Title :
Forces on a Rayleigh particle in the cover region of a planar waveguide
Author :
Ng, L.N. ; Luff, B.J. ; Zervas, M.N. ; Wilkinson, J.S.
Author_Institution :
Optoelectron. Res. Centre, Southampton Univ., UK
fDate :
3/1/2000 12:00:00 AM
Abstract :
We report on the optimization of a waveguide structure for the maximization of the radiation forces exerted on a Rayleigh particle in the cover region. The two main radiation forces involved are the transverse gradient force which attracts a particle into the waveguide and the combined scattering and dissipative forces which drive the particle forward along the channel. The dependence of these forces on parameters including the incident wavelength, the surrounding medium embedding the particles, and the polarizability of the particles is discussed. Both dielectric and metallic gold spheres of radius 10 nm are considered in the model. Special emphasis is devoted to the maximization of the transverse gradient force due to the optical intensity gradient at the waveguide surface, and the wavelength dependence of the polarizability of gold nanoparticles.
Keywords :
chemical sensors; gold; nanostructured materials; optical planar waveguides; polarisability; radiation pressure; Au; Rayleigh particle; cover region; dielectric gold spheres; dissipative forces; gold nanoparticles; incident wavelength; metallic gold spheres; optical intensity gradient; optical planar waveguide; optimization; polarizability; radiation force maximization; scattering forces; transverse gradient force; waveguide structure; waveguide surface; wavelength dependence; Dielectrics; Drives; Gold; Optical polarization; Optical scattering; Optical waveguides; Particle scattering; Rayleigh scattering; Surface waves; Waveguide components;
Journal_Title :
Lightwave Technology, Journal of
