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Optimized diamond inverted nanocones for enhanced color center to fiber coupling

Cem Güney Torun, Philipp-Immanuel Schneider, Martin Hammerschmidt, Sven Burger, Joseph H. D. Munns, Tim Schröder

2021Applied Physics Letters22 citationsDOIOpen Access PDF

Abstract

Nanostructures can be used for boosting the light outcoupling of color centers in diamond; however, the fiber coupling performance of these nanostructures is rarely investigated. Here, we use a finite element method for computing the emission from color centers in inverted nanocones and the overlap of this emission with the propagation mode in a single-mode fiber. Using different figures of merit, the inverted nanocone parameters are optimized to obtain maximal fiber coupling efficiency, free-space collection efficiency, or rate enhancement. The optimized inverted nanocone designs show promising results with 66% fiber coupling or 83% free-space coupling efficiency at the tin-vacancy center zero-phonon line wavelength of 619 nm. Moreover, when evaluated for broadband performance, the optimized designs show 55% and 76% for fiber coupling and free-space efficiencies, respectively, for collecting the full tin-vacancy emission spectrum at room temperature. An analysis of fabrication insensitivity indicates that these nanostructures are robust against imperfections. For maximum emission rate into a fiber mode, a design with a Purcell factor of 2.34 is identified. Finally, possible improvements offered by a hybrid inverted nanocone, formed by patterning into two different materials, are investigated and increase the achievable fiber coupling efficiency to 71%.

Topics & Concepts

Materials scienceCoupling (piping)BroadbandFiberOptoelectronicsWavelengthFabricationOptical fiberMicrofiberNanostructureDiamondDispersion-shifted fiberMode couplingCoupling lossOpticsPhotonic-crystal fiberMode volumeBoosting (machine learning)Plastic optical fiberSingle-mode optical fiberCenter frequencyPolarization-maintaining optical fiberEmission spectrumGraded-index fiberDiamond cubicCoupled mode theoryAmplified spontaneous emissionDiamond and Carbon-based Materials ResearchNonlinear Optical Materials StudiesAdvanced Fiber Laser Technologies
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