Tian-Jiao Wang, Li-Bo Sun, Xuan Ai, Pei Chen, Yu Chen, Xin Wang
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引用次数: 0
摘要
直接甲酸盐燃料电池(DFFCs)作为未来能源组合和环境可持续发展的前景广阔的技术受到越来越多的关注,因为甲酸盐可以利用二氧化碳制成,而且是碳中性的。本文通过简便的自模板法合成了具有丰富缺陷位点的异质结构铂钯合金和氧化物纳米线(铂钯氧化物纳米线),并在甲酸电氧化反应(FOR)中表现出了高活性。合金与氧化物异质结产生的电子调谐影响了铂钯氧化物纳米线的功函数。具有最佳功函数的样品揭示了对中间产物的有利吸附行为,以及铂位点与甲酸氧之间在 d-p 轨道杂化上的强相互作用,有利于以较低的能垒直接进入甲酸电氧化反应途径。除了热力学调节外,由于相邻活性位点上吸收的氢和一氧化碳的结合能力,异质结构还能提供足够的羟基物种来促进二氧化碳的形成,这有助于改善 PtPd-ox NW 上的 FOR 动力学。因此,异质结构 PtPd-ox NW 实现了 FOR 热力学和动力学的双重调控,表现出卓越的性能,在实用系统中展现出巨大的潜力。
Boosting Formate Electrooxidation by Heterostructured PtPd Alloy and Oxides Nanowires
Direct formate fuel cells (DFFCs) receive increasing attention as promising technologies for the future energy mix and environmental sustainability, as formate can be made from carbon dioxide utilization and is carbon neutral. Herein, heterostructured platinum-palladium alloy and oxides nanowires (PtPd-ox NWs) with abundant defect sites are synthesized through a facile self-template method and demonstrated high activity toward formate electrooxidation reaction (FOR). The electronic tuning arising from the heterojunction between alloy and oxides influence the work function of PtPd-ox NWs. The sample with optimal work function reveals the favorable adsorption behavior for intermediates and strong interaction in the d−p orbital hybridization between Pt site and oxygen in formate, favoring the FOR direct pathway with a low energy barrier. Besides the thermodynamic regulation, the heterostructure can also provide sufficient hydroxyl species to facilitate the formation of carbon dioxide due to the ability of combining absorbed hydrogen and carbon monoxide at adjacent active sites, which contributes to the improvement of FOR kinetics on PtPd-ox NWs. Thus, heterostructured PtPd-ox NWs achieve dual regulation of FOR thermodynamics and kinetics, exhibiting remarkable performance and demonstrating potential in practical systems.
期刊介绍:
Advanced Materials, one of the world's most prestigious journals and the foundation of the Advanced portfolio, is the home of choice for best-in-class materials science for more than 30 years. Following this fast-growing and interdisciplinary field, we are considering and publishing the most important discoveries on any and all materials from materials scientists, chemists, physicists, engineers as well as health and life scientists and bringing you the latest results and trends in modern materials-related research every week.