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COMMUNICATION www.advenergymat.de www.MaterialsViews.com Promoting the Water Oxidation Catalysis by Synergistic Interactions between Ni(OH) and Carbon Nanotubes Lei Wang , Hong Chen , Quentin Daniel , Lele Duan , Bertrand Philippe , Yi Yang , Håkan Rensmo , and Licheng Sun * [ 27,43–46 ] The rapid growth in energy demand, the continuous consump- capsulating the electrocatalysts. Recently, Zhao and co- [ 47 ][ 48,49 ] tion of fossil fuels and the arising environmental concerns are workers and Dai and co-workers anchored Co, Ni–Fe stimulating signifi cant research interests in developing alter- based water splitting catalysts on multiwall carbon nanotubes [ 1 ] native energy systems. Production of hydrogen from electro- (MWCNTs), these approaches not only enhanced the charge lytic water splitting is recognized as one of the most promising transportations but also increased the available catalytic sites. strategies for renewable energy storage, and this strategy may Although the obtained materials exhibit excellent activity toward enable direct utilization of the solar energy when further com- water oxidation, the improvement are not signifi cant compared [ 2–4 ][ 50 ] bined with solar cells. Water splitting consists of two half to the original catalysts. Very recently, Zhao and co-workers reactions: oxygen
Advanced Energy Materials – Wiley
Published: Aug 1, 2016
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