High precision differential clock comparisons with a multiplexed optical lattice clock

TL;DR

This paper introduces a multiplexed optical lattice clock with spatially-resolved ensembles, achieving unprecedented coherence times and stability, enabling advanced applications in precision measurement, fundamental physics, and clock network development.

Contribution

The authors demonstrate a multiplexed optical lattice clock with synchronized Ramsey interrogations, significantly improving coherence times and stability, and enabling a miniaturized clock network with multiple ensemble comparisons.

Findings

Atom-atom coherence times up to 26 seconds.

Relative stability of 9.7×10^{-18}/√τ.

Fractional uncertainty of 8.9×10^{-20} after 3.3 hours.

Abstract

Rapid progress in the precision and accuracy of optical atomic clocks over the last decade has advanced the frontiers of timekeeping, metrology, and quantum science. However, the stabilities of most optical clocks remain limited by the local oscillator rather than the atoms themselves, leaving room for further progress. Here we implement a "multiplexed" one-dimensional optical lattice clock, in which spatially-resolved, movable ensembles of ultra-cold strontium atoms are trapped in the same optical lattice, interrogated simultaneously by a shared clock laser, and read-out in parallel. By performing synchronized Ramsey interrogations of ensemble pairs we observe atom-atom coherence times up to 26 seconds, a 270-fold improvement over the atom-laser coherence time, demonstrate a relative stability of $9.7(4)\times10^{-18}/\sqrt{\tau}$ (where $\tau$ is the averaging time in seconds), and reach a fractional uncertainty of $8.9(3)\times 10^{-20}$ after 3.3 hours of averaging. These results demonstrate that applications requiring ultra-high-precision comparisons between optical atomic clocks need not be limited by the stability of the local oscillator. With multiple ensemble pairs, we realize a miniaturized clock network consisting of 6 atom ensembles, resulting in 15 unique pairwise clock comparisons with relative stabilities below $3\times10^{-17}/\sqrt{\tau}$. Finally, we demonstrate the capability to simultaneously load spatially-resolved, heterogeneous ensemble pairs of all four stable isotopes of strontium in a lattice. The unique capabilities offered by this platform pave the way for future studies of precision isotope shift measurements, spatially resolved characterization of limiting clock systematics, development of clock-based gravitational wave and dark matter detectors, and novel tests of relativity including measurements of the gravitational redshift at sub-centimeter scales.