Global ETD Search

331	Shining new light on motoneurons: characterization of motoneuron dendritic spines using light microscopy and novel analytical methods McMorland, Angus John Cathcart January 2009 (has links) Dendritic spines are fundamental units of information processing within the nervous system, responsible for independent modulation of synaptic input to neurons. Filopodia, often morphologically indistinguishable from spines, are involved in formation of synapses during neuronal development. Despite the importance of these structures for neuronal function, no detailed study of their presence on motoneurons has yet been made. Here, the presence of spines on hypoglossal motoneurons (HMs) is described at three developmental stages: at P0–2 and P9–11, spines are present at an average density of ~0.1 spines/micron, but at P19 spine density becomes negligible. In P0–2 and P9–11, spines are nonuniformly distributed, occuring in clusters, and at lower density in the most proximal and distal regions to the soma than at intermediate regions. HM spines coincide with a decrease in cell input resistance, which reduces excitability during development. Thus one may speculate that these spines are involved in the formation of new synapses required to maintain adequate excitatory drive. A major difficulty for the study of spines is their small size, which complicates measurement using optical methods. Here, I present a novel method for reconstructing spine morphology using geometric models based on a priori knowledge of spine structure. Tests of the technique using simulated data indicate that it has a resolving capability of up to 40 nm (limited by noise). The technique has been used to measure dendritic spines on HMs, showing that these structures have necks as small as 0.22 micron. For purely passive modulation of synaptic strength, spine necks need to be <~ 0.15 micron. These data suggest that if modulation of synaptic input occurs, biochemical and/or active electrical processes are needed. The methods developed in this Thesis, which have here been applied to HMs, are generally applicable to the study of spine morphology, and its effect on synaptic processing, in all classes of neurons. neuroscience microscopy dendritic spines high resolution two-photon fluorescence mice motoneuron
332	Shining new light on motoneurons: characterization of motoneuron dendritic spines using light microscopy and novel analytical methods McMorland, Angus John Cathcart January 2009 (has links) Dendritic spines are fundamental units of information processing within the nervous system, responsible for independent modulation of synaptic input to neurons. Filopodia, often morphologically indistinguishable from spines, are involved in formation of synapses during neuronal development. Despite the importance of these structures for neuronal function, no detailed study of their presence on motoneurons has yet been made. Here, the presence of spines on hypoglossal motoneurons (HMs) is described at three developmental stages: at P0–2 and P9–11, spines are present at an average density of ~0.1 spines/micron, but at P19 spine density becomes negligible. In P0–2 and P9–11, spines are nonuniformly distributed, occuring in clusters, and at lower density in the most proximal and distal regions to the soma than at intermediate regions. HM spines coincide with a decrease in cell input resistance, which reduces excitability during development. Thus one may speculate that these spines are involved in the formation of new synapses required to maintain adequate excitatory drive. A major difficulty for the study of spines is their small size, which complicates measurement using optical methods. Here, I present a novel method for reconstructing spine morphology using geometric models based on a priori knowledge of spine structure. Tests of the technique using simulated data indicate that it has a resolving capability of up to 40 nm (limited by noise). The technique has been used to measure dendritic spines on HMs, showing that these structures have necks as small as 0.22 micron. For purely passive modulation of synaptic strength, spine necks need to be <~ 0.15 micron. These data suggest that if modulation of synaptic input occurs, biochemical and/or active electrical processes are needed. The methods developed in this Thesis, which have here been applied to HMs, are generally applicable to the study of spine morphology, and its effect on synaptic processing, in all classes of neurons. neuroscience microscopy dendritic spines high resolution two-photon fluorescence mice motoneuron
333	Shining new light on motoneurons: characterization of motoneuron dendritic spines using light microscopy and novel analytical methods McMorland, Angus John Cathcart January 2009 (has links) Dendritic spines are fundamental units of information processing within the nervous system, responsible for independent modulation of synaptic input to neurons. Filopodia, often morphologically indistinguishable from spines, are involved in formation of synapses during neuronal development. Despite the importance of these structures for neuronal function, no detailed study of their presence on motoneurons has yet been made. Here, the presence of spines on hypoglossal motoneurons (HMs) is described at three developmental stages: at P0–2 and P9–11, spines are present at an average density of ~0.1 spines/micron, but at P19 spine density becomes negligible. In P0–2 and P9–11, spines are nonuniformly distributed, occuring in clusters, and at lower density in the most proximal and distal regions to the soma than at intermediate regions. HM spines coincide with a decrease in cell input resistance, which reduces excitability during development. Thus one may speculate that these spines are involved in the formation of new synapses required to maintain adequate excitatory drive. A major difficulty for the study of spines is their small size, which complicates measurement using optical methods. Here, I present a novel method for reconstructing spine morphology using geometric models based on a priori knowledge of spine structure. Tests of the technique using simulated data indicate that it has a resolving capability of up to 40 nm (limited by noise). The technique has been used to measure dendritic spines on HMs, showing that these structures have necks as small as 0.22 micron. For purely passive modulation of synaptic strength, spine necks need to be <~ 0.15 micron. These data suggest that if modulation of synaptic input occurs, biochemical and/or active electrical processes are needed. The methods developed in this Thesis, which have here been applied to HMs, are generally applicable to the study of spine morphology, and its effect on synaptic processing, in all classes of neurons. neuroscience microscopy dendritic spines high resolution two-photon fluorescence mice motoneuron
334	"Não linearidades ópticas em azocompostos" / Optical nonlinearities in azocompounds Leonardo de Boni 10 December 2004 (has links) Neste trabalho, são estudadas as alterações das propriedades ópticas lineares e não lineares de soluções de azocompostos devidas aos mecanismos de isomerização e às alterações das propriedades estruturais com a temperatura. A dependência da transição pipi* com a estrutura linear dos azocompostos é notada já nas medidas dos espectros de absorção em função da temperatura para o isômero trans. Através do conhecimento dos níveis de energia e dos tempos de relaxação via isomerização, foi possível obter a dinâmica entre os isômeros cis e trans. As medidas não lineares forneceram propriedades interessantes associadas aos estados de energia dos compostos. Por exemplo, através de experimentos de varredura-z e de excitação e prova, foi possível ver que os azocompostos apresentam uma alta transparência quando excitados, a qual desaparece com o término da isomerização. Medidas em função do comprimento de onda mostraram que a transparência observada está presente em toda a banda pipi* e não ocorre na banda npi* . Também foi observado que o tempo de isomerização muda de acordo com o comprimento de onda de excitação, o que pode estar relacionado com a superposição das duas bandas. Os resultados obtidos em femtossegundos foram essenciais para descrever o processo dinâmico de fotoisomerização, observado, por completo, através de medidas com varredura-Z em picossegundos e nanossegundos. Essas medidas forneceram os valores das seções de choque dos isômeros cis, que são difíceis de serem quantificadas devido ao curto tempo de vida desse isômero. Além dos resultados ressonantes, foram feitos experimentos de absorção de dois fótons em femtossegundos usando a técnica de varredura-Z. Esses estudos mostraram a dependência das seções de choque de absorção de dois fótons com características estruturais das moléculas, tais como comprimento de conjugação, grupos push-pull e planaridade. Os resultados ressonantes e não ressonantes obtidos em femtossegundos serviram de base para a calibração da técnica de varredura-Z com pulsos de luz branca. Essa técnica se mostrou adequada para a obtenção dos espectros das não linearidades ópticas ressonantes e não ressonantes em uma única medição (de 5 minutos), diminuindo assim flutuações do laser durante o experimento. / This work reports on the temperature dependence of linear and nonlinear properties of azocompounds solutions due to isomerization mechanisms. The dependence of pipi* transitions on the linear structure of azocompounds is already noticeble in the measurements of absorption spectra as function of the temperature for the trans isomer. Knowing the energy levels and the relaxation times through isomerization, it was possible to obtain the exchange dynamics between cis and trans conformations. Nonlinear measurements provided interesting properties associated with the energy levels of de compounds. For exemple, through Z-scan and pumpprobe experiments, it was possible to verify that azocompounds present a high transparency when excited and that this transparency disapears when the izomerization ends. The wavelength change has shown that the observed transparency is present along the complete pipi* band, but not in the npi* band. It was also observed that the isomerization time changes with the exciting wavelength, which may be related to the superposition of both bands. The results obained with femtoseconds pulses were essential to completily describe the photoisomerization process observed with Z-scan measurements using picoseconds and nanoseconds pulses. These measurements provided values of the crosssection of the cis conformation, which are difficult to be quantified due to the short lifetime of this isomer. Besides ressonant results, experiments of two-photon absorption in the femtosecond regime using the Z-scan technique were made. These studies shown the dependence of the two photons absorption cross-section on structural features of molecules such as conjugation length, push-pull groups and planarity. The ressonant and nonressonant results obteined with femtoseconds have provide the calibration of the Z-scan technique with white light pulses. This technique has been found able to obtain the spectra of ressonat and nonressonant nonlinearities in a single measurement (about 5 minutes), diminishing laser fluctuation during the experiment. Absorção de dois fótons Absorção de estado excitado Absorção multifotônica Azocompostos Dependência com a temperatura Femptossegundos Óptica Não Linear Pulso de Luz Branca refração não linear técnica de excitação e prova Tempo de vida Varredura-Z Azocopounds Excited state absorption Femtosecond life-time Moltiphoton absorption Nonlinear optics nonlinear refraction pump-probe method Thermal dependence Two-photon absorption white light continuum Z-scan
335	Nanoscale imaging of synapse morphology in the mouse neocortex in vivo by two-photon STED microscopy / Imagerie nanométrique de la morphologie synaptique dans le néocortex de souris in vivo par microscopie deux-photon STED Ter Veer, Mirelle Jamilla Tamara 25 November 2016 (has links) Le cerveau est un organe complexe composé de neurones et des cellules non-neuronales. La communication entre les neurones a lieu via les synapses, dont le remodelage morphologique est considéré essentiel pour le traitement et le stockage des informations dans le cerveau des mammifères. Récemment, ce point de vue neuro-centré de la fonction synaptique a évolué, en prenant également en compte les processus gliaux à proximité immédiate de la synapse. Cependant, comme leur structure est bien en deçà de la résolution spatiale de la microscopie optique conventionnelle, les progrès dans les enquêtes dans leur environnement physiologique, le cerveau intact, ont été entravés. En effet, on sait peu sur les variations nanométriques de la morphologie des épines dendritiques et l'interaction avec les processus gliaux, et, finalement, comment elles affectent la transmission synaptique in vivo. Dans cette thèse, nous cherchons à visualiser la dynamique de la nano-morphologie des épines dendritiques et les processus gliaux dans le cortex à tonneaux de souris in vivo. Nous avons donc mis en place l’imagerie super-résolution 2P-STED en temps réel, ce qui permet une haute résolution spatiale et la pénétration profonde des tissus, chez la souris anesthésiée in vivo. Nous montrons que la nano-morphologie des épines est diversifiée, variable, mais globalement stable, et que les différences dans la morphologie des épines peut avoir un effet sur leur compartimentation in vivo. En outre, la mise en œuvre de l’imagerie super-résolution en double couleur in vivo et le développement d'une approche de marquage astrocytaire, nous ont permis de fournir la caractérisation à l'échelle nanométrique des interactions neurone-glie. Ces résultats apportent un aperçu sans précédent dans la dynamique de la synapse à l'échelle nanométrique in vivo, et ouvrent la voie à une meilleure compréhension de la façon dont les réarrangements morphologiques des synapses contribuent à la physiologie du cerveau. / The brain is a complex organ consisting of neurons and non-neuronal cells. Communication between neurons takes place via synapses, whose morphological remodeling is thought to be crucial for information processing and storage in the mammalian brain. Recently, this neuro-centric view of synaptic function has evolved, also taking into account the glial processes in close vicinity of the synapse. However, as their structure is well below the spatial resolution of conventional light microscopy, progress in investigating them in a physiological environment, the intact brain, has been impeded. Indeed, little is known on the nanoscale morphological variations of dendritic spines, the interaction with glial processes, and how these affect synaptic transmission in vivo. Here, we aim to visualize the dynamic nano-morphology of dendritic spines in mouse somatosensory cortex in vivo. We implemented super-resolution 2P-STED time-lapse imaging, which allows for high spatial resolution and deep tissue penetration, in anesthetized mice, and show that the nano-morphology of spines is diverse, variable, but on average stable, and that differences in spine morphology can have an effect on spine biochemical compartmentalization in vivo. Moreover, implementation of dual color in vivo super-resolution imaging and a novel astrocytic labeling approach provided the first steps towards nanoscale characterization of neuron-glia interactions in vivo. These findings bring new insights in synapse dynamics at the nanoscale in vivo, and our methodological endeavors help pave the way for a better understanding of how nanoscale aspects of spine morphology and their dynamics might contribute to brain physiology and animal behavior. Microscopie super résolution Microscopie à deux photons (2P) et STED Préparation in vivo du cerveau Épines dendritiques FRAP Compartimentation des épines Imagerie double couleur Processus gliaux Super-resolution microscopy Two-Photon (2P-) STED microscopy In vivo brain preparation Dendritic spines FRAP Spine compartmentalization Dual color imaging Glial processes
336	Conception et étude de chromophores polyméthines pour l'optique non-linéaire dans le proche infrarouge / Conception and study of polymethine chromophores for nonlinear optics in the near-infrared Pascal, Simon 27 June 2014 (has links) L’objectif de cette thèse consistait à développer des colorants de la famille des polyméthines absorbant dans le proche infrarouge et présentant des propriétés d’optique non-linéaire (ONL) prononcées. De nouveaux chromophores ont été préparés et leurs propriétés spectroscopiques ont été systématiquement étudiées afin d’établir des relations structures-propriétés. Cette stratégie a permis l’identification des facteurs permettant d’exalter la réponse ONL des polyméthines et de prédire leur comportement face à de subtiles modifications structurales. Trois familles de colorants ont été préparées : des monométhines aza-dipyrrométhènes de bore, des heptaméthines symétriques ainsi que des heptaméthines dissymétriques.Dans un premier temps, des aza-bodipys possédant des groupements donneurs périphériques sont synthétisés. Une étude spectroscopique approfondie permet d’identifier les structures présentant une absorption à deux photons importante en vue d’applications en limitation optique aux longueurs d’onde des télécommunications (1500 nm). Le chapitre suivant a pour but de rationaliser les équilibres de la limite cyanine. L’étude de la substitution centrale de nombreux dérivés heptaméthines a permis de moduler leurs propriétés optiques sur une large gamme spectrale et de mettre en évidence une nouvelle structure électronique limite de type bis-dipôle. Parmi cette famille de colorants, des dérivés keto-heptaméthines ont été utilisées en imagerie biologique (cellules et cerveau) par microscopie non-linéaire. Enfin, l’élaboration de structures heptaméthines dissymétriques originales est détaillée dans le dernier chapitre. Ces chromophores ont révélé des propriétés ONL du second ordre idéales pour des applications en modulation électro-optique. / The aim of this thesis consisted in developing dyes from the polymethine family absorbing in the near-infrared (NIR) region and featuring pronounced nonlinear optical (NLO) properties. Several new chromophores have been prepared and their spectroscopic properties have been systematically investigated in order to establish structure-properties relationships. This strategy has permitted the identification of the factors that enhance the NLO response of polymethines and allowed the prediction of their optical behaviour depending on subtle structural modifications. Three families of dyes have been prepared and investigated: boron aza-dipyrro-monomethines (aza-bodipys), symmetrical heptamethines and unsymmetrical heptamethines.In a first time, aza-bodipys possessing electro-donating peripherical substituants has been synthesized. A detailed spectroscopic study allow the identification of structures that present a high two-photon absorption (TPA), towards optical limiting applications at telecommunication wavelengths (1500 nm). The next chapter rationalizes the equilibrium surrounding the cyanine limit. The study of the central substitution of several heptamethines derivatives permitted the fine tuning of their optical properties upon a large spectral region and evidenced a new bis-dipolar electronic structure. Within this dye family, keto heptamethine derivatives has been tested in bio-imaging experiments (living cells and brain) using non-linear microscopy. Finally, the elaboration of original unsymmetrical heptamethines is detailed in the last chapter. These chromophores revealed ideal second order NLO properties for applications in electro-optic modulation. Optique non-linéaire Absorption à deux photons Colorants infrarouges Polyméthines Aza dipyrrométhènes de bore Heptaméthines cyanines Limitation optique Imagerie biologique Modulation électro-optique Nonlinear optics Two-photon absorption Near-infrared dyes Polymethines Boron aza dipyrromethenes Heptamethine cyanines Optical limiting Biological imaging Electro optic modulation
337	Étude théorique et expérimentale de la génération et de la mise en forme d'impulsions térahertz Vidal, Sébastien 14 December 2009 (has links) Cette thèse présente l’étude théorique et expérimentale de la génération et de la mise en forme d’impulsions térahertz (THz). Dans un premier temps, nous avons étudié la génération d’impulsions THz par redressement optique d’impulsions laser femtosecondes intenses dans des cristaux semiconducteurs de ZnTe. Nous avons mis en évidence une forte dépendance de l'efficacité de ce processus de génération avec l'intensité de l'impulsion laser génératrice. Ceci se traduit en particulier par un décalage progressif du spectre vers les basses fréquences et par une évolution anormale de l'énergie THz avec l'intensité laser. Ces comportements résultent d'une combinaison de trois phénomènes : la déplétion de l’impulsion laser au cours de sa propagation dans le cristal, l’absorption de l'onde THz par les porteurs libres créés par absorption à deux photons et une modification de la condition d’accord de phase. Dans un deuxième temps, nous avons développé une approche analytique permettant de générer des impulsions THz de formes particulièrement intéressantes pour les expériences de spectroscopie cohérente ou de contrôle cohérent. Nous avons notamment généré des paires d'impulsions verrouillées en phase, des trains d'impulsions, ainsi que des impulsions THz accordables de grande finesse spectrale. Cette technique repose sur le redressement optique d’impulsions laser femtosecondes mises en forme à l’aide d’un masque à cristaux liquides placé dans le plan de Fourier d’une ligne à dispersion nulle. Afin de démontrer la validité de notre approche, nous avons également développé un programme de simulation qui donne des résultats en très bon accord avec l'expérience. / This thesis deals with the theoretical and experimental study of the generation and shaping of terahertz (THz) pulses. At first, we have studied the generation of THz pulses by optical rectification of intense femtosecond laser pulses in semiconductor ZnTe crystals. We have demonstrated a strong dependence of the efficiency of the generation process with the intensity of the laser pulse. This is evidenced by a progressive shift of the spectrum towards lower frequencies and an abnormal evolution of the THz energy with laser intensity. These behaviors result from a combination of three phenomena: the depletion of the laser pulse during its propagation in the crystal, the absorption of THz wave by free carriers created by two-photon absorption and a change of the phase matching condition. Secondly, we have developed an analytical approach to generate THz shaped pulses particularly interesting for coherent spectroscopy or coherent control. In particular, we have generated phase-locked THz pulses pairs, pulse trains and tunable narrow-band THz pulses. This technique is based on optical rectification of shaped femtosecond laser pulses generated by a liquid crystal Fourier filter. To demonstrate the validity of our approach, we have also developed a program giving results in very good agreement with experiment. Impulsions ultra-courtes Impulsions THz Redressement optique Cristal de ZnTe Absorption à deux photons Mise en forme d’impulsions Trains d’impulsions THz Ultrashort pulses THz pulses Optical rectification ZnTe crystal Two-photon absorption Pulse shaping Phase-locked THz pulse pairs THz pulse trains
338	Méthodes optiques innovantes pour le contrôle rapide et tridimensionnel de l’activité neuronale / Advanced optical methods for fast and three-dimensional control of neural activity Hernández Cubero, Óscar Rubén 22 January 2016 (has links) La révolution en cours des outils optogénétiques - des protéines photosensibles génétiquement induites qui peuvent activer, inhiber et enregistrer l'activité neuronale - a permis d'ouvrir une nouvelle voie pour relier l'activité neuronale et la cognition. Néanmoins, pour profiter au mieux de ces outils nous avons besoin de méthodes optiques qui peuvent projeter des schémas d'illumination complexes dans le cerveau. Pendant mon doctorat, j'ai travaillé sur deux nouveaux systèmes complémentaires pour la stimulation de l'activité neuronale. Le premier système combine des déflecteurs acousto-optiques et une illumination Gaussienne à faible ouverture numérique pour produire une photo activation rapide des outils optogénétiques. La capacité d'accès aléatoire du système permet de délivrer des séquences d'illumination spatialement et temporellement complexes qui simulent avec succès les schémas physiologiques de l'activité des fibres moussues dans des tranches de cerveaux. Ces résultats démontrent que les schémas de stimulation optogénétique peuvent être utilisés pour recréer l'activité en cours et étudier les microcircuits du cerveau dans un environnement physiologique. Alternativement, l'holographie générée par ordinateur (HGO) permet d'améliorer grandement les stimulations optogénétiques en répartissant efficacement la lumière sur plusieurs cibles cellulaires simultanément. Néanmoins, le confinement axial se dégrade pour des schémas d'illuminations larges. Afin de d'améliorer ce point, l’HGO peut être combinée avec une technique de focalisation temporelle qui confine axialement la fluorescence sans dépendre de l'allongement latéral. Les précédentes configurations maintiennent l'excitation non linéaire à un unique plan focal spatiotemporel. Dans cette thèse, je décris deux méthodes différentes qui permettent de dépasser ces limitations et de permettre la génération de schémas focalisés tridimensionnellement, à la fois spatialement et temporellement. / The ongoing revolution of optogenetic tools – genetically encoded light-sensitive proteins that can activate, silence and monitor neural activity – has opened a new pathway to bridge the gap between neuronal activity and cognition. However, to take full advantage of these tools we need optical methods that can deliver complex light patterns in the brain. During my doctorate, I worked on two novel and complementary optical systems for complex spatiotemporally neural activity stimulation. The first system combined acousto-optic deflectors and low numerical aperture Gaussian beam illumination for fast photoactivation of optogenetic tools. The random-access capabilities of the system allowed to deliver complex spatiotemporal illumination sequences that successfully emulated physiological patterns of cerebellar mossy fiber activity in acute slices. These results demonstrate that patterned optogenetic stimulation can be used to recreate ongoing activity and study brain microcircuits in a physiological activity context. Alternatively, Computer Generated Holography (CGH) can powerfully enhance optogenetic stimulation by efficiently shaping light onto multiple cellular targets simultaneously. Nonetheless, the axial confinement degrades for laterally extended illumination patterns. To address this issue, CGH can be combined with temporal focusing that axially confines fluorescence regardless of lateral extent. However, previous configurations restricted nonlinear excitation to a single spatiotemporal focal plane. In this thesis, I describe two alternative methods to overcome this limitation and enable three-dimensional spatiotemporal focused pattern generation. Optogenetique Déflecteur acousto-optique Modulation de phase Excitation biphotonique Modulation du front d'onde Holographie générée par ordinateur Focalisation temporelle Photo conversion de Kaede Suppression de l'ordre zéro Optogenetics Acousto-optic deflectors Low-NA Gaussian beams Phase modulation Two-photon excitation Wave-front shaping Computer generated holography Temporal focusing Three-dimensional light shaping Kaede photoconversion Zero-order suppression 617.752
339	Etudes théoriques des propriétés optiques linéaires et non-linéaires des biomolécules. / Theoretical studies of linear and non-linear optical properties of biomolecules Bonvicini, Andrea 24 October 2019 (has links) Dans cette thèse, les propriétés optiques de biomolécules importantes ont été étudiées en utilisant une approche théorique et, dans un cas, aussi expérimentale. La Théorie de la fonctionnelle de la densité (DFT) et la timedependent-DFT (TD-DFT) sont les principales méthodes de chimie quantique utilisées dans cette thèse. Plusieurs spectroscopies ont été étudiées (au niveau théorique et, dans certains cas, également au niveau expérimental) : absorption électronique linéaire (absorption à un photon, OPA) et non-linéaire (absorption à deux ou trois photons, TPA et 3PA), dichroïsme circulaire électronique (DCE) et spectroscopie de fluorescence. Les effets de l’environnement, particulièrement importants dans des systèmes biologiques, ont été pris en compte, pour les propriétés de l’état fondamental et des états excités en utilisant une méthode multi-échelles QM/MM appelée Polarizable Embedding (PE). L’échantillonnage des conformations a été pris en compte avec des simulations de dynamique moléculaire (MD) qui sont basées sur la mécanique classique. Deux thématiques ont été étudiées dans cette thèse : le cholestérol et le design in silico de ses analogues fluorescents ainsi que la caractérisation des coudes de type β dans différentes conformations grâce à la simulation des spectres DCE. La simulation de plus d’une spectroscopie a été importante dans l’étude des états excités du cholestérol dans des solutions organiques. Le design in silico a suggéré un nouveau stérol-polyénique (P-stérol) qui montre despropriétés optiques améliorées pour le mécanisme d’excitation à trois photons par rapport au déhydroergostérol (DHE), une sonde du cholestérol déjà très utilisée. Ce nouveau P-stérol a été suggéré pour la synthèse. L’étude des spectres de DCE des coudes β en différentes conformations a mené une double conclusion : même si deux allures de DCE pour les conformations des coudes β étudiées (4) ont été trouvées (dans la majorité des cas), la spectroscopie de DCE doit toujours être associée à d’autres techniques spectroscopiques dans la caractérisation en solution des coudes β. / In this thesis, the optical properties of important biomolecules were studied using a theoretical approach and, in one case, also an experimental one. Density Functional Theory (DFT) and time-dependent-DFT (TD-DFT), were the principal quantum chemical methods adopted in this thesis.Various spectroscopies were studied (theoretically and, in some cases, also experimentally) : linear (one-photon, OPA) and non-linear (two- and three-photon, TPA and 3PA) electronic absorption, electronic circular dichroism (ECD) and fluorescence spectroscopy. The environment effects, which are particularly important in biological systems, were taken into account, for both ground and excited states properties, using a multiscale QM/MM method called Polarizable Embedding (PE). The sampling of conformations was addressed by Molecular Dynamic (MD) simulations based on classical mechanics. Two topics were studied in this thesis: cholesterol and the in-silico design of its fluorescent analogues, and the characterization of β-turns in different conformations by simulations of their ECD spectra in aqueous solutions. The simulation of more than one spectroscopy resulted to be important when studying the electronic excited states of cholesterol in organic solutions. The in-silico design study suggested a novel polyene-sterol (P-sterol) which shows improved optical properties for the three-photon excitation mechanism with respect to dehydroergosterol (DHE), an already widely used cholesterol probe. This new P-sterol was thus suggested for synthesis. The achievement from the study of ECD spectra for different β-turn conformations is two-fold: even if two ECD patterns for the β-turn conformations studied (4) were found (in most of cases), ECD spectroscopy should be always associated with other spectroscopic techniques when trying to characterize the β-turn conformations in solutions. Cholestérol Analogues cholestérol TD-DFT CASPT2 QM/MM Intégration polarisable Fluorescence Absorption à deux photons Absorption à trois photons Spectroscopie linéaire Spectroscopie non-linéaire Dichroïsme circulaire Coudes-β Cholesterol Cholesterol analogues TD-DFT CASPT2 QM/MM Polarizable embedding Fluorescence Two-photon absorption Three-photon absorption Linear spectroscopy Non-linear spectroscopy Circular dichroism Βeta-turns 547.7
340	NONLINEAR ULTRAFAST-LASER SPECTROSCOPY OF GAS-PHASE SPECIES AND TEMPERATURE IN HIGH-PRESSURE REACTING FLOWS Kazi Arafat Rahman (8085560) 05 December 2019 (has links) <p>Ultrafast laser-based diagnostic techniques are powerful tools for the detailed understanding of highly dynamic combustion chemistry and physics. The ultrashort pulses provide unprecedented temporal resolution along with high peak power for broad spectral range−ideal for nonlinear signal generation at high repetition rate−with applications including next-generation combustors for gas turbines, plasma-assisted combustion, hypersonic flows and rotating detonation engines. The current work focuses on advancing (i) femtosecond (fs) two-photon laser-induced fluorescence, and (ii) hybrid femtosecond/picosecond vibrational and rotational coherent anti-Stokes Raman scattering (fs/ps RCARS and VCARS) to higher pressures for the first time. </p><p>Quantitative single-laser-shot kHz-rate concentration measurements of key atomic (O-atom) and molecular (CO) species is presented using femtosecond two-photon laser-induced fluorescence (TP-LIF) for a range of equivalence ratios and pressures in diffusion flames. A multitude of signal-interfering sources and loss mechanisms−relevant to high-pressure fs TP-LIF applications−are also quantified up to 20 atm to ensure high accuracy. The pressure scaling of interferences take into account degradation, attenuation and wave-front distortion of the excitation laser pulse; collisional quenching and pressure dependent transition line-broadening and shifting; photolytic interferences; multi-photon ionization; stimulated emission; and radiation trapping. </p><p>Hybrid fs/ps VCARS of N<sub>2</sub> is reported for interference-free temperature measurement at 1300-2300 K in high-pressure, laminar diffusion flames up to 10 atm. A time asymmetric probe pulse allowed for detection of spectrally resolved CARS signals at probe delays as early as ~200-300 fs while being independent of collisions for the full range of pressures and temperatures. Limits of collisional independence, accuracy and precision of the measurement is explored at various probe-pulse delays, pressures and temperatures. </p><p> </p><p>Additionally, a novel all diode-pumped Nd:YAG amplifier design is presented for generation of time-synchronized ps-probe pulses for hybrid fs/ps RCARS of N<sub>2</sub>. High-energy, nearly transform-limited, single-mode, chirp-free ps probe-pulses are generated at variable pulsewidths. The detailed architecture and characterization of the laser is presented. kHz-rate RCARS thermometry is presented up to 2400 K. Excellent spatial, spectral, and temporal beam quality allowed for fitting the theoretical spectra with a simple Gaussian model for the probe pulse with temperature accuracies of 1-2%. </p> <p><br></p> Aerospace Engineering Mechanical Engineering Nonlinear Optics and Spectroscopy combustion diagnostic laser diagnostics nonlinear spectroscopy high-pressure flames two-photon laser-induced fluorescence Multiphoton processes Optical amplifiers Self-focusing Ultrafast spectroscopy Ultrafast lasers

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