Plasmonic resonances of metallic nanoparticles in arrays and in isolation
Burrows, Christopher P.
Date: 28 October 2010
Thesis or dissertation
Publisher
University of Exeter
Degree Title
PhD in Physics
Abstract
Plasmonics is the branch of photonics that is concerned with the interactions which take place
between metallic structures and incident electromagnetic radiation. It is a field which has seen
a recent resurgence of interest, predominantly due to the emerging fields of metamaterials and
sub-wavelength optics. The original work contained ...
Plasmonics is the branch of photonics that is concerned with the interactions which take place
between metallic structures and incident electromagnetic radiation. It is a field which has seen
a recent resurgence of interest, predominantly due to the emerging fields of metamaterials and
sub-wavelength optics. The original work contained within this thesis is concerned with the
plasmonic resonances of metallic nanoparticles which can be excited with visible light. These
structures have been placed in a variety of configurations, and the optical response of each of
these configurations has been probed both experimentally, and with numerical simulations.
The first chapter contains some background and describes some recent advances in the literature,
set against the broad background of more general concepts which are important in
plasmonics.
The best starting point in describing the response of plasmonic systems is to consider individual
metallic particles and this is the subject of the second chapter. Three separate modelling
techniques are described and compared, and dark-field spectroscopy is used to produce experimental
scattering spectra of single particles which support dipolar and higher order modes.
Mie theory is used as a starting point in understanding these modes, and finite element method
(FEM) modelling is used to make numerical comparisons with dark-field data.
When two plasmonic particles are placed close to each other, interactions take place between
them and their response is modified, sometimes considerably. This effect can be even stronger
if particles are placed in large arrays. Interactions between the dipolar modes of gold particles
form the basis of the third chapter. The discussion begins with pairs of particles, and the
coupled dipole approximation (CDA) is introduced to describe the response. Ordered square
arrays are considered and different modelling techniques are compared to experimental data.
Also, random arrays have been investigated with a view to inferring the extinction spectrum of
a single particle from a carefully chosen array of particles in which the inter-particle interactions
are suppressed.
The fourth chapter continues the theme of particles interacting in arrays, but the particles
considered support quadrupolar modes (and they are silver instead of gold). The optical
response is strongly modified, and an explanation is provided which overturns the accepted
explanation.
The final chapter of new results is somewhat different to the others in that a very different
structure is considered and different parameters are extracted. Instead of far-field quantities,
here, near-fields of composite structures are of interest; they can generate greatly enhanced
fields in the vicinity of the structure. These enhanced fields, in turn, enhance the fluorescence
and Raman emission of nearby dye molecules. A novel field integration technique is proposed
which aims to mimic the experiments which were carried out using fluorescence confocal
microscopy.
Doctoral Theses
Doctoral College
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