Abstract
We have built an ytterbium optical lattice clock with improvements over our previous version. An in-vacuum blackbody radiation (BBR) shield is employed to provide a well characterized BBR environment. The effective temperature felt by the atoms can be determined at an accuracy level of 13 mK, leading to a total BBR frequency shift uncertainty of 9.5 × 10−19. We have also built an ultra-stable optical cavity system to pre-stabilize the clock laser, achieving a flicker frequency instability of ∼3 × 10−16. Rabi spectroscopy of the lattice-trapped atoms can achieve sub-Hertz linewidth spectra. Two ytterbium clocks have been operated in an antisynchronized configuration, with real-time BBR-Stark-shift corrections applied to both of them. By comparing the two clocks, we demonstrate a single-clock instability of 5.4 × 10−18 in 4500 s. This clock will be applied for frequency comparisons to other optical clocks of different atomic species in the future.
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