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Application of the Entropy Concept to Thermodynamics and Life Sciences: Evolution Parallels Thermodynamics, Cellulose Hydrolysis Thermodynamics, and Ordered and Disordered Vacancies ThermodynamicsPopovic, Marko 01 June 2018 (has links)
Entropy, first introduced in thermodynamics, is used in a wide range of fields. Chapter 1 discusses some important theoretical and practical aspects of entropy: what is entropy, is it subjective or objective, and how to properly apply it to living organisms. Chapter 2 presents applications of entropy to evolution. Chapter 3 shows how cellulosic biofuel production can be improved. Chapter 4 shows how lattice vacancies influence the thermodynamic properties of materials. To determine the nature of thermodynamic entropy, Chapters 1 and 2 describe the roots, the conceptual history of entropy, as well as its path of development and application. From the viewpoint of physics, thermal entropy is a measure of useless energy stored in a system resulting from thermal motion of particles. Thermal entropy is a non-negative objective property. The negentropy concept, while mathematically correct, is physically misleading. This dissertation hypothesizes that concepts from thermodynamics and statistical mechanics can be used to define statistical measurements, similar to thermodynamic entropy, to summarize the convergence of processes driven by random inputs subject to deterministic constraints. A primary example discussed here is evolution in biological systems. As discussed in this dissertation, the first and second laws of thermodynamics do not translate directly into parallel laws for the biome. But, the fundamental principles on which thermodynamic entropy is based are also true for information. Based on these principles, it is shown that adaptation and evolution are stochastically deterministic. Chapter 3 discusses the hydrolysis of cellulose to glucose, which is a key reaction in renewable energy from biomass and in mineralization of soil organic matter to CO2. Conditional thermodynamic parameters, ΔhydG', ΔhydH', and ΔhydS', and equilibrium glucose concentrations are reported for the reaction C6H10O5(cellulose) + H2O(l) ⇄ C6H12O6(aq) as functions of temperature from 0 to 100°C. Activity coefficients of aqueous glucose solution were determined as a function of temperature. The results suggest that producing cellulosic biofuels at higher temperatures will result in higher conversion. Chapter 4 presents the data and a theory relating the linear term in the low temperature heat capacity to lattice vacancy concentration. The theory gives a quantitative result for disordered vacancies, but overestimates the contribution from ordered vacancies because ordering leads to a decreased influence of vacancies on heat capacity.
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A first-principles non-equilibrium molecular dynamicsstudy of oxygen diffusion in Sm-doped ceriaKlarbring, Johan January 2015 (has links)
Solid oxide fuel cells are considered as one of the main alternatives for future sources of clean energy. To further improve their performance, theoretical methods able to describe the diffusion process in candidate electrolyte materials at finite temperatures are needed. The method of choice for simulating systems at finite temperature is molecular dynamics. However, if the forces are calculated directly from the Schrödinger equation (first-principles molecular dynamics) the computational expense is too high to allow long enough simulations to properly capture the diffusion process in most materials. This thesis introduces a method to deal with this problem using an external force field to speed up the diffusion process in the simulation. The method is applied to study the diffusion of oxygen ions in Sm-doped ceria, which has showed promise in its use as an electrolyte. Good agreement with experimental data is demonstrated, indicating high potential for future applications of the method.
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Optimization of Ionic Conductivity in Doped Ceria Using Density Functional Theory and Kinetic Lattice Monte CarloJanuary 2011 (has links)
abstract: Fuel cells, particularly solid oxide fuel cells (SOFC), are important for the future of greener and more efficient energy sources. Although SOFCs have been in existence for over fifty years, they have not been deployed extensively because they need to be operated at a high temperature (∼1000 °C), are expensive, and have slow response to changes in energy demands. One important need for commercialization of SOFCs is a lowering of their operating temperature, which requires an electrolyte that can operate at lower temperatures. Doped ceria is one such candidate. For this dissertation work I have studied different types of doped ceria to understand the mechanism of oxygen vacancy diffusion through the bulk. Doped ceria is important because they have high ionic conductivities thus making them attractive candidates for the electrolytes of solid oxide fuel cells. In particular, I have studied how the ionic conductivities are improved in these doped materials by studying the oxygen-vacancy formations and migrations. In this dissertation I describe the application of density functional theory (DFT) and Kinetic Lattice Monte Carlo (KLMC) simulations to calculate the vacancy diffusion and ionic conductivities in doped ceria. The dopants used are praseodymium (Pr), gadolinium (Gd), and neodymium (Nd), all belonging to the lanthanide series. The activation energies for vacancy migration between different nearest neighbor (relative to the dopant) positions were calculated using the commercial DFT code VASP (Vienna Ab-initio Simulation Package). These activation energies were then used as inputs to the KLMC code that I co-developed. The KLMC code was run for different temperatures (673 K to 1073 K) and for different dopant concentrations (0 to 40%). These simulations have resulted in the prediction of dopant concentrations for maximum ionic conductivity at a given temperature. / Dissertation/Thesis / Ph.D. Materials Science and Engineering 2011
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Synthesis and characterisation of CeO?, Sm?O? and Sm-doped CeO? nanoparticles with unique morphologiesBugayeva, Natalia January 2006 (has links)
[Truncated abstract] This work was concerned with investigations into the synthesis of Ce(OH)4, Sm(OH)3 and hydrated Ce-Sm mixed oxide nanoparticles with anisotropic morphologies via a chemical precipitation technique. The effect of various experimental parameters including temperature, aging time, ionic environment and thermal treatment on the morphology, structure of nanoparticles as well as elemental homogeneity of the mixed oxide nanoparticles was emphasised. It was shown that different experimental conditions resulted in different particle morphologies. This suggested that by tuning experimental parameters an ultimate goal of nanotechnology, the formation of nanoparticles with desired morphologies and sizes, may be achieved. It was found that by modifying experimental parameters it was possible to influence the development of various morphological and structural characteristics of Ce(OH)4 nanoparticles. The resulting morphologies were fibrous needle-like, rod-like and nanowire particles of various sizes. Characterisation of the nanoparticles was conducted through analysis by X-ray diffraction, surface area analysis and transmission electron microscopy techniques. Investigations into the structure of the hydrated CeO2 nanoparticles were undertaken since it is considered to be a key to the relevant properties of the material. The structure was found to exhibit multiple twinning phenomenon with 5-fold symmetry, with a consequence that atomic planes formed the particle surface. However, upon thermal treatment of needle-like particles, structural transformation was observed that possibly led to the development of more reactive and particle circumferential facets. A structural model and formation mechanism of such structures was proposed. ... A preliminary study into suitability of particle anisotropic morphology for compaction and densification processes was undertaken. Investigations into the sintering behaviour of the particles with anisotropic morphology were conducted on ceria nanoneedles. It was found that these particles displayed favourable sintering characteristics. The final densities of the hydrated ceria needle-like particle samples were achieved as high as 94.1% of the theoretical density after sintering at 1100°C for 5 hours.
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S?ntese e caracteriza??o de NiO-CGO para anodo e eletr?litos s?lidos e base de C?ria para SOFCCella, Beatriz 04 January 2009 (has links)
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Previous issue date: 2009-01-04 / The direct use of natural gas makes the Solid Oxide Fuel Cell (SOFC) potentially more competitive with the current energy conversions technologies. The Intermediate Temperature SOFC (IT-SOFC) offer several advantages over the High
Temperature SOFC (HT-SOFC), which includes better thermal compatibility among components, fast start with lower energy consumption, manufacture and operation cost reduction. The CeO2 based materials are alternatives to the Yttria Stabilized
Zirconia (YSZ) to application in SOFC, as they have higher ionic conductivity and less ohmic losses comparing to YSZ, and they can operate at lower temperatures (500-800?C). Ceria has been doped with a variety of cations, although, the Gd3+ has the ionic radius closest to the ideal one to form solid solution. These electrolytes based in ceria require special electrodes with a higher performance and chemical and termomechanical compatibility. In this work compounds of gadolinia-doped ceria, Ce1-xGdxO2-δ (x = 0,1; 0,2 and 0,3), used as electrolytes, were synthesized by polymeric precursors method, Pechini, as well as the composite material NiO - Ce0,9Gd0,1O1,95, used as anode, also attained by oxide mixture method, mixturing the powders of the both phases calcinated already. The materials were characterized by X ray diffraction, dilatometry and scanning electronic microscopy. The refinement of the diffraction data indicated that all the Ce1-xGdxO2-δ powders were crystallized in a
unique cubic phase with fluorite structure, and the composite synthesized by Pechini method produced smaller crystallite size in comparison with the same material attained by oxide mixture method. All the produced powders had nanometric
characteristics. The composite produced by Pechini method has microstructural characteristics that can increase the triple phase boundaries (TPB) in the anode, improving the cell efficiency, as well as reducing the mass transport mechanism
effect that provokes anode degradation / A utiliza??o direta do g?s natural torna a c?lula a combust?vel de ?xido s?lido (SOFC) potencialmente mais competitiva com as atuais tecnologias para convers?o de energia. A SOFC de temperatura intermedi?ria (IT-SOFC) oferece muitas
vantagens sobre a SOFC de alta temperatura (HT-SOFC), que incluem melhor compatibilidade t?rmica entre os componentes, partida r?pida com menos consumo energ?tico, redu??o de custos de obten??o e opera??o. Os materiais baseados em
CeO2 s?o alternativas aos eletr?litos de zirc?nia estabilizada com ?tria (YSZ) para aplica??es em SOFC, pois t?m condutividade i?nica maior e menores perdas ?hmicas em compara??o a YSZ, e podem operar a temperaturas mais baixas (500-800?C). C?ria tem sido dopada com uma variedade de c?tions, entretanto, o Gd3+ possui o raio i?nico mais pr?ximo do ideal para forma??o da solu??o s?lida. Esses
eletr?litos baseados em c?rio requerem eletrodos especiais com um alto desempenho e compatibilidade termomec?nica e qu?mica. Neste trabalho compostos c?ria dopada com gadol?nia, Ce1-xGdxO2-δ (x = 0,1; 0,2 e 0,3), utilizadas como
eletr?litos, foram sintetizados a partir do m?todo dos precursores polim?ricos, Pechini, assim como o material comp?sito NiO - Ce0,9Gd0,1O1,95, usado para anodo,
obtido tamb?m pelo m?todo de mistura dos ?xidos, p?s das duas fases j? calcinadas. Os materiais foram caracterizados atrav?s das t?cnicas de difra??o de raios X, dilatometria e microscopia eletr?nica de varredura. O refinamento dos dados
obtidos pela difra??o de raios X indicou que todos os p?s de Ce1-xGdxO2-δ cristalizaram em uma ?nica fase c?bica com estrutura fluorita, e que o comp?sito obtido por Pechini produziu menores tamanhos de cristalitos das fases em
compara??o com o p? sintetizado por mistura de ?xidos em uma mesma temperatura de calcina??o. Todos os p?s obtidos t?m caracter?sticas nanom?tricas. O comp?sito obtido por Pechini possui caracter?sticas microestruturais que podem
aumentar a fronteira de fase tripla (TPB) dentro do anodo, melhorando a efici?ncia da c?lula, assim como reduzir o efeito do mecanismo de transporte de massa que provoca degrada??o do anodo
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Influ?ncia do m?todo de s?ntese e caracteriza??o de p?s comp?sitos de NiO- Ce1-xEuxO2-δ para anodos catal?ticos de c?lulas a combust?velMedeiros, Amanda Lucena de 06 February 2013 (has links)
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Previous issue date: 2013-02-06 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico / Fuel cells are electrochemical devices that convert chemical energy into electricity.
Due to the development of new materials, fuel cells are emerging as generating
clean energy generator. Among the types of fuel cells, categorized according to the
electrode type, the solid oxide fuel cells (SOFC) stand out due to be the only device
entirely made of solid particles. Beyond that, their operation temperature is relatively
high (between 500 and 1000 ?C), allowing them to operate with high efficiency.
Another aspect that promotes the use of SOFC over other cells is their ability to
operate with different fuels. The CeO2 based materials doped with rare earth (TR+3)
may be used as alternatives to traditional NiO-YSZ anodes as they have higher ionic
conductivity and smaller ohmic losses compared to YSZ, and can operate at lower
temperatures (500-800?C). In the composition of the anode, the concentration of NiO,
acting as a catalyst in YSZ provides high electrical conductivity and high
electrochemical activity of reactions, providing internal reform in the cell. In this work
compounds of NiO - Ce1-xEuxO2-δ (x = 0.1, 0.2 and 0.3) were synthesized from
polymeric precursor, Pechini, method of combustion and also by microwave-assisted
hydrothermal method. The materials were characterized by the techniques of TG,
TPR, XRD and FEG-SEM. The refinement of data obtained by X-ray diffraction
showed that all powders of NiO - Cex-1EuxO2-δ crystallized in a cubic phase with
fluorite structure, and also the presence of Ni. Through the characterizations can be
proved that all routes of preparation used were effective for producing ceramics with
characteristics suitable for application as SOFC anodes, but the microwave-assisted
hydrothermal method showed a significant reduction in the average grain size and
improved control of the compositions of the phases / C?lulas a combust?vel s?o dispositivos eletroqu?micos que convertem a energia
qu?mica em el?trica. Em virtude do desenvolvimento de novos materiais, as c?lulas a
combust?vel v?m se destacando como promissores na gera??o de energia de forma
limpa. Dentre os tipos de c?lulas a combust?vel, classificadas de acordo com o tipo
de eletr?lito, destacam-se as de ?xido s?lido (SOFC), por serem as ?nicas
inteiramente constitu?das por s?lidos. Al?m disso, pela sua temperatura de opera??o
ser relativamente elevada (entre 500 e 1000 ?C), estas c?lulas operam com alta
efici?ncia. Outro aspecto que favorece o emprego de SOFC ? a sua habilidade de
operar com diferentes combust?veis, como fontes de hidrog?nio.Os materiais a base
de CeO2 dopados com terras raras (TR+3) podem ser utilizados como alternativas
aos tradicionais anodos de NiO-YSZ. Al?m de maior condutividade i?nica maior e
menores perdas ?hmicas, elas podem operar a temperaturas mais baixas (500-
800?C). Na composi??o do anodo, a concentra??o de NiO, atuando como catalisador
confere alta condutividade el?trica e alta atividade eletroqu?mica das rea??es,
proporcionando a reforma interna do combust?vel na c?lula. Neste trabalho
compostos de NiO - Ce1-xEuxO2-δ (x = 0,1; 0,2 e 0,3), foram sintetizados a partir do
m?todo dos precursores polim?ricos, Pechini, do m?todo de combust?o e, tamb?m,
pelo m?todo hidrotermal assistido por micro-ondas. Os materiais obtidos foram
caracterizados atrav?s das t?cnicas de TG, DRX, TPR e MEV-FEG. O refinamento
dos dados obtidos pela difra??o de raios X indicou que todos os p?s de NiO - Ce1-
xEuxO2-δ cristalizaram-se em uma fase c?bica com estrutura fluorita, e tamb?m a
presen?a de NiO. Todas as rotas de prepara??o utilizadas mostraram-se eficientes
para a produ??o de p?s com caracter?sticas adequadas para aplica??o como anodos
de SOFC, por?m o m?todo hidrotermal assistido por micro-ondas apresentou
significativa redu??o do tamanho m?dio de gr?os e melhor controle das
composi??es das fases
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New solid state oxygen and hydrogen conducting materials. Towards their applications as high temperature electrochemical devices and gas separation membranesBalaguer Ramírez, María 02 September 2013 (has links)
Los materiales conductores mixtos de electrones e iones (oxígeno o
protones) son capaces de separar oxígeno o hidrógeno de los gases de combustión
o de corrientes de reformado a alta temperatura. La selectividad de este proceso
es del 100%. Estos materiales, óxidos sólidos densos, pueden usarse en la
producción de electricidad a partir de combustibles fósiles, así como formar parte
de los procesos que forman parte del sistema de captura y almacenamiento de
CO2. Las membranas de transporte de oxígeno (MTO) se pueden utilizar en las
plantas energéticas con procesos de oxicombustión, así como en reactores
catalíticos de membrana (RCM), mientras que las membranas de transporte de
hidrógeno (MTH) se aplican en procesos de precombustión. Además, estos
materiales encuentran aplicación en componentes de sistemas energéticos, como
electrodos o electrolitos de pilas de combustible de óxido sólido, de ambas clases
iónicas y protónicas (SOFC y PC-SOFC).
Los procesos mencionados implican condiciones de operación muy
severas, como altas temperaturas y grandes gradientes de presión parcial de
oxígeno (pO2), probablemente combinadas con la presencia de CO2 and SO2. Los
materiales más que mayor rendimiento de separación presentan y más
ampliamente investigados en este campo son inestables en estas condiciones. Por
tanto, existe la necesidad de encontrar nuevos materiales inorgánicos estables que
proporcionen alta conductividad electrónica e iónica.
La presente tesis propone una búsqueda sistemática de nuevos
conductores iónicos-electrónicos mixtos (MIEC, del inglés) con diferente
estructura cristalina y/o diferente composición, variando la naturaleza de los
elementos y la estequiometría del cristal. La investigación ha dado lugar a materiales capaces de transportar iones oxígeno, protones o cargas electrónicas y
que son estables en las condiciones de operación.
La caracterización de una amplia serie de cerias (CeO2) dopadas con
lantánidos proporciona una comprensión general de las propiedades estructurales
y de transporte, así como la relación entre ellas. Además, se estudia el efecto de la
adición de cobalto a dicho sistema. Se ha completado el análisis con la
optimización de las propiedades de trasporte a partir de la microestructura. Todo
esto permite hacer una clasificación inicial de los materiales basada en el
comportamiento de transporte principal y permite adecuar la estructura y las
condiciones de operación para obtener las propiedades deseadas para cada
aplicación.
Algunos de los materiales extraídos de este estudio alcanzaron las
expectativas. Las familias de materiales basadas en Ce1-x
Tbx
O2-¿
y Ce1-x
Tbx
O2-¿
+2 mol% Co proporcionan flujos de oxígeno bajos pero competitivos, ya que son
estables en atmósferas con CO2. Además, la inclusión de estos materiales en
membranas de dos fases aumenta el flujo de oxígeno. La combinación con una
espinela libre de cobalto y de metales alcalinotérreos como es el Fe2
NiO4, ha
dado lugar a un material prometedor en cuanto a flujo de oxígeno y estabilidad en
CO2 y en SO2, que podría ser integrado en el proceso de oxicombustión.
Por otra parte, se ha añadido metales como codopantes en el sistema
Ce0.9-x
Mx
Gd0.1O1.95. Estos materiales, en combinación con la perovskita La1-
x
Srx
MnO3 usada comúnmente como cátodo de SOFC, han sido capaces de
disminuir la resistencia de polarización del cátodo. La mejora es consecuencia de
la introducción de conductividad iónica por parte de la ceria.
Las perovskitas dopadas basadas en CaTiO3 forman el segundo grupo de
materiales investigados. La dificultad de obtener perovskitas estables y que presenten conducción mixta iónica y electrónica se ha hecho evidente. De entre
los dopantes utilizados, el hierro y la combinación hierro-magnesio han sido los
mejores candidatos. Ambos materiales presentan conductividad principalmente
iónica a alta temperatura, mientras que a baja predomina la conductividad
electrónica tipo p. CaTi0.73Fe0.18Mg0.09O3-¿ se ha mostrado como un material
competente en la fabricación de membranas de oxígeno, que proporciona flujos
adecuados a la par que estabilidad en CO2.
Finalmente, la perovskita La0.87Sr0.13CrO3 (LSC) ha sido dopada con el
objetivo de aumentar la conductividad mixta protónica electrónica. Este estudio
ha llevado al desarrollo de una nueva generación de ánodos para PC-SOFC
basadas en electrolitos de LWO. Las perovskitas dopadas con Ce en el sitio del
La (LSCCe) y con Ni en el sitio del Cr (LSCN) son estables en condiciones de
operación reductoras, así como en contacto con el electrolito. El uso de ambos
materiales como ánodo disminuye la resistencia de polarización con respecto al
LSC. El LSCCe está limitado por los procesos que ocurren a baja frecuencia
(BF), relacionados con los procesos superficiales, y que son atenuados en el caso
del LSCN debido a la formación de nanopartículas de Ni metálico en la
superficie. La infiltración posterior con nanopartículas de Ni permite disminuir la
resistencia a BF lo que sugiere que la reacción superficial de oxidación del H2
está siendo catalizada. La infiltración más concentrada en Ni (5Ni) elimina
completamente la resistencia a BF en ambos ánodos, de forma que los procesos
que ocurren a altas frecuencias son ahora limitantes. El ánodo constituido por
LSCNi20+5Ni dio una resistencia de polarización de 0.26 ¿·cm
2
at 750 ºC en H2
húmedo. / Mixed ionic (oxygen ions or protons) and electronic conducting materials
(MIEC) separate oxygen or hydrogen from flue gas or reforming streams at high
temperature in a process 100% selective to the ion. These solid oxide materials
may be used in the production of electricity from fossil fuels (coal or natural gas),
taking part of the CO2 separation and storage system. Dense oxygen transport
membranes (OTM) can be used in oxyfuel combustion plants or in catalytic
membrane reactors (CMR), while hydrogen transport membranes (HTM) would
be applied in precombustion plants. Furthermore, these materials may also be
used in components for energy systems, as advanced electrodes or electrolytes for
solid oxide fuel cells (SOFC) and proton conducting solid oxide fuel cells (PCSOFC)
working at high and moderate temperature.
The harsh working conditions stablished by the targeted processes
include high temperatures and low O2 partial pressures (pO2), probably
combined with CO2 and SO2 containing gases. The instability disadvantages
presented by the most widely studied materials for these purposes make them
impractical for application to gas separation. Thus, the need to discover new
stable inorganic materials providing high electronic and ionic conductivity is
still present.
This thesis presents a systematic search for new mixed ionic-electronic
conductors. It includes different crystalline structures and/or composition of the
crystal lattice, varying the nature of the elements and the stoichiometry of the
crystal. The research has yielded new materials capable to transport oxygen ions
or protons and electronic carriers that are stable in the working condition to
which they are submitted. / Balaguer Ramírez, M. (2013). New solid state oxygen and hydrogen conducting materials. Towards their applications as high
temperature electrochemical devices and gas separation membranes [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/31654 / Premios Extraordinarios de tesis doctorales
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The development of alternative cathodes for high temperature solid oxide electrolysis cellsYue, Xiangling January 2013 (has links)
This study mainly explores the development of alternative cathode materials for the electrochemical reduction of CO₂ by high temperature solid oxide electrolysis cells (HTSOECs), which operate in the reverse manner of solid oxide fuel cells (SOFCs). The conventional Ni-yttria stabilized zirconia (YSZ) cermets cathode suffered from coke formation, whereas the perovskite-type (La, Sr)(Cr, Mn)O₃ (LSCM) oxide material displayed excellent carbon resistance. Initial CO₂ electrolysis performance tests from different cathode materials prepared by screen-printing showed that LSCM based cathode performed poorer than Ni-YSZ cermets, due to non-optimized microstructure. Efforts were made on microstructure modification of LSCM based cathodes by means of various fabrication methods. Among the LSCM/YSZ graded cathode, extra catalyst (including Pd, Ni, CeO₂, and Pt) aided LSCM/GDC (Gd₀.₁Ce₀.₉O₁.₉₅) cathode, LSCM impregnated YSZ cathode, and GDC impregnated LSCM cathode, the GDC impregnated LSCM cathode, with porous LSCM as backbone for finely dispersed GDC nanoparticles, was found to possess the desired microstructure for CO₂ splitting reaction via SOEC. Incorporating of 0.5wt% Pd into GDC impregnated LSCM cathode gave rise to an Rp of 0.24 Ω cm² at open circuit voltage (OCV) at 900°C in CO₂-CO 70-30 mixture, comparable with the Ni/YSZ cermet cathode operated in the identical conditions. Meanwhile, the cathode kinetics and possible mechanisms of the electrochemical reduction of CO₂ were studied, and factors including CO₂/CO composition, operation temperature and potential were taken into account. The current-to-chemical efficiency of CO₂ electrolysis was evaluated with gas chromatography (GC). The high performance Pd and GDC co-impregnated LSCM cathode was also applied for CO₂ electrolysis without protective CO gas in feed. This cathode also displayed superb performance towards CO₂ electrochemical reduction under SOEC operation condition in CO₂/N₂ mixtures, though it had OCV as low as 0.12V at 900°C. The LSCM/GDC set of SOEC cathode materials were investigated in the application of steam electrolysis and H₂O-CO₂ co-electrolysis as well. For the former, adequate supply of steam was essential to avoid the appearance of S-shaped I-V curves and limited steam transport. The 0.5wt% Pd and GDC co-infiltrated LSCM material has been found to be a versatile cathode with high performance and good durability in SOEC operations.
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Carbon Dioxide Reduction on Gadolinia-Doped Ceria CathodesGreen, Robert David 22 January 2009 (has links)
No description available.
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