Probing intermediate configurations of oxygen evolution catalysis across the light spectrum

IF 49.7 1区材料科学 Q1 ENERGY & FUELS Nature Energy Pub Date : 2024-08-26 DOI:10.1038/s41560-024-01583-x

Jin Suntivich, Geoffroy Hautier, Ismaila Dabo, Ethan J. Crumlin, Dhananjay Kumar, Tanja Cuk

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Abstract

The oxygen evolution reaction is crucial to sustainable electro- and photo-electrochemical approaches to chemical energy production (for example, H₂). Although mechanistic descriptions of the oxygen evolution reaction have been proposed, the frontier challenge is to extract the molecular details of its elementary steps. Here we discuss how advances in spectroscopy and theory are allowing for configurations of reaction intermediates to be elucidated, distinguishing between experimental approaches (static and dynamic) across a range of surface oxygen binding energies on catalysts (from ruthenium to titanium oxides). We outline how interpreting X-ray and optical spectra relies on established and newly implemented computational techniques. A key emphasis is on detecting adsorbed oxygen intermediates at the oxide/water interface by their chemical composition, electronic and vibrational levels and ion–electron kinetic pathways. Integrating the computational advances with the experimental spectra along these lines could ultimately resolve the elementary steps, elucidating how each intermediate leads to another during oxygen evolution reaction.

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跨光谱探测氧进化催化的中间构型

氧进化反应对于以可持续的电化学和光电化学方法生产化学能（如 H2）至关重要。虽然已经提出了氧进化反应的机理描述，但前沿挑战是提取其基本步骤的分子细节。在此，我们将讨论光谱学和理论的进步如何使反应中间产物的构型得以阐明，并区分催化剂（从钌到钛氧化物）表面氧结合能范围内的实验方法（静态和动态）。我们概述了 X 射线和光学光谱的解释如何依赖于已有的和新实施的计算技术。重点是通过化学成分、电子和振动水平以及离子-电子动力学路径来检测氧化物/水界面上吸附的氧中间体。按照这些思路将计算进展与实验光谱相结合，最终可以解决基本步骤问题，阐明在氧进化反应过程中每个中间体如何导致另一个中间体。

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来源期刊

Nature Energy Energy-Energy Engineering and Power Technology

CiteScore

75.10

自引率

1.10%

发文量

193

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