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The space cold atom interferometer for testing the equivalence principle in the China Space Station

Meng He, Xi Chen, Jie Fang, Qunfeng Chen, Huanyao Sun, Yibo Wang, Jiaqi Zhong, Lin Zhou, Chuan He, J. F. Li, Danfang Zhang, G.-G. Ge, Wenzhang Wang, Yang Zhou, Xiao Li, Xiaowei Zhang, Qin Lei, Z. Chen, R. Xu, Yan Wang, Z. Xiong, Junjie Jiang, Zhendi Cai, Kuo Li, Guo Zheng, Weihua Peng, Jin Wang, Mingsheng Zhan

2023npj Microgravity22 citationsDOIOpen Access PDF

Abstract

The precision of the weak equivalence principle (WEP) test using atom interferometers (AIs) is expected to be extremely high in microgravity environment. The microgravity scientific laboratory cabinet (MSLC) in the China Space Station (CSS) can provide a higher-level microgravity than the CSS itself, which provides a good experimental environment for scientific experiments that require high microgravity. We designed and realized a payload of a dual-species cold rubidium atom interferometer. The payload is highly integrated and has a size of [Formula: see text]. It will be installed in the MSLC to carry out high-precision WEP test experiment. In this article, we introduce the constraints and guidelines of the payload design, the compositions and functions of the scientific payload, the expected test precision in space, and some results of the ground test experiments.

Topics & Concepts

InterferometryEquivalence (formal languages)Space (punctuation)PhysicsAtom interferometerInternational Space StationEquivalence principle (geometric)OpticsMathematicsComputer scienceQuantum mechanicsAstronomyAstronomical interferometerDiscrete mathematicsOperating systemCold Atom Physics and Bose-Einstein CondensatesAdvanced Frequency and Time StandardsRadioactive Decay and Measurement Techniques
The space cold atom interferometer for testing the equivalence principle in the China Space Station | Litcius