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Resonant electro-optic frequency comb

Author

Listed:
  • Alfredo Rueda

    (Max Planck Institute for the Science of Light
    University Erlangen-Nuernberg
    School in Advanced Optical Technologies (SAOT)
    Institute of Science and Technology Austria)

  • Florian Sedlmeir

    (Max Planck Institute for the Science of Light
    University Erlangen-Nuernberg)

  • Madhuri Kumari

    (The Dodd-Walls Centre for Photonic and Quantum Technologies
    University of Otago)

  • Gerd Leuchs

    (Max Planck Institute for the Science of Light
    University Erlangen-Nuernberg
    The Dodd-Walls Centre for Photonic and Quantum Technologies
    University of Otago)

  • Harald G. L. Schwefel

    (The Dodd-Walls Centre for Photonic and Quantum Technologies
    University of Otago)

Abstract

High-speed optical telecommunication is enabled by wavelength-division multiplexing, whereby hundreds of individually stabilized lasers encode information within a single-mode optical fibre. Higher bandwidths require higher total optical power, but the power sent into the fibre is limited by optical nonlinearities within the fibre, and energy consumption by the light sources starts to become a substantial cost factor1. Optical frequency combs have been suggested to remedy this problem by generating numerous discrete, equidistant laser lines within a monolithic device; however, at present their stability and coherence allow them to operate only within small parameter ranges2–4. Here we show that a broadband frequency comb realized through the electro-optic effect within a high-quality whispering-gallery-mode resonator can operate at low microwave and optical powers. Unlike the usual third-order Kerr nonlinear optical frequency combs, our combs rely on the second-order nonlinear effect, which is much more efficient. Our result uses a fixed microwave signal that is mixed with an optical-pump signal to generate a coherent frequency comb with a precisely determined carrier separation. The resonant enhancement enables us to work with microwave powers that are three orders of magnitude lower than those in commercially available devices. We emphasize the practical relevance of our results to high rates of data communication. To circumvent the limitations imposed by nonlinear effects in optical communication fibres, one has to solve two problems: to provide a compact and fully integrated, yet high-quality and coherent, frequency comb generator; and to calculate nonlinear signal propagation in real time5. We report a solution to the first problem.

Suggested Citation

  • Alfredo Rueda & Florian Sedlmeir & Madhuri Kumari & Gerd Leuchs & Harald G. L. Schwefel, 2019. "Resonant electro-optic frequency comb," Nature, Nature, vol. 568(7752), pages 378-381, April.
    • Handle: RePEc:nat:nature:v:568:y:2019:i:7752:d:10.1038_s41586-019-1110-x
    DOI: 10.1038/s41586-019-1110-x
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    Citations

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    Cited by:

    1. Mauro Cordella & Felice Alfieri & Javier Sanfelix, 2021. "Reducing the carbon footprint of ICT products through material efficiency strategies: A life cycle analysis of smartphones," Journal of Industrial Ecology, Yale University, vol. 25(2), pages 448-464, April.
    2. Alberto Boretti & Stefania Castelletto, 2021. "Techno-economic performances of future concentrating solar power plants in Australia," Palgrave Communications, Palgrave Macmillan, vol. 8(1), pages 1-10, December.
    3. Filho, F.M. Oliveira & Ribeiro, F.F. & Cruz, J.A. Leyva & de Castro, A.P. Nunes & Zebende, G.F., 2023. "Statistical study of the EEG in motor tasks (real and imaginary)," Physica A: Statistical Mechanics and its Applications, Elsevier, vol. 622(C).
    4. Weeratunge, Hansani & Aditya, Gregorius Riyan & Dunstall, Simon & de Hoog, Julian & Narsilio, Guillermo & Halgamuge, Saman, 2021. "Feasibility and performance analysis of hybrid ground source heat pump systems in fourteen cities," Energy, Elsevier, vol. 234(C).
    5. Ronit Sohanpal & Haonan Ren & Li Shen & Callum Deakin & Alexander M. Heidt & Thomas W. Hawkins & John Ballato & Ursula J. Gibson & Anna C. Peacock & Zhixin Liu, 2022. "All-fibre heterogeneously-integrated frequency comb generation using silicon core fibre," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    6. Mengze Zhao & Zhibin Zhang & Wujun Shi & Yiwei Li & Chaowu Xue & Yuxiong Hu & Mingchao Ding & Zhiqun Zhang & Zhi Liu & Ying Fu & Can Liu & Muhong Wu & Zhongkai Liu & Xin-Zheng Li & Zhu-Jun Wang & Kaih, 2023. "Enhanced copper anticorrosion from Janus-doped bilayer graphene," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    7. Baheej Bathish & Raanan Gad & Fan Cheng & Kristoffer Karlsson & Ramgopal Madugani & Mark Douvidzon & Síle Nic Chormaic & Tal Carmon, 2023. "Absorption-induced transmission in plasma microphotonics," Nature Communications, Nature, vol. 14(1), pages 1-7, December.
    8. Hussein M. E. Hussein & Seunghwi Kim & Matteo Rinaldi & Andrea Alù & Cristian Cassella, 2024. "Passive frequency comb generation at radiofrequency for ranging applications," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    9. Shannon, Matthew, 2022. "The labour market outcomes of transgender individuals," Labour Economics, Elsevier, vol. 77(C).

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