Pyramidal Hyperbolic Metasurfaces Enhance Spontaneous Emission of Nitrogen‐Vacancy Centers in Nanodiamond

Nitrogen‐vacancy (NV) centers in nanodiamond hold great promise for creating superior biological labels and quantum sensing methods. Yet, inefficient photon generation and extraction from excited NV centers restrict the achievable sensitivity and temporal resolution. Herein, an entirely complementar...

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Veröffentlicht in:	Advanced optical materials 2023-03, Vol.11 (6), p.n/a
Hauptverfasser:	Zheng, Peng, Liang, Le, Arora, Saransh, Ray, Krishanu, Semancik, Steve, Barman, Ishan
Format:	Artikel
Sprache:	eng
Schlagworte:	Broadband Decay rate Diamonds hyperbolic metasurfaces Materials science Metasurfaces nanodiamond nanopyramid arrays Nanospheres Nanostructure Nitrogen nitrogen‐vacancy centers Optics Photons plasmonics Spontaneous emission Temporal resolution Thin films
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description	Nitrogen‐vacancy (NV) centers in nanodiamond hold great promise for creating superior biological labels and quantum sensing methods. Yet, inefficient photon generation and extraction from excited NV centers restrict the achievable sensitivity and temporal resolution. Herein, an entirely complementary route featuring pyramidal hyperbolic metasurface is reported to modify the spontaneous emission of NV centers. Fabricated using nanosphere lithography, the metasurface consists of alternatively stacked silica–silver thin films configured in a pyramidal fashion, and supports both spectrally broadband Purcell enhancement and spatially extended intense local fields owing to the hyperbolic dispersion and plasmonic coupling. The enhanced photophysical properties are manifested as a simultaneous amplification to the spontaneous decay rate and emission intensity of NV centers. It is envisioned that the reported pyramidal metasurface can serve as a versatile platform for creating chip‐based ultrafast single‐photon sources and spin‐enhanced quantum biosensing strategies, as well as aid in further fundamental understanding of photoexcited species in condensed phases. A plasmonic hyperbolic metasurface consisting of alternatively stacked silica–silver thin films configured in a pyramidal fashion is developed and found to support both spectrally broadband Purcell enhancement and spatially extended intense local fields. The metasurface allows a simultaneous amplification to the spontaneous decay rate and emission intensity of nitrogen‐vacancy centers in nanodiamond.
doi_str_mv	10.1002/adom.202202548
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Yet, inefficient photon generation and extraction from excited NV centers restrict the achievable sensitivity and temporal resolution. Herein, an entirely complementary route featuring pyramidal hyperbolic metasurface is reported to modify the spontaneous emission of NV centers. Fabricated using nanosphere lithography, the metasurface consists of alternatively stacked silica–silver thin films configured in a pyramidal fashion, and supports both spectrally broadband Purcell enhancement and spatially extended intense local fields owing to the hyperbolic dispersion and plasmonic coupling. The enhanced photophysical properties are manifested as a simultaneous amplification to the spontaneous decay rate and emission intensity of NV centers. It is envisioned that the reported pyramidal metasurface can serve as a versatile platform for creating chip‐based ultrafast single‐photon sources and spin‐enhanced quantum biosensing strategies, as well as aid in further fundamental understanding of photoexcited species in condensed phases. A plasmonic hyperbolic metasurface consisting of alternatively stacked silica–silver thin films configured in a pyramidal fashion is developed and found to support both spectrally broadband Purcell enhancement and spatially extended intense local fields. 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Yet, inefficient photon generation and extraction from excited NV centers restrict the achievable sensitivity and temporal resolution. Herein, an entirely complementary route featuring pyramidal hyperbolic metasurface is reported to modify the spontaneous emission of NV centers. Fabricated using nanosphere lithography, the metasurface consists of alternatively stacked silica–silver thin films configured in a pyramidal fashion, and supports both spectrally broadband Purcell enhancement and spatially extended intense local fields owing to the hyperbolic dispersion and plasmonic coupling. The enhanced photophysical properties are manifested as a simultaneous amplification to the spontaneous decay rate and emission intensity of NV centers. It is envisioned that the reported pyramidal metasurface can serve as a versatile platform for creating chip‐based ultrafast single‐photon sources and spin‐enhanced quantum biosensing strategies, as well as aid in further fundamental understanding of photoexcited species in condensed phases. A plasmonic hyperbolic metasurface consisting of alternatively stacked silica–silver thin films configured in a pyramidal fashion is developed and found to support both spectrally broadband Purcell enhancement and spatially extended intense local fields. 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subjects	Broadband Decay rate Diamonds hyperbolic metasurfaces Materials science Metasurfaces nanodiamond nanopyramid arrays Nanospheres Nanostructure Nitrogen nitrogen‐vacancy centers Optics Photons plasmonics Spontaneous emission Temporal resolution Thin films
title	Pyramidal Hyperbolic Metasurfaces Enhance Spontaneous Emission of Nitrogen‐Vacancy Centers in Nanodiamond
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