Effects of Ionomer Morphology on Oxygen Reduction on Pt

Chlistunoff, Jerzy; Pivovar, Bryan S.

doi:10.1149/2.0661508jes

Cited by 22 publications

(23 citation statements)

References 75 publications

(157 reference statements)

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“…The preferred orientation of Nafion® molecules in contact with an oxidized Pt is that with its hydrophilic component facing the hydrophilic oxidized surface. In presence of liquid water (electrolyte), Nafion® maintains an open morphology [36] at its interface with bare Pt surfaces, even if its hydrophobic component previously occupied that interface in absence of liquid water [67]. Moreover, as oxygen was not eliminated during the preparation of the Pt catalyst inks, the surface of Pt particles was at last partially oxidized and thus strongly hydrophilic.…”

Section: Discussionmentioning

confidence: 99%

“…A scan rate of 100 mV s −1 was used in the ECSA, whereas a 10 mV s − 1 scan rate was applied in the kinetic studies. Slow scan rates may enable a potential/Pt surface driven restructuring [67] and possibly also promote Nafion® desorption and formation of small ionomer aggregates. The lack of a similar effect for Pt4.8G may be associated with the stronger interaction of its more graphitic surface with the hydrophobic Nafion® backbone.…”

Section: The Effect Of Nafion® On Orr Catalyzed By Carbon Supported Pmentioning

confidence: 99%

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On the use of Nafion® in electrochemical studies of carbon supported oxygen reduction catalysts in aqueous media

Chlistunoff

Sansiñena

2016

Journal of Electroanalytical Chemistry

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The paper presents the results of a voltammetric and rotating ring disk electrode (RRDE) study of oxygen reduction reaction (ORR) catalyzed by Fe and Co porphyrins and phthalocyanines adsorbed on a high surface area carbon (Vulcan XC72) and by carbon supported Pt catalysts in presence of various quantities of Nafion®. The results demonstrate that the hydrophobic backbone of Nafion® self assembles on nanoparticles of common carbon supports of ORR catalysts. The phenomenon is promoted by the attractive interactions of the backbone with the graphitic surfaces of carbon particles. It leads to a significant ORR inhibition as a result of the spillover of the hydrophobic Nafion® component onto the catalyst particles. The extent of the inhibition depends on the type and the amount of the catalyst on the carbon surface and the degree of carbon surface graphitization. The activity of the transition metal macrocycles is suppressed by up to two orders of magnitude, whereas that of low Pt loading (4.8%) catalysts by less than one order of magnitude. The results demonstrate a great risk of incorrect catalyst activity determinations when using even very small Nafion® quantities as the catalyst ink dispersing agent.

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Section: Discussionmentioning

confidence: 99%

Section: The Effect Of Nafion® On Orr Catalyzed By Carbon Supported Pmentioning

confidence: 99%

On the use of Nafion® in electrochemical studies of carbon supported oxygen reduction catalysts in aqueous media

Chlistunoff

Sansiñena

2016

Journal of Electroanalytical Chemistry

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“…The interface between the Nafion and the metal has received great attention due to the strong irreversible sulfonate anions adsorption on the Pt. 12,[14][15][16] The degree of sensitivity to the anions highly depends on the Pt facets.12 For example, the facet Pt(111) has been reported to be most sensitive to the anion adsorption. 17,18 To accommodate operation of PEMFC under low humidity conditions, high ionomer to carbon ratios have been adopted to ensure sufficient proton transport, 19 but the excessive sulfonic groups might reduce the catalyst performance.…”

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confidence: 99%

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confidence: 99%

Enhancing Pt/C Catalysts for the Oxygen Reduction Reaction with Protic Ionic Liquids: The Effect of Anion Structure

Huang¹,

Song

Morales‐Collazo

et al. 2017

J. Electrochem. Soc.

139

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Protic ionic liquids (ILs) have been recently studied as a potential approach to enhance oxygen reduction reaction (ORR) activity of carbon supported platinum catalysts (Pt/C) for application in polymer electrolyte membrane fuel cells. The high oxygen solubility in the ILs was suggested as one of the main reasons for the accelerated reaction rates. Because the nature of the anion of the IL has been associated with increased oxygen solubility, in this work we survey a number of ionic liquids with various anions to study this effect. While the search for direct correlation between the ORR activities and the oxygen solubilities does not produce any conclusive results, by contrast, the specific activity showed dependence on the availability of oxygenated species free Pt sites. This finding indicates that the inhibition of Pt oxidation and less adsorption of non-reactive species may also play an important role in the enhanced ORR activity. Moreover, the degree of IL coverage on the Pt surface was estimated using (bi)sulfate ions as an indicator. The surface coverage not only affected the ORR activity, but also the Pt dissolution process. This suggests that an optimal balance between activity and stability can be achieved on a partially covered Pt surface. The oxygen reduction reaction (ORR) that occurs on the cathode poses a major hurdle for the efficient utilization of polymer electrolyte fuel cells (PEMFC). Extensive studies have focused on developing novel catalysts to improve the efficiency of this reaction.1,2 The ORR involves multiple steps, among which O 2 + H + + e − ↔ OOH ads and OH ads + H + + e − ↔ H 2 O act as the potential rate determining steps. Simultaneously optimizing the Gibbs free energies for both steps to completely eliminate the overpotential is very challenging, and a ∼350 mV overpotenial is commonly observed, which is independent of the identity of the catalyst.3,4 The large overpotential has been generally attributed to the sluggish kinetics of the ORR and adsorption of oxygenated species (e.g. OH ad ) or other anions. 5 The coverage of the adsorbed oxygenated species (θ OH ad ) is unfavorable for the reaction, and the availability of the free metal surface (as expressed by the (1-θ OH ad ) term) is one of the governing factors for the ORR activity.6,7 As a result, much effort has been dedicated to weakening the bonding of OH to the catalyst surface either by shifting the d-band center of Pt 8,9 or by lateral repulsion from the supports (e.g. metal oxides). 10,11Anion adsorption on Pt also affects the ORR activity, and it is agreed that the occupation of active sites deactivates the sites and reduces the activity.12 In real-world membrane-electrode assembly (MEA), the Nafion membrane and ionomer, constituted by a Teflon-like backbone and an anionic cluster of sulfonic groups, 13 are widely employed as indispensable components. The interface between the Nafion and the metal has received great attention due to the strong irreversible sulfonate anions adsorption on the Pt. 12,[14][15][16] The de...

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“…In the case of catalyst layers, microelectrodes act as a model analogue, allowing for the study of HOR and ORR in a more controlled and defined environment and architecture than in a typical fuel cell (2,4). Many studies have used microelectrodes to study Nafion and these electrochemical reactions, covering a wide range of topics, but most have focused on ORR (1,2,4,5). Some researchers studied the mass-transport characteristics of oxygen gas in Nafion or the platinum/ionomer interface (1,5,6), whereas others focused on the kinetics of the reaction itself on the electrode (4,7,8).…”

Section: Introductionmentioning

confidence: 99%

Mass-Transport Resistances of Acid and Alkaline Ionomer Layers: A Microelectrode Study Part 1 - Microelectrode Development

et al. 2019

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The use of microelectrodes to study localized mass-transport phenomena in fuel-cell catalyst layers is an increasingly valuable tool. However, existing microelectrode cells have been used in static, equilibrated environment modes with poorly controlled interfaces. In this work, we present a microelectrode cell design that expands the experimental space addressable by microelectrodes to include mechanical pressure, gas flow and ionomer medium, and experimental throughput. The feasibility of the design is examined for fuel-cell reactions, with oxygen reduction currents independent of mechanical pressure and gas flowrate. Finally, cell equilibration time and IR drop across the electrolyte are estimated. The new cell design is robust and provides a consistent base from which to perform more complicated studies examining mass-transport properties of ionomers and/or the electrochemical reaction kinetics of hydrogen oxidation and oxygen reduction.

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Effects of Ionomer Morphology on Oxygen Reduction on Pt

Cited by 22 publications

References 75 publications

On the use of Nafion® in electrochemical studies of carbon supported oxygen reduction catalysts in aqueous media

On the use of Nafion® in electrochemical studies of carbon supported oxygen reduction catalysts in aqueous media

Enhancing Pt/C Catalysts for the Oxygen Reduction Reaction with Protic Ionic Liquids: The Effect of Anion Structure

Mass-Transport Resistances of Acid and Alkaline Ionomer Layers: A Microelectrode Study Part 1 - Microelectrode Development

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