▎ 摘 要
One-pot method is used to synthesize Pt (Pd)/ZnO/graphene composite (simplified as Pt (Pd)/ZnO/GNs). Under hydrothermal conditions, weak basic Zn2+ ions (pH = 9.0) is converted to ZnO, accompanying synchronous reduction of K2PtCl4 (K2PdCl4) and graphene oxide (GO) without additional reducing agent. ZnO deposited on the surface of graphene nanosheets (GNs) offers homogeneous nuclei to anchor metal particles, leading to the uniform dispersion of Pt (Pd) particles, with average diameter of 3.0 nm for Pt and 5.5 nm for Pd. Electrochemical experiments show that Pt/ZnO/GNs and Pd/ZnO/GNs have much higher catalytic activity and stability for methanol oxidation reaction (MOR) and improved tolerance of CO compared with commercially available Johnson Matthey 20% Pt/C catalyst (Pt/C-JM) and Sigma-Aldrich 20% Pd/C catalyst (Pd/C-SA). Under light irradiation, catalytic activities of Pt (Pd)/ZnO/GNs are drastically enhanced, with the mass activities of 1724.2 mA mg(-1) (UV irradiation) & 1935.5 mA mg(-1) (visible irradiation) for Pt/ZnO/GNs, and 733.5 mA mg(-1) (UV irradiation) & 818.3 mA mg(-1) (visible irradiation) for Pd/ZnO/GNs. The improved performance mainly derives from the synergistic effects between the electrocatalysis of well dispersed Pt (Pd) nanoparticles and photo-catalysis of ZnO. And the band gap narrowing of ZnO in Pt (Pd)/ZnO/GNs contributes to the enhanced synergistic catalysis effects under visible light irradiation, which provides new opportunities for exploiting efficient visible light assisted electrocatalytic methanol oxidation reaction. (C) 2015 Elsevier Ltd. All rights reserved.