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Gravitationally induced decoherence vs space-time diffusion: testing the quantum nature of gravity

Author

Listed:
  • Jonathan Oppenheim

    (University College London)

  • Carlo Sparaciari

    (University College London)

  • Barbara Šoda

    (University College London
    University of Waterloo
    Perimeter Institute for Theoretical Physics)

  • Zachary Weller-Davies

    (University College London
    Perimeter Institute for Theoretical Physics)

Abstract

We consider two interacting systems when one is treated classically while the other system remains quantum. Consistent dynamics of this coupling has been shown to exist, and explored in the context of treating space-time classically. Here, we prove that any such hybrid dynamics necessarily results in decoherence of the quantum system, and a breakdown in predictability in the classical phase space. We further prove that a trade-off between the rate of this decoherence and the degree of diffusion induced in the classical system is a general feature of all classical quantum dynamics; long coherence times require strong diffusion in phase-space relative to the strength of the coupling. Applying the trade-off relation to gravity, we find a relationship between the strength of gravitationally-induced decoherence versus diffusion of the metric and its conjugate momenta. This provides an experimental signature of theories in which gravity is fundamentally classical. Bounds on decoherence rates arising from current interferometry experiments, combined with precision measurements of mass, place significant restrictions on theories where Einstein’s classical theory of gravity interacts with quantum matter. We find that part of the parameter space of such theories are already squeezed out, and provide figures of merit which can be used in future mass measurements and interference experiments.

Suggested Citation

  • Jonathan Oppenheim & Carlo Sparaciari & Barbara Šoda & Zachary Weller-Davies, 2023. "Gravitationally induced decoherence vs space-time diffusion: testing the quantum nature of gravity," Nature Communications, Nature, vol. 14(1), pages 1-24, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-43348-2
    DOI: 10.1038/s41467-023-43348-2
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    References listed on IDEAS

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    1. Markus Arndt & Olaf Nairz & Julian Vos-Andreae & Claudia Keller & Gerbrand van der Zouw & Anton Zeilinger, 1999. "Wave–particle duality of C60 molecules," Nature, Nature, vol. 401(6754), pages 680-682, October.
    2. Tobias Westphal & Hans Hepach & Jeremias Pfaff & Markus Aspelmeyer, 2021. "Measurement of gravitational coupling between millimetre-sized masses," Nature, Nature, vol. 591(7849), pages 225-228, March.
    3. Stefan Gerlich & Sandra Eibenberger & Mathias Tomandl & Stefan Nimmrichter & Klaus Hornberger & Paul J. Fagan & Jens Tüxen & Marcel Mayor & Markus Arndt, 2011. "Quantum interference of large organic molecules," Nature Communications, Nature, vol. 2(1), pages 1-5, September.
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