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Exploring large-scale entanglement in quantum simulation

Author

Listed:
  • Manoj K. Joshi

    (Austrian Academy of Sciences
    University of Innsbruck, Institute for Experimental Physics)

  • Christian Kokail

    (Austrian Academy of Sciences
    University of Innsbruck, Institute for Theoretical Physics)

  • Rick Bijnen

    (Austrian Academy of Sciences
    University of Innsbruck, Institute for Theoretical Physics)

  • Florian Kranzl

    (Austrian Academy of Sciences
    University of Innsbruck, Institute for Experimental Physics)

  • Torsten V. Zache

    (Austrian Academy of Sciences
    University of Innsbruck, Institute for Theoretical Physics)

  • Rainer Blatt

    (Austrian Academy of Sciences
    University of Innsbruck, Institute for Experimental Physics)

  • Christian F. Roos

    (Austrian Academy of Sciences
    University of Innsbruck, Institute for Experimental Physics)

  • Peter Zoller

    (Austrian Academy of Sciences
    University of Innsbruck, Institute for Theoretical Physics)

Abstract

Entanglement is a distinguishing feature of quantum many-body systems, and uncovering the entanglement structure for large particle numbers in quantum simulation experiments is a fundamental challenge in quantum information science1. Here we perform experimental investigations of entanglement on the basis of the entanglement Hamiltonian (EH)2 as an effective description of the reduced density operator for large subsystems. We prepare ground and excited states of a one-dimensional XXZ Heisenberg chain on a 51-ion programmable quantum simulator3 and perform sample-efficient ‘learning’ of the EH for subsystems of up to 20 lattice sites4. Our experiments provide compelling evidence for a local structure of the EH. To our knowledge, this observation marks the first instance of confirming the fundamental predictions of quantum field theory by Bisognano and Wichmann5,6, adapted to lattice models that represent correlated quantum matter. The reduced state takes the form of a Gibbs ensemble, with a spatially varying temperature profile as a signature of entanglement2. Our results also show the transition from area- to volume-law scaling7 of von Neumann entanglement entropies from ground to excited states. As we venture towards achieving quantum advantage, we anticipate that our findings and methods have wide-ranging applicability to revealing and understanding entanglement in many-body problems with local interactions including higher spatial dimensions.

Suggested Citation

  • Manoj K. Joshi & Christian Kokail & Rick Bijnen & Florian Kranzl & Torsten V. Zache & Rainer Blatt & Christian F. Roos & Peter Zoller, 2023. "Exploring large-scale entanglement in quantum simulation," Nature, Nature, vol. 624(7992), pages 539-544, December.
    • Handle: RePEc:nat:nature:v:624:y:2023:i:7992:d:10.1038_s41586-023-06768-0
    DOI: 10.1038/s41586-023-06768-0
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    Cited by:

    1. Ya-Dong Wu & Yan Zhu & Yuexuan Wang & Giulio Chiribella, 2024. "Learning quantum properties from short-range correlations using multi-task networks," Nature Communications, Nature, vol. 15(1), pages 1-14, December.

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