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Síntese e caracterização de derivados de polipirrol para aplicação em dispositivos eletroquímicos / Synthesis and characterization of polypyrrole derivatives for application in electrochemical devicesNogueira, Fred Augusto Ribeiro 11 May 2010 (has links)
In this study was studied the capacitive properties of films poly (12-pyrrol-1 yl dodecanoic acid) and electrochromic properties of films poly [1 - (3-brominepropylpyrrole)] prepared by electrochemical methods and deposited on ITO. The polymers were obtained using electrochemical methods and characterized by electrochemical, morphological and optical techniques. Cyclic voltammograms of both polymers showed the presence of a redox couple attributed to the doping-undoped process the polymer. The analysis by infrared spectroscopy for poly (12-pyrrol-1 yl dodecanoic acid) suggested the coupling of the monomers through the alpha positions. The capacitive properties of a poly (12-pyrrol-1 yl dodecanoic acid) were investigated by calculation of the coulombic efficiency (86.6%) and specific capacitance (291 F g-1) obtained from the charge-discharge curves of films obtained by galvanostatic method. The values obtained for these parameters demonstrated the possibility of applications of these films in capacitive devices. The UV-Vis spectra for films of poly [1 - (3-brominepropylpyrrole)] showed absorption bands at  = 335 and 500 nm. The films of poly [1 - (3-brominepropylpyrrole)] show variations in color depending on the applied potential. The electrochromic properties of these films were investigated by calculation of chromatic contrast (18.97 and 20.46 %), coulombic efficiency (61.1%), and electrochromic (248.6 and 470.2 cm2 C-1). The values obtained for these parameters demonstrated the possibility of applications of these films in electrochromic devices / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Neste trabalho foram estudadas as propriedades capacitivas de filmes de poli [ácido (12-pirolildodecanóico)] e as propriedades eletrocrômicas de filmes de poli [1-(3-bromopropilpirrol)] preparados por métodos eletroquímicos e depositados sobre ITO. Os polímeros foram obtidos através dos métodos eletroquímicos e caracterizados por técnicas eletroquímicas, morfológicas e ópticas. Os voltamogramas cíclicos de ambos os polímeros evidenciaram a presença de um par redox atribuído ao processo de dopagem-desdopagem do polímero. As análises por espectroscopia de infravermelho para os filmes poliméricos de poli [ácido (12-pirolildodecanóico)] sugeriram o acoplamento dos monômeros através das posições alfa. As propriedades capacitivas do filme de poli [ácido (12-pirolildodecanóico)] foram investigadas através de cálculos da eficiência coulômbica (86,6%) e da capacitância específicas (291 F g-1) obtidas a partir das curvas de carga-descarga dos filmes obtidos pelo método galvanostático. Os valores obtidos para esses parâmetros demonstraram a possibilidade de aplicações destes filmes em dispositivos capacitivos. Os espectros por UV-Vis para os filmes de poli [1-(3-bromopropilpirrol)] mostraram bandas de absorção em  = 335 e 500 nm. Os filmes de poli [1-(3-bromopropilpirrol)] apresentaram variações de coloração conforme o potencial aplicado. As propriedades eletrocrômicas destes filmes foram investigadas através de cálculos do contraste cromático (18,97 e 20,46 %), eficiência coulômbica (61,1 %) e eletrocrômica (248,6 e 470,2 cm² C-1). Os valores obtidos para esses parâmetros demonstraram a possibilidade de aplicações destes filmes em dispositivos eletrocrômicos.
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Textile-based sensors for in-situ monitoring in electrochemical cells and biomedical applicationsHasanpour, Sadegh 07 December 2020 (has links)
This work explores the blending of e-textile technology with the porous electrode of
polymer electrolyte membrane fuel cells (PEMFCs) and with smart wound patches
to allow monitoring and in-situ diagnostics. This work includes contributions to understanding water transport and conductivity in the carbon cloth gas diffusion layer
(GDL), and further developing thread-based relative humidity (RH) and temperature
sensors, which can be sewn on a cloth GDL in PEMFCs. We also explore the
application of the developed RH and temperature sensors in wearable biomonitoring.
First, an experimental prototype is developed for evaluating water transport, thermal
conductivity and electrical conductivity of carbon cloth GDLs under different hydrophobic
coatings and compressions. Second, we demonstrate the addition of external
threads to the carbon cloth GDL to (1) facilitate water transport and (2) measure
local RH and temperature with a minimal impact on the physical, microstructural
and transport properties of the GDL. We illustrate the roll-to-roll process for fabricating
RH and temperature sensors by dip-coating commodity threads into a carbon
nanotubes (CNTs) suspension. The thread-based sensors response to RH and temperature in the working environment of PEMFCs is investigated. As a proof-of-concept, the local temperature of carbon cloth GDL is monitored in an ex-situ experiment.
Finally, we optimized the coating parameters (e.g. CNTs concentration, surfactant
concentration and a number of dipping) for the thread-based sensors. The
response of the thread-based sensors in room conditions is evaluated and shows a
linear resistance decrease to temperature and a quadratic resistance increase to RH.
We also evaluated the biocompatibility of the sensors by performing cell cytotoxicity
and studying wound healing in an animal model. The novel thread-based sensors
are not only applicable for textile electrochemical devices but also, show a promising
future in wearable biomonitoring applications. / Graduate
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Dispositivos eletroquímicos flexíveis empregando papel pirolisado /Damasceno, Sergio January 2019 (has links)
Orientador: Carlos Cesar Bof Bufon / Resumo: Materiais de carbono obtidos por pirólise de celulose e biopolímeros sintéticos têm sido am-plamente investigados para aplicações no desenvolvimento de dispositivos eletrônicos. Eles apresentam excelentes propriedades elétricas, mas são extremamente frágeis. Então uma alter-nativa seria integrar esses materiais em elastômeros. Assim, para a contornar a fragilidade e a questão de adesão de materiais condutores em substratos alongáveis, neste trabalho é proposto um novo método de fabricação para desenvolvimento de dispositivos eletroquímicos. Inspira-do no sistema redox eficiente das plantas e que está firmemente aderido ao solo pela estrutura das raízes, foi desenvolvido um processo de retardo do fluxo capilar do polidimetilsiloxano (PDMS) na estrutura pirolisada modificada, de forma que fibras pirolisadas integradas no elas-tômero possam garantir adesão e estabilidade mecânica, e que parte delas fique exposta para possibilitar atividade eletroquímica na interface. Baseado no modelo matemático de Lucas-Washburn, as mudanças na superfície das fibras de papel por conta da adição de acetato de celulose e a diminuição do raio dos poros resulta no retardo do fluxo da solução polimérica viscosa na estrutura porosa. Como resultado foi obtida uma superfície de eletrodo de carbono altamente ativa para reações redox. Além disso, testes mecânicos com o dispositivo flexiona-do, dobrado, e alongado, demonstraram que uma deformação linear de até 75% do tamanho inicial não tem efeitos nas pr... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Cellulose and synthetic biopolymers derived carbon materials are extensively used for application in electronic field. They show excellent electrical properties but are extremely fragile and prone to crack. Then an alternative to address this challenge and the adhesion problem reported on literature, a new fabrication route for a flexible and stretchable electrochemical device is proposed. Inspired by trees redox system that is highly adhered on the ground and based on Lucas Wash-Burn model, the pyrolyzed paper is modified with cellulose acetate. Then, in a process named delayed capillary flow of elastomers the surface changes in paper fibers and the decrease in pore radius results in a delay on capillary flow of viscous polymer polydimethylsiloxane (PDMS) solution on its porous structure. As a result, a highly active carbon surface exposed on the top for redox reactions is produced, which shows a remarkable performance and is similar to tree leaves. Also, mechanical deformation studies on the new bendable, twistable, flexible, and stretchable device reveal a linear stretch up to 75%, without effects on its electrochemical properties. These mechanical properties are similar to tree roots highly adhered on the ground. The electrode working area was nanofunctionalized with polydopamine (PDA) that is used for anchoring redox mediators and improvement of wettability with unprecedent homogeneous spreading of liquids and development of self-collection liquid samples. This system is... (Complete abstract click electronic access below) / Mestre
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New electrochemical cells for energy conversion and storageNavarrete Algaba, Laura 03 March 2017 (has links)
In this thesis different materials have been developed to use them in electrochemical cells. The electrochemical cells studied can be divided into two material big groups: solids oxides and acid salts materials.
In the first group, materials to use them in electrodes for fuel cells an electrolyzer based on oxygen ion conductor electrolytes were optimized. Pertaining to this group, the influence of doping the Ba0.5Sr0.5Co0.8Fe0.2O3-d perovskite with 3% of Y, Zr and Sc in B position (ABO3-d) was checked. That optimization could reduce the polarization resistance of electrodes and improve the stability with time. Additionally, the limiting mechanisms in the oxygen reduction reaction were determined, and the influence of CO2 containing atmospheres was checked.
La2NiO4+d;, pertaining to the Ruddlesden-Popper serie, is a mixed conductor of electron and oxygen ions. This compound was doped in La position (with Nd and Pr) and in Ni position (with Co). The dopants introduced were able to produce structural change and improve the cell performance, reducing in more than one order of magnitude the La1.5Pr0.5Ni0.8Co0.2O4+d; polarization resistance respect to the reference material (La2NiO4+d).
In addition, the properties of an electrode based on the pure electronic conductor, La0.8Sr0.2MnO3-d; (LSM), were optimized. The triple phase boundary was enlarged by the addition of a second phase with ionic conductivity. That strategy made possible to reduce the electrode polarization resistance. In order to improve the oxygen reduction reaction, the addition of different catalysts by infiltration was studied. The different infiltrated oxides changed the electrochemistry properties, being the praseodymium oxide the catalyst which made possible a reduction in two orders of magnitude the electrode polarization resistance respects to the composite without infiltration. Furthermore, the efficiency of the cell working in fuel cell and electrolyzer mode was improved.
Concerning the materials selected to use as electrodes on proton conductor electrolytes, the efficiency of electrodes based on LSM was optimized by using a second phase with protonic conductivity (La5.5WO12-d) and varying the sintering temperature of the electrode. Finally, the catalytic activity of the cell was boosted by infiltrating samaria doped ceria nanoparticles, achieving higher power densities for the fuel cell.
The materials pertaining to the Ruddlesden-Popper series and studied for ionic conductor electrolytes were also used for cathodes in proton conductor fuel cells. After checking the compatibility with the electrolyte material, the influence of different electrode sintering temperatures and air containing atmospheres (dry, H2O y D2O) on the cathode performance was studied.
Finally, the electrochemical cells based on acid salts (CsH2PO4) were designed and optimized. In that way, different cell configurations were studied, enabling to obtain thin and dense electrolytes and active electrodes for the hydrogen reduction/oxidation reactions. The thickness of the electrolyte was reduced by using steel and nickel porous supports. Furthermore, an epoxy resin type was added to the electrolyte material to enhance the mechanical properties. The electrodes configuration was modified from pure electronic conductors to composite electrodes. Moreover, copper was selected as an alternative of the expensive platinum working at high operation pressures. The cells developed were able to work with high pressures and with high content of water steam in fuel cell and electrolyzer modes. / En la presente tesis doctoral se han desarrollado materiales para su uso en celdas electroquímicas. Las celdas electroquímicas estudiadas, se podrían separar en dos grandes grupos: materiales de óxido sólido y sales ácidas.
En el primer grupo, se optimizaron materiales para su uso como electrodos en pilas de combustible y electrolizadores, basados en electrolitos con conducción puramente iónica. Dentro de este grupo, se comprobó la influencia de dopar la perovskita Ba0.5Sr0.5Co0.8Fe0.2O3-d, con un 3% de Y, Zr y Sc en la posición B (ABO3-d). Esta optimización llevó a la reducción de la resistencia de polarización así como a una mejora de la estabilidad con el tiempo. Así mismo, se determinaron los mecanismos limitantes en la reacción de reducción de oxígeno, y se comprobó la influencia de la presencia de CO2 en condiciones de operación.
El La2NiO4+d perteneciente a la serie de Ruddlesden-Popper, es un conductor mixto de iones oxígeno y electrones. Éste, fue dopado tanto en la posición del La (con Nd y Pr) como en la posición del Ni (con Co). Los dopantes introducidos además de producir cambios estructurales, provocaron mejoras en el rendimiento de la celda, reduciendo para alguno de ellos, como el La1.5Pr0.5Ni0.8Co0.2O4+d, en casi un orden de magnitud la resistencia de polarización del electrodo de referencia (La2NiO4+d).
De la misma manera, se optimizaron las propiedades del electrodo basado en el conductor electrónico puro La0.8Sr0.2MnO3-d (LSM). La adición de una segunda fase, con conductividad iónica, permitió aumentar los puntos triples (TPB) en los que la reacción de reducción de oxígeno tiene lugar y reducir la resistencia de polarización. Con el fin de mejorar la reacción de reducción de oxígeno, se estudió la adición de nanocatalizadores mediante la técnica de infiltración. Los diferentes óxidos infiltrados produjeron el cambio de las propiedades electroquímicas del electrodo, siendo el óxido de praseodimio el catalizador que consiguió disminuir en dos órdenes de magnitud la resistencia de polarización del composite no infiltrado. De la misma manera, la mejora de la eficiencia del electrodo infiltrado con Pr, mejoró los resultados de la celda electroquímica trabajando como pila (mayores densidades de potencia) y como electrolizador (menores voltajes).
En lo que respecta a los materiales seleccionados para su uso como electrodos en electrolitos con conductividad protónica, se optimizó la eficiencia del cátodo basado en LSM, mediante el uso de una segunda fase conductora protónica (La5.5WO12-d) y variando la temperatura de sinterización del electrodo. Finalmente, se mejoró la actividad catalítica mediante la infiltración de nanopartículas de ceria dopada con samario, produciendo mayores densidades de corriente de la pila de combustible.
Los materiales pertenecientes a la serie de Ruddlesden-Popper y usados para cátodos en pilas iónicas, fueron empleados también para cátodos en pilas protónicas. Después de comprobar que el material electrolítico (LWO) era compatible con los compuestos de la serie de Ruddlesden-Popper, se estudió la influencia de la temperatura de sinterización de los electrodos en el rendimiento, así como de la composición de la atmosfera de aire (seca, H2O y D2O).
Finalmente, se diseñó y optimizó las celdas electroquímicas basadas en sales ácidas (CsH2PO4). En este sentido, se estudiaron diferentes configuraciones de celda, que permitieran obtener un electrolito denso con el menor espesor posible y unos electrodos activos a la reacción de reducción/oxidación de hidrógeno. Se consiguió reducir el espesor del electrolito soportando la celda en discos de acero y níquel porosos. Se añadió una resina tipo epoxi al material electrolítico para aumentar sus propiedades mecánicas. De la misma manera, se cambió la configuración de los electrodos pasando por conductores electrónicos puros a electrodos compuestos por conductores / En la present tesis doctoral es van desenvolupar materials per al seu ús en cel·les electroquímiques. Les cel·les electroquímiques estudiades poden ser dividides en dos grans grups: materials d'òxid sòlid i sals àcides.
En el primer grup, es van optimitzar materials per al seu ús com a elèctrodes en piles de combustible i electrolitzadors, basats en electròlits amb conducció purament iònica. Dins d'este grup, es va comprovar la influència de dopar la perovskita Ba0.5Sr0.5Co0.8Fe0.2O3-d amb un 3% de Y, Zr i Sc en la posició B (ABO3-d;). Esta optimització va portar a la reducció de la resistència de polarització així com a una millora de l'estabilitat amb el temps. Així mateix, es van determinar els mecanismes limitants en la reacció de reducció d'oxigen, i es va comprovar la influència de la presència de CO2 en condicions d'operació.
El La2NiO4+d pertanyent a la sèrie de Ruddlesden-Popper, és un conductor mixt d'ions oxigen i electrons. Este, va ser dopat tant en la posició del La (amb Nd i Pr) com en la posició del Ni (amb Co). Els dopants introduïts a més de produir canvis estructurals, van provocar millores en el rendiment de la cel·la, reduint per a algun d'ells, com el La1.5Pr0.5Ni0.8Co0.2O4+d, en quasi un ordre de magnitud la resistència de polarització de l'elèctrode de referència (La2NiO4+d).
De la mateixa manera, es van optimitzar les propietats de l'elèctrode basat en el conductor electrònic pur La0.8Sr0.2MnO3-d (LSM). L'addició d'una segona fase, amb conductivitat iònica, va permetre augmentar els punts triples (TPB), en els que la reacció de reducció d'oxigen té lloc, i reduir la resistència de polarització. A fi de millorar la reacció de reducció d'oxigen, es va estudiar l'adició de nanocatalitzadors per mitjà de la tècnica d'infiltració. Els diferents òxids infiltrats van produir el canvi de les propietats electroquímiques de l'elèctrode, sent l'òxid de praseodimi el catalitzador que va aconseguir disminuir en dos ordres de magnitud la resistència de polarització del composite no infiltrat. De la mateixa manera, la millora de l'eficiència de l'elèctrode infiltrat amb Pr, va millorar els resultats de la cel·la electroquímica treballant com a pila (majors densitats de potència) i com a electrolitzador (menors voltatges).
Pel que fa als materials seleccionats per al seu ús com a elèctrodes en electròlits amb conductivitat protònica, es va optimitzar l'eficiència del càtode basat en LSM, per mitjà de l'ús d'una segona fase conductora protònica (La5.5WO12-d;) i variant la temperatura de sinterització de l'elèctrode. Finalment, es va millorar l'activitat catalítica mitjançant la infiltració de nanopartícules de ceria dopada amb samari, produint majors densitats de corrent de la pila de combustible.
Els materials pertanyents a la sèrie de Ruddlesden-Popper i usats per a càtodes en piles iòniques, van ser empleats també per a càtodes en piles protòniques. Després de comprovar que el material electrolític (LWO) era compatible amb els compostos de la sèrie de Ruddlesden-Popper, es va estudiar la influència de la temperatura de sinterització dels elèctrodes en el rendiment, així com de la composició de l'atmosfera d'aire (seca, H2O i D2O).
Finalment, es van dissenyar i optimitzar les cel·les electroquímiques basades en sals àcides (CsH2PO4). En este sentit, es van estudiar diferents configuracions de cel·la, que permeteren obtindre un electròlit dens amb el menor espessor possible i uns elèctrodes actius a la reacció de reducció/oxidació d'hidrogen.
Es va aconseguir reduir l'espessor de l'electròlit suportant la cel·la en discos d'acer i níquel porosos. Es va afegir una resina tipus epoxi al material electrolític per a augmentar les seues propietats mecàniques. De la mateixa manera, es va canviar la configuració dels elèctrodes passant per conductors electrònics purs a elèctrodes compostos per conductors protònics / Navarrete Algaba, L. (2017). New electrochemical cells for energy conversion and storage [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/78458
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Monolithes à porosité multi-échelle comme supports pour la réduction enzymatique du CO2 en molécules d'intérêts / Hierarchical porous monoliths as supports for the enzymatic reduction of CO2Baccour, Mohamed 12 October 2018 (has links)
La conversion du dioxyde de carbone en molécules d'intérêts est un enjeu majeur de notre société moderne. Actuellement, ces réactions sont très coûteuses en énergie, impliquent de hautes pressions et températures et sont faiblement sélectives. Une alternative séduisante serait l’utilisation d’enzymes redox, i.e. des déshydrogénases, qui fonctionnent à pH neutre, température et pression ambiantes et sont très sélectives. Le frein à leur utilisation est leur stabilité et le fait qu’elles nécessitent la présence du cofacteur nicotinamide adénine dinucléotide (NAD+ / NADH), couteux et délicat à régénérer. L’immobilisation de déshydrogénases sur des supports poreux monolithiques est proposée dans ce travail de thèse dans l’objectif de développer des réacteurs en flux continu.Dans un premier temps, des monolithes siliciques à porosité hiérarchique macro- et mésoporeux ont été préparés. Des macropores plus larges allant jusqu’à 35-50 microns ont été obtenus. Dans un second temps, des synthèses de monolithes de carbone à porosité hiérarchique en une étape ou en plusieurs étapes par dépôt de carbone sur des monolithes siliciques (greffage de saccharose, suivi de polymérisation et carbonisation) ont été développées. Ce travail a permis un contrôle fin de la macro-, méso et microporosité. Des monolithes de carbone avec une surface spécifique supérieure à 1200 m2.g-1 ont notamment pu être obtenus. Ces matériaux présentent non seulement une macroporosité large (35-50 µm), mais également une mésoporosité bimodale. Au-delà d’une porosité multi-échelle, ces matériaux carbonés présentent l’avantage d’être conducteurs du courant électrique. Ils peuvent ainsi être utilisés comme support pour l’électrocatalyse enzymatique. Ces monolithes de carbones ont été utilisés pour l’immobilisation de formiates déshydrogénases connus pour pouvoir réduire le CO2 en présence du cofacteur NADH. La régénération du cofacteur est étudiée soit par voie électrochimique soit par voie biocatalytique à l'aide d'une deuxième enzyme la phosphite déshydrogénase. Des études de fonctionnalisation des monolithes carbonés pour la co-immobilisation des enzymes et du cofacteur ont également été initiées. / Carbon dioxide (CO2) is a greenhouse gas that results, in part, from human activities and causes global warming and climate change. According to the International Energy Agency, global CO2 emissions from fossil-fuel combustion reached a record high of 31.3 gigatonnes in 2011. The concept of the methanol economy, advocated by Nobel laureate Prof. George A. Olah back in the 1990s, hinges on the chemical recycling of CO2 to methanol and derived, suggesting methanol as a key substitute fuel and starting material for valuable chemicals. The recycling conversion of CO2 could be a rational way to develop an anthropogenic short-term carbon cycle. With this aim, The design of functional porous architectures depicting hierarchical and interconnected pore networks has emerged as a challenging field of research. Particularly, porous monoliths offer many advantages and can be employed as flow-through reactors for separation, catalysis and biocatalysis. This study focuses on the design of monoliths with hierarchical porosity and high surface area. Firstly, silica monoliths with both homogeneous macro- and mesopores were prepared using sol-gel chemistry and spinodal decomposition using PEO polymers. Macropore (up to 30 microns) and mesopore (up to 20 nm) diameters of the monoliths were controlled by modifying various experimental parameters (PEO molecular weight, addition of surfactants, different basic post-treatments, different temperatures, etc.). Secondly, carbonaceous replica have been prepared through hydrothermal carbonization of sucrose, subsequent pyrolysis and silica etching. These materials present large interconnected flow-trough macropores, a bimodal mesoporosity, a high surface area (up to 1400 m2 g-1) and high meso- and macropore volumes.Different enzymes were immobilized onto the monoliths amongst which formate dehydrogenases. Flow-through reactors were engineered and continuous flow biocatalysis was performed. In such systems, straightforward processes for the in situ regeneration of the enzyme cofactor, i.e. 1,4-NADH wrer developped. Flow-through reactors and their use for the enzymatic reduction of carbon dioxide into formate were designed.
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STUDY OF STRUCTURE-PROPERTY-PERFORMANCE OF THE POLYMER ELECTROLYTE MEMBRANE FUEL CELLS (PEMFCS)Chenzhao Li (14141316) 23 November 2022 (has links)
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<p>With the surge of interest in the electrification of transportation driven by global climate change, the need for powertrains using non-carbon energy sources has become more urgent than ever. The fuel cell electric vehicles (FCEVs) using polymer electrolyte membrane fuel cells (PEMFCs) have many advantages over the internal combustion engine (ICE) and other renewable energy vehicles such as high efficiency, zero-emission, fast fueling, unique power, and energy scalability (without heavy penalty from the increased mass). After three decades of intensive development, there are only several thousand FCEVs on the road, in contrast to the millions of battery electric vehicles (BEV) in use today. The biggest challenge of the widespread implantation of the PEMFCs is the cost, primarily due to the use of platinum catalysts. The high intrinsic catalyst activity exhibited using a rotating disc electrode (RDE) is rarely realized in the membrane electrode assembly (MEA), which is the core of PEMFC, due to the difference on the electrolyte(ionomer)/catalyst interfaces. Much of my Ph. D research effort is concentrated on how to reduce the Pt usage and improve the stability of catalyst to reduce the operation cost of fuel cells. Several approaches were practiced improving the performance of MEA in a fuel cell, such as optimizing the ink formulation and MEA fabrication method, enhancing proton conductivity of carbon support for catalysts, engineering the ionomer and catalyst interface via surface functionalization. Such studies unraveled the relationship between property, structure, and performance of MEA, and significantly improved the performance of MEA. Further, to reduce the cost of fuel cell operation, approaches that is to improve the stability of catalysts either in reducing Oswald ripening or limiting surface migration were practiced on developing novel catalysts. Such as doping anion into Pt and Ni alloy crystal structure, introducing PANI on catalyst surface. These approaches significantly improve the stability of catalyst and MEA. Finally, same as platinum group metal (PGM) catalysts, PGM-free catalysts as well as their MEAs were studied. A novel method of PGM-free MEA fabrication was developed which significantly reduced the thickness of catalyst layer, thus greatly reduced the mass transfer resistance. Also, a highly stable and active PGM-free catalyst was developed and can be considered as a strong competitor to replace the traditional PGM catalysts in MEA.</p>
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A Study of Interface Reaction of Li0.35La0.55TiO3-Li2CO3 and Its Effect on Potentiometric CO2 Gas SensorsYoon, Junro 20 December 2012 (has links)
No description available.
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A Few Case Studies of Polymer Conductors for Lithium-based BatteriesSen, Sudeshna January 2016 (has links) (PDF)
The present thesis demonstrates and discusses polymeric ion and mixed ion-electron conductors for rechargeable batteries based on lithium viz. lithium-ion and lithium-sulphur batteries. The proposed polymer ion conductors in the thesis are discussed primarily as potential alternatives to conventional liquid and solid-crystalline electrolytes in lithium-ion batteries. These discussions are part of Chapters 2-4. On the other hand, the polymer based mixed ion-electron conductor is demonstrated as a novel electrode for lithium-Sulphur battery in Chapter 5. Possibility of application of polymer ion conductors is discussed in the context of Li-S battery in Chapter 6. A distinct correlation between the physical properties and electrochemical performance of the proposed conductors is highlighted in detail in this thesis. Systematic investigation of the ion transport mechanism in the polymeric ion conductors has been carried out using various spectroscopic techniques at different time and length scales. Such detailed investigations demonstrate the key structural and physical parameters for design of alternative polymer conductors for rechargeable batteries. Though the thesis discusses the various polymeric conductors in the context of lithium-based batteries, it is strongly felt that the design strategies are equally likely to be beneficial for different battery chemistries as well as for other electrochemical generation and storage devices. A brief discussion of the contents and highlights of the individual chapters are described below:
The thesis comprises of six Chapters.
Chapter 1 briefly reviews the important developments and materials of lithium-based batteries, with specific focus on Li-ion and Li-S batteries. It starts with discussions on different types of liquid, solid crystalline and solid-like electrolytes. Their materials characteristics, advantages and disadvantages are discussed in the context of secondary batteries such as lithium-ion and lithium-sulphur batteries. As prospective alternative electrolytes polymer based soft matter electrolytes are discussed in detail. Special emphasis is given to the recent developments in polymer electrolytes and their ion conduction mechanism, which are central themes to this thesis. The importance of investigation of charge transport, typically ion, on electrochemical processes is also briefly discussed in Chapter 1. A brief discussion about the characteristics, materials and non-trivialities of the electrochemical storage process in Li-S battery is also reviewed.
Chapter 2A demonstrates a binary polymer physical network based gel (PN-x) electrolyte, comprising of an ionic liquid confined inside a binary polymer system for electrochemical devices such as secondary batteries. The synthesis, physical property and electrochemical performances are studied as a function of content of one of the polymers in this Chapter. A physical network of two polymers with different functional groups leads to multiple interesting consequences. The polymer physical network characteristics determine all physical properties including electrochemical property of the ionic liquid integrated PN based GPE. The conductivities of the proposed gel are nearly an order in magnitude higher than the unconfined ionic liquid electrolyte and displays good dimensional stability and electrochemical performance in a separator-free battery configuration. The ac-impedance spectroscopy, steady shear viscosity measurement, dynamic rheology are employed to study physical properties of the proposed gel polymer electrolyte.
Chapter 2B discusses the detailed investigations of the ion transport mechanism of the gel polymer electrolyte, as discussed in Chapter 2A. Ion conduction mechanism is investigated in the light of ion diffusion and solvent dynamics of the entrapped ionic liquid inside the polymer. The studies reveal a heavy influence of network characteristics on the ion conduction mechanism. The influence of solvent dynamics on the ion transport is drastically altered by polymer physical network. Consequently, a drastic change in the ion mobility and nature of predominant charge carrier is observed in the polymer physical network based gel electrolyte. A clear transformation from dual ion conductivity to a predominantly anion conductivity is observed on going from single polymer to a dual polymer network. The spectroscopic tools such as pulsed field gradient nuclear magnetic resonance (PFG–NMR), Brillouin light scattering spectroscopy, ac-impedance spectroscopy, FT-Raman and FTIR spectroscopy were used to elucidate the ion transport mechanism in the Chapter.
Chapter 3 demonstrates a simple design strategy of gel polymer electrolyte comprising of a lithium salt (lithium bis(trifluoromethanesulfonyl) imide, LiTFSI) solvated by two plastic crystalline solvents, one a solid (succinonitrile, abbreviated as SN) and another a (room temperature) ionic liquid (1-butyl-1-methyl-pyrrolidinium bis(trifluoromethane sulfonyl) imide, (abbreviated as IL) confined inside a linear network of poly(methyl methacrylate) (PMMA). The concentration of the IL component determines the physical properties of the unconfined electrolyte and when confined inside the polymer network in gel polymer electrolyte. Intrinsic dynamics of one plastic crystal influences the conduction mechanism of gel polymer electrolytes. The enhanced disordering in the plastic phase of succinonitrile by IL doping alters both the local ion environment and viscosity. The proposed plastic crystal electrolytes show predominantly anion conduction (tTFSI ≈ 0.5) however, lithium transference number (tLi ≈ 0.2) is nearly an order higher than the ionic liquid electrolyte (IL-LiTFSI) (tLi ≈ 0.02-0.06), discussed in Chapter 2. The gel polymer electrolyte displayed high mechanical compliability, stable Li-electrode | electrolyte interface, low rate of Al corrosion and stable cyclability. The promising electrochemical performance further justifies simple strategy of employing mixed physical state plasticizers to tune the physical properties of polymer electrolytes requisite for application in rechargeable batteries.
Chapter 4A proposes a novel liquid dendrimer–based single ion conducting liquid electrolyte as potential alternative to conventional molecular liquid solvent–salt solutions and conventional solid polymer electrolytes for rechargeable batteries, sensors and actuators. The physical properties are investigated as a function of peripheral functionalities in the first generation poly(propyl ether imine) (G1-PETIM)–lithium salt complexes. The change in peripheral group simultaneously affects the effective physical properties viz. viscosity, ionic conductivity, ion diffusion coefficients, transference numbers and also the electrochemical response. The specific change from ester (–COOR) to cyano (–CN) terminated peripheral group resulted in a remarkable switch over from a high cation (tLi+ = 0.9 for –COOR) to a high anion (tPF6- = 0.8 for –CN) transference number.
Chapter 4B presents an analysis of the frequency dependent ionic conductivity of single ion dendrimer conductors by using time temperature scaling principles (TTSPs) and dielectric modeling of the electrode polarization. The TTSP provides information on the salt dissociation and number density of mobile charges and hence provides direct insights into the ion conduction mechanism. Summerfield and Baranovskii–Cordes scaling laws, which are well known TTSPs, have been applied to analyze the ion conductivity. The electrode polarization, which quantifies the number density of mobile charges and ionic mobility, is studied using Macdonald-Coelho model of electrode polarization. The combination of these two theoretical investigations of the experimental data emanating from one technique i.e. ac– impedance spectroscopy, predicts independently the contributions of the effect of mobile ion charges and ionic mobility to ion conduction mechanism.
In Chapter 5 focus shifts from polymer ion conductors to polymer mixed ion-electron conductor. The polymer mixed ion-electron conductor is demonstrated as a novel electrode material for Li-S battery. A simple strategy to overcome the challenges towards practical realization of a stable high performance Li–S battery is discussed. A soft mixed conducting polymeric network is utilized to configure sulphur nanoparticle. The soft matter network provides efficient and distinct pathways for lithium and electron conduction simultaneously. A lithiated polyethylene glycol (PEG) based surfactant tethered on ultra-small sulphur nanoparticles and wrapped up with polyaniline (PAni) (abbreviated as S-MIEC) is demonstrated here as an exceptional cathode for Li–S batteries. The S-MIEC is characterized by several methods: powder-X-ray diffraction (PXRD), thermo gravimetric analysis (TGA), fourier transform infrared (FTIR) spectroscopy, X-ray photoelectron spectroscopy (XPS), scanning electron microscopy (SEM), high resolution transmission electron microscopy (HRTEM), ac-impedance spectroscopy and dc current-voltage measurements are performed to evaluate conductivity of S-MIEC cathode. Electrochemical studies such as cyclic voltammetry, galvanostatic charge-discharge cycling, galvanostatic intermittent titration (GITT) are performed to demonstrate feasibility of S-MIEC in the Li–S battery performance.
Chapter 6 provides a brief summary of the work carried out as part of this thesis and also demonstrates the future perspective of the present work. Potential of the polymer physical network based gel polymer electrolytes, which are discussed in Chapter 2A-B for lithium-ion batteries, are demonstrated in Li-S battery. The proposed polymer physical network confines higher order lithium polysulfides (typically Li2S8) dissolved in tetraethylene glycol dimethyl ether (TEGDME) based electrolyte (TEGDME-1M LiTFSI). The three dimensional polymer network is proposed to be formed by physical blending of the poly(acrylonitrile) (PAN) with the copolymer of AN and poly(ethylene glycol) methyl ether methacrylate (PEGMA), [ P(AN–co–PEGMA)]. We extend here the similar synthetic approaches as described in Chapter 2A. The approach proposed and demonstrated in this concluding Chapter is expected to mitigate some of the major issues of Li-S chemistry. The proposed Li2S8 confined gel electrolyte exhibits moderately high values of ionic conductivity, 2 × 10-3 Ω-1cm-1 and shows a stable capacity of 350 mAhg-1 over 30 days in a separator free Li-S battery.
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Development of electrode architectures for miniaturized biofuel cells / Développement d'architectures d'électrodes pour des biopiles miniaturiséesKarajić, Aleksandar 15 December 2015 (has links)
La demande croissante de systèmes électrochimiques miniaturisés et potentiellement implantables tels que les biocapteurs, les biopiles à combustible et les batteries a conduit à l’émergence de nouvelles technologies pour surmonter les problèmes expérimentaux liés aux grandes dimensions, aux faibles densités de courant, et à la puissance de sortie insuffisante de ces dispositifs. Dans ce travail de thèse, nous présentons de nouvelles approches pour la fabrication d’électrodes miniaturisées avec des architectures macroporeuses et coaxiales dont les applications pourraient être dans les domaines cités plus haut. De plus, nous avons démontré l’utilisation de telles électrodes macroporeuses pour la conception de biopiles fonctionnant à base de glucose et d’oxygène. Les résultats préliminaires concernant la conception d'un nouveau type de biocapteurs de glucose à base de cellules vivantes sont également présentés. La première partie de ce travail se concentre sur différentes stratégies pour la fabrication de cristaux colloïdaux (chapitre 1) qui peuvent être utilisés pour la préparation d'électrodes macroporeuses (chapitre 2) en suivant l'approche dite de matrice sacrificielle dure. La synthèse d'électrodes macroporeuses est basée sur l’électrodéposition potentio statique de matériaux conducteurs (tels que les métaux dans le contexte de ce travail) dans une matrice colloïdale à base de silice qui a été synthétisée par le procédé de Langmuir-Blodgett. Cette méthode a été utilisée pour la conception et la fabrication de cellules électrochimiques à deux électrodes macroporeuses coaxiales et miniaturisées en suivant deux procédures différentes et complémentaires: 1. La première procédure de fabrication est basée sur l'électrodéposition de couches de métaux alternées or-nickel-or, avant la dissolution de la couche de nickel intermédiaire puis une stabilisation mécanique de la structure; 2. La seconde stratégie alternative et complémentaire pour la fabrication de cellules électrochimiques coaxiales et macroporeuses repose sur l'assemblage de l'architecture finale à partir de deux électrodes cylindriques macroporeuses préparées indépendamment et adressables par voie électrochimique. La principale différence entre ces deux approches est la gamme de l’espacement inter-électrode (de quelques dizaines de micromètres (première approche) à des centaines de micromètres qui peut être obtenu par le second procédé de fabrication). En outre,nous avons démontré le fonctionnement électrochimique des deux architectures d'électrodes par l'évaluation en voltampérométrie cyclique à balayage de la réaction de réduction de l'oxygène qui a lieu à la surface des deux électrodes.Le plus grand avantage des stratégies présentées est la possibilité de contrôler finement l'épaisseur de l'électrode (et donc des surfaces actives), la séparation spatiale entre l'électrode interne et externe (c’est-à-dire le volume d'électrolyte qui peut être stocké dans l’interstice) et la taille des pores (en changeant le diamètre des particules colloïdales de silice). Dans la partie suivante (chapitre 3), nous démontrons la possibilité d'utiliser des électrodes macroporeuses pour la fabrication d'une biocathode enzymatique. Les substrats d'or macroporeux ont été choisis comme candidats prometteurs pour améliorer les performances électrochimiques (courant et puissance de sortie) d'une biopile enzymatique à glucose/oxygène en raison de leur surface active élevée. [...] Enfin, notre contribution au développement d'un nouveau type de biocapteur à base de cellulesentières est décrite dans le chapitre 4. [...] / The increasing demand for miniaturized and eventually implantable electrochemicaltools such as biosensors, biofuel cells and batteries has led to the development of newtechnologies to overcome existing problems related to large dimensions, low current densities,and insufficient power output of such devices. In the present work we describe new approachesfor the fabrication of miniaturized, macroporous and coaxial electrode architectures that couldfind their practical application for the fabrication of the systems mentioned above.Furthermore, we have demonstrated the functionality of macroporous electrodes with respectto the design of miniaturized glucose/oxygen biofuel cells. Preliminary results regarding thedesign of a new type of whole-cell based glucose biosensors are also presented.The first part of this work is focusing on different strategies for the fabrication of colloidalcrystals (Chapter 1) that can be used for the synthesis of macroporous electrodes (Chapter2) byfollowing the so-called hard template approach. The synthesis of macroporous electrodes isbased on the potentiostatic electrodeposition of conductive materials (such as metals in thepresent work) into a silica based colloidal template that has been synthesized by the Langmuir-Blodgett procedure. This method has been used for the design and fabrication of miniaturizedcoaxial and macroporous two electrode-electrochemical cells by following two different andcomplementary procedures: 1. The first fabrication procedure is based on the electrodepositionof alternating gold-nickel-gold metal layers, subsequent etching of the intermediate nickel layerand a structural stabilization; 2. The second alternative and complementary strategy for thefabrication of coaxial and macroporous double electrochemical cells relies on assembling thefinal architecture from two independently prepared and electrochemically addressablecylindrical macroporous electrodes. The main difference between these two approaches is therange of inter-electrode distances (from tens of micrometers (first approach) to hundreds ofmicrometers that can be achieved by second fabrication procedure). Also, we demonstrate theelectrochemical functionality of both electrode architectures by cyclo-voltammetricinvestigation of the oxygen reduction reaction that takes place at the surface of bothelectrodes.The biggest advantage of the presented strategies is the possibility to fine tune the electrodethickness (and therefore active surface areas), the spatial separation between inner and outerelectrode (the volume of electrolyte that can be stored between them) and the pore size (bychanging the diameter of silica colloidal particles).In the following segment (Chapter 3), we demonstrate the possibility to use macroporouselectrodes for the fabrication of an enzymatic biocathode. The macroporous gold substrateswere chosen as promising candidates to improve the electrochemical performances (currentand power output) of an enzymatic glucose/oxygen biofuel cells due to their high active surface area. [...] Finally, our contribution to the development of a new type of whole cell based biosensor isdescribed in Chapter 4. [...]
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