Global ETD Search

141	Exploration du traitement au laser femtoseconde de supports transparents de nouveaux composants laser / Exploring femtosecond laser processing of transparent media for novel laser components Gebremichael, Wendwesen 06 June 2019 (has links) L’inscription par laser femtoseconde directe dans les cristaux laser offre une nouvelle opportunité de conception et développement de sources laser intégrées. Elle conduit à un prototypage rapide et à un bon rapport coût-efficacité, conformément aux futures feuilles de route de la photonique. Cependant, les défis liés au dépôt d’énergie d’un laser intense dans des milieux transparents et les modifications qui s’ensuivent restent encore des questions ouvertes. Ces défis ont été relevés en partie grâce à une étude minutieuse et systématique des zones modifiées par laser femtoseconde dans les matériaux transparents. Le fluorure de calcium (CaF2), en raison de sa symétrie cubique et de ses excellentes propriétés de luminescence en tant que cristal laser, a été choisi comme matériaux de référence dans cette thèse. L’inscription laser en régime femtoseconde de guides d’ondes à l’intérieur de ce cristal a été réalisée pour une conception future de source laser intégrée. Pour la première fois, des écritures laser « lisses » et non réciproques ont été observées à l’intérieur de certains échantillons « coupés spécialement » de cristaux de CaF2. De plus, un guidage de la lumière dépendant de la polarisation a été identifié et est présenté. Un modèle et une méthode ont été développés pour caractériser quantitativement et qualitativement ces guides d’ondes, en particulier pour les mesures de perte de transmission, ainsi que les cartographies tridimensionnelles de l’indice de réfraction des zones modifiées. / Femtosecond laser micromachining inside laser crystals offers a new platform to miniaturize highly compact laser sources. It leads to rapid prototyping and cost-effectiveness in line with the future photonics roadmaps. However, the challenges in relation to an intense laser pulse energy deposition within transparent media and the modifications that follow still remain open-ended questions. These challenges have been addressed with a careful and systematic study of femtosecond modified zones inside transparent materials. Due to its cubic symmetry and excellent luminescence properties as laser crystal, Calcium Fluoride (CaF2) was selected, and ultrafast laser inscription of waveguides inside this crystal was realized. Smooth and non-reciprocal writings were observed inside certain “specially cut” samples of the CaF2 crystals for the first time. Additionally, polarization dependent guiding is identified and presented. Furthermore, an authentic model and concept was engaged for the quantitative and qualitative characterization of the waveguides, particularly for the transmission loss measurements and the three-dimensional refractive index mappings of the modified zones. Spectroscopie femtosecondes Guides d'ondes Photonique Waveguide Integrated photonics Femtosecond laser writing Crystal
142	Metal Nanoparticle Synthesis by Photochemical Reduction with a High-Intensity Focused Laser Beam Meader, Victoria K 01 January 2019 (has links) Colloidal, metallic nanoparticles have myriad applications, but they are most ideal when they are monodisperse, and demonstrate maximum catalytic utility when they are small (< 5 nm) and uncoated; because their surface area is accessible and maximized. Laser- assisted metal nanoparticle synthesis is a ‘green’ method that has become a topic of active research because it is able to produce uncoated or ‘naked’ products. The nanoparticles synthesized in this work were formed through the reduction of metal salts in aqueous solutions; but the reducing agent is an electron-dense microplasma generated by the laser pulse interacting with the media. Because no chemical reducing agents or stabilizers are needed, the products have no surfactants. The underlying reaction mechanisms that drive this type of synthesis are generally understood, however, there is insufficient detail that would allow control over the formation of ultimate product morphologies and size distributions. The metals examined in this thesis are: gold, whose formation follows an autocatalytic rate law; and silver, whose formation follows a first-order rate law. Through my research, I was able to explore the effects that physical parameters (such as laser pulse settings) and chemical parameters (such as radical scavenger addition) have on laser-assisted gold or silver nanoparticle synthesis. My research, outlined in this thesis, is therefore focused on elucidating such details and distilling them into methods of control in order to better predict and tune nanoparticle products. photochemistry metallic nanoparticle femtosecond laser reduction synthesis optical breakdown Physical Chemistry
143	An Ultrafast Spectroscopic and Quantum-Chemical Study of the Photochemistry of Bilirubin : Initial Processes in the Phototherapy for Neonatal Jaundice Zietz, Burkhard January 2006 (has links) <p>Bilirubin is a degradation product of haem, which is constantly formed in all</p><p>mammals. Increased levels of bilirubin in humans lead to jaundice, a condition</p><p>that is very common during the first days after birth. This neonatal</p><p>jaundice can routinely be treated by phototherapy without any serious side</p><p>effects. During this treatment, bilirubin undergoes a photoreaction to isomers</p><p>that can be excreted. The most efficient photoreaction is the isomerisation</p><p>around a double bond (Z-E-isomerisation), which results in more soluble</p><p>photoproducts.</p><p>The work presented in this thesis shows results of a femtosecond optical</p><p>spectroscopy study, combined with quantum-mechanical investigations, of</p><p>the mechanism of isomerisation of bilirubin. The spectroscopic research was</p><p>conducted with bilirubin in organic solvents, and in buffer complexed by</p><p>human serum albumin. This albumin complex is present in the blood, and</p><p>has thus medical importance. Quantum-chemical calculations (CASSCF) on</p><p>a bilirubin model were used to explain experimental results.</p><p>The fluorescence decay observed with femtosecond spectroscopy shows an</p><p>ultrafast component (~120 fs), which is explained by exciton localisation,</p><p>followed by processes with a lifetime of about 1-3 ps. These are interpreted</p><p>as the formation of a twisted intermediate, which decays with a lifetime of</p><p>10-15 ps back to the ground state, as observed by absorption spectroscopy.</p><p>CASSCF calculations, in combination with the experimental results, suggest</p><p>the ca. 1-3 ps components to be relaxation to the twisted S1 minimum, followed</p><p>by the crossing of a barrier, from where further relaxation takes place</p><p>through a conical intersection back to the ground state.</p><p>Time-dependent DFT calculations were utilised to analyse the absorption</p><p>spectrum of bilirubin. Good agreement with the measured spectrum was</p><p>achieved, and low-lying states were observed, that need further investigation.</p><p>The theoretically obtained CD spectrum provides direct evidence that</p><p>bilirubin preferentially binds to human serum albumin in the enantiomeric</p><p>P-form at neutral pH.</p> / <p>Bilirubin är en nedbrytningsprodukt av hem som ständigt bildas hos alla</p><p>däggdjur. En förhöjd bilirubinkoncentration i den mänskliga kroppen kan</p><p>leda till gulsot, något som är mycket vanligt under de första dagarna efter</p><p>födelsen (neonatal gulsot). Fototerapi används rutinmässigt som säker behandlingsmetod,</p><p>under vilken bilirubin genomgår en fotoreaktion till en</p><p>isomer som kan utsöndras. Den mest effektiva fotoreaktionen är en Z-Eisomerisation,</p><p>vilken leder till lösligare fotoprodukter.</p><p>Arbetet som presenteras i denna avhandling visar resultaten av en kombinerad</p><p>femtosekund optisk-spektroskopisk och kvantmekanisk undersökning</p><p>av mekanismen bakom bilirubins isomerisation. Den spektroskopiska</p><p>studien genomfördes med bilirubin, löst i organiska lösningsmedel och i</p><p>buffert i komplex med humant serumalbumin. Detta albuminkomplex finns i</p><p>blodet, och är därför av medicinskt intresse. Kvantmekanistiska CASSCFberäkningar</p><p>på en bilirubinmodell användes för att förklara de experimentella</p><p>resultaten.</p><p>Det uppmätta fluorescence sönderfallet visar ultrasnabba komponenter</p><p>(~120 fs). Dessa tolkas som excitonlokalisering, som följs av bildandet av</p><p>ett vridet intermediat med en hastighetskonstant på ca. 1 ps-1(beroende på</p><p>lösningsmedlet). Absorptionsmätningar visar att detta intermediat sönderfaller</p><p>tillbaka till grundtillståndet med en livstid på 10-15 ps.</p><p>CASSCF beräkningar, i kombination med de experimentella resultaten, tyder</p><p>på att sönderfallet med livslängden på ca. 1 ps är en relaxation till det</p><p>vridna S1-tillståndet. Reaktionsvägen därifrån antas passera en barriär till en</p><p>konisk genomskärning, som möjliggör snabb relaxation till grundtillståndet.</p><p>Tidsberoende DFT-beräkningar användes för att analysera bilirubins absorptionsspektrum,</p><p>vilket gav bra överensstämmelse med uppmätta data. Dessutom</p><p>hittades ett tillstånd med låg excitationsenergi, som kräver ytterligare</p><p>studier. Med hjälp av det beräknade CD-spectret kunde det visas att bilirubin</p><p>binder till albumin i P-formen vid neutralt pH.</p> Bilirubin Phototherapy Neonatal Jaundice Femtosecond Spectroscopy CASSCF TD-DFT Isomerisation Dynamics Biophysical chemistry Biofysikalisk kemi
144	Time resolved laser spectroscopy Ekvall, Karin January 2000 (has links) No description available. non-linear polarisation third and fifth order susceptibility cross phase modulation
145	An Ultrafast Spectroscopic and Quantum-Chemical Study of the Photochemistry of Bilirubin : Initial Processes in the Phototherapy for Neonatal Jaundice Zietz, Burkhard January 2006 (has links) Bilirubin is a degradation product of haem, which is constantly formed in all mammals. Increased levels of bilirubin in humans lead to jaundice, a condition that is very common during the first days after birth. This neonatal jaundice can routinely be treated by phototherapy without any serious side effects. During this treatment, bilirubin undergoes a photoreaction to isomers that can be excreted. The most efficient photoreaction is the isomerisation around a double bond (Z-E-isomerisation), which results in more soluble photoproducts. The work presented in this thesis shows results of a femtosecond optical spectroscopy study, combined with quantum-mechanical investigations, of the mechanism of isomerisation of bilirubin. The spectroscopic research was conducted with bilirubin in organic solvents, and in buffer complexed by human serum albumin. This albumin complex is present in the blood, and has thus medical importance. Quantum-chemical calculations (CASSCF) on a bilirubin model were used to explain experimental results. The fluorescence decay observed with femtosecond spectroscopy shows an ultrafast component (~120 fs), which is explained by exciton localisation, followed by processes with a lifetime of about 1-3 ps. These are interpreted as the formation of a twisted intermediate, which decays with a lifetime of 10-15 ps back to the ground state, as observed by absorption spectroscopy. CASSCF calculations, in combination with the experimental results, suggest the ca. 1-3 ps components to be relaxation to the twisted S1 minimum, followed by the crossing of a barrier, from where further relaxation takes place through a conical intersection back to the ground state. Time-dependent DFT calculations were utilised to analyse the absorption spectrum of bilirubin. Good agreement with the measured spectrum was achieved, and low-lying states were observed, that need further investigation. The theoretically obtained CD spectrum provides direct evidence that bilirubin preferentially binds to human serum albumin in the enantiomeric P-form at neutral pH. / Bilirubin är en nedbrytningsprodukt av hem som ständigt bildas hos alla däggdjur. En förhöjd bilirubinkoncentration i den mänskliga kroppen kan leda till gulsot, något som är mycket vanligt under de första dagarna efter födelsen (neonatal gulsot). Fototerapi används rutinmässigt som säker behandlingsmetod, under vilken bilirubin genomgår en fotoreaktion till en isomer som kan utsöndras. Den mest effektiva fotoreaktionen är en Z-Eisomerisation, vilken leder till lösligare fotoprodukter. Arbetet som presenteras i denna avhandling visar resultaten av en kombinerad femtosekund optisk-spektroskopisk och kvantmekanisk undersökning av mekanismen bakom bilirubins isomerisation. Den spektroskopiska studien genomfördes med bilirubin, löst i organiska lösningsmedel och i buffert i komplex med humant serumalbumin. Detta albuminkomplex finns i blodet, och är därför av medicinskt intresse. Kvantmekanistiska CASSCFberäkningar på en bilirubinmodell användes för att förklara de experimentella resultaten. Det uppmätta fluorescence sönderfallet visar ultrasnabba komponenter (~120 fs). Dessa tolkas som excitonlokalisering, som följs av bildandet av ett vridet intermediat med en hastighetskonstant på ca. 1 ps-1(beroende på lösningsmedlet). Absorptionsmätningar visar att detta intermediat sönderfaller tillbaka till grundtillståndet med en livstid på 10-15 ps. CASSCF beräkningar, i kombination med de experimentella resultaten, tyder på att sönderfallet med livslängden på ca. 1 ps är en relaxation till det vridna S1-tillståndet. Reaktionsvägen därifrån antas passera en barriär till en konisk genomskärning, som möjliggör snabb relaxation till grundtillståndet. Tidsberoende DFT-beräkningar användes för att analysera bilirubins absorptionsspektrum, vilket gav bra överensstämmelse med uppmätta data. Dessutom hittades ett tillstånd med låg excitationsenergi, som kräver ytterligare studier. Med hjälp av det beräknade CD-spectret kunde det visas att bilirubin binder till albumin i P-formen vid neutralt pH. Bilirubin Phototherapy Neonatal Jaundice Femtosecond Spectroscopy CASSCF TD-DFT Isomerisation Dynamics Biophysical chemistry Biofysikalisk kemi
146	Generation, Characterization and Application of the 3rd and 4th Harmonics of a Ti:sapphire Femtosecond Laser Wright, Peter 25 January 2012 (has links) Femtosecond time-resolved photoelectron spectroscopy (fsTRPES) experiments have been used to study the photoelectron energy spectra of simple molecules since the 1980’s. Analysis of these spectra provides information about the ultrafast internal conversion dynamics of the parent ions. However, ultraviolet pulses must be used for these pump-probe experiments in order to ionize the molecules. Since current solid state lasers, such as the Ti:sapphire laser, typically produce pulses centered at 800nm, it is necessary to generate UV pulses with nonlinear frequency mixing techniques. I therefore constructed an optical setup to generate the 3rd and 4th harmonics, at 266.7nm and 200nm, respectively, of a Ti:sapphire (Ti:sa) chirped-pulse amplified (CPA) laser system that produces 35fs pulses centered at 800nm. Thin Beta-Barium Borate (β-BaB2O4 or BBO) crystals were chosen to achieve a compromise between short pulse durations and reasonable conversion efficiencies, since ultrashort pulses are quite susceptible to broadening from group velocity dispersion (GVD). Output energies of around 11μJ and 230nJ were measured for the 266.7nm and 200nm pulses, respectively. The transform limits of the 3rd and 4th harmonic pulse lengths were calculated from their measured spectral widths. We found that the 266.7nm bandwidth was large enough to support sub-30fs pulses, and due to cutting at the lower-wavelength end of the 200nm spectrum, we calculated an upper limit of 38fs. The pulses were compressed with pairs of CaF2 prisms to compensate for dispersion introduced by transmissive optics. Two-photon absorption (TPA) intensity autocorrelations revealed fully compressed pulse lengths of 36 ± 2 fs and 42 ± 4 fs for the 3rd and 4th harmonics, respectively. sum-frequency generation 4th harmonic generation femtosecond laser pulses ultraviolet pulse characterization time-resolved photoelectron spectroscopy
147	Generation, Characterization and Application of the 3rd and 4th Harmonics of a Ti:sapphire Femtosecond Laser Wright, Peter 25 January 2012 (has links) Femtosecond time-resolved photoelectron spectroscopy (fsTRPES) experiments have been used to study the photoelectron energy spectra of simple molecules since the 1980’s. Analysis of these spectra provides information about the ultrafast internal conversion dynamics of the parent ions. However, ultraviolet pulses must be used for these pump-probe experiments in order to ionize the molecules. Since current solid state lasers, such as the Ti:sapphire laser, typically produce pulses centered at 800nm, it is necessary to generate UV pulses with nonlinear frequency mixing techniques. I therefore constructed an optical setup to generate the 3rd and 4th harmonics, at 266.7nm and 200nm, respectively, of a Ti:sapphire (Ti:sa) chirped-pulse amplified (CPA) laser system that produces 35fs pulses centered at 800nm. Thin Beta-Barium Borate (β-BaB2O4 or BBO) crystals were chosen to achieve a compromise between short pulse durations and reasonable conversion efficiencies, since ultrashort pulses are quite susceptible to broadening from group velocity dispersion (GVD). Output energies of around 11μJ and 230nJ were measured for the 266.7nm and 200nm pulses, respectively. The transform limits of the 3rd and 4th harmonic pulse lengths were calculated from their measured spectral widths. We found that the 266.7nm bandwidth was large enough to support sub-30fs pulses, and due to cutting at the lower-wavelength end of the 200nm spectrum, we calculated an upper limit of 38fs. The pulses were compressed with pairs of CaF2 prisms to compensate for dispersion introduced by transmissive optics. Two-photon absorption (TPA) intensity autocorrelations revealed fully compressed pulse lengths of 36 ± 2 fs and 42 ± 4 fs for the 3rd and 4th harmonics, respectively. sum-frequency generation 4th harmonic generation femtosecond laser pulses ultraviolet pulse characterization time-resolved photoelectron spectroscopy
148	Intrinsic Nonlinear Microscopy: From Neuronal Firing to Historical Artwork Samineni, Prathyush January 2012 (has links) <p>Imaging based on nonlinear processes takes advantage of the localized excitation to achieve high spatial resolution, optical sectioning, and deeper penetration in highly scattering media. However, the use of nonlinear contrast for imaging has conventionally been limited to processes that create light of wavelengths that are different from the wavelengths used for excitation. Intrinsic nonlinear contrasts that do not generate light at distinct wavelengths are generally difficult to measure because of the overwhelming background from the excitation light. This dissertation focuses on extension of nonlinear microscopy to these new intrinsic processes by using femtosecond pulse shaping to encode the nonlinear information as new frequency components in the spectrum. We will present a pump-probe microscopy technique based on pulse train shaping technology to sensitively access nonlinear transient absorption or gain processes. This technique has recently been used to uniquely identify a variety of biological pigments with high spatial resolution. Here, we extend this technique to image and characterize several inorganic and organic pigments used in historical artwork. We also present a spectral reshaping technique based on individual femtosecond pulse shaping to sensitively access nonlinear refractive contrasts in scattering media. We will describe an extension of this technique to utilize two distinct wavelengths and discuss its application in biological imaging. This two-color implementation would allow the extension of widely employed phase contrast to the nonlinear regime.</p> / Dissertation Optics Medical imaging and radiology Chemistry femtosecond Nonlinear microscopy phase modulation pigments pulseshaping pump-probe
149	Development and Characterization of a Regeneratively Amplified Ultrafast Laser System with an All-Glass Stretcher and Compressor Walker, Stephen January 2006 (has links) High-peak power laser systems are defined along with a brief introduction of the technology used in their development and application to the project. A review of concepts surrounding optical pulses, focusing on the particular phenomena involved with the ultrafast, follows. Numerical models involving optical pulses are introduced and verified. An extensive description of the laser system is presented, including models used in its design. Data verifying the correct operation of the laser system is presented and interpreted. A dispersion compensation system, including a function model, is introduced, and its application to the laser system is analyzed. An introduction to pulse characterization techniques is presented followed by the design and verification of two different characterization devices. Experiments utlizing the dispersion compensation system and pulse characterization devices are presented and the results are interpreted. Conclusions are made regarding the performance of the laser system models and pulse characterization devices, along with suggested improvements for each. The results of the experiments are discussed including suggestions for future work. Physics & Astronomy Ultrafast Regenerative Amplifier Regenerative Pulse Shaping Prism Compressor high-peak power laser Femtosecond
150	Femtosecond Time-Resolved Studies on the Reaction Pathways for the Generation of Reactive Oxygen Species in Photodynamic Therapy by Indocyanine Green Luo, Ting 26 August 2008 (has links) Photodynamic therapy (PDT), which utilizes the combination of light and a photosensitizing drug to cause tissue damages, has emerged as a novel clinical approach for the treatment of numerous cancers, as well as some other non-malignant conditions. Although a few photosensitizers have been approved for clinical uses, the mechanism of drug action, especially the initial photochemical reactions that lead to the formation of the reactive oxygen species (ROS), is still not well understood. Moreover, the PDT efficiency of currently used drugs is limited due to the strong attenuation of light by tissues in the wavelength range of 630-690 nm, where these drugs are photo-activated. Photosensitizers which are sensitive to near infrared (NIR) light are believed to be able to overcome this limitation. In this thesis work, the molecular mechanism of action of indocyanine green (ICG), a potential NIR PDT drug, was investigated using our femtosecond time-resolved laser spectroscopy. Femtosecond time-resolved fluorescence decay profiles of ICG in water were obtained using the fluorescence up-conversion technique. The lifetime of ICG excited singlet state was determined to be about 150 ps, directly from the fluorescence decay kinetic traces. The excited triplet-state yield of ICG in water was found to be extremely low, according to the result of the ground-state bleaching recovery measurement. This observation is contrary to the conventional understanding that the ROS would be generated mainly from the excited triplet state of the photosensitizer and, therefore, suggests the existence of a new reaction pathway. Pump-probe transient absorption spectroscopy was applied to study the reaction between ICG and oxygen in more details. The results reveal that the formation of ICG and oxygen ground-state complexes ([ICG]<sub>m</sub>:[O<sub>2</sub>]<sub>n</sub>) is a key step in the generation of the ROS. Electron transfer from the excited singlet state of ICG to oxygen has been proposed to be a possible pathway for the generation of ROS. Photodynamic therapy Femtosecond Time-Resolved Reactive Oxygen Species Indocyanine Green Physics

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