Quantitative and automatic analysis of interferometric fringe data using carrier fringe and FFT techniques

Quan, C.

January 1992

No description available.

535

Optical interference

Laser Lithography of Thin Polymer Films

Hudson, John Monte

08 1900

Laser lithography has been implemented in many ways to pattern polymeric materials. By using a tightly focused laser beam we can induce sharp thermal gradients, exceeding 1,500,000 °C/cm, onto the surface of a thin polymer film. The temperature dependence of the surface tension in such a thermal field gives rise to a flow of material away from the center of the beam focus driven by the Marangoni or thermocapillary effect. The evolution of a film irradiated by a focused laser can be, in a general sense, predicted by a presented hydrodynamic model, which is based on simple fluid mechanics. However, the details of the individual evolution profiles show a more complicated behaviour. It has been shown that this complex behaviour can be explained by considering the optical interference effects of the thin polymer coating. An optical feedback control routine has been developed to compensate for the interference effect by monitoring and maintaining a constant absorbed laser power. This ensures that the temperature gradient that drives the lithography process is consistent during operation. Additional studies involving high laser power effects, different material systems and other thin film phenomena have revealed an interesting assortment of novel behaviours. The extension of these behaviours to the lithography process lead towards the development of applications in microfabriation and microfluidic devices. / Thesis / Master of Applied Science (MASc)

laser lithography

Marangoni effect

thermal gradient

optical interference

On the chromogenic behavior of tungsten oxide films : A cryogenic experiment

Langhammer, David

January 2015

The chromogenic properties of tungsten trioxide (WO3) have been studied by photoluminescence spectroscopy at 4.2 K in order to characterize the electronic structure of this material and see how this relates to optical responses during chromogenic coloration. Transition processes between electron energy states are often the cause of optical phenomena and it is important to identify such processes in order to understand the chromogenic coloration of tungsten oxide films. Much research work has been devoted to characterize the physical and chemical mechanisms that are responsible for this coloration and this is of fundamental importance to understand the chromogenic behavior. The latest research shows that oxygen vacancies could play an important role in certain coloration processes, but it is still a matter of debate whether these are important for the overall response. This work aims to identify specific transitions that are related to oxygen vacancies by measuring photoluminescence from films with controlled vacancy content. The main goal of the project was to set up an experiment that could measure photoluminescence at liquid helium temperature. This was done by installing and integrating the components included in this experimental set-up. The films had been prepared prior to this work and were deposited on a nanocrystalline CaF2 substrate, which is a material that has a very large band gap and was therefore expected to fully transparent in the UV range. However it was found that the substrate inelastically scattered the UV excitation light, which produced strong signals that overshadowed the photoluminescence and prevented an effective characterization of the electronic structure in the films. Instead, suggestions were given on how to minimize uncertainty factors and overcome the difficulties met in this work. It was also found that the films attain a lasting blue coloration by exposure to UV light in vacuum, and that this might be due to oxygen being desorbed from the film during experiments in vacuum.

Photoluminescence

chromogenic

band gap

electronic orbital

density functional theory

optical interference

Design of Multilayer Optical Media: Organic Photovoltaics and Optical Data Storage

Valle, Brent

19 August 2013

No description available.

Physics

Optics

photovoltaics

organic photovoltaics

optical data storage

optical interference

optical transfer matrix

cavity effects

Electrostatic Self-Assembly of Linear and Nonlinear Optical Thin Films

Cooper, Kristie Lenahan

06 May 1999

This dissertation demonstrates the feasibility of using novel electrostatic self-assembly (ESA) methods to fabricate linear and nonlinear optical thin films and components. The ESA process involves the layer-by-layer alternate adsorption of anionic and cationic complexes from aqueous solutions. Selection of the molecules in each layer, their orientation at the molecular level, and the order in which the layers are assembled determine the film's bulk optical, electronic, magnetic, thermal, mechanical and other properties. In this work, the capability of nanoscale control over film optical properties allowed the fabrication of complicated refractive index profiles required for linear optical interference filters. The inherent ordered nature of ESA films yielded extremely stable noncentrosymmetric thin films for second-order nonlinear optical applications. The ESA technique offers numerous advantages over conventional thin film fabrication methods and offers great potential in commercial applications such as reflectance and AR filters, EO waveguides and modulators and other optoelectronic devices. The structure of each monolayer in ESA films is dependent on the processing parameters, producing subsequent variations in bulk film properties both intentionally and incidentally. As this method is still in its infancy, variations in ESA processing methods, including process automation, are considered first in this document. These results allowed carefully controlled refractive index experiments and the synthesis of both step and graded index structures, several microns thick. Dielectric stack, Rugate, and antireflection optical interference filters were designed, synthesized and demonstrated. c(2) films of both commercially available polymer dyes and novel polymers designed specifically for the ESA process were demonstrated using second harmonic generation. UV/vis spectroscopy, ellipsometry and atomic force microscopy analysis are presented. / Ph. D.

dielectric stack

optical thin films

chi(2) effect

optical interference filter

nonlinear optics (NLO)

electrostatic self-assembly (ESA)

Conception et mise en oeuvre d'un télémètre à très haute exactitude pour application aux missions spatiales de vol en formation et à la caractérisation des grandes installations / Design and implementation of a very high accuracy rangefinder for application to formation flight space missions and to the characterization of large installations

Phung, Duy-Hà

25 June 2013

Au-delà de son utilisation en géophysique ou en métrologie à grande échelle, la télémétrie laser des longues distances devrait trouver de nombreuses applications pour les missions spatiales. Les instruments d'observation par synthèse ouverture en vols en formation demandent que la géométrie de la constellation soit connue et contrôlée à bien mieux que la longueur d’onde de la fenêtre d’observation. Pour répondre à ces besoins, nous avons étudié un nouveau schéma de mesure qui combine une mesure interférométrique, réalisée sur un faisceau à deux modes et une mesure de temps de vols. Mon travail de thèse a porté sur la conception, mise en œuvre et la caractérisation de la mesure interférométrique. Pour qu'elles ne soient pas affectées par les dérives lentes de l'instrumentation microonde, les deux mesures de phase de longueur d’onde optique (1.55 µm) et de longueur d’onde synthétique (15 mm) sont extraites d'un même signal d’interférence à deux modes en utilisant une procédure de mesure dédiée : on réalise des mesures du signal d’interférence à trois valeurs de la fréquence optique de la source, calculées d'après le résultat de la mesure de temps de vol. Le télémètre met à profit les propriétés du signal d'interférence à deux modes et exploite la phase et l'amplitude du signal à 20 GHz de façon à éliminer les dérives de phase à long terme du signal microonde dans les chaînes de mesure. On peut en attendre, en moins de 0.1 s, une mesure de résolution et d'exactitude inférieures au nanomètre. Le montage expérimental a permis de montrer que le principe de mesure est correct. Sur la mesure d’un chemin optique dans l'air, nous avons obtenu une résolution de 100 pm à 100 µs, qui nous permet d'observer le bruit acoustique. Le bruit sur la mesure des signaux permet d'espérer une résolution de à 10 pm à 43 ms. Les imperfections optiques du montage ont été mises en évidence: elles ont été décrites par une expression analytique, puis à l’aide d’optiques dédiées réduites au niveau nécessaire pour le fonctionnement de l'instrument. La phase des signaux de battement à 20 GHz est affectée d'erreurs de plusieurs 10-3 cycles qui, si elles ne sont pas corrigées, provoquent des erreurs de la mesure de longueur par une ou plusieurs fois la longueur d'onde optique. Nous avons réalisé une étude spécifique du couplage amplitude-phase à l'origine de cette déformation, et montré qu'il est en partie d'origine thermique, lié à la puissance de plusieurs kW/cm² dissipée dans les photodiodes à 20 GHz. Cet effet, voisin de ce qui est connu depuis quelques années en instrumentation microonde sous le nom d' "effet mémoire", est difficile à prendre en compte et la correction qui est faite sur les données ne parvient pas totalement à éviter que le télémètre délivre des valeurs erronées de la distance. En conclusion de ce mémoire deux options sont présentées afin de remédier à cette déformation du signal et d'aboutir à un instrument de haute exactitude. / Beyond its use in geophysics or in large scale metrology, laser-based measurement of long distances is expected to find numerous applications in space missions. Synthetic aperture instruments in formation flight require that the constellation geometry be known and controlled to much better than the wavelength of the observation window. To meet these needs, we have been studying a novel laser ranging scheme that combine an interferometric measurement, performed on a two-mode laser beam, and a time of flight measurement. My thesis focused on the design, implementation, and characterization of the interferometric measurement. To prevent systematic errors due to slow drifts in the microwave components, the two phase measurements of optical wavelength (1.55 microns) and the synthetic wavelength (15 mm) are extracted from the same two-mode interference signal by using a dedicated measurement procedure: we perform interference signal measurements at three optical frequency values of the laser source, calculated based on the time of flight measurement result. The rangefinder utilizes the two-mode interference signal properties and exploits phase and amplitude of the 20 GHz signal in a manner to eliminate long-term phase drifts of the microwave signal in the measurement chain. We can expect in less than 0.1 s, a measurement with sub-nanometer accuracy and resolution. The experimental setup showed that the principle is correct. On an optical path measurement in air, we obtained a 100 pm resolution in 100 us, which allows us to observe the acoustic noise. The measurement signal noise allows expecting a 10 pm resolution in 43 ms. Optical imperfections in the setup have been observed. They were described by an analytical expression, then, using dedicated optics, they were reduced to the level required for the instrument operation. The phase of two-mode signal is affected to several 10-3 cycle errors which, if not corrected, result in errors in the measurement length by multiples of the optical wavelength. We performed a specific study of amplitude-to-phase coupling causing this deformation, and showed that it is part of thermal origin, related to the power of several kW/cm² dissipated in the 20 GHz photodiodes. This effect, close to what has been known for some years in microwave instrumentation under the name of "memory effects", is difficult to take into account and the correction made on the data can not completely prevent the rangefinder from delivering incorrect values of the distance. In concluding this thesis two options are presented to remedy this signal distortion and result in a high accuracy instrument.

Télémétrie laser

Métrologie

Mesure de phase

Interférence optique

Couplage amplitude/phase

Instrumentation micro-ondes

Laser rangefinder

Metrology

Phase measurement

Optical interference

Amplitude-to-phase coupling

Microwave instrumentation

Detekce průtoku pomocí optických interferenčních metod / Flow detection using optical intereference methods

Hoštáková, Nina

January 2015

The thesis deals with LSCI (Laser Speckle Contrast Imaging), an optical method utilizing laser speckle contrast for the estimation of blood flow changes. LSCI is non-invasive and technically not demanding approach, capabilities of which have not yet been fully exploited. The literature review part contains detailed description of the operating principle, imaging techniques, potential for medical applications with considering the limiting factors. The main aim of the thesis is to design and construct a complete LSCI system including appropriate phantoms able to simulate blood flow through the tissue. Imaging algorithms for the obtained data evaluation were implemented in Matlab® development enviroment. Finally, the created system was tested using different acquisition parameters as well as varying the image processing schemes. The resulting qualitative flow images were subsequently discussed and confronted with the theoretical assumptions.