数字式微型阴极射线磁力计

Q3 Physics and Astronomy Instruments Pub Date : 2024-04-24 DOI:10.3390/instruments8020029
Marcos Turqueti, Gustav Wagner, Azriel Goldschmidt, Rebecca Carney
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引用次数: 0

摘要

在本研究中,我们介绍了一种创新型数字微型阴极射线磁力计的概念和构造,该磁力计专为精确检测磁场而设计。该装置解决了磁性探头固有的几个局限性,如直流偏移、非线性、温度漂移、传感器老化和需要经常重新校准,同时还能在广泛的磁场中工作。该设备的核心原理是利用带电粒子束作为灵敏度介质。该系统利用电子束与闪烁体材料的相互作用,闪烁体材料会发出可见光,然后被成像仪捕捉。发射的闪烁光由 CMOS 传感器捕捉。该传感器不仅能记录闪烁光,还能准确确定电子束的位置,从而提供对磁场绘图至关重要的宝贵空间信息。创新的关键在于将电子束投影、基于闪烁的 CMOS 相机检测和数字图像信号处理结合在一起。通过这种协同作用,磁强计实现了卓越的精度、灵敏度和动态范围。CMOS 传感器实现的精确位置登记功能进一步增强了该装置在捕捉复杂磁场模式方面的实用性,从而可以绘制二维磁场图。在这项工作中,对探头性能的优化是针对光源中插入设备(包括起爆器)的表征应用而量身定制的。
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Digital Miniature Cathode Ray Magnetometer
In this study, we introduce the concept and construction of an innovative Digital Miniature Cathode Ray Magnetometer designed for the precise detection of magnetic fields. This device addresses several limitations inherent to magnetic probes such as D.C. offset, nonlinearity, temperature drift, sensor aging, and the need for frequent recalibration, while capable of operating in a wide range of magnetic fields. The core principle of this device involves the utilization of a charged particle beam as the sensitivity medium. The system leverages the interaction of an electron beam with a scintillator material, which then emits visible light that is captured by an imager. The emitted scintillation light is captured by a CMOS sensor. This sensor not only records the scintillation light but also accurately determines the position of the electron beam, providing invaluable spatial information crucial for magnetic field mapping. The key innovation lies in the combination of electron beam projection, CMOS imager scintillation-based detection, and digital image signal processing. By employing this synergy, the magnetometer achieves remarkable accuracy, sensitivity and dynamic range. The precise position registration enabled by the CMOS sensor further enhances the device’s utility in capturing complex magnetic field patterns, allowing for 2D field mapping. In this work, the optimization of the probe’s performance is tailored for applications related to the characterization of insertion devices in light sources, including undulators.
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来源期刊
Instruments
Instruments Physics and Astronomy-Instrumentation
CiteScore
2.60
自引率
0.00%
发文量
70
审稿时长
11 weeks
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