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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Spatio-temporal ultrafast laser tailoring for bulk functionalization of transparent materials

Mauclair, Cyril 27 May 2010 (has links) (PDF)
In the past decade, ultrashort laser sources have had a decisive impact on material processing for photonic applications. The technique is usually restricted to the elemental association of an ultrashort source with a focusing lens. It is thus limited in the achievable bulk modifications. Accompanying studies of material modifications in space and time, we propose here that automated spatio-temporal tailoring of the laser pulses is an efficient manner to overcome these limitations. More precisely, we demonstrate the generation of multiple processing foci for synchronous photomachining of multiple devices in the bulk. Thus, we report on the parallel photowriting of waveguides, light couplers, light dividers in 2D/3D in fused silica glass. We show that the domain of photowriting can be extended to deep focusing. We indicate that this can be achieved by wavefront shaping or temporal profile tailoring conducted by an evolutionary optimization loop. We also have unveiled a singular interaction regime where regular structuring takes place before the focal region. For the first time, the dynamics of the energy coupling to the glassy matrix is evaluated for various temporal pulse profiles. Enhanced energy confinement in the case of picosecond pulses is confirmed by characterization of the transient electronic gas and of the subsequent pressure. These pump-probe studies were carried out with a self-build time-resolved microscopy system with temporally shaped pump irradiation. We also developed a new method based on the Drude model to differentiate the electronic and matrix contributions to the contrast of the microscopy images.
2

Spatio-temporal ultrafast laser tailoring for bulk functionalization of transparent materials / Mise en forme spatio-temporelle d’impulsions laser ultracourtes pour la fonctionnalisation dans le volume de matériaux transparents

Mauclair, Cyril 27 May 2010 (has links)
L’arrivée des sources lasers ultracourtes a bouleversé le domaine de la micro-structuration pour l’optique intégrée. Le plus souvent, le procédé se résume à l’utilisation d’une lentille de focalisation sur le trajet du faisceau laser. Cette méthode souffre de limitations intrinsèques sur la vitesse d’usinage et sur le spectre des modifications accessibles. Nous montrons dans ce mémoire que la mise en forme spatio-temporelle des impulsions lasers ultracourtes répond efficacement à ces défis. En particulier, nous indiquons la possibilité de multiplier le nombre de spots lasers pour la fabrication simultanée de plusieurs composants optiques, en répondant ainsi au besoin de rapidité. Cette avancée majeure est illustrée par la photoinscription en parallèle de guides, de diviseurs, de coupleurs ainsi que de démultiplexeurs de lumière en 2Det 3D dans la silice. Il est également reporté ici que le domaine de photoinscription peut être élargi à la focalisation profonde dans les matériaux grâce à la modulation du front d’onde ainsi que la mise en forme temporelle de l’impulsion permettant de préserver la densité d’énergie déposée. Le couplage d’énergie vers le matériau transparent en fonction de divers profils d’impulsions est étudié à l’échelle femtoseconde. La caractérisation du gaz d’électrons libres ainsi que de l’onde de pression nous permet de mettre en évidence l’efficacité des impulsions picosecondes `a déposer l’énergie de manière plus confinée dans différents verres. Ces études sont conduites sur un système de microscopie de type pompe-sonde permettant de mettre en forme l’irradiation pompe. / In the past decade, ultrashort laser sources have had a decisive impact on material processing for photonic applications. The technique is usually restricted to the elemental association of an ultrashort source with a focusing lens. It is thus limited in the achievable bulk modifications. Accompanying studies of material modifications in space and time, we propose here that automated spatio-temporal tailoring of the laser pulses is an efficient manner to overcome these limitations. More precisely, we demonstrate the generation of multiple processing foci for synchronous photomachining of multiple devices in the bulk. Thus, we report on the parallel photowriting of waveguides, light couplers, light dividers in 2D/3D in fused silica glass. We show that the domain of photowriting can be extended to deep focusing. We indicate that this can be achieved by wavefront shaping or temporal profile tailoring conducted by an evolutionary optimization loop. We also have unveiled a singular interaction regime where regular structuring takes place before the focal region. For the first time, the dynamics of the energy coupling to the glassy matrix is evaluated for various temporal pulse profiles. Enhanced energy confinement in the case of picosecond pulses is confirmed by characterization of the transient electronic gas and of the subsequent pressure. These pump-probe studies were carried out with a self-build time-resolved microscopy system with temporally shaped pump irradiation. We also developed a new method based on the Drude model to differentiate the electronic and matrix contributions to the contrast of the microscopy images.
3

Controle das características geométricas de nanopartículas de prata através da conformação temporal de pulsos ultracurtos utilizando algorítimos genéticos / Control of the geometric characteristics of silver nanoparticles by ultrashort pulses temporal shaping using genetic algorithms

Cordeiro, Thiago da Silva 12 August 2013 (has links)
Este trabalho utilizou pulsos laser ultracurtos para modificar, de forma controlada, as características dimensionais de nanopartículas de prata em solução aquosa. Para atingir este objetivo foram empregados algoritmos genéticos e circuitos microfluídicos. Utilizou-se um conformador temporal de pulsos ultracurtos para criar diversos perfis temporais de pulsos que irradiaram soluções de nanopartículas de prata. Estes perfis temporais foram ajustados em tempo real, visando otimizar o resultado do experimento, quantificada pela diminuição do diâmetro médio das nanopartículas nas soluções irradiadas. Uma vez que cada experimento de minimização do diâmetro das nanopartículas exigiu centenas de medidas, sua realização foi possível em decorrência da utilização de um circuito microfluídico construído especialmente para este trabalho. Neste circuito é possível utilizar pequenas quantidades de amostra, levando a curtos tempos de irradiação e medição, além da evidente economia de amostras. Para a realização deste trabalho foi elaborado e testado um algoritmo genético interfaceado a diversos equipamentos, incluindo um filtro acustóptico dispersivo programável que modifica as características temporais dos pulsos ultracurtos, através da introdução de componentes de fases espectrais nestes pulsos. Utilizando o algoritmo genético e o filtro acustóptico dispersivo programável foram realizados experimentos de encurtamento da duração temporal dos pulsos ultracurtos provenientes do sistema laser, resultando na obtenção de pulsos com durações próximas às limitadas por transformada de Fourier. Além disso, foram realizados experimentos para a otimização do processo evolutivo do algoritmo genético escrito em Labview. Os experimentos de irradiação de soluções de nanopartículas de prata mostraram que, ao conformar a duração dos pulsos utilizados nas irradiações, pôde-se controlar as dimensões destas nanopartículas, diminuindo seu tamanho médio por um fator 2. Esses experimentos caracterizam a irradiação de nanopartículas por lasers de pulsos ultracurtos como uma importante técnica de controle de características de nanopartículas. / This work used ultrashort laser pulses to modify, in a controlled way, the dimensional characteristics of silver nanoparticles in aqueous solution. To reach this goal, genetic algorithm and microfluidic circuits were used. A pulse shaper was used to create different temporal profiles for the ultrashort pulses used to irradiate the silver nanoparticle solutions. These temporal profiles were conformed in real time, aiming to optimize the experiment result, quantified by the decrease of the average diameter of the nanoparticles in the irradiated solutions. Since each nanoparticle diameter minimization experiment demanded hundreds of measurements, its achievement was possible by the use of a microfluidic circuit specially built for this work. This circuit enables the use of small sample quantities, leading to short irradiation and measurement intervals, besides evident sample savings. To make this work possible, a genetic algorithm was created and tested. This genetic algorithm was interfaced to several equipments, including an acustooptic programmable dispersive filter that modifies the ultrashort pulses temporal characteristics by the introduction of spectral phases in the pulses. The genetic algorithm and the acustooptic programmable dispersive filter were used in conjunction in experiments to temporally shorten the ultrashort pulses from the laser system, generating pulses durations close to the Fourier transform limited ones. Besides, experiments were performed with the Labview coded genetic algorithm to optimize its evolutionary process. The silver nanoparticles irradiation experiments showed that the ultrashort pulses temporal conformation allowed the control of these particles dimensions, decreasing its mean size by a factor of 2. These experiments characterize the nanoparticles irradiation by ultrashort pulses as an important technique to control the nanoparticles characteristics.
4

Controle das características geométricas de nanopartículas de prata através da conformação temporal de pulsos ultracurtos utilizando algorítimos genéticos / Control of the geometric characteristics of silver nanoparticles by ultrashort pulses temporal shaping using genetic algorithms

Thiago da Silva Cordeiro 12 August 2013 (has links)
Este trabalho utilizou pulsos laser ultracurtos para modificar, de forma controlada, as características dimensionais de nanopartículas de prata em solução aquosa. Para atingir este objetivo foram empregados algoritmos genéticos e circuitos microfluídicos. Utilizou-se um conformador temporal de pulsos ultracurtos para criar diversos perfis temporais de pulsos que irradiaram soluções de nanopartículas de prata. Estes perfis temporais foram ajustados em tempo real, visando otimizar o resultado do experimento, quantificada pela diminuição do diâmetro médio das nanopartículas nas soluções irradiadas. Uma vez que cada experimento de minimização do diâmetro das nanopartículas exigiu centenas de medidas, sua realização foi possível em decorrência da utilização de um circuito microfluídico construído especialmente para este trabalho. Neste circuito é possível utilizar pequenas quantidades de amostra, levando a curtos tempos de irradiação e medição, além da evidente economia de amostras. Para a realização deste trabalho foi elaborado e testado um algoritmo genético interfaceado a diversos equipamentos, incluindo um filtro acustóptico dispersivo programável que modifica as características temporais dos pulsos ultracurtos, através da introdução de componentes de fases espectrais nestes pulsos. Utilizando o algoritmo genético e o filtro acustóptico dispersivo programável foram realizados experimentos de encurtamento da duração temporal dos pulsos ultracurtos provenientes do sistema laser, resultando na obtenção de pulsos com durações próximas às limitadas por transformada de Fourier. Além disso, foram realizados experimentos para a otimização do processo evolutivo do algoritmo genético escrito em Labview. Os experimentos de irradiação de soluções de nanopartículas de prata mostraram que, ao conformar a duração dos pulsos utilizados nas irradiações, pôde-se controlar as dimensões destas nanopartículas, diminuindo seu tamanho médio por um fator 2. Esses experimentos caracterizam a irradiação de nanopartículas por lasers de pulsos ultracurtos como uma importante técnica de controle de características de nanopartículas. / This work used ultrashort laser pulses to modify, in a controlled way, the dimensional characteristics of silver nanoparticles in aqueous solution. To reach this goal, genetic algorithm and microfluidic circuits were used. A pulse shaper was used to create different temporal profiles for the ultrashort pulses used to irradiate the silver nanoparticle solutions. These temporal profiles were conformed in real time, aiming to optimize the experiment result, quantified by the decrease of the average diameter of the nanoparticles in the irradiated solutions. Since each nanoparticle diameter minimization experiment demanded hundreds of measurements, its achievement was possible by the use of a microfluidic circuit specially built for this work. This circuit enables the use of small sample quantities, leading to short irradiation and measurement intervals, besides evident sample savings. To make this work possible, a genetic algorithm was created and tested. This genetic algorithm was interfaced to several equipments, including an acustooptic programmable dispersive filter that modifies the ultrashort pulses temporal characteristics by the introduction of spectral phases in the pulses. The genetic algorithm and the acustooptic programmable dispersive filter were used in conjunction in experiments to temporally shorten the ultrashort pulses from the laser system, generating pulses durations close to the Fourier transform limited ones. Besides, experiments were performed with the Labview coded genetic algorithm to optimize its evolutionary process. The silver nanoparticles irradiation experiments showed that the ultrashort pulses temporal conformation allowed the control of these particles dimensions, decreasing its mean size by a factor of 2. These experiments characterize the nanoparticles irradiation by ultrashort pulses as an important technique to control the nanoparticles characteristics.

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