Chin‐Cheng Chiang scite author profile

Solid-state quantum emitters are in high demand for emerging technologies such as advanced sensing and quantum information processing. Generally, these emitters are not sufficiently bright for practical applications, and a promising solution consists in coupling them to plasmonic nanostructures. Plasmonic nanostructures support broadband modes, making it possible to speed up the fluorescence emission in room-temperature emitters by several orders of magnitude. However, one has not yet achieved such a fluorescence lifetime shortening without a substantial loss in emission efficiency, largely because of strong absorption in metals and emitter bleaching. Here, we demonstrate ultrabright single-photon emission from photostable nitrogen-vacancy (NV) centers in nanodiamonds coupled to plasmonic nanocavities made of low-loss single-crystalline silver. We observe a 70-fold difference between the average fluorescence lifetimes and a 90-fold increase in the average detected saturated intensity. The nanocavity-coupled NVs produce up to 35 million photon counts per second, several times more than the previously reported rates from room-temperature quantum emitters.

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Memory applications from 2D materials

Chiang

Ostwal

et al. 2021

Applied Physics Reviews

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Air-Stable P-Doping in Record High-Performance Monolayer WSe₂ Devices

Chiang

Lan

Pang

et al. 2022

IEEE Electron Device Lett.

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Deterministic integration of single nitrogen-vacancy centers into nanopatch antennas

Bogdanov¹,

Makarova²,

Lagutchev³

et al. 2019

Preprint

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Chip‐Compatible Quantum Plasmonic Launcher

Chiang

Bogdanov

Makarova

et al. 2020

Advanced Optical Materials

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Integrated on-demand single-photon sources are critical for the implementation of photonic quantum information processing systems. To enable practical quantum photonic devices, the emission rates of solid-state quantum emitters need to be substantially enhanced and the emitted signal must be directly coupled to an on-chip circuitry. The photon emission rate speed-up is best achieved via coupling to plasmonic antennas, while on-chip integration can be easily obtained by directly coupling emitters to photonic waveguides. The realization of practical devices requires that both the emission speed-up and efficient out-couping are achieved in a single architecture.Here, we propose a novel platform that effectively combines on-chip compatibility with high radiative emission rates -a quantum plasmonic launcher. The proposed launchers contain single nitrogen-vacancy (NV) centers in nanodiamonds as quantum emitters that offer record-high average fluorescence lifetime shortening factors of about 7000 times. Nanodiamonds with single NV are sandwiched between two silver films that couple more than half of the emission into inplane propagating surface plasmon polaritons. This simple, compact, and scalable architecture represents a crucial step towards the practical realization of high-speed on-chip quantum networks. coated with a 3 nm thick alumina layer. The NV emission is strongly enhanced and couples preferentially to inplane surface plasmon modes, making this design compatible with on-chip integration.

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