Contributions à l’étude de la thermo diffusion de mélanges binaires en conditions de réservoirs / Contribution to the study of thermosdiffusion phenomena on binary mixtures in reservoir conditions.

Giraudet, Cédric Michel Marius

30 March 2015

La thermodiffusion, également appelé effet Soret, décrit le couplage entre les gradients de température et les flux massiques qui en résultent. Ce phénomène intervient dans de nombreux processus naturels et applications industrielles. En particulier, les réservoirs pétroliers sont sujets à ce phénomène impliquant des fluides multi constituants confinés dans une matrice poreuse et soumis à un gradient de température. Néanmoins, malgré beaucoup des progrès, il existe relativement peu de mesures fiables de ce phénomène et sa modélisation reste largement un problème ouvert. L’objectif principal de cette thèse s’inscrit dans ce cadre, à savoir développer une approche expérimental permettant de fournir des données de références sur la thermodiffusion notamment dans l’optique de quantifier l’effet de la pression sur cette dernière. Ainsi, durant cette thèse, nous avons développé une cellule de thermodiffusion en milieu libre qui permet d’étudier par shadowgraphie les fluctuations de non équilibre induites par effet Soret. L’appareil de mesure a ensuite été utilisé pour étudier deux mélanges binaires représentatifs de fluides pétroliers, à savoir le mélange équimassique tétraline/dodécane (en phase liquide) et le mélange dioxyde de carbone/méthane (en phases gaz et supercritique). En complément, des simulations de dynamique moléculaire ont été réalisées sur le mélange dioxyde de carbone/méthane. Par analyse dynamique des images de shadowgraphie nous avons pu déterminer les coefficients de diffusion et Soret en fonction de la pression pour le mélange tétraline/dodécane. Aux incertitudes près, nous observons une décroissance linéaire avec la pression pour ces coefficients. De plus nous avons observé l’effet du confinement de la cellule sur les fluctuations en très bon accord avec la théorie et les simulations. Pour le mélange dioxyde de carbone/méthane l’analyse dynamique a montré une cinétique difficilement accessible de par les limites physiques et informatiques du dispositif expérimental utilisé. L’analyse statique montre, quant à lui, une croissance rapide de l’amplitude des fluctuations avec la pression jusqu’à un seuil au-delà duquel elle décroît. Sur ce mélange les simulations de dynamique moléculaire ont montré un bon accord avec les prédictions théoriques. / Thermodiffusion, also called the Soret effect, describes the coupling between temperature gradient and resulting fluxes. This phenomenon is involved in a number of natural and industrial processes. In particular, multi components fluids in petroleum reservoirs are subjected to this phenomenon because of the geo-thermal gradient. Nevertheless, in spite of a lot of advances, there are few available data of this phenomenon and the establishment of a theoretical model, able to give a quantitative estimation of these transport coefficients whatever molecules in presence, is still an open question. The principal aim of this thesis is to develop an experimental approach allowing providing reference data on thermodiffusion as a function of the pressure. During this thesis, we developed a high pressure thermodiffusion cell in free medium, enabling us to study concentration non-equilibrium fluctuations induced by the Soret effect by means of shadowgraph optical technique. With this setup we investigated two binary mixtures representatives of petroleum fluids; namely the equimassic tetralin/dodecane mixture in liquid phase and the carbon dioxide/methane mixture in gaseous and super critical state. Furthermore, molecular dynamic simulations on the second mixture were performed. Using a dynamic image analysis, we have measured molecular diffusion and Soret coefficient for the tetralin/dodecane mixture. Within experimental uncertainties, we observed a linear decrease of these coefficients with the pressure. Furthermore, we were able to observe the effect of confinement (finite size effect induced by cell vertical boundary conditions) on fluctuation dynamics, in good agreement with calculations and simulations based on hydrodynamic fluctuation theory on similar solutal Rayleigh number. Concerning the carbon dioxide/methane mixture, the dynamic analysis revealed a kinetic too fast for our experimental apparatus. Conversely, static analysis revealed a rapid increase of the non-equilibrium fluctuation magnitude as a function of the pressure up to a threshold beyond which it decreases. On this mixture, performed molecular dynamic simulations provided results in good agreement with expected theoretical behaviour.

Thermodiffusion

Diffusion

Haute pression

Indice de réfraction

Shadowgraphie

Diffusion dynamique de la lumière

Interférométrie

Simulations par dynamique moléculaire

Dioxyde de carbone

Hydrocarbures

Mélanges binaires

Confinement

Fluctuations hydrodynamiques

Thermodiffusion

Diffusion

High pressure

Refractive index

Shadowgraph optical techniques

Dynamic light scattering

Interferometry

Molecular dynamic simulations

Carbon dioxide

Hydrocarbons

Binary mixtures

Confinement

Hydrodynamic fluctuations

Novel fabrication and testing of light confinement devices

Ring, Josh

January 2016

The goal of this project is to study novel nanoscale excitation volumes, sensitive enoughto study individual chromophores and go on to study new and exciting self assemblyapproaches to this problem. Small excitation volumes may be engineered using light con-finement inside apertures in metal films. These apertures enhance fluorescence emissionrates, quantum yields, decrease fluorescence quenching, enable higher signal-to-noiseratios and allow higher concentration single chromophore fluorescence, to be studied byrestricting this excitation volume. Excitation volumes are reported on using the chro-mophore's fluorescence by utilising fluorescence correlation spectroscopy, which monitorsfluctuations in fluorescence intensity. From the correlation in time, we can find the res-idence time, the number of chromophores, the volume in which they are diffusing andtherefore the fluorescence emission efficiency. Fluorescence properties are a probe ofthe local environment, a particularly powerful tool due to the high brightness (quantumyield) fluorescent dyes and sensitive photo-detection equipment both of which are readilyavailable, (such as avalanche photodiodes and photomultiplier tubes). Novel materialscombining the properties of conducting and non-conducting materials at scales muchsmaller than the incident wavelength are known as meta-materials. These allow combi-nations of properties not usually possible in natural materials at optical frequencies. Theproperties reported so far include; negative refraction, negative phase velocity, fluorescenceemission enhancement, lensing and therefore light confinement has also been proposed tobe possible. Instead of expensive and slow lithography methods many of these materialsmay be fabricated with self assembly techniques, which are truly nanoscopic and otherwiseinaccessible with even the most sophisticated equipment. It was found that nanoscaled volumes from ZMW and HMMs based on NW arrays wereall inefficient at enhancing fluorescence. The primary cause was the reduced fluorescencelifetime reducing the fluorescence efficiency, which runs contrary to some commentatorsin the literature. NW based lensing was found to possible in the blue region of the opticalspectrum in a HMM, without the background fluorescence normally associated with a PAAtemplate. This was achieved using a pseudo-ordered array of relatively large nanowireswith a period just smaller than lambda / 2 which minimised losses. Nanowires in the traditionalregime lambda / 10 produced significant scattering and lead to diffraction, such that they werewholly unsuitable for an optical lensing application.

540

Développements de modèles optiques et de méthodes non supervisées de résolution des problèmes bilinéaires : application à l’imagerie vibrationnelle / Development of optical models and non-supervised methods to solve bilinear problems : application to vibrationnal mapping

Bonnal, Thomas

24 April 2018

La caractérisation fine des matériaux inorganiques nécessite d'avoir accès à des informations complémentaires de celles apportées par des techniques d'analyse élémentaire ou de diffraction. La spectroscopie infrarouge à transformée de Fourier permet de caractériser les liaisons covalentes et l'environnement des groupes fonctionnels dans les matériaux. C'est donc une technique de choix pour l'étude des matériaux hydratés, amorphes ou sujets à des phénomènes de vieillissement. En couplant cette technique à une platine de déplacement, il est possible de réaliser des cartographies des phases sur quelques centimètres carrés : c'est la microscopie infrarouge. Cette thèse développe plus particulièrement l'utilisation de la lumière réfléchie au travers de l'étude de la réflexion spéculaire et de la réflexion totale atténuée (ATR).Après une première partie se focalisant sur les méthodes d'acquisitions disponibles, une seconde partie s'attache à obtenir de manière non supervisée les cartographies chimiques associées aux concentrations relatives des différents composants présents dans la zone analysée. Des techniques de réduction de données et d'analyse factorielle sont mises en place afin d'estimer le nombre de composants chimiques et leurs spectres relatifs ; des problèmes de minimisation sous contraintes sont résolus pour extraire l'information chimique. La réflexion spéculaire ne nécessite aucun contact avec l‘échantillon et, de ce fait, n'entraine aucune altération de la surface analysée. C'est sur le papier une technique de choix pour suivre l'évolution d'un matériau. Cependant, elle souffre de la complexité d'interprétation liée à l'allure des spectres obtenus. Afin de développer la cartographie issue de la réflexion spéculaire, des modèles prenant en compte l'optique géométrique, l'optique ondulatoire, des corrections d'interférogrammes et des méthodes classiques d'homogénéisation ont été développés. Ce travail a permis d'aboutir à un modèle optique liant les spectres issus de la réflexion spéculaire avec les concentrations relatives des composants. Ce modèle tient compte de la polarisation, de l'angle d'incidence et utilise les constantes diélectriques du matériau. Ce modèle a été validé sur un matériau contenant trois composants distincts facilement identifiables en infrarouge et spécialement mis en forme pour cette étude. Ce modèle a ouvert la voie à l'utilisation innovante de lumières polarisées elliptiquement pour déterminer l'indice de réfraction complexe d'un matériau. Ainsi, des spectroscopes infrarouges couplés à un accessoire de contrôle de l'angle d'incidence peuvent être utilisés en complément de l'ellipsométrie / Complementary information, to that provided by elemental analysis and diffraction techniques, is needed to characterize inorganic materials. Fourier Transform Infrared spectroscopy enables to characterize covalent bonds and the environment of functional groups in materials. Thus, it is a technique of interest to study hydrated materials, amorphous materials or any materials, which may experience ageing phenomena. By combining this technique with a micrometric motorized stage, cartographies of chemical compounds can be obtained on several square millimeters: this is the infrared microscopy technique. This Ph.D. thesis focuses on the use of reflected light, in particular through the study of specular reflection and of Attenuated Total Reflectance (ATR). After a first part focused on the different acquisition set-ups, a second part covers the unsupervised methodologies of resolution employed to obtain chemical maps. They result in one map for each component present in the analyzed area. Dimensions reduction techniques and multivariate statistics techniques are implemented to estimate the number of components and their infrared spectra; minimization problems under constraints are solved to retrieve chemical information. When specular reflection is used to acquire spectra, no contact is made with the sample, thus no damage of the analyzed area occurs during the acquisition. A priori, it is a great technique to study the evolution of a material. However, this technique suffers from the complexity of interpretation of the resulting spectra. With the objective to democratize the use of specular reflection to obtain chemical maps, models based on geometrical optics and including diffraction, correction of interferograms and classical homogenization techniques have been developed. This work resulted in an optical model linking the angle of incidence, the polarization state and the dielectric optical constants of the material with the reflected light, which is measured. A model material, constituted of three distinct phases, detectable in the infrared range, has specially been fabricated to validate this optical model. This model set the stage for the use of elliptically polarized light in the determining of the complex refractive indices of materials in the infrared range. Thanks to this development, infrared spectroscopes, equipped with a classical set-up to control the angle of incidence, can now be used in addition to ellipsometry techniques

Cartographies chimiques

Optimisation sous contraintes

Modélisation de la lumière réfléchie

Fourier Transform infrared microscopy

Chemical mapping

Hyperspectral data

Constrained optimization

Optical model of reflected light

530

Rolled-up Microtubular Cavities Towards Three-Dimensional Optical Confinement for Optofluidic Microsystems

Bolaños Quiñones, Vladimir Andres

15 September 2015

This work is devoted to investigate light confinement in rolled-up microtubular cavities and their optofluidic applications. The microcavities are fabricated by a roll-up mechanism based on releasing pre-strained silicon-oxide nanomembranes. By defining the shape and thickness of the nanomembranes, the geometrical tube structure is well controlled. Micro-photoluminescence spectroscopy at room temperature is employed to study the optical modes and their dependence on the structural characteristics of the microtubes. Finite-difference-time-domain simulations are performed to elucidate the experimental results. In addition, a theoretical model (based on a wave description) is applied to describe the optical modes in the tubular microcavities, supporting quantitatively and qualitatively the experimental findings. Precise spectral tuning of the optical modes is achieved by two post-fabrication methods. One method employs conformal coating of the tube wall with Al2O3 monolayers by atomic-layer-deposition, which permits a mode tuning over a wide spectral range (larger than one free-spectral-range). An average mode tuning to longer wavelengths of 0.11nm/ Al2O3-monolayer is obtained. The other method consists in asymmetric material deposition onto the tube surface. Besides the possibility of mode tuning, this method permits to detect small shape deformations (at the nanometer scale) of an optical microcavity. Controlled confinement of resonant light is demonstrated by using an asymmetric cone-like microtube, which is fabricated by unevenly rolling-up circular-shaped nanomembranes. Localized three-dimensional optical modes are obtained due to an axial confinement mechanism that is defined by the variation of the tube radius and wall windings along the tube axis. Optofluidic functions of the rolled-up microtubes are explored by immersing the tubes or filling their core with a liquid medium. Refractive index sensing of liquids is demonstrated by correlating spectral shift of the optical modes when a liquid interacts with the resonant light of the microtube. In addition, a novel sensing methodology is proposed by monitoring axial mode spacing changes. Lab-on-a-chip methods are employed to fabricate an optofluidic chip device, allowing a high degree of liquid handling. A maximum sensitivity of 880 nm/refractive-index-unit is achieved. The developed optofluidic sensors show high potential for lab-on-a-chip applications, such as real-time bio/chemical analytic systems.

Photonik

optische Mikroresonatoren

optische Mikrokavitäten

Ringresonantoren

Aufrolltechnologie

Integration auf dem Chip

Lab-in-a-tube

Lab-on-a-Chip

Optofluidik

Brechungsindex Sensor

photonics

optical Microresonators

optical Microcavities

ring resonators

Rolled-up Technology

on-chip integration

Lab-in-a-tube

Lab-on-a-Chip

Optofluidic

refractive index sensor

ddc:530

ddc:535

Photonik

Mikrostruktur

Optischer Resonator

Lab on a Chip

Mikrofluidik

Optischer Sensor

Asymptotic limits of negative group delay phenomenon in linear causal media

Kandic, Miodrag

07 October 2011

Abnormal electromagnetic wave propagation characterized by negative group velocity and consequently negative group delay (NGD) has been observed in certain materials as well as in artificially built structures. Within finite frequency intervals where an NGD phenomenon is observed, higher frequency components of the applied waveform are propagated with phase advancement, not delay, relative to the lower frequency components. These media have found use in many applications that require positive delay compensation and an engineered phase characteristic, such as eliminating phase variation with frequency in phase shifters, beam-squint minimization in phased array antenna systems, size reduction of feed-forward amplifiers and others. The three principal questions this thesis addresses are: can a generic formulation for artificial NGD structures based on electric circuit resonators be developed; is it possible to derive a quantitative functional relationship (asymptotic limit) between the maximum achievable NGD and the identified trade-off quantity (out-of-band gain); and, can a microwave circuit exhibiting a fully loss-compensated NGD propagation in both directions be designed and implemented? A generic frequency-domain formulation of artificial NGD structures based on electric circuit resonators is developed and characterized by three parameters, namely center frequency, bandwidth and the out-of-band gain. The developed formulation is validated through several topologies reported in the literature. The trade-off relationship between the achievable NGD on one hand, and the out-of-band gain on the other, is identified. The out-of-band gain is shown to be proportional to transient amplitudes when waveforms with defined “turn on/off” times are propagated through an NGD medium. An asymptotic limit for achievable NGD as a function of the out-of-band gain is derived for multi-stage resonator-based NGD circuits as well as for an optimally engineered linear causal NGD medium. Passive NGD media exhibit loss which can be compensated for via active elements. However, active elements are unilateral in nature and therefore do not allow propagation in both directions. A bilateral gain-compensated circuit is designed and implemented, which overcomes this problem by employing a dual-amplifier configuration while preserving the overall circuit stability.

negative group delay

metamaterial

NGD

group delay compensation

abnormal propagation

superluminal propagation

group velocity

group delay

Kramers-Kronig relations

causal medium

causal media

causality

constant phase shifter

phased array

feed-forward amplifier

reciprocal circuit

bilateral circuit

delay circuit

distributed parameter circuit

active device

gain compensation

negative refractive index

NRI

LHM

left handed material

cloaking

Asymptotic limits of negative group delay phenomenon in linear causal media

Kandic, Miodrag

07 October 2011

Abnormal electromagnetic wave propagation characterized by negative group velocity and consequently negative group delay (NGD) has been observed in certain materials as well as in artificially built structures. Within finite frequency intervals where an NGD phenomenon is observed, higher frequency components of the applied waveform are propagated with phase advancement, not delay, relative to the lower frequency components. These media have found use in many applications that require positive delay compensation and an engineered phase characteristic, such as eliminating phase variation with frequency in phase shifters, beam-squint minimization in phased array antenna systems, size reduction of feed-forward amplifiers and others. The three principal questions this thesis addresses are: can a generic formulation for artificial NGD structures based on electric circuit resonators be developed; is it possible to derive a quantitative functional relationship (asymptotic limit) between the maximum achievable NGD and the identified trade-off quantity (out-of-band gain); and, can a microwave circuit exhibiting a fully loss-compensated NGD propagation in both directions be designed and implemented? A generic frequency-domain formulation of artificial NGD structures based on electric circuit resonators is developed and characterized by three parameters, namely center frequency, bandwidth and the out-of-band gain. The developed formulation is validated through several topologies reported in the literature. The trade-off relationship between the achievable NGD on one hand, and the out-of-band gain on the other, is identified. The out-of-band gain is shown to be proportional to transient amplitudes when waveforms with defined “turn on/off” times are propagated through an NGD medium. An asymptotic limit for achievable NGD as a function of the out-of-band gain is derived for multi-stage resonator-based NGD circuits as well as for an optimally engineered linear causal NGD medium. Passive NGD media exhibit loss which can be compensated for via active elements. However, active elements are unilateral in nature and therefore do not allow propagation in both directions. A bilateral gain-compensated circuit is designed and implemented, which overcomes this problem by employing a dual-amplifier configuration while preserving the overall circuit stability.

negative group delay

metamaterial

NGD

group delay compensation

abnormal propagation

superluminal propagation

group velocity

group delay

Kramers-Kronig relations

causal medium

causal media

causality

constant phase shifter

phased array

feed-forward amplifier

reciprocal circuit

bilateral circuit

delay circuit

distributed parameter circuit

active device

gain compensation

negative refractive index

NRI

LHM

left handed material

cloaking

Instrumentação optoeletrônica em hardware: implementação de algoritmos otimizados em sensoriamento a FBG / Optoelectronics instrumentation in hardware: implementation of optimized algorithms for FBG sensing

Wang, Yujuan

17 December 2012

Made available in DSpace on 2016-12-12T20:27:37Z (GMT). No. of bitstreams: 1 Yujuan Wang.pdf: 1608760 bytes, checksum: 9cb82304a2c95c2b0e357dc7f8449815 (MD5) Previous issue date: 2012-12-17 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / This work presents the development of an FPGA-based optical interrogation system of multiplexed FBG sensors. The Fabry-Perot filter is used to implement the tunable filter method, as a demodulator for FBG sensors. The tuning signal generation for Fabry-Perot filter and the data aquisition are implemented and syncronized em FPGA. Peak-detection algorithms, based on centroid and FIR filter, are implemented em FPGA. The peak displacement detected of FBG reflected spectrum is used to refer sensed elements, such as variation of temperature and refractive index. Besides, other auxiliary digital circuits are implemented for the system configuration, visulization of the detected peak information and the serial communication to monitor entire spectra in computer. All these digital circuits are working on their own duty at the same time, synchronised by the crystal clock of FPGA. The system was used to monitor the fabrication process of an refractive index sensor. The fabricated sensor was tested by measuring the refractive index of water and sucrose. In another experiment, the system was tested by measuring the temperature of a water sample. In addition, a method to calibrate the tuning signal generator is proposed, which can also be employed in other applications that uses DA converters. Finally, the developed system was packaged to facilitate its transportation. / Este trabalho descreve a implementação de um sistema de interrogação óptico para FBGs multiplexadas, com o controle dos processos implementado em FPGA. A interrogação das FBGs é realizada por meio do método de filtro sintonizável, com o uso de filtro Fabry-Perot. Um FPGA é utilizado para gerar sinal de sintonia para o filtro Fabry-Perot e realizar a leitura do sinal espectral refletido pelas FBGs. Algoritmos de detecção de pico (centroide e filtro FIR) foram implementados no FPGA para processar os sinais refletidos por cada FBG, com o objetivo de inferir as propriedades sensoreadas, como variação de temperatura ou índice de refração. Além destes circuitos digitais, são implementados outros circuitos digitais para a configuração do sistema, para a visualização do pico detectado do sinal espectral e para o monitoramento do espectro inteiro via comunicação serial. Todos circuitos cumprem a própria função paralelamente em virtude do paralelismo do FPGA, sincronizado pelo clock do oscilador cristal do FPGA. O sistema desenvolvido foi utilizado no monitoramento do processo de fabricação de sensor de índice de refração e então na leitura do índice de refração de amostras de sacarose e água. O sistema também foi utilizado para a leitura da temperatura de amostras de água, onde foi estimada a sensibilidade e a resolução do sistema. Também foi proposto um método para a calibração do sistema, que pode ser utilizado também em outros trabalhos. O sistema final foi colocado em uma maleta para facilitar o seu transporte para o local de uso.

Sistema de interrogação óptico

FPGA, Redes de bragg em fibra óptica

Método de filtro sintonizável

Filtro Fabry-Perot

Centróide

Filtro FIR

Temperatura

Índice de refração

Calibração

Optoeletronics instrumentation system

FPGA

Fiber bragg grating

Tunable filter Method

Centroid

FIR filter

Temperature

Refractive index

Calibration

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA

Macroscopic and Microscopic surface features of Hydrogenated silicon thin films

Pepenene, Refuoe Donald

January 2018

Magister Scientiae - MSc (Physics) / An increasing energy demand and growing environmental concerns regarding the use of fossil fuels in South Africa has led to the challenge to explore cheap, alternative sources of energy. The generation of electricity from Photovoltaic (PV) devices such as solar cells is currently seen as a viable alternative source of clean energy. As such, crystalline, amorphous and nanocrystalline silicon thin films are expected to play increasingly important roles as economically viable materials for PV development. Despite the growing interest shown in these materials, challenges such as the partial understanding of standardized measurement protocols, and the relationship between the structure and optoelectronic properties still need to be overcome.

Plasmonic devices for surface optics and refractive index sensing / Composants plasmoniques pour l'optique de surface et la mesure de faibles variations d'indice

Stein, Benedikt

03 July 2012

Ce manuscrit s'inscrit dans le contexte du contrôle de la propagation des plasmons de surface. A cet effet, des nanostructures diélectriques et métalliques ont été conçues et caractérisées par microscopie à champ de fuite dans les espaces réels et réciproques. La manipulation des plasmons de surface à l'aide de lentilles diélectriques et d' éléments à gradient d'indice est présentée, et la réfraction négative, la direction et l'auto-collimation des plasmons de surface dans des cristaux plasmoniques à une ou deux dimensions sont démontrées. Ces résultats ont été utilisés pour le guidage de nanoparticules à l'aide de forces optiques, ainsi que pour deux méthodes permettant de renforcer le facteur de mérite de sondes plasmoniques de variation d'indice de réfraction, basées l' une sur les résonances de Fano naturelles de la microscopie à champ de fuite, et pour la seconde sur les structures des bandes plasmoniques anisotropes. / In this thesis devices for controlling the flow of surface plasmon polaritons are described. Dielectric and metallic nanostructures were designed for this purpose, and characterized by leakage radiation microscopy in real and in reciprocal spaces. Manipulation of surface plasmons by dielectric lenses and gradient index elements is presented, and negative refraction, steering and self-collimation of surface plasmons in one- and two-dimensional plasmonic crystals is demonstrated. The achieved degree of control was applied for routing of nanoparticles by optical forces, as well as for two methods of enhancing the figures of merit of plasmonic refractive index sensors, based on the one hand on Fano resonances natural to leakage radiation microscopy, and on the other hand on anisotropie plasmonic bandstructures.

Nano-optique

Plasmons de surface

Microscopie à champ de fuite

Métamatériaux

Cristaux plasmoniques

Effet superprisme

Réfraction négative

Auto-collimation

Micromanipulation optique

Détection de variation d'indice

Résonance de Fano

Nano-optics

Surface plasmons

Leakage radiation microscopy

Metamaterials

Plasmonic crystals

Superprism effect

Negative refraction

Self-collimation

Optical micromanipulation

Refractive index sensing

Fano resonances

539.1

Estudos das propriedades estruturais e ópticas de vidros teluritos / Studies of the structural and optical properties of the tellurite glasses

Júlia Maria Giehl

25 February 2011

Vidros teluritos são considerados fortes candidatos para aplicações em lasers e óptica não linear devido a importantes características, como o elevado índice de refração, baixa energia de fônons, baixa temperatura de transição vítrea e sua fácil preparação. Neste trabalho foram produzidas amostras dos sistemas vítreos TeO2- ZnO-Na2O, TeO2-Nb2O5-Na2O e Te2O-Na2O incluindo ou não dopagens de AgNO3 para estudos estruturais e ópticos. As propriedades estruturais e os mecanismos de recombinação destes vidros foram estudados por meio das técnicas de ressonância paramagnética eletrônica, termoluminescência e correntes de despolarização termicamente estimuladas. Já as propriedades ópticas como o coeficiente de absorção linear, índice de refração linear e não linear foram estudadas por meio das técnicas de absorção óptica, acoplamento de prismas e varredura Z. Foram ainda desenvolvidos estudos da precipitação de nanopartículas de prata para o sistema TeO2-ZnO-Na2O com dopagens de AgNO3 com diferentes temperaturas de tratamento térmico. A caracterização das nanopartículas metálicas foi realizada por meio da técnica de absorção óptica auxiliada por microscopia eletrônica de transmissão e espectrometria de energia dispersiva. Foram observadas por ressonância paramagnética eletrônica quatro respostas paramagnéticas dos vidros irradiados com raio , sendo uma de natureza desconhecida e as outras três identificadas como g¹, g² e g³ atribuídas respectivamente ao centro de buraco do telúrio e do oxigênio, centro de buraco do oxigênio terminal e centro de elétron do telúrio. Foi proposto ainda um modelo para explicar os mecanismos de formação destes centros. A partir dos resultados de termoluminescência observou-se que os processos de recombinação destes centros de defeitos são não radioativos. Neste projeto foram estudados pela primeira vez na literatura os fenômenos de polarização e despolarização em vidros teluritos, com e sem irradiação gama, por meio da técnica de correntes de despolarização termicamente estimuladas. Quanto às propriedades ópticas, foi investigada a influência da adição de prata dos sistemas vítreos TeO2-ZnO-Na2O e TeO2-Nb2O5-Na2O em relação à energia do gap, a cauda de Urbach, índice de refração linear e não linear.Nos resultados de varredura Z do sistema vítreo TeO2-Nb2O5-Na2O foi observado o aumento da assimetria na curva com aumento da adição de AgNO3 Este fenômeno foi explicado por meio de uma adaptação do modelo de Sumi para processos não radiativos, responsáveis pelo aumento do caráter térmico do índice de refração não linear. Por fim um modelo foi criado para explicar a precipitação de nanopartículas de prata na matriz vítrea TeO2-ZnO-Na2O mediante tratamento térmico. / Tellurite glasses are considered powerful candidates for applications in lasers and nonlinear optics due to their important properties such as high refractive index, low phonon energy, relatively low glass transition temperature and easy glass production at room atmosphere. In this work glass samples of the systems ZnO-Na2O, TeO2-Nb2O5-Na2O and Te2O-Na2O were produced, including or not the AgNO3 doping for the structural and optical study purposes. The structural properties and the recombination mechanisms of these glasses were studied by means of the techniques of electron paramagnetic resonance, thermoluminescence and thermally stimulated depolarization currents. The optical properties such as the optical linear absorption coefficient, linear and nonlinear refractive index were studied by means of the optical absorption techniques, prism coupling and Z-scan. Further studies were developed on the precipitation of silver nanoparticles embedded in the glass system TeO2-ZnO-Na2O doped with AgNO3, by means of thermal treatments at different temperatures. The characterization of the metallic nanoparticles was carried out by optical absorption aided by transmission electron microscopy and dispersive energy spectroscopy. Four paramagnetic responses were observed by electron paramagnetic resonance of the -irradiated glasses, one not yet identified and the other three identified as g0, g1 and g3 attributed respectively to the tellurium-oxygen hole center, non-bridging oxygen hole center and tellurium electron center. A model to explain the formation mechanisms of these centers was proposed. The thermoluminescence results indicated that the recombination processes of these centers are non-radiative. This is the first study that deals with polarization and depolarization phenomena in tellurite glasses with and without gamma irradiation, by the technique of thermally stimulated depolarization currents. In what regards the optical properties of the glass systems TeO2-ZnONa2O and TeO2-Nb2O5-Na2O, the effect of the silver doping on the gap energy, Urbach tail, linear and nonlinear refractive indices were investigated. Through the Z-scan technique results of the glass system TeO2-Nb2O5-Na2O, an increasing asymmetry of the curve, with increasing AgNO3 content was observed. This phenomenon was explained through an adaptation of Sumi´s model for non-radiative processes, applied to a silver doped insulating glass, to explain the thermal character of the nonlinear refractive index. Finally, a model was developed to explain the silver nanoparticles precipitation in the TeO2-ZnO-Na2O glass matrix submitted to thermal treatment.

Absorção óptica

Centros de defeitos

Índice de refração não linear

Microscopia eletrônica de transmissão

Nanopartículas de prata

Ressonância paramagnética eletrônica

Termoluminescência

Varredura Z

Vidros teluritos

Defect centers

Electron paramagnetic resonance

Nonlinear refractive index

Optical absorption

Silver nanoparticles

Tellurite glasses

Thermoluminescence

Transmission electron microscopy

Z-scan