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21	ETUDE STRUCTURALE ET MORPHOLOGIQUE DE MULTICOUCHES DISCONTINUES METAL-OXYDE Micha, Jean-Sébastien 06 March 2002 (has links) (PDF) Cette étude présente les résultats de caractérisations structurales et morphologiques de multicouches discontinues métal-oxyde, composés d'un empilement de plans de nanoparticules métalliques noyées dans une matrice d'oxyde. L'amplitude de la magnétorésistance tunnel dans ces matériaux dépend de l'organisation du métal à plusieurs échelles. De multiples techniques ont été utilisées afin de sonder l'ordre local structural et magnétique (XAFS, Spectroscopie Mössbauer), l'ordre à moyenne distance (Réflectivité X, GISAXS, MET) et l'ordre à grande distance (Diffraction X). Les données issues de ces différentes techniques sont comparées et confrontées à celles des mesures magnétiques. Trois systèmes ont été étudiés, Fe/ZrO2, Co/ZrO2 et Co/SiO2, en faisant varier l'épaisseur de la couche nominale de métal déposé eM, la température du recuit TR effectué après l'élaboration par pulvérisation cathodique et la vitesse de dépôt des couches. Les ions paramagnétiques mis en évidence en périphérie des nanoparticules ne font pas partie intégrante d'une couche d'un oxyde connu du métal déposé. Ils sont « morts » du point de vue des propriétés magnétiques et électriques. La fraction d'atomes « morts » est plus importante avec la zircone qu'avec la silice et peut être diminuée en augmentant TR, eM et/ou en diminuant la vitesse de dépôt. La valeur de eM correspondant au seuil de percolation dans le plan des couches est déplacée vers les grandes valeurs de eM en augmentant TR. Le mouillage métal-oxyde est important avec la zircone (comparée à la silice) et avec le fer (comparée au cobalt). La morphologie des couches granulaires qui en résulte, notamment la taille des particules, détermine le comportement superparamagnétique ou ferromagnétique des particules. Pour chaque système métal-oxyde, un diagramme schématique (TR, eM) résume les propriétés magnétiques, structurales et morphologiques observées. [PHYS:COND] Physics/Condensed Matter Magnétorésistance tunnel XAFS GISAXS Spectroscopie Mössbauer Fe/ZrO2 Co/ZrO2 Co/SiO2 Multicouches discontinues Structure et Morphologie Nanoparticules forme et taille distribution Superparamagnétisme et ferromagnétisme
22	Sobre a estabilidade de catalisadores de cobalto suportados durante a reforma do etanol Ávila Neto, Cícero Naves de 11 June 2012 (has links) Made available in DSpace on 2016-06-02T19:55:32Z (GMT). No. of bitstreams: 1 4549.pdf: 10506362 bytes, checksum: 622f533bcc042279d1b10154620ecb35 (MD5) Previous issue date: 2012-06-11 / Financiadora de Estudos e Projetos / Cobalt-based catalysts supported on γ-alumina and magnesium aluminate modified with lanthanum and cerium have been applied to various conditions of reforming of ethanol. The initial challenge was to control the rate of carbon accumulation, a major cause of deactivation of catalysts under steam reforming of ethanol. In situ X-ray absorption spectroscopy analyses showed that the rate of carbon accumulation is inversely proportional to the amount of Co2+ species and directly proportional to the amount of Co0 species. X-ray photoelectron spectroscopy analyses showed that, after reducing the catalysts in hydrogen, the oxidized fraction of the particles is mainly on their surface. Both the oxidized and reduced fractions of cobalt crystallites have face-centered cubic structure. The concentration of superficial oxygen under reforming conditions is determined by the curvature of the surface of the particles, the nature of the supports and the presence of promoters such as platinum and copper. The concentration of superficial oxygen is also highly sensitive to reaction conditions such as the composition and amount of oxidizing agents, such as oxygen and water, and reaction temperature. The rate of accumulation of carbon could be controlled with co-feeding oxygen to the reactor, process called oxy-reforming of ethanol, and using ceria as support. However, stability tests showed that catalyst deactivation may also occur by oxidation of metal sites. The ignition of the reforming process takes place in a microregion at the entrance of the catalyst bed where ethanol is fully oxidized, releasing energy and increasing the local temperature. Spatial-resolved X-ray absorption spectroscopy analyses showed that the ratio Co2+/Co0 is much greater than one inside this microregion. The high local temperature and the presence of oxidized species in the entrance of the bed produce the appropriate conditions which lead the Co2+ ions to diffuse into the defect spinel structure of γ-alumina, leading to loss of potentially active sites for reforming of ethanol. This phenomenon is unleashed as a wave that propagates from the entrance of the bed downstream to the regions where Co2+ species exist. However, one can prevent the diffusion of Co2+ species to the structure of γ- alumina using aluminates as supports. / Catalisadores de cobalto suportados em γ-alumina e aluminato de magnésio modificados com lantânio e cério foram aplicados a diferentes condições de reforma do etanol. O desafio inicial foi tentar controlar a taxa de acúmulo de carbono, um dos principais fatores de desativação de catalisadores em condições de reforma a vapor do etanol. Análises de espectroscopia de absorção de raios X in situ comprovaram que a diminuição da taxa de acúmulo de carbono está ligada ao aumento da quantidade de espécies Co2+ em relação à quantidade de espécies Co0 nas partículas de cobalto. Análises de espectroscopia de fotoelétrons excitados por raios X demonstraram que, após redução em hidrogênio, a fração oxidada das partículas encontra-se majoritariamente na superfície das mesmas. Ambas as frações oxidadas e reduzidas das partículas de cobalto apresentam estrutura cúbica de face centrada. A concentração de oxigênio superficial em condições de reforma do etanol é determinada pela curvatura da superfície das partículas, pela natureza dos suportes e pela presença de promotores tais como platina e cobre. A concentração de oxigênio superficial é também fortemente sensível às condições de reação, tais como a composição e quantidade de agentes oxidantes, como a água e o oxigênio, e a temperatura de reação. O acúmulo de carbono pôde ser controlado com a coalimentação de oxigênio ao reator, processo denominado reforma a vapor com coalimentação de oxigênio, e utilizando-se céria como suporte. Entretanto, testes de estabilidade demonstraram que a desativação do catalisador pode também ocorrer por oxidação dos sítios metálicos. A ignição da reforma ocorre em uma microrregião na entrada do leito catalítico onde o etanol é completamente oxidado, liberando energia e aumentando a temperatura local. Análises de espectroscopia de absorção de raios X in situ resolvidas no espaço demonstraram que, nesta microrregião, a razão Co2+/Co0 é muito maior que um. O aumento da temperatura local e a presença de espécies oxidadas na entrada do leito produzem as condições adequadas para que íons Co2+ se difundam na estrutura espinela defeituosa da γ- alumina, levando a perdas de sítios potencialmente ativos para a reforma do etanol. Este fenômeno se deflagra como uma onda de desativação que se propaga da entrada do leito em direção às regiões à jusante onde existem espécies Co2+. Por outro lado, pode-se evitar a difusão de espécies Co2+ na estrutura da γ-alumina utilizando-se aluminatos como suporte. Catálise Produção de hidrogênio Reforma do etano Catalisadores de cobalto Mecanismos de desativação XAS in situ Estabilidade Hydrogen production Ethanol reforming Cobalt-supported catalysts Stability Deactivation mechanisms In situ XAFS ENGENHARIAS::ENGENHARIA QUIMICA
23	Structure Sensitivity in the Subnanometer Regime on Pt and Pd Supported Catalysts Kuo, Chun-Te 29 October 2020 (has links) Single-atom and cluster catalysts have been receiving significant interest due to not only their capability to approach the limit of atom efficiency but also to explore fundamentally unique properties. Supported Pt-group single atoms and clusters catalysts in the subnanometer size regime maximize the metal utilization and were reported to have extraordinary activities and/or selectivities compared with nanoparticles for various reactions including hydrogenation reactions. However, the relationship between metal nuclearity, electronic and their unique catalytic properties are still unclear. Thus, it is crucial to establish their relations for better future catalyst design. Ethylene hydrogenation and acetylene hydrogenation are two important probe reactions with the simplest alkene and alkyne, and they have been broadly studied as the benchmark reactions on the various catalyst systems. However, the catalytic properties and reaction mechanism of those hydrogenation reactions for metal nuclearitiy in the subnanometer regime is still not well understood. In this study, we applied different characterization techniques including x-ray absorption fine structure (XAFS), X-ray diffraction (XRD), X-ray photoelectron spectroscopy(XPS), diffuse reflectance infrared spectroscopy (DRIFTS), calorimetry and high-resolution scanning transmission electron microscopy (STEM) to investigate the structure of Pt/TiO2 and Pd/COF single-atom catalysts and tested their catalytic properties for hydrogenation reactions. In order to develop such relations, we varied the nuclearity of Pt supported on TiO2 from single atoms to subnanometer clusters to larger nanoparticles. For acetylene hydrogenation, Pt in the subnanometer size regime exhibits remarkably high selectivity to ethylene compared to its nanoparticle counterparts. The high selectivity is resulted from the decreased electron density on Pt and destabilization of C2H4, which were rationalized by X-ray photoelectron spectroscopy and calorimetry results. On the other hand, the activity of H2 activation and acetylene hydrogenation decreased as Pt nuclearity decreased. Therefore, our results show there's a trade-off between activity and selectivity for acetylene hydrogenation. Additionally, the kinetics measurements of ethylene hydrogenation and acetylene hydrogenation were performed on Pt/TiO2 catalysts, and they found to be structure sensitive for both reactions, which the reaction orders and activation energy changes as particles size change. The activity of ethylene hydrogenation decreases, and activation energy increase from 43 to 86 kJ/mol, as Pt nuclearity decreased from an average size of 2.1 nm to 0.7 nm and single atoms. The reaction orders in hydrocarbons (ethylene and acetylene) were less negative on subnanometer clusters and single atoms in contract to nanoparticles. The results imply that hydrocarbons, ethylene and acetylene species, do not poison the catalyst on Pt in the subnanometer size regime, and hydrogen activation turn to competitive adsorption path with surface hydrocarbons species. Moreover, single atom Pd supported on imine-linked covalent organic framework was synthesized, characterized by a various of techniques including X-ray photoelectron spectroscopy (XPS), X-ray absorption spectroscopy (XAS), and diffuse reflectance infrared Fourier transform spectroscopy (DRIFTS) of adsorbed CO, and evaluated its catalytic properties for ethylene hydrogenation. The XAS results show that Pd atoms are isolated and stabilized by two covalent Pd–N and Pd-Cl bonds. DRIFTS of CO adsorption shows a sharp symmetrical peak at 2130 cm−1. The Pd single atoms are active for hydrogenation of ethylene to ethane at room temperature. The reaction orders in C2H4 and H2 were 0.0 and 0.5 suggesting that ethylene adsorption is not limiting while hydrogen forms on Pd through dissociative adsorption. / Doctor of Philosophy / More than 90% of chemicals come from petroleum and natural gas, and most of these chemicals are composed of alkene and alkyne, hydrocarbons containing at least one double bonds or triple bonds, such as ethylene, propylene, butenes, butadiene. These small hydrocarbon molecules with carbon-carbon bonds (double or triple) are in great interest of fundamental study and serve as probe units for understanding more complex reactions. Catalysts are materials that can be added to a chemical reaction to accelerate the specific rate of reactions. Most catalysts are supported noble metals thus increase the utilization of metal atoms are important. Decreasing the particle size to increase the metal dispersion is the simple approach to maximize the atom efficiency. However, it is not well understood how do the electronic property and catalytic performance change as particle size decrease. In this work, we focus on the structure sensitivity on catalysts in sub-nanometer region. Supported Pt and Pd catalysts, known to be highly active for hydrogenation reactions, are studied on hydrogenation reactions of acetylene and ethylene, the simplest alkene and alkyne. The Pd and Pt catalysts with particle sizes ranging from single atoms, sub-nanometer clusters and nanoparticles were prepared, characterized and tested for hydrogenation reactions mentioned above. The results show that significantly change in electronic property, catalytic performance (activity and/or selectivity) and reaction kinetics of the catalysts as the particle size changing from nanometer to sub-nanometer region. The fundamental understanding of structure sensitivity on catalysts and their relations between surface structure, electronic property and catalytic performance presented in this work can help the researchers design better catalysts for future work. Single-atom catalysts Subnanometer clusters Hydrogenation Kinetic study Operando characterization X-ray absorption fine structure (XAFS) Calorimetry
24	Structural and Kinetic Study of Low-temperature Oxidation Reactions on Noble Metal Single Atoms and Subnanometer Clusters Lu, Yubing 23 April 2019 (has links) Supported noble metal catalysts make the best utilization of noble metal atoms. Recent advances in nanotechnology have brought many attentions into the rational design of catalysts in the nanometer and subnanometer region. Recent studies showed that catalysts in the subnanometer regime could have extraordinary activity and selectivity. However, the structural performance relationships behind their unique catalytic performances are still unclear. To understand the effect of particle size and shape of noble metals, it is essential to understand the fundamental reaction mechanism. Single atoms catalysts and subnanometer clusters provide a unique opportunity for designing heterogeneous catalysts because of their unique geometric and electronic properties. CO oxidation is one of the important probe reactions. However, the reaction mechanism of noble single atoms is still unclear. Additionally, there is no agreement on whether the activity of supported single atoms is higher or lower than supported nanoparticles. In this study, we applied different operando techniques including x-ray absorption fine structure (XAFS), diffuse reflectance infrared spectroscopy (DRIFTS), with other characterization techniques including calorimetry and high-resolution scanning transmission electron microscopy (STEM) to investigate the active and stable structure of Ir/MgAl2O4 and Pt/CeO2 single-atom catalysts during CO oxidation. With all these characterization techniques, we also performed a kinetic study and first principle calculations to understand the reaction mechanism of single atoms for CO oxidation. For Ir single atoms catalysts, our results indicate that instead of poisoning by CO on Ir nanoparticles, Ir single atoms could adsorb more than one ligand, and the Ir(CO)(O) structure was identified as the most stable structure under reaction condition. Though one CO was strongly adsorbed during the entire reaction cycle, another CO could react with the surface adsorbed O* through an Eley-Rideal reaction mechanism. Ir single atoms also provide an interfacial site for the facile O2 activation between Ir and Al with a low barrier, and therefore O2 activation step is feasible even at room temperature. For Pt single-atom catalysts, our results showed that Pt(O)3(CO) structure is stable in O2 and N2 at 150 °C. However, when dosing CO at 150 °C, one surface O* in Pt(O)3(CO) could react with CO to form CO2, and the reacted O* can be refilled when flowing O2 again at 150 °C. This suggests that an adsorbed CO is present in the entire reaction cycle as a ligand, and another gas phase CO could react with surface O* to form CO2 during low-temperature CO oxidation. Supported single atoms synthesized with conventional methods usually consist of a mixture of single atoms and nanoparticles. It is important to quantify the surface site fraction of single atoms and nanoparticles when studying catalytic performances. Because of the unique reaction mechanism of Ir single atoms and Ir nanoparticles, we showed that kinetic measurements could be applied as a simple and direct method of quantifying surface site fractions. Our kinetic methods could also potentially be applied to quantifying other surface species when their kinetic behaviors are significantly different. We also benchmarked other in-situ and ex-situ methods of quantifying surface site fraction of single atoms and nanoparticles. To bridge the gap between single atoms and nanoparticles and have a better understanding of the effect of nuclearity on CO oxidation, we also studied supported Ir subnanometer clusters with the average size less than 0.7 nm (< 13 atoms) prepared by both inorganic precursor and organometallic complex Ir4(CO)12. Low-temperature CO adsorption indicates that CO and O2/O could co-adsorb on Ir subnanometer clusters, however on larger nanoparticle the particle surface is covered by CO only. Additional co-adsorption of CO and O2 was studied by CO and O2 calorimetry at room temperature. CO oxidation results showed that Ir subnanometer clusters are more active than Ir single atoms and Ir nanoparticles at all conditions, and this could be explained by the competitive adsorption of CO and O2 on subnanometer clusters. / Doctor of Philosophy / CO oxidation is one of the important reactions in catalytic converters. Three-way catalysts, typically supported noble metals, are very efficient at high temperature but could be poisoned by CO at cold start. Better designed catalysts are required to improve the performance of the catalytic converter to lower the emissions of gasoline engines. To reach this goal, more efficient use of the noble metal is required. Single-atom catalysts consist of isolated noble metal atoms supported on different supports, which provide the best utilization of noble metal atoms and provides a new opportunity for a better design of heterogeneous catalysts. The unique electronic and geometric properties of metal single atoms catalysts could lead to a better activity and selectivity. Subnanometer clusters have also been shown to have unique electronic properties. With a better understanding of the structure of supported single atoms and subnanometer clusters, their catalytic performance can be optimized for better catalysts in the catalytic converter and other applications. In this work, we applied in-situ and operando characterization, kinetic studies and first principle calculations aiming to understand the active and stable structure of noble metal single atoms and vi subnanometer clusters under reaction condition, and their reaction mechanisms during CO oxidations. For MgAl₂O₄ supported Ir single atoms, our results suggest that CO could be co-adsorbed with O₂/O under reaction conditions. These multiple ligands adsorption leads to a unique reaction mechanism during CO oxidation. Though one CO was adsorbed during the whole reaction cycle, another gas phase CO could react with the O* species co-adsorbed with CO through an Eley-Rideal mechanism. This suggests that Ir single atoms are no longer poisoned by CO, and on the other hand the O₂ can be activated on an interfacial site with a low reaction barrier. Ir subnanometer clusters showed higher activities than Ir single atoms and nanoparticles. In-situ IR and high energy resolution fluorescence detected – X-ray absorption near edge spectroscopy (HERFD-XANES) showed that CO could co-adsorb with O₂ at room temperature, and this competitive adsorption could explain the high activity during CO oxidation. Supported Ir single atoms and subnanometer clusters are not poisoned by CO and O₂ could be co-adsorbed, this could be potentially applied to solve the poisoning of catalyst in the catalytic converter at cold start temperature. We also performed kinetic study on CeO₂ supported Pt single atoms. Similar behavior was observed, and we showed that the CO and O co-adsorbed complex is stable in O₂ and N₂, but could react in CO. With the understanding of the active structure of noble metal single atoms and the origin of activities, better-designed catalysts can be synthesized to improve the activity and selectivity of low-temperature oxidation reactions. Single-atom catalysts Subnanometer clusters CO oxidation Kinetic study Operando characterization X-ray absorption fine structure (XAFS) Calorimetry
25	Defect-induced local electronic structure modifications within the system SrO - SrTiO3 - TiO2 Zschornak, Matthias 05 August 2015 (has links) (PDF) Owing to their versatile orbital character with both local and highly dispersive degrees of freedom, transition metal oxides span the range of ionic, covalent and metallic bonding. They exhibit a vast diversity of electronic phenomena such as high dielectric, piezoelectric, pyroelectric, ferroelectric, magnetic, multiferroic, catalytic, redox, and superconductive properties. The nature of these properties arises from sensitive details in the electronic structure, e.g. orbital mixing and orbital hybridization, due to non-stoichiometry, atomic displacements, broken symmetries etc., and their coupling with external perturbations. In the work presented here, these variations of the electronic structure of crystals due to structural and electronic defects have been investigated, exemplarily for the quasi-binary system SrO - SrTiO3 - TiO2. A number of binary and ternary structures have been studied, both experimentally as well as by means of electronic modeling. The applied methods comprise Resonant X-ray Scattering techniques like Diffraction Anomalous Fine Structure, Anisotropy of Anomalous Scattering and X-ray Absorption Fine Structure, and simultaneously extensive electronic calculations by means of Density Functional Theory and Finite Difference Method Near-Edge Structure to gain a thorough physical understanding of the underlying processes, interactions and dynamics. It is analyzed in detail how compositional variations, e.g. manifesting as oxygen vacancies or ordered stacking faults, alter the short-range order and affect the electronic structure, and how the severe changes in mechanical, optical, electrical as well as electrochemical properties evolve. Various symmetry-property relations have been concluded and interpreted on the basis of these modifications in electronic structure for the orbital structure in rutile TiO2, for distorted TiO6 octahedra and related switching mechanisms of the Ti valence, for elasticity and resistivity in strontium titanate, and for surface relaxations in Ruddlesden-Popper phases. Highlights of the thesis include in particular the methodical development regarding Resonant X-Ray Diffraction, such as the first use of partially forbidden reflections to get the complete phase information not only of the tensorial structure factor but of each individual atomic scattering tensor for a whole spectrum of energies, as well as the determination of orbital degrees of freedom and details of the partial local density of states from these tensors. On the material side, the most prominent results are the identification of the migration-induced field-stabilized polar phase and the exergonic redox behavior in SrTiO3 caused by defect migration and defect separation. Oxide Perowskite Strukturelle Symmetrie Defekte Elektronische Struktur DFT Resonante Röntgenstreuung REXS RXD DAFS AAS XAFS Migration Elektroformierung oxides perovskites structural symmetry defects electronic structure DFT resonant X-ray scattering REXS RXD DAFS AAS XAFS migration electroformation ddc:530 Strontiumtitanat Elektronenstruktur Gitterbaufehler Röntgenstreuung Dichtefunktionalformalismus
26	Defect-induced local electronic structure modifications within the system SrO - SrTiO3 - TiO2: symmetry and disorder Zschornak, Matthias 08 May 2015 (has links) Owing to their versatile orbital character with both local and highly dispersive degrees of freedom, transition metal oxides span the range of ionic, covalent and metallic bonding. They exhibit a vast diversity of electronic phenomena such as high dielectric, piezoelectric, pyroelectric, ferroelectric, magnetic, multiferroic, catalytic, redox, and superconductive properties. The nature of these properties arises from sensitive details in the electronic structure, e.g. orbital mixing and orbital hybridization, due to non-stoichiometry, atomic displacements, broken symmetries etc., and their coupling with external perturbations. In the work presented here, these variations of the electronic structure of crystals due to structural and electronic defects have been investigated, exemplarily for the quasi-binary system SrO - SrTiO3 - TiO2. A number of binary and ternary structures have been studied, both experimentally as well as by means of electronic modeling. The applied methods comprise Resonant X-ray Scattering techniques like Diffraction Anomalous Fine Structure, Anisotropy of Anomalous Scattering and X-ray Absorption Fine Structure, and simultaneously extensive electronic calculations by means of Density Functional Theory and Finite Difference Method Near-Edge Structure to gain a thorough physical understanding of the underlying processes, interactions and dynamics. It is analyzed in detail how compositional variations, e.g. manifesting as oxygen vacancies or ordered stacking faults, alter the short-range order and affect the electronic structure, and how the severe changes in mechanical, optical, electrical as well as electrochemical properties evolve. Various symmetry-property relations have been concluded and interpreted on the basis of these modifications in electronic structure for the orbital structure in rutile TiO2, for distorted TiO6 octahedra and related switching mechanisms of the Ti valence, for elasticity and resistivity in strontium titanate, and for surface relaxations in Ruddlesden-Popper phases. Highlights of the thesis include in particular the methodical development regarding Resonant X-Ray Diffraction, such as the first use of partially forbidden reflections to get the complete phase information not only of the tensorial structure factor but of each individual atomic scattering tensor for a whole spectrum of energies, as well as the determination of orbital degrees of freedom and details of the partial local density of states from these tensors. On the material side, the most prominent results are the identification of the migration-induced field-stabilized polar phase and the exergonic redox behavior in SrTiO3 caused by defect migration and defect separation. info:eu-repo/classification/ddc/530 ddc:530
27	Estudos estruturais de xerogéis de óxido de níquel. / Structural studies of niquel oxide xerogels. Fischer, Hannes 07 February 2000 (has links) Foram estudadas as características estruturais de xerogéis obtidos pelo método sol-gel a partir de soluções líquidas precursoras compostas de cloreto de níquel (NiCl2), butanol, água e ácido acético, secos em estufa e tratados a diferentes temperaturas entre 150 e 900ºC. Nos tratamentos isotérmicos a essas temperaturas os elementos voláteis se desprendem do material inicial e transformações estruturais acontecem. Analisaram-se os materiais porosos resultantes (xerogéis) mediante técnicas estruturais: espalhamento de raios X a baixo ângulo (SAXS), espectroscopia de absorção de raios X (XANES e XAFS), difração de raios X (XRD) e microscopia eletrônica de varredura. Complementaram-se estes estudos mediante análise química (espectroscopia de infravermelho), térmica (análise térmica diferencial), gravimétrica (perda de massa) e de densidade. Os resultados experimentais demonstraram que a estrutura porosa do material inicial à base de NiCl2 se transforma numa estrutura bifásica, também porosa, composta por uma fase rica em NiCl2 e outra em óxido de níquel (NiO), sendo que a fração de volume ocupada pela fase de NiO no material final aumenta com a temperatura de tratamento térmico. No caso de temperaturas acima de 500ºC, praticamente todo o volume da amostra se transforma e é ocupado pela fase NiO. Mostrou-se que a estrutura porosa presente em todos os materiais, estudada por SAXS, é composta por nanoporos (10-150Å) e mesoporos (maiores que 150Å), sendo que a fração de volume ocupada pelos mesmos depende da temperatura do tratamento térmico. Em particular os nanoporos somente estão presentes nas amostras tratadas abaixo de 500ºC. A ordem local média ao redor dos átomos de Ni, determinada por EXAFS, corresponde ao esperado de sistemas bifásicos cujas frações de volume dependem da temperatura de tratamento, em concordância com os resultados de XRD. Investigaram-se as características dos materiais obtidos após os diferentes tratamentos térmicos em função de diferentes condições de preparação das soluções precursoras. Numa primeira série de experiências, variou-se o conteúdo de ácido acético na solução. Demonstrou-se que maiores concentrações de ácido acético promovem a formação de um material com estrutura mais compacta. Numa segunda série de experiências variou-se o conteúdo de água. Determinou-se que a quantidade de água afeta somente a estrutura dos materiais tratados a temperaturas inferiores à 500ºC. / Structural properties of several xerogels obtained by the sol-gel procedure and heat treated at different temperatures between 150 and 900ºC were studied. The initial systems were dry gels prepared from liquid solutions composed of nickel chloride, buthanol, water and acetic acid. During the different isothermal treatments, volatile species leave the inicial material and structural transformations occur. The resulting porous materials (xerogels) were studied by means of several structural techniques: small angle X ray scattering (SAXS), X ray absorption spectroscopy (XANES and EXAFS), X ray diffraction (XRD) and scanning electron microscopy. These studies were complemented with chemical analysis (infrared spectroscopy), differential thermal analisis, mass loss and density measurements. The experimental results demonstrated that the porous structure of the starting material, based on nickel chloride, transforms in a also porous biphasic structure composed of nickel chloride and nickel oxide, respectively, rich fase. The volume fraction occupied by the nickel oxide rich fase of the final material increases with temperature of heat treatment. For temperatures above 500ºC, practically all the sample volume transforms and is occupied by the NiO phase. It was demonstrated that the porous structure of all materials, studied by SAXS, is composed of nanopores (sizes ranging from 10 to 150Å ) and mesopores (larger than 150Å), their fraction depending on the heat treatment temperature. Particularly, nanopores are only present in samples treated below 500ºC. The average local order close to nickel atoms, determined by EXAFS, corresponds to the expected one for biphasic systems whose volume fractions depend on treatment temperature, in agreement with XRD results. The structural properties of the several materials obtained after different heat treatments were studied as functions of preparation conditions of precursor solutions. In a first series of experiments, acetic acid content in the solution was varied. It was demonstrated that higher acetic acid content promotes the formation of more compact structures. In a second series of experiments, water content was varied. It was concluded that water content only affects the structure of the materials heat treated at temperatures below 500ºC. angle bifásico byphasic drx espalhamento exafs fase lnls níquel oxide óxido phase sas saxs scattering sistema small sol gel sol-gel solution system transição transition X-ray xafs xerogel xrd
28	Estudos estruturais de xerogéis de óxido de níquel. / Structural studies of niquel oxide xerogels. Hannes Fischer 07 February 2000 (has links) Foram estudadas as características estruturais de xerogéis obtidos pelo método sol-gel a partir de soluções líquidas precursoras compostas de cloreto de níquel (NiCl2), butanol, água e ácido acético, secos em estufa e tratados a diferentes temperaturas entre 150 e 900ºC. Nos tratamentos isotérmicos a essas temperaturas os elementos voláteis se desprendem do material inicial e transformações estruturais acontecem. Analisaram-se os materiais porosos resultantes (xerogéis) mediante técnicas estruturais: espalhamento de raios X a baixo ângulo (SAXS), espectroscopia de absorção de raios X (XANES e XAFS), difração de raios X (XRD) e microscopia eletrônica de varredura. Complementaram-se estes estudos mediante análise química (espectroscopia de infravermelho), térmica (análise térmica diferencial), gravimétrica (perda de massa) e de densidade. Os resultados experimentais demonstraram que a estrutura porosa do material inicial à base de NiCl2 se transforma numa estrutura bifásica, também porosa, composta por uma fase rica em NiCl2 e outra em óxido de níquel (NiO), sendo que a fração de volume ocupada pela fase de NiO no material final aumenta com a temperatura de tratamento térmico. No caso de temperaturas acima de 500ºC, praticamente todo o volume da amostra se transforma e é ocupado pela fase NiO. Mostrou-se que a estrutura porosa presente em todos os materiais, estudada por SAXS, é composta por nanoporos (10-150Å) e mesoporos (maiores que 150Å), sendo que a fração de volume ocupada pelos mesmos depende da temperatura do tratamento térmico. Em particular os nanoporos somente estão presentes nas amostras tratadas abaixo de 500ºC. A ordem local média ao redor dos átomos de Ni, determinada por EXAFS, corresponde ao esperado de sistemas bifásicos cujas frações de volume dependem da temperatura de tratamento, em concordância com os resultados de XRD. Investigaram-se as características dos materiais obtidos após os diferentes tratamentos térmicos em função de diferentes condições de preparação das soluções precursoras. Numa primeira série de experiências, variou-se o conteúdo de ácido acético na solução. Demonstrou-se que maiores concentrações de ácido acético promovem a formação de um material com estrutura mais compacta. Numa segunda série de experiências variou-se o conteúdo de água. Determinou-se que a quantidade de água afeta somente a estrutura dos materiais tratados a temperaturas inferiores à 500ºC. / Structural properties of several xerogels obtained by the sol-gel procedure and heat treated at different temperatures between 150 and 900ºC were studied. The initial systems were dry gels prepared from liquid solutions composed of nickel chloride, buthanol, water and acetic acid. During the different isothermal treatments, volatile species leave the inicial material and structural transformations occur. The resulting porous materials (xerogels) were studied by means of several structural techniques: small angle X ray scattering (SAXS), X ray absorption spectroscopy (XANES and EXAFS), X ray diffraction (XRD) and scanning electron microscopy. These studies were complemented with chemical analysis (infrared spectroscopy), differential thermal analisis, mass loss and density measurements. The experimental results demonstrated that the porous structure of the starting material, based on nickel chloride, transforms in a also porous biphasic structure composed of nickel chloride and nickel oxide, respectively, rich fase. The volume fraction occupied by the nickel oxide rich fase of the final material increases with temperature of heat treatment. For temperatures above 500ºC, practically all the sample volume transforms and is occupied by the NiO phase. It was demonstrated that the porous structure of all materials, studied by SAXS, is composed of nanopores (sizes ranging from 10 to 150Å ) and mesopores (larger than 150Å), their fraction depending on the heat treatment temperature. Particularly, nanopores are only present in samples treated below 500ºC. The average local order close to nickel atoms, determined by EXAFS, corresponds to the expected one for biphasic systems whose volume fractions depend on treatment temperature, in agreement with XRD results. The structural properties of the several materials obtained after different heat treatments were studied as functions of preparation conditions of precursor solutions. In a first series of experiments, acetic acid content in the solution was varied. It was demonstrated that higher acetic acid content promotes the formation of more compact structures. In a second series of experiments, water content was varied. It was concluded that water content only affects the structure of the materials heat treated at temperatures below 500ºC. bifásico drx espalhamento exafs fase lnls níquel óxido sas saxs sistema sol gel transição xafs xerogel angle byphasic oxide phase scattering small sol-gel solution system transition X-ray xrd
29	Etude de mousses de verres issus de Tubes à Rayons Cathodiques (TRC) en fin de vie contenant de l'oxyde de plomb : Elaboration, caractérisations physicochimiques et applications. Mear, François 13 December 2004 (has links) (PDF) Ce travail est consacré à la recherche et l'étude d'une filière de valorisation des verres de Tubes à Rayons Cathodiques (TRC) en fin de vie. La présence d'éléments lourds dans la composition de ces verres oblige les fabricants et les distributeurs à les recycler afin d'éviter leur mise en décharge, limitée aux déchets ultimes.<br />La filière la plus prometteuse semble celle du verre expansé, matériau déjà commercialisé et qui permettrait d'écouler la quasi-totalité du gisement. Le verre expansé est obtenu après traitement thermique d'un mélange de poudre de verre de TRC et d'un réducteur qui peut être le nitrure de titane ou le carbure de silicium. La réaction entre le réducteur et l'oxyde de plomb présent dans la matrice donne lieu à un dégagement gazeux à l'origine de la structure cellulaire.<br />Une faible densité justifiée par une forte porosité, autour de 80%, ainsi qu'une distribution de taille d'accès aux pores unique et centrée autour de 0,3 à 0,5 µm suivant le réducteur utilisé ont été obtenues.<br />La présence de plomb métal sous forme de bille en surface de pores a pu être mis en évidence.<br />Les mousses obtenues possèdent une conductivité thermique faible (<0,25 W.m-1.K-1), ce qui les classe dans la catégorie des isolants thermiques tout en possédant des propriétés mécaniques satisfaisantes : contrainte moyenne à la rupture variant de 4 à 250 MPa suivant le procédé de synthèse. Les propriétés d'isolation électrique sont conservées. <br />L'ensemble de ces propriétés permet d'envisager des applications industrielles comme la réalisation de panneau d'isolation, en accord avec les réglementations environnementales. <br />Une dépollution partielle du matériau par extraction mécanique des billes de plomb formées après traitement thermique est par ailleurs envisageable. [CHIM:OTHE] Chemical Sciences/Other Mousse de verre Tube à Rayon Cathodique (TRC) Verre de cône Eléments lourds Plomb Porosité Nitrure de titane Carbure de silicium Diffraction des rayons X Structure cellulaire Spectroscopie d'Absorption X (XAFS) Propriétés mécaniques

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