Modes that propagate along the surf

Modes that propagate along the surface of a conductor are often referred to as surface
plasmons (SP’s) at optical frequencies, and at microwave frequencies simply as
surface currents. It is the purpose of this thesis to show that at microwave frequencies,
by altering the surface of a metal through the addition of a photonic structure, the
properties of these modes may be controlled. In particular, control over the way in
which these modes interact with incident radiation opens up the possibility of
developing new and exciting photonic devices capable of controlling the resonant
absorptive and transmissive nature of microwave structures.
The work presented in this thesis is divided into two main sections. The initial
experimental chapters are concerned with the coupling of incident radiation to a SPP
mode that propagates along a dual periodic, corrugated aluminium-air interface,
resulting in extremely efficient absorption of the incident radiation. Further, the
frequency at which the resonant absorption occurs is shown to be remarkably
independent of the angle of incidence and, in addition, occurs at a frequency which is
predetermined by the physical parameters of the grating, demonstrating the potential
of selectively absorbing designer-surfaces.
The subsequent experimental chapters are concerned with the extraordinary
transmission of radiation through sub-wavelength apertures, mediated by either a
photonic surface, or wave-guide modes within the aperture. This is the first
experimental study of the enhanced transmission phenomenon to be conducted in the
microwave regime, and together with the finite element method modelling of the
system provides remarkable and original insight into the characteristics observed in
the transmission spectra through such structures