Optical coherence between atomic species at the second scale: improved clock comparisons via differential spectroscopy

Abstract

Comparisons of high-accuracy optical atomic clocks Ludlow2015 are essential for precision tests of fundamental physics Safronova2018, relativistic geodesy McGrew2018, Grotti2018, Delva2019, and the anticipated redefinition of the SI second Riehle2018. The scientific reach of these applications is restricted by the statistical precision of interspecies comparison measurements. The instability of individual clocks is limited by the finite coherence time of the optical local oscillator (OLO), which bounds the maximum atomic interrogation time. In this letter, we experimentally demonstrate differential spectroscopy Hume2016, a comparison protocol that enables interrogating beyond the OLO coherence time. By phase-coherently linking a zero-dead-time (ZDT) Schioppo2017 Yb optical lattice clock with an Al+ single-ion clock via an optical frequency comb and performing synchronised Ramsey spectroscopy, we show an improvement in comparison instability relative to our previous result network2020frequency of nearly an order of magnitude. To our knowledge, this result represents the most stable interspecies clock comparison to date.