We present a compact atomic clock interrogating ultracold Rb-87 magnetically trapped on an atom chip. Very long coherence times sustained by spin self-rephasing allow us to interrogate the atomic transition with 85% contrast at 5-s Ramsey time. The clock exhibits a fractional frequency stability of 5.8 x 10(-13) at 1 s and is likely to integrate into the 10(-15) range in less than a day. A detailed analysis of seven noise sources explains the measured frequency stability. Fluctuations in the atom temperature (0.4 nK shot-to-shot) and in the offset magnetic field (5 x 10(-6) relative fluctuations shot-to-shot) are the main noise sources together with the local oscillator, which is degraded by the 30% duty cycle. The analysis suggests technical improvements to be implemented in a future second generation setup. The results demonstrate the remarkable degree of technical control that can be reached in an atom chip experiment.
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机译:我们提出了一个紧凑的原子钟,该原子钟询问被磁性捕获在原子芯片上的超冷Rb-87。自旋自定相所维持的非常长的相干时间使我们能够在5 s Ramsey时间以85%的对比度询问原子跃迁。该时钟在1 s内具有5.8 x 10(-13)的分数频率稳定性,并且有可能在不到一天的时间内整合到10(-15)范围内。对七个噪声源的详细分析说明了测得的频率稳定性。原子温度(0.4nK到发射点之间的波动)和偏移磁场(5 x 10(-6)相对于发射点之间的相对波动)的波动是主要的噪声源,而本地振荡器也会降低30%的占空比。分析建议在将来的第二代设置中实施技术改进。结果表明,在原子芯片实验中可以达到很高的技术控制水平。
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