Theoretical Studies on Electrode Reactions in Proton Exchange Membrane Fuel Cells

Tian, Feng

January 2011

No description available.

Oxygen Reduction Reaction

Cathode

Fuel Cells

Platinum catalysts

durability

alloy catalysts

electron transfer

Non-Precious Metal Electrocatalysts for the Oxygen Reduction Reaction in Proton Exchange Membrane (PEM) Fuel Cells

Singh, Deepika

18 August 2014

No description available.

Chemical Engineering

Theoretical Study of Oxygen Reduction Reaction Catalytic Properties of Defective Graphene in Fuel Cells

Zhang, Lipeng

30 August 2013

No description available.

Quantum Physics

Chemical Engineering

Materials Science

Preparation and characterization of highly active nano pt/c electrocatalyst for proton exchange membrane fuel cell.

Ying, Qiling

January 2006

<p>Catalysts play an essential role in nearly every chemical production process. Platinum supported on high surface area carbon substrates (Pt/C) is one of the promising candidates as an electrocatalyst in low temperature polymer electrolyte fuel cells. Developing the activity of the Pt/C catalyst with narrow Pt particle size distribution and good dispersion has been a main concern in current research.</p> <p><br /> In this study, the main objective was the development and characterization of inexpensive and effective nanophase Pt/C electrocatalysts. A set of modified Pt/C electrocatalysts with high electrochemical activity and low loading of noble metal was prepared by the impregnation-reduction method in this research. The four home-made catalysts synthesized by different treatments conditions were characterized by several techniques such as EDS, TEM, XRD, AAS, TGA, BET and CV.</p> <p><br /> Pt electrocatalysts supported on acid treatment Vulcan XC-72 electrocatalysts were produced successfully. The results showed that Pt particle sizes of Pt/C (PrOH)x catalysts between 2.45 and 2.81nm were obtained with homogeneous dispersion, which were more uniform than the commercial Pt/C (JM) catalyst. In the electrochemical activity tests, ORR was confirmed as a structure-sensitive reaction. The Pt/C (PrOH/pH2.5) showed promising results during chemically-active surface area investigation, which compared well with that of the commercial standard Johnson Matthey Pt/C catalyst. The active surface area of Pt/C (PrOH/pH2.5) at 17.98m2/g, was higher than that of the commercial catalyst (17.22 m2/g ) under the conditions applied. In a CV electrochemical activity test of Pt/C catalysts using a Fe2+/Fe3+ mediator system study, Pt/C (PrOH/pH2.5) (67mA/cm2) also showed promise as a catalyst as the current density is comparable to that of the commercial Pt/C (JM) (62mA/cm2).</p> <p><br /> A remarkable achievement was attained in this study: the electrocatalyst Pt supported on CNTs was synthesized effectively. This method resulted in the smallest Pt particle size 2.15nm. In the electrochemically-active surface area study, the Pt/CNT exhibited a significantly greater active surface area (27.03 m2/g) and higher current density (100 mA/cm2) in the Fe2+/Fe3+ electrochemical mediator system than the other home-made Pt/C catalysts, as well as being significantly higher than the commercial Pt/C (JM) catalysts. Pt/CNT catalyst produced the best electrochemical activities in both H2SO4 and K4[Fe(CN)6] electrolytes. As a result of the characteristics of Pt/CNT，it can be deduced that the Pt/CNT is the best electrocatalyst prepared in this study and has great potential for use in fuel cell applications.</p>

Electrocatalyst

Nano-size

Platinum

Carbon material

Carbon nanotubes

Cathode

Hydrogen evolution reaction

Oxygen reduction reaction

Impregnation-reduction

Development and Application of Reaction Route Graph Representation and Analysis of Catalytic Reaction Networks

O'Malley, Patrick Daniel

18 January 2017

Chemical reactions can have a staggering amount of molecular complexity. Reaction mechanisms have been proposed with over one hundred elementary reaction steps that occur in the same system simultaneously. While several methods exist to simplify and make sense of the pathways and kinetics via which these reactions proceed, e.g., reaction graphs, sensitivity or flux analysis, microkinetic analysis, and comparison of energy landscapes, etc., these methods all have limitations and are often not able to capture a comprehensive picture of the kinetics of system. It has been found useful to view these mechanisms as a network, i.e., a reaction graph. These graphs enable the visualization of the pathways of the reaction and can provide an analytical tool for pathway and kinetic analysis. However, many of the specific graph-theoretic approaches in the literature are not the most suitable for kinetic analysis of complex mechanisms; as they are simply not based on rules that are rigorous enough to fully enumerate all the pathways or provide quantitative analysis of the reaction rates. Our Reaction Route (RR) Graph approach is different in that it depicts the mechanism by a graph that is consistent with all physical and chemical laws associated with reaction networks, particularly being consistent with mass and energy conservation, i.e., Kirchoff’s Flux Law (KFL) and Kirchoff’s Potential Law (KPL). Because of their adherence to these laws, RR Graphs are able to provide an accurate graph-theoretical tool not only for depicting all reactions routes as walks (hence the name RR Graph) but also for pruning mechanisms and allowing a simplified but accurate quantitative description of reaction rates. This adherence to KFL and KPL does mean that the construction and implementation of these graphs can be prohibitively difficult for large mechanisms. For large reaction systems,especially nonlinear mechanisms, it is not realistic to generate these graphs by hand. And although there exists an analytical solution to find a determinant matrix for the RR Graph of a mechanism, the process involves an exhaustive search for a solution which experiences a combinatorial explosion as the number of steps gets very large. This leads to the idea of developing an algorithm for a computer program that can determine how to generate these graphs automatically. Unfortunately, the same combinatorial explosion is present such that for a moderately sized twenty step mechanism, it could take an average computational processor over a decade to find a solution. We have determined, however, that this brute force combinatorial approach can be avoided if heuristics could be developed to bridge gaps in our knowledge of how these graphs are constructed. Thus, developing a better analytical approach and/or a tighter set of heuristics for a computer algorithm are the overarching goals of this work. To make progress toward developing such heuristics, a set of microkinetic mechanisms were analyzed with the notion that the realization of the RR Graphs would highlight a better approach to their construction and usage. In particular, a very large linear reaction system, a smaller linear system and two non-linear reaction systems were analyzed to develop insights into how each graph is manually constructed and analyzed. Furthermore, kinetic analysis was done for these mechanisms and compared to experimental data and other analytical tools to prove not only the validity of the RR Graphs, but also how they are a significant improvement over more commonly used approaches for mechanistic and kinetic analysis. Based on the lessons learned through a consideration of these examples, a set of heuristics are established and enumerated with the ultimate goal of developing an intuitive algorithm that can help automate drawing and kinetic analysis via RR Graphs of complex mechanisms.

catalytic reaction

methane steam reforming

oxygen reduction reaction

reaction affinity

reaction resistance

reaction route graph analysis

water gas shift reaction

Estudo do desempenho e degradação de catalisadores e membranas em células a combustível de eletrólito polimérico / A performance and degradation study of catalysts and membranes for proton exchange fuel cell

Fernandes, Adriano Caldeira

05 November 2009

Neste trabalho, a reação de redução de oxigênio (RRO) foi estudada em catalisadores nano-particulados de Pt e ligas de PtM (M = Co, Cr, Fe e Ni) suportados em carbono, preparados localmente por método de impregnação, para aplicação em células a combustível de eletrólito polimérico (CCEP). A caracterização física destes materiais foi realizada através das técnicas de energia dispersiva de raios x (EDS), difração de raios x (DRX), absorção de raios x (XAS) e microscopia eletrônica de varredura e transmissão. Os testes eletroquímicos dos catalisadores foram realizados com o uso de voltametria cíclica, medidas de polarização em estado estacionário e espectroscopia de impedância eletroquímica. Estes estudos foram conduzidos em meia-célula usando eletrodos de disco/anel rotatórios e tendo ácido sulfúrico (0,5 mol L-1) como eletrólito e em células unitárias CCEP contendo membranas de Nafion&reg; 212 (N212) e Nafion&reg; 112 (N112), alimentadas com H2 no ânodo e O2/ar no cátodo, em diferentes temperaturas e pressões. Finalmente, foram também realizados estudos de durabilidade tanto dos catalisadores como das membranas poliméricas, os quais foram submetidos a procedimentos de degradação acelerada (PDA). Os resultados dos estudos em meia-célula mostraram que os catalisadores bimetálicos (PtM) são menos ativos cataliticamente para a RRO comparados à Pt pura, fatos que não se confirmaram nos testes em células unitárias. Por outro lado, após a aplicação do PDA os catalisadores apresentaram mudanças significativas em suas propriedades estruturais e eletrônicas que levaram à diminuição da atividade frente a RRO. No geral as células a combustível com N212 apresentaram melhor desempenho do que aquelas com N112, quando operadas com ar no cátodo, porém os estudos confirmaram que a degradação da membrana leva à redução do desempenho devido o aumento do cruzamento de gás, principalmente de H2. / In this work, the oxygen reduction reaction (ORR) was studied on nano-particulated Pt and PtM (M = Co, Cr, Fe e Ni) alloy electrocatalysts supported on carbon, prepared by an impregnation method, for utilization on polymer electrolyte fuel cell (PEFC). The physical properties of the materials have been investigated by energy dispersive X-ray analyses (EDX), X-ray diffraction (XRD), X-ray absorption spectroscopy (XAS), and scanning and transmission electron microscopy. The electrochemical investigations were carried out using cyclic voltammetry, steady state polarization measurements and electrochemical impedance spectroscopy. Studies were conducted on half-cells with rotating ring-disk electrodes having 0.5 mol L-1 H2SO4 as electrolyte and on PEFC single cells built with Nafion&reg; 212 (N212) and Nafion&reg; 112 (N112) membranes, feed with H2 and O2/air at several temperatures and pressures. Finally, durability studies of either, the catalysts and membranes, were carried out, after they were submitted to accelerated degradation procedures (ADP). The half-cell results indicated a lower activity for the ORR of the bimetallic electrocatalysts, compared to pure Pt, but this was not confirmed by the single cell tests. On the other hand, after the ADP, the catalysts showed significant changes on the morphological and electronic properties, which leaded to a reduction of the activity for the ORR. The single cells with N212 presented higher performance than those with N112, when operating with air supplied cathodes, but the results confirmed that the degradation of the membranes leads to a reduction of the fuel cell performance by increasing the gas crossover, mainly of H2.

Catalisador

Catalyst

Célula a combustível

Degradação

Degradation

Membrana

Membrane

Oxygen reduction reaction

PEM fuel cell

Reação de redução de oxigênio

Desenvolvimento de catalisadores de Pt-Co/C para a reação de redução de oxigênio em células a combustível de membrana de troca protônica / Development of Pt-Co/C electrocatalysts for the oxygen reduction reaction in the proton exchange membrane fuel cells

Salgado, José Ricardo Cezar

25 February 2005

A pesquisa e desenvolvimento de novos materiais catalisadores para as reações eletródicas em células a combustível de membrana trocadora de prótons são de grande importância para a viabilização destes sistemas como geradores de energia. Neste trabalho foram preparados catalisadores de Pt-Co suportados em carbono (Pt-Co/C) por diferentes métodos e são apresentados os resultados da caracterização física por diferentes técnicas. Os resultados da avaliação da atividade eletrocatalítica para a reação de redução de oxigênio (RRO) em ácido sulfúrico, na ausência e presença de metanol e a avaliação do desempenho destes materiais em células a combustível unitárias alimentadas com H2 e/ou metanol (no ânodo) e O2 (no cátodo) são também apresentados. Em linhas gerais, observou-se que os catalisadores de Pt-Co/C apresentaram maior atividade catalítica para a RRO quando comparados ao catalisador Pt/C sendo o método de impregnação o melhor método de preparação dentre os investigados. O catalisador Pt75Co25/C, preparado pela deposição do Co sobre Pt/C seguido pelo tratamento à alta temperatura, apresentou o melhor desempenho para a RRO devido à provável formação de uma liga que apresenta menor tamanho de partícula e menor distância interatômica Pt-Pt que o Pt/C. Adicionalmente, este material apresentou boa estabilidade nos testes em célula a combustível alimentada com H2/O2. Catalisadores Pt-Co/C mostraram boa tolerância ao metanol quando usados como cátodos com maior atividade para a RRO que o Pt/C, tanto em ácido sulfúrico na ausência e presença de metanol como na célula a combustível de metanol direto. / Research and development of new catalyst materials for the electrodic reactions in polymer electrolyte fuel cells are of great importance for the development of these systems as sources of energy. In this work electrocatalyts Pt-Co supported on carbon (Pt-Co/C) were prepared by different methods. Additionally to conventional electrochemical characterization, the materials were physically characterized by means of several different techniques. The evaluation of the electrocatalytic activity for the oxygen reduction reaction (ORR) in acid media, in the absence and presence of methanol, as well as the evaluation of the performance in fuel cells fed with H2 or methanol (in the anode) and O2 (in the cathode) are investigated. Pt-Co/C electrocatalyts presented better catalytic activity for the ORR when compared to Pt/C. Additionally, the impregnation method was found as being the best preparation method investigated. Pt75Co25/C electrocatalyts prepared by deposition of Co on Pt/C followed by thermal treatment at high temperatures presented the best performance for the ORR due the probable formation of an alloy with small particle size and shorter Pt-Pt bond distance compared to Pt/C. This material presented good stability in fuel cells. Pt-Co/C electrocatalyts showed good tolerance to methanol when used as cathode materials, showing better activity for the ORR compared to Pt/C, in acid medium in the absence and presence of methanol and in direct methanol fuel cells.

Catalisadores de Pt-Co/C

Célula a combustível

Fuel cell

Oxygen reduction reaction

Pt-Co/C electrocatalysts

Reação de redução de oxigênio

Desempenho eletrocatalítico de eletrodos recobertos com filmes de quitosana frente a reação de redução de oxigênio em meio alcalino / Electrocatalytic performance of electrodes recovered with chitosan films for the oxygen reduction reaction in alkaline medium

Sanches, Cassandra Degelo

13 November 2009

A reação de redução de oxigênio (RRO) foi estudada em eletrodos lisos de platina e prata recobertos com filmes de quitosana e em eletrodos porosos de Pt/C, Ag/C, MnyOx/C e TiO2/C na ausência e na presença de filmes à base de quitosana, em eletrólito alcalino. Nestes estudos foram empregadas curvas de polarização em estado estacionário, obtidas em eletrodos de disco rotatório (EDR) e em células a combustível alcalina (CCA) unitárias, através das quais foram construídos os correspondentes diagramas de curvas de Tafel e os gráficos de Levich. Os estudos realizados em EDRs permitiram estabelecer-se uma boa compreensão da atividade catalítica e dos mecanismos envolvidos na RRO. Foi observada uma diminuição da atividade eletrocatalítica dos eletrodos metálicos (Pt e Ag lisos e porosos) quando na presença dos filmes de quitosana, havendo também uma mudança no mecanismo da reação. Assim, nos experimentos de EDR verificou-se que em altas densidades de corrente a etapa determinante da velocidade é a adsorção do oxigênio, em contraste com os eletrodos sem o filme para os quais a etapa determinante é a difusão do oxigênio. Nestes casos não foi possível calcular o número de elétr. Já, nos casos dos eletrodos de MnyOx/C e TiO2/C não foi observada nenhuma diminuição significativa na atividade eletrocatalítica destes materiais na presença dos filmes de quitosana, assim como no mecanismo da reação na presença dos filmes (inclusive no número de elétrons envolvidos na reação), apesar de se notar um pequeno aumento nos valores dos coeficientes de Tafel. Foram também realizados testes de alguns dos materiais como cátodos em células a combustível alcalinas unitárias alimentadas com hidrogênio/oxigênio, tendo sido verificado que o desempenho é promissor, apesar de ser inferior ao de células com eletrólito de membrana ácidas. / The oxygen reduction reaction was studied on smooth platinum and silver electrodes recovered with chitosan films and on Pt/C, Ag/C, MnyOx/C e TiO2/C porous electrodes in the presence or absence of chitosan-based films in alkaline electrolyte. These studies were carried out using steady state polarization measurement, obtained in a rotating disc electrode (RDE) and in alkaline fuel cells (AFC) (single cell), from which the corresponding Tafel curves and Levich plots were built. The studies carried out using the RDE had allowed establishing a good understanding of the catalytic activity and of the involved RRO mechanisms. A reduction in the electrocatalytic activity of the metallic electrodes and a change in the reaction mechanism (Pt and Ag smooth and porous) were caused by the presence of the chitosan films Thus, the RDE experiments showed that at high current densities the rate determining step of the ORR is the oxygen adsorption, in contrast to the electrodes without the film for which the rate determining step is the oxygen diffusion. In these cases it was not possible to calculate the number of electrons involved in the reaction. In the cases of the MnyOx/C and TiO2/C electrodes no significant change in the electrocatalytic activity, as well as in the reaction mechanism were caused due to the presence of the films (also in the number of electrons involved in the reaction), although a small increase in the Tafel coefficient values was noted. Also, tests of some of the materials as cathodes in AFC single cells with hydrogen/oxygen were carried out. These results showed that the performance is promising, although inferior to those of acid membrane electrolyte fuel cells.

Alkaline Fuel Cell

Célula a Combustível Alcalina

Chitosan Membrane

Electrocatalysis

Electrochemistry

Eletrocatálise

Eletroquímica

Membrana de Quitosana

Oxygen Reduction Reaction

Reação de Redução de Oxigênio

Estudo da atividade eletrocatalá­tica de catalisadores à  base de platina suportada em carbetos de metais de transição para a reação de redução de oxigênio em meio ácido / Study of the electrocatalytic activity of platinum-based catalysts supported on transition metal carbide for the oxygen reduction reaction in acid medium

Bott Neto, José Luiz

10 August 2018

As células a combustível são dispositivos eletroquímicos que produzem energia elétrica limpa. Entretanto, o seu uso em larga escala ainda é limitado devido às enormes perdas de potencial que ocorrem no cátodo em função da lenta cinética da reação de redução de oxigênio (RRO). Portanto, é necessário o desenvolvimento de novos catalisadores que sejam viáveis comercialmente, apresentem alta atividade eletrocatalítica e grande estabilidade para esta reação. Neste trabalho, a RRO foi estuda em meio ácido em eletrocatalisadores à base de platina suportadas em carbetos de tungstênio (WC) e molibdênio (MoC) com diferentes estruturas cristalinas. Os carbetos foram preparados pelos métodos de decomposição térmica (MDT) e carburação (MC) e, subsequentemente, utilizados para a preparação dos catalisadores do tipo Pt-carbeto pelo método do ácido fórmico ou borohidreto de sódio. Estes materiais foram caracterizados por difração de raios-X (XRD), espectroscopia de energia dispersiva de raios-X (EDX), microscopia eletrônica de transmissão (TEM), espectroscopia de absorção de raios-X (XAS) in situ e espectroscopia de fotoelétrons excitados por raios-X (XPS). As medidas eletroquímicas foram realizadas em meio ácido usando a técnica de eletrodo disco-anel rotativo de camada fina. Os resultados de XRD, em conjunto com as medidas de TEM, indicaram que o MDT e MC fornecem carbetos com estruturas cúbicas (&beta;-WC1-x e &delta;-MoC) e hexagonais (&alpha;-WC e &alpha;-Mo2C) com tamanho de partícula < 2 nm e entre 10 e 40 nm, respectivamente. Os estudos eletroquímicos evidenciaram que os catalisadores Pt-carbeto/C apresentam diferenças de atividade específica (SA) e mássica (MA) para a RRO em função da estrutura e composição e que todos os catalisadores do tipo Pt-&beta;-WC1-x/C, Pt- &alpha;-Mo2C/C e Pt-&delta;-MoC/C e Pt2Ni- &alpha;-WC/C apresentam maior SA em comparação à Pt/C. A concentração de carbeto na matriz de carbono também influenciou significativamente os valores de SA, porém não há uma tendência clara que permita unificar um efeito comum para todos os catalisadores. Dentre todos estes catalisadores, o Pt-&beta;-WC1-x40/C e o Pt-&delta;-MoC40/C são 3,6 e 2,5 vezes mais ativos (SA) em comparação ao catalisador Pt/C. Também foi observado que a via predominante da RRO envolve cerca de 4 elétrons por molécula de oxigênio, com baixa produção de H2O2 em todos os casos. No caso dos materiais baseados em Pt-&beta;-WC1-x/C, análises de XANES in situ mostraram um pequeno aumento na ocupação da banda 5d da Pt, o que deve levar a uma interação Pt-OHx mais fraca, aumentando a cinética da RRO como observado. Além disso, os resultados de XPS evidenciam que a melhora na atividade específica está relacionada a um efeito sinérgico entre Pt ou Pt2Ni com as espécies do tipo WOx ou MoOx; exceto para os catalisadores de ligas Pt2Ni, para o qual os resultados de XPS indicaram a presença de WC na superfície do catalisador. Os testes de estabilidade mostraram que apesar do Pt/C ser mais ativo após 12.000 ciclos, o catalisador Pt-&alpha;-WC20/C é o mais estável em relação a sua AS, indicando que as interações benéficas das fases remanescente de Pt e WC/WOx são mantidas após o teste de durabilidade. / Fuel cells are electrochemical devices that produce clean electrical energy. However, their use on large scale is still limited due to the enormous potential losses that occur at the cathode due the slow kinetics of the oxygen reduction reaction (ORR). Therefore, the development of new catalysts that are commercially viable, present high electrocatalytic activity and great stability for this reaction is still necessary. In this work, the ORR was studied in acid medium on platinum-based electrocatalysts supported on tungsten (WC) and molybdenum (MoC) carbides with different crystalline structures. Carbides were prepared by the thermal decomposition (TDM) and a carburizing (CM) methodes and, subsequently used for the preparation of the Pt-carbide type catalysts by the formic acid or sodium borohydride method. These materials were characterized by X-ray diffraction (XRD), energy-dispersive X-ray spectroscopy (EDX), transmission electron microscopy (TEM), X-ray absorption spectroscopy (XAS) and X-ray photoelectron spectroscopy (XPS). The electrochemical measurements were performed in acid medium using the thin-layer rotating disk-ring electrode technique. The results of XRD, together with those of TEM, indicate that the MDT and MC provide carbides with cubic (&beta;-WC1-x and &delta;-MoC) and hexagonal ( &alpha;-WC and &alpha;-Mo2C) structures with particle size < 2 nm and between 10 and 40 nm, respectively. The Pt-carbide/C catalysts exhibit differences in the specific activity (SA) and mass (MA) for the ORR as a function of structure and composition. All catalysts of the types Pt-&beta;-WC1-x/C, Pt- &alpha;-Mo2C/C, Pt-&delta;-MoC/C and Pt2Ni- &alpha;-WC/C presented higher SA as compared to Pt/C. The concentration of carbide in the carbon matrix significantly influence the SA, but no tendency was clearly found so to identify a common effect catalysts overall. Among all catalysts, Pt-&beta;-WC1-x40/C and Pt-&delta;-MoC40/C are 3.6 and 2.5 times more active (SA) compared to the Pt/C catalyst. It was also observed that the predominant ORR mechanism involve &cong; 4 electrons per oxygen molecule, and so with negligible production of H2O2. In the case of the materials based on Pt-&beta;-WC1-x/C, in situ XANES analyzes evidenced a small increase in the Pt 5d-band, occupancy leading to a weaker Pt-OHx interaction, increasing ORR kinetics as observed. In addition, XPS results show that the improvement in SA is related to a synergistic effect between Pt or Pt2Ni with WOx or MoOx species, except for the Pt2Ni alloy catalysts, for which the XPS results indicated the presence of some WC on the catalyst surface. Stability tests show that although Pt/C is more active after 12,000 cycles, the Pt-&alpha;-WC20/C catalyst is the most stable relative to its SA, indicating that the beneficial interactions of the remaining phases of Pt and WC/WOx are maintained after the durability test.

carbetos

carbides

catalisadores

célula a combustível

electrocatalysis

fue cells

molibdênio

molybdenum

oxygen reduction reaction

reação redução de oxigênio

tungsten

tungstênio

Estudo da atividade e da estabilidade de eletrocatalisadores de Pt suportados em carbono, monocarbeto e dióxido de tungstênio frente a reação de redução de oxigênio / Study of the activity and stability of Pt electrocatalysts supported on carbon, tungsten monocarbide and tungsten dioxide for the oxygen reduction reaction

Ferreira, Orlando Lima de Sousa

16 October 2014

Os objetivos deste trabalho foram: i) estudar a degradação de catalisadores do tipo Pt-M (onde M = Co e Cr) suportados em carbono após tratamento ácido e a atividade catalítica dos mesmos para a reação de redução de oxigênio; ii) avaliar o desempenho e a estabilidade de eletrocatalisadores de platina suportada em monocarbeto e dióxido de tungstênio (WC/C e WO2/C, respectivamente) para a reação de redução de oxigênio em eletrólitos ácidos. O tratamento ácido foi realizado mantendo-se uma certa quantidade do eletrocatisador em uma solução ácida (H2SO4 0,5 mol L-1) a 90ºC por 24 h. Os catalisadores Pt3Co/C e Pt3Cr/C foram caracterizados antes e após o tratamento pelas seguintes técnicas: Espectroscopia por Dispersão de Energia de Raios X (EDX), Difratometria de Raios X (DRX), Microscopia Eletrônica de Transmissão (MET), Espectroscopia de Absorção de Raios X (XAS), como também submetidos a testes eletroquímicos. Os resultados mostraram que os metais menos nobres foram lixiviados devido ao tratamento ácido e que houve variações da região do potencial de redução de óxidos. Em relação aos carbertos de tungstênio, este foram sintetizados pelo método sonoquímico e caracterizados por EDX, DRX e MET. Os resultados eletroquímicos obtidos a partir desses materiais não apresentaram atividade catalítica significante para a RRO, porém, quando se tem Pt ancorada nesse material, a reação de redução de oxigênio é catalisada, similarmente ao desempenho de Pt/C, e segue uma reação via 4 elétrons. Já os materiais formados por dióxido de tungstênio foram sintetizados pelo método de impregnação e também foram caracterizados por EDX, DRX e MET. Os dados obtidos nos testes eletroquímicos destes materiais demonstraram uma certa atividade catalítica para RRO, e que esta reação se ocorre via 2 elétrons. Já para os materiais com Pt suportada em WO2/C, a reação segue a conhecida via 4 elétrons, como no caso de Pt/C. Ao serem submetidos ao tratamento ácido, tanto os catalisadores suportados em WC/C quanto os suportados em WO2/C apresentaram maior estabilidade quando comparados ao Pt/C comercial. / The objectives of this work were: i) to study the degradation of Pt-M catalysts (where M = Co and Cr) supported on carbon after acid treatment and their catalytic activities for the oxygen reduction reaction; ii) to evaluate the performance and stability of platinum electrocatalysts based in tungsten monocarbide (WC/C) and tungsten dioxide (WO2/C) for the oxygen reduction reaction in acidic electrolytes. The acid treatment was carried out by keeping a certain amount of eletrocatalyst in an acidic solution (H2SO4 0.5 mol L-1) at 90°C for 24 h. The Pt3Co/C and Pt3Cr/C catalysts were characterized before and after treatment by the following techniques: Energy Dispersive Spectroscopy (EDS), X-Ray Diffraction (XRD), Transmission Electron Microscopy (TEM), X-Ray Absorption Spectroscopy (XAS), followed by electrochemical tests. The results showed that the non-noble metals have been leached due to the acid treatment and that there are variations in the potential region of oxide reduction. Tungsten carbides, were synthesized by a chemistry and characterized by EDS, XRD and TEM. The electrochemical results obtained for the WC/C materials showed no significant catalytic activity for the ORR, but when Pt is anchored, the oxygen reduction reaction is catalyzed, and the performance is similar to that of Pt/C, and with reaction following the 4 electrons pathways. The materials formed by tungsten dioxide were synthesized by an impregnation method, and also characterized by EDS, XRD and TEM. The data obtained in the electrochemical tests of the bare materials showed some catalytic activity for ORR, but the reaction is promoted via the 2 electrons pathways. As for the previous cases the materials formed by Pt supported on WO2/C the reaction follows the 4 electrons steps. When subjected to the acid treatment, as in the case of the catalysts supported on WC/C, the WO2/C-supported materials had higher stability when compared to the commercial Pt/C catalyst.

acid treatment

dióxido de tungstênio

monocarboneto de tungstênio

oxygen reduction reaction

reação de redução de oxigênio

tratamento ácido

tungsten dioxide

tungsten monocarbide