The ASTAROTH project

LOW RADIOACTIVITY TECHNIQUES 2022 (LRT 2022): Proceedings of the 8th International Workshop on Low Radioactivity Techniques Pub Date : 2022-11-04 DOI:10.1063/5.0161723

D. D’Angelo, A. Zani, F. Alessandria, A. Andreani, A. Castoldi, S. Coelli, D. Cortis, G. D. Carlo, L. Frontini, N. Gallice, C. Guazzoni, V. Liberali, M. Monti, D. Orlandi, M. Sorbi, A. Stabile, M. Statera

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Abstract

The most discussed topic in direct search for dark matter is arguably the verification of the DAMA claim. In fact, the observed annual modulation of the signal rate in an array of NaI(Tl) detectors can be interpreted as the awaited signature of dark matter interaction. Several experimental groups are currently engaged in the attempt to verify such a game-changing claim with the same target material. However, all present-day designs are based on a light readout via Photomultiplier Tubes, whose high noise makes it challenging to achieve a low background in the 1-6 keV energy region of the signal. Even harder it would be to break below 1 keV energy threshold, where a large fraction of the signal potentially awaits to be uncovered. ASTAROTH is an R\&D project to overcome these limitations by using Silicon Photomultipliers (SiPM) matrices to collect scintillation light from NaI(Tl). The all-active design based on cubic crystals is operating in the 87-150 K temperature range where SiPM noise can be even a hundred times lower with respect to PMTs. The cryostat was developed following an innovative design and is based on a copper chamber immersed in a liquid argon bath that can be instrumented as a veto detector. We have characterized separately the crystal and the SiPM response at low temperature and we have proceeded to the first operation of a NaI(Tl) crystal read by SiPM in cryogeny.

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ASTAROTH项目

在直接寻找暗物质的过程中，讨论最多的话题是DAMA理论的验证。事实上，在NaI(Tl)探测器阵列中观测到的信号速率的年调制可以解释为期待已久的暗物质相互作用的特征。几个实验小组目前正试图用同样的目标材料来验证这样一个改变游戏规则的说法。然而，目前所有的设计都是基于光电倍增管的光读出，其高噪声使得在信号的1-6 keV能量区域实现低背景具有挑战性。更困难的是突破1千电子伏特以下的能量阈值，在这个阈值下，很大一部分信号可能等待被发现。ASTAROTH是一个研发项目，通过使用硅光电倍增管(SiPM)矩阵来收集来自NaI(Tl)的闪烁光来克服这些限制。基于立方晶体的全主动设计在87-150 K温度范围内工作，其中SiPM噪声可以比pmt低100倍。低温恒温器采用了一种创新的设计，它是基于浸在液态氩浴中的铜腔，可以作为否决权探测器。我们分别对晶体和SiPM在低温下的响应进行了表征，并进行了SiPM在低温下读取NaI(Tl)晶体的第一次操作。

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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LOW RADIOACTIVITY TECHNIQUES 2022 (LRT 2022): Proceedings of the 8th International Workshop on Low Radioactivity Techniques

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