基于铷里德堡原子的频率可调谐微波电场测量

doi:10.3969/j.issn.1000-1158.2024.01.14

摘要
图/表
参考文献(26)
相关文章 (2)

全文: PDF (474 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要基于里德堡原子的能级调控特性实现了微波电场连续调谐测量。用铷原子气室作为微波电场传感器同时去感知待测微波场和调谐微波场,利用强调谐场对里德堡原子能级精细调节实现了待测场共振频率的同步改变,从而拓展了现有单频点微波测量的频率响应范围。在与68P3/2→66D5/2跃迁共振的调谐场作用下,利用测量的AT分裂光谱的幅值差来确定待测场共振频点的调谐变化,最终使共振的6.916GHz待测场的共振频率的调谐范围从原有的30MHz极限拓宽至150MHz,为微波电场的量子计量及拓展应用奠定技术基础。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	阮伟民
	张映昀
	冯志刚
	周亚东
	宋振飞
	屈继峰

关键词 ：微波量子计量, 里德堡原子, 微波电场, 量子相干, 能级调谐

Abstract：The continuous tuning measurement of microwave electric field is realized based on the energy level regulation of Rydberg atoms. A rubidium atomic gas chamber is used as a microwave electric field sensor to sense the signal field and the tuning field at the same time. The tuning field is used to fine-tune the Rydberg atomic energy level to realize the synchronous change of the resonant frequency of the signal field, thus expanding the frequency response range of the existing single-frequency microwave measurement. Under the effect of the tuning field that resonates with 68P3/2→66D5/2 transition, the amplitude difference of the measured AT splitting spectrum is used to determine the tuning change of the resonance frequency point of the signal field. Finally, the tuning range of the signal field with the frequency of 6.916GHz is widened from the original 30MHz to 150MHz. It lays a technical foundation for the quantum measurement and application of microwave electric field.

Key words： microwave quantum metrology Rydberg atoms microwave electric field quantum coherence level tuning

收稿日期: 2022-11-14 发布日期: 2024-01-22

PACS:

TB973

基金资助:国家自然科学基金(62071443); 国家重点研发计划(2021YFF0603704)

通讯作者: 冯志刚(1981-),男,山西长治人,中国计量科学研究院副研究员,主要从事微波电磁场量子计量,脉冲波形计量及应用方面的研究。Email:fengzg@nim.ac.cn 宋振飞(1983-),男,江苏南通人,中国计量科学研究院副研究员,主要从事微波电磁场量子精密测量方面的研究。Email:songzf@nim.ac.cn E-mail: fengzg@nim.ac.cn

作者简介: 阮伟民(1996-),男,安徽芜湖人,中国计量大学硕士研究生,研究方向为微波电磁场量子精密测量。Email:ruanwm@cjlu.edu.cn

引用本文:

阮伟民,张映昀,冯志刚,周亚东,宋振飞,屈继峰. 基于铷里德堡原子的频率可调谐微波电场测量[J]. 计量学报, 2024, 45(1): 97-102.
RUAN Weimin,ZHANG Yingyun,FENG Zhigang,ZHOU Yadong,SONG Zhenfei,QU Jifeng. Frequency Tunable Microwave Electric Field Measurement Based on Rubidium Rydberg Atoms. Acta Metrologica Sinica, 2024, 45(1): 97-102.

链接本文:

http://jlxb.china-csm.org:81/Jwk_jlxb/CN/10.3969/j.issn.1000-1158.2024.01.14 或 http://jlxb.china-csm.org:81/Jwk_jlxb/CN/Y2024/V45/I1/97

［10］	BIDEL Y, ZAHZAM N, BRESSON A, et al. Absolute airborne gravimetry with a cold atom sensor［J］. Journal of Geodesy, 2020, 94: 1-9.
［3］	黄巍, 梁振涛, 杜炎雄, 等. 基于里德堡原子的电场测量［J］. 物理学报, 2015, 64(16): 69-76.
［5］	LUDLOW A D, BOYD M M, YE J, et al. Optical atomic clocks［J］. Reviews of Modern Physics, 2015, 87(2): 637.
［9］	PETERS A, CHUNG K Y, CHU S. High-precision gravity measurements using atom interferometry［J］. Metrologia, 2001, 38(1): 25.
［1］	KANDA M, ORR R. Near-field gain of a horn and an open-ended waveguide: Comparison between theory and experiment［J］. IEEE transactions on antennas and propagation, 1987, 35(1): 33-40.
［4］	刘潇, 吴艳丽, 秦瑶, 等. TEM 室法环天线校准系统建立及测量结果不确定度评定［J］. 计量学报, 2021, 42(8): 1061-1067.
［7］	AFFOLDERBACH C, DU G X, BANDI T, et al. Imaging microwave and DC magnetic fields in a vapor-cell Rb atomic clock［J］. IEEE Transactions on Instrumentation and Measurement, 2015, 64(12): 3629-3637.
［11］	韩雨桐. SI 基本单位与时间计量［J］. 计量学报, 2022, 43(1): 1-6.
［12］	JIAO Y, HAO L, HAN X, et al. Atom-based radio-frequency field calibration and polarization measurement using cesium n DJ floquet states［J］. Physical Review Applied, 2017, 8(1): 014028.
	ZHANG J, SONG Z F, LI J, et al. Precision measurement of microwave power based on Rydberg atoms ［J］. Acta Metrologica Sinica, 2019, 40(5): 749-754.
［15］	MILLER S A, ANDERSON D A, RAITHEL G. Radio-frequency-modulated Rydberg states in a vapor cell［J］. New Journal of Physics, 2016, 18(5): 053017.
［17］	LIU Z K, ZHANG L H, LIU B, et al. Deep learning enhanced Rydberg multifrequency microwave recognition［J］. Nature communications, 2022, 13(1): 1997.
［2］	KANDA M. Standard probes for electromagnetic field measurements［J］. IEEE transactions on antennas and propagation, 1993, 41(10): 1349-1364.
［8］	HORSLEY A, DU G X, PELLATON M, et al. Imaging of relaxation times and microwave field strength in a microfabricated vapor cell［J］. Physical review A, 2013, 88(6): 063407.
［16］	LIAO K Y, TU H T, YANG S Z, et al. Microwave electrometry via electromagnetically induced absorption in cold Rydberg atoms［J］. Physical Review A, 2020, 101(5): 053432.
［18］	KUMAR S, FAN H, KBLER H, et al. Atom-based sensing of weak radio frequency electric fields using homodyne readout［J］. Scientific reports, 2017, 7(1): 42981.
［19］	JING M, HU Y, MA J, et al. Atomic superheterodyne receiver based on microwave-dressed Rydberg spectroscopy［J］. Nature Physics, 2020, 16(9): 911-915.
	HUANG W, LIANG Z T, DU Y X, et al. Electric field measurement based on Rydberg atoms ［J］. Acta Physica Sinica, 2015, 64(16): 69-76.
	HANG Y T. SI basic units and time measurement［J］. Acta Metrologica Sinica, 2022, 43(1): 1-6.
［20］	DING D S, LIU Z K, SHI B S, et al. Enhanced metrology at the critical point of a many-body Rydberg atomic system［J］. Nature Physics, 2022, 18(12): 1447-1452.
［21］	SIMONS M T, GORDON J A, HOLLOWAY C L, et al. Using frequency detuning to improve the sensitivity of electric field measurements via electromagnetically induced transparency and Autler-Townes splitting in Rydberg atoms［J］. Applied Physics Letters, 2016, 108(17): 174101.
［23］	HU J, LI H, SONG R, et al. Continuously tunable radio frequency electrometry with Rydberg atoms［J］. Applied Physics Letters, 2022, 121(1): 014002.
［25］	MEYER D H, KUNZ P D, COX K C. Waveguide-coupled Rydberg spectrum analyzer from 0 to 20GHz［J］. Physical review applied, 2021, 15(1): 014053.
［26］	ANDERSON D A, MILLER S A, RAITHEL G, et al. Optical measurements of strong microwave fields with Rydberg atoms in a vapor cell［J］. Physical Review Applied, 2016, 5(3): 034003.
［6］	NICHOLSON T L, CAMPBELL S L, HUTSON R B, et al. Systematic evaluation of an atomic clock at 2× 10-18 total uncertainty［J］. Nature communications, 2015, 6(1): 1-8.
［14］	SEDLACEK J A, SCHWETTMANN A, KüBLER H, et al. Microwave electrometry with Rydberg atoms in a vapour cell using bright atomic resonances［J］. Nature physics, 2012, 8(11): 819-824.
［24］	MOHAPATRA A K, JACKSON T R, ADAMS C S. Coherent optical detection of highly excited Rydberg states using electromagnetically induced transparency［J］. Physical review letters, 2007, 98(11): 113003.
	LIU X, WU Y L, QING Y, et al. Establishment of TEM Chamber loop antenna calibration System and Evaluation of Uncertainty of Measurement Results［J］. Acta Metrologica Sinica, 2021, 42(8): 1061-1067.
［13］	张杰, 宋振飞, 李君, 等. 基于里德堡原子的微波功率精密测量［J］. 计量学报, 2019, 40(5): 749-754.
［22］	SIMONS M T, ARTUSIO-GLIMPSE A B, HOLLOWAY C L, et al. Continuous radio-frequency electric-field detection through adjacent Rydberg resonance tuning［J］. Physical Review A, 2021, 104(3): 032824.