论文标题
对宾果创新的首次低温测试
First cryogenic tests on BINGO innovations
论文作者
论文摘要
中微子双β衰减($ 0 \nu2β$)是一个假设的稀有核转变。它的观察结果将提供有关中微子(Dirac或Majoraana粒子)性质的重要见解,表明Lepton数量不能保守。宾果游戏(Bi-Esotope $ 0 \nu2β$下一代天文台)旨在为将来的降压器$ 0 \ nu2- $实验设定技术理由。它基于双重光线读数,即嵌入双β衰减同位素的主要闪烁吸收器以及伴随着低温光检测器。宾果游戏将研究两个最有前途的同位素:$^{100} $ mo嵌入在li $ _2 $ _2 $ moo $ _4 $(lmo)晶体和$^{130} $ teo $ _2 $中。宾果技术将大大减少感兴趣区域的背景,从而提高发现灵敏度$ 0 \nu2β$。所提出的解决方案将对下一代隆重计量尺度实验(如丘比特)产生很大的影响。在此贡献中,我们介绍了在宾果R&D框架中进行的第一个测试中获得的结果。
Neutrinoless double-beta decay ($0\nu2β$) is a hypothetical rare nuclear transition. Its observation would provide an important insight about the nature of neutrinos (Dirac or Majorana particle) demonstrating that the lepton number is not conserved. BINGO (Bi-Isotope $0\nu2β$ Next Generation Observatory) aims to set the technological grounds for future bolometric $0\nu2β$ experiments. It is based on a dual heat-light readout, i.e. a main scintillating absorber embedding the double-beta decay isotope accompanied by a cryogenic light detector. BINGO will study two of the most promising isotopes: $^{100}$Mo embedded in Li$_2$MoO$_4$ (LMO) crystals and $^{130}$Te embedded in TeO$_2$. BINGO technology will reduce dramatically the background in the region of interest, thus boosting the discovery sensitivity of $0\nu2β$. The proposed solutions will have a high impact on next-generation bolometric tonne-scale experiments, like CUPID. In this contribution, we present the results obtained during the first tests performed in the framework of BINGO R&D.
