Quantum-limited optical time transfer for future geosynchronous links

Caldwell, Emily D.; Deschenes, Jean-Daniel; Ellis, Jennifer; Swann, William C.; Stuhl, Benjamin K.; Bergeron, Hugo; Newbury, Nathan R.; Sinclair, Laura C.

Quantum-limited optical time transfer for future geosynchronous links

Emily D. Caldwell, Jean-Daniel Deschenes, Jennifer Ellis, William C. Swann, Benjamin K. Stuhl, Hugo Bergeron, Nathan R. Newbury () and Laura C. Sinclair ()
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Emily D. Caldwell: National Institute of Standards and Technology (NIST)
Jean-Daniel Deschenes: Octosig Consulting
Jennifer Ellis: National Institute of Standards and Technology (NIST)
William C. Swann: National Institute of Standards and Technology (NIST)
Benjamin K. Stuhl: Space Dynamics Laboratory
Hugo Bergeron: Octosig Consulting
Nathan R. Newbury: National Institute of Standards and Technology (NIST)
Laura C. Sinclair: National Institute of Standards and Technology (NIST)

Nature, 2023, vol. 618, issue 7966, 721-726

Abstract: Abstract The combination of optical time transfer and optical clocks opens up the possibility of large-scale free-space networks that connect both ground-based optical clocks and future space-based optical clocks. Such networks promise better tests of general relativity1–3, dark-matter searches4 and gravitational-wave detection5. The ability to connect optical clocks to a distant satellite could enable space-based very long baseline interferometry6,7, advanced satellite navigation8, clock-based geodesy2,9,10 and thousandfold improvements in intercontinental time dissemination11,12. Thus far, only optical clocks have pushed towards quantum-limited performance13. By contrast, optical time transfer has not operated at the analogous quantum limit set by the number of received photons. Here we demonstrate time transfer with near quantum-limited acquisition and timing at 10,000 times lower received power than previous approaches14–24. Over 300 km between mountaintops in Hawaii with launched powers as low as 40 µW, distant sites are synchronized to 320 attoseconds. This nearly quantum-limited operation is critical for long-distance free-space links in which photons are few and amplification costly: at 4.0 mW transmit power, this approach can support 102 dB link loss, more than sufficient for future time transfer to geosynchronous orbits.

Date: 2023
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DOI: 10.1038/s41586-023-06032-5

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