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101	An investigation of some magnetic oxides grown by pulsed laser deposition Sena, S. P. January 1998 (has links) No description available. 530.41
102	Etude de la structure électronique des films minces de magnétite Fe304 (001)/MgO par photoémission résolue en angle / Electronic structure studies of magnetite thin films Fe3O4 (001)/MgO using angle resolved photoemission Sabra, Maher 13 July 2011 (has links) La thèse présente l'élaboration et l'étude des films minces (35 nm) cristallins et stœchiométriques de la magnétite Fe304(001)/MgO. La qualité de ces films est étudiée par différentes techniques (DEL, XPS, XMCD, Effet Kerr, Auger). Nous supposons que les films se recouvrent partiellement, même sous ultra vide, par de Fe2O3. Pour la première fois, l'étude de la structure électronique de la bande t2g de ces films est réalisée par photoémission résolue en angle (ARPES)à température ambiante et à 75 K, en utilisant des photons à basses énergies (6eV - 21 eV). Nous avons constaté que le signal de la photoémission est composé des états électroniques de deux périodicités liées à la zone de Brillouin primitive de la surface (a=4.2 Å) et à la zone de Brillouin de la reconstruction de la surface (a=8.4 Å). Nous pensons que la présence des états liés à la reconstruction sont probablement responsables de la chute de la densité d'état à EF. Une signature de Verwey est observée par ARPES à basse température. Nous estimons que la réalisation des films ultra minces de magnétite est difficilement aboutie. / With its half-metallic behavior predicted theoretically, the magnetic oxideFe3O4 (TC = 863 K) is promising for applications in spintronics as thin films.High quality films and the electronic band structure are still a challenge to faceexperimentally. We managed to develop single crystalline Fe3O4(0 0 1) films(35 nm) on MgO. Analysis by XPS, XAS and XMCD allowed to characterizethe quality of the films prepared. The magnetic study shows a perfect XMCDsignal and a form magnetic anisotropy which lays down the axis of easy magnetizationin the film plane. Our samples are stable during the photoemissionmeasurements. The photoemission measurements of the t2g band show thatthe electronic bands cannot be described by a DFT calculation. Indeed, spinpolarons due to strong electron-phonon coupling mechanism are involved inthe electronic transport. Angle-resolved photoemission shows a dispersion ofthe t2g band in the ��M direction corresponding to two periodicities [the unitcell of the surface reconstruction a = 8,4 Å (30% of the signal) and the simpleunit cell of the surface a = 4;2 Å]. At a temperature T < TV (TV = 120 K,Verwey temperature), the angle-resolved photoemission shows the opening ofa 100 meV band gap, with a rigid shift of the spectral weight of the t2g bandto the high binding energy side. Magnétite Demi métal Photoémission Film mince Structure spinele Magnetite Half metal Photoemission Thin film Spinel structure
103	Magnetite as an indicator mineral in till: a test using the Mount Polley porphyry Cu-Au deposit, British Columbia Pisiak, Laura 23 December 2015 (has links) In the Canadian Cordillera, Mesozoic calcalkaline and alkaline intrusive igneous rocks that are prospective for hosting porphyry Cu-Au mineralization may be overlain by thick glacial overburden. Previous studies have shown that magnetite from ore deposits has a unique trace element signature that differs from magnetite in common igneous or metamorphic rocks. This study investigated if the composition of ore-related magnetite in till could provide a unique exploration tool to locate porphyry deposits in glaciated terrain. Bulk till samples were collected over an area of ~700 km2 surrounding the Mount Polley porphyry Cu-Au deposit, south-central British Columbia. Twenty elements were measured by LA-ICP-MS in ~50 detrital magnetite grains in each of 20 till samples. Previously proposed discrimination diagrams are proven to be of limited use in correctly identifying ore-related magnetite. Therefore, linear discriminant analysis (LDA) was performed on a compiled dataset of magnetite compositions from various porphyry deposits and intrusive igneous rocks in order to rigorously redefine the chemical signature of hydrothermal magnetite from porphyry systems. Application of the LDA models to magnetite in till found that the dispersal of hydrothermal grains from Mount Polley is coincident with the deposit and the interpreted ice-flow history. Anomalous concentrations of hydrothermal magnetite grains in till are detected up to 2.5 km west-southwest and 4 km northwest of the deposit, indicating that magnetite has a strong potential to be an effective indicator in mineral exploration for porphyry systems. / Graduate magnetite mineral chemistry hydrothermal porphyry indicator mineral exploration till provenance discriminant analysis Mount Polley
104	GRAPHENE-BASED SEMICONDUCTOR AND METALLIC NANOSTRUCTURED MATERIALS Zedan, Abdallah 12 April 2013 (has links) Exciting periods of scientific research are often associated with discoveries of novel materials. Such period was brought about by the successful preparation of graphene which is a 2D allotrope of carbon with remarkable electronic, optical and mechanical properties. Functional graphene-based nanocomposites have great promise for applications in various fields such as energy conversion, opteoelectronics, solar cells, sensing, catalysis and biomedicine. Herein, microwave and laser-assisted synthetic approaches were developed for decorating graphene with various semiconductor, metallic or magnetic nanostructures of controlled size and shape. We developed a scalable microwave irradiation method for the synthesis of graphene decorated with CdSe nanocrystals of controlled size, shape and crystalline structure. The efficient quenching of photoluminescence from the CdSe nanocrystals by graphene has been explored. The results provide a new approach for exploring the size-tunable optical properties of CdSe nanocrystals supported on graphene which could have important implications for energy conversion applications. We also extended this approach to the synthesis of Au-ceria-graphene nanocomposites. The synthesis is facilely conducted at mild conditions using ethylenediamine as a solvent. Results reveal significant CO conversion percentages between 60-70% at ambient temperatures. Au nanostructures have received significant attention because of the feasibility to tune their optical properties by changing size or shape. The coupling of the photothermal effects of these Au nanostructures of controlled size and shape with GO nanosheets dispersed in water is demonstrated. Our results indicate that the enhanced photothermal energy conversion of the Au-GO suspensions could to lead to a remarkable increase in the heating efficiency of the laser-induced melting and size reduction of Au nanostructures. The Au-graphene nanocomposites are potential materials for photothermolysis, thermochemical and thermomechanical applications. We developed a facile method for decorating graphene with magnetite nanocrystals of various shapes (namely, spheres, cubes and prisms) by the microwave-assisted-reduction of iron acetylacetonate in benzyl ether. The shape control was achieved by tuning the mole ratio between the oleic acid and the oleyamine. The structural, morphological and physical properties of graphene-based nanocomposites described herein were studied using standard characterization tools such as TEM, SEM, UV-Vis and PL spectroscopy, powder X-ray diffraction, XPS and Raman spectroscopy. Graphene quantum dots metallic nanoparticles laser synthesis shape control magnetite nanocrystals Chemistry Physical Sciences and Mathematics
105	Structure électronique et magnétique des oxydes de métaux de transition : le cas de Fe3O4 / Electronic structure and magnetism of transition metal oxides : the case of Fe3O4 Wang, Weimin 28 September 2012 (has links) La magnétite (Fe3O4) est un candidat prometteur pour des applications dans des dispositifs en spintronique. Ce ferrimagnétique avec une température de Curie élevée a été théoriquement prévu pour être un demi-métal avec un canal conducteur pour les spins minoritaire et un semi-conducteur pour les spins majoritaires, résultant en 100% de polarisation en spin au niveau de Fermi. Cependant, jusqu'à présent, aucune preuve expérimentale claire sur ce sujet n'a été faite. Cette thèse présente des études en photoémission résolue en angle et en spin sur la structure électronique et magnétique de couches minces de Fe3O4 (001) épitaxiées sur MgO(001) . Un calcul de la structure de bande utilisant l'approximation du gradient généralisé (GGA + U) est proposé pour expliquer les résultats expérimentaux. Bien que l'intensité de photémission au niveau de Fermi soit très faible en raison du rôle joué par les polarons, une dispersion de la bande Fe 3d-t2g est observée. Le comportement global de cette bande est en bon accord avec le calcul de la structure état électronique représentant état fondamental. Pour simuler les spectres de photoémission, nous avons utilisé l'approximation de l'électron libre à l'état final, tout en ignorant les éléments de matrice de la transition électronique. Dans la simulation, les bandes calculées sont convoluées respectivement par la lorentzienne et la gaussien pour tenir compte de la durée de vie et des effets de couplage électron-phonon. En intégrant l'intensité spectrale sur un intervalle d'énergie de 100 MeV au niveau de Fermi, nous avons obtenu la première preuve expérimentale de la surface de Fermi. Détermination de la polarisation de spin des électrons est un test ultime des calculs de bandes et des spectres de photoémission modélisés. Dans nos expériences de photoémission résolue en spin, nous avons utilisé des photons de 4.65 et 6.20 eV. Le même échantillon comme pour la photoémission intégré en spin a été mesuré, nécessitant son transfert par l'air dans une autre chambre. L'échantillons n'a pas été soumis à un nettoyage avant les mesures résolues en spin ce a conduit à une réduction de la polarisation en spin à cause de la présence d'une couche polluée sur la surface. Néanmoins, une polarisation de spin de - 50% et -72 % a été mesurée au voisinage de EF respectivement pour les photons de 6.20 et de 4.65 eV. Nous en concluons que Fe3O4 peuvent être décrits par un modèle de bande et en particulier qu'il est demi-métallique. Nous avons également utilisé des impulsions femtoseconde laser dans une expérience pompe-sonde pour étudier la dynamique ultra-rapide à l'échelle atomique. Nos résultats montrent que la durée de vie des électrons excités dans Fe3O4 est beaucoup plus longue que dans un métal «ordinaire». L'analyse de la polarisation en spin des électrons excités montre que la désaimantation ne se produit pas dans le domaine de la femtoseconde, ce qui est compatible avec des propriétés demi-métalliques de la magnétite . / Magnetite (Fe3O4) is a promising candidate for application in spintronic devices. This ferrimagnet with a high Curie temperature has been theoretically predicted to be a half-metal with a conductive minority-spin (↓) channel and a semiconductive majority-spin (↑) channel, resulting in 100 % spin polarization at the Fermi level. But up to now, any clear experimental evidence is lacking. This thesis presents spin- and angle-resolved photoemission studies on the magnetic and electronic structure of Fe3O4 (001) epitaxially grown on MgO (001). A band structure calculation using generalized gradient approximation plus U (GGA+U) to the density functional theory (DFT) is proposed to explain the experimental results. Although the PES intensity at Fermi level is very low because of the role played by polarons, a dispersion of the Fe 3d-t2g states is observed. The overall behaviour of these bands is in good agreement with the calculation of ground state electronic structure. In order to simulate the spectra, we used the free electron approximation for the final states, ignoring the matrix elements. Calculated ground state data are convoluted by Lorentzian and Gaussian functions to account for the lifetime and electron-phonon coupling effects, respectively. By integrating the spectral intensity over an energy interval of 100meV at Fermi level, we obtained the first experimental evidence of the Fermi surface plot. Determination of electron spin polarization is an ultimate test of both the band calculations and our model of Fe3O4 photoemission spectra. In our spin-resolved photoemission experiments 4.65 and 6.20 eV photons were used. The same sample was used as for spin-integrated ARPES, requiring its transfer through air to another chamber. It was not subject to any cleaning prior to the SRPES measurements that lead to a reduction of the spin polarization as a consequence of the presence of a dead layer on the surface. Nevertheless the spin polarization close to EF reaches - 50% and -72% for 6.20 and 4.65 eV photons respectively. We conclude that Fe3O4 can be described within a band model and in particular that it is half-metallic. We also used femtosecond laser pulses in pump-probe experiments to investigate ultrafast dynamics on atomic scale. Our results show that the lifetime of excited electrons in Fe3O4 is much longer than in an “ordinary” metal. From the spin analysis of excited electrons, we deduce that the demagnetization does not occur in the femtosecond range, which is compatible with half-metallic properties of magnetite.</dcterms:abstract> <dc:type xsi:type="dcterms:DCMIType" Demi-métal Magnétite Photoémission Polarisation de spin Half-metal Magnetite Photoemission Spin polarization
106	Nanopartículas multifuncionais dispersáveis e suas potenciais aplicações em nanomedicina / Dispersable Multifunctional Nanoparticles and Their Potential Aplications in Nanomedicine Cardoso, Roberta Mansini 27 June 2018 (has links) O design de materiais na escala nanométrica está levando a sistemas com novas propriedades e aplicações as mais diversas, como em sistemas de diagnóstico e de tratamento inteligentes e sustentáveis. Melhorar a eficiência dos tratamentos de doenças através do desenvolvimento de fármacos mais eficientes e com menos efeitos colaterais, e agentes de contraste e de diagnóstico mais específicos e sensíveis para monitoramento preventivo precoce, é um dos principais objetivos da Nanomedicina. Todavia, a química de superfície necessária para realizar tais reações de funcionalização/conjugação de moléculas ainda está longe de ser adequadamente controlada, particularmente considerando-se a complexidade das biomoléculas e a estabilidade coloidal. Assim, nesta tese foram desenvolvidos processos de conjugação de nanopartículas de óxido de ferro (SPIONs) com um ou mais agentes co-funcionalizantes, gerando partículas mono, bi e multifuncionalizadas dispersáveis em meio aquoso. Os esforços foram concentrados no desenvolvimento de sistemas de diagnóstico e de entrega de fármacos baseados em nanopartículas, cujas propriedades precisam ser ajustadas pela conjugação de biomoléculas e espécies bioativas em sua superfície, num verdadeiro trabalho de engenharia a nível nanométrico/molecular. De fato, nanopartículas modificadas com moléculas co-funcionalizantes estabilizantes (glicerol-fosfato, glicose-fosfato, fosforiletanolamina, dopamina e tiron), agentes de vetorização que direcionam o nanoconjugado a células-alvo tumorais (ácido fólico e biotina), bem como com fármacos como metotrexato e ibuprofeno foram preparadas, e o efeito das mesmas sobre a eficiência de incorporação por células tumorais (HeLa e MCF-7) estudada. Os estudos de atividade biológica in vitro foram realizados em parceria com o Laboratório de Processos Fotoinduzidos e Interfaces (LPFI-IQUSP). Os resultadosobtidos confirmaram a possibilidade de se controlar a atividade biológica das nanopartículas por meio dos agentes funcionalizantes, abrindo perspectivas interessantes para o desenvolvimento de nanoagentes multifuncionais para teranóstica, conjugados com agentes de vetorização específicos (particularmente anticorpos e aptâmeros), além de agentes de contraste (radiofármacos, fluoróforos, contraste para IRM, etc.) e moléculas terapêuticas (antitumorais, anti-inflamatórios, dentre outros). Entretanto, diversos são os problemas associados aos processos químicos envolvendo a produção e funcionalização desses nanomateriais por processos convencionais em batelada, que tendem a ser demorados e apresentam dificuldade de controle dos parâmetros de reação e baixa reprodutibilidade, dificultando o escalonamento produtivo e a comercialização dos eventuais produtos. Uma estratégia promissora é o uso de reatores microfluídicos com projeto de canais adequado, além de atuadores e sensores que, juntos garantam excelente controle de processos e baixo consumo de energia e de reagentes. Assim, também foram desenvolvidos reatores microfluídicos para produção e funcionalização de nanopartículas de ouro, de forma a tornar os processos químicos programáveis, mais eficientes, controláveis e econômicos, em parceria com o Laboratório de Micromanufatura do Instituto de Pesquisas Tecnológicas (LMI-BIONANO/IPT). Essa parte do desenvolvimento foi realizando empregando a tecnologia de microfabricação em Low Temperature Co-fired Ceramics (LTCC), uma tecnologia versátil que possibilita a produção de dispositivos de diferentes geometrias em materiais cerâmicos de baixa reatividade e de baixo custo. Esses dispositivos podem tornar os processos de produção de nanopartículas multifuncionais dispersáveis suficientemente simples, versáteis e reprodutíveis para atender aos altos padrões de qualidade exigidos para produtos voltados para aplicações biomédicas / Materials design at nanoscale is leading us to intelligent systems with new properties and applications, such as more efficient diagnostic and treatment systems. Improving the treatment of diseases by the development of more specific and efficient drugs, displaying fewer or no side effects, conjugated with sensitive contrast/diagnostic agents for early preventive monitoring and treatment is one of the main goals of the Nanomedicine. However, the knowledge on surface chemistry required to perform such molecular functionalization/conjugation reactions still is far from being adequately controlled, particularly considering the complexity of biomolecules and reaching colloidal stability. Thus, in this thesis, processes of conjugation of iron oxide nanoparticles (SPIONs) with one or more co-functionalizing agents have been developed so as to generate mono, bi and multi-particles dispersible in aqueous medium. Efforts were specifically focused on the development of drug delivery and diagnostic systems based on nanoparticles whose properties must be adjusted by the conjugation of biomolecules and bioactive species on their surface, in a truly nano/molecular scale engineering work. In fact, nanoparticles modified with stabilizing co-functionalizing molecules (glycerolphosphate, glucose-phosphate, phosphorylethanolamine, dopamine and tiron), targeting agents (folic acid and biotin) to guide itself and concentrate in specific tumor cells, as well as with drugs such as methotrexate and ibuprofen were prepared, and their effect on the efficiency of uptake by tumor cells (HeLa and MCF-7) studied. In vitro biological activity studies were performed in collaboration with the Laboratory of Photo Induced Processes and Interfaces (LPFI-IQUSP). The results confirmed the possibility of controlling the biological activity of nanoparticles by anchoring suitable functionalizing agents in an additive way, opening interesting new perspectives for the development ofmultifunctional theranostics nanoagents, conjugated with specific vectorization agents (particularly antibodies and aptamers), as well as diagnostic (radiopharmaceuticals, fluorophores, MRI contrast, etc.) and therapeutic agents (antitumor, anti-inflammatory, among others). However, there are several problems associated with the production and functionalization of these nanomaterials by conventional batch processes, which tend to be time consuming and difficult to control, as confirmed by their low reproducibility, making it difficult to produce and commercialize the eventual products. A promising strategy is the use of microfluidic reactors with suitable channel designs, as well as actuators and sensors that, together, ensure excellent process control and low energy and reagent consumption. Thus, microfluidic reactors were also developed for the production and functionalization of gold nanoparticles in order to make chemical processes more predictable, efficient, controllable and economical, in partnership with the Micromanufacturing Laboratory of the Institute of Technological Research (LMI-BIONANO/IPT). This part of the development was accomplished by employing the Low Temperature Co-fired Ceramics (LTCC) microfabrication technology, a versatile technology that enables the production of devices of different geometries in ceramic materials of low reactivity and of low cost. These devices can make the production processes of dispersible multifunctional nanoparticles simple, versatile and reproducible enough to meet the high standards of quality required for products for biomedical applications LTCC LTCC Magnetita Magnetite Microfluidic reactor Nanomedicina Nanomedicine Nanoparticles Nanopartículas Química de superfície Reator microfluídico Surface chemistry
107	Estudo do comportamento magnético de nanopartículas de magnetita e nanofios de níquel diluídos em cristais líquidos liotrópicos / Study on the magnetic behavior of magnetite nanoparticles and nickel nanowires diluted in nematic fluids Arantes, Fabiana Rodrigues 20 May 2010 (has links) Neste trabalho foi feito um estudo do comportamento magnético de cristais líquidos liotrópicos de laurato de potássio dopados com nanopartículas de magnetita. Medidas zero-field cooling (ZFC) e field cooling (FC) com campos de 50 Oe mostram que as nanopartículas magnéticas permanecem bloqueadas a temperatura ambiente devido à presença das micelas do cristal, e apresentam um comportamento superparamagnético quando dispersas somente em água. Simulações Monte Carlo indicam que o aumento da temperatura de bloqueio das nanopartículas imersas em cristais líquidos liotrópicos pode ser obtido considerando uma forte interação, similar à de troca, entre os momentos superficiais e uma camada extra, simulando a presença das micelas. Medidas ZFC-FC e de suscetibilidade magnética permitiram determinar as temperaturas de transição entre as fases micelar isotrópica e nemática discótica. A curva de magnetização na região da fase discótica parece seguir o mesmo comportamento do parâmetro de ordem desta fase. Foram obtidos nanofios de níquel pelo processo de eletrodeposição AC em lâminas de alumina porosas para dopar cristais líquidos liotrópicos na fase isotrópica. As medidas ZFC-FC desses sistemas foram mais delicadas que as das nanopartículas devido ao baixo sinal das amostras e baixa solubilidade dos nanofios no cristal líquido. A técnica para a dissolução dos fios e dopagem dos cristais foi aprimorada, no entanto são necessários mais estudos para melhorar a estabilidade dessas amostras. / In this work we studied the magnetic behavior of potassium laurate lyotropic liquid crystals doped with magnetite nanoparticles. Zero-field cooling (ZFC) and field-cooling (FC) measurements with 50 Oe applied field showed a blocking behavior of magnetic nanoparticles at room temperature due to the micelle presence, while presenting superparamagnetic behavior when dispersed in water. Monte Carlo simulations suggest that this increase in the nanoparticles\' blocking temperature when immersed in lyotropic liquid crystals can be acquired taking into account an exchange-like strong interaction between the nanoparticles\' superficial magnetic moments and an extra layer playing the role of the micelles. ZFC-FC and magnetic susceptibility measures allowed us to find the transition temperatures between the isotropic micellar and the discotic nematic phases. The magnetization curve in the discotic phase resembles the behavior of the order parameter in that phase. We obtained nickel nanowires by AC electrodeposition in anodic porous alumina to dope lyotropic liquid crystals in the isotropic phase. The ZFC-FC measurements in those systems were more intricate given the weak magnetization of the samples and low solubility of the nanowires in the liquid crystal. We refined the technique for dissolution and doping of the crystals, but more studies are needed in order to improve the samples\' stability. cristais líquidos liotrópicos liquid crystals magnetita magnetite nanofios nanoparticles nanopartículas nanowires nickel níquel superparamagnetism superparamagnetismo
108	Síntese de nanopartículas magnéticas com elevada magnetização de saturação e estabilidade química / Synthesis of magnetic nanoparticles with high saturation magnetization and chemical stability Martinêz, Gustavo Adolfo Lopez 23 July 2013 (has links) Atualmente, o desenvolvimento de nanopartículas (NPs) magnéticas vem recebendo muito interesse da comunidade científica, devido à versatilidade de aplicações, principalmente em biomedicina como diagnóstico e terapia. Para tais aplicações e desejável que as NPs apresentem comportamento superparamagnético e alta magnetização de saturação (Ms). Neste contexto, existe preferência pela utilização de NPs de óxidos de ferro (maghemita e magnetita), devido à baixa toxicidade destes, quando comparadas com as NPs metálicas. No entanto, esses materiais apresentam baixo valor de Ms, o que pelo menos limita suas aplicações. Assim, no presente trabalho foi estudados diversos métodos de obtenção de NPs magnéticas com alto valores de Ms. Desta forma, neste trabalho foram obtidas nanopartículas de carbeto de ferro com alta magnetização de saturação (Ms ≈ 121 emu g-1) via processo de decomposição térmica e com tamanho em torno de 9 nm. Ainda, na tentativa de se obter NPs de ferro metálico, foram modificados diferentes parâmetros de síntese (temperatura de reação, tempo de reação, surfactantes), ocorrendo na formação de NPs de óxido de ferro na fase magnetita com tamanho em torno de 7,5 nm e comportamento magnético das nanopartículas próximo ao superparamagnético com Ms ≈ 40 emu g-1. Apesar de não ter sido possível verificar a formação de ferro metálico, os materiais obtidos, principalmente o carbeto de ferro, se mostraram promissores para a aplicação em biomedicina. / Magnetic nanoparticles have received great attention, due to their several applications possibilities such as diagnostic and therapy in biomedicine. For these applications are required nanoparticles with superparamagnetic behavior and high saturation magnetization (Ms). In this context, iron oxides (magnetite and maghemite) have been used because of lower toxicity than metallic nanoparticles. However, these materials show lower Ms than metallic magnetic nanoparticles that affect these applications. In this way, we studied several synthetic routes in order to high Ms values. Thereby, we obtained iron carbide nanoparticles with high magnetization (Ms = 121 emu.g-1) and controlled size (around 9 nm) using thermal decomposition process. Furthermore, in order to obtain metallic iron nanoparticles, magnetite nanoparticles were obtained with controlled size around 7,5 nm and superparamagnetic behavior with Ms = 40 emu.g-1. Besides metallic iron nanoparticles have not been obtained, iron carbide nanoparticles showed high magnetization and show promising for biomedical applications. iron carbide nanoparticles magnetite nanoparticles magnetização de saturação nanopartículas de carbeto de ferro nanopartículas de magnetita saturation magnetization
109	Tratamento de efluente contendo urânio com zeólita magnética / Treatment of effluent containing uranium with magnetic zeolite Craesmeyer, Gabriel Ramos 30 October 2013 (has links) No presente estudo obteve-se com sucesso o compósito zeólita:magnetita usando-se como material de partida sulfato ferroso para síntese da magnetita e cinzas leves de carvão para síntese da fase zeolítica. A zeólita foi sintetizada por tratamento hidrotérmico alcalino e as nanopartículas de magnetita foram obtidas pela precipitação de íons Fe2+ em uma solução alcalina. Uma reprodutibilidade foi alcançada na preparação de diferentes amostras do nanocompósito zeolítico. O material foi caracterizado pelas técnicas de espectrometria de Infravermelho, difratometria de raios-X de pó, fluorescência de raios-X, microscopia eletrônica de varredura com a técnica de EDS, massa especifícia e área específica e por outras propriedades físico-químicas. O compósito era constituído pelas fases zeolíticas hidroxisodalita e NaP1, magnetita, quartzo e mulita das cinzas remanescentes do tratamento alcalino e magnetita incorporada na sua estrutura. A capacidade de remoção de U(VI) de soluções aquosas sobre o compósito zeólita:magnetita foi avaliada pela técnica descontínua. Os efeitos do tempo de contato e da concentração inicial do adsorbato sobre a adsorção foram avaliados. Determinou-se o tempo de equilíbrio do sistema e foram avaliados os modelos cinéticos de pseudo-primeira ordem, pseudo-segunda ordem e o modelo de difusão intrapartícula. Um tempo de contato de 120 min foi suficiente para a adsorção do íon uranilo alcançar o equilíbrio. A velocidade de adsorção seguiu o modelo cinético de pseudo-segunda-ordem, sendo que a difusão intrapartícula não era a etapa determinante do processo. Dois modelos de isotermas de adsorção, os modelos de Langmuir e de Freundlich, também foram avaliados. O modelo de Langmuir foi o que melhor se ajustou aos dados experimentais. A partir do modelo cinético e da isoterma que melhor descreveram o comportamento do sistema foi possível calcular os valores teóricos para a capacidade máxima de adsorção do U(VI) sobre o compósito zeólita:magnetita. As capacidades máximas de remoção calculadas foram de 20,7 mg.g-1 pela isoterma de Langmuir e de 23,4 mg.g-1 pelo modelo cinético de pseudo-segunda ordem. O valor experimental obtido foi 23,3 mg.g-1. / Within this work, a magnetic-zeolite composite was successfully synthesized using ferrous sulfate as raw material for the magnetic part of the composite, magnetite, and coal fly ash as raw material for the zeolitic phase. The synthesis of the zeolitic phase was made by alkali hydrothermal treatment and the magnetite nanoparticles were obtained through Fe2+ precipitation on alkali medium. The synthetic process was repeated many times and showed good reproducibility comparing the zeolitic nanocomposite from different batches. The final product was characterized using infrared spectroscopy, powder X-ray difraction, X-ray fluorescence, scanning electron microscopy with coupled EDS. Specific mass, specific surface area and other physicochemical proprieties. The main crystaline phases found in the final product were magnetite, zeolites types NaP1 and hydroxysodalite, quartz and mulite, those last two remaing from the raw materials. Uranium removal capacity of the magnetic zeolite composite was tested using bathc techniques. The effects of contact time and initial concentration of the adsorbate over the adsorption process were evaluated. Equilibrium time was resolved and the following kinectics and difusion models were evaluated: pseudo-first order kinectic model, pseudo-second order kinectic model and intraparticule difusion model. A contact time of 120 min turned out to be enough to reach equilibrium of the adsorption process. The rate of adsorption followed the pseudo-second order model and the intraparticle diffusion didnt turned out to be a speed determinant step. Two adsorption isotherms models, the Langmuir model and the Freundlich model, were also evaluated. The Langmuir model was the best fit for the obtained experimental data. Using the best fitted adsorption isotherm and kinectic model, the theorical maximum adsorption capacity of uranium over the composite was determined for both models. The maximum removal capacity calculated was 20.7 mg.g-1 for the Langmuir isotherm and 23.4 mg.g-1 for the pseudo-second order model. The experimental value attained was 23,3 mg.g-1. adsorção adsorption cinza leve de carvão coal fly ash magnetita magnetite urânio uranium zeólita zeolite
110	Estudo da magnetita como material adsorvedor de íons uranilo / Study of magnetite as adsorbent material of uranyl ions Leal, Roberto 24 March 2006 (has links) A magnetita, também chamada de ferrita de ferro, é um minério conhecido como imã natural e encontrada em depósitos de ferro. Além desse comportamento intrínseco, a magnetita possui a capacidade de remover os íons metálicos do meio aquoso por fenômenos de adsorção. O seu caráter fortemente magnético a distingue de outros tipos de adsorventes, visto que, é facilmente removida da solução por separação magnética. Neste trabalho estudou-se a adsorção de urânio(VI), na forma de íons UO22+, de solução nítrica pela magnetita sintética. Esta foi preparada por precipitação simultânea adicionando-se uma solução de NaOH à solução contendo os íons Fe2+ e Fe3+. A magnetita sintética, na forma de um pó preto, exibiu uma resposta magnética de atração intensa na presença de um campo magnético, sem contudo tornar-se magnética, um comportamento típico de material superparamagnético constatado por medidas de magnetização. Estudou-se a influência dos parâmetros de adsorção de íons UO22+ tais como o pH, a dose do adsorvente, tempo de contato e a isoterma de equilíbrio. A máxima adsorção de urânio foi encontrada no intervalo de pH entre 4 e 5. Verificou-se que quanto maior a dose de magnetita menor a capacidade de adsorção e maior a remoção de U. Da relação entre adsorção e tempo de contato verificou-se que a remoção aumentou rapidamente com o tempo e atingiu-se a condição de equilíbrio em 30 min. Os resultados da isoterma de equilíbrio apresentaram maior concordância com o modelo de Langmuir, o qual permitiu a determinação da capacidade teórica de saturação da magnetita para o urânio. A interação entre os íons UO22+ e a magnetita foi caracterizada como uma adsorção química e espontânea. / Magnetite, also known as iron ferrite, is a mineral iron and a natural magnet found in iron deposits. In addition to its magnetic intrinsic behavior, the magnetite has the capacity to remove the metallic ions from aqueous medium by adsorption phenomena. The strong magnetic character of magnetite distinguishes it from other adsorbent types, which it allows to be readily removed from solution by magnetic separation. In this work, uranium (VI) adsorption, as UO22+ ions, from nitric solution by synthetic magnetite was investigated. It was prepared by simultaneous precipitation process, adding a NaOH solution into a solution containing Fe2+ and Fe3+ ions. The synthetic magnetite, a black powder, has exhibited a strong magnetic response in presence of a magnetic field, without nevertheless becomes magnetic. This typical superparamagnetic behavior was confirmed by magnetization measurements. Adsorption parameters of UO22+ ions such as pH. the adsorbent dose, contact time and equilibrium isotherm were evaluated. Maximum uranium adsorption was observed in the pH 4.0-5.0 range. It was noticed that increase in magnetite dose increased the percent removal of uranium, but decreased the adsorption capacity of the magnetite. It was observed from the relation between adsorption and contact time that the removal has increased very fast with time, and achieved the equilibrium within 30 minutes. The results of equilibrium isotherm agreed well with the Langmuir model, and so the theorical saturation capacity of the magnetite was determined for uranyl ions. The interaction between UO22+ ions and the magnetite was defined as a spontaneous chemical adsorption. adsorbents adsorção industrial wastes íons uranilo liquid wastes magnetic fields magnetita magnetite radioactive wastes uranyl compounds

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