光电化学
催化作用
格式化
电化学
氧化还原
光电解
化学
甘油
分解水
化学工程
矿化(土壤科学)
价(化学)
析氧
电化学能量转换
能量转换
太阳能
材料科学
无机化学
氧气
光电化学电池
纳米技术
电解水
价带
燃料电池
催化氧化
太阳能转换
能量转换效率
多相催化
钌
能源
作者
Ádám Balog,Eva Ng,Gergely F. Samu,Egon Kecsenovity,A. Csík,Sixto Giménez,Csaba Janáky
摘要
ABSTRACT Photoelectrochemistry is a promising method for the direct conversion of sunlight into valuable chemicals by combining the functions of solar panels and electrolyzers in one technology. In most studies, semiconductor/catalyst photoelectrode assemblies are used to achieve reasonable efficiencies. At the same time, unlike in dark electrochemical processes, the role of the catalyst is not straightforward in photoelectrochemistry, where the onset potential of the redox process should be mostly determined by the flatband potential of the semiconductor. In addition, the energy of holes (i.e., the surface potential) is independent of the applied bias; it is defined by the valence band (VB) position. In this study, we compared PdAu, Au, and Ni on Si photoanodes in the photoelectrochemical (PEC) oxidation of glycerol at record high current densities (> 180 mA cm ‒2 ), coupled to H 2 evolution at the cathode. We successfully decreased the energy requirement (i.e., the cell voltage) of the paired conversion of glycerol and water by 0.7 V by exchanging the widely studied Ni catalyst with PdAu. The catalyst choice also dictates the product distribution, resulting mainly in C3 products on PdAu, glycolate (C2 product) on Au, and formate (C1 product) on Ni, without complete mineralization of glycerol (CO 2 formation) that is difficult to rule out in dark electrochemical processes (as demonstrated by comparative measurements). Finally, we achieved a bias‐free (standalone) operation with PdAu/Si and Au/Si photoanodes by combining the PEC oxidation of glycerol with oxygen reduction reaction (ORR).
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