Improved systematic evaluation of a strontium optical clock with uncertainty below 1× 10-18

Abstract

We report a systematic uncertainty of 9.2× 10-19 for the USTC Sr1 optical lattice clock, achieving accuracy at the level required for the roadmap of the redefinition of the SI second. A finite-element model with in situ-validated, spatially-resolved chamber emissivity reduced blackbody radiation shift uncertainty to 6.3× 10-19. Concurrently, an externally mounted lattice cavity combined with a larger beam waist suppressed density shifts. Enhanced lattice depth modulation consolidated lattice light shift uncertainty to 6.3× 10-19 by enabling simultaneous determination of key polarizabilities and magic wavelength. Magnetic shifts were resolved below 10-18 via precision characterization of the second-order Zeeman coefficient. Supported by a crystalline-coated ultra-low-expansion cavity-stabilized laser and refined temperature control suppressing BBR fluctuations, the clock also achieves a frequency stability better than 1×10-18 at 30,000-s averaging time. These developments collectively establish a new benchmark in USTC Sr1 clock performance and pave the way for high-accuracy applications in metrology and fundamental physics.