Dissertations / Theses on the topic 'Nonlinear optical microscopies'
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Allcock, Philip. "A microscopic quantum electrodynamical theory of novel nonlinear optical processes." Thesis, University of East Anglia, 1996. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.338097.
Full textBart, Graeme. "Bridging the Microscopic and Macroscopic Realms of Laser Driven Plasma Dynamics." Thesis, Université d'Ottawa / University of Ottawa, 2018. http://hdl.handle.net/10393/38187.
Full textAu, Ivy Win Long. "The Design and Construction of a Second Harmonic Generation Microscope For Collagen Imaging." Thesis, University of Canterbury. Department of Physics, 2013. http://hdl.handle.net/10092/8537.
Full textLombardini, Alberto. "Nonlinear optical endoscopy with micro-structured photonic crystal fibers." Thesis, Aix-Marseille, 2016. http://www.theses.fr/2016AIXM4377.
Full textIn this thesis, we propose the use of a novel type of photonic crystal fiber, the Kagomé lattice hollow core fiber, for the delivery of ultra-short pulses in nonlinear endoscopy. These fibers allow undistorted pulse delivery, over a broad transmission window, with minimum background signal generated in the fiber, thanks to the propagation in a hollow-core. We solved the problem of spatial resolution, by means of a silica micro-bead inserted in the Kagomé fiber large core. We have developed a miniature imaging system, based on a piezo-electric tube scanner, an achromatic micro-lenses assembly and a specifically designed Kagomé double-clad fiber. With this system we were able to image biological tissues, in endoscope modality, activating different contrasts such as TPEF, SHG and CARS, at the distal end of the fiber, a result which finds no equal in current literature. The integration in a portable probe (4.2 mm in diameter) shows the potential of this system for future in-vivo multimodal endoscopy
Meckbach, Lars [Verfasser], and Stephan W. [Akademischer Betreuer] Koch. "Microscopic theory of the linear and nonlinear optical properties of TMDCs / Lars Meckbach ; Betreuer: Stephan W. Koch." Marburg : Philipps-Universität Marburg, 2020. http://d-nb.info/1216242259/34.
Full textAzzoune, Abderrahim. "Nanofibres optiques pour la réalisation de sources de photons corrélés." Thesis, Université Paris-Saclay (ComUE), 2019. http://www.theses.fr/2019SACLO009.
Full textSources of correlated photon pairs are key components required for quantum telecommunications networks. Implementing these sources directly with optical fibers minimizes the insertion losses. We propose to design such a source from a tapered optical fiber.The tapered fiber has a diameter lower than 500 nm over a length of a few centimeters. The small diameter of the tapered section favors the non-linear effects, while the unstretched sections make it possible to connect this tapered fiber with the fibers of the telecommunication networks with very low losses.In this thesis, we present a design of a new source, fully fibered of correlated photons based on standard telecommunications tapered fibers (SMF28). To produce these pairs of photons we will use the parametric fluorescence due to symmetry breaking at the surface of a silica nanofiber.We have developed an optical microscopy measurement technique to measure all the profile of tapered fibers with nanometer resolution far beyond the diffraction limit.In parallel, we modeled the second-order nonlinear surface susceptibility by taking into account the vector aspect of the propagation of the optical field in a two or three-layered microfiber. In a second step, we define modal phase matchings that are necessary to obtain a strong parametric fluorescence. We size this nanofiber for a good optimization of pairs generation efficiency. The entire process of photon creation will be modeled
Smith, Brett. "Coherent Anti-Stokes Raman Scattering Miniaturized Microscope." Thèse, Université d'Ottawa / University of Ottawa, 2013. http://hdl.handle.net/10393/24281.
Full textNowak, Derek Brant. "The Design of a Novel Tip Enhanced Near-field Scanning Probe Microscope for Ultra-High Resolution Optical Imaging." PDXScholar, 2010. https://pdxscholar.library.pdx.edu/open_access_etds/361.
Full textGomes, Jorge Augusto Coura. "Desenvolvimento de uma microscopia óptica não linear por rotação da polarização elíptica." Universidade de São Paulo, 2016. http://www.teses.usp.br/teses/disponiveis/76/76132/tde-11032016-111456/.
Full textThe use of nonlinear optical processes is one approach used in the optical microscopy, to obtain three-dimensional (3D) images, without destruction, of transparent objects. The acquisition of 3D images is an important resource to allow better visualization of those objects with internal complex structures. Various nonlinear optical processes are used in microscopy; for example, second-harmonic generation, third-harmonic generation, two-photon absorption, fluorescence induced by two-photon absorption, etc. which one with particular characteristics, advantage and disadvantage, etc. An interesting refractive nonlinearity, the nonlinear elliptical polarization rotation (NEPR) which is a Kerr nonlinearity similar to self focusing. Through NEPR, it is possible to determine the absolute magnitude of nonlinearity location, and this feature is possible to develop even never used microscopy. The NEPR signal is not regularly used for microscopy due to its difficult measurement. However, recently a new accurate and simple method of measurement NEPR was developed with use of rotating polarizer and a dual-phase lock-in amplifier. In this way, in this work we propose a proof of concept of one simple microscopy using the NEPR signal. We assembled a optical microscopy based on NEPR measurement using a rotating polarizer, a dual phase lock-in, low cost components, and a femtosecond laser system. We have successfully obtained image of glass capillaries, optical fibers, glass beds and onion cells.
Pratavieira, Sebastião. "Montagem e caracterização de um microscópio óptico não linear para imagens de tecidos biológicos." Universidade de São Paulo, 2014. http://www.teses.usp.br/teses/disponiveis/76/76132/tde-28012015-135658/.
Full textAccurate diagnosis of the morphological and metabolic conditions of a tissue and/or an organ is essential to define the presence of pathological changes, and to evaluate the response during a number of treatments. The use of optical techniques for biological tissue imaging is an excellent alternative for this purpose. Such techniques allow non-invasive diagnostic procedures, with cellular resolution, and usually provide almost instantaneous response. The use of nonlinear optical techniques such as fluorescence promoted by two-photon absorption is one example of optical technique in which we obtain images of living tissue with spatial resolution at cellular level. The purpose of this study is the assembly and characterization of a custom-made non-linear microscope. This microscope allows customized adjustment for in vitro, in vivo and ex vivo imaging of biological samples. The excitation is done using a tunable femtosecond Ti:Sapphire laser. Two galvanometer mirrors conjugated by two spherical mirrors are used for the lateral scan and for the axial scan a piezoeletric stage is utilized. The light is focused in tissue by an 20X objective lens, in water immersion, numerical aperture of 1.0, and working distance of 2.0 mm. The lateral resolution obtained was (0.8 ± 0.1) μm and (4.4 ± 1.5) μm for axial resolution, which is sufficient for images with sub-cellular resolution to be achieved in biological tissues. Fluorescence and second harmonic generation images were performed using epithelial and hepatic tissue. Those images revealed aspects considered relevant in morpho-histopathology – such as nuclear and citoplasm membrane structures, and the presence of collagen. By means of the microscope it is possible to have images in different depths of tissues with sub-cellular resolution. The assembly of such an equipment shall represent a potential contribution to diagnostics and lesion treatment fields, so that it may result in more precise detection of diseases and more effective treatments in the future.
Pelegati, Vitor Bianchin 1982. "Microscopias ópticas de processos coerentes." [s.n.], 2016. http://repositorio.unicamp.br/jspui/handle/REPOSIP/321828.
Full textTese (doutorado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin
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Resumo: Técnicas de microscopias ópticas são as principais ferramentas capazes de observar células e tecidos biológicos em tempo real e com mínimo dano. Essa área foi revolucionada recentemente através das microscopias confocais de varredura a laser e as microscopias de óptica não linear, naturalmente confocais. Entre os processos não lineares temos, a fluorescência excitada por dois ou mais fótons, geração de segundo harmônico [Second Harmonic Generation - SHG] e terceiro harmônico [Third Harmonic Generation - THG]. SHG e THG são técnicas de óptica não linear coerentes, não necessitam de marcadores exógenos e permitem reconstrução de imagens em três dimensões com resolução espacial subcelular. As técnicas de fluorescência permitem visualizar estruturas específicas no espaço, mas não permitem discriminar as substâncias químicas nas estruturas celulares, e as técnicas de SHG e THG não possuem especificidade química. Espectroscopia Raman possui especificidade química através das propriedades vibracionais das moléculas e pode ser usada como mecanismo de contraste na aquisição de imagens. Comparada com a espectroscopia/microscopia infravermelho, a microscopia Raman traz a informação das vibrações moleculares do infravermelho para o visível, eliminando os problemas da baixa resolução espacial e opacidade das amostras. Entretanto a baixa sensibilidade dessa técnica implica em tempos de aquisição de imagens muito longos, da ordem de horas, inviabilizando acompanhar a dinâmica de processos celulares em tempo real. Como solução para essa baixa sensibilidade do espalhamento Raman espontâneo, surgiu a microscopia por espalhamento Raman Coerente anti-Stokes [Coherent Anti-Stokes Raman Scattering - CARS]. Comparado com Raman espontâneo, a microscopia CARS representa aumento de 4 a 5 ordens de grandeza na sensitividade da técnica, diminuindo os tempos de aquisição ao ponto de viabilizar a aquisição em taxas de vídeos (mais rápido do que 30 quadros por segundo) e estudos em tempo real. Essa tese é dedicada ao estudo experimental e teórico, assim como de algumas aplicações, das técnicas de óptica não linear, com destaque para processos de óptica não linear coerentes. Apresentamos de forma detalhada três sistemas experimentais para a aquisição de imagens de Raman coerente e um sistema integrado com várias técnicas de óptica não linear. Mostramos as primeiras imagens de CARS realizadas no Brasil. Além do CARS convencional, trabalhamos com outra técnica de CARS de ordem mais alta, o CARS cascata [cascade CARS - CCARS], e, no melhor do nosso conhecimento, apresentamos as primeiras imagens internacionais obtidas com essa metodologia. CCARS aumenta o contraste da técnica CARS, diminuindo o fundo não ressonante, um problema que aflige a comunidade científica dedicada ao uso dessa técnica. Além da diminuição do fundo não ressonante, a emissão do CCARS acontece em um comprimento de onda diferente de qualquer outro efeito não linear coerente, significando um acréscimo de complexidade mínimo para sua detecção quando comparado com o CARS. Por último mostramos algumas aplicações realizadas com o sistema experimental desenvolvido para integrar diversas modalidades ópticas em paralelo, especialmente da geração de harmônicos com a fluorescência excitada por dois fótons e suas variantes, como microscopia de tempo de vida de fluorescência (Fluorescence Lifetime Imaging ¿ FLIM)
Abstract: Optical microscopies techniques are the main tools capable of observing cell and biological tissues in real time and with minimum damage. This area have recently been revolutionized by confocal laser scanning microscopies and non-linear microscopies, naturally confocal. Among the non-linear process we have, the two or more photons excited fluorescence, second harmonic generation [SHG] and third harmonic generation [THG]. SHG and THG are coherent nonlinear techniques, they do not require exogenous markers and allow three dimension imaging reconstruction with subcellular resolution. The fluorescence techniques allow visualizing specific structures in space, but do not allow discriminating the chemical substances in cellular structures, SHG and THG techniques do not have chemical specificity. Raman spectroscopy has chemical specificity through the vibrational properties of the molecules and can be used as a contrast mechanism for imaging acquisition. Compared to infrared spectroscopy/microscopy, Raman microscopy brings information about molecular vibration from infrared to visible, eliminating the low resolution and sample opacity problems. However, this technique low sensibility implies in very long imaging acquisition times, order of hours, making it not viable for following cellular process dynamics in real time. As an answer for the spontaneous Raman scattering low sensibility, the coherent anti-Stokes Raman scattering [CARS] emerged. Compared to spontaneous Raman, CARS microscopy presents an increase of 4 to 5 orders of magnitude in the sensitivity of the technique, lowering the acquisition times to the point of making video acquisition (faster than 30 frames per second) and real time studies possible. This thesis is dedicated to the experimental and theoretical study, as well as some applications, of the non-linear techniques, with emphasis on coherent non-linear optical processes. We present in detailed form three experimental systems for the acquisition of coherent Raman images, and a system with the integration of various non-linear techniques. We show the first CARS images acquired in Brazil. In addition to conventional CARS, we worked with other higher order CARS technique, the cascade CARS [CCARS], and, in the best of our knowledge, we present the first international image acquired with this methodology. CCARS increases the contrast from CARS technique, decreasing the non-resonant background, a problem that afflicts the scientific community dedicated to the use of this technique. Besides the decrease of the non-resonant background, the CCARS emission occurs in a different wavelength from any other non-linear coherent effect, meaning a minimum complexity increase for its detection when compared with CARS. Finally we show some applications performed with the experimental system developed to integrate several optical modalities in parallel, especially the generation of harmonics with two photons excitation fluorescence and their variants such as Fluorescence Lifetime Imaging [FLIM]
Doutorado
Física
Doutor em Ciências
830406/2010
CAPES
Saint-Jalm, Sarah. "Sources optiques fibrées solitoniques pour la spectroscopie et la microscopie non linéaires." Thesis, Aix-Marseille, 2014. http://www.theses.fr/2014AIXM4353/document.
Full textOne of the issues that has to be overcome to realize a nonlinear endoscope for biomedical applications is the propagation of ultra-short pulses in an optical fiber. Nonlinear processes require high peak powers in the focal volume in order to generate observable signals, so the pulses should be as short as possible. This makes them sensitive to the dispersion and nonlinearities of the fibers. Most of the existing techniques of ultra-short pulses fiber-delivery rely on complex pre-compensation systems to counteract these effects. In this work, we explore the possibilities offered by the generation of high-energy solitons in a custom-built solid-core photonic bandgap fiber, for nonlinear microscopy and spectroscopy. Optical solitons preserve their shape when they propagate in a fiber, and their duration remains close to the minimum value physically allowed by their bandwidth, without the need of any pre-compensation. Moreover, the wavelength and delay of the soliton can be tuned by changing the power at the input of the fiber. Several soliton-based light sources were designed and realized, generating contrast in the most prevalent nonlinear microscopy modalities. TPEF and SHG images of biological samples were first realized by taking advantage of the short duration of the solitons. By controlling the delay of the soliton, transient absorption measurements were then realized in a pump-probe configuration. Finally, the wavelength tunability of the soliton was used to generate the Stokes beam in a CRS setup based on the spectral focusing technique. The capabilities of this scheme were demonstrated by performing CRS microspectroscopy to monitor a chemical equilibrium
Neradovskiy, Maxim. "Guides d’ondes dans un cristal de niobate de lithium périodiquement polarisé : fabrication et étude par des techniques de microscopie à sonde locale." Thesis, Nice, 2016. http://www.theses.fr/2016NICE4035/document.
Full textThe investigation of influence of the soft proton exchange (SPE) optical waveguide (WG) creation onperiodically poled lithium niobate (PPLN) has been done. It has been shown that the WG fabricationprocess can induce the formation of needle like nanodomains, which can be responsible for thedegradation of the nonlinear response of the WG created in PPLN crystals. The domain structure (DS)evolution has been studied in congruent lithium niobate (LN) crystals with surface layers modified bythree different proton exchange techniques. The significant decrease of the nucleation threshold fieldand qualitative change of domain rays nucleation and growth have been revealed. The formation of abroad domain boundary and dendrite domain structure as a result of nanodomains merging in front ofthe moving rays has been demonstrated. The formation of DS in LN with SPE by irradiation of coveredby electron resist polar surface of LN has been investigated. Formation of domains with arbitrary shapesas a result of discrete switching has been revealed. Finally, it has been demonstrated that electron beamirradiation of lithium niobate crystals with surface resist layer can produce high quality periodical domainpatterns after channel waveguide fabrication. Nonlinear characterizations show that the conversionefficiencies and the phase matching spectra conform to theoretical predictions, indicating that thiscombination presents a great interest for device fabrication. Second harmonic generation withnormalized nonlinear conversion efficiency up to 48%/(W cm2) has been achieved in such waveguides
Trinh, Duc Thien. "Linear electrooptic microscopy : applications to micro and nano-structured materials." Thesis, Cachan, Ecole normale supérieure, 2015. http://www.theses.fr/2015DENS0012/document.
Full textComplementing Second-Harmonic Generation (SHG) microscopy, a new home-made nonlinear microscope named Pockels Linear Electro-Optical Microscopy (PLEOM) based on the linear electrooptic (Pockels) effect, has been developed and used to map the second-order susceptibility Chi(2) of non-centrosymmetric materials with high sensitivity due to a stabilized interferometric homodyne detection scheme [1, 2]. This enables PLEOM to detect the electrooptic phase retardation of light resulting from the variation of the refractive index of nonlinear materials down to 10-6 radian and to investigate nonlinear materials at the nano-scale [3] towards applications in imaging of biological samples and tracking of labels therein. With PLEOM, a new imaging method allows to access, besides the aplitude, the no less crucial phase response, which is not readily amenable to classical SHG microscopy. In the frame of this dissertation, we have further extended the range of applications of PLEOM to investigate nonlinear materials and structures from nano- to millimeter-scale.Firstly, we have proposed and demonstrated a new approach towards the full vector determination of the spontaneous polarization of single ferroelectric nano-crystals used as SHG nano-probes. This method allows to remove the ambiguity inherent to earlier polarization-resolved SHG microscopy experiments, and has permitted full determination of the orientation of single domain ferroelectric nano-crystals. The electrooptic phase response obtained in the form of phase images and polarization diagrams yields the full orientation in the laboratory frame of randomly dispersed single nano-crystals, together with their electric polarization dipole. The complete vector determination of the dipole orientation is a prerequisite to important applications including ferroelectric nano-domain orientation, membrane potential imaging and rotation dynamics of single biomolecules, especially by using a new low-cost non-invasive imaging method with a low intensity illumination beam.The ferroelectric domain pattern of periodically poled KTiOPO4 and of a two-dimensional decagonal quasi-periodic LiNbO3 nonlinear crystal was determined by local measurement of their electro-optically induced phase retardation. Owing to the sign reversal of the electrooptic coefficients upon domain inversion, a 180 degree (pi) phase shift is observed across domain barriers between domains with opposed orientations. PLEOM allows to reveal the nonlinear and electrooptic spatially modulated patterns in ferroelectric crystals in a non-destructive manner and to determine their poling period, duty cycle and short-range order as well as to detect local defects in the domain structure, such due to incomplete poling.In addition, we have also proposed and demonstrated a new method, based on the voltage dependence of the electrooptic dephasing, to mimic the membrane potential in cells, working at this stage on nonlinear dye containing phospholipidic membranes, grown in a microfluidic set-up
Rendón, Barraza Carolina. "Polarization-resolved nonlinear microscopy in metallic and ferroelectric nanostructures for imaging and control in complex media." Thesis, Aix-Marseille, 2016. http://www.theses.fr/2016AIXM4365.
Full textIn this work, we develop a novel polarized nonlinear microscopy method that exploits sub-diffraction resolution information. Fourier analysis of the polarization modulated nonlinear signal is performed on over-sampled, drift-corrected images (50nm pixel size). The information gained by polarization-induced modulation signals provides a higher level of spatial selectivity that is directly related to the local optical response of the investigated system, at a scale below the diffraction limit. The gain in spatial scale is due to the additional spatial sensitivity brought by polarization. This approach is applied to polarized second harmonic generation imaging in plasmonic nanostructures (150nm size) of multi-branched shapes, in which the vectorial nature of the local field confinement can be retrieved with a resolution of 40 nm. We also demonstrate the possibility to image spatial heterogeneities within crystalline ferroelectric BaTiO3 nanoparticles of 70nm to 500nm size, emphasizing in particular the existence of a centrosymmetric shell in small size structures. These nanostructures will be used as starting models for coherent optical probes in biological media (cells, tissue slices or in vivo) with two objectives. First, the nonlinear nature of their emission will make them stable and tunable nanosources, able to report their localization with high accuracy in 3D, potentially sensing local environment changes, and actively inducing perturbations such as controlled temperature increase at the nanoscale. Second, the coherent nature of their emission will make them useful as local nanoprobes for wavefront and polarization correction through scattering media
Rakotoarimalala, Stephan. "Etude par microscopie non linéaire et modélisaion de la dynamique induite par la lumière des systèmes moléculaires complexes : application aux systèmes moléculaires et aux tissus biologiques." Thesis, Angers, 2017. http://www.theses.fr/2017ANGE0097.
Full textThe spatial symmetry of a material environment strongly influences the mechanism of its interaction with an external electromagnetic field. This is evident in non-linear optics. It is well established the oretically that for crystals the space group is provided with an inversion symmetry - so-called centrosymmetrical crystals -Paired harmonic generation is impossible
Sevrain, David. "Développements en microscopie non linéaire cohérente et incohérente et applications." Phd thesis, Université de Bretagne occidentale - Brest, 2013. http://tel.archives-ouvertes.fr/tel-01061828.
Full textOiticica, Pedro Ramon Almeida. "Microscopia por geração de soma de frequências em interfaces líquidas e sólidas." Universidade de São Paulo, 2015. http://www.teses.usp.br/teses/disponiveis/76/76132/tde-13042015-112958/.
Full textInterface studies are important for the complete understanding of many processes in chemistry, physics and biology. These systems are mainly governed by the interfacial properties of the materials. In the last two decades, the development of new experimental methods improved our understanding of interfacial properties. The advent of a host of laser spectroscopy techniques based on nonlinear optics and the development of the scanning probe microscopy techniques, opened up unimaginable possibilities of studies at surfaces and interfaces. Among these nonlinear spectroscopies we turned our attention to Sum Frequency Generation spectroscopy (SFG spectroscopy). This technique was developed by Shen et al. in 1987 and, since then, it has been applied to many studies of surfaces and interfaces. SFG spectroscopy can provide information about the chemical nature by the vibrational spectra and about the average of molecular ordering in a single monolayer. The SFG signal only can be generated in a noncentrossymetric media, this includes surfaces or interfaces between centrossymetric media, where there is a broken in the inversion symmetry. The combination of SFG spectroscopy with optical microscopy has been proposed as a novel experimental technique to obtain images at interfaces with chemical sensitivity by the vibrational spectra as well as contrast by the ordering and orientation of the molecules. In this work we present the development, construction and characterization of an SFG Microscope (SFGM). This SFGM was specially designed to perform studies on surfaces or interfaces of liquids and solids. Initial SFGM performance tests were performed at the liquid/air interface of the water/acetonitrile (H2O/CH3CN) binary solution. The images of the SFG signal were acquired on the resonance of the methyl group (CH3) of acetonitrile present at the liquid⁄air interface of the binary solution. By varying the molar fraction of acetonitrile in the solution between 4% and 20% we observed the dependency of the SFG signal intensity as a function the acetonitrile bulk mole fraction. We also performed tests in multi-layered Langmuir-Blodgett films of stearic acid (CH3(CH2)16COOH). We obtained the SFG spectromicroscopy in the resonance of CH2 and CH3 groups of the fatty acid. By the differences between the SFG spectra of ordered and disordered regions, the spectromicroscopy revealed microscopic distribution of the conformational ordering in the alkyl chains that composes the film. The sensitivity of the SFG microscope was characterized and it was shown that images could be acquired at the water surface in less than one minute. The optical characterization and the performed tests at the liquid/air and solid/air interfaces demonstrated the full capabilities of the SFGM as a tool for investigations in any liquid or solid interface.
Barbano, Émerson Cristiano. "Third-harmonic generation at interfaces with femtosecond pulses: self-focusing contribution and nonlinear microscopy." Universidade de São Paulo, 2016. http://www.teses.usp.br/teses/disponiveis/76/76131/tde-20012017-154741/.
Full textGeração de terceiro harmônico (GTH) é um processo óptico não linear fundamental que tem sido usado em diferentes aplicações, como em caracterização óptica não linear de materiais e microscopia não linear. Ele é amplamente empregado uma vez que a não linearidade de terceira ordem é a mais importante em materiais isotrópicos e GTH ocorre em todos os meios independente da simetria. Na condição de feixe fortemente focalizado a GTH é observada apenas nas interfaces do material, onde a simetria focal é quebrada devido à presença de dois meios com diferentes índices de refração e/ou susceptibilidades de terceira ordem. Medindo lâminas de diferentes tipos de vidros ópticos, com pulsos de laser de femtossegundos, nós explicamos o perfil assimétrico de intensidade de GTH observado nas interfaces. O harmônico gerado na interface de saída é sistematicamente mais intenso do que o gerado na entrada e este fenômeno pode ser entendido levando-se em conta a presença do efeito de autofocalização. Basicamente, a autofocalização reduz a cintura do feixe na interface de saída do material, resultando em uma maior irradiância e, consequentemente, maior GTH. Este estudo foi estendido para o caso de interfaces de uma cubeta preenchida com diferentes solventes orgânicos. Tais sistemas apresentam quatro interfaces e uma mistura na contribuição dos processos não lineares, dado que as paredes da cubeta apresentam apenas não linearidade eletrônica e os solventes podem apresentar não linearidades tanto eletrônicas quanto orientacionais. Neste sentido, os solventes podem apresentar uma contribuição adicional de autofocalização e, devido à natureza não instantânea do processo orientacional, a autofocalização proveniente do solvente pode ser influenciada pela duração do pulso. Neste caso, a GTH, que é um fenômeno eletrônico (instantâneo), pode ser indiretamente afetada pela duração do pulso por meio do efeito de autofocalização. Usualmente, a contribuição orientacional não é considerada na caracterização de materiais por GTH, o que pode levar à valores incorretos para os coeficientes não lineares, o que significa que nosso estudo é importante do ponto de vista de física fundamental como também em aplicações como caracterização de materiais. Por conta da aplicação da GTH em microscopia não linear, apresentamos também nesta tese uma técnica de microscopia, que baseia-se em uma modulação em frequência espacial para imageamento (SPIFI) com uso de um detector de elemento único. O microscópio foi desenvolvido na Colorado School of Mines (CSM) durante um período de estágio. O sistema utiliza um modulador espacial de luz (SLM) para produzir a modulação em frequência espacial e permite obtenção de imagens em alta resolução. Imagens por GTH SPIFI são mostradas pela primeira vez e também apresentamos imagens obtidas por outros processos ópticos não lineares. Em resumo, os estudos apresentados neste trabalho de doutorado são de grande importância para o entendimento fundamental do processo de GTH, caracterização de materiais e microscopia óptica não linear.
Massin, Julien. "Ingénierie moléculaire pour l'imagerie par microscopie non-linéaire : synthèse et propriétés de nouvelles sondes." Thesis, Lyon, École normale supérieure, 2011. http://www.theses.fr/2011ENSL0701.
Full textThe objective of this thesis is the design of new organic probes for nonlinear optical microscopy by two-photon excited fluorescence (TPEF) and second harmonic generation (SHG). In the first part, we describe the synthesis of probes for voltage sensitive imaging by SHG, bearing one or more sugar units and their spectroscopic characterization. The first biological imaging tests have shown good affinity of the probes to the cell membrane and the SHG signal of neuronal cell was observed over a period of nearly three hours. The second part comprises the synthesis and the study of chromophores with solid state fluorescence properties for use in fluorescent nanoparticles for biological imaging. 18 of the 21 compounds synthesized have been crystallized, their crystal structures determined by X-ray diffraction and their spectroscopic properties studied in solution and in the solid state. These studies showed that the arrangement of molecules relative to each had a great influence on the solid state fluorescence and therefore that the substitution was very important. The chapter ends with the first tests of fluorescent nanoparticles synthesis
Pelegati, Vitor Bianchin 1982. "Microscopias de óptica não linear = fluorescência excitada por absorção de dois fótons, geração de segundo harmônico e geração de terceiro harmônico." [s.n.], 2010. http://repositorio.unicamp.br/jspui/handle/REPOSIP/277504.
Full textDissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin
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Resumo: Biologia celular é um novo mundo promissor com enorme impacto social, econômico e na saúde. Organismos vivos são capazes de, produzir a própria energia a partir da luz do sol, se reproduzir, de se auto-reparar, sinalizar e navegar por sinais bioquímicos, biomecânicos, luminosos, térmicos, e outros, e produzir materiais à temperatura ambiente. As possibilidades abertas por essa área incluem, desde bactérias e protozoários usados para destruir células de câncer, regeneração de órgãos inteiros, produção de etanol a partir de algas, e outros. Entretanto, para o entendimento da biologia em seu nível mais profundo, ferramentas de observação não destrutivas fazem-se necessária para seguir os processos celulares durante seu tempo de vida. A óptica tem a única onda não destrutiva capaz de fornecer informações em tempo real com suficiente resolução espacial de eventos acontecendo internamente à célula. Ademais, porque feixes de luz não colidem, a óptica permite a integração de diferentes técnicas capazes de reunir informações simultâneas de processos celulares. Óptica não linear é especialmente adequada para tal, pois não requer marcação ou processamentos especiais de amostras que poderiam destruir, ou modificar, os processos celulares. Além disso, técnicas elásticas, como a geração de segundo e terceiro harmônicos não liberam energia no material que é, portanto, preservado após a observação. O objetivo dessa tese é desenvolver uma plataforma multimodal para observação de processos biológicos pelo uso de microscopias de fluorescência excitada por absorção de dois fótons, geração de segundo harmônico e geração de terceiro harmônico no mesmo instrumento. Nosso grupo foi pioneiro em demonstrar a aquisição de imagens de geração de segundo harmônico no Brasil e, essa tese é a primeira a realizar a aquisição de imagens por geração de terceiro harmônico. Estas três técnicas juntas fornecem informações complementares a respeito da organização de células e tecidos. Enquanto a fluorescência pode ser específica para algumas proteínas alvo, o segundo harmônico pode observar a rede de colágeno da matriz extra celular e, o terceiro harmônico pode observar os núcleos e gotículas de lipídios internas às células. Esta tese descreve o sistema experimental para realizar essas aquisições multimodais de imagens, a física por trás dos sinais não lineares, importantes para entender seu significado biológico, e mostra aplicações das técnicas para diferentes amostras biológicas e inorgânicas
Abstract: Cell biology is promising a brave new world with enormous social economic and health impacts. Living organisms are capable of producing their own energy from sun light, reproduce, self-repair, signalize and travel in response to biochemical, biomechanical, light and thermal signals among others, and to produce materials at room temperature. The possibilities opened by this area range from bacteria and protozoa used to destroy cancer cells, whole organs regeneration, ethanol produced from algae, and others. However, to actually understand biology at its deepest level no destructive observation tools are necessary to follow cell processes during their time course. Optics is about the only wave capable to provide non destructive real time information with enough spatial resolution of the events happening inside the cells. Moreover, because light beams do not collide, optics allows the integration of different techniques capable to gather simultaneous information during a cell process. Non linear optics is specially suited for that in the sense that it does not require staining or special sample processing that would destroy, or change, the process. Besides, elastic techniques such as second and third harmonic generation do not release energy at the material which is therefore preserved after the observation. The objective of this thesis is to develop a multimodality platform for biology process observation by using Two Photon Excited Fluorescence, Second Harmonic Generation and Third Harmonic Generation Microscopy with the same instrument. Our group was the first one to demonstrate the acquisition of Second Harmonic Generation images in Brazil and this thesis is the first one to perform the acquisition of third harmonic generation images. These three techniques together provide complementary information respect to cell and tissue organization. While fluorescence can be specific target to some proteins, second harmonic can observe the collagen network of extra cellular matrix and the third harmonic can observe the nucleus and lipid droplets inside the cells. This thesis describe the experimental setup to perform these multimodal image acquisition, the physics behind the non linear signals, important to understand their biological mean, and shows applications of these techniques for different biological and inorganic samples
Mestrado
Física
Mestre em Física
Maurel, Clément. "Verres pour la Photostructuration." Phd thesis, Université Sciences et Technologies - Bordeaux I, 2009. http://tel.archives-ouvertes.fr/tel-00438449.
Full textAl-Obaidi, Rand. "In vitro enamel subsurface lesions : characterization and treatment." Thesis, Montpellier, 2018. http://www.theses.fr/2018MONTT017/document.
Full textWhite spot lesion is the subsurface hypomineralization of enamel indicating the 1st stage of dental caries development. Early detection of incipient dental caries before it reaches the stage of cavitation offers an opportunity for effective dental care. The objectives of this study were to strengthen the idiom of minimally invasive treatment. In order to achieve the specified goals; we have identified a modified pH cycling model that can mimic the intraoral conditions leading to white spot lesions formation in a short time. In addition, non-invasive optical techniques, such as confocal Raman microscopy and multiphoton microscopy were used in this study to detect small changes in the enamel chemical composition in vitro.Furthermore, nano-indentation technique was used to detect the changes in the mechanical properties of enamel and relate them to those affecting its chemical composition after caries induction in order to add chemico-mechanical specificity in providing important information about subsurface lesions in enamel. The obtained results demonstrate a great potential for the examined techniques, providing a basis for interesting applications in the clinical diagnosis of various pathological conditions in dentistry. To treatment the incipient carious lesions non-invasively, the effectiveness of GC Tooth Mousse cream and nHA containing-dentifrice "KAREX" in the remineralization of demineralized enamel through localizing amorphous calcium phosphate at tooth surface has been inspected. The study indicated a lack of reliable evidence supporting the efficacy of remineralizing agents in the treatment of white spot lesions. Within the limitations of this study, further laboratory studies together with clinical research are therefore required to increase the available knowledge on this prevalent subject
Slablab, Abdallah. "Étude de la génération de rayonnement optique de seconde harmonique dans les systèmes nanométriques et fabrication des sondes optiques pour le champ proche." Phd thesis, École normale supérieure de Cachan - ENS Cachan, 2010. http://tel.archives-ouvertes.fr/tel-00678485.
Full textMatar, Gladys. "Caractérisation biophysique de peptides riches en tryptophane à l'interface air-eau : apport de l'optique non linéaire." Thesis, Lyon 1, 2010. http://www.theses.fr/2010LYO10249.
Full textMembrane proteins are extremely rich in aromatic amino acids, like tryptophan (W). This particularity is found in many antimicrobial peptides and in several virus fusion proteins. An example of these fusion proteins is the HIV-1 envelop glycoprotein, the gp41. It is clear that the W residues are implicated in membrane perturbation and pore formation. The aim of this work was the investigation of the W residue role in such activities, using the nonlinear optic. First, we determined the W hyperpolarizabilité (nonlinear potential) by the Hyper Rayleigh Scattering (HRS). Then, the evolution of the nonlinear signal of small synthetic peptides, as function of the increasing number of their W residues, was demonstrated. These results allowed us to follow the W residue involvement of two peptides, K3W4 and gp41W, in the interaction with lipids monolayer at the air-water interface, using the second harmonic generation (SHG). The influence of such interaction in the peptide structure and orientation was determined using the PM-IRRAS. In conclusion, we showed the coherence between the SHG signal variation, due to the W orientation changes, and the PMIRRAS spectra modification, due to the gp41W helix orientation changes
Giehl, Júlia Maria. "Estudos das propriedades estruturais e ópticas de vidros teluritos." Universidade de São Paulo, 2011. http://www.teses.usp.br/teses/disponiveis/43/43134/tde-31032011-143131/.
Full textTellurite 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.
Fovo, Alice Dal. "Tecniche ottiche lineari e nonlineari e nuove metodologie fotoacustiche per l'analisi e il monitoraggio non invasivo delle opere d'arte. Linear and nonlinear optical techniques and novel photoacoustic modalities for the non-invasive analysis and monitoring of artworks." Doctoral thesis, 2019. http://hdl.handle.net/2158/1151726.
Full textTsai, Ming-Hung, and 蔡明宏. "Transmission-Type Three-Dimensional Optical Microscope with Nonlinear Compensation." Thesis, 2012. http://ndltd.ncl.edu.tw/handle/t3kupu.
Full text國立虎尾科技大學
光電與材料科技研究所
100
In this study, we proposed a transmission-type three-dimensional optical microscope with nonlinear compensation. The method is based on the critical angle method and the use of CCD detection technology to measure the 3-D profile of a transparent specimen. When a beam passes through the transparent specimen, the surface height or the refractive index will change the beam directions causes its output ray deflect a slight angle. Afterward the rays are incident into a parallelogram prism at the critical angle nearby and cause the output intensity be changed. By the first-order optical approximation and the formula of internal reflection, the reflectivity of the prism is proportional to the surface height. We should use a CCD sensor to be located at the image plane to record the critical angle or total reflection images. Finally, using the Matlab program to analyze the surface height of the specimen, and conpensate the nonlinear error due to the nonlinear curve of reflectivity, the three-dimensional profile of the test specimen is obtained.
Hong, Zhi-Ying, and 洪志穎. "Characterizing doped-ion-based optical elements by multi-modality nonlinear microscope." Thesis, 2018. http://ndltd.ncl.edu.tw/handle/avtq79.
Full textChung, Hsiang-Yu, and 鍾向宇. "The Application of Mini Aspheric Lens in Miniaturized Video-rate Nonlinear Optical Microscope." Thesis, 2013. http://ndltd.ncl.edu.tw/handle/76520108281093587200.
Full text國立臺灣大學
光電工程學研究所
101
Nonlinear optical microscopy has been developed for many years. Due to the mechanism of nonlinear optics, the nonlinear signal can only be generated around the focus of the objective. Thus, this kind of microscopy is known for its optical virtual biopsy ability in comparison with the traditional wide field microscopy. The excitation light is infrared, which is not only less invasive but also provides better depth of penetration. Typical way to apply nonlinear optical microscopy is directly integrating a conventional microscope with a laser light source and some additional scanning mechanisms. However, it will make the whole system bulkier. In order to apply nonlinear optical microscopy in clinical applications, the system must be miniaturized and redesigned for more flexibility. In this thesis, the investigation is focused on the miniaturized imaging head. An optical imaging head with a miniaturized size, a larger field of view (FOV), and a video frame-rate is highly desired because a miniaturized system is more convenient to be manipulated during the observation and allows intravital applications. Larger field of view means we can reveal more information once simultaneously. Higher frame rate can not only deal with the image blurring problem resulted from vibrations but also allow one to reduce the imaging acquisition time, thus dynamic observation may be realized. Aspheric lenses, which are known for their complex lens surface profile designed for aberration reduction or replacement for a multi-lens system, are used in 3C products, such as cell phone cameras, optical disk drives, or laser diode collimators. With its smaller size and cheaper price, it could be an alternative to traditional objectives in miniaturized nonlinear microscopy systems. In this thesis, we present our investigation on the potential to use high numerical aperture mini aspheric lens (a blu-ray disk lens with 0.85 NA and a laser diode collimating lens with 0.8 NA) as the objective of the miniaturized nonlinear microscopy system. The structure of the system is very simple, and only five mirrors or lenses are used. The mini aspheric lens is integrated with a tube lens pair for beam size magnification. A MEMS mirror acts as a scanner, and a dichroic beam splitter separates the excitation light and the epi-collected signal. We investigate its performance for 2PF (two-photon fluorescence), SHG (second harmonic generation), and THG (third harmonic generation) microscopies. Live GFP (green fluorescence protein) zebrafish is used to estimate the feasibility of in-vivo experiment and the ability of dynamic observation. Comparison among different systems from other groups is also listed.
Golde, Daniel [Verfasser]. "Microscopic investigations of the terahertz and the extreme nonlinear optical response of semiconductors / vorgelegt von Daniel Golde." 2010. http://d-nb.info/1006504273/34.
Full textHuang, Shih-Feng, and 黃士逢. "Study on Nonlinear Compensation for Enhancing the Vertical Resolution of Three-dimensional (3-D) Electro-Optical Laser Microscope." Thesis, 2012. http://ndltd.ncl.edu.tw/handle/6hgu2u.
Full text國立虎尾科技大學
光電與材料科技研究所
100
In this study, we proposes a non-scanning, non-interferometric, three- dimensional (3D) optical microscope based on geometric optics, and critical angle principle. According to the first-order optic approximation, the deflection angle of the reflection light from the test specimen is proportional to its surface height. In addition, the reflectance of a parallelogram prism is also proportional to the incident angle at the critical angle nearby. We used two charge-coupled devices (CCD) as cameras to record the images at the critical angle nearby and at the angle of total internal reflection, respectively, for making a reflectance profile. The reflectance profile can be transformed into the 3-D surface profile of the test surface. Because the reflectance curve versus the incident angle is nonlinear, the nonlinear-error compensation is need to do in order to reduce the error and to enhance the measurement accuracy. This is one of the focus in this study. The reflectance profile, obtained from CCDs, is the ratio of intensity recorded at the critical angle to the intensity recorded at the total internal reflection angle. The 3-D microscope provides a sub-micron measuring range with nanometer resolution in the axial direction and can also be used to measure roughness, film thickness or surface defects in real time.