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81	Characterization of cobalt and cerium coordination environments for catalytic steam reforming of bio-derived liquids Soykal, Ibrahim Ilgaz I. January 2013 (has links) No description available. Chemical Engineering
82	A High Temperature Planar Solid Oxide Fuel Cell Operating on Phosphine Contaminated Coal Syngas De Silva, Kandaudage Channa R. 25 July 2011 (has links) No description available. Chemical Engineering Energy Solid oxide fuel cells coal syngas phosphine contaminated silver current collectors ceria anodes
83	Coatings for corrosion protection of metals and alloys Yang, Lijia 10 1900 (has links) <p>Thin films prepared by electrochemical and physical vapor deposition (PVD) methods were investigated for corrosion protection of metals and alloys. Various electrochemical methods were developed, such as electrophoretic deposition (EPD), electrolytic deposition (ELD) and combined methods. EPD method has been developed for the deposition of polymer films, including poly(2-vinylpyridine) (PVP) and co-polymer poly(4-vinylpyridine-<em>co</em>-butyl methacrylate) (PVPBM). The method involved the electrophoresis of protonated polymer macromolecules, base generation at the cathode surface, charge neutralization and deposition of water insoluble polymer films. Nanostructured CeO<sub>2</sub> ﬁlms were prepared by cathodic ELD and EPD. Cathodic ELD involved electrosynthesis of CeO<sub>2</sub> nanoparticles in the cathodic reaction and film formation. New dispersion agents were developed for CeO<sub>2</sub> particles for application in EPD processes. The kinetics of ELD and EPD and deposition mechanisms were investigated.</p> <p>Composite polymer-CeO<sub>2</sub> ﬁlms were deposited using various strategies, based on ELD or EPD of CeO<sub>2</sub> and EPD of polymers. The composite films were deposited as monolayers, multilayers or materials of graded composition. The deposition yield and film composition can be varied.</p> <p>The composite films were studied by electron microscopy, X-ray diffraction, thermogravimetric and differential thermal analysis. Electrochemical testing showed that polymer and composite films provided corrosion protection of stainless steel substrates.</p> <p>Corrosion protection properties of coatings deposited on commercial AMPCO and TZM alloys was investigated. CrN, CrN-D, and TiC were deposited by PVD method. Ni coatings were deposited by electroplating. The analysis of Tafel plots and impedance spectroscopy data showed that CrN and CrN-D coatings deposited by PVD showed better corrosion protection of AMPCO and TZM alloys, compared to TiC and Ni coatings. The results of this investigation pave the way for the fabrication of novel coatings with advanced corrosion protection, wear and mechanical properties, using combined PVD and electrochemical methods.</p> / Master of Applied Science (MASc) coating corrossion ceria polymer EPD co-deposition Other Materials Science and Engineering Other Materials Science and Engineering
84	Implications of the Use of Cerium Oxide Nanoparticle Diesel Fuel-Borne Catalysts: From Transformation During Combustion Through Exposure to Plants and Soils Dale, James G. 28 April 2017 (has links) The fate of nanoparticulate cerium oxide from the diesel fuel catalyst Envirox was studied from its presence in the additive to its transformations during combustion through its exposure to plants and soils using a broad range of analytical techniques. Envirox is a fuel-borne catalyst comprised of nanoparticles of cerium oxide suspended in kerosene. The particles suspended in Envirox were confirmed by synchrotron X-ray diffraction, dynamic light scattering, and electron microscopy to be 5-7 nm crystals of CeO2 present as 15 nm aggregates. Significant changes to the particles were induced by the combustion process, resulting in 50-300 nm euhedral crystals of CeO2 in the exhaust as discovered using high resolution transmission electron microscopy. Single particle electron diffraction of the emitted cerium oxide particles showed evidence of ordered oxygen vacancies, indicative of a superstructure. Variations in the engine operating load resulted in no significant differences in the emitted cerium oxide particles. The mobility through soils and impacts on the plant Brassica napus (dwarf essex rape) of the emitted cerium oxide were compared to small and large CeO2 nanoparticles as well as diesel particulate matter emissions with very low cerium. The small CeO2 nanoparticles exhibited high mobility through soils and significant uptake and translocation in the plants. The large CeO2 nanoparticles showed extremely low mobility in soils and no significant increase in cerium anywhere in the plants. Cerium emissions from a diesel engine utilizing Envirox was found to have moderate mobility through the soils as well as an increased association with the roots of the plants, though translocation of the cerium into the aboveground biomass was not statistically significant. Despite uptake and translocation of some materials by B. napus, exposure to these cerium sources at 100 ppm Ce in the topsoil showed no significant impacts on the growth or overall health of the plants when compared to unexposed control samples. This dissertation shows that CeO2 nanoparticles employed as catalysts suspended in diesel fuel are altered during their use resulting in changes to their mobility and interaction upon entering the environment. This dissertation lays the groundwork for a new approach to nanotoxicology. / Ph. D. Ceria cerium oxide diesel additive diesel fuel fuel-borne catalyst nanomaterials nanotoxicology
85	Design of optical characteristics of ceria nanoparticles for applications including gas sensing and up-conversion Shehata, Nader 13 December 2012 (has links) This thesis investigates the impact of doping on the optical and structural characteristics of cerium oxide (ceria) nanoparticles synthesized using chemical precipitation. The dopants selected are samarium and neodymium, which have positive association energy with oxygen vacancies in the ceria host, and negative association lanthanides, holmium and erbium, as well as two metal dopants, aluminum and iron. Characteristics measured are absorption and fluorescence spectra and the diameter and lattice parameter of ceria. Analysis of the characteristics indicates qualitatively that the dopant controls the O-vacancy concentration and the ratio of the two cerium ionization states: Ce+3 and Ce+4. A novel conclusion is proposed that the negative association lanthanide dopants can act as O-vacancies scavengers in ceria while the O-vacancy concentration increases in ceria doped with positive association lanthanide elements. Doped ceria nanoparticles are evaluated in two applications: dissolved oxygen (DO) sensing and up-conversion. In the first application, ceria doped with either Sm or Nd and ceria doped with aluminum have a strong correlation between the fluorescence quenching with the DO concentration in the aqueous solution in which the ceria nanoparticles are suspended. Stern-Volmer constants (KSV) of doped ceria are found to strongly depend upon the O-vacancy concentration and are larger than some of the fluorescent molecular probes currently used to measure DO. The KSV measured between 25-50oC is found to be significantly less temperature dependent as compared to the constants of commercially-available DO molecular probes. In the second application, up-conversion, ceria nanoparticles doped with erbium and an additional lanthanide, either Sm or Nd, are exposed to IR radiation at 780 nm. Visible emission is only observed after the nanoparticles are calcinated at high temperature, greatly diminishing the concentration of O-vacancies. It is concluded that O-vacancies do not play a dominant role in up-conversion, unlike that drawn for down-conversion, where the fluorescence intensity is strongly correlated with the O-vacancy concentration. Correlations between annealing temperatures, dopant, and dopant concentrations with the power dependence of up-conversion on the pump and the origin of the intensities of the visible emission are presented. These studies show the promise of doped ceria nanoparticles. / Ph. D. Ceria nanoparticles lanthanide dopants oxygen vacancies fluorescence quenching oxygen sensing up-conversion
86	Carbon Dioxide Reduction on Gadolinia-Doped Ceria Cathodes Green, Robert David 22 January 2009 (has links) No description available. Chemical Engineering Chemistry Materials Science carbon dioxide reduction carbon dioxide electrolysis Gadolinia-doped ceria ceria impedance spectroscopy porous electrode model electrode kinetics exchange rate vacancy diffusion coefficient thermodynamic factor
87	Ceria Based Catalysts for Low Temperature NO<sub>x</sub> Storage and Release Jones, Samantha 01 January 2016 (has links) Model ceria catalysts were evaluated for NOx storage and desorption performance under lean conditions. Three different storage temperatures (80 °C, 120 °C, and 160 °C) were utilized to evaluate NOx storage. Higher temperatures resulted in higher NOx storage. It was observed that storage of platinum promoted ceria resulted in higher NOx storage compared to promotion with palladium. NOx desorption behavior of platinum promoted ceria indicated that the majority of NOx is released at high temperatures (> 350 °C), comparatively palladium promotion released more of the stored NOx at lower temperatures. Diffuse Reflectance Infrared Fourier Transform Spectroscopy (DRIFTS) indicated that platinum promotion results in NOx storage as thermally stabile nitrates, while palladium promotion results in NOx storage as thermally labile nitrites. Doping ceria with trivalent rare earth oxides has been shown to improve NOx storage by generating lattice oxygen vacancies. Ceria doped with Pr, Y, La, Sm, and Nd at two different concentrations (5 and 20 mol%) and promoted with Pt were evaluated. Doping ceria with 5% Sm, Nd, and Pr improved the amount of NOx stored while the addition of Sm and La did not improve storage. Upon increasing dopant concentration, NOx storage decreased in all cases but Pr. However, increasing Pr concentration was found to increase NOx storage as well as low temperature NOx release. Ceria doped with Pr promoted with Pd increased the amount of NOx released at lower temperatures compared to Pt promotion, although palladium promotion resulted in lower storage. Similar DRIFTS spectra were obtained with Ce-Pr when promoted with Pt or Pd compared to model catalysts. Platinum promotion results in the storage of NOx at nitrates, which require high temperatures for removal. Comparatively, Pd promotion results in NOx stored at nitrites requiring lower temperatures for removal. Ceria doped with Pr proved to be promising, although not thermally stable when exposed to high temperatures as may be seen during a DPF clean up. Therefor, stabilizing Ce-Pr catalysts with Zr were evaluated. It was found that stabilizing Ce-Pr with Zr was not found to be beneficial to the catalyst performance. NOx Low temperature NOx storage Passive NOx Adsorbers PNA DRIFTS Ce-Pr and doped ceria. Chemistry Inorganic Chemistry
88	Functional nanocomposites for advanced fuel cell technology and polygeneration Raza, Rizwan January 2011 (has links) In recent decades, the use of fossil fuels has increased exponentially with a corresponding sharp increase in the pollution of the environment. The need for clean and sustainable technologies for the generation of power with reduced or zero environment impact has become critical. A number of attempts have been made to address this problem; one of the most promising attempts is polygeneration. Polygeneration technology is highly efficient and produces lower emissions than conventional methods of power generation because of the simultaneous generation of useable heat and electrical power from a single source of fuel. The overall efficiency of such systems can be as high as 90%, compared to 30-35% for conventional single-product power plants. A number of different technologies are available for polygeneration, such as micro gas turbines, sterling engines, solar systems, and fuel cells. Of these, fuel cell systems offer the most promising technology for polygeneration because of their ability to produce electricity and heat at a high efficiency (about 80%) with either low or zero emissions. Various fuel-cell technologies can be used in polygeneration systems. Of these, solid oxide fuel cells (SOFCs) are the most suitable because they offer high system efficiency for the production of electricity and heat (about 90%) coupled with low or zero emissions. Compared to other types of fuel cells, SOFCs have fuel flexibility (direct operation on hydrocarbon fuels, such as biogas, bio-ethanol, bio-methanol, etc.) and produce high-quality heat energy. The development of polygeneration systems using SOFCs has generally followed one of two approaches. The first approach involves the design of a SOFC system that operates at a temperature of 850 oC and uses natural gas as a fuel. The second approach uses low-temperature (generally 400-600 oC) SOFC (LTSOFC) systems with biomass, e.g., syngas or liquid fuels, such as bio-methanol and bio-ethanol. The latter systems have strong potential for use in polygeneration. High-temperature SOFCs have obvious disadvantages, and challenges remain for lowering the cost to meet commercial interest. The SOFC systems need lower operating temperatures to reduce their overall costs. This thesis focuses on the development of nanocomposites for advanced fuel-cell technology (NANOCOFC), i.e., the next generation SOFCs, which are low-temperature (400-600 oC), marketable, and affordable SOFCs. In addition, new concepts that pertain to fuel-cell science and technology—NANOCOFC (www.nanocofc.com)—are explored and developed. The content of this thesis is divided into five parts: In the first part of this thesis (Papers 1-5), the two-phase nanocomposite electrolytes, viz. ceria-salt and ceria-oxide, were prepared and studied using different electrochemical techniques. The microstructure and morphology of the composite electrolytes were characterised using XRD, SEM and TEM, and the thermal analysis was conducted using DSC. An ionic conductivity of 0.1 S/cm was obtained at 300 ºC, which is comparable to that of conventional YSZ operating at 1000 ºC. The maximum output power density was 1000 mW/cm2 at 550 oC. A co-doped ceria-carbonate was also developed to improve the ionic conductivity, morphology, and performance of the electrolyte. In the second part of this thesis (Papers 7-9), composite electrodes that contained less or no nickel (Ni) were developed for a low-temperature SOFC. All of the elements were highly homogenously distributed in the composite electrode, which resulted in high catalytic activity and good ASOFC performance. The substitution of Ni by Zn in these electrodes could reduce their cost by a factor of approximately 25. In the third part of this thesis (Papers 10), an advanced multi-fuelled solid-oxide fuel cell (ASOFC) with functional nanocomposites (electrolytes and electrodes) was developed. Several different types of fuel, such as gaseous (hydrogen and biogas) and liquid fuels (bio-ethanol and bio-methanol), were tested. Maximum power densities of 1000, 300, 600, and 550 mW/cm2 were achieved with hydrogen, bio-gas, bio-methanol, and bio-ethanol, respectively, in the ASOFC. Electrical and total efficiencies of 54% and 80%, respectively, were achieved when the single cell was used with hydrogen. The fourth part of this thesis (Papers 11) concerns the design of a 5 kW ASOFC system based on the demonstrated advanced SOFC technology. A polygeneration system based on a low-temperature planar SOFC was then designed and simulated. The efficiency of the overall system was approximately 80%. The fifth part of this thesis (Paper 12) describes a single-layer multi-fuelled electrolyte-free fuel cell that is a revolutionary innovation in renewable-energy sources. Conventional fuel cells generate electricity by ion transport through the electrolyte. However, this new device works without an electrolyte, and all of the processes occur at particle surfaces in the material. Based on a theoretical calculation, an additional 18% enhancement of the fuel cell’s efficiency will be achieved using this new technology compared to the conventional technologies. Our developed ASOFC systems with functional nanocomposites offer significant advantages in reducing the operational and capital costs for the production of power and heat by using different fuels based on the fuel-cell technology. ASOFC systems can be used for polygeneration with renewable fuels (i.e., biomass fuels) at high efficiency as a sustainable solution to energy generation in our society. The results have been achieved for this thesis work has demonstrated an advanced fuel cell technology. / <p>QC 20111213</p> Polygeneration advanced fuel cell functional materials ceria-carbonate nanocomposites multi-fuelled electrolyte free fuel cell Energy Engineering Energiteknik
89	Zircônia céria mesoporosa para células de combustível e catalisadores / Mesoporous zirconia ceria for catalysts and fuel cells Cassimiro, Vinicius Roberto de Sylos 07 December 2015 (has links) Os materiais à base de céria (CeO2) e zircônia (ZrO2) estão presentes em diversas aplicações tecnológicas, destacando-se como anodo de células de combustível de óxido sólido (SOFC) e em catálise, tanto para a produção de hidrogênio, como na automotiva (Three-Way Catalysis). A solução sólida ZrxCe1-xO2- é de especial interesse, pois apresenta melhor estabilidade térmica e maior capacidade de armazenamento de oxigênio (OSC), quando comparada com os óxidos não dopados. Os materiais mesoporosos (poros de 2 a 50 nm) possuem elevada área superficial e permeabilidade a gases, características estas importantes para o desempenho das SOFCs e dos processos de catálise. Neste trabalho, zircônia-céria (Zr0,1Ce0,9O2-) mesoporosa foi sintetizada pelo processo sol-gel, utilizando, como precursores, os cloretos inorgânicos (ZrCl4 e CeCl3.7H2O), o copolímero em bloco P123 (PEO20PPO70PEO20) como direcionador de estrutura e o TIPB (tri-isopropil-benzeno) como agente dilatador. A solução passou por tratamento hidrotérmico durante 48h a 80°C, com posterior calcinação a 400°C para a remoção do polímero, resultando no óxido cristalizado. Na análise foram utilizadas as técnicas: difração de raios X em alto ângulo (XRD), espalhamento de raios X a baixo ângulo (SAXS), isotermas de adsorção de nitrogênio (NAI) e microscopia eletrônica de varredura e transmissão (SEM e TEM). Os resultados mostraram que o material possui elevada área superficial (110m2/g), mesoporos de várias dimensões, atingindo valores médios em torno de 30 nm, fase majoritariamente cúbica Fm3m e, em menor proporção, tetragonal P42/nmc. As micrografias revelaram que o óxido está totalmente nano-cristalizado, com os poros tipo fendas e uma mesoporosidade secundária com distribuição de tamanhos menor e mais estreita. Quatro amostras foram sintetizadas com diferentes razões em massa TIPB/P123 (0, 1, 2 e 4), de forma que foi possível verificar um aumento na dimensão dos poros devido à inclusão do dilatador. As demais propriedades estruturais e morfológicas mantiveram-se inalteradas entre todas as amostras, mesmo com diferentes quantidades de TIPB. / The ceria (CeO2) and zirconia (ZrO2) based materials are present in several technological applications, mainly as Solid Oxide Fuel Cells (SOFC) anodes and catalysts, for hydrogen production and automotive converter (Three-Way Catalysis). The solid solution ZrxCe1-xO2- has attracted special attention, since it shows better thermal stability and higher oxygen storage capacity (OSC), if compared to the non-doped oxides. The mesoporous materials (pores of 2 to 50 nm) show high surface area and gas permeability, important properties for SOFCs and catalysts efficiency. In this work, mesoporous ceria-zirconia (Zr0,1Ce0,9O2-) was synthesized by a sol-gel route using inorganic chlorides (ZrCl4 e CeCl3.7H2O) as precursors, block copolymer P123 (PEO20PPO70PEO20) as template and TIPB (tri-isopropyl-benzene) as swelling agent. The solution was submitted to hydrothermal treatment for 48h at 80°C and calcined at 400°C to remove the template, resulting in the crystallized oxide. The characterization was performed by X-ray diffraction at high angles (XRD), small angle X-ray scattering (SAXS), nitrogen adsorption isotherms (NAI) and transmission and scanning electron microscopy (TEM and SEM). The results showed that the material has high surface area (110m2/g), a wide pore size distribution with mean values around 30 nm, predominant cubic phase Fm3m and, in less quantity, tetragonal P42/nmc. The micrographs revealed that the oxide is totally nano-crystallized, having pores with slit shape and a secondary smaller mesoporosity with a narrow size distribution. Four samples were produced with different TIPB/P123 mass rate (0, 1, 2, 4), therefore was possible to verify the pore size expansion due to the swelling addition. The structural and morphological properties remained unchanged, even with different quantities of TIPB. Catalisadores Catalysts Dilatador de estrutura Materiais nanoestruturados Mesopore Mesoporo Nanostructured materials SOFC SOFC Swelling agent Zirconia ceria Zircônia céria
90	Efeito da adição de ZnO em catalisadores Ni-Al2O3, Ni-CeO2, Ni-MgO e Ni-ZrO2 para reação de reforma seca de metano / Effect of ZnO addition on Ni-Al2O3, Ni-CeO2, Ni-MgO and Ni-ZrO2 catalysts for dry reforming of methane Alves, Camila Almeida 12 May 2014 (has links) Devido a crescente preocupação com relação ao efeito estufa e com o objetivo de obter produtos de maior valor agregado a partir dos gases CH4 e CO2, este trabalho estudou catalisadores de níquel suportados em diferentes óxidos (Al2O3, CeO2, MgO e ZrO2) promovidos com ZnO aplicados na reação de reforma seca de metano para obter gás de síntese (H2 + CO). Primeiramente foram estudados catalisadores de níquel suportados em ZrO2 dopados com diferentes teores de zinco: 0%, 5%, 12,5% e 25% a fim de selecionar o catalisador mais promissor para estudos posteriores. Também foram utilizados dois métodos de preparo: impregnação e co-precipitação. Os resultados de DRX mostraram que a adição de zinco estabilizou a fase tetragonal da zircônia em todos os teores de zinco e em ambos os métodos de preparo. As análises de RTP mostraram que os catalisadores impregnados sofreram maior redução do que os co-precipitados e para maiores teores de zinco foram necessárias maiores temperaturas de redução. Os testes catalíticos mostraram que o aditivo zinco não exerceu efeito sobre os catalisadores impregnados, porém para as amostras co-precipitadas notou-se um teor ótimo com relação à conversão de reagentes na reação e o catalisador 5Ni12ZZc apresentou os melhores resultados. A deposição de carbono também foi menor nos catalisadores co-precipitados. No estudo dos diferentes suportes, as análises de DRX sugerem a dopagem de todos os óxidos com zinco, pois houve mudanças no parâmetro de rede em todas as amostras. As análises de RTP mostraram que a adição de zinco diminui a temperatura de redução do catalisador suportado em alumina e, no suporte CeO2 o efeito é o contrário. Nos testes catalíticos observaram-se efeitos distintos: nos catalisadores Ni-ZnO-CeO2 e Ni-ZnO-MgO o efeito da adição de zinco causou diminuição na conversão dos reagentes, por outro lado, causou diminuição na deposição de carbono e inibição da formação do carbono grafite; nos catalisadores Ni-ZnO-Al2O3 a conversão de reagentes não se alterou com a adição de zinco porém houve uma diminuição na deposição de carbono. Os melhores resultados, portanto, foram apresentados pelo catalisador 5NiZnAl que converteu acima de 80% dos reagentes e não sofreu desativação pela deposição de carbono. / Due to the increasing concern related to the greenhouse effect and aiming to obtain products with higher added-value from CH4 and CO2 gases, nickel catalysts supported on different oxides (Al2O3, CeO2, MgO and ZrO2) promoted with ZnO were studied and applied to the dry reforming of methane reaction to obtain syngas (H2+CO). Firstly, ZrO2 supported Nickel catalysts doped with different zinc content: 0, 5, 12,5 and 25% molar ratio were used to identify and select the best amount of zinc to further studies. Two preparation methods were investigated: impregnation and co-precipitation. The XRD results showed that the zinc addition stabilized the zircon tetrahedral phase of all catalysts from both preparation methods. The TPR analyses showed that the impregnated catalysts reduced more than the co-precipitated ones and higher reduction temperature was needed for the catalysts with higher zinc content. The catalytic tests indicated that the zinc content did not have any effect over the impregnated catalysts, whilst for the co-precipitated samples, a great content was noted and the 5Ni12ZZc catalyst showed the best results. The co-precipitated catalysts also had lower carbon deposition. In the study of different supports, the XRD analyses showed that the zinc interacts with all the used oxides, because there were changes of the cell parameter of all samples. The TPR analyses indicated that the zinc addition lowers the reduction temperature of the alumina supported catalyst and the effect is opposite for the CeO2 support. Different effects were observed during the catalytic tests: for the CeO2 and MgO supported catalysts the effect of zinc addition caused a decrease in the conversion of reactants, but it lowered the deposition of carbon and inhibited the formation of graffiti carbon; for the Al2O3 supported catalysts, the reactant conversion was the same with the addition of zinc, however there was a reduction on the carbon deposition. Therefore, the best results were obtained for the 5NiZnAl catalyst, which converted over 80% of the reactants and wasn\'t deactivated by carbon deposition. alumina alumina ceria céria dry reforming of methane magnesia magnésia nickel níquel reforma seca de metano zinc zinco zirconia zircônia

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