Enhanced electrocatalysis of the oxygen reduction reaction based on patterning of platinum surfaces
Author: ["Dusan Strmcnik","María Escudero-Escribano","Kensaku Kodama","Vojislav R. Stamenkovic","Angel Cuesta","Nenad M. Marković"]
Publication: Nature Chemistry
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Abstract
The slow rate of the oxygen reduction reaction in the phosphoric acid fuel cell is the main factor limiting its wide application. Here, we present an approach that can be used for the rational design of cathode catalysts with potential use in phosphoric acid fuel cells, or in any environments containing strongly adsorbing tetrahedral anions. This approach is based on molecular patterning of platinum surfaces with cyanide adsorbates that can efficiently block the sites for adsorption of spectator anions while the oxygen reduction reaction proceeds unhindered. We also demonstrate that, depending on the supporting electrolyte anions and cations, on the same CN-covered Pt(111) surface, the oxygen reduction reaction activities can range from a 25-fold increase to a 50-fold decrease. This behaviour is discussed in the light of the role of covalent and non-covalent interactions in controlling the ensemble of platinum active sites required for high turn over rates of the oxygen reduction reaction. The phosphoric acid fuel cell is limited by its slow rate of oxygen reduction at the cathode, but now an approach to the rational design of improved catalysts for this process has been developed. Molecular patterning of platinum surfaces with cyanide adsorbates is used to block the adsorption of spectator anions without hindering oxygen reduction, thus improving catalytic activity.
Cite this article
Strmcnik, D., Escudero-Escribano, M., Kodama, K. et al. Enhanced electrocatalysis of the oxygen reduction reaction based on patterning of platinum surfaces with cyanide. Nature Chem 2, 880–885 (2010). https://doi.org/10.1038/nchem.771
