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Beilstein J. Nanotechnol. 2014, 5, 44–67, doi:10.3762/bjnano.5.5
Figure 1: Simplified representation of suggested degradation mechanisms for platinum particles on a carbon su...
Figure 2: A) ORR cyclic voltammograms of Pt@HGS 1–2 nm in 0.1 M HClO4 saturated with Ar (black) and with oxyg...
Figure 3: Electrochemical oxidation of a carbon monoxide monolayer (CO-stripping curves) after 0, 360, 1080, ...
Figure 4: IL-SEM of Pt/Vulcan 3–4 nm (green), Pt@HGS 1–2 nm (blue) and Pt@HGS 3–4 nm (red) after 0 (top) and ...
Figure 5: Identical location dark field IL-STEM of Pt/Vulcan 3–4 nm (green), Pt@HGS 1–2 nm (blue) and Pt@HGS ...
Figure 6: IL-TEM micrographs of Pt/Vulcan 3–4 nm after 0 and after 3600 potential cycles between 0.4 and 1.4 V...
Figure 7: IL-TEM micrographs of the Pt/Vulcan 3–4 nm catalyst before and after 5000 potential cycles between ...
Figure 8: IL-TEM micrographs of the Pt@HGS 3–4 nm catalyst before and after 5000 potential cycles between 0.4...
Figure 9: IL-TEM micrographs from degradation studies on four Pt/C fuel cell catalysts. Pt/C 5 nm (A,B) and P...
Figure 10: IL-TEM micrograph of Pt/C 5 nm subjected to 1.3 VRHE at 348 K (75 °C) for 16 h in 0.1 M HClO4. A sh...
Figure 11: A) Dependence of the AID on platinum content for various platinum particle sizes, calculated for a ...
Figure 12: Impact of catalyst particle size and post-synthesis heat treatment on the normalized platinum surfa...