Pt single crystal surfaces in electrochemistry and electrocatalysis

EES catalysis Pub Date : 2023-11-20 DOI:10.1039/D3EY00260H
Juan M. Feliu and Enrique Herrero
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Abstract

In this review, recent advances in the use of platinum single-crystal surfaces in electrochemistry are addressed. The starting point is the voltammetric characterization in a supporting electrolyte because the profile can be used as a fingerprint of the surface, allowing the surface quality and solution cleanliness to be established. The signals appearing in these voltammograms have been assigned to the adsorption of H, OH, and the anions in the supporting electrolyte. Then, the distinctive behavior of the Pt(111) electrode regarding the adsorption of species and the electrocatalysis in comparison with the other single-crystal surfaces is discussed. For the H/OH adsorption, the (111) ordered domain is the only one in which both processes appear in different potential windows. For the remaining ordered domains, steps, and kinks, both processes overlap, giving rise to signals that correspond to the competitive adsorption/desorption of OH and H. This fact implies that OH may be adsorbed on the surface at potentials as low as 0.15 V, which is a paradigm shift in the up-to-now prevailing understanding of the electrochemical behavior of platinum electrodes and has important implications for the elucidation of the mechanism of electrocatalytic reactions. The effects of this new knowledge on the proposed reaction mechanisms for the oxidation of CO and small organic molecules and the reduction of oxygen and hydrogen peroxide are discussed in detail. Since the elucidation of the reaction mechanisms requires in many cases the use of computational modeling, the conditions that the models should fulfill to reach valid conclusions are discussed. Relevant examples, which highlight the importance of the local structure of the interphase in the electrochemical behavior are given.

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电化学和电催化中的铂单晶表面
本文综述了近年来铂单晶表面在电化学领域的应用进展。首先是在支撑电解质中进行伏安表征,因为伏安表征可以作为表面的指纹,从而确定表面质量和溶液清洁度。在这些伏安图中出现的信号被分配到H, OH和阴离子在支持电解质中的吸附。然后,讨论了Pt(111)电极与其他单晶表面相比在吸附物质和电催化方面的独特行为。对于H/OH吸附,(111)有序结构域是唯一两个过程出现在不同势窗的结构域。对于其余的有序结构域、步骤和结,两个过程重叠,产生对应OH和h的竞争性吸附/解吸的信号。这一事实意味着OH可能在低至0.15 V的电位下被吸附在表面,这是目前对铂电极电化学行为的普遍理解的范式转变,对阐明电催化反应的机制具有重要意义。详细讨论了这一新知识对CO和小有机分子氧化反应机制以及氧和过氧化氢还原的影响。由于阐明反应机理在许多情况下需要使用计算模型,因此讨论了模型应满足的条件才能得出有效的结论。举例说明了界面局部结构在电化学行为中的重要性。
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Back cover Correction: High photocatalytic yield in the non-oxidative coupling of methane using a Pd–TiO2 nanomembrane gas flow-through reactor Embedding the intermetallic Pt5Ce alloy in mesopores through Pt–C coordination layer interactions as a stable electrocatalyst for the oxygen reduction reaction† Efficient CO2-to-CO conversion in dye-sensitized photocatalytic systems enabled by electrostatically-driven catalyst binding† Green energy driven methane conversion under mild conditions
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