Preparing single SiV− center in nanodiamonds for external, optical coupling with access to all degrees of freedom

Preparing single SiV− center in nanodiamonds for external, optical coupling with access to all degrees of freedom

Optical coupling enables intermediate- and long-range interactions between distant quantum emitters. Such interaction may be the basic element in bottom-up approaches of coupled spin systems or for integrated quantum photonics and quantum plasmonics. Here, we prepare nanodiamonds carrying single, ne...

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Bibliographic Details
Published in:New journal of physics Vol. 21; no. 10; pp. 103047 - 103055
Main Authors: Häußler, Stefan, Hartung, Lukas, Fehler, Konstantin G, Antoniuk, Lukas, Kulikova, Liudmila F, Davydov, Valery A, Agafonov, Viatcheslav N, Jelezko, Fedor, Kubanek, Alexander
Format: Journal Article
Language:English
Published: IOP Publishing 01-10-2019
Institute of Physics: Open Access Journals
Subjects:
Acoustics
color centers in diamond
hybrid quantum systems
Mechanics
nanodiamonds (NDs)
Physics
quantum optics
silicon-vacancy center
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Summary:Optical coupling enables intermediate- and long-range interactions between distant quantum emitters. Such interaction may be the basic element in bottom-up approaches of coupled spin systems or for integrated quantum photonics and quantum plasmonics. Here, we prepare nanodiamonds carrying single, negatively-charged silicon-vacancy centers for evanescent optical coupling with access to all degrees of freedom by means of atomic force nanomanipulation. The color centers feature excellent optical properties, comparable to silicon-vacancy centers in bulk diamond, resulting in a resolvable fine structure splitting, a linewidth close to the Fourier-Transform limit under resonant excitation and a good polarization contrast. We determine the orbital relaxation time T1 of the orbitally split ground states and show that all optical properties are conserved during translational nanomanipulation. Furthermore, we demonstrate the rotation of the nanodiamonds. In contrast to the translational operation, the rotation leads to a change in polarization contrast. We utilize the change in polarization contrast before and after nanomanipulation to determine the rotation angle. Finally, we evaluate the likelihood for indistinguishable, single photon emission of silicon-vacancy centers located in different nanodiamonds. Our work enables ideal evanescent, optical coupling of distant nanodiamonds containing silicon-vacancy centers with applications in the realization of quantum networks, quantum repeaters or complex quantum systems.
Bibliography:NJP-110869.R2
ISSN:1367-2630
1367-2630
DOI:10.1088/1367-2630/ab4cf7