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Atomic clock performance enabling geodesy below the centimetre level

Author

Listed:
  • W. F. McGrew

    (National Institute of Standards and Technology
    University of Colorado)

  • X. Zhang

    (National Institute of Standards and Technology
    Peking University)

  • R. J. Fasano

    (National Institute of Standards and Technology
    University of Colorado)

  • S. A. Schäffer

    (National Institute of Standards and Technology
    University of Copenhagen)

  • K. Beloy

    (National Institute of Standards and Technology)

  • D. Nicolodi

    (National Institute of Standards and Technology
    University of Colorado)

  • R. C. Brown

    (National Institute of Standards and Technology
    Georgia Tech Research Institute)

  • N. Hinkley

    (National Institute of Standards and Technology
    University of Colorado
    Stable Laser Systems)

  • G. Milani

    (National Institute of Standards and Technology
    Istituto Nazionale di Ricerca Metrologica
    Politecnico di Torino)

  • M. Schioppo

    (National Institute of Standards and Technology
    National Physical Laboratory (NPL))

  • T. H. Yoon

    (National Institute of Standards and Technology
    Korea University)

  • A. D. Ludlow

    (National Institute of Standards and Technology
    University of Colorado)

Abstract

The passage of time is tracked by counting oscillations of a frequency reference, such as Earth’s revolutions or swings of a pendulum. By referencing atomic transitions, frequency (and thus time) can be measured more precisely than any other physical quantity, with the current generation of optical atomic clocks reporting fractional performance below the 10−17 level1–5. However, the theory of relativity prescribes that the passage of time is not absolute, but is affected by an observer’s reference frame. Consequently, clock measurements exhibit sensitivity to relative velocity, acceleration and gravity potential. Here we demonstrate local optical clock measurements that surpass the current ability to account for the gravitational distortion of space-time across the surface of Earth. In two independent ytterbium optical lattice clocks, we demonstrate unprecedented values of three fundamental benchmarks of clock performance. In units of the clock frequency, we report systematic uncertainty of 1.4 × 10−18, measurement instability of 3.2 × 10−19 and reproducibility characterized by ten blinded frequency comparisons, yielding a frequency difference of [−7 ± (5)stat ± (8)sys] × 10−19, where ‘stat’ and ‘sys’ indicate statistical and systematic uncertainty, respectively. Although sensitivity to differences in gravity potential could degrade the performance of the clocks as terrestrial standards of time, this same sensitivity can be used as a very sensitive probe of geopotential5–9. Near the surface of Earth, clock comparisons at the 1 × 10−18 level provide a resolution of one centimetre along the direction of gravity, so the performance of these clocks should enable geodesy beyond the state-of-the-art level. These optical clocks could further be used to explore geophysical phenomena10, detect gravitational waves11, test general relativity12 and search for dark matter13–17.

Suggested Citation

  • W. F. McGrew & X. Zhang & R. J. Fasano & S. A. Schäffer & K. Beloy & D. Nicolodi & R. C. Brown & N. Hinkley & G. Milani & M. Schioppo & T. H. Yoon & A. D. Ludlow, 2018. "Atomic clock performance enabling geodesy below the centimetre level," Nature, Nature, vol. 564(7734), pages 87-90, December.
  • Handle: RePEc:nat:nature:v:564:y:2018:i:7734:d:10.1038_s41586-018-0738-2
    DOI: 10.1038/s41586-018-0738-2
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    Citations

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    Cited by:

    1. David R. Leibrandt & Sergey G. Porsev & Charles Cheung & Marianna S. Safronova, 2024. "Prospects of a thousand-ion Sn2+ Coulomb-crystal clock with sub-10−19 inaccuracy," Nature Communications, Nature, vol. 15(1), pages 1-12, December.
    2. M. Schioppo & J. Kronjäger & A. Silva & R. Ilieva & J. W. Paterson & C. F. A. Baynham & W. Bowden & I. R. Hill & R. Hobson & A. Vianello & M. Dovale-Álvarez & R. A. Williams & G. Marra & H. S. Margoli, 2022. "Comparing ultrastable lasers at 7 × 10−17 fractional frequency instability through a 2220 km optical fibre network," Nature Communications, Nature, vol. 13(1), pages 1-11, December.
    3. Eliot A. Bohr & Sofus L. Kristensen & Christoph Hotter & Stefan A. Schäffer & Julian Robinson-Tait & Jan W. Thomsen & Tanya Zelevinsky & Helmut Ritsch & Jörg H. Müller, 2024. "Collectively enhanced Ramsey readout by cavity sub- to superradiant transition," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    4. Xin Zheng & Jonathan Dolde & Matthew C. Cambria & Hong Ming Lim & Shimon Kolkowitz, 2023. "A lab-based test of the gravitational redshift with a miniature clock network," Nature Communications, Nature, vol. 14(1), pages 1-9, December.

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