Muon scattering tomography with resistive plate chambers

2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record (NSS/MIC) Pub Date : 2012-10-01 DOI:10.1109/NSSMIC.2012.6551060

P. Baesso, D. Cussans, Paul Glaysher, C. Thomay, J. Velthuis, Caroline Vassallo

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引用次数: 19

Abstract

Muon Scattering Tomography is a scanning technique which uses cosmic muons as probes to gather information on the content of the inspected volume. Because the scattering angle depends on the Z2 of the materials in the volume, it is possible to obtain a 3D image of the volume content by carefully tracking the muon paths. This has very interesting potential applications in several fields, from engineering to homeland security, where MST could be used to inspect shipping containers and trucks in search of special nuclear materials (SNM). For such applications to be feasible it is necessary to have large area detectors (10-100 square meters) while maintaining the efficiency and angular resolution necessary to discriminate between low-Z and high-Z materials. Resistive Plate Chambers (RPCs) are very good candidates. RPCs are widely adopted in high energy physics experiments thanks to their excellent performance in terms of time resolution, charged particle detection efficiency and low cost per unit area. In collaboration with the UK Atomic Weapon Establishment we have built and tested a prototype based on 12 RPCs (50 cm × 50 cm). To obtain the required spatial resolution we adopted a novel approach for the RPC readout, coupling each detector with 300 fine pitch strips (1.5 mm) and using multiplexing analog readout chips to reduce the amount of readout channels. The prototype performs very well: all the chambers have efficiency above 99% and purity above 95%. The signal-to-noise for the electronic readout ranges from 25 to 90. The spatial resolution for the layers is better than 1 mm and we show that this is sufficient to successfully image a block of lead of 10 cm × 10 cm × 15 cm. We are now in the process of upgrading the electronics with new ASICs which feature built-in ADCs. The first test

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电阻板室的介子散射层析成像

介子散射层析成像是一种扫描技术，它使用宇宙介子作为探测器来收集有关被检查体积内容的信息。由于散射角取决于体积中材料的Z2，因此通过仔细跟踪μ子路径可以获得体积内容的3D图像。这在几个领域有非常有趣的潜在应用，从工程到国土安全，MST可以用来检查集装箱和卡车，以寻找特殊核材料(SNM)。对于这样的应用是可行的，有必要有大面积的探测器(10-100平方米)，同时保持效率和角分辨率需要区分低z和高z材料。电阻板室(rpc)是非常好的候选者。rpc具有时间分辨率高、带电粒子检测效率高、单位面积成本低等优点，在高能物理实验中得到广泛应用。在与英国原子武器机构的合作中，我们已经建造并测试了基于12个rpc(50厘米× 50厘米)的原型。为了获得所需的空间分辨率，我们采用了一种新颖的RPC读出方法，将每个检测器与300个细间距条带(1.5 mm)耦合，并使用多路复用模拟读出芯片来减少读出通道的数量。样机的性能非常好:所有的腔室效率都在99%以上，纯度在95%以上。电子读数的信噪比范围从25到90。这些层的空间分辨率优于1毫米，我们表明这足以成功成像10厘米× 10厘米× 15厘米的铅块。我们现在正在用内置adc的新型asic升级电子产品。第一个测试

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2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record (NSS/MIC)

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