In-orbit operation of an atomic clock based on laser-cooled 87 Rb atoms

Liang Liu; De-Sheng Lü; Wei-Biao Chen; Tang Li; Qiu-Zhi Qu; Bin Wang; Lin Li; Wei Ren; Zuo-Ren Dong; Jian-Bo Zhao; Wen-Bing Xia; Xin Zhao; Jing-Wei Ji; Mei-Feng Ye; Yan-Guang Sun; Yuan-Yuan Yao; Dan Song; Zhao-Gang Liang; Shan-Jiang Hu; Dun-He Yu; Xia Hou; Wei Shi; Hua-Guo Zang; Jing-Feng Xiang; Xiang-Kai Peng; Yu-Zhu Wang

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In-orbit operation of an atomic clock based on laser-cooled 87 Rb atoms

机译：基于激光冷却的87 Rb原子的原子钟在轨运行

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Atomic clocks based on laser-cooled atoms are widely used as primary frequency standards. Deploying such cold atom clocks (CACs) in space is foreseen to have many applications. Here we present tests of a CAC operating in space. In orbital microgravity, the atoms are cooled, trapped, launched, and finally detected after being interrogated by a microwave field using the Ramsey method. Perturbing influences from the orbital environment on the atoms such as varying magnetic fields and the passage of the spacecraft through Earth’s radiation belt are also controlled and mitigated. With appropriate parameters settings, closed-loop locking of the CAC is realized in orbit and an estimated short-term frequency stability close to 3.0?×?10?13τ?1/2 has been attained. The demonstration of the long-term operation of cold atom clock in orbit opens possibility on the applications of space-based cold atom sensors.

机译：基于激光冷却原子的原子钟被广泛用作主要频率标准。预计在太空中部署这种冷原子钟（CAC）具有许多应用。在这里，我们介绍在太空中运行的CAC的测试。在轨道微重力中，原子被冷却，俘获，发射并最终在通过拉姆齐方法被微波场询问后被检测到。轨道环境对原子的干扰影响，例如变化的磁场和航天器通过地球辐射带的通道，也得到控制和缓解。通过适当的参数设置，可以在轨道上实现CAC的闭环锁定，并且估计的短期频率稳定性接近3.0？×？10？13τ？1/2。冷原子钟在轨道上长期运行的演示为基于空间的冷原子传感器的应用打开了可能性。

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《Nature Communications》 |2018年第1期|共页
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Liang Liu; De-Sheng Lü; Wei-Biao Chen; Tang Li; Qiu-Zhi Qu; Bin Wang; Lin Li; Wei Ren; Zuo-Ren Dong; Jian-Bo Zhao; Wen-Bing Xia; Xin Zhao; Jing-Wei Ji; Mei-Feng Ye; Yan-Guang Sun; Yuan-Yuan Yao; Dan Song; Zhao-Gang Liang; Shan-Jiang Hu; Dun-He Yu; Xia Hou; Wei Shi; Hua-Guo Zang; Jing-Feng Xiang; Xiang-Kai Peng; Yu-Zhu Wang;
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1. Laser-cooled /sup 87/Rb clock [J] . Fertig C., Gibble K. IEEE Transactions on Instrumentation and Measurement . 1999,第2期

机译：激光冷却/ sup 87 / Rb时钟
2. Accurate measurement of the quadratic Zeeman coefficient of ~(87)Rb clock transition based on the Ramsey atom interferometer [J] . B Wu, Z Y Wang, B Cheng, Journal of Physics, B. Atomic, Molecular and Optical Physics: An Institute of Physics Journal . 2014,第1期

机译：基于Ramsey原子干涉仪精确测量〜（87）Rb时钟跃迁的二次塞曼系数
3. Single-mode vertical-cavity surface emitting lasers for ~(87)Rb-based chip-scale atomic clock [J] . Derebezov I.A., Haisler V.A., Bakarov A.K., Semiconductors . 2010,第11期

机译：单模垂直腔表面发射激光器，用于〜（87）Rb基芯片级原子钟
4. COLD COLLISION FREQUENCY SHIFTS AND LASER-COOLED ~(87)RB CLOCKS [C] . Symposium on Frequency Standards and Metrology . 2002

机译：冷碰撞频率换档和激光冷却〜（87）RB时钟
5. The Saga of Light-Matter Interaction and Magneto-optical Effects Applications to Atomic Magnetometry, Laser-cooled Atoms, Atomic Clocks, Geomagnetism, and Plant Bio-magnetism. [D] . Corsini, Eric P. 2012

机译：物质相互作用和磁光效应的传奇在原子磁力计，激光致冷原子，原子钟，地磁和植物生物磁性中的应用。
6. In-orbit operation of an atomic clock based on laser-cooled 87Rb atoms [O] . Liang Liu, De-Sheng Lü, Wei-Biao Chen, -1

机译：基于激光冷却的87Rb原子的原子钟在轨运行
7. Interaction of laser-cooled $^{87}$Rb atoms with higher order modes of an optical nanofiber [O] . Kumar, Ravi, Gokhroo, Vandna, Maimaiti, Aili, 2014

机译：激光冷却的$ ^ {87} $ Rb原子与高阶模式的相互作用光学纳米纤维
8. All-Optical Atomic Clock Based on Coherent Population Trapping in 85Rb. [R] . Merimaa, M., Lindvall, T., Tittonen, I., 2001

机译：基于85Rb相干种群陷阱的全光原子钟。

In-orbit operation of an atomic clock based on laser-cooled 87 Rb atoms

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