Collaborative Research: The MuLan Project-Development of instrumentation for a new high-precision determination of the Fermi coupling constant

合作研究：木兰计划——开发用于新型高精度测定费米耦合常数的仪器

• 批准号: 0079735
• 负责人: David Hertzog
• 金额: $ 37万
• 依托单位: University of Illinois at Urbana-Champaign
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2000
• 资助国家: 美国
• 起止时间: 2000-08-15 至 2005-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0079735&HistoricalAwards=false
• 关键词: Collaborative; Research; MuLan; Project; Development

0079735Hertzog The MuLan Project will develop the instrumentation needed to measure the lifetime of the positive muon to unprecedented precision, namely, a factor of 20 better than the current world average. The muon lifetime fixes the value of the Fermi constant, which governs the strength of all weak-interaction processes, just as the fine structure constant governs the strength of allelectromagnetic-interaction processes. The Fermi constant is one of the fundamental parameters of the Standard Model of particlephysics. A low-energy, continuous-wave muon beam at the Paul Scherrer Institute (PSI) in Switzerland will be modified by a new beam chopper system in order to create intense, short bursts of muons, which will stop in thin targets. A positive muon stopped inappropriate materials decays as if it were in vacuum. Such targets will be surrounded by a nearly hermetic set of 180 fast-scintillator timing detectors, each coupled to a state-of-the-art waveform digitizer, and all readout by a high-speed data acquisition system. Online analysis of the nearly 100 terabytes of data will take place with a small array of fast microprocessors. A second use of the instrumentation is in conjunction with an ongoing effort at PSI to measure the negative muon lifetime inhydrogen gas. The negative muon can decay exactly in the same manner as the positive muon, or in hydrogen it can interact with aproton by the weak-interaction process known as "capture." The capture rate is predicted very accurately by theory; however,current experiments, which have various interpretation problems, are in disagreement with theory by a very significant amount. Ifthis disagreement is confirmed, this difference raises the exciting possibility of pointing to new and unaccounted for physics. Bymeasuring the difference between the positive and negative muon lifetimes, we will determine the muon capture rate reliably and at aprecision more than four times better than current measurements. The MuLan timing detectors, beamline and custom electronics areexpected to play a major role in this effort.

0079735 Hertzog MuLan项目将开发测量正μ子寿命所需的仪器，以达到前所未有的精度，即比目前世界平均水平高出20倍。 μ子寿命决定了费米常数的值，费米常数决定了所有弱相互作用过程的强度，就像精细结构常数决定了所有电磁相互作用过程的强度一样。 费米常数是粒子物理标准模型的基本参数之一。 瑞士Paul Scherrer研究所（PSI）的低能量连续波μ子束将被一个新的束流斩波器系统修改，以产生强烈的短μ子脉冲，这些脉冲将在薄目标中停止。 一个正的μ介子阻止了不合适的物质的衰变，就好像它在真空中一样。 这些目标将被一组几乎密封的180个快速闪烁体定时探测器包围，每个探测器都连接到一个最先进的波形数字化仪，所有数据都由一个高速数据采集系统读出。 对近100 TB数据的在线分析将通过一小批快速微处理器进行。 仪器的第二个用途是与PSI正在进行的测量氢气中负μ子寿命的工作相结合。 负μ子的衰变方式与正μ子的衰变方式完全相同，或者在氢中，它可以通过称为“俘获”的弱相互作用过程与质子相互作用。“理论预测的捕获率非常准确;然而，目前的实验存在各种解释问题，与理论存在非常大的差异。 如果这种分歧得到证实，这种差异就提出了一种令人兴奋的可能性，即指向新的、无法解释的物理学。 通过测量正负μ子寿命之间的差异，我们将可靠地确定μ子捕获率，其精确度比目前的测量结果高出四倍以上。 穆兰定时探测器、光束线和定制电子设备预计将在这项工作中发挥重要作用。