Matter-Wave Interferometry for Inertial Sensing and Tests of Fundamental Physics

CPT and Lorentz Symmetry Pub Date : 2019-09-18 DOI:10.1142/9789811213984_0010

D. Schlippert, C. Meiners, R. Rengelink, C. Schubert, D. Tell, É. Wodey, K. Zipfel, W. Ertmer, E. Rasel

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引用次数: 20

Abstract

Very Long Baseline Atom Interferometry (VLBAI) corresponds to ground-based atomic matter-wave interferometry on large scales in space and time, letting the atomic wave functions interfere after free evolution times of several seconds or wave packet separation at the scale of meters. As inertial sensors, e.g., accelerometers, these devices take advantage of the quadratic scaling of the leading order phase shift with the free evolution time to enhance their sensitivity, giving rise to compelling experiments. With shot noise-limited instabilities better than $10^{-9}$ m/s$^2$ at 1 s at the horizon, VLBAI may compete with state-of-the-art superconducting gravimeters, while providing absolute instead of relative measurements. When operated with several atomic states, isotopes, or species simultaneously, tests of the universality of free fall at a level of parts in $10^{13}$ and beyond are in reach. Finally, the large spatial extent of the interferometer allows one to probe the limits of coherence at macroscopic scales as well as the interplay of quantum mechanics and gravity. We report on the status of the VLBAI facility, its key features, and future prospects in fundamental science.

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惯性传感的物质波干涉测量与基础物理测试

甚长基线原子干涉测量法(VLBAI)对应于大尺度空间和时间上的地面原子-物质-波干涉测量法，使原子波函数在几秒的自由演化时间或在米尺度上的波包分离后进行干涉。作为惯性传感器，例如加速度计，这些器件利用了阶相移随自由演化时间的二次标度来提高灵敏度，从而引起了引人注目的实验。VLBAI在视界1秒处的弹束噪声限制不稳定性优于$10^{-9}$ m/s$^2$，可以与最先进的超导重力仪竞争，同时提供绝对而不是相对测量。当同时对几个原子状态、同位素或物种进行操作时，可以在$10^{13}$及以上的部分水平上测试自由落体的普遍性。最后，干涉仪的大空间范围允许人们在宏观尺度上探测相干性的极限，以及量子力学和引力的相互作用。我们报告了VLBAI设施的现状，其主要特点，以及在基础科学中的未来前景。

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CPT and Lorentz Symmetry

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