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Signatures of self-organized criticality in an ultracold atomic gas

Author

Listed:
  • S. Helmrich

    (Universität Heidelberg)

  • A. Arias

    (Universität Heidelberg
    University of Strasbourg and CNRS
    University of Strasbourg and CNRS)

  • G. Lochead

    (Universität Heidelberg
    University of Strasbourg and CNRS
    University of Strasbourg and CNRS)

  • T. M. Wintermantel

    (Universität Heidelberg
    University of Strasbourg and CNRS
    University of Strasbourg and CNRS)

  • M. Buchhold

    (California Institute of Technology
    California Institute of Technology)

  • S. Diehl

    (Universität zu Köln)

  • S. Whitlock

    (Universität Heidelberg
    University of Strasbourg and CNRS
    University of Strasbourg and CNRS)

Abstract

Self-organized criticality is an elegant explanation of how complex structures emerge and persist throughout nature1, and why such structures often exhibit similar scale-invariant properties2–9. Although self-organized criticality is sometimes captured by simple models that feature a critical point as an attractor for the dynamics10–15, the connection to real-world systems is exceptionally hard to test quantitatively16–21. Here we observe three key signatures of self-organized criticality in the dynamics of a driven–dissipative gas of ultracold potassium atoms: self-organization to a stationary state that is largely independent of the initial conditions; scale-invariance of the final density characterized by a unique scaling function; and large fluctuations of the number of excited atoms (avalanches) obeying a characteristic power-law distribution. This work establishes a well-controlled platform for investigating self-organization phenomena and non-equilibrium criticality, with experimental access to the underlying microscopic details of the system.

Suggested Citation

  • S. Helmrich & A. Arias & G. Lochead & T. M. Wintermantel & M. Buchhold & S. Diehl & S. Whitlock, 2020. "Signatures of self-organized criticality in an ultracold atomic gas," Nature, Nature, vol. 577(7791), pages 481-486, January.
  • Handle: RePEc:nat:nature:v:577:y:2020:i:7791:d:10.1038_s41586-019-1908-6
    DOI: 10.1038/s41586-019-1908-6
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    Cited by:

    1. Bang Liu & Li-Hua Zhang & Qi-Feng Wang & Yu Ma & Tian-Yu Han & Jun Zhang & Zheng-Yuan Zhang & Shi-Yao Shao & Qing Li & Han-Chao Chen & Bao-Sen Shi & Dong-Sheng Ding, 2024. "Higher-order and fractional discrete time crystals in Floquet-driven Rydberg atoms," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    2. Giacomo Bighin & Tilman Enss & Nicolò Defenu, 2024. "Universal scaling in real dimension," Nature Communications, Nature, vol. 15(1), pages 1-9, December.

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