Collaborative Research: The DarkSide Dark-Matter Search Using Liquid Argon

合作研究：使用液氩进行暗物质搜索

• 批准号: 2310047
• 负责人: ROBERT VOGELAAR
• 金额: $ 70.5万
• 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: 2023
• 资助国家: 美国
• 起止时间: 2023-09-01 至 2026-08-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2310047&HistoricalAwards=false
• 关键词: Collaborative; Research; DarkSide; Dark; Matter

A large body of astronomical observations, including galactic rotation curves, strong gravitational lensing, and the anisotropy of the cosmic microwave background, indicates that known matter only accounts for a small fraction of the observed mass-energy of the Universe. A strong candidate for the remaining mass is weakly interacting Dark Matter particles with properties different from ordinary matter. Direct (non-gravitational) detection of dark matter would be a transformational discovery and would represent a watershed moment in the history of science, opening the gates to the investigation of the dark universe. The goal of this award is the testing, on-site installation, commissioning, and transitioning to operations of DarkSide-20k (DS-20k), an experiment capable of pushing the sensitivity of direct dark matter searches beyond that of any current or presently funded experiment. Broader scientific and technological impacts from the project include, among others: the production of low-radioactivity underground argon (UAr) for DS-20k and for nuclear test ban verification and radiometric dating; the continued study of the underground gas source discovered during the UAr exploration, a source which supplies 15 % of the current U.S. helium consumption; and the continued development of 3Dπ, a LAr-based TOF-PET system that can enhance cancer screening while lowering radiation dose.A leading dark matter candidate is a weakly interacting massive particle, or WIMP, a thermal relic of the Big Bang that has a sub-electroweak-scale self-annihilation cross section and a mass in the GeV/c2 to TeV/c2 range. The motion of galactic halo WIMPs relative to a detector on Earth could result in WIMP-nucleus elastic collisions detectable by a low-background, low-energy-threshold detector capable of unambiguously identifying a small number of nuclear recoils from WIMP collisions over the course of a very large exposure. Thanks to its excellent ionization response and unique scintillation light emission characteristics, liquid argon can provide outstanding sensitivity for WIMP-nuclear collisions and strong background suppression. The U.S. NSF groups involved in this program have led the conception and development of the DarkSide-20k liquid argon dark matter search. With support from a separate Mid-scale award, they are responsible for the construction and delivery of the most critical DS-20k components: the liquid argon time projection chamber (LAr TPC) that serves as the heart of the DS-20k dark matter detector along with its critical ancillary components, including the high-voltage delivery system, and the associated cryogenic, purification, and calibration systems. The U.S. NSF groups are also leading the activities for the procurement of the required ultra-low radioactivity argon, which is extracted from a special underground source in Colorado, with support from other US and international funding agencies (U.S. Department of Energy, Istituto Nazionale di Fisica Nucleare of Italy, and Canada Foundation for Innovation). This award will support the U.S. groups for the final testing, on-site installation, commissioning, and transition to operations of the DS-20k detector and preparation for science analyses. The DarkSide-20k experiment will utilize a two-phase time projection chamber with a 50-tonne fill (20-tonne fiducial) to extend the exploration for dark matter, reaching, in a 10 years run, a cross section of 4.9×10−48 cm2 for a 90 % C.L. exclusion and 1.6×10−47 cm2 at a 5 σ discovery significance for a 1 TeV/c2 WIMP, well beyond any current or presently funded experiment. This will lead to either discovery, confirmation, or exclusion of the WIMP dark matter hypothesis down to the level where coherent scatters from atmospheric neutrinos become an unavoidable background. DarkSide-20k will also be sensitive to a galactic supernova neutrino burst originating anywhere in the Milky Way Galaxy.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

大量的天文观测，包括星系旋转曲线、强引力透镜和宇宙微波背景的各向异性，表明已知物质只占宇宙观测到的质能的一小部分。剩余质量的一个强有力的候选者是弱相互作用的暗物质粒子，其性质不同于普通物质。对暗物质的直接（非引力）探测将是一个变革性的发现，并将代表科学史上的一个分水岭，为暗宇宙的研究打开大门。该奖项的目标是测试，现场安装，调试和过渡到DarkSide-20 k（DS-20 k）的操作，该实验能够推动直接暗物质搜索的灵敏度超过任何当前或目前资助的实验。 该项目产生的更广泛的科学和技术影响包括：为DS-20 k生产低放射性地下氩（UAr），并用于核禁试核查和放射性测年;继续研究在UAr勘探期间发现的地下气源，该气源供应美国目前氦消费量的15%;以及3Dπ的持续发展，这是一种基于LAr的TOF-PET系统，可以在降低辐射剂量的同时增强癌症筛查。一个领先的暗物质候选者是一种弱相互作用大质量粒子，或称WIMP，大爆炸的热遗迹，具有亚电弱尺度的自湮灭截面，质量在GeV/c2到TeV/c2范围内。银河系晕WIMP相对于地球上的探测器的运动可能导致WIMP与核的弹性碰撞，这种碰撞可以被低背景、低能量阈值的探测器探测到，该探测器能够在非常大的曝光过程中明确地识别出WIMP碰撞产生的少量核反冲。由于其优异的电离响应和独特的闪烁发光特性，液态氩可以为WIMP核碰撞提供出色的灵敏度和强背景抑制。参与该计划的美国NSF小组领导了DarkSide-20 k液态氩暗物质搜索的概念和发展。在另一个中型项目的支持下，他们负责建造和交付DS-20 k最关键的组件：作为DS-20 k暗物质探测器核心的液氩时间投影室（LAr TPC）沿着关键辅助组件，包括高压输送系统，以及相关的低温，纯化和校准系统。美国国家科学基金会各小组还在其他美国和国际供资机构（美国能源部、意大利国家核裂变研究所和加拿大创新基金会）的支助下，牵头采购所需的超低放射性氩，氩是从科罗拉多的一个特殊地下来源提取的。该合同将支持美国团队进行DS-20 k探测器的最终测试、现场安装、调试和过渡操作，并为科学分析做好准备。DarkSide-20 k实验将使用一个50吨填充的两相时间投影室（20吨基准）来扩展对暗物质的探索，在10年的运行中，达到4.9×10−48 cm 2的横截面，90% C. L。排除和1.6×10−47 cm 2在5 σ发现意义的1 TeV/c2 WIMP，远远超过任何目前或目前资助的实验。这将导致WIMP暗物质假说的发现、确认或排除，直到大气中微子的相干散射成为不可避免的背景。DarkSide-20 k还将对起源于银河系任何地方的银河系超新星中微子爆发敏感。该奖项反映了NSF的法定使命，并通过使用基金会的智力价值和更广泛的影响审查标准进行评估，被认为值得支持。