Collaborative Research: Measuring G with a Microsphere in a Magneto-Gravitational Trap
合作研究:用磁引力阱中的微球测量 G
基本信息
- 批准号:1707678
- 负责人:
- 金额:$ 2.95万
- 依托单位:
- 依托单位国家:美国
- 项目类别:Standard Grant
- 财政年份:2017
- 资助国家:美国
- 起止时间:2017-05-01 至 2021-04-30
- 项目状态:已结题
- 来源:
- 关键词:
项目摘要
The gravitational constant of the universe "G" sets the strength of gravity both in Newton's and Einstein's theories of gravity. But despite its central importance to our understanding of gravity, experiments over the past 20 years have led to measurements of G that disagree enormously beyond the reported errors. Are these discrepancies evidence of a non-constant G, reflective of some new gravitational theory beyond Einstein, or are they simply due to misunderstandings of experimental errors? To tackle this question, we are undertaking an effort toward a fundamentally new experimental design for measuring G, which involves a magnetically-suspended, micron-diameter sphere that oscillates back and forth in a magnetic trap. The oscillation frequency will shift due to the introduction of carefully-machined masses placed near the oscillating sphere, and we expect our measure of this frequency shift will determine G to about ten parts in a million--on par with other state-of-the-art experiments, but with largely independent, and hopefully better-understood sources of error.We propose measuring G, the Newtonian gravitational constant, using a novel experimental setup. The measurement approach is based on the time-of-swing method, where a pair of field masses modifies the spring constant, and thus the oscillation frequency, of a simple harmonic oscillator. The unique feature of the proposed approach is that the simple harmonic oscillator consists of a microsphere levitated in a magnetic trap in ultra-high vacuum. This system has several features that make it uniquely suited to precision measurements, including a low oscillation frequency, ultra-high quality factor (Q), and multiple degrees of freedom for compensation of drift in the oscillation frequency. One of the key challenges in the experimental design is stabilizing or compensating the oscillation frequencies so frequency shifts can be resolved well enough to measure G to 10 ppm. Thus, the first year will be dedicated to optimizing the experimental design to this end, with a goal of presenting a proof of principle for this novel approach, as well as a path forward to performing the state-of-the-art measurement of G. The proposed strategy has also been chosen to minimize the systematic errors that have plagued other measurements of G. First, the time-of-swing method is simple to analyze, with zero first-order sensitivity to misalignment. Second, most of the recorded data will be taken in the form of precisely time-stamped images of the particle, which can be analyzed and reanalyzed as needed. Third, all data will be made freely available for other groups to study, analyze, and compare with our reported results. This will ensure that there is confidence in the new measurement despite disagreement among past measurements of G.
在牛顿和爱因斯坦的引力理论中,宇宙的引力常数“G”决定了引力的强度。但是,尽管它对我们对引力的理解至关重要,但过去20年的实验已经导致了对G的测量,除了报告的误差之外,它的测量结果存在巨大的不一致。这些差异是非常数G的证据,反映了爱因斯坦之外的一些新的引力理论,还是仅仅是因为对实验错误的误解?为了解决这个问题,我们正在致力于一种全新的测量G的实验设计,它包括一个磁悬浮的微米直径的球体,它在磁捕获器中来回振荡。由于在振荡球附近引入了精心加工的质量,振荡频率将发生变化,我们预计我们对这种频移的测量将确定G到百万分之十--与其他最先进的实验一样,但有很大程度上独立的、有望更好地理解的误差来源。我们建议使用一种新的实验装置来测量G,牛顿引力常数。这种测量方法是基于摆动时间法,在这种方法中,一对场质量修改了简谐振荡器的弹簧常数,从而修改了振荡频率。该方法的独特之处在于,简谐振子是由一个悬浮在超高真空中的磁陷阱中的微球组成的。该系统具有几个独特的特点,使其特别适合精密测量,包括低振荡频率、超高品质因数(Q)以及用于补偿振荡频率漂移的多个自由度。实验设计中的关键挑战之一是稳定或补偿振荡频率,这样频率漂移就可以很好地解决,测量G到10ppm。因此,第一年将致力于为此目的优化实验设计,目的是为这一新方法提供原理证明,以及执行最先进的G测量的前进道路。建议的策略也被选择为将困扰G的其他测量的系统误差降至最低。首先,摆动时间方法分析简单,对未对准的一阶灵敏度为零。其次,大多数记录的数据将以粒子的精确时间戳图像的形式获取,这些图像可以根据需要进行分析和重新分析。第三,所有数据将免费提供给其他小组进行研究、分析,并与我们报告的结果进行比较。这将确保人们对新的衡量标准有信心,尽管过去G的衡量标准存在分歧。
项目成果
期刊论文数量(2)
专著数量(0)
科研奖励数量(0)
会议论文数量(0)
专利数量(0)
Active optical table tilt stabilization
主动光学平台倾斜稳定
- DOI:10.1063/5.0006916
- 发表时间:2020
- 期刊:
- 影响因子:1.6
- 作者:Lewandowski, Charles W.;Knowles, Tyler D.;Etienne, Zachariah B.;D’Urso, Brian
- 通讯作者:D’Urso, Brian
High-Sensitivity Accelerometry with a Feedback-Cooled Magnetically Levitated Microsphere
- DOI:10.1103/physrevapplied.15.014050
- 发表时间:2021-01-27
- 期刊:
- 影响因子:4.6
- 作者:Lewandowski, Charles W.;Knowles, Tyler D.;D'Urso, Brian
- 通讯作者:D'Urso, Brian
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Zachariah Etienne其他文献
Zachariah Etienne的其他文献
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{{ truncateString('Zachariah Etienne', 18)}}的其他基金
Collaborative Research: Measuring G with a Magneto-Gravitational Trap
合作研究:用磁引力阱测量 G
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2227079 - 财政年份:2022
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合作研究:用磁引力阱测量 G
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2004311 - 财政年份:2020
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Standard Grant
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提高算法效率:动态曲线坐标中的数值相对论
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Continuing Grant
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1002667 - 财政年份:2010
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$ 2.95万 - 项目类别:
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