高准确度的钙离子光频标  被引量：4

作　　者：管桦[1,2] 黄垚[1,2] 李承斌[1,2] 高克林[1,2,3] Guan Hua1,2,Huang Yao1,2,Li Cheng-Bin1,2,Gao Ke-Lin1,2. 1.(State Key Laboratory of Magnetic Resonance and Atomic and Molecular Physics, Wuhan Institute of Physics and Mathematics, Chinese Academy of Sciences, Wuhan 430071, China）2. （Key Laboratory of Atomic Frequency Standards, Wuhan Institute of Physics and Mathematics, Chinese Academy of Sciences, Wuhan 430071, China）3.（Center for Cold Atom Physics, Chinese Academy of Sciences, Wuhan 430071, China)

机构地区：[1]中国科学院武汉物理与数学研究所波谱与原子分子物理国家重点实验室,武汉430071 [2]中国科学院武汉物理与数学研究所中国科学院原子频标重点实验室,武汉430071 [3]中国科学院冷原子物理中心(武汉),武汉430071

出　　处：《物理学报》2018年第16期155-164,共10页Acta Physica Sinica

基　　金：国家自然科学基金(批准号:91336211;11474318;11622434;11774388);国家重点基础研究发展计划(批准号:2012CB821301;2005CB724502);中国科学院先导专项(批准号XDB21030100)资助的课题~~

摘　　要：近年来,冷原子技术和激光技术促进了高精度光频标的发展,有望在建立时间基准、推动基础研究和满足国家需求等方面发挥重要的作用.本文介绍了中国科学院武汉物理与数学研究所近年来在高准确度钙离子(^(40)Ca^+)光频标研究方面的进展:采用新的ULE腔系统,实现了729 nm钟跃迁激光器1—100 s的频率稳定度均优于2×10^(-15),通过对外场和环境效应的控制及克服,特别是囚禁离子运动效应的抑制,获得单个钙离子光频标的不确定度优于5.5×10^(-17);通过两台光频标的比对,测得20000 s的稳定度也进入10^(-17)量级;基于高精度钙离子光频标平台,进行了相关精密测量的工作,包括:基于全球定位系统的超高精度远程光频绝对值测量方案,第二次测量了钙离子的光频跃迁绝对值,该测量结果再次被国际时间频率咨询委员会采纳,更新了钙离子的频率推荐值;精确测量了钙离子的钟跃迁魔幻波长,由此提出新型的全光囚禁离子光频标的方法;精密测量了钙离子的亚稳态寿命等参数.以上工作推动了基于冷原子的精密测量工作.With the development of the technologies in the lasers and the manipulation of cold atoms, the high precision optical frequency standards have been extensively studied and built in recent years. These high precision frequency standards may play an important role in establishing the new time reference, promoting the researches in the fundamental fields,fulfilling the national strategic needs, etc. In this paper, the research progress of high accuracy 40 Ca~＋optical frequency standard in Wuhan Institute of Physics and Mathematics（WIPM） of Chinese Academy of Sciences is presented. A new ULE super cavity is adopted for stabilizing the frequency of 729 nm clock laser, and the stability of the laser is improved now to 2×10^-15 in a duration of 1–100 s. By controlling the external fields and other environmental influences,especially suppressing the micromotion effects of the trapped ion, the uncertainty of the optical frequency standard based on a single 40Ca^＋ is reduced to 5.5 × 10^-17. The stability of 5 × 10^-17 in a duration of 20000 s is achieved via the comparison between two 40Ca^＋ optical frequency standards. Several precision measurement experiments are performed,based on the high precision 40Ca^＋ optical frequency standard. The absolute value of the clock transition frequency of the 40Ca^＋ optical frequency standard is measured second time, using an optical comb referenced to a hydrogen maser which is calibrated via GPS referenced to UTC（NIM）） using the precise point positioning data-processing technique.The frequency offset of UTC（NIM） relative to the SI second can be evaluated through BIPM circular-T reports, and the newly measured value of 4 s 2S1/2–3d2 D5/2 transition is adopted by CCTF-20, thus updating the recommended value of 40Ca^＋ optical clock transition. Besides the absolute frequency measurement, the magic wavelengths of 40Ca^＋optical clock transition are measured precisely, and this work is a milestone for establishing all-optical trapped-ion clocks. The lifetim

关 键 词：光频标 精密测量 钙离子 魔幻波长 

分 类 号：TN24[电子电信—物理电子学]