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Point-to-point stabilized optical frequency transfer with active optics

Benjamin P. Dix-Matthews, Sascha Schediwy, David R. Gozzard, Etienne Savalle, François-Xavier Esnault, Thomas Lévèque, Charles Gravestock, Darlene D’Mello, Skevos Karpathakis, Michael E. Tobar, Peter Wolf

2021Nature Communications77 citationsDOIOpen Access PDF

Abstract

Abstract Timescale comparison between optical atomic clocks over ground-to-space and terrestrial free-space laser links will have enormous benefits for fundamental and applied sciences. However, atmospheric turbulence creates phase noise and beam wander that degrade the measurement precision. Here we report on phase-stabilized optical frequency transfer over a 265 m horizontal point-to-point free-space link between optical terminals with active tip-tilt mirrors to suppress beam wander, in a compact, human-portable set-up. A phase-stabilized 715 m underground optical fiber link between the two terminals is used to measure the performance of the free-space link. The active optical terminals enable continuous, cycle-slip free, coherent transmission over periods longer than an hour. In this work, we achieve residual instabilities of 2.7 × 10 −6 rad 2 Hz −1 at 1 Hz in phase, and 1.6 × 10 −19 at 40 s of integration in fractional frequency; this performance surpasses the best optical atomic clocks, ensuring clock-limited frequency comparison over turbulent free-space links.

Topics & Concepts

PhysicsOpticsOptical linkNoise (video)Free-space optical communicationOptical fiberScintillationLaserSIGNAL (programming language)Phase noisePhase (matter)Atomic clockComputer scienceDetectorProgramming languageArtificial intelligenceImage (mathematics)Quantum mechanicsAdvanced Frequency and Time StandardsAtomic and Subatomic Physics ResearchCold Atom Physics and Bose-Einstein Condensates
Point-to-point stabilized optical frequency transfer with active optics | Litcius