Step bunching instability and its effects in electrocatalysis on platinum surfaces

IF 42.8 1区 化学 Q1 CHEMISTRY, PHYSICAL
Francesc Valls Mascaró, Marc T. M. Koper, Marcel J. Rost
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Abstract

The atomic-scale surface structure plays a major role in the electrochemical behaviour of a catalyst. The electrocatalytic activity towards many relevant reactions, such as the oxygen reduction reaction on platinum, exhibits a linear dependency with the number of steps until this linear scaling breaks down at high step densities. Here we show, using Pt(111)-vicinal surfaces and in situ electrochemical scanning tunnelling microscopy, that this anomalous behaviour at high step densities has a structural origin and is attributed to the bunching of closely spaced steps. While Pt(554) presents parallel single steps and terrace widths that correspond to its nominal, expected value, most steps on Pt(553) are bunched. Our findings challenge the common assumption in electrochemistry that all stepped surfaces are composed of homogeneously spaced steps of monoatomic height and can successfully explain the anomalous trends documented in the literature linking step density to both activity and potential of zero total charge. The electrocatalytic activity of metal catalysts commonly exhibits a positive linear correlation with the presence of steps, but this dependency breaks down for Pt catalysts with high step densities. Now, using in situ electrochemical scanning tunnelling microscopy, it is shown that this is due to the bunching of closely spaced steps, forming double and triple steps.

Abstract Image

Abstract Image

铂表面阶跃束化不稳定性及其对电催化的影响
原子尺度的表面结构对催化剂的电化学行为起着重要作用。许多相关反应(如铂上的氧还原反应)的电催化活性与阶跃数呈线性关系,直到高阶跃密度时这种线性比例关系才会打破。在这里,我们利用铂(111)的二维表面和原位电化学扫描隧道显微镜来证明,这种在高阶次密度下的反常行为是由结构引起的,并归因于紧密间隔的阶次串联。铂(554)呈现平行的单一阶梯,阶梯宽度符合其标称的预期值,而铂(553)上的大多数阶梯是成串的。我们的发现挑战了电化学中所有阶梯表面都是由单原子高度的均匀间隔阶梯组成的普遍假设,并能成功解释文献中记载的将阶梯密度与活性和零总电荷电位联系起来的异常趋势。
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来源期刊
Nature Catalysis
Nature Catalysis Chemical Engineering-Bioengineering
CiteScore
52.10
自引率
1.10%
发文量
140
期刊介绍: Nature Catalysis serves as a platform for researchers across chemistry and related fields, focusing on homogeneous catalysis, heterogeneous catalysis, and biocatalysts, encompassing both fundamental and applied studies. With a particular emphasis on advancing sustainable industries and processes, the journal provides comprehensive coverage of catalysis research, appealing to scientists, engineers, and researchers in academia and industry. Maintaining the high standards of the Nature brand, Nature Catalysis boasts a dedicated team of professional editors, rigorous peer-review processes, and swift publication times, ensuring editorial independence and quality. The journal publishes work spanning heterogeneous catalysis, homogeneous catalysis, and biocatalysis, covering areas such as catalytic synthesis, mechanisms, characterization, computational studies, nanoparticle catalysis, electrocatalysis, photocatalysis, environmental catalysis, asymmetric catalysis, and various forms of organocatalysis.
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