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Quantum circuits with many photons on a programmable nanophotonic chip

Author

Listed:
  • J. M. Arrazola

    (Xanadu)

  • V. Bergholm

    (Xanadu)

  • K. Brádler

    (Xanadu)

  • T. R. Bromley

    (Xanadu)

  • M. J. Collins

    (Xanadu)

  • I. Dhand

    (Xanadu)

  • A. Fumagalli

    (Xanadu)

  • T. Gerrits

    (National Institute of Standards and Technology)

  • A. Goussev

    (Xanadu)

  • L. G. Helt

    (Xanadu)

  • J. Hundal

    (Xanadu)

  • T. Isacsson

    (Xanadu)

  • R. B. Israel

    (Xanadu)

  • J. Izaac

    (Xanadu)

  • S. Jahangiri

    (Xanadu)

  • R. Janik

    (Xanadu)

  • N. Killoran

    (Xanadu)

  • S. P. Kumar

    (Xanadu)

  • J. Lavoie

    (Xanadu)

  • A. E. Lita

    (National Institute of Standards and Technology)

  • D. H. Mahler

    (Xanadu)

  • M. Menotti

    (Xanadu)

  • B. Morrison

    (Xanadu)

  • S. W. Nam

    (National Institute of Standards and Technology)

  • L. Neuhaus

    (Xanadu)

  • H. Y. Qi

    (Xanadu)

  • N. Quesada

    (Xanadu)

  • A. Repingon

    (Xanadu)

  • K. K. Sabapathy

    (Xanadu)

  • M. Schuld

    (Xanadu)

  • D. Su

    (Xanadu)

  • J. Swinarton

    (Xanadu)

  • A. Száva

    (Xanadu)

  • K. Tan

    (Xanadu)

  • P. Tan

    (Xanadu)

  • V. D. Vaidya

    (Xanadu)

  • Z. Vernon

    (Xanadu)

  • Z. Zabaneh

    (Xanadu)

  • Y. Zhang

    (Xanadu)

Abstract

Growing interest in quantum computing for practical applications has led to a surge in the availability of programmable machines for executing quantum algorithms1,2. Present-day photonic quantum computers3–7 have been limited either to non-deterministic operation, low photon numbers and rates, or fixed random gate sequences. Here we introduce a full-stack hardware−software system for executing many-photon quantum circuit operations using integrated nanophotonics: a programmable chip, operating at room temperature and interfaced with a fully automated control system. The system enables remote users to execute quantum algorithms that require up to eight modes of strongly squeezed vacuum initialized as two-mode squeezed states in single temporal modes, a fully general and programmable four-mode interferometer, and photon number-resolving readout on all outputs. Detection of multi-photon events with photon numbers and rates exceeding any previous programmable quantum optical demonstration is made possible by strong squeezing and high sampling rates. We verify the non-classicality of the device output, and use the platform to carry out proof-of-principle demonstrations of three quantum algorithms: Gaussian boson sampling, molecular vibronic spectra and graph similarity8. These demonstrations validate the platform as a launchpad for scaling photonic technologies for quantum information processing.

Suggested Citation

  • J. M. Arrazola & V. Bergholm & K. Brádler & T. R. Bromley & M. J. Collins & I. Dhand & A. Fumagalli & T. Gerrits & A. Goussev & L. G. Helt & J. Hundal & T. Isacsson & R. B. Israel & J. Izaac & S. Jaha, 2021. "Quantum circuits with many photons on a programmable nanophotonic chip," Nature, Nature, vol. 591(7848), pages 54-60, March.
    • Handle: RePEc:nat:nature:v:591:y:2021:i:7848:d:10.1038_s41586-021-03202-1
    DOI: 10.1038/s41586-021-03202-1
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    Citations

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    Cited by:

    1. Hui Hui Zhu & Hao Chen & Tian Chen & Yuan Li & Shao Bo Luo & Muhammad Faeyz Karim & Xian Shu Luo & Feng Gao & Qiang Li & Hong Cai & Lip Ket Chin & Leong Chuan Kwek & Bengt Nordén & Xiang Dong Zhang & , 2024. "Large-scale photonic network with squeezed vacuum states for molecular vibronic spectroscopy," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    2. Takaya Ochiai & Tomohiro Akazawa & Yuto Miyatake & Kei Sumita & Shuhei Ohno & Stéphane Monfray & Frederic Boeuf & Kasidit Toprasertpong & Shinichi Takagi & Mitsuru Takenaka, 2022. "Ultrahigh-responsivity waveguide-coupled optical power monitor for Si photonic circuits operating at near-infrared wavelengths," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    3. F. H. B. Somhorst & R. Meer & M. Correa Anguita & R. Schadow & H. J. Snijders & M. Goede & B. Kassenberg & P. Venderbosch & C. Taballione & J. P. Epping & H. H. Vlekkert & J. Timmerhuis & J. F. F. Bul, 2023. "Quantum simulation of thermodynamics in an integrated quantum photonic processor," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    4. Emma Lomonte & Martin A. Wolff & Fabian Beutel & Simone Ferrari & Carsten Schuck & Wolfram H. P. Pernice & Francesco Lenzini, 2021. "Single-photon detection and cryogenic reconfigurability in lithium niobate nanophotonic circuits," Nature Communications, Nature, vol. 12(1), pages 1-10, December.
    5. Xuan-Kun Li & Jian-Xu Ma & Xiang-Yu Li & Jun-Jie Hu & Chuan-Yang Ding & Feng-Kai Han & Xiao-Min Guo & Xi Tan & Xian-Min Jin, 2024. "High-efficiency reinforcement learning with hybrid architecture photonic integrated circuit," Nature Communications, Nature, vol. 15(1), pages 1-10, December.
    6. X. L. He & Yong Lu & D. Q. Bao & Hang Xue & W. B. Jiang & Z. Wang & A. F. Roudsari & Per Delsing & J. S. Tsai & Z. R. Lin, 2023. "Fast generation of Schrödinger cat states using a Kerr-tunable superconducting resonator," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    7. Sunkyu Yu & Namkyoo Park, 2023. "Heavy tails and pruning in programmable photonic circuits for universal unitaries," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    8. Zihan Li & Rui Ning Wang & Grigory Lihachev & Junyin Zhang & Zelin Tan & Mikhail Churaev & Nikolai Kuznetsov & Anat Siddharth & Mohammad J. Bereyhi & Johann Riemensberger & Tobias J. Kippenberg, 2023. "High density lithium niobate photonic integrated circuits," Nature Communications, Nature, vol. 14(1), pages 1-8, December.

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