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Auteurs principaux: Meyer, Dylan, Lind, Alexander, Groman, William, Trent, Hero, Mashburn, Carter, Heyrich, Matthew, Sherman, Jeffrey, Quinlan, Franklyn, Santamaria-Botello, Gabriel, Diddams, Scott A.
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2511.21955
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author Meyer, Dylan
Lind, Alexander
Groman, William
Trent, Hero
Mashburn, Carter
Heyrich, Matthew
Sherman, Jeffrey
Quinlan, Franklyn
Santamaria-Botello, Gabriel
Diddams, Scott A.
author_facet Meyer, Dylan
Lind, Alexander
Groman, William
Trent, Hero
Mashburn, Carter
Heyrich, Matthew
Sherman, Jeffrey
Quinlan, Franklyn
Santamaria-Botello, Gabriel
Diddams, Scott A.
contents Robust and portable optical clocks promise to bring sub-picosecond timing instability to smaller form factors, offering possible performance improvements and new scenarios for positioning and navigation, radar technologies, and experiments probing fundamental physics. However, there are currently limited methods suitable for broadly disseminating the sub-picosecond timing signals or performing frequency comparison of these clocks--particularly over open-air paths. Established microwave time transfer techniques only offer nanosecond level time synchronization, whereas optical techniques have challenging pointing requirements and lack the capability of all-weather operation. In this paper, we explore optically derived millimeter-wave carriers as a time-frequency link for full utilization of the next generation of portable optical clocks. We introduce an architecture that synthesizes 90 GHz millimeter waves with a one second residual instability of 2x10^-15, averaging into the 10^-17 range. In addition, we demonstrate a first-of-its-kind 110 m phase-stabilized free-space frequency comparison link over a millimeter-wave band with a one second instability in the 10^-14 region. Technical and systematic uncertainties are investigated and characterized, providing a foundation for future time and frequency transfer experiments among distributed portable optical clocks.
format Preprint
id arxiv_https___arxiv_org_abs_2511_21955
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Photonic Generation and Free-Space Distribution of Millimeter Waves for Portable Optical Clocks
Meyer, Dylan
Lind, Alexander
Groman, William
Trent, Hero
Mashburn, Carter
Heyrich, Matthew
Sherman, Jeffrey
Quinlan, Franklyn
Santamaria-Botello, Gabriel
Diddams, Scott A.
Optics
Robust and portable optical clocks promise to bring sub-picosecond timing instability to smaller form factors, offering possible performance improvements and new scenarios for positioning and navigation, radar technologies, and experiments probing fundamental physics. However, there are currently limited methods suitable for broadly disseminating the sub-picosecond timing signals or performing frequency comparison of these clocks--particularly over open-air paths. Established microwave time transfer techniques only offer nanosecond level time synchronization, whereas optical techniques have challenging pointing requirements and lack the capability of all-weather operation. In this paper, we explore optically derived millimeter-wave carriers as a time-frequency link for full utilization of the next generation of portable optical clocks. We introduce an architecture that synthesizes 90 GHz millimeter waves with a one second residual instability of 2x10^-15, averaging into the 10^-17 range. In addition, we demonstrate a first-of-its-kind 110 m phase-stabilized free-space frequency comparison link over a millimeter-wave band with a one second instability in the 10^-14 region. Technical and systematic uncertainties are investigated and characterized, providing a foundation for future time and frequency transfer experiments among distributed portable optical clocks.
title Photonic Generation and Free-Space Distribution of Millimeter Waves for Portable Optical Clocks
topic Optics
url https://arxiv.org/abs/2511.21955