Manipulating chiral photon generation from plasmonic nanocavity-emitter hybrid systems: from weak to strong coupling

By confining light into a deep subwavelength scale to match the characteristic dimension of quantum emitters, plasmonic nanocavities can effectively imprint the light emission with unique properties in terms of intensity, directionality, as well as polarization. In this vein, achiral quantum emitter...

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Published in:Nanophotonics (Berlin, Germany) Germany), 2024-02, Vol.13 (3), p.357-368
Main Authors: Yang, Jian, Hu, Huatian, Zhang, Qingfeng, Zu, Shuai, Chen, Wen, Xu, Hongxing
Format: Article
Language:English
Subjects:
chiral coupled oscillator model
chiral Jaynes–Cummings model
chiral photon generation
chiral plasmons
Chirality
Circular polarization
Coupling
Electrons
Emitters
high degree of circular polarization
Hybrid systems
Laboratories
Light emission
Luminescence
Luminous intensity
Photons
Physics
Plasmonics
Plasmons
Quantum dots
Scattering
strong coupling
Symmetry
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Summary:By confining light into a deep subwavelength scale to match the characteristic dimension of quantum emitters, plasmonic nanocavities can effectively imprint the light emission with unique properties in terms of intensity, directionality, as well as polarization. In this vein, achiral quantum emitters can generate chiral photons through coupling with plasmonic nanocavities with either intrinsic or extrinsic chirality. As an important metric for the chiral-photon purity, the degree of circular polarization (DCP) is usually tuned by various scattered factors such as the nanocavity design, the emitter type, and the coupling strategy. The physical mechanisms of the chiral photon generation, especially when plasmons and emitters step into the strong coupling regime, are less explored. In this paper, we extended the coupled-oscillator and Jaynes–Cummings models to their chiral fashion to account for the above factors within a single theoretical framework and investigated the chiroptical properties of a plasmonic nanocavity-emitter hybrid system from weak to strong coupling. It was demonstrated that both the circular differential scattering and prominent scattering DCP rely on the intrinsic chirality generated by breaking the mirror symmetry with the emitter, and is thereby tunable by the coupling strength. However, the luminescence DCP (as high as 87 %) is closely related to the extrinsic chirality of the bare nanocavity and independent of the coupling strength. The results thus reveal two different physical mechanisms of generating chiral photons in scattering and luminescence. Our findings provide a theoretical guideline for designing chiral photon devices and contribute to the understanding of chiral plasmon-emitter interaction.
ISSN:2192-8614
2192-8606
2192-8614
DOI:10.1515/nanoph-2023-0738