Long-range plasmonic directional coupler switches controlled by nematic liquid crystals
Academic Article
Publication Date:
2013
abstract:
A liquid-crystal tunable plasmonic optical switch based on a long-range metal stripe directional coupler is proposed and theoretically investigated. Extensive electro-optic tuning of the coupler's characteristics is demonstrated by introducing a nematic liquid crystal layer above two coplanar plasmonic waveguides. The switching properties of the proposed plasmonic structure are investigated through rigorous liquid-crystal studies coupled with a finite-element based analysis of light propagation. A directional coupler optical switch is demonstrated, which combines very low power consumption, low operation voltages, adjustable crosstalk and coupling lengths, along with sufficiently reduced insertion losses. © 2013 Optical Society of America.
Iris type:
01.01 Articolo in rivista
Keywords:
Coupling length; Finite-element; Low-power consumption; Nematic li; Operation voltage; Plasmonic directional couplers; Plasmonic waveguides; Switching properties; Crystal structure; Directional couplers; Finite element method; Liquids; Optical switches; Optical waveguides; Plasmons; Nematic liquid crystals; article; chemistry; electromagnetic field; equipment; equipment design; equipment failure; liquid crystal; radiation exposure; refractometry; signal processing; surface plasmon resonance; telecommunication; theoretical model; Electromagnetic Fields; Equipment Design; Equipment Failure Analysis; Liquid Crystals; Models; Theoretical; Refractometry; Signal Processing; Computer-Assisted; Surface Plasmon Resonance; Telecommunications
List of contributors:
Beccherelli, Romeo; Zografopoulos, Dimitrios
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