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Paper detail

Transition edge sensor based detector: from X-ray to $γ$-ray

The Transition Edge Sensor is extremely sensitive to the change of temperature, combined with the high-Z metal of a certain thickness, it can realize the high energy resolution measurement of particles such as X-rays. X-rays with energies below 10 keV have very weak penetrating ability, so only a few microns thick of gold or bismuth can obtain quantum efficiency higher than 70\%. Therefore, the entire structure of the TES X-ray detector in this energy range can be realized in the microfabrication process. However, for X-rays or gamma rays from 10 keV to 200 keV, sub-millimeter absorber layers are required, which cannot be realized by microfabrication process. This paper first briefly introduces a set of TES X-ray detectors and their auxiliary systems built by ShanghaiTech University, then focus on the introduction of the TES $γ$-ray detector, with absorber based on an sub-millimeter lead-tin alloy sphere. The detector has a quantum efficiency above 70\% near 100 keV, and an energy resolution of about 161.5eV@59.5keV.

preprint2022arXivOpen access
Shuo ZhangJing-Kai XiaTao SunWen-Tao WuBing-Jun WuYong-Liang WangRobin CantorKe HanXiao-Peng ZhouHao-Ran LiuFu-You FanSi-Ming GuoJun-Cheng LiangDe-Hong LiYan-Ru SongXu-Dong JuQiang FuZhi Liu
physics.ins-detastro-ph.IM
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Shuo ZhangJing-Kai XiaTao SunWen-Tao WuBing-Jun WuYong-Liang WangRobin CantorKe HanXiao-Peng ZhouHao-Ran LiuFu-You FanSi-Ming GuoJun-Cheng LiangDe-Hong LiYan-Ru SongXu-Dong JuQiang FuZhi Liu

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