A multi-ion optical clock with 5 × 10-19 uncertainty

Abstract

Today's most accurate clocks are based on laser spectroscopy of electronic transitions in single trapped ions and feature fractional frequency uncertainties below 1×10-18. Scaling these systems to multiple, simultaneously interrogated ions reduces measurement times, driving recent advances in multi-ion clocks. However, maintaining state-of-the-art systematic uncertainties while increasing the number of ions remains a central challenge. Here, we report on a multi-ion optical atomic clock with a fractional frequency uncertainty of 5.3×10-19 and up to 10 ions. Ion-resolved state detection enables minimization of position-dependent shifts, with residual effects suppressed below the 10-20-level. Clock operation with eight to ten ions reduces the measurement time by a factor of 4.8 compared to single-ion operation. A comparison with an established single-ion clock yields an unperturbed frequency ratio of 0.6926711632159660405(20), with a statistical uncertainty of 0.9×10-18 and a combined uncertainty of 2.9× 10-18. These results demonstrate robust multi-ion clock operation with reduced averaging time and state-of-the-art accuracy.

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