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First uncertainty evaluation of the cesium fountain primary frequency standard NMIJ-F2

Akifumi Takamizawa, Shinya Yanagimachi, Ken Hagimoto

2022Metrologia18 citationsDOI

Abstract

Abstract We report the first uncertainty evaluation of NMIJ-F2, the second atomic fountain primary frequency standard at the National Metrology Institute of Japan. To improve the frequency stability, we increase the number of detected atoms to 9 × 10 5 using high-power cooling laser beams for vapor-loaded optical molasses and optical pumping into the Zeeman sublevel m F = 0. We also employ an ultra-stable cryogenic sapphire oscillator as a local oscillator to prevent the degradation of frequency stability due to the Dick effect. After correcting the collisional frequency shift by alternating atom densities, the frequency stability typically reaches 2.5 × 10 −13 ( τ /s) −1/2 . Its value is 1.9 × 10 −16 after 20 days of measurement. Type B uncertainty is typically evaluated at 4.7 × 10 −16 ; the largest contribution is from a distributed cavity phase shift, followed by a microwave leakage shift. In long-term comparison, the frequency of NMIJ-F2 is found to be consistent with that of the other primary and secondary frequency standards within the uncertainty.

Topics & Concepts

Frequency standardMetrologyPrimary standardCaesiumMaterials scienceZeeman effectMicrowaveLaser coolingLocal oscillatorMeasurement uncertaintyPhysicsAtomic physicsLaserOpticsPhase noiseCalibrationNuclear physicsQuantum mechanicsMagnetic fieldAdvanced Frequency and Time StandardsAtomic and Subatomic Physics ResearchScientific Measurement and Uncertainty Evaluation
First uncertainty evaluation of the cesium fountain primary frequency standard NMIJ-F2 | Litcius