High performance electrocatalytic hydrocarbon thin films containing Pt nano-clusters are deposited by simultaneous plasma polymerization of ethylene and sputtering of a Pt target. The proposed synthetic approach largely simplifies the PEMFC electrocatalyst fabrication process with respect to conventional methods. The deposition of the hydrocarbon matrix provides the mechanical support and electronic continuity, ensuring a uniform metal dispersion, avoiding Pt nanoparticle agglomeration. The Pt catalyst is dispersed as small vertically stacked clusters with size less than 10 nm in columnar thin (250-500 nm) films. PEMFC testing with plasma deposited 500 nm thick film and 0.513 mg cm-2 Pt load as anodic electrocatalyst led to a maximum reproducible power density as high as 300 mW cm-2. © 2010 The Royal Society of Chemistry.
Plasma deposited Pt-containing hydrocarbon thin films as electrocatalysts for PEM fuel cell / Dilonardo, E; Milella, A; Palumbo, F; Thery, J; Martin, S; Barucca, Gianni; Mengucci, Paolo; D'Agostino, R; Fracassi, F.. - In: JOURNAL OF MATERIALS CHEMISTRY. - ISSN 0959-9428. - 20:(2010), pp. 10224-10227.
Plasma deposited Pt-containing hydrocarbon thin films as electrocatalysts for PEM fuel cell.
BARUCCA, Gianni;MENGUCCI, Paolo;
2010-01-01
Abstract
High performance electrocatalytic hydrocarbon thin films containing Pt nano-clusters are deposited by simultaneous plasma polymerization of ethylene and sputtering of a Pt target. The proposed synthetic approach largely simplifies the PEMFC electrocatalyst fabrication process with respect to conventional methods. The deposition of the hydrocarbon matrix provides the mechanical support and electronic continuity, ensuring a uniform metal dispersion, avoiding Pt nanoparticle agglomeration. The Pt catalyst is dispersed as small vertically stacked clusters with size less than 10 nm in columnar thin (250-500 nm) films. PEMFC testing with plasma deposited 500 nm thick film and 0.513 mg cm-2 Pt load as anodic electrocatalyst led to a maximum reproducible power density as high as 300 mW cm-2. © 2010 The Royal Society of Chemistry.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
