Global ETD Search

1	Hydrogenase in Azotobacter vinelandii : the role of the heme ligands in HoxZ Meek, Laura 23 August 1999 (has links) Graduation date: 2000 Azotobacter Cytochrome b Hydrogen -- Oxidation Ligands
2	Ni-C electrocatalysts for hydrogen oxidation in low-temperature acidic fuel cells Chin, Xiao Yao January 2012 (has links) No description available. 669
3	Eletrocatalisadores de ligas de platina dispersos em substratos de óxidos para a reação de oxidação de hidrogênio puro e na presença de CO / Electrocatalysts of platinum alloys dispersed in oxide substrates for pure hydrogen oxidation reaction and in the presence of CO Freitas, Kênia da Silva 29 April 2009 (has links) Neste trabalho são apresentados resultados dos estudos da reação de oxidação de hidrogênio puro realizados em eletrodos rotatório em camada ultrafina porosa e na presença de CO em células a combustível utilizando catalisadores formados por Pt dispersas em substratos de óxidos, tais como, Pt/RuO 2 -C, Pt/RhO 2 -C, Pt/WO 3 -C e em Pt/WC-C. As reações foram também estudadas em suporte puro, como, RhO 2 /C e WC/C em diferentes proporções atômicas. Este estudo teve como finalidade estudar as propriedades catalíticas destes materiais visando elucidar os mecanismos da reação de oxidação de hidrogênio (ROH) sobre estes catalisadores dispersos, possibilitando a obtenção de parâmetros cinéticos das reações. Em conjunto com as medidas eletroquímicas, foram realizados estudos sobre as propriedades eletrônicas e estruturais destes catalisadores, o que possibilita relacionar suas propriedades eletrônicas e estruturais com a cinética da HOR. Observou-se que a presença dos óxidos de Ru, Rh e WO 3 favorecem a diminuição do grau de recobrimento da Pt por CO, deixando mais sítios disponíveis a ROH, em consequência do esvaziamento da banda 5d da Pt, o que diminui a retro-doação de elétrons da Pt ao CO, diminuindo a força da ligação Pt-CO. Como observado, essas modificação eletrônicas observadas nos espectros de XANES não induziram a nenhuma mudança perceptível na cinética ou no mecanismo reacional. Para quase todos os catalisadores, a tolerância ao CO pode ser explicada tanto em termos do mecanismo eletrônico como do bifuncional evidenciado pela formação de CO 2 nas medidas de EMS. / This work shows results of studies of the hydrogen oxidation reaction (HOR) pure in rotation in ultra porous layer and in the presence of CO in the fuel cell to the electrocatalysts of Pt alloy dispersed on oxide substrates such Pt/RuO 2 -C, Pt/RhO 2 -C, Pt/WO 3 -C, Pt/WC-C and pure materials, as RhO 2 /C and WC. The study of the catalytic properties of these materials to elucidate the mechanisms of hydrogen oxidation reaction on these dispersed catalysts, allowing the collection of kinetic parameters of reactions. Together with the electrochemical measurements were carried out studies on the structural and electronic properties of these catalysts, which allow relating their structural and electronic properties with the kinetics of the HOR. It was observed that the presence of oxides of Ru, Rh and WO 3 encourage the reduction of the degree of coating of Pt by CO, leaving more sites available to ROH, as a consequence of emptying of the Pt 5d band, which reduces the backdonation of electrons from Pt to CO by reducing the strength of Pt-CO binding. As noted, these changes observed in electronic spectra of XANES not led to any perceptible change in the kinetics or the reaction mechanism. For almost all catalysts, the CO tolerance can be explained in terms of the electronic effect and the bifunctional mechanism evidenced by the formation of CO 2 in the EMS. CO oxidation electrocatalysts eletrocatalisadores hydrogen oxidation mecanismo de reação oxidação de CO oxidação de hidrogênio oxide substrate reaction mechanism substratos de óxidos
4	Molecular Simulation of Chemically Reacting Flows Inside Micro/Nano-channels Ahmadzadegan, Amir 23 September 2013 (has links) The main objective of this thesis is to study the fundamental behaviour of multi-component gas mixture flows in micro/nano-channels undergoing catalytic chemical reactions on the walls. This work is primarily focused on nano-scale reacting flows seen in related applications; especially, miniaturized energy sources such as micro-fuel cells and batteries. At these geometries, the order of the characteristic length is close to the mean free path of the flowing gas, making the flow highly rarefied. As a result, non-equilibrium conditions prevail even the bulk flow and therefore, continuum assumptions are not held anymore. Hence, discrete methods should be adopted to simulate molecular movements and interactions described by the Boltzmann equation. The Direct Simulation Monte Carlo (DSMC) method was employed for the present research due to its natural ability for simulating a broad range of rarefied gas flows, and its flexibility to incorporate surface chemical reactions. In the first step, fluid dynamics and the heat transfer of H₂/N₂ and H₂/N₂/CO₂ gas mixture slip flows in a plain micro-channel are simulated. The obtained results are compared to the corresponding data achieved from Navier-Stokes equations with slip/jump boundary conditions. Generally, very good agreements are observed between the two methods. It proves the ability of DSMC in replicating the fluid properties of multi-component gas mixtures even when high mass discrepancies exist among the species. Based on this comparison, the proper parameters are set for the prepared DSMC code, and the appropriate intermolecular collision model is identified. It is also found that stream variables should be calculated more accurately at flow boundaries in order to simulate the intense upstream diffusion emerging at low velocity flows frequently seen in micro/nano-applications. Therefore, in the second step, a novel pressure boundary condition is introduced for gas mixture flows by substituting the commonly used Maxwell velocity distribution with the Chapman-Enskog distribution function. It is shown that this new method yields better results for lower velocity and higher rarefaction level cases. In the last step, a new method is proposed for coupling the flow field simulated by DSMC and surface reactions modelled by the species conservation ODE system derived from the reaction mechanism. First, a lean H₂/air slip flow subjected to oxidation on platinum coated walls in a flat micro-channel 4μm in height is simulated as a verification test case. The results obtained are validated against the solutions of the Navier-Stokes equations with slip/jump boundary conditions and very good conformity is achieved. Next, several cases undergoing the same reaction with Reynolds numbers ranging from 0.2 to 3.6 and Knudsen numbers ranging from 0.025 to 0.375, are simulated using the verified code to investigate the effects of the channel height ranging from 0.5μm to 2μm , the inlet mass flow rate ranging from 5 kg/m².s to 25 kg/m².s, the inlet temperature ranging from 300K to 700K, the wall temperature ranging from 300K to 1000K, and the fuel/air equivalence ratio ranging from 0.28 to 1.5. Some of the findings are as follows: (1) increasing the surface temperature from 600K to 1000K and/or the inlet temperature from 300K to 700K results in negligible enhancement of the conversion rate, (2) the optimum value of the equivalence ratio is on the fuel lean side (around 0.5), (3) the efficiency of the reactor is higher for smaller channel heights, and (4) increasing the inlet mass flux elevates the reaction rate especially for the smaller channels; this effect is not linear and is more magnified for lower mass fluxes. DSMC Microchannel Nanochannel Catalytic chemical reaction Chapman-Enskog distribution Hydrogen oxidation over platinum Rarefied gas flow Transition regime Slip regime
5	Eletrocatalisadores de ligas de platina dispersos em substratos de óxidos para a reação de oxidação de hidrogênio puro e na presença de CO / Electrocatalysts of platinum alloys dispersed in oxide substrates for pure hydrogen oxidation reaction and in the presence of CO Kênia da Silva Freitas 29 April 2009 (has links) Neste trabalho são apresentados resultados dos estudos da reação de oxidação de hidrogênio puro realizados em eletrodos rotatório em camada ultrafina porosa e na presença de CO em células a combustível utilizando catalisadores formados por Pt dispersas em substratos de óxidos, tais como, Pt/RuO 2 -C, Pt/RhO 2 -C, Pt/WO 3 -C e em Pt/WC-C. As reações foram também estudadas em suporte puro, como, RhO 2 /C e WC/C em diferentes proporções atômicas. Este estudo teve como finalidade estudar as propriedades catalíticas destes materiais visando elucidar os mecanismos da reação de oxidação de hidrogênio (ROH) sobre estes catalisadores dispersos, possibilitando a obtenção de parâmetros cinéticos das reações. Em conjunto com as medidas eletroquímicas, foram realizados estudos sobre as propriedades eletrônicas e estruturais destes catalisadores, o que possibilita relacionar suas propriedades eletrônicas e estruturais com a cinética da HOR. Observou-se que a presença dos óxidos de Ru, Rh e WO 3 favorecem a diminuição do grau de recobrimento da Pt por CO, deixando mais sítios disponíveis a ROH, em consequência do esvaziamento da banda 5d da Pt, o que diminui a retro-doação de elétrons da Pt ao CO, diminuindo a força da ligação Pt-CO. Como observado, essas modificação eletrônicas observadas nos espectros de XANES não induziram a nenhuma mudança perceptível na cinética ou no mecanismo reacional. Para quase todos os catalisadores, a tolerância ao CO pode ser explicada tanto em termos do mecanismo eletrônico como do bifuncional evidenciado pela formação de CO 2 nas medidas de EMS. / This work shows results of studies of the hydrogen oxidation reaction (HOR) pure in rotation in ultra porous layer and in the presence of CO in the fuel cell to the electrocatalysts of Pt alloy dispersed on oxide substrates such Pt/RuO 2 -C, Pt/RhO 2 -C, Pt/WO 3 -C, Pt/WC-C and pure materials, as RhO 2 /C and WC. The study of the catalytic properties of these materials to elucidate the mechanisms of hydrogen oxidation reaction on these dispersed catalysts, allowing the collection of kinetic parameters of reactions. Together with the electrochemical measurements were carried out studies on the structural and electronic properties of these catalysts, which allow relating their structural and electronic properties with the kinetics of the HOR. It was observed that the presence of oxides of Ru, Rh and WO 3 encourage the reduction of the degree of coating of Pt by CO, leaving more sites available to ROH, as a consequence of emptying of the Pt 5d band, which reduces the backdonation of electrons from Pt to CO by reducing the strength of Pt-CO binding. As noted, these changes observed in electronic spectra of XANES not led to any perceptible change in the kinetics or the reaction mechanism. For almost all catalysts, the CO tolerance can be explained in terms of the electronic effect and the bifunctional mechanism evidenced by the formation of CO 2 in the EMS. eletrocatalisadores mecanismo de reação oxidação de CO oxidação de hidrogênio substratos de óxidos CO oxidation electrocatalysts hydrogen oxidation oxide substrate reaction mechanism
6	L’hydrogénase [Ni-Fe] multi-tolérante d’Aquifex aeolicus : de l’immobilisation fonctionnelle à la biopile H2/O2 Ciaccafava, Alexandre 18 December 2012 (has links) Les hydrogénases sont les enzymes responsables de la conversion de l'H2. De part leur efficacité et spécificité vis-à-vis de l'oxydation de l'H2, elles apparaissent comme des biocatalyseurs potentiels dans les biopiles à combustible. Dans cet objectif, nous avons étudié l'immobilisation fonctionnelle sur diverses électrodes de l'hydrogénase membranaire tolérante à l'O2 de la bactérie hyperthermophile Aquifex aeolicus. Par une approche couplée d'électrochimie, de microscopie et de spectroscopie, il est montré que l'orientation de l'hydrogénase sur une électrode n'est pas contrôlée par des interactions électrostatiques mais hydrophobes. Ce contrôle est lié à l'environnement spécifique du dernier relais électronique en surface de l'enzyme. En particulier, l'hélice transmembranaire hydrophobe entourée de détergent est impliquée dans l'immobilisation. Cette orientation spécifique induit la nécessité d'un médiateur redox pour l'oxydation de l'H2 sur une interface hydrophobe. A contrario, l'hydrogénase adopte une multitude d'orientations sur surfaces chargées. Dans ces conditions, une connexion directe efficace des enzymes est obtenue, mais aussi l'augmentation du courant global par médiation de l'oxydation de l'H2. La définition des paramètres d'immobilisation de l'hydrogénase, a permis de développer des interfaces électrochimiques propres à l'augmentation des courants. En couplant une biocathode basée sur la bilirubin oxidase pour la réduction de l'O2, une biopile H2/O2 a été construite basée à l'anode sur l'hydrogénase d'Aquifex aeolicus. / Hydrogenases are the key enzymes for H2 conversion in many microorganisms. They present high specificity and efficiency towards H2 oxidations. Consequently, they appear as attracting biocatalysts in view of the development of biofuel cells. Within that goal, we have studied in this work the functional immobilization of O2-tolerant [NiFe] hydrogenase from the hyperthermophilic bacterium Aquifex aeolicus. Using electrochemistry, microscopy and spectroscopy, including PM-IRRAS, it is demonstrated that hydrogenase orientation on electrode interface is not controlled by electrostatic interactions but by hydrophobic interactions. The control of the orientation is driven by the environment of the last electron relay located at the surface of the enzyme. The hydrophobic transmembrane helix which is surrounded by neutral detergent is directly involved in the immobilization process. This specific orientation on hydrophobic interface induces the need for a redox mediator in order to achieve H2 oxidation. Conversely, hydrogenase adopts multiple orientations on charged interfaces. As a consequence, a direct and efficient connexion of enzymes is obtained, but also the increase in oxidation current is obtained due the mediated electrocatalysis. The determination of the best parameters for hydrogenase immobilization has allowed to develop new electrochemical interfaces, with increased current densities for H2 oxidation, and increased bioelectrode stability. By coupling a biocathode based on bilirubin oxidase for O2 reduction, a H2/O2 biofuel cell has been built with Aquifex aeolicus hydrogenase as the bioanode. Hydrogénase Hyperthermophile Orientation Protéine membranaire Électrochimie Pm-irras Détergent Oxydation de l’Hydrogène Biopile à combustible Hydrogenase Hyperthermophile Orientation Membrane protein Electrochemistry Pm-irras Detergent Hydrogen oxidation Biofuel cell
7	Tolerância ao CO da reação de oxidação de hidrogênio por mecanismos de oxidação: efeitos do substrato do eletrocatalisador / CO tolerance of the hydrogen oxidation reaction by oxidation mechanisms: effects of electrocatalyst substrate Iezzi, Renato Caio 14 October 2016 (has links) O alto custo da produção de hidrogênio puro para ser usado como combustível para uma reação de oxidação de hidrogênio (ROH) em células a combustível faz com que seja atrativo o uso de hidrogênio gerado através da reforma de combustíveis fóssil. Entretanto, o hidrogênio gerado por reforma de outros combustíveis possui contaminantes como CO, que por se adsorver fortemente sobre a superfície do eletrodo de platina, prejudica em muito o processo de oxidação do hidrogênio. Assim o estudo de novos catalisadores mais resistentes a essa contaminação e de outros mecanismos que contribuam para um melhor desempenha de uma célula a combustível do tipo PEMFC, se faz necessário. Esse presente trabalho tem como objetivo o estudo dos catalisadores PtMo/C - 80:20, PtMoO2/C, PtMoO3/C, que foram sintetizados, e PtMoPtRu/C, PtMoPt3Fe/C e PtMoPt3FePtRu/C que foram obtidos através da mistura do PtMo/C - 80:20 sintetizado com os PtRu/C e PtFe/C que são comerciais, através da realização de curvas de polarização no estado estacionário, voltametrias cíclicas e degradação eletroquímica acelerada. Também foi avaliada a eficiência da membrana de Aquivion®, com relação ao cruzamento de subprodutos da degradação dos eletrodos, através de curvas de polarização no estado estacionário, voltametrias cíclicas e variação de temperatura de operação da célula PEMFC. O método usado para a síntese dos eletrocatalisadores se mostrou eficiente na obtenção dos catalisadores, obtendo-se os catalisadores com proporção bem próxima da desejada. Os resultados mostraram uma grande estabilidade química dos catalisadores mistos sendo o PtMoPt3FePtRu/C o mais estável e o PtMoPtRu/C o catalisador mais ativo para uma ROH. Os experimentos com a membrana de Aquivion® mostraram que essa é capaz de diminuir o cruzamento de subprodutos da degradação dos eletrodos. / The high cost of pure hydrogen production to be used as fuel for a hydrogen oxidation reaction (HOR) in fuel cells makes it attractive to use hydrogen generated by reforming of fossil fuels. However, the hydrogen generated by reforming other fuels has contaminants such as CO, which adsorb strongly on the surface of the platinum electrode, affect much the hydrogen oxidation process. Thus the study of new catalysts more resistant to such contamination and other mechanisms that contribute to a better performs of a fuel cell of the PEMFC type, it is necessary. This present study aims to study of catalysts PtMo/C - 80:20 PtMoO2/C, PtMoO3/C, which were synthesized and PtMoPtRu/C, PtMoPt3Fe/C and PtMoPt3FePtRu/C which were obtained by mixing the PtMo/C - 80:20 synthesized with PtRu/C and PtFe/C which are commercial, by performing polarization curves at steady state, cyclic voltammetry and electrochemical degradation accelerated. It also evaluated the efficiency of Aquivion® membrane with respect to the cross-products of degradation of the electrodes by means of polarization curves at steady state, cyclic voltammetry and operating temperature range of the cell PEMFC. The method used for the synthesis of electrocatalysts proved efficient in obtaining the catalysts, the catalysts obtaining very near to the desired proportion. The results showed a great chemical stability of the mixed catalyst being PtMoPt3FePtRu/C more stable and PtMoPtRu/C as catalyst more active for HOR. Experiments with Aquivion® membrane have shown that this can reduce the cross-products of degradation of the electrodes. Aquivion Aquivion Electrocatalyst Eletrocatalisador Hydrogen oxidation Nafion Nafion Oxidação de hidrogênio Proton exchange membrane fuel cells Tolerance to CO Tolerância ao CO
8	Desenvolvimento de eletrocatalisadores a base de paládio dispersos em carbono para a reação de oxidação de hidrogênio na presença de CO / Development of palladium base electrocatalysts dispersed on carbon for the hydrogen oxidation reaction in the presence of CO Garcia, Amanda Cristina 03 October 2007 (has links) A performance de células a combustível de membrana de troca polimérica (PEMFC) alimentadas com hidrogênio contaminado com CO foi investigada para ânodos com eletrocatalisadores de PdPt/C e PdPtRu/C em diferentes proporções. Os materiais produzidos foram caracterizados por energia dispersiva de raios-X (EDX) e difração de raios-X (DRX). As propriedades eletrônicas da Pt foram analisadas por espectroscopia de absorção de raios-X (XAS) na região de XANES (X-ray absorption near edge structure). As avaliações do desempenho eletroquímico foram feitas através do levantamento sistemático de curvas de polarização de estado estacionário, voltametria cíclica e stripping de CO em células a combustível unitárias. Também foram feitas medidas de espectrometria eletroquímica diferencial de massas para avaliar o monitoramento de CO2 (massa/carga 44). Foi observada uma pequena diminuição da magnitude da linha branca nos espectros para as ligas PdPt/C e PdPtRu/C quando comparados com Pt/C, sendo que este fenômeno foi atribuído a um aumento de ocupação da banda Pt 5d. Melhores resultados com relação a tolerância ao CO da reação de oxidação de hidrogênio foram obtidos para os catalisadores PdPt/C e PdPtRu/C quando comparados com Pt e Pd puros. Nenhum efeito sinérgico favorável foi observado com a adição de Ru. O monitoramento de CO2 nos experimentos de espectrometria de massas (DEMS), enquanto as células eram alimentadas com H2 + 100 ppm CO, mostrou aumento na quantidade de formação deste produto somente para ânodos contendo PdPtRu/C e nenhuma formação de CO2 do início ao final das variações de potenciais nos casos dos eletrodos contendo PdPt/C. / The performance of proton exchange membrane fuel cells (PEMFC) fed with CO-contaminated hydrogen was investigated for anodes with PdPt/C and PdPtRu/C electrocatalysts at different ratios. The produced materials were characterized by energy dispersive (EDX) and X-ray diffraction (XRD). The electronics properties of Pt were analyzed by X-ray absorption spectroscopy (XAS) X-ray absorption near edge structure (XANES) in the region. Evaluations of the electrochemical performance were carried out by steady state single cell polarization measurements, cyclic voltammetry and the CO-stripping techniques. Measurements of differential electrochemical mass spectrometry (DEMS) were carried out to evaluate the CO2 (mass 44) formation. A small reduction of the white line magnitude was in the XANES spectro for the PdPt/C and PdPtRu/C alloys when compared with Pt/C. This phenomenon was assigned for the increase of occupation of the Pt 5d band. Higher CO-tolerances were obtained for the PdPt/C and PdPtRu/C catalysts when compared with those for pure Pd/C and Pt/C. No favorable synergistic effect occurred with Ru addition in the electrode performance for the PEMFC fed with H2+100 ppm CO. The CO2 (mass 44) monitoring with DEMS experiments with the cells fed with H2+100 ppm CO showed the formation of this product only to PdPtRu/C, while no CO2 formation could be detected from beginning to end potential in the cases of Pd/C and PdPt/C. carbon monoxide células a combustível electrocatalysts of PdPt/C and PdPtRu/C eletrocatalisadores de PdPt/C e PdPtRu/C fuel cell hydrogen oxidation reaction monóxido de carbono reação de oxidação de hidrogênio
9	Catalytic and Electrocatalytic Pathways in Fuel Cells Vilekar, Saurabh A. 19 April 2010 (has links) A fundamental understanding of the kinetics and mechanisms of the catalytic reaction steps involved in the process of converting a fuel into hydrogen rich stream suitable for a fuel cell, as well as the electro-catalytic reactions within a fuel cell, is not only conceptually appealing, but could provide a sound basis for the design and development of efficient fuel processor/fuel cell systems. With the quantum chemical calculations on kinetics of elementary catalytic reaction steps becoming rather commonplace, and with increasing information now available in terms of electronic structures, vibration spectra, and kinetic data (activation energy and pre-exponential factors), the stage is set for development of a comprehensive approach. Toward this end, we have developed a framework that can utilize this basic information to develop a comprehensive understanding of catalytic and electrocatalytic reaction networks. The approach is based on the development of Reaction Route (RR) Graphs, which not only represent the reaction pathways pictorially, but are quantitative networks consistent with the Kirchhoff's laws of flow networks, allowing a detailed quantitative analysis by exploiting the analogy with electrical circuits. The result is an unambiguous portrayal of the reaction scheme that lays bare the dominant pathways. Further, the rate-limiting steps are identified rationally with ease, based on comparison of step resistances, as are the dominant pathways via flux analysis. In fact, explicit steady-state overall reaction (OR) rate expression can also be derived in an Ohm's law form, i.e. OR rate = OR motive force/OR resistance of an equivalent electric circuit, which derives directly from the RR graph of its mechanism. This approach is utilized for a detailed analysis of the catalytic and electro-catalytic reaction systems involved in reformer/fuel cell systems. The catalytic reaction systems considered include methanol decomposition, water gas shift, ammonia decomposition, and methane steam reforming, which have been studied mechanistically and kinetically. A detailed analysis of the electro-catalytic reactions in connection to the anode and cathode of fuel cells, i.e. hydrogen electrode reaction and the oxygen reduction reaction, has also been accomplished. These reaction systems have not so far been investigated at this level of detail. The basic underlying principles of the RR graphs and the topological analysis for these reaction systems are discussed. methane steam reforming water gas shit ammonia decomposition hydrogen oxidation methanol decomposition electro-catalysis fuel cells reaction route graph theory oxygen reduction fuel cell model catalysis
10	Elucidation of hydrogen oxidation kinetics on metal/proton conductor interface Feng, Shi 16 September 2013 (has links) High temperature proton conducting perovskite oxides are very attractive materials for applications in electrochemical devices, such as solid oxide fuel cells (SOFCs) and hydrogen permeation membranes. A better understanding of the hydrogen oxidation mechanism over the metal/proton conductor interface, is critical for rational design to further enhance the performances of the applications. However, kinetic studies focused on the metal/proton system are limited, compared with the intensively studied metal/oxygen ion conductor system, e.g., Ni/YSZ (yttrium stabilized zirconia, Zr₁-ₓYₓO₂-δ). This work presents an elementary kinetic model developed to assess reaction pathway of hydrogen oxidation/reduction on metal/proton conductor interface. Individual rate expressions and overall hydrogen partial pressure dependencies of current density and polarization resistance were derived in different rate limiting cases. The model is testified by tailored experiments on Pt/BaZr₀.₁Ce₀.₇Y₀.₁Yb₀.₁O₃-δ (BZCYYb) interface using pattern electrodes. Comparison of electrochemical testing and the theoretical predictions indicates the dissociation of hydrogen is the rate-limiting step (RLS), instead of charge transfer, displaying behavior different from metal/oxygen ion conductor interfaces. The kinetic model presented in this thesis is validated by high quantitative agreement with experiments under various conditions. The discovery not only contributes to the fundamental understanding of the hydrogen oxidation kinetics over metal/proton conductors, but provides insights for rational design of hydrogen oxidation catalysts in a variety of electrochemical systems. Solid oxide fuel cells Hydrogen separation Ceramic membranes Hydrogen oxidation kinetics Kinetic model Pattern electrode Rate limiting step Electrochemical apparatus Electrochemistry Fuel cells

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