应用于相干布居囚禁原子钟的低相位噪声微波频率综合器

doi:10.3969/j.issn.1000-1158.2022.11.18

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摘要相干布居囚禁(CPT)原子钟作为微波原子钟的一种类型,由于不需要微波谐振腔即可实现微波探询,可极大降低体积和功耗,从而实现芯片级、低功耗的原子钟。CPT原子钟性能指标的主要限制因素之一是微波综合器的相位噪声,为了提升CPT原子钟的性能,研制了一种应用于CPT原子钟的低相位噪声频率综合器。实验结果表明,频率综合器在200Hz处的绝对相位噪声为108dBc/Hz。微波综合器由于Dick效应对原子钟频率稳定度的限制为8.2×10^-14,可以完全满足CPT原子钟的性能指标要求。此频率综合器也可更广泛地用于其它高性能微波原子精密测量系统以及计量标准器。

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	姚明昊
	段俊毅
	王学影
	韩琪娜
	施杨
	周琨荔
	茹宁
	刘小赤
	屈继峰

关键词 ：计量学, 微波综合器, 相位噪声, 光频移, 原子钟

Abstract：Atomic clock based on coherent population trapping (CPT) could interrogate the atoms without microwave cavity, which significantly reduce the volume of the physical package. One of the main limitations of CPT clock is the phase noise of the microwave synthesizer. Here a low phase nosie microwave synthesizer for CPT clock system is demonstrated. The absolute phase noise of the microwave synthesizer achieved -108dBc/Hz at 200Hz offset frequency. The frequency stability limitation of CPT clock with this synthesizer is calculated to be 8. 2×10-14 with Dick effect formula. This low phase noise microwave synthesizer could be also applied in other types of precision measurement system and standards based on atoms.

Key words： metrology microwave synthesizer phase noise light shift atomic clock

收稿日期: 2021-10-26 发布日期: 2022-11-14

PACS:

TB939

基金资助:国家自然科学基金(61975194)

通讯作者: 刘小赤(1987-),湖北荆州人,中国计量科学研究院副研究员,研究方向为小型化原子频标。Email:liuxch@nim.ac.cn E-mail: liuxch@nim.ac.cn

作者简介: 姚明昊(1997-),河北唐山人,中国计量大学研究生,研究方向为原子分子物理。Email:ymh15869105336@gmail.com

引用本文:

姚明昊,段俊毅,王学影,韩琪娜,施杨,周琨荔,茹宁,刘小赤,屈继峰. 应用于相干布居囚禁原子钟的低相位噪声微波频率综合器[J]. 计量学报, 2022, 43(11): 1501-1505.
YAO Ming-hao,DUAN Jun-yi,WANG Xue-ying,HAN Qi-na,SHI Yang,ZHOU Kun-li,RU Ning,LIU Xiao-chi,QU Ji-feng. Low Phase Noise Microwave Synthesizer for Coherent Population Trapping Atomic Clock. Acta Metrologica Sinica, 2022, 43(11): 1501-1505.

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