Title :
Excitation of Surface Plasmons Using Tilted Planar-Waveguide Bragg Gratings
Author :
Holmes, C. ; Daly, K.R. ; Sparrow, I.J.G. ; Gates, J.C. ; D´Alessandro, G. ; Smith, P.G.R.
Author_Institution :
Optoelectron. Res. Centre, Univ. of Southampton, Southampton, UK
Abstract :
We present a planar-integrated optical surface plasmon refractometer. The fabricated device operates by grating-matched coupling between a core waveguide mode and a set of hybrid plasmon-dielectric modes of a much wider integrated structure. The constructed device incorporates a 50-nm-thin gold layer that separates a tilted planar-waveguide Bragg grating and a liquid analyte. It is demonstrated that polarization-dependent plasmon anomalies occur in the transmission spectra of the device, which are understood using a numerical Cauchy integral mode solving approach. Sensitivities in this planar-integrated device are comparable with existing fiber-based plasmonic sensors but with the advantages of planar integration and microfluidic adaptation.
Keywords :
Bragg gratings; gold; light polarisation; nanophotonics; nanostructured materials; optical fabrication; optical planar waveguides; optical sensors; refractometers; surface plasmons; transparency; Au; core waveguide mode; fiber-based plasmonic sensors; grating-matched coupling; hybrid plasmon-dielectric modes; numerical Cauchy integral mode solving method; optical fabrication; planar-integrated optical surface plasmon refractometer; polarization-dependent plasmon anomaly; size 50 nm; surface plasmon excitation; thin gold layer; tilted planar-waveguide Bragg gratings; transmission spectra; Gold; Indexes; Optical fibers; Optical sensors; Plasmons; Refractive index; Waveguides; gratings; plasmonics; sensors;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2011.2164395
