transactions on Radiation and Plasma Medical Sciences RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-
CiteScore
8.00
自引率
18.20%
发文量
109
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Affiliate Plan of the IEEE Nuclear and Plasma Sciences Society Table of Contents IEEE Transactions on Radiation and Plasma Medical Sciences Information for Authors IEEE Transactions on Radiation and Plasma Medical Sciences Publication Information Three-Gamma Imaging in Nuclear Medicine: A Review
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