2023
DOI: 10.1038/s41566-023-01248-3
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Spin-selective strong light–matter coupling in a 2D hole gas-microcavity system

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Cited by 5 publications
(1 citation statement)
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“…Recently, room-temperature strong coupling between quantum emitters and plasmons has attracted a lot of attention in optical and quantum physics. In the strong light–matter coupling regime, the energy exchange between plasmons and matter excitations becomes faster than the dissipation and decoherence, producing new optical hybrid states called plexcitons. Plexcitons can facilitate studies of coherent energy transfer, quantum entanglement, Bose–Einstein condensation, and other quantum phenomena, exhibiting great potential in quantum light sources, , single-molecule sensing, and quantum computing . Due to the great advantages in miniaturization, stability, and fine-controllability, strongly coupled systems of metal plasmonic nanocavities–emitters have become a significant research direction in room-temperature strong coupling. , More noteworthy, recent advances have combined plexcitons with a single broken symmetry to unlock their rich many-body nature, greatly promoting the fields of chiroptics, magneto-optics, and polariton physics. However, in conventional plasmonic hybrid nanocavities governed by single asymmetrical plexcitons, such as chiral plexcitons and magnetically dressed plexcitons, nonreciprocity is missing. The absence of a plexcitonic nonreciprocal mechanism limits the development of optical technologies dominated by light–matter polaritons.…”
mentioning
confidence: 99%
“…Recently, room-temperature strong coupling between quantum emitters and plasmons has attracted a lot of attention in optical and quantum physics. In the strong light–matter coupling regime, the energy exchange between plasmons and matter excitations becomes faster than the dissipation and decoherence, producing new optical hybrid states called plexcitons. Plexcitons can facilitate studies of coherent energy transfer, quantum entanglement, Bose–Einstein condensation, and other quantum phenomena, exhibiting great potential in quantum light sources, , single-molecule sensing, and quantum computing . Due to the great advantages in miniaturization, stability, and fine-controllability, strongly coupled systems of metal plasmonic nanocavities–emitters have become a significant research direction in room-temperature strong coupling. , More noteworthy, recent advances have combined plexcitons with a single broken symmetry to unlock their rich many-body nature, greatly promoting the fields of chiroptics, magneto-optics, and polariton physics. However, in conventional plasmonic hybrid nanocavities governed by single asymmetrical plexcitons, such as chiral plexcitons and magnetically dressed plexcitons, nonreciprocity is missing. The absence of a plexcitonic nonreciprocal mechanism limits the development of optical technologies dominated by light–matter polaritons.…”
mentioning
confidence: 99%