Kasey J. Russell scite author profile

The negatively-charged nitrogen vacancy center (NV) in diamond has generated significant interest as a platform for quantum information processing and sensing in the solid state. For most applications, high quality optical cavities are required to enhance the NV zero-phonon line (ZPL) emission. An outstanding challenge in maximizing the degree of NV-cavity coupling is the deterministic placement of NVs within the cavity. Here, we report photonic crystal nanobeam cavities coupled to NVs incorporated by a delta-doping technique that allows nanometer-scale vertical positioning of the emitters. We demonstrate cavities with Q up to ~24,000 and mode volume V ~ 0.47(λ/n) 3 as well as resonant enhancement of the ZPL of an NV ensemble with Purcell factor of ~20. Our fabrication technique provides a first step towards deterministic NV-cavity coupling using spatial control of the emitters.A diamond-based emitter-cavity system provides an important platform for the realization of quantum information processing and sensing in the solid state 1-4 . The long electron spin coherence of the negatively-charged nitrogen vacancy center (subsequently referred to as NV) in

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Low threshold, room-temperature microdisk lasers in the blue spectral range

Aharonovich

Woolf

Russell

et al. 2013

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InGaN-based active layers within microcavity resonators offer the potential of low threshold lasers in the blue spectral range. Here we demonstrate optically pumped, room temperature lasing in high quality factor GaN microdisk cavities containing InGaN quantum dots (QDs) with thresholds as low as 0.28 mJ/cm 2 . This work, the first demonstration of lasing action from GaN microdisk cavities with QDs in the active layer, provides a critical step for the nitrides in realizing low threshold photonic devices with efficient coupling between QDs and an optical cavity.

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High‐Current‐Density Monolayer CdSe/ZnS Quantum Dot Light‐Emitting Devices with Oxide Electrodes

et al. 2011

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Gap-mode plasmonic nanocavity

Russell

2010

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Here we describe the fabrication and characterization of a plasmonic nanocavity formed in the narrow gap between a Ag nanowire and a flat Ag substrate. The fluorescence spectrum of nanocrystals within the gap was strongly modified by the cavity modes, showing peaks of position and width (Q∼30–60) in quantitative agreement with numerical calculations. At gap spacings of ∼15 nm, the noncavity background fluorescence is largely quenched by the Ag substrate, while the modal fluorescence remains strong, indicating that gap-type structures are more robust to fluorescence quenching.

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Kasey J. Russell

Large spontaneous emission enhancement in plasmonic nanocavities

Deterministic coupling of delta-doped nitrogen vacancy centers to a nanobeam photonic crystal cavity

Low threshold, room-temperature microdisk lasers in the blue spectral range

High‐Current‐Density Monolayer CdSe/ZnS Quantum Dot Light‐Emitting Devices with Oxide Electrodes

Gap-mode plasmonic nanocavity

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