Development of Superconducting Tunnel Junction detectors as a far-infrared photon-by-photon spectrometer for neutrino decay search

2015 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) Proceedings Pub Date : 2015-05-11 DOI:10.1109/I2MTC.2015.7151327

Y. Takeuchi, S. Kim, K. Takemasa, K. Kiuchi, K. Nagata, K. Kasahara, T. Okudaira, Tatsuya Ichimura, Masahiro Kanamaru, Kouya Moriuchi, Ren Senzaki, S. Yagi, H. Ikeda, S. Matsuura, T. Wada, Takuo Yoshida, S. Komura, Keisuke Orikasa, Ryuta Hirose, Y. Kato, M. Hazumi, Y. Arai, S. Shiki, M. Ukibe, G. Fujii, T. Adachi, M. Ohkubo, E. Ramberg, Jonghee Yoo, M. Kozlovsky, P. Rubinov, D. Sergatskov, H. Ishino, A. Kibayashi, S. Mima, Soo-Bong Kim

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引用次数: 2

Abstract

We present the development of Superconducting Tunnel Junction (STJ) detectors as a far-infrared single photon spectrometer, which is motivated for an application to a search for the radiative decay of the cosmic neutrino background (CνB). The photon energy spectrum from the radiative decays of CνB is expected to have a sharp edge at high energy end in a far-infrared region ranging from 14 meV to 25 meV (from 50 μm to 90 μm in wavelength) in the cosmic infrared background and the overwhelming infrared foreground from the zodiacal emission. Thus, the detector is required photon-by-photon detection with sufficiently high energy resolution, in order to gain the best signal-to-noise ratio as well as to identify the edge structure. The following two types of photon detectors are under consideration: an array of niobium/aluminum STJ (Nb/Al-STJ) pixels with a diffraction grating, and STJ using hafnium (Hf-STJ). Each Nb/Al-STJ pixel is required to be capable of detecting single photons in the far-infrared region, and the pixel array measures the photon wavelength spectrum which the diffraction grating creates. Hf-STJ is expected to achieve 2% energy resolution for single photon of 25 meV due to very small gap energy of hafnium.

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用于中微子衰变搜索的远红外光子-光子光谱仪超导隧道结探测器的研制

我们提出了超导隧道结(STJ)探测器作为远红外单光子光谱仪的发展，其动机是应用于寻找宇宙中微子背景(CνB)的辐射衰变。CνB辐射衰减的光子能谱在宇宙红外背景和黄道带发射的压倒性红外前景中，在14 ~ 25 meV(波长从50 μm到90 μm)的远红外区域的高能端有一个锋利的边缘。因此，为了获得最佳的信噪比以及识别边缘结构，探测器需要具有足够高的能量分辨率的光子对光子检测。以下两种类型的光子探测器正在考虑中:一种是带有衍射光栅的铌/铝STJ (Nb/Al-STJ)像素阵列，另一种是使用铪(Hf-STJ)的STJ。每个Nb/Al-STJ像元被要求能够探测远红外区域的单个光子，并且像元阵列测量衍射光栅产生的光子波长光谱。由于铪的间隙能量非常小，预计Hf-STJ在25 meV的单光子中可以达到2%的能量分辨率。

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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2015 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) Proceedings

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