A. Ludlow, G. Campbell, S. Blatt, M. Boyd, T. Zelevinsky, M.J. Martin, M. D. de Miranda, J. Thomsen, Jun Ye, T. Fortier, J. Stalnaker, S. Diddams, C. Oates
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引用次数: 0
摘要
本文报道了一种基于核自旋极化、超冷中性锶的一维光学晶格光学频率标准的改进表征和操作。我们在JILA和NIST博尔德校区之间实现了远程光学载波相位链路,允许使用其他光学标准对Sr系统进行高精度评估。对自由空间Ca标准的频率测量可以确定Sr标准在1 × 10-16分数不确定度或以下的系统位移。我们观察到时钟跃迁的密度依赖移位及其对激发态分数的依赖,移位的零交叉。我们执行一个50小时的锶跃迁的绝对频率测量参考NIST-F1 Cs喷泉标准。这产生了Sr时钟跃迁频率的值,其分数不确定度为8.6 x 10-16,受所使用的h脉泽和Cs标准的限制。这是我们对87Sr时钟频率的第五次,也是最准确的一次测量。
We report on the improved characterization and operation of an optical frequency standard based on nuclear-spin-polarized, ultracold neutral strontium confined in a one dimensional optical lattice. We implement a remote optical carrier phase link between JILA and NIST Boulder campus, permitting high precision evaluation of the Sr system with other optical standards. Frequency measurement against a free-space Ca standard enables determination of systematic shifts of the Sr standard at or below 1 x 10-16 fractional uncertainty. We observe a density-dependent shift of the clock transition and its dependence on excited state fraction, with a zero crossing of the shift. We perform a 50-hour-long absolute frequency measurement of the strontium transition referenced to the NIST-F1 Cs fountain standard. This yields a value for the Sr clock transition frequency with a fractional uncertainty of 8.6 x 10-16, limited by the H-maser and Cs standards used. This represents our fifth, and the most accurate, measurement of the 87Sr clock frequency.
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