Neutron-gamma pulse shape discrimination for organic scintillation detector using 2D CNN based image classification

IF 1.8 3区工程技术 Q3 CHEMISTRY, INORGANIC & NUCLEAR Applied Radiation and Isotopes Pub Date : 2025-03-01 Epub Date: 2025-01-21 DOI:10.1016/j.apradiso.2024.111653

Annesha Karmakar , Anikesh Pal , G. Anil Kumar , Bhavika , Vivek , Mohit Tyagi

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Abstract

This study shows an implementation of neutron-gamma pulse shape discrimination (PSD) using a two-dimensional convolutional neural network. The inputs to the network are snapshots of the unprocessed, digitized signals from a BC501A detector. By exposing a BC501A detector to a Cf-252 source, neutron and gamma signals were collected to create a training dataset. The realistic datasets were created using a data-driven approach for labeling the digitized signals, having classified snapshots of neutron and gamma pulses. Our algorithm was able to successfully differentiate neutrons and gammas with similar accuracy as the Charge Integration (CI) approach. Additionally, the independent dataset accuracy for our suggested 2D CNN-based PSD approach is 99%. In contrast to the traditional charge integration method, our suggested algorithm with data augmentation, is capable of extracting features from snapshots of the raw data based on the signal structures, making it computationally more efficient and also appropriate for other types of neutron detectors.

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基于二维CNN图像分类的有机闪烁探测器中子-伽马脉冲形状识别。

本研究展示了一种利用二维卷积神经网络实现中子-伽马脉冲形状识别（PSD）的方法。网络的输入是来自BC501A检测器的未处理的数字化信号的快照。通过将BC501A探测器暴露于Cf-252源，收集中子和伽马信号以创建训练数据集。实际数据集是使用数据驱动方法创建的，用于标记数字化信号，具有中子和伽马脉冲的分类快照。我们的算法能够成功地区分中子和伽马与类似的精度电荷积分（CI）方法。此外，我们建议的基于2D cnn的PSD方法的独立数据集精度为99%。与传统的电荷积分方法相比，我们提出的数据增强算法能够根据信号结构从原始数据的快照中提取特征，使其计算效率更高，也适用于其他类型的中子探测器。

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来源期刊

Applied Radiation and Isotopes 工程技术-核科学技术

CiteScore

3.00

自引率

12.50%

发文量

406

审稿时长

13.5 months

期刊介绍： Applied Radiation and Isotopes provides a high quality medium for the publication of substantial, original and scientific and technological papers on the development and peaceful application of nuclear, radiation and radionuclide techniques in chemistry, physics, biochemistry, biology, medicine, security, engineering and in the earth, planetary and environmental sciences, all including dosimetry. Nuclear techniques are defined in the broadest sense and both experimental and theoretical papers are welcome. They include the development and use of α- and β-particles, X-rays and γ-rays, neutrons and other nuclear particles and radiations from all sources, including radionuclides, synchrotron sources, cyclotrons and reactors and from the natural environment. The journal aims to publish papers with significance to an international audience, containing substantial novelty and scientific impact. The Editors reserve the rights to reject, with or without external review, papers that do not meet these criteria. Papers dealing with radiation processing, i.e., where radiation is used to bring about a biological, chemical or physical change in a material, should be directed to our sister journal Radiation Physics and Chemistry.