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Ultrastable Free-Space Laser Links for a Global Network of Optical Atomic Clocks

David R. Gozzard, Lewis Howard, Benjamin P. Dix-Matthews, Skevos Karpathakis, C. Gravestock, Sascha Schediwy

2022Physical Review Letters67 citationsDOIOpen Access PDF

Abstract

A global network of optical atomic clocks will enable unprecedented measurement precision in fields including tests of fundamental physics, dark matter searches, geodesy, and navigation. Free-space laser links through the turbulent atmosphere are needed to fully exploit this global network, by enabling comparisons to airborne and spaceborne clocks. We demonstrate frequency transfer over a 2.4 km atmospheric link with turbulence comparable to that of a ground-to-space link, achieving a fractional frequency stability of 6.1×10^{-21} in 300 s of integration time. We also show that clock comparison between ground and low Earth orbit will be limited by the stability of the clocks themselves after only a few seconds of integration. This significantly advances the technologies needed to realize a global timescale network of optical atomic clocks.

Topics & Concepts

Atomic clockPhysicsTime delay and integrationFree-space optical communicationLaserTime transferOptical communicationStability (learning theory)Aerospace engineeringRemote sensingComputer scienceOpticsSatelliteAstronomyGeologyMachine learningEngineeringAdvanced Frequency and Time StandardsAtomic and Subatomic Physics ResearchCold Atom Physics and Bose-Einstein Condensates
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