Estudo e desenvolvimento de catalisadores para células a combustível visando o aumento de escala e avaliação da distribuição de corrente / Study and development of catalysts for fuel cells in order to increase scale and evaluation of current distribution

Pires, Felipe Ibanhi

03 February 2016

O trabalho visa o desenvolvimento do sistema para medidas de distribuição de corrente e ampliação de escala (50 cm²) buscando aperfeiçoar as condições de preparação do conjunto eletrodo membrana (MEA) quanto às condições de operação da célula e avaliar a melhor geometria. Foram realizados estudos de síntese de catalisadores de Pt-M e avaliação do desempenho desses materias e das rotas de síntese utilizadas com objetivo de aplicar estes materias em sistemas de maior escala. A insuficiência do desempenho e estabilidade dos catalisadores são fatores que ainda inviabilizam o uso em larga escala das células a combustível de eletrólito polimérico sólido, destacando-se as perdas associadas ao desempenho do cátodo. Os catalisadores preparados foram nanopartículas bimetálicas PtM/C (M = Fe, Co e Ni) suportadas em carbono de elevada área superficial, por duas rotas sintéticas. Foram utilizadas as rotas: ácido fórmico e etilenoglicol modificado (EG). Em ambas as rotas se buscou catalisadores com alto grau de incorporação do segundo metal, tamanho de partícula pequeno e bom desempenho catalítico do cátodo. Observou-se que pela rota do ácido fórmico com modificações no processo de síntese é possível obter a incorporação nominal do segundo metal no catalisador, porém há desvantagem de o tamanho de partícula ser elevado. Pela rota do EG obteve-se catalisadores com pequeno tamanho de partícula, porém a incorporação do segundo metal mostrou-se ineficiente. Os estudos de ampliação de escala foram realizados em células de 50 cm2 variando-se as condições de operação; i) diferentes placas de distribuição de gás, e ii) diferentes valores de fluxo dos gases reagentes. Foi observado que a baixos fluxos de gases a quantidade de reagente é insuficiente para ser difundida por todo eletrodo, o que ocasiona reação apenas na região de entrada de gases no sistema, ocasionando uma rápida limitação em obter-se densidades de corrente alta. Pode-se observar que a diferença de desempenho entre as placas é pequena, porém a placa serpentina 6 apresentou melhor desempenho. O desempenho dos cátodos preparados com catalisadores comerciais e os sintetizados no laboratório nas células de 50 cm² mostrou sofrer bastante influência das condições de operação comparada com as células de 4,6 cm². / The work aims at the development of the system for current distribution measurements and scale (50 cm²) seeking to improve the conditions of preparation of the membrane electrode assembly (MEA) as the cell operating conditions and evaluate the best geometry. We were performed catalyst synthesis studies of Pt-M and performance evaluation of these materials and the synthetic routes used in order to apply these materials in larger-scale systems. The failure of the performance and stability of the catalysts are factors that make yet infeasible the scale up use for solid polymer electrolyte fuel cells, highlighting the losses associated with the performance of the cathode. The nanoparticles of bimetallic catalysts Pt-M/C (M = Fe, Co and Ni) supported on high surface area carbon were prepared by two different synthetic routes. The synthesis route utilized were formic acid and modified ethylene glycol (EG). In both route search catalysts with a high degree of incorporation of the second metal, small particle size and good catalytic performance. It was observed that the route of formic acid with modifications in the synthesis process it is possible to obtain the average incorporation of the second metal in the catalyst, but there is a disadvantage of the particle size is high. The route of EG modified was obtained catalysts with small particle size, but incorporation of the second metal was inefficient. The scale-up studies were performed in 50 cm2 cell varying operating conditions: i) different gas distribution plates and ii) different values of flow of reactant gases. It was observed that at low gas flows the amount of reagent is insufficient to be spread throughout the electrode, causing reaction only in the region of entry of gases in the system, causing a fast limitation in obtain high current densities. It can be observed that the performance difference between the plates is small, but the plate serpentine 6 showed the best performance. The performance of the cathodes prepared with commercial catalysts and synthesized in the laboratory in 50 cm² cells showed considerable influence the operating conditions compared to cells 4,6 cm².

ampliação de escala

célula a combustível

current distribution

distribuição de corrente

eletrocatalisadores a base de Pt

fuel cell

oxygen reduction reaction

Pt-based electrocatalysts

Reação de redução de oxigênio

scale up

Síntese e Investigação da Atividade de Eletrocatalisadores Formados por Elementos Abundantes do Tipo M-N-C para a Reação Redução de Oxigênio / Synthesis and Investigation of the electrocatalytic Activity of materials based by Abundant Elements of Type M-N-C for the oxygen reduction reaction

Francisca Elenice Rodrigues de Oliveira

10 April 2018

O desenvolvimento de células de combustível de formato direto encontra obstáculos importantes relacionados com a lenta cinética da reação de redução de oxigênio e baixa tolerância ao formato em cátodos baseados em Pt. Neste estudo, foram sintetizados eletrocatalisadores com diferentes estruturas, formados por elementos abundantes, e suas atividades e seletividades para a RRO foram testadas em meiacélulas e em células unitárias de formato / ar, em eletrólito alcalino. Os resultados mostraram que nanopartículas de liga de ferro-cobalto, encapsuladas por carbono grafítico, e nitretos metálicos nanoestruturados, suportados em carbono, (caracterizados por TEM e XRD) não apresentam atividades eletrocatalíticas superiores ao carbono puro (Vulcan amorfo ou grafitizado). Carbono dopado com nitrogênio (N-C) mostrou um aumento no potencial de meia-onda, evidenciando um influente papel do nitrogênio na eletrocatálise da RRO, mas com alto sobrepotencial. A inserção de oxigênio via tratamento térmico em ar, formando óxidos de FeCo nanoestruturados, suportados por carbono, produziu, como esperado, um aumento considerável na atividade, mostrando que a ligação do ferro ou cobalto com o oxigênio tem papel importante, provavelmente, na alta reatividade redox para a transferência de elétrons para o RRO. A adição de um precursor de nitrogênio durante a síntese (imidazol) resultou na formação de estruturas formadas por átomos de ferro e cobalto, coordenados por nitrogênio, inseridos em uma matriz de carbono, como revelado por EXAFS, mostrou que as estruturas M-N-C têm papel decisivo na atividade eletrocatalítica para a RRO (aproximando-se da Pt/C) e, também, mostrou alta tolerância à presença de íons formato. Experimentos em células a combustível unitárias, com difusão natural de formato e com cátodo aberto ao ar, com elétrodo de difusão de gás, mostraram densidades de potência de 15,5 e 10,5 mW cm-2 com eletrólitos à base de hidróxido e carbonato de potássio, respectivamente, e com estabilidade de operação maior que 120 h a 0,3 mA cm-2. Portanto, os resultados deste trabalho mostram o papel decisivo de estruturas M-NC (coordenadas) na alta atividade para a ORR, em altos potenciais, excluindo-se atividades atribuídas a nanoestruturas de nitretos metálicos e nanopartículas metálicas encapsuladas, incluindo as dopadas por nitrogênio na superfície. / The development of direct formate fuel cells encounters significant obstacles related to the slow kinetics of the oxygen reduction reaction (ORR) and low formate tolerance in Pt-based cathodes. In this study, electrocatalysts with different structures, composed of abundant elements, were synthesized, and their activities and selectivities for the ORR were tested in half-cells and in single cells in alkaline electrolyte. The results showed that carbon-encapsulated nanoparticles of iron-cobalt alloy and carbon-supported nanostructured metal nitrides (characterized by TEM and XRD) do not present electrocatalytic activities superior to pure carbon (amorphous or graphitized Vulcan). Nitrogen-doped carbon (N-C) showed an increase in the halfwave potential, evidencing an influential role of nitrogen in the electrocatalysis of the ORR, but with a high overpotential. The insertion of oxygen through heat treatment in air, forming carbon-supported nanostructured FeCo oxides, produced, as expected, an increase in activity, probably due to the high oxide reactivity for the electronic mediation processes for the ORR. The addition of a nitrogen precursor during the synthesis (imidazole) resulted in the formation of structures formed by iron and cobalt atoms, coordinated by nitrogen, inserted in a carbon matrix, as revealed by EXAFS, and showed that M-N-C structures play a decisive role in the electrocatalytic activity for the ORR (approaching Pt/C) and, also, showed high tolerance to the presence of ions format. Experiments in single cells with air-breathing cathode and with natural diffusion of formate, showed power densities of 15.5 and 10.5 mW cm-2 with hydroxide and carbonate-based electrolytes, respectively, and with operating stability higher than 120 h at 0.3 mA cm-2. Therefore, the results of this work show the decisive role of M-N-C structures (coordination) in the high activity for the ORR, in high potentials, excluding activities attributed to nanostructures of metallic nitrides and encapsulated metallic nanoparticles, including those doped by surface nitrogen.

célula a combustível de íons formato

M-N-C

reação de redução de oxigênio

direct formate fuel cells

earth-abundant electrocatalysts

M-N-C

oxygen reduction reaction

Estudo da atividade eletrocatalítica de óxidos nanoestruturados de Ru, Ir, Hf e La visando o estudo da reação de redução de oxigênio (RRO) / Study of electrocatalytic activity of nanostructured oxides of Ru, Ir, Hf and La for the study of the oxygen reduction reaction (ORR)

Jonas Batista Reis

04 September 2015

Neste trabalho foi estudada a atividade eletrocatalítica dos eletrocatalisadores nanoestruturados de Ru, Ir, Hf ou La suportados em carbono Printex 6L frente à Reação de Redução de Oxigênio (RRO) em meio ácido. Inicialmente analisou-se a influência do Método de Impregnação e dos Precursores Poliméricos (MPP), também conhecido como Pechini para os eletrocatalisadores RuO2/C e IrO2/C. Ficou evidente neste estudo, que os materiais obtidos pelo MPP apresentaram uma maior eficiência de corrente para a eletrogeração de H2O2 quando comparado ao método da Impregnação. Na etapa seguinte, os eletrocatalisadores HfO2/C e LaONO3/C foram preparados apenas pelo MPP. As propriedades estruturais, morfológicas e de superfície foram investigadas por meio das técnicas de caracterização DRX, FRX, MET, XPS e TG. De acordo com os dados de DRX e MET, verificou-se que o método de incorporação do metal no carbono Printex 6L favoreceu a formação dos óxidos nanoestruturados. Ademais, foi verificado que os eletrocatalisadores obtidos pelo método de Pechini apresentam menores tamanho de cristalitos (1 a 5 nm), melhor distribuição dos óxidos sobre a matriz de carbono (menos aglomerados) e menores tamanhos de partículas. O comportamento eletroquímico dos eletrocatalisadores foi avaliado através das voltametrias lineares (curvas de polarização) obtidas pelo eletrodo de disco anel rotatório (RRDE). Os resultados obtidos pelas voltametrias lineares, cálculos de eficiência de corrente de H2O2 (H2O2 %), número total de elétrons trocados (nt) e de Koutecký-Levich mostraram que a incorporação dos eletrocatalisadores (Ru e Ir) no carbono Printex 6L obtidos por ambos os métodos de síntese influenciaram negativamente na eletrogeração de H2O2. Neste caso, os eletrocatalisadores de Ru e Ir apresentaram uma tendência ao mecanismo via 4 elétrons, ou seja, geração de H2O como produto final da RRO. Os resultados mostraram ainda que os eletrocatalisadores contendo maiores teores de Hf, apresentaram maiores eficiência de corrente para H2O2 quando comparado ao carbono Printex 6L, uma vez que o catalisador contendo 15 % de Hf apresentou valores de eficiência de corrente de H2O2 próximos a 80 % e número de elétrons de 2,4. Além disso, foi observado também um deslocamento no potencial de aproximadamente 200 mV para valores mais positivos, o que significa um menor consumo energético em termos de eletrogeração de H2O2. Para os eletrocatalisadores à base de La, a amostra contendo 7% apresentou uma melhor eficiência de corrente de H2O2, com valores próximos a 87% e número de elétrons de 2,3, além de um deslocamento do potencial de aproximadamente 250 mV para valores mais positivos. Pode-se inferir então, que os eletrocatalisadores de Hf e La obtidos pelo método de Pechini são promissores para utilização em Eletrodos de Difusão Gasosa (EDG) visando a eletrogeração in situ de H2O2, visto que apresentam uma tendência a mecanismo via 2 elétrons. / In the present work, the electrocatalytic activity of nanostructured electrocatalysts based on Ru, Ir, Hf or La supported in Printex L6 front of Oxygen Reduction Reaction (ORR) in an acid medium were studied. Initially, the influence of impregnation methods and polymeric precursors (MPP), also known as Pechini for the electrocatalysts RuO2/C and IrO2/C, was analyzed. It was evidenced in this study, that the materials obtained by MPP presented bigger efficiency for H2O2 electrogeneration when compared to the impregnation method. In the following stage, the electrocatalysts HfO2/C and LaONO3/C were prepared only by MPP. The structural properties and surface morphology were investigated by means of the characterization techniques DRX, FRX, TEM, XPS and TG. According to the XRD and TEM data, it was found that the method of metal incorporation in Printex 6L carbon promoted the formation of nanostructured oxides. Moreover, it was verified that the electrocatalysts obtained by Pechini\'s method presented smaller crystallite size (1 to 5 nm), better distribution of the oxides on the carbon matrix (fewer clusters) and smaller particle sizes. The electrochemical behavior of the electrocatalysts were evaluated by linear voltammetry (polarization curves) obtained by rotating ring-disk electrode (RRDE). The results obtained by linear voltammetry, calculations of current efficiency of H2O2 (H2O2 %), total number of exchanged electrons (nt) and of Koutecký-Levich showed that the incorporation of the electrocatalysts (Ru and Ir) in Printex 6L carbon obtained by both methods of synthesis influenced negatively on the electrogeneration of H2O2. In that case, the Ru and Ir electrocatalysts showed a tendency to a 4 electrons mechanism, that is, generation of H2O as final product of the ORR. The results also showed that the electrocatalysts containing higher Hf content, presented higher current efficiency for H2O2 when compared to carbon Printex L6, since that the catalyst containing 15% of Hf presented values of current efficiency for H2O2 around 80% and number of electrons of 2.4. Furthermore, a potential displacement for positive values of approximately 200 mV was also observed which means lower energy consumption in terms of H2O2 electrogeneration. For the La based electrocatalysts, the sample containing 7% showed better current efficiency for H2O2, with values near 87% and number of electrons of 2.3, besides a potential displacement of approximately 250 mV for more values positive. It can be inferred that the Hf and La electrocatalysts obtained by Pechini\'s method are promising for use in Gas Diffusion Electrodes (GDE) aiming in situ electrogeneration of H2O2, since they exhibit a tendency to a mechanism via 2 electrons.

eletrocatalisadores

háfnio e lantânio

irídio

óxidos de rutênio

Reação de redução de oxigênio (RRO)

electrocatalysts

Iridium

lanthanum and hafnium

Oxygen Reduction Reaction (ORR)

ruthenium oxides

Síntese e caracterização de óxidos de manganês puros e dopados com cátions metálicos utilizados como materiais aplicados em dispositivos eletroquímicos de conversão de energia / Synthesis and characterization of pure and cations doped manganese oxides used as materials in electrochemical energy conversion devices

Naiza Vilas Bôas

10 November 2017

O dióxido de manganês (MnO2) é um catalisador eficiente de baixo custo utilizado no cátodo de baterias do tipo metal-ar e células a combustível alcalinas, sendo capaz de promover a redução completa de oxigênio pela rota 4e-. No entanto, o dióxido de manganês é um semicondutor e só pode ser utilizado como material eletródico nos dispositivos mencionados se combinado com algum suporte condutor. O suporte condutor mais utilizado para este fim é o carbono em pó. Entretanto, este material não possui estabilidade suficiente nas condições operacionais das células alcalinas, sendo convertido gradativamente em CO2. Uma das possíveis estratégias para tentar minimizar esta deficiência é incrementar a condutividade eletrônica do óxido puro pela dopagem com alguns cátions metálicos. Sendo assim, este trabalho tem como objetivo geral pesquisar de maneira sistemática o efeito da dopagem de dióxido de manganês com alguns cátions metálicos, como o Bi3+e Ce4+ nas propriedades físico-químicas e eletrocatalíticas deste óxido, visando o uso dos mesmos como em cátodos de baterias recarregáveis do tipo Zn-ar. As análises das características morfológicas dos catalisadores por meio de MEV e TEM mostram que os óxidos de manganês são gerados na forma de nano-bastões de 50 a 100 nm de comprimento. Os óxidos puros e dopados com bismuto e cério apresentam estruturas tetragonais típicas, ocorrendo expansão da célula unitária dos óxidos dopados pela troca de íons manganês pelos correspondentes dopantes na rede cristalina de MnO2. Os resultados eletroquímicos sugerem um aumento de condutividade do óxido dopado que possibilita seu uso sem mistura com carbono. Além disso, observa-se que a RRO é catalisada por um mecanismo que envolve a transferência de 4e- nestes materiais com participação de peróxido como intermediário. O óxido de manganês dopado com Bi apresentou promissor desempenho catalítico para a RDO, o que junto com os demais resultados apresentados para a RRO o qualificou a funcionar como o catalisador bifuncional mais promissor de todos os estudados em baterias do tipo metal-ar. Experimentos realizados em mini baterias do tipo Zn-ar demonstraram a total capacidade do catalisador dopado com bismuto operar como catalisador do eletrodo de ar, resultando num desempenho superior ao de um catalisador convencional de MnO2/C. / Manganese dioxide is at the same time an efficient and low-cost material used as cathode catalyst in the air electrode of metal-air and alkaline fuel cells, capable to promote the complete reduction of oxygen thru the 4e- mechanism. However, manganese dioxide is a semiconductor and can be used as electrodic material in the mentioned devices only combined with a conductor support. High surface area carbon powder is the most commonly used material for such purpose. The problem is that carbon suffers from severe instabilities in the experimental conditions that fuel cells and metal-air batteries operates, being gradually converted into CO2. A possible strategy to overcome or at least minimize the low oxide conductivity is by doping this material with some metallic cations. In this sense, the main purpose of this work was the systematic investigation of the physicochemical and electrocatalytic properties of Bi3+ and Ce4+ doped manganese dioxide materials used as cathode catalysts in the air electrode of alkaline type Zn-air batteries. The morphologic characterization performed SEM and TEM revealed that pure as well cation doped MnO2 are formed as poly dispersed nanorods with 50-100 nm length. Both pure and doped materials presented typical tetragonal structures, although a cell expansion was observed in the doped oxides caused by the exchange of some manganese cations by the doping counter parts. Electrochemical results suggest that a material with increased conductivity results from the doping process, allowing it to operate as air catalyst without the use of a carbon support. Besides, it is observed that the oxygen reduction reaction proceeds thru the 4e- mechanism on the doped oxides involving hydrogen peroxide as intermediate. The Bi doped oxide presented the best performance for the oxygen evolution reaction among all catalysts investigated. This result together with the superior performance for the oxygen reduction reaction presented by this material suggest that Bi doped MnO2 is a potential candidate to operate as an air catalyst of rechargeable alkaline metal-air batteries. Experiments conducted in a mini Zn-air battery using Bi doped MnO2 as air catalyst corroborated this observation.

bateria Zn-ar

dopagem

eletrocatálise

óxido de manganês

reação de desprendimento de oxigênio

reação de redução de oxigênio

doping

electrocatalysis

manganese dioxide

oxygen evolution reaction

oxygen reduction reaction

Zn-ar battery

New cofacial binuclear complexes for the oxygen reduction reaction and selective anion binding

Devoille, Aline M. J.

January 2011

This thesis describes the design, synthesis and reactivity of bimetallic complexes of doubly-pillared Schiff-base calixpyrrole ligands. Chapter One introduces the oxygen reduction reaction in light of the global energy scenario at present and in the future. Compounds and materials known to catalyse this reaction are discussed, with particular focus on transition metal complexes of pyrrole-containing macrocycles and the ability of these compounds to act as catalysts in redox reactions. Chapter Two describes the design and synthesis of several of the macrocyclic ligands developed during this project. The wide range of metals and geometries supported by one of the ligands, H4L, are outlined and include complexes of alkali-metals (Li, K), a rare earth metal (Mg), transition metals (Pd, Fe) and an actinide (UO2 2+). Chapter Three presents the use of [Co2(L)] for the reduction of dioxygen to water. The redox behaviour of the complex and its ability to reversibly bind oxygen were evaluated. The catalytic activity of [Co2(L)] was investigated in solution by UV-Vis spectrophotometry and electrochemically by rotating ring-disk electrochemistry. In Chapter Four, the ability of [Zn2(L)] to bind anions is described. Isothermal microcalorimetry, NMR, UV-Visible spectrophotometry, and fluorophotometry were used to study the de-aggregation of the anion free complex and the subsequent anion binding event. The stability of the complexes was estimated by DFT calculations. Chapter Five outlines the synthesis of complexes of L for other transition metals relevant to small molecule activation. Chapter Six contains a conclusion and suggestions on further investigations to carry out. Chapter Seven presents the full experimental details and analytical data for this work.

Estudo da reação de redução de O2 em meio ácido em uma matriz de carbono Printex 6L modificado com ftalocianina de prata / Study of the reduction reaction of O2 in acidic environment on Printex 6L carbon modified with silver phthalocyanine

Ribeiro, Gabriela Cabral Bremenkamp

18 August 2017

Este trabalho teve como objetivo estudar a atividade eletrocatalítica da matriz Printex 6L contendo o modificador organometálico ftalocianina de prata nos percentuais 0,5; 1,0; 3,0 e 5,0% m/m para a Reação de Redução de Oxigênio (RRO). Para isso, fezse a constatação da incorporação do modificador por Fluorescência de Raios - X (FRX), o estudo da estabilidade dos catalisadores pela técnica de voltametria cíclica, bem como a avaliação da eficiência de corrente para eletrogeração de H2O2 a partir dos dados coletados na voltametria de varredura linear utilizando um sistema de eletrodo de discoanel rotatório (RRDE). A análise dos 40 ciclos obtidos para a voltametria cíclica revelou que os materiais contendo 0,5; 1,0; 3,0 e 5,0% m/m de ftalocianina de prata suportados na matriz de carbono amorfo apresentaram picos correspondentes a reações redox atribuídos à presença de impurezas, os quais desapareceram logo nos primeiros ciclos. O estudo da eficiência de corrente e número de elétrons envolvidos na RRO para os catalisadores avaliados mostraram uma queda na eficiência de corrente em relação ao padrão 2 elétrons Printex 6L (H2O2% = 92% e nt = 2,1), para os catalisadores contendo 0,5% (H2O2% = 62%), 1,0% (H2O2% = 76%) e 5% (H2O2% = 69%) de ftalocianina de prata, bem como aumento no número de elétrons envolvidos na RRO (nt = 2,8, 2,4, 2,6, respectivamente). Para o material contendo 3,0% de ftalocianina de prata, obteve-se eficiência de corrente para peróxido de hidrogênio e número de elétrons envolvidos na reação semelhante aos do padrão 2 elétrons, Printex 6L (3% Ft-Ag: H2O2% = 89% e nt = 2,2) . Avaliando as curvas de Koutecký-Levich obtidas para os materiais modificados, observou-se a semelhança da inclinação das retas correspondentes ao Printex 6L e ao material 3% Ft-Ag, mostrando que estes possuem comportamento similar, o que também é observado nos resultados obtidos anteriormente. No entanto, os materiais estudados apresentaram rendimento para a RRO via 2 elétrons inferiores ao Printex não modificado, indicando que a modificação do Printex com a Ft-Ag não é interessante para a obtenção de H2O2. / The objective of this work was to study the electrocatalytic activity of the carbon black containing the organometallic modifier silver phthalocyanine in the percentages 0.5, 1.0, 3.0 and 5.0% m / m for the Oxygen Reduction Reaction (ORR). For this, I studied the incorporation of the modifier by X-Ray Fluorescence, the stability of the catalysts by the cyclic voltammetry technique, as well as the evaluation of the current efficiency for H2O2 electrogeneration from the data Collected in linear scanning voltammetry using a rotatory disc-ring electrode system (RRDE). The analysis of the 40 cycles obtained for cyclic voltammetry showed that carbon materials containing 0.5, 1.0, 3.0 and 5.0% w/w of silver phthalocyanine had peaks corresponding to redox reactions of impurities, which disappeared as early as the first cycles. The study of the current efficiency and number of electrons involved in the RRO for the catalysts evaluated showed a decrease in the current efficiency in relation to the 2 Printex 6L (H2O2% = 92% and nt = 2.1) electrons for the catalysts containing 0.5% (H2O2% = 62%), 1.0% (H2O2% = 76%) and 5% (H2O2% = 69%) of silver phthalocyanine, as well as increase in the number of electrons involved in RRO (nt = 2.8, 2.4, 2.6, respectively). For the material containing 3.0% silver phthalocyanine, it was obtained current efficiency for hydrogen peroxide and the number of electrons involved in the reaction similar to the standard 2 electrons, Printex 6L (3% Ft-Ag: H2O2% = 89% e nt = 2.2). By evaluating the Koutecký-Levich curves obtained for the modified materials, we observed the similarity of the inclination of the lines corresponding to Printex 6L and the material 3% Ft-Ag, showing that they have similar behavior, which is also observed in the obtained results previously. However, the materials studied presented yield for the RRO via 2 electrons lower than the unmodified Printex, indicating that the modification of the Printex with the Ft-Ag is not interesting to obtain H2O2.

Carbon

carbono

ftalocianina de prata

hydrogen peroxide electrogeneration

Oxygen reduction reaction

Printex 6L

Printex 6L

Reação de redução de oxigênio

silver phthalocyanine

Eletrogeração de peróxido de hidrogênio (H2O2) em eletrodos de difusão gasosa (EDG) modificados com quinonas (metil-p-benzoquinona, antraquinona-2-ácido carboxílico e ácido antraflávico) e azocomposto (Sudan Red 7B) / Electrogeneration of hydrogen peroxide (H2O2) in gas diffusion electrodes (GDE) modified with quinones (methyl-p-benzoquinone, anthraquinone-2-carboxylic acid and anthraflavic acid) and azo compound (Sudan Red 7B)

Moreira, Juliana

13 November 2018

Os processos oxidativos avançados (POA) são uma alternativa para complementar os processos clássicos de tratamento de efluentes que podem não ser eficientes para remoção de alguns tipos de poluentes como, por exemplo, os poluentes emergentes. Os POA se baseiam na geração de espécies altamente reativas (radicais hidroxila), a partir de peróxido de hidrogênio (H2O2), que oxidam os poluentes. O H2O2 pode ser eletrogerado in situ pela reação de redução de oxigênio (RRO) no meio reacional. O uso de eletrodos de difusão gasosa (EDG) altamente porosos proporciona o suprimento de oxigênio na interface eletrodo/solução podendo aumentar a velocidade da RRO. O uso de modificadores como quinonas e azocompostos imobilizados à matriz de carbono dos EDG podem aumentar a geração de H2O2. Portanto, os modificadores orgânicos Sudan Red 7B (SR7B), metil-p-benzoquinona (MPB), ácido antraflávico (AA) e antraquinona-2-ácido carboxílico (A2CA) foram adicionados em diferentes teores ao carbono Printex L6 (CP) e microcamadas porosas destes materiais foram estudados por voltametria cíclica e de varredura linear em eletrodo de disco-anel rotatório (RRDE). Os materiais contendo 0,5% de SR7B e 5,0% de MPB levaram a aumento na eficiência de geração de H2O2 para 86,2 e 85,5%, respectivamente, em relação ao CP puro que levou a 82,8%. EDG de CP modificados com 0,5% de SR7B foram construídos com telas metálicas em sua faces externas e a aplicação de densidades de corrente de 75, 100 e 150 mA cm-2 levou a uma maior eletrogeração de H2O2. Em densidades de corrente de 75 mA cm-2, o EDG modificado gerou 1020,1 mg L-1 de H2O2 com consumo energético de 118,0 kWh kg-1 de H2O2, constante cinética aparente de 37,3 mg L-1 min-1 e eficiência de corrente de 17,9%, enquanto o EDG de CP puro gerou menor concentração de H2O2; 717, 3 mg L-1, com maior consumo energético; 168,5 kWh kg-1, menor constante cinética aparente; 21,4 mg L-1 min-1, e menor eficiência de corrente; 12,6%. Portanto, o EDG modificado poderia ser empregado em sistemas que precisem de altas gerações de H2O2. / The advanced oxidation processes (AOP) are an alternative to the classical processes of treatment of effluents that may not be effective for the removal of some types of pollutants such as emerging pollutants. The AOP are based on the highly reactive species (hydroxyl radicals) from hydrogen peroxide (H2O2), which oxidize pollutants. H2O2 can be electrogenerated in situ by the oxygen reduction reaction (ORR) in the reaction medium. The use of highly porous gas diffusion electrodes (GDE) provides the supply of oxygen at the electrode/solution interface, which can increase the RRO speed. The use of modifiers such as quinones and azocompounds immobilized on the carbon matrix of GDE may increase H2O2 generation. Therefore, the organic modifiers Sudan Red 7B (SR7B), methyl-p-benzoquinone (MPB), anthraflavic acid (AA) and anthraquinone-2-carboxylic acid (A2CA) were added in different contents to carbon Printex L6 (CP) and microporous layers of these materials were studied by cyclic voltammetry and linear sweep voltammetry on a rotating ring- disc electrode (RRDE). Materials with 0.5% of SR7B and 5.0% of MPB increased the current efficiency for electrogeneration of H2O2 to 86.2 and 85.5%, respectively, in relation to pure CP that leaded to 82.8%. GDE of CP modified with 0.5% of SR7B were constructed with metallic screens on their outer faces and an application of current densities of 75, 100 and 150 mA cm-2 led to a greater electrogeneration of H2O2. At current densities of 75 mA cm-2, the modified GDE generated 1020.1 mg L-1 of H2O2 with energy consumption of 118.0 kWh kg-1 of H2O2, apparent kinetic constant of 37.3 mg L-1 min-1 and current efficiency of 17.9%, while GDE of pure CP generated lower H2O2 concentration; 717, 3 mg L-1, with higher energy consumption; 168.5 kWh kg-1, lower apparent kinetic constant; 21.4 mg L-1 min-1, and lower current efficiency; 12.6%. Therefore, the modified GDE could be applied in systems that require high generations of H2O2.

advanced oxidative processes

azo compounds

azocompostos

eletrodo de difusão gasosa

gas diffusion electrode

modificadores orgânicos

organic modifiers

oxygen reduction reaction

processos oxidativos avançados

quinonas

quinones

reação de redução do oxigênio

SURFACE AND STRUCTURAL MODIFICATION OF CARBON ELECTRODES FOR ELECTROANALYSIS AND ELECTROCHEMICAL CONVERSION

Zhang, Yan

01 January 2018

Electrocatalysis is key to both sensitive electrochemical sensing and efficient electrochemical energy conversion. Despite high catalytic activity, traditional metal catalysts have poor stability, low selectivity, and high cost. Metal-free, carbon-based materials are emerging as alternatives to metal-based catalysts because of their attractive features including natural abundance, environmental friendliness, high electrical conductivity, and large surface area. Altering surface functionalities and heteroatom doping are effective ways to promote catalytic performance of carbon-based catalysts. The first chapter of this dissertation focuses on developing electrode modification methods for electrochemical sensing of biomolecules. After electrochemical pretreatment, glassy carbon demonstrates impressive figures-of-merit in detecting small, redox-active biomolecules such as DNA bases and neurotransmitters. The results highlight a simplified surface modification procedure for producing efficient and highly selective electrocatalysts. The next four chapters focus on evaluating nitrogen-doped carbon nano-onions (𝑛-CNOs) as electrocatalysts for oxygen reduction and CO2 reduction. 𝑛-CNOs exhibit excellent electrocatalytic performance toward O2 to H2O reduction, which is a pivotal process in fuel cells. 𝑛-CNOs demonstrate excellent resistance against CO poisoning and long-term stability compared to state-of-the-art Pt/C catalysts. In CO2 electrochemical conversion, 𝑛-CNOs demonstrate significant improvement in catalytic performance toward reduction of CO2 to CO with a low overpotential and high selectivity. The outstanding catalytic performance of 𝑛-CNOs originates from the asymmetric charge distribution and creation of catalytic sites during incorporation of nitrogen atoms. High contents of pyridinic and graphitic N are critical for high catalytic performance. This work suggests that carbon-based materials can be outstanding alternatives to traditional metal-based electrocatalysts when their microstructures and surface chemistries are properly tailored.

Glassy Carbon

Electrochemical Treatment

Nitrogen-Doped Carbon Nano-Onion

Oxygen Reduction Reaction

CO2 Reduction Reaction

Biochemistry

Catalysis and Reaction Engineering

Nanoscience and Nanotechnology

Perovskite-related and trigonal RBaCo₄O₇-based oxide cathodes for intermediate temperature solid oxide fuel cells

Kim, Young Nam, 1974-

06 February 2012

Solid oxide fuel cells (SOFCs) offer the advantages of (i) employing less expensive catalysts compared to the expensive Pt catalyst used in proton exchange membrane fuel cells and (ii) directly using hydrocarbon fuels without requiring external fuel reforming due to the high operating temperature. However, the conventional high operating temperatures of 800 - 1000 °C lead to interfacial reactions and thermal expansion mismatch among the components and limitations in the choice of electrode and interconnect materials. These problems have prompted a lowering of the operating temperature to an intermediate range of 500 - 800 °C, but the poor oxygen reduction reaction kinetics of the conventional La[subscript 1-x]Sr[subscript x]MnO₃ perovskite cathode remains a major obstacle for the intermediate temperature SOFC. In this regard, cobalt-containing oxides with perovskite or perovskite-related structures have been widely investigated, but they suffer from large thermal expansion coefficient (TEC) mismatch with the electrolytes. With an aim to lower the TEC and maximize the electrochemical performance, this dissertation focuses on perovskite-related and trigonal RBaCo₄O₇-based oxide cathode materials. First, the effect of M = Fe and Cu in the perovskite-related layered LnBaCo₂₋xMxO₊[delta] (Ln = Nd and Gd) oxides has been investigated. The Fe and Cu substitutions lower the polarization resistance and offer fuel cell performance comparable to that of La[subscript 1-x]Sr[subscript x]CoO₃₋[delta] perovskite due to improved chemical stability with the electrolyte and a better matching of the TEC with those of standard electrolytes. Second, the perovskite-related intergrowth oxides Ln(Sr,Ca)₃Fe₁.₅Co₁.₅O₀ and La₁.₈₅Sr₁.₁₅Cu[subscript 2-x]Co[subscript x]O[subscript 6 +delta] and their composites with gadolinia-doped ceria (GDC) have been investigated. The electrical conductivity, TEC, and catalytic activity increase with increasing Co content. The composite cathodes exhibit enhanced electrochemical performance due to lower TEC and increased triple-phase boundary. Third, RBa(Co,Zn)₄O₇ (R = Y, Ca, and In) oxides with a trigonal structure and tetrahedral-site Con+ ions have been investigated. The chemical instability normally encountered with this class of oxides has been overcome by appropriate cationic substitutions as in (Y₀.₅Ca₀.₅)Ba(Co₂.₅Zn₁.₅)O₇ and (Y₀.₅In₀.₅)BaCo₃ZnO₇. With an ideal matching of TEC with those of standard electrolytes, the RBa(Co,Zn)₄O₇ (R = Y, Ca, and In) + GDC composite cathodes exhibit low polarization resistance and electrochemical performance comparable to that of perovskite oxides. / text

Cathodes

Solid oxide fuel cells

Oxygen reduction reaction

Layered perovskite

Intergrowth oxide

Mixed ionic electronic conductors

Oxygen separation membranes

Metal oxides

Crystal chemistry

Non-Precious Cathode Electrocatalytic Materials for Zinc-Air Battery

Kim, Baejung

13 December 2013

In the past decade, rechargeable batteries attracted the attention from the researchers in search for renewable and sustainable energy sources. Up to date, lithium-ion battery is the most commercialized and has been supplying power to electronic devices and hybrid and electric vehicles. Lithium-ion battery, however, does not satisfy the expectations of ever-increasing energy and power density, which of their limits owes to its intercalation chemistry and the safety.1-2 Therefore, metal-air battery drew much attention as an alternative for its high energy density and a simple cell configuration.1 There are several different types of metal-air batteries that convey different viable reaction mechanisms depending on the anode metals; such as Li, Al, Ca, Cd, and Zn. Redox reactions take place in a metal-air cell regardless of the anode metal; oxidation reaction at the anode and reduction reaction at the air electrode. Between the two reaction, the oxygen reduction reaction (ORR) at the air electrode is the relatively the limiting factor within the overall cell reactions. The sluggish ORR kinetics greatly affects the performance of the battery system in terms of power output, efficiency, and durability. Therefore, researchers have put tremendous efforts in developing highly efficient metal air batteries and fuel cells, especially for high capacity applications such as electric vehicles. Currently, the catalyst with platinum nanoparticles supported on carbon material (Pt-C) is considered to exhibit the best ORR activities. Despite of the admirable electrocatalytic performance, Pt-C suffers from its lack of practicality in commercialization due to their prohibitively high cost and scarcity as of being a precious metal. Thus, there is increasing demand for replacing Pt with more abundant metals due economic feasibility and sustainability of this noble metal.3-5 Two different attitudes are taken for solution. The first approach is by optimizing the platinum loading in the formulation, or the alternatively the platinum can be replaced with non-precious materials. The purpose of this work is to discover and synthesize alternative catalysts for metal-air battery applications through optimized method without addition of precious metals. Different non-precious metals are investigated as the replacement of the precious metal including transition metal alloys, transition metal or mixed metal oxides, and chalcogenides. These types of metals, alone, still exhibits unsatisfying, yet worse, kinetics in comparison to the precious metals. Nitrogen-doped carbon material is a recently well studied carbon based material that exhibits great potential towards the cathodic reaction.6 Nitrogen-doped carbon materials are found to exhibit higher catalytic activity compared to the mentioned types of metals for its improved conductivity. Benefits of the carbon based materials are in its abundance and minimal environmental footprints. However, the degradation of these materials has demonstrated loss of catalytic activity through destruction of active sites containing the transition metal centre, ultimately causing infeasible stability. To compensate for these drawbacks and other limits of the nitrogen-doped carbon based catalysts, nitrogen-doped carbon nanotubes (NCNT) are also investigated in the series of study. The first investigation focuses on a development of a simple method to thermally synthesize a non-precious metal based nitrogen-doped graphene (NG) electrocatalyst using exfoliated graphene (Ex-G) and urea with varying amounts of iron (Fe) precursor. The morphology and structural features of the synthesized electrocatalyst (Fe-NG) were characterized by SEM and TEM, revealing the existence of graphitic nanoshells that potentially contribute to the ORR activity by providing a higher degree of edge plane exposure. The surface elemental composition of the catalyst was analyzed through XPS, which showed high content of a total N species (~8 at.%) indicative of the effective N-doping, present mostly in the form of pyridinic nitrogen groups. The oxygen reduction reaction (ORR) performance of the catalyst was evaluated by rotating disk electrode voltammetry in alkaline electrolyte and in a zinc-air battery cell. Fe-NG demonstrated high onset and half-wave potentials of -0.023 V (vs. SCE) and -0.110 V (vs. SCE), respectively. This excellent ORR activity is translated into practical zinc-air battery performance capabilities approaching that of commercial platinum based catalyst. Another approach was made in the carbon materials to further improve the cost of the electrode. Popular carbon allotropes, CNT and graphene, are combined as a composite (GC) and heteroatoms, nitrogen and sulfur, are introduced in order to improve the charge distribution of the graphitic network. Dopants were doped through two step processes; nitrogen dopant was introduced into the graphitic framework followed by the sulfur dopant. The coexistence of the two heteroatoms as dopants demonstrated outstanding ORR performance to those of reported as metal free catalysts. Furthermore, effects of temperature were investigated through comparing ORR performances of the catalysts synthesized in two different temperatures (500 ??? and 900 ???) during the N-doping process (consistent temperature was used for S-doping). Through XPS analysis of the surface chemistry of catalysts produced with high temperature during the N-doping step showed absence of N-species after the subsequent S-doping process (GC-NHS). Thus, the synergetic effects of the two heteroatoms were not revealed during the half-cell testing. Meanwhile, the two heteroatoms were verified in the catalyst synthesized though using low temperature during the N-doping process followed by the S-doping step (GC-NLS). Consequently, ORR activity of the resulting material demonstrated promising onset and half-wave potentials of -0.117 V (vs. SCE) and -0.193 V (vs. SCE). In combination of these investigations, this document introduces thorough study of novel materials and their performance in its application as ORR catalyst in metal air batteries. Moreover, this report provides detailed fundamental insights of carbon allotropes, and their properties as potential elecrocatalysts and essential concepts in electrochemistry that lies behind zinc-air batteries. The outstanding performances of carbon based electrocatalyst are reviewed and used as the guides for further direction in the development of metal-air batteries as a promising sustainable energy resource in the future.

oxygen reduction reaction

graphene nanosheet

carbon nanotube

zinc-air battery

composite

activity

dual-doped graphene

exfoliated graphene

iron

nano-shells

nitrogen-doped graphene

sulfur-doped graphene