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Reducing frequency drift caused by light shift in coherent population trapping-based low-power atomic clocks

Shinya Yanagimachi, Kazuhiro Harasaka, Ryoichiro Suzuki, Mitsuru Suzuki, Shigeyoshi Goka

2020Applied Physics Letters32 citationsDOI

Abstract

We propose a model to reduce the influence that the light-shift induced frequency drift has on the long-term stability of coherent population trapping (CPT)-based low-power atomic clocks. We experimentally validated the proposed model using the chip-scale atomic clock architecture. The model considers both the drift of the dc-bias current to compensate for the wavelength aging of the vertical-cavity surface-emitting laser (VCSEL) and the variation in the modulation index of the light field generated by the VCSEL. We investigated the dc-bias-current-dependency of the frequency drift in an atomic clock module both theoretically and experimentally, confirming that the frequency drift can change as a function of the VCSEL basic parameters. When the atomic clock module was operated over a period of five months at the dc-bias current affording a zero-crossing of the clock frequency drift, the Allan standard deviation and clock frequency drift for long-term stability were 8.0×10−12 for averaging times of 4×106 s and 2.4×10−13/day, respectively. Our approach is promising to improve the long-term stability of CPT-based low-power atomic clocks.

Topics & Concepts

Atomic clockFrequency driftAllan variancePhysicsVertical-cavity surface-emitting laserPopulationPower (physics)OpticsOptoelectronicsLaserAtomic physicsStandard deviationQuantum mechanicsDemographyPhase-locked loopMathematicsStatisticsSociologyPhase noiseAtomic and Subatomic Physics ResearchQuantum optics and atomic interactionsAdvanced Frequency and Time Standards
Reducing frequency drift caused by light shift in coherent population trapping-based low-power atomic clocks | Litcius