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A rigorous multipolar framework for nanoparticles optical properties description : theory and experiments / Construction d'un cadre rigoureux pour la description multipolaire des propriétés optiques de nanoparticulesRouxel, Jérémy 24 April 2015 (has links)
Les propriétés optiques linéaires et non-linéaires de nanoparticules métalliques de tailles non-négligeables comparées à celles des longueurs d’onde excitatrices sont étudiées dans cette thèse. Les informations issues de la symétrie sont mises en avant afin de décrire des nanoparticules appartenant à des groupes ponctuels. Pour cela, un formalisme totalement irréductible est mis en place afin de prendre en compte l’extension spatiale des objets étudiés. Dans ce formalisme, le tenseur de réponse non-linéaire possède un nombre fini de valeurs significatives reliant les composantes multipolaires des champs incidents et sortants. Ce formalisme est alors appliqué analytiquement à l’étude de la réponse non- linéaire du second ordre de nano-étoiles d’or en interprétant des mesures de SHG résolue en polarisation. Finalement, des expériences de spectroscopies multidimensionnelles sont utilisées dans le but de connecter les propriétés spatiales et les propriétés spectrales de ces objets. L’introduction de modes propres définis par la symétrie des objets permet encore une fois de donner un sens physique aux comportements électroniques mis en jeu / Using metallic nanoparticles with a threefold symmetry thorough the study, the impact of the symmetry on the nonlinear properties is investigated. Interpretations of polarization-resolved SHG experiments indicate the importance of multipolar resonances, in particular quadrupole and octupole, to explain the strong values of the nonlinear susceptibilities in such systems. A fully irreducible formalism is then developed to treat extended objects like nanoparticles. In this formalism, the nonlinear response tensor is a discrete set of values easily constrained by symmetries instead of a field. This formalism permits to describe simply linear and nonlinear optical response from nanoparticles. Finally, time-domain experiments are conducted with the aim to connect spatial and spectral properties. These experiments allow to interpret the spectra in terms of eigenmodes
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Investigation into C-H activation and characterisation of excited states using ultrafast TRIR spectroscopyWriglesworth, Alisdair January 2014 (has links)
No description available.
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Generation, Characterization and Application of the 3rd and 4th Harmonics of a Ti:sapphire Femtosecond LaserWright, Peter 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.
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Experimental Investigation of Detonation Re-initiation Mechanisms Following a Mach Reflection of a Quenched DetonationBhattacharjee, Rohit Ranjan January 2013 (has links)
Detonation waves are supersonic combustion waves that have a multi-shock front structure followed by a spatially non-uniform reaction zone. During propagation, a de-coupled shock-flame complex is periodically re-initiated into an overdriven detonation following a transient Mach reflection process. Past researchers have identified mechanisms that can increase combustion rates and cause localized hot spot re-ignition behind the Mach shock. But due to the small length scales and stochastic behaviour of detonation waves, the important mechanisms that can lead to re-initiation into a detonation requires further clarification.
If a detonation is allowed to diffract behind an obstacle, it can quench to form a de-coupled shock-flame complex and if allowed to form a Mach reflection, re-initiation of a detonation can occur. The use of this approach permits the study of re-initiation mechanisms reproducibly with relatively large length scales. The objective of this study is to experimentally elucidate the key mechanisms that can increase chemical reaction rates and sequentially lead to re-initiation of a de-coupled shock-flame complex into an overdriven detonation wave following a Mach reflection.
All experiments were carried out in a thin rectangular channel using a stoichiometric mixture of oxy-methane. Three different types of obstacles were used - a half-cylinder, a roughness plate along with the half-cylinder and a full-cylinder. Schlieren visualization was achieved by using a Z-configuration setup, a high speed camera and a high intensity light source.
Results indicate that forward jetting of the slip line behind the Mach stem can potentially increase combustion rates by entraining hot burned gas into unburned gas. Following ignition and jet entrainment, a detonation wave first appears along the Mach stem. The transverse wave can form a detonation wave due to rapid combustion of unburned gas which may be attributed to shock interaction with the unburned gas. Alternatively, the Kelvin-Helmholtz instability can produce vortices along the slipline that may lead to mixing between burned-unburned gases and potentially increase combustion rates near the transverse wave. However, the mechanism(s) that causes the transverse wave to re-initiate into a detonation wave remains to be satisfactorily resolved.
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Etude des processus thermophysiques en régime d'interaction laser/matière nanoseconde par pyro/réflectométrie rapide / Fast pyro/reflectometry study of thermophysical processus induced by nanosecond laser/material interactionAmin Chalhoub, Eliane 10 December 2010 (has links)
Face au développement actuel des nanotechnologies, l'étude et la caractérisation des propriétés thermiques des couches minces et des nanomatériaux devient nécessaire pour le développement et la qualité des nouvelles technologies. Notre système expérimental a été conçu et mis en oeuvre dans le but d'étudier les différents phénomènes qui régissent l'interaction matière/laser nanoseconde en temps réel. Ce système est composé de deux méthodes optiques complémentaires : la réflectivité résolue en temps RRT et la pyrométrie infrarouge rapide PIR. Nous avons montré dans un premier temps la possibilité d'étudier en temps réel les modifications de l'état de surface d'une couche mince métallique déposée sur un substrat isolant, le phénomène de photoluminescence ainsi que la cinétique de fusion/resolidification et celle de l'ablation. De plus, nous présenterons une méthode originale afin de déterminer les propriétés thermiques (la capacité calorifique volumique et la conductivité thermique) des surfaces nanostructurées. L'analyse nécessite une préparation de l'échantillon ainsi que l'utilisation d'un modèle théorique éprouvé que l'on ajuste avec un algorithme d'optimisation sur nos relevés expérimentaux. / The recent development of nanotechnology has made the study and the characterisation of thermal properties of thin films and nanomaterials very important for the development and the quality of new technologies. Our experimental setup is designed and built in order to study different phenomena, in real time, that arise while the interaction of a laser with materials at the nanosecond scale. This system is composed of two complementary optical diagnostics, the time resolved reflectivity and the fast infrared pyrometry. First, we have shown the ability to study in real time the surface structural changes in the case of a thin metal layer deposited on an insulating substrate, the phenomenon of photoluminescence and the kinetics of melting/resolidification and also the ablation. In addition, we present a novel method in order to determine the thermal properties (volumetric heat capacity and thermal conductivity) of nanostructured surfaces. The analysis is based on the use of a proven theoretical model that is adjusted with an optimisation algorithm on our experimental measurements.
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Pump-probe spectroscopy of photovoltaic materialsSpencer, Ben January 2011 (has links)
The study of photovoltaic materials is important so as to develop new solar energy technologies: in particular, quantum-confined semiconductors could offer increased quantum efficiencies at a much lower manufacture cost. This thesis contains results from a number of pump-probe experiments designed to probe the carrier dynamics in bulk and quantum-confined photovoltaics. A THz time-domain spectrometer was designed, built and commissioned. The THz refractive indices and absorption coefficients of toluene and hexane were determined, and the spectrometer was benchmarked using a photoexcited GaAs wafer. Results are presented of time-resolved THz spectroscopy of photoexcited bulk InP as a function of laser excitation wavelength. These data were used to extract the quantum efficiency of bulk InP in order to compare with recent results for InP quantum dots. The quantum efficiency in quantum dots increases when the incident photon energy is at least twice the band gap energy, whereasthe efficiency of the bulk material is found to decrease. This is because of surface recombination, and these measurements therefore verify the potential superiority of quantum dot materials over bulk materials for use in solar energy applications. Initial measurements of quantum dots using THz spectroscopy highlighted the various experimental challenges involved and the upgrades required to study such samples in the future.The time-dependence of the photoinduced surface photovoltage (SPV) in Si was studied on nanosecond timescales by synchronizing an ultrafast laser system to a synchrotron radiation source (the SRS at Daresbury, UK), and measuring the resulting shift in the photoelectron spectrum. The equilibrium band bending was determined, and the decay of the SPV was attributed to the recombination of charge carriers across the band gap. Results are presented for the SPV in bulk ZnO and for PbS quantum dot chemically attached to ZnO. The fact that the PbS quantum dots were chemically attached to the surface without becoming oxidized was verified using X-ray photoelectron spectroscopy (XPS). The changes caused by photoexcitation occur on much longer timescales in ZnO than Si (sub-milliseconds rather than nanoseconds), and these timescales were conveniently accessed using the time-resolved XPS facility at the TEMPO beamline at Synchrotron SOLEIL (Paris, France). This is due to oxygen adsorption and desorption processes at the ZnO surface affectingthe transfer of charge carriers. The addition of PbS quantum dots to the ZnO surface was found to increase the speed of this charge transfer due to injection of carriers directly from the PbS quantum dot to the bulk ZnO conduction band.
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Serial Femtosecond Crystallography of Proteins in Proteins and CancerJanuary 2020 (has links)
abstract: This thesis focuses on serial crystallography studies with X-ray free electron lasers
(XFEL) with a special emphasis on data analysis to investigate important processes
in bioenergy conversion and medicinal applications.
First, the work on photosynthesis focuses on time-resolved femtosecond crystallography
studies of Photosystem II (PSII). The structural-dynamic studies of the water
splitting reaction centering on PSII is a current hot topic of interest in the field, the
goal of which is to capture snapshots of the structural changes during the Kok cycle.
This thesis presents results from time-resolved serial femtosecond (fs) crystallography
experiments (TR-SFX) where data sets are collected at room temperature from a
stream of crystals that intersect with the ultrashort femtosecond X-ray pulses at an
XFEL with the goal to obtain structural information from the transient state (S4)
state of the cycle where the O=O bond is formed, and oxygen is released. The most
current techniques available in SFX/TR-SFX to handle hundreds of millions of raw
diffraction patterns are discussed, including selection of the best diffraction patterns,
allowing for their indexing and further data processing. The results include two 4.0 Å
resolution structures of the ground S1 state and triple excited S4 transient state.
Second, this thesis reports on the first international XFEL user experiments in
South Korea at the Pohang Accelerator Laboratory (PAL-XFEL). The usability of this
new XFEL in a proof-of-principle experiment for the study of microcrystals of human
taspase1 (an important cancer target) by SFX has been tested. The descriptions of
experiments and discussions of specific data evaluation challenges of this project in
light of the taspase1 crystals’ high anisotropy, which limited the resolution to 4.5 Å,
are included in this report
In summary, this thesis examines current techniques that are available in the
SFX/TR-SFX domain to study crystal structures from microcrystals damage-free,
with the future potential of making movies of biological processes. / Dissertation/Thesis / Masters Thesis Chemistry 2020
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Continuous-Flow Synthesis and Materials Interface Engineering of Lead Sulfide Quantum Dots for Photovoltaic ApplicationsEl-Ballouli, Ala’a O. 25 May 2016 (has links)
Harnessing the Sun’s energy via the conversion of solar photons to electricity has emerged as a sustainable energy source to fulfill our future demands. In this regard, solution-processable, size-tunable PbS quantum dots (QDs) have been identified as a promising active materials for photovoltaics (PVs). Yet, there are still serious challenges that hinder the full exploitation of QD materials in PVs. This dissertation addresses two main challenges to aid these QDs in fulfilling their tremendous potential in PV applications.
First, it is essential to establish a large-scale synthetic technique which maintains control over the reaction parameters to yield QDs with well-defined shape, size, and composition. Rigorous protocols for cost-effective production on a scale are still missing from literature. Particularly, previous reports of record-performance QD-PVs have been based on small-scale, manual, batch syntheses. One way to achieve a controlled large-scale synthesis is by reducing the reaction volume to ensure uniformity. Accordingly, we design a droplet-based continuous-flow synthesis of PbS QDs. Only upon separating the nucleation and growth phases, via a dual-temperature-stage reactor, it was possible to achieve high-quality QDs with high photoluminescence quantum yield (50%) in large-scale. The performance of these QDs in a PV device was comparable to batch-synthesized QDs, thus providing a promise in utilizing automated synthesis of QDs for PV applications.
Second, it is crucial to study and control the charge transfer (CT) dynamics at QD interfaces in order to optimize their PV performance. Yet, the CT investigations based on PbS QDs are limited in literature. Here, we investigate the CT and charge separation (CS) at size-tunable PbS QDs and organic acceptor interfaces using a combination of femtosecond broadband transient spectroscopic techniques and steady-state measurements. The results reveal that the energy band alignment, tuned by the quantum confinement, is a key element for efficient CT and CS processes. Additionally, the presence of interfacial electrostatic interaction between the QDs and the acceptors facilitates CT from large PbS QD (bandgap < 1 eV); thus enabling light-harvesting from the broad near-infrared solar spectrum range.
The advances in this work – from automated synthesis to charge transfer studies – pave new pathways towards energy harvesting from solution-processed nanomaterials.
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ELUCIDATING THE HMG-COA REDUCTASE REACTION MECHANISM USING PH-TRIGGERED TIME-RESOLVED X-RAY CRYSTALLOGRAPHYVatsal Purohit (11825150) 18 December 2021 (has links)
<p>HMG-CoA reductase from Pseudomonas mevalonii (<i>Pm</i>HMGR) catalyzes the oxidation of mevalonate and mevaldyl-CoA to form HMG-CoA using CoA-SH and two NAD+ cofactors. While the enzyme has been used extensively as a drug target in humans to treat hypercholesterolemia, its pathway has also been found to be critical for the survival of antibiotic resistant gram-positive bacteria. Structural studies using non-productive and slow-substrate binary complexes as well as biochemical studies using half and full reactions led to the proposal that the conversion of mevalonate to HMG-CoA occurs through the generation of two intermediates, mevaldehyde and mevaldyl-CoA (Shown in Fig 1.1). However, several intermediary changes along the <i>Pm</i>HMGR reaction pathway remain unclear. By gathering information about the enzyme’s intermediate states via structural studies, we could identify potential allosteric sites that further the reaction mechanism. Using this knowledge, we could design enzyme inhibitors that act as novel antibacterials. The application of time-resolved crystallographic methods would provide structural information about transitory states in the PmHMGR reaction mechanism. The <i>Pm</i>HMGR crystal has been shown to be suitable for time-resolved crystallographic measurements for the reaction steps resulting in mevaldyl-CoA formation. However, our structural investigations of the mevalonate, CoA and NAD+ complex that are expected to result in the formation of mevaldehyde (Fig 1.1) do not show any changes corresponding to a turnover in the crystal environment. <br></p><p><br></p><p>To investigate the factors limiting enzymatic activity in the crystal, we investigated the effects of pH and specific ions in the crystallization environment. Kinetic studies indicated a strong <i>Pm</i>HMHGR inhibition in the crystallization buffer that is dependent on the concentration of the crystallization precipitant ammonium sulfate. These studies also indicated an increase in enzyme turnover with increasing pH. Utilizing the ionic concentration and pH-dependent properties of the enzyme in the crystallization environment, we have developed a reaction triggering approach using pH changes for <i>Pm</i>HMGR crystals.<br></p><p><br></p><p>We have demonstrated our application of this ‘pH-jump’ method by observing changes in <i>Pm</i>HMGR crystals after reaction initiation. Changes in the density of mevalonate, CoA and NAD+have indicated mevaldehyde and mevaldyl-CoA formation. Additionally, the appearance of a unique NADH absorbance peak after the pH-change has also highlighted the initiation of the <i>Pm</i>HMGR reaction and the occurrence of a hydride transfer step. Our analysis of the movements using time-resolved structures post reaction-initiation have also highlighted structural changes and inter-domain contacts in the small and flap domain that would allow cofactor exchange and product release. The pH-jump method can hence be utilized as a novel approach for triggering the <i>Pm</i>HMGR reaction in crystals and further studying transitory states along its reaction pathway.<br></p>
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Automatizace optické sestavy pro časově rozlišitelnou spektroskopii / Automatization of an optical setup for time-resolved spectroscopyŠimek, Daniel January 2021 (has links)
Time-resolved spectroscopy is a modern method enabling the analysis of the dynamics of quantum luminescence transitions. This method uses ultra-fast light pulses to study materials, which makes it possible to observe the time evolution of luminescence quenching and thus provides additional information for static absorption and emission spectroscopy. This diploma thesis deals with the automation of the optical setup used in the Optical and Plasmonic Laboratory at Ceitec Nano for performing time-resolved spectroscopy. As part of the work, an application was created enabling communication with 13 devices used in the laboratory. The application automates already performed measurements, and in addition enables the scanning of samples, which was not possible due to time constraints due to the manual control of the stage movement. At the end of the work, test measurements are performed, with a discussion of their effectiveness and time savings for the user.
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