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Experimental demonstration of memory-enhanced quantum communication

Author

Listed:
  • M. K. Bhaskar

    (Harvard University)

  • R. Riedinger

    (Harvard University)

  • B. Machielse

    (Harvard University)

  • D. S. Levonian

    (Harvard University)

  • C. T. Nguyen

    (Harvard University)

  • E. N. Knall

    (Harvard University)

  • H. Park

    (Harvard University
    Harvard University)

  • D. Englund

    (Research Laboratory of Electronics, MIT)

  • M. Lončar

    (Harvard University)

  • D. D. Sukachev

    (Harvard University)

  • M. D. Lukin

    (Harvard University)

Abstract

The ability to communicate quantum information over long distances is of central importance in quantum science and engineering1. Although some applications of quantum communication such as secure quantum key distribution2,3 are already being successfully deployed4–7, their range is currently limited by photon losses and cannot be extended using straightforward measure-and-repeat strategies without compromising unconditional security8. Alternatively, quantum repeaters9, which utilize intermediate quantum memory nodes and error correction techniques, can extend the range of quantum channels. However, their implementation remains an outstanding challenge10–16, requiring a combination of efficient and high-fidelity quantum memories, gate operations, and measurements. Here we use a single solid-state spin memory integrated in a nanophotonic diamond resonator17–19 to implement asynchronous photonic Bell-state measurements, which are a key component of quantum repeaters. In a proof-of-principle experiment, we demonstrate high-fidelity operation that effectively enables quantum communication at a rate that surpasses the ideal loss-equivalent direct-transmission method while operating at megahertz clock speeds. These results represent a crucial step towards practical quantum repeaters and large-scale quantum networks20,21.

Suggested Citation

  • M. K. Bhaskar & R. Riedinger & B. Machielse & D. S. Levonian & C. T. Nguyen & E. N. Knall & H. Park & D. Englund & M. Lončar & D. D. Sukachev & M. D. Lukin, 2020. "Experimental demonstration of memory-enhanced quantum communication," Nature, Nature, vol. 580(7801), pages 60-64, April.
    • Handle: RePEc:nat:nature:v:580:y:2020:i:7801:d:10.1038_s41586-020-2103-5
    DOI: 10.1038/s41586-020-2103-5
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    Cited by:

    1. E. Mehdi & M. Gundín & C. Millet & N. Somaschi & A. Lemaître & I. Sagnes & L. Gratiet & D. A. Fioretto & N. Belabas & O. Krebs & P. Senellart & L. Lanco, 2024. "Giant optical polarisation rotations induced by a single quantum dot spin," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    2. Adam Johnston & Ulises Felix-Rendon & Yu-En Wong & Songtao Chen, 2024. "Cavity-coupled telecom atomic source in silicon," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    3. Hodaka Kurokawa & Keidai Wakamatsu & Shintaro Nakazato & Toshiharu Makino & Hiromitsu Kato & Yuhei Sekiguchi & Hideo Kosaka, 2024. "Coherent electric field control of orbital state of a neutral nitrogen-vacancy center," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    4. Hanfeng Wang & Matthew E. Trusheim & Laura Kim & Hamza Raniwala & Dirk R. Englund, 2023. "Field programmable spin arrays for scalable quantum repeaters," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    5. Ryan Snodgrass & Vincent Kotsubo & Scott Backhaus & Joel Ullom, 2024. "Dynamic acoustic optimization of pulse tube refrigerators for rapid cooldown," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    6. Mihika Prabhu & Carlos Errando-Herranz & Lorenzo Santis & Ian Christen & Changchen Chen & Connor Gerlach & Dirk Englund, 2023. "Individually addressable and spectrally programmable artificial atoms in silicon photonics," Nature Communications, Nature, vol. 14(1), pages 1-7, December.

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