Controlling All Degrees of Freedom of the Optical Coupling in Hybrid Quantum Photonics

Lettner, Niklas; Antoniuk, Lukas; Ovvyan, Anna P.; Gehring, Helge; Wendland, Daniel; Agafonov, Viatcheslav N.; Pernice, Wolfram H. P.; Kubanek, Alexander

doi:10.1021/acsphotonics.3c01559

ACS Photonics

2024

DOI: 10.1021/acsphotonics.3c01559

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Controlling All Degrees of Freedom of the Optical Coupling in Hybrid Quantum Photonics

Niklas Lettner,

Lukas Antoniuk,

Anna P. Ovvyan

et al.

Abstract: Nanophotonic quantum devices can significantly boost light−matter interaction, which is important for applications such as quantum networks. Reaching a high interaction strength between an optical transition of a spin system and a single mode of light is an essential step that demands precise control over all degrees of freedom of the optical coupling. While current devices have reached a high accuracy of emitter positioning, the placement process remains overall statistically, reducing the device fabrication … Show more

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Cited by 2 publications

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All-optical spin access via a cavity-broadened optical transition in on-chip hybrid quantum photonics

Antoniuk,

Lettner,

Ovvyan

et al. 2024

Phys. Rev. Applied

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Hybrid quantum photonic systems connect classical photonics to the quantum world and promise to deliver efficient light-matter quantum interfaces while leveraging the advantages of both, the classical and the quantum, subsystems. However, combining efficient, scalable photonics and solid-state quantum systems with desirable optical and spin properties remains a formidable challenge. In particular, the access to individual spin states and coherent mapping to photons remains unsolved for hybrid systems. In this paper, we demonstrate all-optical initialization and readout of the electron spin of a negatively charged silicon-vacancy center in a nanodiamond coupled to a silicon nitride photonic crystal cavity. We characterize relevant parameters of the coupled emitter-cavity system and determine the silicon-vacancy center’s spin-relaxation and spin-decoherence rate. Our results mark a key step towards the realization of a hybrid spin-photon interface based on silicon nitride photonics and the silicon-vacancy center’s electron spin in nanodiamonds with potential use for quantum networks, quantum communication, and distributed quantum computation. Published by the American Physical Society 2024

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All-optical spin access via a cavity-broadened optical transition in on-chip hybrid quantum photonics

Antoniuk,

Lettner,

Ovvyan

et al. 2024

Phys. Rev. Applied

View full text Add to dashboard Cite

show abstract

Strongly coupled spins of silicon-vacancy centers inside a nanodiamond with sub-megahertz linewidth

Klotz,

Waltrich,

Lettner

et al. 2024

Nanophotonics

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The search for long-lived quantum memories, which can be efficiently interfaced with flying qubits, is longstanding. One possible solution is to use the electron spin of a color center in diamond to mediate interaction between a long-lived nuclear spin and a photon. Realizing this in a nanodiamond furthermore facilitates the integration into photonic devices and enables the realization of hybrid quantum systems with access to quantum memories. Here, we investigated the spin environment of negatively charged silicon-vacancy centers in a nanodiamond and demonstrate strong coupling of its electron spin, while the electron spin’s decoherence rate remained below 1 MHz. We furthermore demonstrate multi-spin coupling with the potential to establish registers of quantum memories in nanodiamonds.

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Controlling All Degrees of Freedom of the Optical Coupling in Hybrid Quantum Photonics

Cited by 2 publications

References 28 publications

All-optical spin access via a cavity-broadened optical transition in on-chip hybrid quantum photonics

All-optical spin access via a cavity-broadened optical transition in on-chip hybrid quantum photonics

Strongly coupled spins of silicon-vacancy centers inside a nanodiamond with sub-megahertz linewidth

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