Title :
Modeling of Complementary (Void) Plasmon Waveguiding
Author :
Feigenbaum, Eyal ; Orenstein, Meir
Author_Institution :
Technion-Israel Inst. of Technol., Haifa
Abstract :
Plasmonic circuit elements, which are based on complementary waveguide structures (waveguides with a dielectric core and metal cladding), are becoming preferred plasmonic devices for applications. In this paper, we look into the modeling of such devices, namely 1D waveguides and related elements as well as 2D slots, trenches, and channels supporting plasmonic slow waves. Methods such as the effective index, finite-difference time domain, finite elements, or other full-vectorial propagation schemes are among the methods discussed, and their limitations in the field of plasmonics are set. We believe that although many successful validated modeling methods were presented intensive efforts are still required for perfecting the various tools to faithfully describe nanosized plasmonic wave propagation on high-contrast nanometal discontinuities.
Keywords :
finite difference time-domain analysis; finite element analysis; light propagation; nanotechnology; optical planar waveguides; optical waveguide theory; plasmonics; 1-D waveguides; 2-D slots; absorbing media; complementary waveguide structures; dielectric core; dispersive media; effective index methods; finite element method; finite-difference time domain methods; full-vectorial propagation schemes; high-contrast nanometal discontinuities; integrated optics; metal cladding; nanosized plasmonic wave propagation; optical interconnections; optical planar waveguide components; optical propagation; optical waveguide theory; plasma media; plasmon waveguiding; plasmonic circuit elements; plasmonic devices; plasmonic slow waves; Circuits; Electromagnetic waveguides; Optical devices; Optical interconnections; Optical planar waveguides; Optical propagation; Optical sensors; Optical waveguide theory; Optical waveguides; Plasmons; Integrated optics; optical interconnections; optical planar waveguide components; optical propagation; optical propagation in absorbing media; optical propagation in dispersive media; optical propagation in plasma media; optical waveguide components; optical waveguide theory; plasmons;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2007.903558
