Fast nuclide identification based on a sequential Bayesian method

The rapid identification of radioactive substances in public areas is crucial. However, traditional nuclide identification methods only consider information regarding the full energy peaks of the gamma-ray spectrum and require long recording times, which lead to long response times. In this paper, a...

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Bibliographic Details
Published in:Nuclear science and techniques 2021-12, Vol.32 (12), p.116-127, Article 143
Main Authors: Li, Xiao-Zhe, Zhang, Qing-Xian, Tan, He-Yi, Cheng, Zhi-Qiang, Ge, Liang-Quan, Zeng, Guo-Qiang, Lai, Wan-Chang
Format: Article
Language:English
Subjects:
Beam Physics
Nuclear Energy
Particle Acceleration and Detection
Particle and Nuclear Physics
Physics
Physics and Astronomy
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Summary:The rapid identification of radioactive substances in public areas is crucial. However, traditional nuclide identification methods only consider information regarding the full energy peaks of the gamma-ray spectrum and require long recording times, which lead to long response times. In this paper, a novel identification method using the event mode sequence (EMS) information of target radionuclides is proposed. The EMS of a target radionuclide and natural background radiation were established as two different probabilistic models and a decision function based on Bayesian inference and sequential testing was constructed. The proposed detection scheme individually processes each photon. When a photon is detected and accepted, the corresponding posterior probability distribution parameters are estimated using Bayesian inference and the decision function is updated. Then, value of the decision function is compared to preset detection thresholds to obtain a detection result. Experiments on different target radionuclides ( 137 Cs and 60 Co) were performed. The count rates of the regions of interest (ROI) in the backgrounds between [651, 671], [1154, 1186], and [1310, 1350] keV were 2.35, 5.14, and 0.57 CPS, respectively. The experimental results demonstrate that the average detection time was 6.0 s for 60 Co (with an activity of 80400 Bq) at a distance of 60 cm from the detector. The average detection time was 7 s for 137 Cs (with an activity of 131000 Bq) at a distance of 90 cm from the detector. The results demonstrate that the proposed method can detect radioactive substances with low activity.
ISSN:1001-8042
2210-3147
DOI:10.1007/s41365-021-00982-z