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The preparation and characterisation of some bis-cyclopentadienyl metallocenesConstantine, Steven Peter January 1997 (has links)
No description available.
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Solid-Liquid Equilibrium in Multi Solute SystemsKurosawa, Izumi 18 May 2004 (has links)
Solid-liquid equilibrium in isomorphous amino acid systems has been investigated as a model for systems that form solid solutions. Solid- and liquid-phase compositions in L-valine + L-leucine, L-valine + L-isoleucine, and L-isoleucine + L-valine in water were measured over the entire range of solid composition, and it was shown (from mass balance and phase rule considerations) that these systems form solid solutions. The solid- phases resulting from isothermal and cooling crystallization experiments were also investigated using powder x-ray diffractometry which showed that homogeneous solid solutions could only be obtained in cooling crystallization experiments, whereas isothermal experiments generally produced inhomogeneous solids. This suggests that data reported in the literature from isothermal experiments may not represent true equilibrium values. Solid-phase activity coefficients were estimated using binary and ternary equilibrium data and the UNIFAC-Kuramochi model for liquid-phase nonidealities. The solid phases in the three systems investigated exhibited significant nonidealities that were correlated using the Margules model. The model parameters exhibited a linear relationship with the ratio of binary solubilities of the two solutes. Such simple relationship may be advantageous when solid-liquid equilibrium of thermally unstable solutes or components with unknown physical properties are crystallized.
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Production of silver-loaded zeolites and investigation of their antimicrobial activityKwakye-Awuah, Bright January 2008 (has links)
The production of silver-loaded zeolites either by ion exchange method or by isomorphous substitution of silver ions into zeolites frameworks and their antimicrobial activity is presented. Silver-loaded zeolites produced by ion-exchange in this work include silver-exchanged zeolite X, silver-exchanged zeolite A and silver-exchanged high-alumina Phillipsite. Silver-doped Analcime was produced by isomorphous substitution of silver ions into the Analcime framework. The silver-loaded zeolites were characterized by X-ray diffraction (XRD) analysis, scanning electron microscopy (SEM), energy dispersive X-ray (EDX) analysis, particle size analysis and Fourier transformed infrared (FTIR) spectroscopy. Studies showed that the amount of silver ions loaded into the zeolites frameworks differed for each zeolite. XRD analysis showed little or no changes in the phase purity of all zeolites before and after ion exchange or before and after substitution of silver ions. SEM analysis and particle size analysis showed that the morphology of each zeolite particles was closely related before and after ion exchanged or before and after substitution of silver ions. The antimicrobial activity of these silver-loaded zeolites was investigated by exposing Escherichia coli K12W-T, Staphylococcus aureus NCIMB6571 and Pseudomonas aeruginosa NCIMB8295 suspended in tryptone soya broth (TSB) to the silver-loaded zeolites. The first stage of the investigation involved the exposure of the strains to silver-loaded zeolites in TSB for a duration of 24 hours at different concentration of silver-loaded zeolites. The second stage involved the exposure of the strains to silver-loaded zeolites in TSB over a period of two hours. The persistency of antimicrobial activity of silver-loaded zeolites was investigated by retrieving each silver-loaded zeolite from the first exposure cultures, washed copiously with de-ionised water and adding to fresh bacterial suspensions. To understand the mode of antimicrobial activity of the silver-loaded zeolites, the uptake of silver ions by the strains, composition of fatty acid, as well as the DNA content of Escherichia coli K12W-T was studied. The results obtained showed silver ions appeared to elute from the zeolites frameworks into the TSB in anomalous trend. All three microorganisms were completely inhibited within one hour with the silver-loaded zeolites retaining their antimicrobial activity. The release of silver ions from the zeolites frameworks followed first-order kinetics with varying rate constants and half-lives. The fatty acid composition of all strains as well as the DNA content of Escherichia coli K12W-T were affected by the action of silver ions.
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Micronutrientes e metais pesados em fosfogesso – acúmulo, mobilidade e fator de transferência em latossolos de cerrado / Environmental evaluation on the use of the residue from the processing of phosphate rock in soils of CerradoSilva, David Faria da 21 July 2009 (has links)
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Previous issue date: 2009-07-21 / The calcium sulphate dihydrate (CaSO4.2H2O), phosphogypsum, also known as agricultural gypsum, is one of the major residues generated in the production of phosphate fertilizers by means of solubilization process of phosphate rock with sulfuric acid. The generation rate is approximately 4.8 t for each ton of phosphoric acid produced, and its main disposal form is the stacking in nearby the factories. However, this type of final disposal can lead to environmental impacts, such as leaching and superficial outflow of toxic elements, such as F- and heavy metals, resulting in contamination of water resources and releasing of aerosols caused by wind erosion in the stacks. One way to minimize such impacts is by recycling this residue would be its use in agriculture. The use of phosphogypsum as a soil conditioner in subsurface has been a viable alternative for the utilization of this residue in agriculture. However, it is necessary to consider the content o some heavy metals as well other toxic elements in this material, which may limit its use. It is important to highlight that the gypsum is classified as Class IIA, that is, it is neither hazardous nor inert, since it presents levels of arsenic, fluoride, aluminum, iron, manganese and sulfates above the maximum limit allowed in solubilization tests according to the ‘Associação Brasileira de Normas Técnicas’ - ABNT. The objective of this work was to evaluate the use of phosphogypsum, from a company which produces phosphoric acid, as well as to evaluate the contamination of plants, soils and drained water. Phosphogypsum samples were collected from an active stack regularly used for direct application in soil. Samples of the 30 collection points were dried in oven at 60 ºC. Afterwards the samples were sieved in 0,250 mm (sieve 60 mesh), and then analyzed. Cultivation of corn and soybeans was performed in pots of 25 dm3 containing soil treated with increasing doses of the conditioner applied to the superficial layer (0-18 cm depth). The samples of soils utilized were of Red-Yellow oxysoil and Yellow Oxisoil, originated from the towns of Sete Lagoas and Três Marias, both in the ‘Cerrado’ region of Minas Gerais. The leaching solutions of the pots of corn and soybeans were periodically collected and analyzed for the determination of heavy metals. With these results it can be concluded that there was no significant contamination of soils, plants and water drainage after the short term use of phosphogypsum. Nevertheless, it is recommended that further reapplication must be carefully evaluated, from an environmental standpoint, particularly in sandy soil with groundwater near the surface. / O sulfato de cálcio dihidratado (CaSO4.2H2O), fosfogesso, também denominado de gesso agrícola, é um dos principais resíduos gerados na produção de fertilizantes fosfatados por meio do processo de solubilização da rocha fosfática com ácido sulfúrico. A taxa de geração é de ,aproximadamente, 4,8 t para cada tonelada de ácido fosfórico produzido, sendo sua principal forma de descarte o empilhamento em áreas ao redor das fábricas. No entanto, esse tipo de disposição final pode gerar impactos ao meio ambiente, como por exemplo, a lixiviação e escoamento superficial de elementos tóxicos, como F־ e metais pesados, resultando na contaminação dos recusrsos hídricos e na liberação de aerossóis causados por erosão eólica nas pilhas. Uma das maneiras de minimizar tais impactos é a reciclagem deste resíduo, utilizando-o, por exemplo, na agricultura. Nesse sentido, o uso de fosfogesso como condicionador de solos tem se mostrado uma alternativa viável para o aproveitamento desse resíduo na agricultura. Entretanto, é necessário considerar os teores de alguns metais pesados e outros elementos tóxicos nesse material, que pode limitar o seu uso. É importante ressaltar que o gesso é classificado como resíduo sólido de classe IIA – não perigoso e não inerte, por apresentar teores de arsênio, fluoretos, alumínio, ferro, manganês e sulfatos acima do limite máximo permitido nos testes de solubilização, de acordo com a Associação Brasileira de Normas Técnicas – ABNT. Em vista do exposto, este trabalho teve como objetivo avaliar a utilização de fofosfogesso, proveniente de uma empresa de produção de ácido fosfórico, bem como avaliar a contaminação das plantas, dos solos e da água de drenagem. Foram coletadas amostras de fosfogesso de uma pilha ativa regularmente utilizada para aplicação direta na agricultura. Amostras dos 30 pontos de coleta foram secas em estufa a 60 ºC, peneiradas em malha de 0,250 mm (60 Mesh) e analisadas. Foram realizados cultivos com milho e soja em vasos de 25 dm3 contendo solos tratados com doses crescentes do condicionador aplicado na camada superficial (0-18 cm de profundidade). Foram utilizadas amostras de um Latossolo Vermelho-Amarelo e um Latossolo Amarelo, provenientes das cidades de Sete Lagoas e Três Marias, ambas regiões do Cerrado do Estado de Minas Gerais. As soluções lixiviadas dos vasos de milho e soja, foram coletadas periodicamente e analisadas para a determinação da concentração de metais pesados. A partir dos resultados obtidos pode-se concluir que não se verificou contaminação expressiva de solos, plantas e águas de drenagem, a curto prazo, em decorrência da utilização do fosfogesso. Não obstante, recomenda-se que as reaplicações devam ser criteriosamente avaliadas, do ponto de vista ambiental, principalmente em solos arenosos e com lençol freático muito próximo à superfície.
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Magnetic Susceptibility of Powdered SmPO4Cannata, Ronald 03 1900 (has links)
<p> The magnetic susceptibility of samarium orthophosphate (SmPO4) has been measured over the temperature range from 0.4
to 270°K. A theoretical expression for the susceptibility has been developed assuming a crystal field of cubic symmetry and fitted to the experimental data. </p> / Thesis / Master of Science (MSc)
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Process Kinetics of Transient Liquid PhaseTurriff, Dennis Michael Ryan 09 1900 (has links)
The problem of inadequate measurement techniques for quantifying the isothermal solidification process during transient liquid phase sintering (TLPS) in binary isomorphous systems such as Ni-Cu, and the resulting uncertainty regarding the solidification mechanism and its sensitivity to important process parameters, has been investigated. A unique combination of differential scanning calorimetry (DSC), neutron diffraction (ND), and metallographic techniques has enabled the quantitative characterization of important TLPS stages (i.e., solid-state sintering, melting and dissolution, isothermal solidification, and homogenization) as well as verifying the re-melt behaviour of post-sintered specimens and measuring variable melting point (VMP) properties. This has resulted in the advancement of the fundamental understanding of liquid formation and its removal mechanism during isothermal, or diffusional, solidification. The Ni-Cu system was chosen for experimentation due to its commercial relevance as a braze filler material and also because it is an ideal model system (due to its isomorphous character) that is not well understood on a quantitative or phenomenological basis. Samples consisted of elemental Ni and Cu powder mixtures of varying particle size and composition.
In DSC experiments, the progress of isothermal solidification was determined by measuring the enthalpy of melting and solidification after isothermal hold periods of varying length and comparing these to the measured enthalpy of pure Cu. The low melting enthalpies measured for all Ni/Cu mixtures heated just past the Cu melting point (1090°C) indicate that solid-state sintering and interdiffusion during heat-up significantly suppress initial liquid formation and densification from the wetting liquid. For samples heated well past the Cu melting point (1140°C), Ni dissolution causes increased initial liquid fractions and densification. It was found that significantly more time was required for complete liquid removal at 1140°C vs. 1090°C. This is attributed to the observed increase in initial liquid fractions formed at higher processing temperatures due to the dissolution of Ni. This effectively counteracts the increased diffusivities at these temperatures, and thus more time is required to completely remove the increased liquid content. TLP mixtures sintered at 1140°C using three different particle sizes revealed that fine base metal Ni particles cause high degrees of solid-state interdiffusion during heat-up, small initial liquid fractions, and accelerated liquid removal rates due to high surface area/volume ratios. A diffusion-based analytical model was developed to account for these effects (i.e., particle size, temperature, solid-state sintering, and dissolution). Comparison with experimental DSC results reveals that this model can accurately predict liquid removal given accurate diffusivities. Metallographic analysis of post-sintered DSC specimens via SEM and EDS indicates that isothermal liquid solidification leaves behind Ni-rich cores surrounded by Cu-rich matrix regions having compositions given by the Ni-Cu phase diagram solidus (CS) at a selected isothermal processing temperature (TP).
ND experiments were used to investigate the melting event and interdiffusion during the isothermal hold segment by analyzing the evolution of the {200} FCC peaks of Ni and Cu. ND patterns were collected in situ at 1 minute intervals during prolonged sintering cycles for larger powder specimens. The Cu melting event was characterized by an abrupt decrease in Cu peak intensity at 1085°C as well as a shift towards higher 2 angles corresponding to lower Cu contents. This shifted residual peak (hereafter referred to as the CS peak) originates from regions of the specimen having compositions near solidus at TP. Immediately following the melting event, the evolution of ND patterns shows that these CS peaks grow rapidly, indicating the isothermal growth of a Cu-rich phase. These in situ findings confirmed the metallographic and DSC data and indicated that isothermal solidification of the liquid phase proceeds via the growth of a solute-rich solid solution layer surrounding the Ni particles. This occurs by the transient progression of the solid/liquid interface at compositions given by the liquidus and solidus (CS/CL). During sintering, diffraction intensities gradually increased at intermediate 2 angles between previous Ni and Cu peaks. ND patterns gradually evolved from initially having a broad double-peak profile to a sharper single-peak profile due to increased Ni-Cu interdiffusion. The 2position and width of the post-sintered peaks indicated very homogeneous sintered alloys. Metallographic analysis of post-sintered specimens having undergone prolonged sintering and homogenization revealed extensive Kirkendall pore formation from unequal diffusivities (DCu > DNi).
In this study, the unique combination of diffusion-based modelling as well as DSC, ND, and supporting metallographic analysis has enabled the identification of characteristic sintering behaviour, important process parameters, and processing windows for TLPS in Ni-Cu systems. Quantitative and in situ information of this nature is absent in the previous TLPS literature.
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Process Kinetics of Transient Liquid PhaseTurriff, Dennis Michael Ryan 09 1900 (has links)
The problem of inadequate measurement techniques for quantifying the isothermal solidification process during transient liquid phase sintering (TLPS) in binary isomorphous systems such as Ni-Cu, and the resulting uncertainty regarding the solidification mechanism and its sensitivity to important process parameters, has been investigated. A unique combination of differential scanning calorimetry (DSC), neutron diffraction (ND), and metallographic techniques has enabled the quantitative characterization of important TLPS stages (i.e., solid-state sintering, melting and dissolution, isothermal solidification, and homogenization) as well as verifying the re-melt behaviour of post-sintered specimens and measuring variable melting point (VMP) properties. This has resulted in the advancement of the fundamental understanding of liquid formation and its removal mechanism during isothermal, or diffusional, solidification. The Ni-Cu system was chosen for experimentation due to its commercial relevance as a braze filler material and also because it is an ideal model system (due to its isomorphous character) that is not well understood on a quantitative or phenomenological basis. Samples consisted of elemental Ni and Cu powder mixtures of varying particle size and composition.
In DSC experiments, the progress of isothermal solidification was determined by measuring the enthalpy of melting and solidification after isothermal hold periods of varying length and comparing these to the measured enthalpy of pure Cu. The low melting enthalpies measured for all Ni/Cu mixtures heated just past the Cu melting point (1090°C) indicate that solid-state sintering and interdiffusion during heat-up significantly suppress initial liquid formation and densification from the wetting liquid. For samples heated well past the Cu melting point (1140°C), Ni dissolution causes increased initial liquid fractions and densification. It was found that significantly more time was required for complete liquid removal at 1140°C vs. 1090°C. This is attributed to the observed increase in initial liquid fractions formed at higher processing temperatures due to the dissolution of Ni. This effectively counteracts the increased diffusivities at these temperatures, and thus more time is required to completely remove the increased liquid content. TLP mixtures sintered at 1140°C using three different particle sizes revealed that fine base metal Ni particles cause high degrees of solid-state interdiffusion during heat-up, small initial liquid fractions, and accelerated liquid removal rates due to high surface area/volume ratios. A diffusion-based analytical model was developed to account for these effects (i.e., particle size, temperature, solid-state sintering, and dissolution). Comparison with experimental DSC results reveals that this model can accurately predict liquid removal given accurate diffusivities. Metallographic analysis of post-sintered DSC specimens via SEM and EDS indicates that isothermal liquid solidification leaves behind Ni-rich cores surrounded by Cu-rich matrix regions having compositions given by the Ni-Cu phase diagram solidus (CS) at a selected isothermal processing temperature (TP).
ND experiments were used to investigate the melting event and interdiffusion during the isothermal hold segment by analyzing the evolution of the {200} FCC peaks of Ni and Cu. ND patterns were collected in situ at 1 minute intervals during prolonged sintering cycles for larger powder specimens. The Cu melting event was characterized by an abrupt decrease in Cu peak intensity at 1085°C as well as a shift towards higher 2 angles corresponding to lower Cu contents. This shifted residual peak (hereafter referred to as the CS peak) originates from regions of the specimen having compositions near solidus at TP. Immediately following the melting event, the evolution of ND patterns shows that these CS peaks grow rapidly, indicating the isothermal growth of a Cu-rich phase. These in situ findings confirmed the metallographic and DSC data and indicated that isothermal solidification of the liquid phase proceeds via the growth of a solute-rich solid solution layer surrounding the Ni particles. This occurs by the transient progression of the solid/liquid interface at compositions given by the liquidus and solidus (CS/CL). During sintering, diffraction intensities gradually increased at intermediate 2 angles between previous Ni and Cu peaks. ND patterns gradually evolved from initially having a broad double-peak profile to a sharper single-peak profile due to increased Ni-Cu interdiffusion. The 2position and width of the post-sintered peaks indicated very homogeneous sintered alloys. Metallographic analysis of post-sintered specimens having undergone prolonged sintering and homogenization revealed extensive Kirkendall pore formation from unequal diffusivities (DCu > DNi).
In this study, the unique combination of diffusion-based modelling as well as DSC, ND, and supporting metallographic analysis has enabled the identification of characteristic sintering behaviour, important process parameters, and processing windows for TLPS in Ni-Cu systems. Quantitative and in situ information of this nature is absent in the previous TLPS literature.
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