Nanostructured hybrid plasmonic waveguide in a slot structure for high-performance light transmission

Squeezing light to nanoscale is the most vital capacity of nanophotonic circuits processing on-chip optical signals that allows to significantly enhance light–matter interaction by stimulating various nonlinear optical effects. It is well known that plasmon can offer an unrivaled concentration of op...

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Veröffentlicht in:Optics express 2021-08, Vol.29 (18), p.29341-29356
Hauptverfasser: Huang, Chia-Chih, Chang, Ruei-Jan, Huang, Chia-Chien
Format: Artikel
Sprache:eng
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Zusammenfassung:Squeezing light to nanoscale is the most vital capacity of nanophotonic circuits processing on-chip optical signals that allows to significantly enhance light–matter interaction by stimulating various nonlinear optical effects. It is well known that plasmon can offer an unrivaled concentration of optical energy beyond the optical diffraction limit. However, the progress of plasmonic technology is mainly hindered by its ohmic losses, thus leading to the difficulty in building large-area photonic integrated circuits. To significantly increase the propagation distance of light, we develop a new waveguide structure operating at the telecommunication wavelength of 1,550 nm. It consists of a nanostructured hybrid plasmonic waveguide embedded in a high-index-contrast slot waveguide. We capitalize on the strong mode confinement of the slot waveguide and reduce mode areas with the nanostructured hybrid plasmonic configuration while maintaining extremely low ohmic losses using a nanoscale metal strip. The proposed design achieves a record propagation distance of 1,115 µm while comparing with that of other designs at a mode area of the order of 10 −5 A 0 ( A 0 is the diffraction-limited area). The mode characterization considering fabrication imperfections and spectral responses show the robustness and broadband operation range of the proposed waveguide. Moreover, we also investigated the crosstalk to assess the density of integration. The proposed design paves the way for building nanophotonic circuits and optoelectronic devices that require strong light–matter interaction.
ISSN:1094-4087
1094-4087
DOI:10.1364/OE.438771