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Experimental signature of programmable quantum annealing

Author

Listed:
  • Sergio Boixo

    (Information Sciences Institute, University of Southern California
    University of Southern California
    Center for Quantum Information Science & Technology, University of Southern California)

  • Tameem Albash

    (Center for Quantum Information Science & Technology, University of Southern California
    University of Southern California)

  • Federico M. Spedalieri

    (Information Sciences Institute, University of Southern California
    Center for Quantum Information Science & Technology, University of Southern California)

  • Nicholas Chancellor

    (University of Southern California)

  • Daniel A. Lidar

    (University of Southern California
    Center for Quantum Information Science & Technology, University of Southern California
    University of Southern California
    University of Southern California)

Abstract

Quantum annealing is a general strategy for solving difficult optimization problems with the aid of quantum adiabatic evolution. Both analytical and numerical evidence suggests that under idealized, closed system conditions, quantum annealing can outperform classical thermalization-based algorithms such as simulated annealing. Current engineered quantum annealing devices have a decoherence timescale which is orders of magnitude shorter than the adiabatic evolution time. Do they effectively perform classical thermalization when coupled to a decohering thermal environment? Here we present an experimental signature which is consistent with quantum annealing, and at the same time inconsistent with classical thermalization. Our experiment uses groups of eight superconducting flux qubits with programmable spin–spin couplings, embedded on a commercially available chip with >100 functional qubits. This suggests that programmable quantum devices, scalable with current superconducting technology, implement quantum annealing with a surprising robustness against noise and imperfections.

Suggested Citation

  • Sergio Boixo & Tameem Albash & Federico M. Spedalieri & Nicholas Chancellor & Daniel A. Lidar, 2013. "Experimental signature of programmable quantum annealing," Nature Communications, Nature, vol. 4(1), pages 1-8, October.
    • Handle: RePEc:nat:natcom:v:4:y:2013:i:1:d:10.1038_ncomms3067
    DOI: 10.1038/ncomms3067
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    Cited by:

    1. Jaka Vodeb & Michele Diego & Yevhenii Vaskivskyi & Leonard Logaric & Yaroslav Gerasimenko & Viktor Kabanov & Benjamin Lipovsek & Marko Topic & Dragan Mihailovic, 2024. "Non-equilibrium quantum domain reconfiguration dynamics in a two-dimensional electronic crystal and a quantum annealer," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    2. Kurowski, Krzysztof & Pecyna, Tomasz & Slysz, Mateusz & Różycki, Rafał & Waligóra, Grzegorz & Wȩglarz, Jan, 2023. "Application of quantum approximate optimization algorithm to job shop scheduling problem," European Journal of Operational Research, Elsevier, vol. 310(2), pages 518-528.
    3. Deng, Zhipeng & Wang, Xuezheng & Dong, Bing, 2023. "Quantum computing for future real-time building HVAC controls," Applied Energy, Elsevier, vol. 334(C).

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