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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
51

Laser-induced breakdown spectroscopy (LIBS) on geological samples : compositional differentiation and relative hardness quantification

Panya panya, Sipokazi Ntombifikile 02 1900 (has links)
This master’s thesis is focused on the LIBS technique for compositional differentiation and relative hardness quantification of selected geological samples. The experimental part of this thesis was conducted at the National Institute of Laser Enhanced Sciences (NILES) in Cairo, Egypt where a simple LIBS system was constructed. In parallel to the experimental work, the literature review was surveyed with the aim to give a thorough view of the history, fundamentals and all the factors related to LIBS. LIBS is a developing analytical technique, which is used to perform qualitative and semi-quantitative elemental analysis of materials (solid, liquid and gas). The fast data collection and the lack of sample preparation made LIBS be an attractive technique to be used for geological samples. This study was done to improve analytical methods for geochemical analysis of samples during different exploration phases (Mining, filed analysis, etc.), as a real-time analysis method to save money and time spent in labs. For a generation of laser induced plasma, a Q-switched Nd: YAG laser operated at 10 Hz and wavelength of 1064 nm was employed on the surface of the samples. A spectrometer fitted with an intensified charge-coupled device (ICCD) was used to disperse and detect the spectrum; then fed to a computer for recording and further processing of the data. The sample set was compiled from samples collected from different areas (South Africa and Namibia). Using principal component analysis (PCA), it was found that LIBS was able to differentiate between the samples even those of the same area. The results from the LIBS technique were correlated with subsequent analysis of the same samples by Particle-induced X-ray emission (PIXE). The feasibility of relative hardness estimation using LIBS was done by measuring the plasma excitation temperature for different samples. LIBS with its advantages as an elemental analysis technique made it possible to estimate the hardness of geological samples. Based on theory and results, an analytical technique for compositional differentiation and quantification of relative hardness of geological samples is proposed. / National Research Foundation (South Africa) / Physics / M Sc. (Physics)
52

Progress Toward Time-Resolved X-ray Spectroscopy of Metalloproteins

Scott C. Jensen (5929838) 16 January 2019 (has links)
<p>Metalloproteins, or proteins with a metal ion cofactor, are essential for biological function of both lower and higher level organisms. These proteins provide a multitude of functions from molecular transport, such as the hemoglobin transport of oxygen, to biologically important catalytic processes. As an example case, photosystem II (PSII) is studied as a representative metalloprotein. It was chosen based on the potential impact in the energy sector due to its ability to perform water oxidation using solar based energy. Understanding mechanisms by which the Mn<sub>4</sub>Ca cluster inside PSII, also known as the oxygen evolving complex (OEC), can store energy as redox equivalents for splitting water will be essential for future development of analogous artificial systems. By using time resolved x-ray spectroscopy, the electron structure of the metal in the protein was probed through the catalytic cycle. While the applications mentioned herein are based on PSII from spinach, the developments in time-resolved x-ray spectroscopy techniques are also applicable to other metalloproteins.</p><p></p><p>By creating a new x-ray spectrometer we were able to capture the difference in x-ray emission spectra between two compounds differing in a single metal bound ligand, i.e. Mn<sup>IV</sup>-OH and Mn<sup>IV</sup>=O. This both establishes the functionality of the x-ray emission spectrometer and provides useful insight into the expected changes upon an oxygen double bond formation. This change in spectroscopic signal is discussed in context of the OEC which has been hypothesized to form a Mn<sup>IV</sup>=O state.</p><p></p><p>A new sample delivery system and further developments to the x-ray spectrometer enabled both time-resolved x-ray absorption and time-resolved x-ray emission of PSII. These experiments show the potential of synchrotron sources for time-resolved x-ray spectroscopy. From our x-ray absorption measurements we were able to follow the electronic structure changes in time using a single incident photon energy. From the kinetic traces obtained, we show possible alternative interpretations of previous results showing a delay in reduction during the final step in water oxidation. From the x-ray emission spectroscopy (XES) measurements of PSII we were able to reproduce previous results within a limited collection time and give estimates for data size requirements for metalloproteins using this spectrometer. Between the results of both these measurements, we show the improved capability for time resolved measurements at synchrotrons.</p><p>The development of x-ray free electron lasers (XFELs) has also opened many opportunities for understanding faster electronic dynamics by providing femtosecond x-ray pulse durations with ~10<sup>12</sup> photons per pulse. While theoretical modeling of distortions to crystallographic data have been performed, little to no work has been done to understand under what conditions such an intense pulse will have on an impact on emission spectra. Here an atomistic model was developed, and data collected, to clarify the effects of sequential ionization, i.e. two single photons absorbed by the same atom at different times during a single pulse. Experimentally we found that XFELs easily achieve flux densities that invoke a different response than is classically observed for single photon absorption and emission for Mn<sup>II</sup> which was used as a representative case for 3d transition metals in general. We also give parameters by which the onset of this damage can be predicted and an approximation to its effect on 3d transition metals. Additionally this work guides the work of future XFEL facilities as it shows that shorter pulses, currently believed to be able to escape x-ray induced distortions to crystallography data, is not a viable method for overcoming changes in x-ray emission spectra.</p><div><br></div>
53

Angle-Dependent Electron Spectroscopy Studies of C<sub>60</sub> Compounds and Carbon Nanotubes

Schiessling, Joachim January 2003 (has links)
<p>Fullerenes have been shown to constitute a prototypical building block for truly nanometer-sized devices and exotic nanounit-based materials, e.g., high-temperature superconductors. This makes the detailed understanding of fullerene electronic states in compounds and at interfaces of primary importance, since the high symmetry of the molecule greatly </p><p>simplifies the starting point of the analysis. Carbon nanotubes, which combine one macroscopic with two nanoscopic dimensions, are perhaps of even greater practical interest.</p><p>Angle-dependent electron spectroscopies have been employed in the present work to study these materials, characterizing their structure, bonding, and electronic states. For solid C<sub>60</sub>, the photoelectron angular distribution has been found to be essentially that of the free molecule, modified by solid state scattering; a similar distribution is found for K<sub>3</sub>C<sub>60.</sub></p><p>The surface and bulk electronic structure of K<sub>3</sub>C<sub>60</sub> has been identified by angle-dependent core and valence photoelectron spectroscopy (PES) and x-ray emission spectroscopy. An insulating surface layer has been identified for this high-temperature superconductor.</p><p>Angle-dependent valence PES is used to investigate the electronic states of C<sub>60</sub>/Al(110). Electron correlations are found to be the origin of the splitting observed in the molecular orbitals, which is quite sensitive to the molecular orientation. The components of the highest occupied molecular orbital are differentiated according to their overlap with the substrate.</p><p>A rigid shift of valence- and core-levels has been observed even for ionic and covalent C<sub>60 </sub>compounds, reflecting the efficient static polarizability screening of the molecule. </p><p>The alignment of multi-walled carbon nanotubes has been investigated by x-ray absorption spectroscopy, using the spectral intensity ratio of π*- and *-resonances. Core level combined with valence PES shows that the degree of defect structure varies from position to position on the sample. Valence photoelectron spectra of defect-free sample spots closely resembles the total DOS of graphite.</p>
54

Angle-Dependent Electron Spectroscopy Studies of C60 Compounds and Carbon Nanotubes

Schiessling, Joachim January 2003 (has links)
Fullerenes have been shown to constitute a prototypical building block for truly nanometer-sized devices and exotic nanounit-based materials, e.g., high-temperature superconductors. This makes the detailed understanding of fullerene electronic states in compounds and at interfaces of primary importance, since the high symmetry of the molecule greatly simplifies the starting point of the analysis. Carbon nanotubes, which combine one macroscopic with two nanoscopic dimensions, are perhaps of even greater practical interest. Angle-dependent electron spectroscopies have been employed in the present work to study these materials, characterizing their structure, bonding, and electronic states. For solid C60, the photoelectron angular distribution has been found to be essentially that of the free molecule, modified by solid state scattering; a similar distribution is found for K3C60. The surface and bulk electronic structure of K3C60 has been identified by angle-dependent core and valence photoelectron spectroscopy (PES) and x-ray emission spectroscopy. An insulating surface layer has been identified for this high-temperature superconductor. Angle-dependent valence PES is used to investigate the electronic states of C60/Al(110). Electron correlations are found to be the origin of the splitting observed in the molecular orbitals, which is quite sensitive to the molecular orientation. The components of the highest occupied molecular orbital are differentiated according to their overlap with the substrate. A rigid shift of valence- and core-levels has been observed even for ionic and covalent C60 compounds, reflecting the efficient static polarizability screening of the molecule. The alignment of multi-walled carbon nanotubes has been investigated by x-ray absorption spectroscopy, using the spectral intensity ratio of π*- and *-resonances. Core level combined with valence PES shows that the degree of defect structure varies from position to position on the sample. Valence photoelectron spectra of defect-free sample spots closely resembles the total DOS of graphite.
55

Core Level Spectroscopy of Water and Ice

Nordlund, Dennis January 2004 (has links)
A core level spectroscopy study of ice and water is presented in this thesis. Combining a number of experiments and spectrum calculations based on density functional theory, changes in the local valence electronic structure are shown to be sensitive to the local H-bonding configurations. Exploiting this sensitivity, we are able to approach important scientific problems for a number of aggregation states; liquid water, the water-metal interface, bulk and surface of hexagonal ice. For the H-bonded model system hexagonal ice, we have probed the occupied valence electronic structure by x-ray emission and x-ray photoelectron spectroscopy. Stepwise inclusion of different types of interactions within density functional theory, together with a local valence electron population analysis, show that it is essential to include intermolecular charge transfer together with internal s-p rehybridizations in order to describe the changes in electronic structure seen in the experiment. The attractive electrostatic interaction between water molecules is enhanced by a decrease in Pauli repulsion. A simple electrostatic model due to charge induction from the surrounding water is unable to explain the electronic structure changes. By varying the probing depth in x-ray absorption the structure of the bulk, subsurface and surface regions is probed in a thin ice film. A pronounced continuum for fully coordinated species in the bulk is in sharp contrast to the spectrum associated with a broken symmetry at the surface. In particular molecular arrangements of water with one uncoordinated OH group have unoccupied electronic states below the conduction band that are responsible for a strong anisotropic pre-edge intensity in the x-ray absorption spectrum. The topmost layer is dominated by an almost isotropic distribution of these species, which is inconsistent with an unrelaxed surface structure. For liquid water the x-ray absorption spectrum resembles that of the ice surface, indicating a domination of species with broken hydrogen bond configurations. The sensitivity to the local hydrogen bond configuration, in particular the sensitivity to broken bonds on the donor side, allows for a detailed analysis of the liquid water spectrum. Most molecules in liquid water are found in two-hydrogen-bonded configurations with one strong donor and one strong acceptor hydrogen bond. The results, consistent with diffraction data, imply that most molecules are arranged in strongly H-bonded chains or rings embedded in a disordered cluster network. Molecular dynamics simulations are unable to describe the experimental data. The water overlayer on the close-packed platinum surface is studied using a combination of core-level spectroscopy and density functional theory. A new structure for water adsorption on close-packed transition metal surfaces is found, where a weakly corrugated non-dissociated overlayer interacts via alternating oxygen-metal and hydrogen-metal bonds. The latter results from a balance between metal-hydrogen bond formation and OH bond weakening. The ultrashort core-hole lifetime of oxygen provides a powerful probe of excited state dynamics via studies of the non-radiative or radiative decay following x-ray absorption. Electrons excited into the pre-edge state for single donor species at the ice surface remain localized long enough for early time solvation dynamics to occur and these species are suggested as strong pre-existing traps to the hydrated electron. Fully coordinated molecules in the bulk contribute to a strong conduction band with electron transfer times below 0.5 femtoseconds. Upon core-ionization, both protons are found to migrate substantial distances on a femtosecond timescale. This unusually fast proton dynamics for non-resonant excitation is captured both by theory and experiment with a measurable isotope effect.
56

Desenvolvimento de sistemas catalíticos não suportados para células a combustível de membrana polimérica de temperatura elevada de operação / Development of unsupported catalytic systems for high temperature polymeric fuel cell applications

DOUBEK, GUSTAVO 09 October 2014 (has links)
Made available in DSpace on 2014-10-09T12:42:05Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:05:52Z (GMT). No. of bitstreams: 0 / Tese (Doutoramento) / IPEN/T / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP
57

Desenvolvimento de sistemas catalíticos não suportados para células a combustível de membrana polimérica de temperatura elevada de operação / Development of unsupported catalytic systems for high temperature polymeric fuel cell applications

DOUBEK, GUSTAVO 09 October 2014 (has links)
Made available in DSpace on 2014-10-09T12:42:05Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:05:52Z (GMT). No. of bitstreams: 0 / Células a combustível de membrana polimérica têm cada vez mais se destacado como meio na obtenção de energia, pela sua alta eficiência e potencial para fazê-la de modo sustentável. Entretanto muitos ainda são os desafios para consolidá-la comercialmente. Dentre eles, a aglomeração e a perda de área ativa em catalisadores suportados em carbono recebem um destaque especial, principalmente em células PEM de temperatura elevada de operação. Eletrocatalisadores não suportados, baseados em nanoarquiteturas de geometria controlada, têm se tornado uma tendência em diversas frentes de pesquisa. Tal fato se deve à alta eficiência e estabilidade atingidas por sistemas nanométricos organizados, além da possibilidade em se criar superfícies funcionais adaptadas a reações específicas. O trabalho de pesquisa buscou o desenvolvimento de sistemas catalíticos não suportados, de alta área superficial, como alternativa a eletrocatalisadores nanoparticulados suportados em carbono, a fim de se reduzir a perda sobre a área ativa quando submetidos às condições de operação em células a combustível. O trabalho explorou dois conceitos, a confecção de nanotubos de platina e a confecção de nanofios nanoporosos à base de platina vítrea. Para este desenvolvimento foram estudados e caracterizados os efeitos da dissolução seletiva, em escala nanométrica, acoplados à conformabilidade de metais amorfos e à utilização da troca galvânica como ferramenta de síntese de superfícies. Tais estudos foram utilizados como base para o projeto de sistemas catalíticos não suportados. Os materiais propostos foram avaliados quanto a sua atividade e estabilidade frente a reações comuns em células a combustível. Tais sistemas demonstraram uma alta estabilidade em relação à sua área ativa, em ensaios de durabilidade, assim como uma alta utilização do metal nobre, tornando-os promissores para a tecnologia de células a combustível. / Tese (Doutoramento) / IPEN/T / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP
58

Desenvolvimento e aplicação de um simulador pediátrico craniano para dosimetria em tomografia computadorizada / Development and application of a pediatric head phantom for dosimetry in computed tomography

MARTINS, ELAINE W. 26 August 2016 (has links)
Submitted by Marco Antonio Oliveira da Silva (maosilva@ipen.br) on 2016-08-26T10:42:03Z No. of bitstreams: 0 / Made available in DSpace on 2016-08-26T10:42:03Z (GMT). No. of bitstreams: 0 / Para avaliar os níveis de exposição e a dose absorvida em pacientes submetidos a exames de tomografia computadorizada, TC, é necessário calcular os índices de dose em medições com um simulador de PMMA, ou cheio de água. O simulador deve ser capaz de reproduzir as características de absorção e espalhamento do corpo ou parte do corpo humano em um campo de radiação. As grandezas específicas em TC: índice de kerma livre no ar (Ca,100), índice de kerma no ar ponderado (CW), índice de kerma no volume total (Cvol) e produto kerma no ar-comprimento (PKL) devem ser determinadas e comparadas com os níveis de referência já existentes na literatura. Neste trabalho foi desenvolvido um simulador pediátrico craniano, já que no Brasil os níveis de referência para diagnósticos (NRDs) disponíveis foram determinados baseados em um simulador padrão adulto. O simulador desenvolvido inovou em sua construção apresentando materiais que simulam a calota craniana em osso cortical (alumínio) e osso esponjoso (PVC). O seu interior foi preenchido com água destilada. As dimensões foram escolhidas de acordo com as recomendações da Organização Mundial da Saúde e do International Commission on Radiation Units, para o tamanho da cabeça de uma criança de 0 a 5 anos: 160 mm de diâmetro e 155 mm de altura. A calota craniana tem uma espessura de 4 mm e diâmetro interno de 111,9 mm. Para avaliar seu comportamento foram realizados testes em laboratórios e em feixes clínicos. Os resultados apresentaram uma atenuação de até 23% na utilização dos materiais que simulam a calota craniana evidenciando que os valores adotados para os cálculos de NRD podem estar superestimando a dose recebida por pacientes pediátricos. Percebe-se que a dose recebida em exames de crânio apresenta uma distribuição diferente por ser parcialmente atenuada e/ou retroespalhada pela calota craniana, o que não é considerado ao se utilizar o simulador constituído apenas de PMMA. / Tese (Doutorado em Tecnologia Nuclear) / IPEN/T / Instituto de Pesquisas Energéticas e Nucleares - IPEN-CNEN/SP
59

An x-ray spectroscopic study of novel materials for electronic applications

Raekers, Michael 08 June 2009 (has links)
The electronic and magnetic structure of the colossal magneto resistance material La1-xSrxMnO3, the high-k and strain tailoring compounds REScO3 (Sm, Gd, Dy) and the multiferroic LuFe2O4 was investigated by means of x-ray spectroscopic techniques. SQUID measurements of La1-xSrxMnO3 (x = 0.125, 0.17, 0.36) were compared with XMCD results. The very good agreement between these two experiments proofs the applicability of the correction factor for the spin magnetic moment and the importance of charge transfer. The magnetic moment measured by SQUID and that determined from XMCD proofs that the magnetic moment is completely localized at the Mn ions for different temperatures and magnetic fields. For x = 0.125 the orbital magnetic moment determined from XMCD corresponds to the structural changes in the phase diagram. Additionally the measured orbital moments correspond to anomalies in magnetization versus temperature curves. The magnetic and electronic structure of the rare earth scandates (SmScO3, GdScO3 and DyScO3) were investigated by means of XPS, XES, XAS, SQUID and neutron powder diffraction. The magnetic measurements reveal antiferromagnetic coupling at low temperatures in agreement with neutron diffraction data. With XAS and XES at the O K-edge in comparison with band structure calculations of the unoccupied oxygen states, the band gaps of REScO3 were determined and it was found that these values are corresponding to the Sc-O mean distances. The electronic and magnetic structure of LuFe2O4 was presented. The valence state of Fe ions was determined to 50% divalent and 50% trivalent by XPS of Fe 2p and 3s levels. The big orbital magnetic moment found by XMCD could explain a discrepancy between the magnetic measurements and the spin configuration, which was confirmed by XMCD.
60

Growth and Characterization of Wide Band-Gap Group III Oxide Semiconductors by MOCVD

Hernandez, Armando, Jr. January 2021 (has links)
No description available.

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