Selective catalysts for the hydrogen oxidation and oxygen reduction reactions by patterning of platinum with calix[4]arene molecules

Selective catalysts for the hydrogen oxidation and oxygen reduction reactions by patterning of platinum with calix[4]arene molecules

The design of new catalysts for polymer electrolyte membrane fuel cells must be guided by two equally important fundamental principles: optimization of their catalytic behaviour as well as the long-term stability of the metal catalysts and supports in hostile electrochemical environments. The method...

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Bibliographic Details
Published in:Nature materials Vol. 9; no. 12; pp. 998 - 1003
Main Authors: Marković, Nenad M, Genorio, Bostjan, Strmcnik, Dusan, Subbaraman, Ram, Tripkovic, Dusan, Karapetrov, Goran, Stamenkovic, Vojislav R, Pejovnik, Stane
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-12-2010
Nature Publishing Group
Subjects:
639/301/299/893
639/301/357
639/301/923/966
Alloy plating
Alloying
Anodes
Biomaterials
Carbon
Catalysis
Catalysts
Catalytic oxidation
Chemical reactions
Chemistry and Materials Science
Condensed Matter Physics
Electrochemistry
Fuel cells
Fuel technology
Hydrogen
letter
Materials Science
Molecular chemistry
Nanotechnology
Optical and Electronic Materials
Oxidation
Oxygen
Platinum
Polymers
Stability
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Summary:The design of new catalysts for polymer electrolyte membrane fuel cells must be guided by two equally important fundamental principles: optimization of their catalytic behaviour as well as the long-term stability of the metal catalysts and supports in hostile electrochemical environments. The methods used to improve catalytic activity are diverse, ranging from the alloying and de-alloying of platinum to the synthesis of platinum core–shell catalysts. However, methods to improve the stability of the carbon supports and catalyst nanoparticles are limited, especially during shutdown (when hydrogen is purged from the anode by air) and startup (when air is purged from the anode by hydrogen) conditions when the cathode potential can be pushed up to 1.5 V (ref. 11). Under the latter conditions, stability of the cathode materials is strongly affected (carbon oxidation reaction) by the undesired oxygen reduction reaction (ORR) on the anode side. This emphasizes the importance of designing selective anode catalysts that can efficiently suppress the ORR while fully preserving the Pt-like activity for the hydrogen oxidation reaction. Here, we demonstrate that chemically modified platinum with a self-assembled monolayer of calix[4]arene molecules meets this challenging requirement.
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ISSN:1476-1122
1476-4660
DOI:10.1038/nmat2883