秒定义变革及我国时间频率基准的发展和应对

doi:10.12267/j.issn.2096-5931.2022.07.001

信息通信技术与政策 ›› 2022, Vol. 48 ›› Issue (7): 2-8.doi: 10.12267/j.issn.2096-5931.2022.07.001

秒定义变革及我国时间频率基准的发展和应对

Redefinition of unit of time and research progress of primary frequency standard in NIM

曹士英, 房芳

中国计量科学研究院时间频率计量科学研究所,北京 100029

收稿日期:2022-06-13 出版日期:2022-07-15 发布日期:2022-08-10
作者简介:
曹士英中国计量科学研究院时间频率计量科学研究所频率标准及应用实验室主任,研究员,博士,主要从事时间频率计量工作|房芳中国计量科学研究院时间频率计量科学研究所所长,研究员,博士,国际时间频率咨询委员会代表,国际频控会微波频标组专家/副主席,中国计量测试学会时频委员会主任委员,全国时间频率计量技术委员会主任委员,主要从事时间频率计量工作

CAO Shiying, FANG Fang

Division of Time and Frequency Metrology, National Institute of Metrology, Beijing 100029, China

Received:2022-06-13 Online:2022-07-15 Published:2022-08-10

摘要/Abstract

摘要：

国际单位制的量子化变革使得除了物质的量的定义外,其他国际单位的定义都与时间单位建立了直接或间接的联系。高准确度的时间频率基准在国民经济建设、国防建设和科学研究中发挥着重要的作用。主要介绍了时间单位的定义从天文秒到原子秒的发展历程以及关于秒定义变革的讨论和对原子钟的要求,并介绍了我国国家计量院在时间频率基准方面的研究工作及应对措施。

关键词: 秒定义, 时间频率基准, 铯原子喷泉钟, 光钟

Abstract:

The redefinition of the International System of Units makes the definitions of other base units directly or indirectly related to the unit of time (second) except that of the amount of substance. High-accuracy time and frequency standards plays an important role in national economy, national defense and scientific research. This paper mainly introduces the development of the definition of the second from astronomical second to atomic second, and the discussion on the redefinition of the second and the requirements for atomic clocks. Finally, it introduces the research work and counter measures of National Metrology Institute of China on time and frequency standards.

Key words: definition of the unit of time, time and frequency primary standard, caesium fountain clock, optical clock

中图分类号:

TN99
O562.3

曹士英, 房芳. 秒定义变革及我国时间频率基准的发展和应对[J]. 信息通信技术与政策, 2022, 48(7): 2-8.

CAO Shiying, FANG Fang. Redefinition of unit of time and research progress of primary frequency standard in NIM[J]. Information and Communications Technology and Policy, 2022, 48(7): 2-8.

导出引用管理器 EndNote|Ris|BibTeX

链接本文:

http://ictp.caict.ac.cn/CN/10.12267/j.issn.2096-5931.2022.07.001

http://ictp.caict.ac.cn/CN/Y2022/V48/I7/2

图/表 7

图1 NIM3磁选态铯束原子钟

图2 NIM4激光冷却铯原子喷泉钟

图3 NIM5激光冷却铯原子喷泉钟

图4 NIM6激光冷却铯原子喷泉钟

图5 NIM-Sr2锶原子光晶格钟[19]

图6 掺铒光纤光学频率梳

图7 基于超窄线宽激光锁定的双光梳系统

参考文献 22

[1]	Bureau International des Poids et Mesures. SI base unit: second (s)[EB/OL]. [2022-06-13]. https://www. bipm.org/en/si-base-units/second.
[2]	HEAVNER T P, DONLEY E A, LEVI F, et al. First accuracy evaluation of NIST-F2[J]. Metrologia, 2014, 51(3):174-182.
[3]	BREWER S M, CHEN J S, HANKIN A M, et al. 27Al+ quantum-logic clock with a systematic uncertainty below 10-18[J]. Physical Review Letters, 2019, 123(3):033201.
[4]	ESSEN L, PARRY J V L. An atomic standard of frequency and time interval: a Cæsium resonator[J]. Nature, 1955,176:280-282.
[5]	MARKOWITZ W, HALL R G, ESSEN L, et al. Frequency of cesium in terms of ephemeris time[J]. Physical Review Letters, 1958,1:105-107.
[6]	TERRIEN J. News from the international bureau of weights and measures[J]. Metrologia, 1968, 4(1):41-45.
[7]	Bureau Internationaldes Poids et Mesures. On the revision of the international system of units (SI)[C]. In:the General Conference on Weights and Measures (CGPM) 26th Meeting. Versailles, 2018.
[8]	WEYERS S, GERGINOV V, KAZDA M, et al. Advances in the accuracy, stability, and reliability of the PTB primary fountain clocks[J]. Metrologia, 2018, 55(6):789-805.
[9]	PANFILO G, ARIAS F. The coordinated universal time (UTC)[J]. Metrologia, 2019, 56(5):042001.
[10]	PETIT G, ARIAS F, PANFILO G. International atomic time: status and future challenges[J]. C R Physique, 2015,16:480-488.
[11]	McGrew W F, ZHANG X, FASANO R J, et al. Atomic clock performance enabling geodesy below the centimetre level[J]. Nature, 2018,564:87-90.
[12]	JOHNSON L A M, GILL P, MARGOLIS H S. Evaluating the performance of the NPL femtosecond frequency combs: agreement at the 10-21 level[J]. Metrologia, 2015, 52(1):62-71.
[13]	LI T, LIN P, LI M, et al. The transportable cesium fountain clock NIM5: its construction and performance[C]. In: Maleki L, ed. Frequency Standards and Metrology (Proceedings of the 7th Symposium). Singapore: World Scientific, 2009:314-320.
[14]	FANG F, LI M, LIN P, et al. NIM5 Cs fountain clock and its evaluation[J]. Metrologia, 2015, 52(4):454-468.
[15]	DAI S Y, FANG F, LIU K, et al. The ultra-stable microwave based on ultra-stable laser with robustness and long-term stability[C]. Proceeds of SPIE 10825, Quantum and Nonlinear Optics V, 2018:1082515.
[16]	房芳, 张爱敏, 林弋戈, 等. 时间: 天文时-原子秒-基于常数重新定义秒[J]. 中国科学: 物理学力学天文学, 2021, 51(7):074208.
[17]	LIN Y G, WANG Q, LI Y, et al. First evaluation and frequency measurement of the strontium optical lattice clock at NIM[J]. Chinese Physics Letters, 2015, 32(9):090601.
[18]	LIN Y G, WANG Q, MENG F, et al. A 87Sr optical lattice clock with 2.9 × 10^-17 uncertainty and its absolute frequency measurement[J]. Metrologia, 2021, 58(3):035010.
[19]	中国科学计量研究院. 国家市场监管重点实验室(时间频率与重力计量基准)[EB/OL]. [2022-06-13]. https://www.nim.ac.cn/node/214.
[20]	ZUO Y, DAI S, CAO S, et al. Design of the optical system for 171-ytterbium single-ion optical clock[C]// Optical Sensors 2021. International Society for Optics and Photonics, 2021,11772:1177227.
[21]	CAO S Y, HAN Y, DING Y J, et al. Precise determination of characteristic laser frequencies by an Er-doped fibre optical frequency comb[J]. Chinese Physics B, 2022 Accepted to be published.
[22]	崔佳华, 林百科, 孟飞, 等. 相位锁定至超窄线宽激光的高相干性双光梳研究[J]. 红外与毫米波学报, 2020, 39(1):25-31.

秒定义变革及我国时间频率基准的发展和应对

Redefinition of unit of time and research progress of primary frequency standard in NIM

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

图/表 7

参考文献 22

相关文章 0

编辑推荐

Metrics

本文评价