铯喷泉钟C场的测量与计算

doi:10.3969/j.issn.1000-1158.2023.02.15

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摘要在铯原子喷泉钟实验中,C场均匀度决定了二阶塞曼频移的不确定度评定。使用微波激励法可以测量C场各个高度经时间加权的磁感应强度的平均值。为了得到C场的实际磁场分布,需要对微波激励法的测量结果进行去时间加权计算。介绍了两种去时间加权的算法,并利用仿真数据对算法进行了验证。最后使用微波激励法和两种去时间加权算法,结合蒙特卡洛不确定度评定方法对NIM6铯喷泉钟C场进行了测量与计算。

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	刘洪康
	刘昆
	韩蕾
	房芳
	陈伟亮
	郑发松
	戴少阳
	左娅妮
	李天初

关键词 ：计量学, 铯喷泉钟, C场, 微波激励法, 去时间加权, 蒙特卡洛不确定度评定

Abstract：In the cesium fountain clock experiment, the magnetic uniformity of C field determines the uncertainty evaluation of the second order Zeeman frequency shift. Microwave excitation method can be used to measure the average value of the time-weighted magnetic induction intensity at each height of the C field. In order to obtain the actual magnetic field distribution of C field, the measurement results of microwave excitation method need to be de-weighted. To introduces two de-time-weighted algorithms and verifies them with simulation data. Finally, the C field of NIM6 cesium fountain clock is measured and calculated by microwave excitation method and two de-time-weighted algorithms combined with Monte Carlo uncertainty evaluation method.

Key words： metrology cesium fountain clock C field microwave excitation method de-time-weighting Monte Carlo uncertainty evaluation

收稿日期: 2022-03-15 发布日期: 2023-02-21

PACS:

TB939

基金资助:国家重点研发计划重点专项(2016YFF0200202);中国计量科学研究院基本科研业务费重点领域项目(AKYZD2009)

通讯作者: 刘昆(1982-),男,天津人,中国计量科学研究院副研究员,主要研究方向为原子钟、时间频率计量方法等。Email: liukun@nim.ac.cn E-mail: liukun@nim.ac.cn

作者简介: 刘洪康(1995-),男,山东潍坊人,北京理工大学硕士研究生,研究方向为测试计量技术及仪器。Email: cwlhk9509@163.com

引用本文:

刘洪康,刘昆,韩蕾,房芳,陈伟亮,郑发松,戴少阳,左娅妮,李天初. 铯喷泉钟C场的测量与计算[J]. 计量学报, 2023, 44(2): 258-264.
LIU Hong-kang,LIU Kun,HAN Lei,FANG Fang,CHEN Wei-liang,ZHENG Fa-song,DAI Shao-yang,ZUO Ya-ni,LI Tian-chu. Measurement and Calculation of C Field of Cesium Fountain Clock. Acta Metrologica Sinica, 2023, 44(2): 258-264.

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	Han Y T. SI Base Units and Time Measurement［J］. Acta Metrologica Sinica, 2022, 43(1): 1-6.
［11］	刘昆, 房芳, 陈伟亮, 等. 应用于铯喷泉钟的磁屏蔽系统的设计［J］. 计量学报, 2014, 35(3): 281-285.
［18］	倪育才. 实用测量不确定度评定［M］. 北京: 中国质量标准出版传媒有限公司, 2020: 240-244.
［8］	王义遒. 原子的激光冷却与陷俘［M］. 北京: 北京大学出版社, 2007: 342-343.
［10］	陈伟亮, 房芳, 袁小迪, 等. NIM6铯喷泉钟背景气体碰撞频移的评估［J］. 计量技术, 2020, (5): 11-13.
［15］	Fang F, Li M S, Lin P W, et al. NIM5 Cs fountain clock and its evaluation ［J］. Metrologia, 2015, 52 (4): 454-468.
［17］	江文松, 王中宇, 罗哉, 等. 基于蒙特卡罗法的冲击力溯源系统不确定度评定［J］. 计量学报, 2020, 41(4): 448-454.
［1］	Clairon A, Laurent P, Santarelli G, et al. A cesium fountain frequency standard: preliminary results ［J］. IEEE Transactions on Instrumentation and Measurement, 1995, 44(2): 128 - 131.
［6］	Wynands R, Weyers S. Atomic fountain clocks ［J］. Metrologia, 2005, 42(3): 64-79.
［13］	Jefferts S R, Shirley J, Parker T E, et al. Accuracy evaluation of NIST-F1 ［J］. Metrologia, 2002, 39 (4): 321-336.
［2］	Dai S Y, Zheng F S, Liu K, et al. Cold atom clocks and their applications in precision measurements ［J］. Chinese Physics B, 2021, 30(1): 42-56.
［4］	Heavner T P, Donley E A, Levi F, et al. First accuracy evaluation of NIST-F2 ［J］. Metrologia, 2014, 51(3): 174-182.
［9］	施俊如, 王心亮, 阮军, 等. 铯原子喷泉钟空间均匀C场的研究［J］. 时间频率学报, 2018, 41 (3): 145-150.
	Shi J R, Wang X L, Ruan J, et al. Study of C fields spatial uniformity for cesium fountain clock ［J］. Journal of Time and Frequency, 2018, 41(3): 145-150.
	Liu K, Fang F, Chen W L, et al. Design of magnetic shield for cesium fountain clock ［J］. Acta Metrologica Sinica, 2014, 35(3): 281-285.
［16］	刘昆, 宋文霞, 袁小迪, 等. 冷原子上抛高度的精确计算方法［J］. 计量科学与技术, 2021, 65(10): 3-5.
	Liu K, Song W X, Yuan X D, et al. Accurate Calculation of the Height of Cold Atoms Throw Up ［J］. Metrology Science and Technology, 2021, 65(10): 3-5.
［19］	韩雨桐. SI基本单位与时间计量［J］. 计量学报, 2022, 43(1): 1-6.
［3］	王倩, 魏荣, 王育竹. 原子喷泉频标: 原理与发展［J］. 物理学报, 2018, 67(16): 154-170.
	Chen W L, Fang F, Yuan X D, et al. Evaluation of the Background Gas Collision Frequency Shift in NIM6 Cesium Fountain Clock ［J］. Measurement Technique, 2020, (5): 11-13.
	Jiang W S, Wang Z Y, Luo Z, et al. Uncertainty Evaluation on the Traceable Measurement System of the Impact Force Based on a Monte Carlo Method ［J］. Acta Metrologica Sinica, 2020, 41(4): 448-454.
［5］	Chu S, Hollber L, Bjorkholm J E, et al. Three-dimensional viscous confinement and cooling of atoms by resonance radiation pressure ［J］. Physical Review Letters, 1985, 55(1): 48-51.
［7］	Szymaniec K, Park S E, Marra G, et al. First accuracy evaluation of the NPL-CsF2 primary frequency standard ［J］. Metrologia, 2010, 47(4): 65-79.
［12］	Park Y H, Eon P S, Lee S, et al. Inverse problem approach to evaluate quadratic Zeeman effect for an atomic fountain frequency standard KRISS-F1 ［J］. Japanese Journal of Applied Physics, 2021, 60(6): 062001.
［14］	Szymaniec K, Chalupczak W, Whibberley P B, et al. Evaluation of the primary frequency standard NPL-CsF1 ［J］. Metrologia, 2005, 42 (1): 49-57.
	Wang Q, Wei R, Wang Y Z. Atomic fountain frequency standard: principle and development ［J］. Acta Physica Sinica, 2018, 67 (16): 154-170.