Ju Liu, Yaoyao Xu, Huaqing Luo, Lushuai Cao, Minkang Zhou, Xiaochun Duan, Zhongkun Hu
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引用次数: 0
Abstract
The gravitational redshift (GR), as predicted by Einstein’s general theory of relativity, posits that two identical clocks situated at different gravitational potentials will tick at different rates. In this study, we explore the impact of the GR on a single-photon-based atom interferometer and propose a corresponding testing scheme. Our approach conceptualizes the atom interferometer as two coherent atomic clocks positioned at distinct elevations, which is referred to as an atomic clock interferometer, allowing us to derive the GR-induced phase shift. This effect becomes significant due to the notable energy difference between the two atomic internal states, comparable to other relativistic effects in single-photon-based atomic clock interferometers. Furthermore, our proposed scheme incorporates the velocity of the laser device to effectively mitigate other relativistic effects. The ensuing analysis indicates an anticipated GR test precision at the 10−5 level for our proposed approach.
爱因斯坦广义相对论所预言的引力红移(GR)认为,位于不同引力势的两个相同时钟会以不同的速率滴答作响。在本研究中,我们探讨了广义相对论对基于单光子的原子干涉仪的影响,并提出了相应的测试方案。我们的方法将原子干涉仪概念化为两个位于不同高度的相干原子钟,这被称为原子钟干涉仪,使我们能够推导出 GR 引起的相移。由于两个原子内部状态之间存在显著的能量差异,这种效应变得非常重要,与基于单光子的原子钟干涉仪中的其他相对论效应相当。此外,我们提出的方案还结合了激光设备的速度,以有效减轻其他相对论效应。随后的分析表明,我们提出的方法预期的 GR 测试精度为 10-5 级。
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