UHV, Electrochemical NMR, and Electrochemical Studies of Platinum/Ruthenium Fuel Cell Catalysts

Lu, Chao; Rice, Cynthia A.; Masel, Richard I.; Babu, P.; Waszczuk, P.; Kim, H. S.; Oldfield, Eric; Wiȩckowski, Andrzej

doi:10.1021/jp020169u

Cited by 195 publications

(155 citation statements)

References 26 publications

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“…This phenomenon has already been observed by cyclic voltammetry at Ru-modified electrodes for both Pt (hkl) electrodes [19±23] and non-supported Pt nanoparticles [12,25,26]. In addition, using spectroscopic methods such as IR reflectance spectroscopy [19,20,27] or solid state NMR spectroscopy [12,28], two types of CO species have been identified on the electrode surface. It is therefore very likely that CO surface mobility is related to the kinetics of CO and methanol oxidation at PtRu electrodes.…”

Section: Introductionmentioning

confidence: 56%

Electrooxidation of Carbon Monoxide at Ruthenium–Modified Platinum Nano‐particles: Evidence for CO Surface Mobility

et al. 2002

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Ru‐modified Pt nanoparticle surfaces were prepared using Ru electrochemical or spontaneous deposition on commercial‐grade carbon‐supported Pt nanoparticles (Pt‐Vulcan XC72, E‐TEK). Evidence for CO mobility was provided by cyclic voltammetry and FTIR reflectance spectroscopy experiments in weakly specifically adsorbing electrolyte such as 0.1 M HClO4. Since the diffusion of CO is slow, a “two peak” voltammetric behavior was observed for 0 < θRu < 10%. A further increase in Ru coverage leads to the observation of only one CO oxidation peak at a potential ca. 150 mV less positive. FTIR reflectance spectra recorded on Ru‐modified Pt nanoparticles show a band located around 2000–2020 cm–1, which is attributed to adsorbed CO on Ru sites. Exchange between CO species adsorbed on Ru and Pt sites was also observed along with a complete oxidation of a pre‐adsorbed CO monolayer at a potential relevant for DMFC applications. These results confirm that the formation of a PtRu alloy is not a pre‐requisite for obtaining CO‐tolerant electrocatalysts.

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Section: Introductionmentioning

confidence: 56%

Electrooxidation of Carbon Monoxide at Ruthenium–Modified Platinum Nano‐particles: Evidence for CO Surface Mobility

et al. 2002

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“…A catalytic effect can also be explained by the ligand effect where the metal M atoms close to Pt are expected to influence the density of electronic states of Pt, leading to the weakening of the Pt-CO bond. [36][37][38][39] The present work focuses on ethanol oxidation on Pt alloy catalysts (Pt-Sn and Pt-Sn-W) prepared by an arc-melting furnace process. Chronoamperometric measurements were performed with each catalyst in order to compare their electroactivities to that of Pt alone.…”

Section: Introductionmentioning

confidence: 99%

Ethanol electrooxidation on Pt-Sn and Pt-Sn-W bulk alloys

Anjos¹,

Hahn²,

Léger³

et al. 2008

J. Braz. Chem. Soc.

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A oxidação de etanol foi estudada sobre eletrodos Pt-Sn e Pt-Sn-W preparados em forno a arco elétrico. Diferentes técnicas eletroquímicas, tais como voltametria cíclica e cronoamperometria foram utilizadas para avaliar a atividade catalítica desses materiais. O processo de eletro-oxidação também foi investigado in situ por espectroscopia de reflectância na região do infravermelho para determinar intermediários adsorvidos e produtos da reação. Os resultados experimentais indicaram que as ligas Pt-Sn e Pt-Sn-W são capaz de oxidar etanol principalmente para acetaldeído e ácido acético. CO adsorvido também foi detectado, demonstrando a viabilidade do rompimento da ligação C-C na molécula de etanol durante o processo de oxidação. Adicionalmente, o CO adsorvido foi oxidado a CO 2 . Esse produto de reação foi claramente detectado por SNIFTIRS. O catalisador Pt-Sn-W mostrou um melhor desempenho eletroquímico em relação ao Pt-Sn e este, por sua vez, é melhor do que Pt pura.Ethanol oxidation has been studied on Pt-Sn and Pt-Sn-W electrodes prepared in an arc-melting furnace. Different electrochemical techniques like cyclic voltammetry and chronoamperometry were used to evaluate the catalytic activity of these materials. The electro-oxidation process was also investigated by in situ infrared reflectance spectroscopy in order to determine adsorbed intermediates and reaction products. Experimental results indicated that Pt-Sn and Pt-Sn-W alloys are able to oxidize ethanol mainly to acetaldehyde and acetic acid. Adsorbed CO was also detected, demonstrating the viability of splitting the C-C bond in the ethanol molecule during the oxidation process. The adsorbed CO was further oxidized to CO 2 .This reaction product was clearly detected by SNIFTIRS. Pt-Sn-W catalyst showed a better electrochemical performance than Pt-Sn that, in it turn, is better than Pt-alone.Keywords: ethanol oxidation, direct ethanol fuel cell, platinum-tin, platinum-tin-tungsten, in situ Infrared Reflectance Spectroscopy IntroductionEthanol is a molecule of considerable interest because of its importance and potential use as renewable fuel (can be obtained from sugar cane for example) for fuel cells applications.1-4 Among the various alcohols which can be used as alternative fuel, ethanol is the most promising one because it is a safer molecule comparatively to methanol. As a liquid, it is easy to store and handle when comparing to hydrogen. Moreover, ethanol has a high theoretical energy (8 kWh kg -1 against 6.1 kWh kg -1 for methanol and 33 kWh kg -1 for pure hydrogen without storage). 5,6 Ethanol main disadvantage comes from its molecular structure with a carbon containing a primary alcohol function and a methyl group. This characteristic induces a hard conversion of ethanol into carbon dioxide due to the difficult to break the C-C bond and promote the complete oxidation of the methyl group with Pt as electrocatalyst. [7][8][9] Several studies on the ethanol electrooxidation focused mainly to identify adsorbed intermediates showed the presence of carbo...

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“…High-surface area PtRu alloy supported on carbon black is one of the most promising materials as an anode catalyst for DMFC , because of its high tolerance against carbon monoxide poisoning. The promotion effect of Ru has been mainly discussed based on the so-called "bifunctional mechanism" [4][5][6] or "ligand effect" [37][38][39][40][41][42][43][44][45][46][47][48][49][50][51] or a mixture of both.…”

Section: Introductionmentioning

confidence: 99%

Particle growth behavior of carbon-supported Pt, Ru, PtRu catalysts prepared by an impregnation reductive-pyrolysis method for direct methanol fuel cell anodes

Kawaguchi

Sugimoto

Murakami

et al. 2005

Journal of Catalysis

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UHV, Electrochemical NMR, and Electrochemical Studies of Platinum/Ruthenium Fuel Cell Catalysts

Cited by 195 publications

References 26 publications

Electrooxidation of Carbon Monoxide at Ruthenium–Modified Platinum Nano‐particles: Evidence for CO Surface Mobility

Electrooxidation of Carbon Monoxide at Ruthenium–Modified Platinum Nano‐particles: Evidence for CO Surface Mobility

Ethanol electrooxidation on Pt-Sn and Pt-Sn-W bulk alloys

Particle growth behavior of carbon-supported Pt, Ru, PtRu catalysts prepared by an impregnation reductive-pyrolysis method for direct methanol fuel cell anodes

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