A Disc-DIRC Cherenkov detector with high resolution micro channel plate photomultiplier tubes

2014 IEEE Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC) Pub Date : 2014-11-01 DOI:10.1109/NSSMIC.2014.7431161

J. Rieke, M. Duren, E. Etzelmuller, K. Fohl, A. Hayrapetyan, B. Krock, O. Merle, R. Dzhygadlo, A. Gerhardt, K. Gotzen, G. Kalicy, M. Krebs, H. Kumawat, D. Lehmann, M. Patsyuk, K. Peters, G. Schepers, L. Schmitt, C. Schwarz, J. Schwiening, M. Traxler, M. Zuhlsdorf, V. Dodokhov, F. Uhlig, A. Britting, W. Eyrich, A. Lehmann, E. Cowie, T. Keri, R. Montgomery, P. Achenbach, M. Cardinali, M. Hoek, W. Lauth, S. Schlimme, C. Sfienti, M. Thiel, P. Buhler, L. Gruber, J. Marton, K. Suzuki

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引用次数: 1

Abstract

The upcoming PANDA Experiment at FAIR in Germany will be equipped with a novel Cherenkov detector type for high-energy particle identification. This very compact Disc-DIRC detector uses a large disc-shaped fused silica plate of 2 cm thickness as its Cherenkov radiator. The internally reflected Cherenkov light is transported to the rim of the disc where it is focused by quartz light guides onto microchannel plate photomultiplier tubes (MCP-PMTs) with high spatial resolution (pitch 0.5 mm) and high time resolution (σ ≈ 100 ps). The device has an active area of about 3 m2 and will be able to identify pions and kaons with a separation power of more than 3σ in the momentum range up to 4 GeV/c. It has 32400 individual pixels and each can handle a mean photon rate of up to about 100 kHz. The presented design deals with numerous challenges that come with the very hostile environment in which the detector has to function properly, caused by the presence of high magnetic fields of up to 2 Tesla, high levels of radiation, high particle and background rates and a tight spatial volume. First test measurements have shown the performance of the design.

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具有高分辨率微通道板光电倍增管的Disc-DIRC切伦科夫探测器

即将在德国FAIR举行的PANDA实验将配备一种新型切伦科夫探测器，用于高能粒子的识别。这款非常紧凑的Disc-DIRC探测器使用2厘米厚的大圆盘状熔融硅板作为切伦科夫散热器。内部反射的切伦科夫光被传输到光盘的边缘，在那里它被石英光导聚焦到具有高空间分辨率(间距0.5 mm)和高时间分辨率(σ≈100 ps)的微通道板光电倍增管(mcp - pmt)上。该装置的有效面积约为3 m2，能够在高达4 GeV/c的动量范围内识别分离功率大于3σ的介子和介子。它有32400个单独的像素，每个像素可以处理高达约100千赫的平均光子速率。所提出的设计处理了许多挑战，这些挑战来自于非常恶劣的环境，在这种环境中，探测器必须正常工作，这是由高达2特斯拉的高磁场、高水平的辐射、高粒子和背景速率以及紧凑的空间体积造成的。第一次测试测量显示了设计的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2014 IEEE Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC)

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