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Room temperature polariton lasing in quantum heterostructure nanocavities.

Jang-Won KangBokyung SongWenjing LiuSeong-Ju ParkRitesh AgarwalChang-Hee Cho
Published in: Science advances (2019)
Ultralow-threshold coherent light emitters can be achieved through lasing from exciton-polariton condensates, but this generally requires sophisticated device structures and cryogenic temperatures. Polaritonic nanolasers operating at room temperature lie on the crucial path of related research, not only for the exploration of polariton physics at the nanoscale but also for potential applications in quantum information systems, all-optical logic gates, and ultralow-threshold lasers. However, at present, progress toward room temperature polariton nanolasers has been limited by the thermal instability of excitons and the inherently low quality factors of nanocavities. Here, we demonstrate room temperature polaritonic nanolasers by designing wide-gap semiconductor heterostructure nanocavities to produce thermally stable excitons coupled with nanocavity photons. The resulting mixed states of exciton polaritons with Rabi frequencies of approximately 370 meV enable persistent polariton lasing up to room temperature, facilitating the realization of miniaturized and integrated polariton systems.
Keyphrases
  • room temperature
  • ionic liquid
  • energy transfer
  • molecular dynamics
  • high resolution
  • healthcare
  • mass spectrometry
  • risk assessment
  • quantum dots
  • climate change
  • health information