Collaborative Research: Beta-decay Angular Correlation Measurements with Cold and Ultracold Neutrons

合作研究：用冷和超冷中子进行β衰变角相关测量

• 批准号: 1306997
• 负责人: ROBERT VOGELAAR
• 金额: $ 10.5万
• 依托单位: Virginia Polytechnic Institute and State University
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2013
• 资助国家: 美国
• 起止时间: 2013-08-01 至 2017-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1306997&HistoricalAwards=false
• 关键词: Collaborative; Research; Beta; decay; Angular

This award funds a collaborative research program involving two separate angular correlation measurements with neutrons. These measurements will enable us to extract fundamental information concerning the weak interaction which causes neutron decay, including the axial coupling constant of the nucleon. This coupling constant appears in a very wide variety of nuclear and particle physics contexts, from being a critical input to high precision calculations of the solar fusion rates, to being a target for higher precison lattice QCD calculations, to placing, together with the neutron lifetime, limits on the existence of new particle physics interactions.The first experiment, UCNA, measures the beta-asymmetry, or the correlation between the neutron polarization and the decay beta-particle's momentum. UCNA is the first experiment to use ultracold neutrons, or neutrons with energies below about 300 neV that can be stored in material bottles, for this kind of measurement. Ultracold neutrons have advantages both for neutron polarimetry and neutron-generated backgrounds, key sources of systematic error in existing neutron angular correlation experiments. The UCNA experiment is currently operating, with one more run period planned at the neutron densities currently available at the Los Alamos ultracold neutron source. The targeted precision is below 0.4%, roughly a factor of 2 more precise than the current world average for the beta-asymmetry. The second experiment, Nab, uses an unpolarized beam of cold neutrons (with temperatures near 30K) to measure the electron-neutrino angular correlation, with a planned sensitivity at about the 0.1% level for the electron-neutrino correlation. This experiment should also be able to place important limits on extensions to the standard model of particle physics for scalar andtensor couplings.Key to the success of these experiments is the involvement of undergraduate and graduate students, as well as postdoctoral scholars. These young scientists will receive excellent training in experimental techniques, particle detectors, and data analysis.

该奖项资助了一项合作研究计划，涉及两个独立的中子角相关测量。 这些测量将使我们能够提取有关导致中子衰变的弱相互作用的基本信息，包括核子的轴向耦合常数。这个耦合常数出现在非常广泛的核物理和粒子物理背景下，从作为太阳聚变速率的高精度计算的关键输入，到作为更高精度晶格QCD计算的目标，再到与中子寿命一起限制新粒子物理相互作用的存在。第一个实验UCNA测量β不对称性，或者中子极化和衰变β粒子动量之间的相关性。UCNA是第一个使用超冷中子或能量低于300 neV的中子进行这种测量的实验，这些中子可以储存在材料瓶中。 超冷中子在中子极化测量和中子产生的本底方面都具有优势，这是现有中子角相关实验中系统误差的主要来源。 UCNA实验目前正在运行，计划在洛斯阿拉莫斯超冷中子源目前可用的中子密度下再运行一个周期。 目标精度低于0.4%，比当前β不对称性的世界平均精度高出约2倍。第二个实验Nab使用非极化冷中子束（温度接近30 K）测量电子-中微子角相关，计划灵敏度约为0.1%。这个实验也应该能够对标量和张量耦合的粒子物理标准模型的扩展施加重要的限制。这些实验成功的关键是本科生和研究生以及博士后学者的参与。 这些年轻的科学家将在实验技术、粒子探测器和数据分析方面接受出色的培训。