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Room-temperature strong coupling in a single-photon emitter-metasurface system

Author

Listed:
  • T. Thu Ha Do

    (Technology and Research))

  • Milad Nonahal

    (University of Technology Sydney
    Faculty of Science, University of Technology Sydney
    The University of Manchester)

  • Chi Li

    (University of Technology Sydney
    Faculty of Science, University of Technology Sydney
    Monash University)

  • Vytautas Valuckas

    (Technology and Research))

  • Hark Hoe Tan

    (The Australian National University
    The Australian National University)

  • Arseniy I. Kuznetsov

    (Technology and Research))

  • Hai Son Nguyen

    (UMR5270
    Institut Universitaire de France (IUF))

  • Igor Aharonovich

    (University of Technology Sydney
    Faculty of Science, University of Technology Sydney)

  • Son Tung Ha

    (Technology and Research))

Abstract

Solid state single-photon sources with high brightness and long coherence time are promising qubit candidates for modern quantum technology. To prevent decoherence processes and preserve the integrity of the qubits, decoupling the emitters from their surrounding environment is essential. To this end, interfacing single photon emitters (SPEs) with high-finesse cavities is required, especially in the strong coupling regime, when the interaction between emitters can be mediated by cavity fields. However, achieving strong coupling at elevated temperatures is challenging due to competing incoherent processes. Here, we address this long-standing problem by using a quantum system, which comprises a class of SPEs in hexagonal boron nitride and a dielectric cavity based on bound states in the continuum (BIC). We experimentally demonstrate, at room temperature, strong coupling of the system with a large Rabi splitting of ~4 meV thanks to the combination of the narrow linewidth and large oscillator strength of the emitters and the efficient photon trapping of the BIC cavity. Our findings unveil opportunities to advance the fundamental understanding of quantum dynamical system in strong coupling regime and to realise scalable quantum devices capable of operating at room temperature.

Suggested Citation

  • T. Thu Ha Do & Milad Nonahal & Chi Li & Vytautas Valuckas & Hark Hoe Tan & Arseniy I. Kuznetsov & Hai Son Nguyen & Igor Aharonovich & Son Tung Ha, 2024. "Room-temperature strong coupling in a single-photon emitter-metasurface system," Nature Communications, Nature, vol. 15(1), pages 1-8, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-46544-w
    DOI: 10.1038/s41467-024-46544-w
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    1. K. Hennessy & A. Badolato & M. Winger & D. Gerace & M. Atatüre & S. Gulde & S. Fält & E. L. Hu & A. Imamoğlu, 2007. "Quantum nature of a strongly coupled single quantum dot–cavity system," Nature, Nature, vol. 445(7130), pages 896-899, February.
    2. Hannah L. Stern & Qiushi Gu & John Jarman & Simone Eizagirre Barker & Noah Mendelson & Dipankar Chugh & Sam Schott & Hoe H. Tan & Henning Sirringhaus & Igor Aharonovich & Mete Atatüre, 2022. "Room-temperature optically detected magnetic resonance of single defects in hexagonal boron nitride," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    3. J. P. Reithmaier & G. Sęk & A. Löffler & C. Hofmann & S. Kuhn & S. Reitzenstein & L. V. Keldysh & V. D. Kulakovskii & T. L. Reinecke & A. Forchel, 2004. "Strong coupling in a single quantum dot–semiconductor microcavity system," Nature, Nature, vol. 432(7014), pages 197-200, November.
    4. Clarisse Fournier & Alexandre Plaud & Sébastien Roux & Aurélie Pierret & Michael Rosticher & Kenji Watanabe & Takashi Taniguchi & Stéphanie Buil & Xavier Quélin & Julien Barjon & Jean-Pierre Hermier &, 2021. "Position-controlled quantum emitters with reproducible emission wavelength in hexagonal boron nitride," Nature Communications, Nature, vol. 12(1), pages 1-6, December.
    5. T. Yoshie & A. Scherer & J. Hendrickson & G. Khitrova & H. M. Gibbs & G. Rupper & C. Ell & O. B. Shchekin & D. G. Deppe, 2004. "Vacuum Rabi splitting with a single quantum dot in a photonic crystal nanocavity," Nature, Nature, vol. 432(7014), pages 200-203, November.
    6. Ashok Kodigala & Thomas Lepetit & Qing Gu & Babak Bahari & Yeshaiahu Fainman & Boubacar Kanté, 2017. "Lasing action from photonic bound states in continuum," Nature, Nature, vol. 541(7636), pages 196-199, January.
    7. K. M. Birnbaum & A. Boca & R. Miller & A. D. Boozer & T. E. Northup & H. J. Kimble, 2005. "Photon blockade in an optical cavity with one trapped atom," Nature, Nature, vol. 436(7047), pages 87-90, July.
    8. H. J. Kimble, 2008. "The quantum internet," Nature, Nature, vol. 453(7198), pages 1023-1030, June.
    9. V. Ardizzone & F. Riminucci & S. Zanotti & A. Gianfrate & M. Efthymiou-Tsironi & D. G. Suàrez-Forero & F. Todisco & M. Giorgi & D. Trypogeorgos & G. Gigli & K. Baldwin & L. Pfeiffer & D. Ballarini & H, 2022. "Polariton Bose–Einstein condensate from a bound state in the continuum," Nature, Nature, vol. 605(7910), pages 447-452, May.
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