A vapor-cell clock with fractional frequency reaching 10-16 level stability

Abstract

Compact optical clocks with high stability are essential for next-generation frequency standard field applications, from navigation to geodesy, yet existing vapor cell clock systems have remained confined to fractional instabilities over 10-15. Here we report the breaking of this long standing barrier by demonstrating a molecular iodine optical clock that reaches an instability of 6.6× 10-16 and consistently operates at the 10-16 level throughout 100 s to 2000 s, surpassing all previous vapor-cell standards by nearly an order of magnitude. This achievement is enabled by a special design architecture that integrates a monolithic, drift immune spectroscopic unit bonded to an ultra low expansion glass substrate with active temperature control of key components. The whole system only occupies 25 L. The system achieves 5× 10-15 instability at 1 s and sustains 10-16 level performance over hours, representing the first medium-term optical stability at this level from a compact, field ready package. Our work establishes that 10-16 fractional frequency instability can be engineered into robust, portable systems through holistic stability conscious design, opening a path towards high precision time keeping beyond the laboratory environment.