纳米结构电极作为活性位点的随机阵列:建模和理论表征

arXiv: Chemical Physics Pub Date : 2020-01-02 DOI:10.1149/2.0302001JES

A. Oleinick, O. Sliusarenko, I. Svir, C. Amatore

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引用次数: 3

摘要

本文综述了纳米活性位点的规则和随机阵列行为的理论描述的主要原理。进一步说明了当它们涉及具有相同尺寸的活性位点的常见情况时，如何应用它们来建立扩散限制条件下阵列响应的有用的半解析近似。这种近似是一般的，如不同类型阵列的例子，可以用来描述任何阵列的行为，涉及其活性位点在衬底表面的任意分布。此外，这种有效的方法允许基于计时安培数据的任何阵列的活性位点分布的统计表征。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Editors' Choice—Review—Nanostructured Electrodes as Random Arrays of Active Sites: Modeling and Theoretical Characterization

This review presents the main principles underlying the theoretical description of the behavior of regular and random arrays of nanometric active sites. It is further shown how they can be applied for establishing a useful semi-analytical approximation of the arrays responses under diffusion limited conditions when they involve the common situation of active sites with identical sizes. This approximation is general and, as exemplified for different type of arrays, can be employed for describing the behavior of any array involving arbitrary distributions of their active sites onto the substrate surface. Furthermore, this efficient approach allows statistical characterization of active sites distributions of any array based on chronoamperometric data.

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arXiv: Chemical Physics

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