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Ultrafast photoluminescence and multiscale light amplification in nanoplasmonic cavity glass

Author

Listed:
  • Piotr Piotrowski

    (Centre of Excellence ENSEMBLE3 sp. z o.o
    University of Warsaw)

  • Marta Buza

    ((Formerly at) Institute of Electronic Materials Technology)

  • Rafał Nowaczyński

    (University of Warsaw
    Warsaw University of Technology)

  • Nuttawut Kongsuwan

    (Quantum Technology Foundation (Thailand)
    Ministry of Higher Education, Science, Research and Innovation)

  • Hańcza B. Surma

    (Centre of Excellence ENSEMBLE3 sp. z o.o
    (Formerly at) Institute of Electronic Materials Technology)

  • Paweł Osewski

    ((Formerly at) Institute of Electronic Materials Technology)

  • Marcin Gajc

    ((Formerly at) Institute of Electronic Materials Technology)

  • Adam Strzep

    (Institute of Low Temperature and Structure Research PAS)

  • Witold Ryba-Romanowski

    (Institute of Low Temperature and Structure Research PAS)

  • Ortwin Hess

    (Trinity College Dublin)

  • Dorota A. Pawlak

    (Centre of Excellence ENSEMBLE3 sp. z o.o
    University of Warsaw
    (Formerly at) Institute of Electronic Materials Technology)

Abstract

Interactions between plasmons and exciton nanoemitters in plexcitonic systems lead to fast and intense luminescence, desirable in optoelectonic devices, ultrafast optical switches and quantum information science. While luminescence enhancement through exciton-plasmon coupling has thus far been mostly demonstrated in micro- and nanoscale structures, analogous demonstrations in bulk materials have been largely neglected. Here we present a bulk nanocomposite glass doped with cadmium telluride quantum dots (CdTe QDs) and silver nanoparticles, nAg, which act as exciton and plasmon sources, respectively. This glass exhibits ultranarrow, FWHM = 13 nm, and ultrafast, 90 ps, amplified photoluminescence (PL), λem≅503 nm, at room temperature under continuous-wave excitation, λexc = 405 nm. Numerical simulations confirm that the observed improvement in emission is a result of a multiscale light enhancement owing to the ensemble of QD-populated plasmonic nanocavities in the material. Power-dependent measurements indicate that >100 mW coherent light amplification occurs. These types of bulk plasmon-exciton composites could be designed comprising a plethora of components/functionalities, including emitters (QDs, rare earth and transition metal ions) and nanoplasmonic elements (Ag/Au/TCO, spherical/anisotropic/miscellaneous), to achieve targeted applications.

Suggested Citation

  • Piotr Piotrowski & Marta Buza & Rafał Nowaczyński & Nuttawut Kongsuwan & Hańcza B. Surma & Paweł Osewski & Marcin Gajc & Adam Strzep & Witold Ryba-Romanowski & Ortwin Hess & Dorota A. Pawlak, 2024. "Ultrafast photoluminescence and multiscale light amplification in nanoplasmonic cavity glass," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-47539-3
    DOI: 10.1038/s41467-024-47539-3
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    References listed on IDEAS

    as
    1. Thang B. Hoang & Gleb M. Akselrod & Christos Argyropoulos & Jiani Huang & David R. Smith & Maiken H. Mikkelsen, 2015. "Ultrafast spontaneous emission source using plasmonic nanoantennas," Nature Communications, Nature, vol. 6(1), pages 1-7, November.
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    3. A. V. Akimov & A. Mukherjee & C. L. Yu & D. E. Chang & A. S. Zibrov & P. R. Hemmer & H. Park & M. D. Lukin, 2007. "Generation of single optical plasmons in metallic nanowires coupled to quantum dots," Nature, Nature, vol. 450(7168), pages 402-406, November.
    4. Ekaterina I. Galanzha & Robert Weingold & Dmitry A. Nedosekin & Mustafa Sarimollaoglu & Jacqueline Nolan & Walter Harrington & Alexander S. Kuchyanov & Roman G. Parkhomenko & Fumiya Watanabe & Zeid Ni, 2017. "Spaser as a biological probe," Nature Communications, Nature, vol. 8(1), pages 1-7, August.
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