Abstract: We discuss frequency standards based on laser-cooled $+199$/Hg$+$PLU$/ ions confined in cryogenic rf traps. In one experiment, the frequency of a microwave source is served to the ions' ground-state hyperfine transition at 40.5 GHz. For seven ions and a Ramsey free precession time of 100 s, the fractional frequency stability is 3.3 (2) $MUL 10$+$MIN@13$/ $tau$+$MIN@1/2$/ for measurement times $tau $LS 2 h. The ground-state hyperfine interval is measured to be 40 507 347 996.841 59 (14) (41) Hz, where the first number in parentheses is the uncertainty due to statistics and systematic errors, and the second is the uncertainty in the frequency of the time scale to which the standard is compared. In a second experiment under development, a strong-binding cryogenic trap will confine a single ion used for an optical frequency standard based on a narrow electric quadrupole transition at 282 nm. The bandwidth of the laser used to drive this transition is less than 10 Hz at 563 nm. !25
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机译:摘要:我们讨论了基于在低温rf阱中限制的激光冷却$ + 199 $ / Hg $ + $ PLU $ /离子的频率标准。在一个实验中,微波源的频率在40.5 GHz时作用于离子的基态超精细跃迁。对于七个离子和100 s的Ramsey自由进动时间,分数频率稳定性为3.3(2)$ MUL 10 $ + $ MIN @ 13 $ / $ tau $ + $ MIN @ 1/2 $ /测量时间$ tau $ LS 2小时基态超精细间隔的测量值为40 507 347 996.841 59(14)(41)Hz,其中括号中的第一个数字是由于统计和系统误差引起的不确定性,第二个是频率的不确定性与标准进行比较的时间范围。在正在开发的第二个实验中,强结合的低温阱将基于282 nm的窄四极电子跃迁将单个离子限制在光频率标准中。用于驱动此跃迁的激光带宽在563 nm处小于10 Hz。 !25
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