Frequency Control of Single Quantum Emitters in Integrated Photonic Circuits

Schmidgall, E. R.; Chakravarthi, Srivatsa; Gould, Michael N.; Christen, Ian; Hestroffer, Karine; Hatami, Fariba; Fu, Kai-Mei C.

doi:10.1021/acs.nanolett.7b04717

Cited by 45 publications

(65 citation statements)

References 24 publications

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“…NV centres are compatible with integrated photonic circuits; the study by Faraon et al [173] demonstrates coupling of NV centre fluorescence to diamond-on-silicon waveguides and grating couplers, and the study by Gould et al [174] shows coupling to waveguides via GaP microdisks. Further to this, the GaP system has been modified to allow the single photon emission frequency to be tuned by an applied bias voltage ( Figure 7) [175]. This could compensate for the natural variation in emission frequencies from different NV centres.…”

Section: Nitrogen Vacancy Centres As Quantum Emittersmentioning

confidence: 99%

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Quantum nanophotonic and nanoplasmonic sensing: towards quantum optical bioscience laboratories on chip

Xavier

Jones

et al. 2021

Nanophotonics

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Quantum-enhanced sensing and metrology pave the way for promising routes to fulfil the present day fundamental and technological demands for integrated chips which surpass the classical functional and measurement limits. The most precise measurements of optical properties such as phase or intensity require quantum optical measurement schemes. These non-classical measurements exploit phenomena such as entanglement and squeezing of optical probe states. They are also subject to lower detection limits as compared to classical photodetection schemes. Biosensing with non-classical light sources of entangled photons or squeezed light holds the key for realizing quantum optical bioscience laboratories which could be integrated on chip. Single-molecule sensing with such non-classical sources of light would be a forerunner to attaining the smallest uncertainty and the highest information per photon number. This demands an integrated non-classical sensing approach which would combine the subtle non-deterministic measurement techniques of quantum optics with the device-level integration capabilities attained through nanophotonics as well as nanoplasmonics. In this back drop, we review the underlining principles in quantum sensing, the quantum optical probes and protocols as well as state-of-the-art building blocks in quantum optical sensing. We further explore the recent developments in quantum photonic/plasmonic sensing and imaging together with the potential of combining them with burgeoning field of coupled cavity integrated optoplasmonic biosensing platforms.

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Section: Nitrogen Vacancy Centres As Quantum Emittersmentioning

confidence: 99%

“…Pink: GaP microdisks and waveguides; Yellow: Ti/Au electrodes for applying bias voltage;Grey: diamond substrate. Reprinted with permission from the study by Schmidgall et al[175]. Copyright (2018) American Chemical Society.…”

mentioning

confidence: 99%

Quantum nanophotonic and nanoplasmonic sensing: towards quantum optical bioscience laboratories on chip

Xavier

Jones

et al. 2021

Nanophotonics

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“…While resonant excitation was used to stabilize the ZPL for few tens of seconds [36], anti-Stokes excitation of quantum emitters in hBN was also used to suppress the spectral wandering [37]. Improving material quality [38] and/ or active electrical [39][40][41] or strain-based feedback can further help to minimize unwanted spectral wandering.…”

Section: Quantum Light From 2d Semiconductors and Insulatorsmentioning

confidence: 99%

Advances in quantum light emission from 2D materials

2019

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Two-dimensional (2D) materials are being actively researched due to their exotic electronic and optical properties, including a layer-dependent bandgap, a strong exciton binding energy, and a direct optical access to electron valley index in momentum space. Recently, it was discovered that 2D materials with bandgaps could host quantum emitters with exceptional brightness, spectral tunability, and, in some cases, also spin properties. This review considers the recent progress in the experimental and theoretical understanding of these localized defect-like emitters in a variety of 2D materials as well as the future advantages and challenges on the path toward practical applications.

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“…Electrical tuning and stabilization of NV centers in an integrated optical circuit has been recently demonstrated in ref. [] on the hybrid GaP‐on‐diamond photonic platform (see Figure d,e).…”

Section: Active Componentsmentioning

confidence: 99%

Diamond as a Platform for Integrated Quantum Photonics

Lenzini¹,

Gruhler²,

Walter³

et al. 2018

Adv Quantum Tech

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Integrated quantum photonics enables the generation, manipulation, and detection of quantum states of light in miniaturized waveguide circuits. Implementation of these three operations in a single integrated platform is a crucial step toward a fully scalable approach to quantum photonic technologies. In this context, diamond has emerged as a particularly promising material as it naturally combines a large transparency range for the fabrication of low‐loss photonic circuits, and a variety of optically active defects for the realization of efficient single‐photon emitters. Furthermore, its high Young's modulus makes it ideal for the implementation of tunable optomechanical devices for active quantum state manipulation. This review reports recent progress on the realization of the main components required for a diamond‐based integrated quantum photonic architecture: single‐photon emitters, static and actively tunable waveguide circuits, and, as a last building block, integrated superconducting single‐photon detectors.

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Frequency Control of Single Quantum Emitters in Integrated Photonic Circuits

Cited by 45 publications

References 24 publications

Quantum nanophotonic and nanoplasmonic sensing: towards quantum optical bioscience laboratories on chip

Quantum nanophotonic and nanoplasmonic sensing: towards quantum optical bioscience laboratories on chip

Advances in quantum light emission from 2D materials

Diamond as a Platform for Integrated Quantum Photonics

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