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Room temperature exciton–polariton Bose–Einstein condensation in organic single-crystal microribbon cavities

Author

Listed:
  • Ji Tang

    (Chinese Academy of Sciences
    University of Chinese Academy of Sciences)

  • Jian Zhang

    (Chinese Academy of Sciences)

  • Yuanchao Lv

    (Chinese Academy of Sciences)

  • Hong Wang

    (Chinese Academy of Sciences
    University of Chinese Academy of Sciences)

  • Fa Feng Xu

    (Chinese Academy of Sciences
    University of Chinese Academy of Sciences)

  • Chuang Zhang

    (Chinese Academy of Sciences
    University of Chinese Academy of Sciences)

  • Liaoxin Sun

    (Chinese Academy of Sciences)

  • Jiannian Yao

    (Chinese Academy of Sciences
    University of Chinese Academy of Sciences)

  • Yong Sheng Zhao

    (Chinese Academy of Sciences
    University of Chinese Academy of Sciences)

Abstract

Exciton–polariton Bose–Einstein condensation (EP BEC) is of crucial importance for the development of coherent light sources and optical logic elements, as it creates a new state of matter with coherent nature and nonlinear behaviors. The demand for room temperature EP BEC has driven the development of organic polaritons because of the large binding energies of Frenkel excitons in organic materials. However, the reliance on external high-finesse microcavities for organic EP BEC results in poor compactness and integrability of devices, which restricts their practical applications in on-chip integration. Here, we demonstrate room temperature EP BEC in organic single-crystal microribbon natural cavities. The regularly shaped microribbons serve as waveguide Fabry–Pérot microcavities, in which efficient strong coupling between Frenkel excitons and photons leads to the generation of EPs at room temperature. The large exciton–photon coupling strength due to high exciton densities facilitates the achievement of EP BEC. Taking advantages of interactions in EP condensates and dimension confinement effects, we demonstrate the realization of controllable output of coherent light from the microribbons. We hope that the results will provide a useful enlightenment for using organic single crystals to construct miniaturized polaritonic devices.

Suggested Citation

  • Ji Tang & Jian Zhang & Yuanchao Lv & Hong Wang & Fa Feng Xu & Chuang Zhang & Liaoxin Sun & Jiannian Yao & Yong Sheng Zhao, 2021. "Room temperature exciton–polariton Bose–Einstein condensation in organic single-crystal microribbon cavities," Nature Communications, Nature, vol. 12(1), pages 1-8, December.
    • Handle: RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-23524-y
    DOI: 10.1038/s41467-021-23524-y
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    Cited by:

    1. Raj Pandya & Richard Y. S. Chen & Qifei Gu & Jooyoung Sung & Christoph Schnedermann & Oluwafemi S. Ojambati & Rohit Chikkaraddy & Jeffrey Gorman & Gianni Jacucci & Olimpia D. Onelli & Tom Willhammar &, 2021. "Microcavity-like exciton-polaritons can be the primary photoexcitation in bare organic semiconductors," Nature Communications, Nature, vol. 12(1), pages 1-11, December.

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