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Photonic crystal waveguides based active and passive devices for phased array antenna systemsJiang, Yongqiang, January 1900 (has links) (PDF)
Thesis (Ph. D.)--University of Texas at Austin, 2006. / Vita. Includes bibliographical references.
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Highly integrated polymer photonic switching and interconnectsWang, Xiaolong, January 1900 (has links) (PDF)
Thesis (Ph. D.)--University of Texas at Austin, 2006. / Vita. Includes bibliographical references.
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DC-excited cw CO₂ metal waveguide laserAl-Mashaabi, Fahad Saleh 01 January 1988 (has links)
A novel design for a DC excited cw C02 metal waveguide laser has been developed in which a slotted hollow-cathode in a transverse discharge also doubles as a metal waveguide. This design has been implemented in a compact design that produces up to 1 watt of cw, 10.6 μm radiation. The discharge characteristics, laser gain and laser output has been studied as functions of various discharge parameters. The advantages of the new transverse discharge of the slotted hollow cathode geometry include low voltage, positive impedence and high optical gain. Overall efficiency is comparable with those of conventional longitudinal CO2 lasers. The output laser modes were very clean low order Gaussian modes.
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Aberration Corrected Photoemission Electron Microscopy with Photonics ApplicationsFitzgerald, Joseph P. S. 09 March 2015 (has links)
Photoemission electron microscopy (PEEM) uses photoelectrons excited from material surfaces by incident photons to probe the interaction of light with surfaces with nanometer-scale resolution. The point resolution of PEEM images is strongly limited by spherical and chromatic aberration. Image aberrations primarily originate from the acceleration of photoelectrons and imaging with the objective lens and vary strongly in magnitude with specimen emission characteristics. Spherical and chromatic aberration can be corrected with an electrostatic mirror, and here I develop a triode mirror with hyperbolic geometry that has two adjacent, field-adjustable regions. I present analytic and numerical models of the mirror and show that the optical properties agree to within a few percent. When this mirror is coupled with an electron lens, it can provide a large dynamic range of correction and the coefficients of spherical and chromatic aberration can be varied independently. I report on efforts to realize a triode mirror corrector, including design, characterization, and alignment in our microscope at Portland State University (PSU). PEEM may be used to investigate optically active nanostructures, and we show that photoelectron emission yields can be identified with diffraction, surface plasmons, and dielectric waveguiding. Furthermore, we find that photoelectron micrographs of nanostructured metal and dielectric structures correlate with electromagnetic field calculations. We conclude that photoemission is highly spatially sensitive to the electromagnetic field intensity, allowing the direct visualization of the interaction of light with material surfaces at nanometer scales and over a wide range of incident light frequencies.
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Propagation of optical waves in tapered fibers and metallic wave guidesZandi, Bahram 01 January 1986 (has links)
The equations tor the propagation of Electromagnetic and Optical waves in tapered fibers and metallic waveguides are derived. Solutions are derived for the displacement of the beam from the waveguide axis as a function of distance along the axis, and also tor the beam width as a function of distance. These equations are solved numerically for a variety of tapered guides. Experiments are conducted which verify the theoretical results.
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A theoretical study of the propagation characteristics of some optical waveguides by the beam propagation method /Osborne, Robert. January 1986 (has links)
No description available.
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Modal interference techniques for strain detection in few-mode optical fibersDuncan, Bradley Dean 21 July 2010 (has links)
Interference between the modes of an optical fiber results in specific intensity patterns which can be modulated as a function of disturbances in the optical fiber system. These modulation effects are a direct result of the difference in propagation constants of the constituent modes. In this presentation it is shown how the modulated intensity patterns created by the interference of specific mode groups in few-mode optical fibers (V < 5.0) can be used to detect strain. A detailed discussion of the modal phenomena responsible for the observed strain induced pattern modulation is given and it is shown that strain detection sensitivities on the order of 10-9 can be expected. Data taken during the evaluation of an actual experimental strain detection system based on the developed theory is also presented. / Master of Science
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A path integral approach to the coupled-mode equations with specific reference to optical waveguidesMountfort, Francesca Helen 03 1900 (has links)
MSc / Thesis (MSc (Physics))--University of Stellenbosch, 2009. / The propagation of electromagnetic radiation in homogeneous or periodically modulated media can
be described by the coupled mode equations. The aim of this study was to derive analytical expressions
modeling the solutions of the coupled-mode equations, as alternative to the generally used numerical
and transfer-matrix methods. The path integral formalism was applied to the coupled-mode equations.
This approach involved deriving a path integral from which a generating functional was obtained. From
the generating functional a Green’s function, or propagator, describing the nature of mode propagation
was extracted. Initially a Green’s function was derived for the propagation of modes having position
independent coupling coefficients. This corresponds to modes propagating in a homogeneous medium
or in a uniform grating formed by a periodic variation of the index of refraction along the direction of
propagation. This was followed by the derivation of a Green’s function for the propagation of modes having
position dependent coupling coefficients with the aid of perturbation theory. This models propagation
through a nonuniform inhomogeneous medium, specifically a modulated grating.
The propagator method was initially tested for the case of propagation in an arbitrary homogeneous
medium. In doing so three separate cases were considered namely the copropagation of two modes in
the forward and backward directions followed by the counter propagation of the two modes. These more
trivial cases were used as examples to develop a rigorous mathematical formalism for this approach. The
results were favourable in that the propagator’s results compared well with analytical and numerical
solutions.
The propagator method was then tested for mode propagation in a periodically perturbed waveguide.
This corresponds to the relevant application of mode propagation in uniform gratings in optical fibres.
Here two case were investigated. The first scenario was that of the copropagation of two modes in a long
period transmission grating. The results achieved compared well with numerical results and analytical
solutions. The second scenario was the counter propagation of two modes in a short period reflection
grating, specifically a Bragg grating. The results compared well with numerical results and analytical
solutions. In both cases it was shown that the propagator accurately predicts many of the spectral
properties of these uniform gratings.
Finally the propagator method was applied to a nonuniform grating, that is a grating for which the
uniform periodicity is modulated - in this case by a raised-cosine function. The result of this modulation
is position dependent coupling coefficients necessitating the use of the Green’s function derived using
perturbation theory. The results, although physically sensible and qualitatively correct, did not compare
well to the numerical solution or the well established transfer-matrix method on a quantitative level at
wavelengths approaching the design wavelength of the grating. This can be explained by the breakdown
of the assumptions of first order perturbation theory under these conditions.
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Photonic crystal interfaces : a design-driven approachAyre, Melanie January 2006 (has links)
Photonic Crystal structures have been heralded as a disruptive technology for the miniaturization of opto-electronic devices, offering as they do the possibility of guiding and manipulating light in sub-micron scale waveguides. Applications of photonic crystal guiding - the ability to send light around sharp bends or compactly split signals into two or more channels have attracted a great deal of attention. Other effects of this waveguiding mechanism have become apparent, and attracted much interest - the novel dispersion surfaces of photonic crystal structures allow the possibility of “slow light” in a dielectric medium, which as well as the possibility of compact optical delay lines may allow enhanced light-matter interaction, and hence miniaturisation of active optical devices. I also consider a third, more traditional type of photonic crystal, in the form of a grating for surface coupling. In this thesis, I address many of the aspects of passive photonic crystals, from the underlying theory through applied device modelling, fabrication concerns and experimental results and analysis. Further, for the devices studied, I consider both the relative merits of the photonic crystal approach and of my work compared to that of others in the field. Thus, the complete spectrum of photonic crystal devices is covered. With regard to specific results, the highlights of the work contained in this thesis are as follows: Realisation of surface grating couplers in a novel material system demonstrating some of the highest reported fibre coupling efficiencies. Development of a short “injecting” taper for coupling into photonic crystal devices. Optimisation and experimental validation of photonic crystal routing elements (Y-splitter and bend). Exploration of interfaces and coupling for “slow light” photonic crystals.
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Atom guiding in free-space light beams and photonic crystal fibresLivesey, John Gregor January 2007 (has links)
In this thesis I describe experimental work and present data on the guiding of Rubidium atoms along free-space propagating light beams as well as within hollow core glass fibres, namely photonic crystal fibres. I describe experiments, laser systems and vacuum trap assemblies designed to facilitate this guiding. These experiments are intended to aid progression within the field of cold atom guidance wherein narrow diameter, long distance hollow-fibre guides are a current goal. Realisation of these guides could lead to promising applications such as atom interferometers and spatially accurate, multi-source, atom depositors. Herein, guided fluxes are observed in free-space guiding experiments for distances up to 50mm and up to 10GHz red-detuning from resonance. Additionally hollow-core, Kagome structured, quasi- and true-photonic crystal fibres are characterised. Finally a number of detailed fibre-guiding magneto-optic traps are developed. Both cold atomic-beams and cold atomic clouds are reliably positioned above fibre entrance facets in conjunction with a guiding laser beam coupled into the fibre core. Issues regarding optical flux detection outwith fibre confinement appear to have hindered observation of guided atoms. A far more sensitive detection system has been developed for use in current, ongoing fibre-guide experiments.
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