Authors
Wei-shan LI , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China; Follow Li-peng TIAN , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China; Jun-hua DU , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China; Hong-liang HUANG , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China; Wei LI , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China; Li-xia ZHANG , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China; Hong-yan YANG , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China; Pan-pan GUO , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China; Zhi-hui ZHOU , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China; Xing-de XIANG , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China; Zhao FU , School of Chemistry and Environment & Key Lab of Electrochemical Technology onEnergy Storage and Power Generation in Guangdong Universities,Guangzhou 510006,China;
Corresponding Author
Wei-shan LI(liwsh@scnu.edu.cn)
Abstract
There are several problems that limit the application of direct small organic fuel cell,including the use of precious platinum and the activity loss of platinum due to the intermediates poisons from the oxidation of small organic molecules.These problems have attracted wide interest and many solutions have been proposed.We have developed a new method to reduce the platinum usage and improve its activity,based on the modification of platinum with hydrogen molybdenum/tungsten bronze(HxMo(W)O3 ) was reviewed.
Keywords
hydrogen molybdenum bronze, hydrogen tungsten bronze, platinum, modification, fuel cell, small organic, electrocatalyst
Publication Date
2009-11-28
Online Available Date
2009-11-28
Recommended Citation
Wei-shan LI, Li-peng TIAN, Jun-hua DU, Hong-liang HUANG, Wei LI, Li-xia ZHANG, Hong-yan YANG, Pan-pan GUO, Zhi-hui ZHOU, Xing-de XIANG, Zhao FU.
Platinum Modified with Hydrogen Molybdenum/Tungsten Bronze as Electrocatalysts for Direct Small Organic Molecule Fuel Cell[J]. Journal of Electrochemistry ,
2009,
15(4): 418-425.
https://jelectrochem.xmu.edu.cn/journal/vol15/iss4/10
Since February 14, 2023
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