Title :
Localised plasmons in gold photonic nanocavities
Author :
Coyle, S. ; Netti, M.C. ; Whittaker, D.M. ; Baumberg, J.J. ; Ghanem, M.A. ; Birkin, P.R. ; Bartlett, P.N.
Author_Institution :
Department of Physics and Astronomy, Southampton Univ., UK
Abstract :
Summary form only given. We demonstrate a simple scheme to produce large-area coloured metal surfaces by completely confining surface plasmons inside gold spherical nanocavities. Previous work on photonic metals has focused on the use of regular arrays of corrugations or holes of a lateral size much less than the optical wavelength which produces complex and highly directional performance due to their periodicity. In contrast to periodic patterning which produces photonic crystals for travelling waves, the negative nanocavity curvature here localises the electromagnetic fields into small volumes which can be arranged non-periodically. Thus, plasmons trapped in spherical voids arranged in amorphous arrays possess simple discrete energy levels.
Keywords :
gold; metallic thin films; microcavities; nanotechnology; photonic crystals; porous materials; reflectivity; surface plasmon resonance; visible spectra; Au; Au photonic nanocavities; amorphous arrays; assembled latex spheres; discrete energy levels; electrochemical deposition; electromagnetic field localisation; large-area coloured metal surfaces; local optical reflectivity; localised surface plasmons; macroporous Au films; metallic mesh; negative nanocavity curvature; nonperiodic arrangement; self-assembled template; sharp quantised plasmon resonances; specular reflection spectra; spherical nanocavities; spherical voids; surface texturing; Conducting films; Gold; Nanotechnology; Optical reflection; Optical spectroscopy;
Conference_Titel :
Quantum Electronics and Laser Science Conference, 2002. QELS '02. Technical Digest. Summaries of Papers Presented at the
Conference_Location :
Long Beach, CA, USA
Print_ISBN :
1-55752-708-3
DOI :
10.1109/QELS.2002.1031391
