摘要
采用涂覆热分解法制备不同成分的Ti/IrO2+MnO2电极,利用恒电位循环伏安法研究Ti/IrO2-MnO2电极在硫酸溶液中的电化学表面行为,并用直线外推法定量地评价电极的电化学活性表面积。结果表明,Ti/(0.7)IrO2+(0.3)MnO2的伏安电荷达到最高,为电化学活性表面积最大;随着电位扫描速率增大,伏安电流密度不断增加,而伏安电荷容量逐渐减少,直到维持恒定;所有Ti/IrO2+MnO2电极的"内部"电化学活性表面积远大于"外部"电化学活性表面积,约为"外部"电化学活性表面积的2倍,说明电极内部存在丰富的多孔结构,真实表面积巨大,因此Ir4+/Ir3+转化反应多发生于内电化学活性表面区域。
Ti/IrO2+MnO2 coated electrodes with different compositions were prepared by the thermal decomposition method. The electrochemical surface of Ti/IrO2+MnO2 electrodes were studied by potentiostatic cyclic voltammetry in sulfuric acid solution, and the electrochemical active surface area of electrodes were evaluated quantitatively by a linear extrapolation. The results show that the voltammetric charge of Ti/(0.7)IrO2+(0.3)MnO2 is the highest, along with the largest electrochemical active surface area.With the increase of the potential scanning speed, the voltammetric current density increases continuously, while the voltammetric charge decreases gradually until a constant value is reached. For all the Ti/IrO2+MnO2 electrodes, the "inner" electrochemical active surface area is much larger than the "outer" electrochemical active surface area, by about two times. It means that there are a lot of micropores inside the electrodes with a very large real surface area, thus the Ir4+/Ir3+valence state transition occurs at the "inner" electrochemical active surface.
作者
周键
关文学
王三反
张学敏
ZHOU Jian;GUAN Wenxue;WANG Sanfan;ZHANG Xueming(College of Environmental and Municipal Engineering,Lanzhou Jiaotong University,Lanzhou 730070,Gansu,China;Ministry of Education Engineering Research Center of Water Resource Comprehensive Utilization in Cold and AridRegions,Lanzhou 730070,Gansu,China)
出处
《化工进展》
EI
CAS
CSCD
北大核心
2019年第8期3782-3787,共6页
Chemical Industry and Engineering Progress
基金
国家自然科学基金(51804150)
甘肃省青年科技基金计划(17JR5RA088)
国家科技支撑计划(2015BAE04B01)
兰州交通大学“天佑青年托举人才计划”基金
