McCarthy Brian D, Beiler Anna M, Johnson Ben A, Liseev Timofey, Castner Ashleigh T, Ott Sascha
Department of Chemistry, Ångström Laboratory, Uppsala University, Box 523, 75120 Uppsala, Sweden.
Coord Chem Rev. 2020 Mar 1;406. doi: 10.1016/j.ccr.2019.213137. Epub 2019 Dec 21.
The electrochemical analysis of molecular catalysts for the conversion of bulk feedstocks into energy-rich clean fuels has seen dramatic advances in the last decade. More recently, increased attention has focused on the characterization of metal-organic frameworks (MOFs) containing well-defined redox and catalytically active sites, with the overall goal to develop structurally stable materials that are industrially relevant for large-scale solar fuel syntheses. Successful electrochemical analysis of such materials draws heavily on well-established homogeneous techniques, yet the nature of solid materials presents additional challenges. In this tutorial-style review, we cover the basics of electrochemical analysis of electroactive MOFs, including considerations of bulk stability, methods of attaching MOFs to electrodes, interpreting fundamental electrochemical data, and finally electrocatalytic kinetic characterization. We conclude with a perspective of some of the prospects and challenges in the field of electrocatalytic MOFs.
在过去十年中,用于将大量原料转化为富含能量的清洁燃料的分子催化剂的电化学分析取得了显著进展。最近,人们越来越关注含有明确氧化还原和催化活性位点的金属有机框架(MOF)的表征,总体目标是开发出结构稳定且与大规模太阳能燃料合成相关的工业材料。对此类材料进行成功的电化学分析在很大程度上依赖于成熟的均相技术,但固体材料的性质带来了额外的挑战。在本教程式综述中,我们涵盖了电活性MOF电化学分析的基础知识,包括本体稳定性的考量、将MOF附着到电极上的方法、解释基本电化学数据,以及最后进行电催化动力学表征。我们以对电催化MOF领域的一些前景和挑战的展望作为结尾。