Global ETD Search

91	CONSTRUCTIVE (COHERENT) ELASTIC MICROWAVE SCATTERING-BASED PLASMA DIAGNOSTICS AND APPLICATIONS TO PHOTOIONIZATION Adam Robert Patel (13171986) 29 July 2022 (has links) <p>Constructive elastic microwave scattering, or, historically, coherent microwave scattering (CMS), refers to the inference of small plasma object characteristics via in-phase electromagnetic scattering – and has become a valuable technique in applications ranging from photoionization and electron-loss rate measurements to trace species detection, gaseous mixture and reaction characterization, molecular spectroscopy, and standoff measurement of local vector magnetic fields in gases through magnetically-induced depolarization. Notable advantages of the technique include a high sensitivity, good temporal resolution, low shot noise, non-intrusive probing, species-selectivity when coupled with resonance-enhanced multiphoton ionization (REMPI), single-shot acquisition, and the capability of time gating due to continuous scanning.</p> <p>Originally, the diagnostic was used for the measurement of electron total populations and number densities in collisional, weakly-ionized, and unmagnetized small plasma objects – so called collisional scattering. However, despite increased interest in recent years, the technique’s applicability to collisionless plasmas has remained relatively unexplored. This dissertation intends to expand upon the theoretical, mathematical, and experimental basis for CMS and demonstrate the constructive Thomson & Rayleigh scattering regimes for the first time. Furthermore, this work seeks to explore other novel and relevant capabilities of CMS including electron momentum-transfer collision frequency measurements via scattered phase information and spatially-resolved electron number characterizations of elongated plasma filament structures.</p> <p>This dissertation additionally leverages the technique to diagnose microplasmas and situations of particular interest. Primarily, photoionization (PI) – including UV resonance-enhanced multiphoton ionization, non-resonant visible PI, and mid-IR tunneling ionization in gaseous media. Such processes bear importance to studies on nonequilibrium plasmas, soft ionization in mass spectrometry, the development of compact particle accelerators, X-ray and deep UV radiation sources, laser-assisted combustion, laser-induced breakdown spectroscopy, species detection, mixture characterization and spectroscopy, studies on nonlinear beam propagation (filamentation, self-trapping and pulse splitting, dispersion, modulation instabilities), and so on. Finally, the application of CMS to ion thrusters is demonstrated.</p> Lasers and quantum electronics Coherent Microwave Scattering Plasma Diagnostics Photoionization Laser Induced Plasmas Microwave Scattering Multiphoton Ionization Tunneling Ionization Laser Filamentation Ultrafast Optics Nonlinear Optics
92	Applications of micro-3D printing to microfluidic cell dosing Robinson, Michael Mayes 16 September 2014 (has links) Cellular growth, development, differentiation, and death are mediated to some degree by the interaction of soluble factors with plasma membrane receptors. Traditionally the cellular response to chemical cues has been studied by exposing entire culture dishes to a desired reagent. While the addition of soluble reagents homogenously to cell culture dishes provides a basis for understanding much of cell biology, greater spatial resolution of reagent delivery is necessary in order to elucidate mechanisms on the subcellular scale. This dissertation explores techniques that may improve the quality and precision of delivering soluble factors to cultured cells in order to better understand the complex processes of cell biology. These advancements were made possible by applying high intensity, focused laser light to soluble materials to achieve microscopic three-dimensional (µ-3D) printing. In combination with a previously developed microfluidic cell dosing platform, microstructures were designed and µ-3D printed to hydrodynamically focus reagent streams for cell dosing. Structures were also µ-3D printed within micrometers of living cells from a solution of gelatin and bovine serum albumin with minimal cytotoxicity. When µ-3D printed, these proteins displayed both temperature and pH-responsive properties. In order to allow for on-the-fly control of reagent stream size and temporal pulse width, microstructures were µ-3D printed from temperature-responsive N- isoproplyacrylamide. To further improve the temporal resolution of the system, a technique for cycling between reagents with millisecond exchange times using laminar flow microfluidics was developed. The utility of these techniques was demonstrated by staining rat Schwann cells and mouse neuroblastoma rat glioma hybrid cells (NG108-15) with focused streams of fluorescent dyes. These advancements may allow future experiments to determine the placement of soluble factors necessary for bacterial quorum sensing or stem cell differentiation. / text 3D printing Microfluidic Multiphoton Hydrodynamic focusing Cell dosing Thermoresponsive N-isoproplyacrylamide Gelatin Schwann cell NG108-15 cell
93	Optical micromanipulation using ultrashort pulsed laser sources Little, Helen January 2007 (has links) In this thesis two previously separate fields of study are brought together: optical micromanipulation and ultrashort laser research. Here, the benefits of combining the high peak powers of ultrashort pulsed lasers and conventional optical micromanipulation techniques are explored. As optical trapping has been studied extensively, the focus of this research is on optical guiding. Moreover, the emphasis is on the use of Bessel beams as these have been shown to offer greater guiding distances than comparable Gaussian beams. The studies within this thesis show that optical guiding in Bessel and Gaussian beams is governed by the average power of the laser. However, the benefits of guiding with ultrashort pulsed lasers to exploit multi-photon processes become evident as the demonstration of simultaneous optical guiding and second harmonic generation in microscopic nonlinear crystal fragments is detailed. This work is developed by using ultrashort pulses to induce two-photon excitation-induced fluorescence in the guiding medium. This allows direct visualisation of the beam-particle interaction and measurement of the reconstruction of the Bessel beam around an object. Some studies using two-photon excitation to investigate Bessel beam penetration through turbid media are discussed. Finally, the work is concluded by exploring the use of pulsed white-light lasers in optical guiding. The wavelength-dependent propagation and reconstruction properties of the white-light Bessel beam are studied before some preliminary optical guiding experiments are discussed. From this, the broad bandwidth of the supercontinuum source is found to offer extended guiding distances in Gaussian beams thereby negating the need for Bessel beams. 535
94	Nanoscale engineering of semiconductor heterostructures for quadratic nonlinear optics and multiphoton imaging / Ingénierie à l’échelle nanométrique d’hétérostructures à base de semiconducteurs pour l’optique non-linéaire quadratique et l’imagerie multiphotonique Zieliński, Marcin 09 February 2011 (has links) Les phénomènes de diffusion cohérente non-linéaire ont été récemment proposés en alternatives à la fluorescence comme processus de marquage en microscopie multiphotonique. Les matériaux couramment appliqués dans ce contexte buttent toutefois sur une limite inférieure en taille déterminée par le seuil de détection de signaux faibles en optique non-linéaire. Aucun des efforts récents en détection en génération de second-harmonique (GSH), qui est le processus non-linéaire d’ordre le plus bas, n’a permis de descendre à ce jour au-dessous d’une barrière en taille de 40nm même en ayant recours aux techniques de détection les plus sensibles telles que le comptage de photons uniques. Les nanoparticules (NPs) restent ainsi dans la famille des nano-diffuseurs de “grande“ taille. Il apparaît toutefois possible de déplacer de façon significative cette limite inférieure vers les plus petites tailles en substituant aux isolants diélectriques ou aux semi-conducteurs à grands gaps des particules quantiques (PQs) à base de semi-conducteurs à gaps directs.Dans ce travail, un nouveau type de nanosondes hautement non-linéaires a été conçu et développé de façon à franchir cette barrière de taille minimale pour atteindre l’échelle de nanoparticules uniques. Nous considérons ainsi l’excitation résonnante à deux photons de nanoparticules quantiques individuelles à base de CdTe (de la famille des “zinc-blendes”) d’un diamètre d’environ 12.5nm, qui fournissent une émission cohérente efficace par GSH jusqu’à hauteur de 105 comptages de photons par seconde. Elles présentent de plus l’avantage d’une remarquable sensibilité à l’orientation de leur réseau cristallin octupolaire.De plus, il a été démontré que les effets de confinement quantique déterminent fortement les caractéristiques de la susceptibilité non-linéaire du second-ordre χ(2). La caractérisation quantitative du χ(2) des PQs, en particulier leur dispersion spectrale et leur dépendance en taille est menée par spectroscopie de particules uniques ainsi qu’en moyenne d’ensemble par diffusion Hyper-Rayleigh (HRS). Nous fournissons en particulier la preuve que sous certaines conditions, le χ(2) de structures à base de semi-conducteurs en mode de confinement quantique peut très largement dépasser sa valeur en milieu massif. De plus, un nouveau type de PQs hybridant des semi-conducteurs en géométries de type “bâtonnet sur sphère” (BS) a été développé sur la base de composantes cristallines de symétries différentes, afin d’augmenter leur non-linéarité quadratique effective, tout en maintenant leur taille dans un régime proche d’un fort confinement quantique. Le nouveau tenseur hybride complexe χ(2) est analysé en terme d’interférence des susceptibilités constitutives, en prenant en compte les différentes formes et symétries associées aux composantes octupolaires et dipolaires.Il en résulte pour de telles structures une exaltation significative du χ(2), qui excède celle des PQs à constituant unique compte tenu du couplage entre matériaux non-linéaires et d’un temps de décohérence plus long, que nous attribuons à un effet de separation de charge photo-induit. / Nonlinear coherent scattering phenomena from single nanoparticles have been recently proposed as alternative processes for fluorescence in multiphoton microscopy staining. Commonly applied nanoscale materials, however, have reached a certain limit in size dependent detection efficiency of weak nonlinear optical signals. None of the recent efforts in detection of second-harmonic generation (SHG), the lowest order nonlinear process, have been able to cross a ~40 nm size barrier for nanoparticles (NPs), thus remaining at the level of “large” nanoscatterers, even when resorting to the most sensitive detection techniques such as single-photon counting technology. As we realize now, this size limitation can be significantly lowered when replacing dielectric insulators or wide gap semiconductors by direct-gap semiconducting quantum dots (QDs). Herein, a new type of highly nonlinear nanoprobes is engineered in order to surpass above mentioned size barrier at the single nanoparticle scale. We consider two-photon resonant excitation in individual zinc-blende CdTe QDs of about 12.5 nm diameter, which provide efficient coherent SHG radiation, as high as 105 Hz, furthermore exhibiting remarkable sensitivity to spatial orientation of their octupolar crystalline lattice. Moreover, quantum confinement effects have been found to strongly contribute to the second-order nonlinear optical susceptibility χ(2) features. Quantitative characterization of the χ(2) of QDs by way of their spectral dispersion and size dependence is therefore undertaken by single particle spectroscopy and ensemble Hyper-Rayleigh Scattering (HRS) studies. We prove that under appropriate conditions, χ(2) of quantum confined semiconducting structures can significantly exceed that of bulk. Furthermore, a novel type of semiconducting hybrid rod-on-dot (RD) QDs is developed by building up on crystalline moieties of different symmetries, in order to increase their effective quadratic nonlinearity while maintaining their size close to a strong quantum confinement regime. The new complex hybrid χ(2) tensor is analyzed by interfering the susceptibilities from each component, considering different shape and point group symmetries associated to octupolar and dipolar crystalline structures. Significant SHG enhancement is consequently observed, exceeding that of mono-compound QDs, due to a coupling between two nonlinear materials and slower decoherence, which we attribute to the induced spatial charge separation upon photoexcitation. Génération de second harmonique Multiphoton microscopy Second-harmonic generation Nonlinear polarimetry Semiconducting quantum dots Quantum confinement Hybrid heterostructures
95	Three-photon imaging of ovarian cancer Barton, Jennifer K., Amirsolaimani, Babak, Rice, Photini, Hatch, Kenneth, Kieu, Khanh 29 February 2016 (has links) Optical imaging methods have the potential to detect ovarian cancer at an early, curable stage. Optical imaging has the disadvantage that high resolution techniques require access to the tissue of interest, but miniature endoscopes that traverse the natural orifice of the reproductive tract, or access the ovaries and fallopian tubes through a small incision in the vagina wall, can provide a minimally-invasive solution. We have imaged both rodent and human ovaries and fallopian tubes with a variety of endoscope-compatible modalities. The recent development of fiber-coupled femtosecond lasers will enable endoscopic multiphoton microscopy (MPM). We demonstrated two-and three-photon excited fluorescence (2PEF, 3PEF), and second-and third-harmonic generation microscopy (SHG, THG) in human ovarian and fallopian tube tissue. A study was undertaken to understand the mechanisms of contrast in these images. Six patients (normal, cystadenoma, and ovarian adenocarcinoma) provided ovarian and fallopian tube biopsies. The tissue was imaged with three-dimensional optical coherence tomography, multiphoton microscopy, and frozen for histological sectioning. Tissue sections were stained with hematoxylin and eosin, Masson's trichrome, and Sudan black. Approximately 1 mu m resolution images were obtained with an excitation source at 1550 nm. 2PEF signal was absent. SHG signal was mainly from collagen. 3PEF and THG signal came from a variety of sources, including a strong signal from fatty connective tissue and red blood cells. Adenocarcinoma was characterized by loss of SHG signal, whereas cystic abnormalities showed strong SHG. There was limited overlap of two-and three-photon signals, suggesting that three-photon imaging can provide additional information for early diagnosis of ovarian cancer. cancer fallopian tube multiphoton imaging ovary second harmonic generation three-photon excited fluorescence third harmonic generation two-photon excited fluorescence
96	Produção de nanopartículas de Au induzida por pulsos laser de femtossegundos formatados / Gold nanoparticles production induced by shaped femtosecond laser pulses Ferreira, Paulo Henrique Dias 27 October 2011 (has links) Neste trabalho investigamos a dinâmica de formação de nanopartículas de Au por pulsos de femtossegundos formatados (800 nm, 30 fs, 1 kHz e 2 mJ), induzida pela ionização da molécula de quitosana. Inicialmente desenvolvemos um sistema de formatação de pulsos ultracurtos que faz uso de um modulador espacial de luz, constituído por um arranjo linear de cristais líquidos, com o qual somos capazes de impor distintas modulações de fase ao pulso laser. Para monitorar o processo de produção de nanopartículas, montamos um sistema de excitação (pulsos de femtossegundos) e prova (luz branca), o qual permite a observação em tempo real do aparecimento da banda de plásmon e, consequentemente, da dinâmica de formação das nanopartículas. Resultados obtidos para pulsos não formatados (limitados por Transformada de Fourier) demonstraram que a formação de nanopartículas deve-se à ionização não linear da quitosana, a qual está relacionada à oxidação do grupo hidroxila para o grupo carbonila. Medidas de microscopia eletrônica de transmissão forneceram os tamanhos (entre 20 e 100 nm) e formatos (esferas, pirâmides, hexágonos, bastões, etc) das nanopartículas geradas. Ainda, nossos resultados revelaram que esta ionização é iniciada por absorção multifotônica, mais especificamente por absorção de 4 fótons. Utilizando pulsos formatados com fase espectrais constante, degrau e cossenoidal com diferentes frequências, investigamos a influência destes na formação de nanopartículas. Concluímos que os pulsos mais longos são mais favoráveis ao processo de ionização, e consequente redução dos íons de Au para a formação de nanopartículas metálicas. Este comportamento se deve, provavelmente, à redistribuição da energia absorvida para os modos vibracionais, o que é mais provável para pulsos mais longos. Assim, o método apresentado pode abrir novas maneiras para a formação de nanopartículas de metálicas, as quais podem ser mais exploradas dos pontos de vista aplicado e fundamental. / In this work we have studied the synthesis of Au nanoparticles using shaped ultrashort pulses (800 nm, 30 fs, 1 kHz and 2 mJ), induced by the ionization of the chitosan. Initially we developed a pulse shaping setup that uses a spatial light modulator (liquid crystals array), with which we are able to impose distinct phase mask to the laser pulse. In order to monitor the nanoparticles production process, we used a pump-probe system, consisting of femtosecond pulses (pump) and white light (probe), which allows the observation of the plasmon band enhancement and hence the nanoparticles formation dynamics. The results obtained by Fourier Transform limited pulses have shown that the nanoparticles formation is due to the nonlinear ionization of chitosan, which is related to hydroxyl group oxidation to the carbonyl group. Transmission electron microscopy measurements provided the sizes (20-100 nm) and shapes (spheres, pyramids, hexagons, rods, etc.) of the produced nanoparticles. Moreover, our results revealed that ionization is initiated by multiphoton absorption, more specifically by four photons absorption. Using pulses shaped with constant, step and cossenoidal (with different frequencies) spectral phase masks, we investigated their influence in the nanoparticles formation. We conclude that longer pulses are more favorable to the ionization process and, consequently, to the gold ions reduction for the synthesis of the metallic nanoparticles. This behavior is probably due to the redistribution of the absorbed energy to the vibrational modes, which is more likely for longer pulses. Therefore, the approach presented here can open new ways to produce metallic nanoparticles, which can be further explored from applied and fundamental points of view. Amplified ultrashort pulses Femtosecond pulse shaping Formatação de pulsos de femtossegundos Gold nanoparticles Ionização multifotônica Multiphoton ionization Nanopartículas de ouro Pulsos ultracurtos amplificados
97	Relação entre a estrutura molecular e as propriedades de absorção de multi-fótons em compostos orgânicos π-conjugados / Structure-property relationship for multiphoton absorption process in π-conjugated organic compounds Vivas, Marcelo Gonçalves 27 July 2011 (has links) Nesta tese estudamos a relação entre as propriedades de absorção de multi-fótons e a estrutura molecular de três classes distintas de compostos orgânicos π-conjugados: derivados de vitamina A, complexos de platina acetilada e compostos quirais. Materiais orgânicos emergiram nas últimas décadas como candidatos para aplicações em dispositivos fotônicos, principalmente aqueles envolvendo processos de absorção multifotônica, uma vez que suas propriedades podem ser facilmente otimizadas através de engenharia molecular. Devido às diferenças inerentes entre as estruturas químicas dos compostos aqui investigados, foi possível verificar individualmente a influência do comprimento de conjugação, da presença de grupos doadores e aceitadores de elétrons (estruturas push-pull), da planaridade molecular e de efeitos de comprimento de ligação sobre a seção de choque de absorção multifotônica. Para tanto, foram utilizadas as técnicas de Varredura-Z convencional e com contínuo de luz branca, espectroscopia de fluorescência por absorção de multi-fótons e fluorescência resolvida no tempo. Para correlacionar as propriedades moleculares com os espectros não-lineares, foram utilizados cálculos de química quântica em conjunto com o modelo de soma de estados essenciais. Através desse modelo foi possível associar aspectos puramente moleculares, como o momento de dipolo de transição, o momento de dipolo estático, a força do oscilador e a largura de linha dos estados eletrônicos com a estrutura molecular dos cromóforos, visando futuras aplicações tecnológicas. Resultados de espectroscopia de absorção de dois fótons revelaram que os derivados da vitamina A, como o trans-β-apo-8-carotenal e all-trans β-caroteno, possuem magnitudes da seção de choque extremamente elevadas (~5000 GM), indicando-os como materiais promissores para armazenamento óptico 3D. Os complexos de platina acetilada apresentaram características impares para aplicações em dispositivos de limitação de potência óptica baseados em processos de absorção de dois e três fótons como, elevadas absortividades não-lineares, boa transparência óptica, baixo limiar de limitação, alto intervalo dinâmico e rápido tempo de resposta. Por fim, os compostos quirais abriram possibilidades de explorar novos efeitos em óptica não-linear como, por exemplo, efeito de dipolo magnético e quadrupolo elétrico, apenas modificando o estado de polarização da luz. / In this thesis we studied the relationship between the multi-photon absorption properties and the molecular structure of three distinct classes of π-conjugated organic compounds: derivatives of vitamin A, platinum acetylide complexes and chiral compounds. Organic materials have emerged as potential candidates for applications involving multiphoton absorption, since their properties can be changed through molecular engineering. Because of the inherent differences between the molecular structures of the compounds investigated here, it was possible to verify the influence of conjugation length, electron donor and acceptors groups (push-pull structures), molecular planarity and effects of bond length alternation on the multi-photon absorption cross-section. To investigate such properties, we have employed the conventional and white-light continuum femtosecond Z-scan technique and multi-photon and time-resolved fluorescence spectroscopy. We have also employed quantum chemical calculation and the essential sum-over-states approach to correlate the impact of molecular properties on the nonlinear spectra. It was possible to link pure molecular features such as transition dipole moment, static dipole moment, oscillator strength and states linewidth with the chromophores structures, aiming at future applications. The two-photon absorption spectroscopy results revealed that the derivatives of vitamin A, such as trans-β-apo-8-carotenal and all-trans β-carotene, present cross-sections values extremely high (~ 5000 GM), indicating them as promising materials for 3D optical storage. The platinum acetylide complexes can be applied in optical power limiting devices based on the two- and three-photon absorption process, since they present unique features, such as high nonlinearity, good optical transparency, low threshold limit, high dynamic range and fast response time. Finally, the chiral compounds opened up new possibilities to be explored in nonlinear optics, such as the effect of magnetic dipole and electric quadrupole, only manipulating the polarization state of the light. Absorção de multi-fótons Espectroscopia não-linear Materiais orgânicos Multiphoton absorption Nonlinear spectroscopy Organic materials Técnica de varredura-Z Z-scan technique
98	Relação entre a estrutura molecular e as propriedades de absorção de multi-fótons em compostos orgânicos π-conjugados / Structure-property relationship for multiphoton absorption process in π-conjugated organic compounds Marcelo Gonçalves Vivas 27 July 2011 (has links) Nesta tese estudamos a relação entre as propriedades de absorção de multi-fótons e a estrutura molecular de três classes distintas de compostos orgânicos π-conjugados: derivados de vitamina A, complexos de platina acetilada e compostos quirais. Materiais orgânicos emergiram nas últimas décadas como candidatos para aplicações em dispositivos fotônicos, principalmente aqueles envolvendo processos de absorção multifotônica, uma vez que suas propriedades podem ser facilmente otimizadas através de engenharia molecular. Devido às diferenças inerentes entre as estruturas químicas dos compostos aqui investigados, foi possível verificar individualmente a influência do comprimento de conjugação, da presença de grupos doadores e aceitadores de elétrons (estruturas push-pull), da planaridade molecular e de efeitos de comprimento de ligação sobre a seção de choque de absorção multifotônica. Para tanto, foram utilizadas as técnicas de Varredura-Z convencional e com contínuo de luz branca, espectroscopia de fluorescência por absorção de multi-fótons e fluorescência resolvida no tempo. Para correlacionar as propriedades moleculares com os espectros não-lineares, foram utilizados cálculos de química quântica em conjunto com o modelo de soma de estados essenciais. Através desse modelo foi possível associar aspectos puramente moleculares, como o momento de dipolo de transição, o momento de dipolo estático, a força do oscilador e a largura de linha dos estados eletrônicos com a estrutura molecular dos cromóforos, visando futuras aplicações tecnológicas. Resultados de espectroscopia de absorção de dois fótons revelaram que os derivados da vitamina A, como o trans-β-apo-8-carotenal e all-trans β-caroteno, possuem magnitudes da seção de choque extremamente elevadas (~5000 GM), indicando-os como materiais promissores para armazenamento óptico 3D. Os complexos de platina acetilada apresentaram características impares para aplicações em dispositivos de limitação de potência óptica baseados em processos de absorção de dois e três fótons como, elevadas absortividades não-lineares, boa transparência óptica, baixo limiar de limitação, alto intervalo dinâmico e rápido tempo de resposta. Por fim, os compostos quirais abriram possibilidades de explorar novos efeitos em óptica não-linear como, por exemplo, efeito de dipolo magnético e quadrupolo elétrico, apenas modificando o estado de polarização da luz. / In this thesis we studied the relationship between the multi-photon absorption properties and the molecular structure of three distinct classes of π-conjugated organic compounds: derivatives of vitamin A, platinum acetylide complexes and chiral compounds. Organic materials have emerged as potential candidates for applications involving multiphoton absorption, since their properties can be changed through molecular engineering. Because of the inherent differences between the molecular structures of the compounds investigated here, it was possible to verify the influence of conjugation length, electron donor and acceptors groups (push-pull structures), molecular planarity and effects of bond length alternation on the multi-photon absorption cross-section. To investigate such properties, we have employed the conventional and white-light continuum femtosecond Z-scan technique and multi-photon and time-resolved fluorescence spectroscopy. We have also employed quantum chemical calculation and the essential sum-over-states approach to correlate the impact of molecular properties on the nonlinear spectra. It was possible to link pure molecular features such as transition dipole moment, static dipole moment, oscillator strength and states linewidth with the chromophores structures, aiming at future applications. The two-photon absorption spectroscopy results revealed that the derivatives of vitamin A, such as trans-β-apo-8-carotenal and all-trans β-carotene, present cross-sections values extremely high (~ 5000 GM), indicating them as promising materials for 3D optical storage. The platinum acetylide complexes can be applied in optical power limiting devices based on the two- and three-photon absorption process, since they present unique features, such as high nonlinearity, good optical transparency, low threshold limit, high dynamic range and fast response time. Finally, the chiral compounds opened up new possibilities to be explored in nonlinear optics, such as the effect of magnetic dipole and electric quadrupole, only manipulating the polarization state of the light. Absorção de multi-fótons Espectroscopia não-linear Materiais orgânicos Técnica de varredura-Z Multiphoton absorption Nonlinear spectroscopy Organic materials Z-scan technique
99	Desenvolvimento e validação da espectroscopia vibracional de íons em fase gasosa / Development and validation of gas-phase ion spectroscopy Cervi, Gustavo 07 June 2019 (has links) Este trabalho conta com um apanhado geral da técnica de espectrometria de massas acoplada a espectroscopia vibracional de íons, suas aplicações, limitações, desenvolvimento e embasamento teórico. Para tal é apresentado um resumo da teoria quântica aplicada à espectroscopia vibracional, natureza da luz, eletromagnetismo e ótica de sistemas de OPO/OPA, laser de gás e de estado sólido. A seção experimental é dividida em duas. A primeira apresenta o acoplamento físico do espectrômetro de massas às fontes de radiação laser, juntamente com os softwares para permitir comunicação entre esses módulos. Na segunda parte, são apresentados espectros IRMPD de amostras padrão para comparação e validação com a literatura bem como espectros inéditos para exemplificar o uso da técnica de espectroscopia de íons em sistemas de interesse biológico, como as bases nitrogenadas do DNA. / This master thesis presents a general overview of the mass spectrometry technique coupled to vibrational ion spectroscopy, its applications, limitations, development and theoretical basis. For that, a summary of the quantum theory applied to vibrational spectroscopy, the nature of light, electromagnetism and optics of OPO/OPA, gas discharge and solid-state laser systems is shown. The experimental section is divided in two, the first presents the physical coupling of the mass spectrometer to the laser sources, along with softwares which allows the communication between these modules. In the second part, some IRMPD spectra of standard samples are presented for comparison and validation with the literature as well as unpublished spectra to exemplify the use of the ion spectroscopy technique in systems of biological interest, such as the DNA bases. Espectrometria de massas Espectroscopia de íons Espectroscopia vibracional Infrared multiphoton dissociation Ion spectroscopy IRMPD Mass spectrometry Vibrational spectroscopy
100	Paquets d'onde vibrationnels créés par ionisation de H2 en champ laser intense Fabre, Baptiste 09 December 2005 (has links) Les dernières évolutions technologiques en matière de laser ont permis l'observation de nouveaux phénomènes hautement non-linéaires lors de l'interaction de ces sources brèves et intenses avec la matière. Du point de vue moléculaire, ces processus, tels que l'affaiblissement de la liaison ou la génération d'harmonique, sont consécutifs à la création au sein de l'ion d'un paquet d'onde vibrationnel après ionisation par effet tunnel de la molécule neutre. Il est généralement admis dans nombre d'articles que cette transition électronique conduit à une distribution des états de vibration conforme à celle prédite par l'approximation de Condon. Afin de vérifier la validité de cette assertion, nous avons mis en place un dispositif expérimental original permettant une mesure fiable de l'excitation vibrationnelle de H2+ après ionisation de la molécule neutre par un champ laser intense. Les résultats obtenus contredisent fortement le postulat selon lequel la transition aurait lieu préférentiellement à la séparation internucléaire d'équilibre (approximation de Condon) et remettent en cause les interprétations des expériences de dynamique moléculaire précédentes. En faisant varier la longueur d'onde, nous avons également mis en évidence les processus dominants et l'importance de la structure électronique au sein des différents domaines d'ionisation. Ces mesures ouvrent des perspectives intéressantes quant à la mise en place d'expériences de dynamique moléculaire utilisant un faisceau d'ions moléculaires d'excitation vibrationnelle connue. / The continuing development of femtosecond laser technology allows the study of new, highly non-linear phenomena in laser-molecule interaction. Most scientists agree that the first step of all these processes is the creation of an elctronic wavepacket in the continuum by tunnelling ionisation of the neutral molecule. As a rule, most publications were also unanimous about the vibrational population created in the ion, asumed to be properly described by the classical Condon approximation. Thanks to a unique setup we were able to measure in an unambiguous way the vibrational distribution created by intense-laser-field ionisation. Our study shows a discrepancy between our results and the one predicted by the Condon approximation. Other wavelength-dependent measurements reveal the dominant processes for the different ionisation regimes. These results open new experimental perspectives for the study of the molecular dynamics. Multiphotonique Multiphoton Tunnel ionisation Strong field Hydrogen Vibrational distribution Distribution vibrationnelle ADK Franck-Condon Fentosecond laser Laser femtoseconde

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