{"title":"电化学贡献:约翰·爱德华·布朗·兰德尔斯(1912-1998)","authors":"Evgeny Katz","doi":"10.1002/elsa.202300005","DOIUrl":null,"url":null,"abstract":"<p>John Edward Brough Randles (Figure 1) was an English electrochemist who made important contributions to the theoretical background of polarography, cyclic voltammetry, and electrochemical impedance spectroscopy. Many modern techniques of electrochemistry are descended from his work, including cyclic voltammetry, anodic stripping voltammetry, and various types of hydrodynamic voltammetry. The Randles-Ševčík equation applied on linear sweep voltammetry and cyclic voltammetry, and the Randles equivalent circuit used in the modeling of impedance spectra are named after him.</p><p>The earliest electrochemical work of Randles performed with an oscillopolarograph (cathode ray polarograph) resulted in the development of linear sweep voltammetry.<sup>[</sup><span><sup>1, 2</sup></span><sup>]</sup> In addition to the experimental work, Randles solved a theoretical problem for expressing the current for diffusion-controlled electrochemical reactions by applying an ingenious graphical method.<sup>[</sup><span><sup>3</sup></span><sup>]</sup></p><p>Another important contribution of Randles to electrochemistry was in the theoretical analysis of Faraday impedance spectra published in 1947.<sup>[</sup><span><sup>4</sup></span><sup>]</sup> The Randles equivalent circuit has been applied to the analysis of the impedance spectra including interfacial electron transfer (Faradaic component), capacitance and diffusion contributions to the impedance. It became the most frequently used theoretical treatment of impedance spectra. It should be noted that similar results were obtained by Russian scientists Dolin and Erschler in 1940, but the papers published in the Russian language have not been seen by the electrochemical community.</p><p>The Randles equivalent circuit (Figure 2) is one of the simplest and most common circuit models of electrochemical impedance. It includes a solution resistance, a double-layer capacitor, and a charge transfer or polarization resistance. While the Randles equivalent circuit is frequently sufficient for modeling simple electrochemical systems, it can be used as a starting point for more sophisticated models, for example, based on more resistances and capacitances organized in parallel or in a sequence.</p><p>It should be noted that John Randles was not only working on solving theoretical problems in electrochemistry, but he was a very good experimentalist. As an example of his experimental work, the Volta potential difference between a mercury droplet and an electrolyte solution measured by Randles can be mentioned.<sup>[</sup><span><sup>5</sup></span><sup>]</sup> Notably, the great Russian electrochemist Alexander Frumkin had failed to obtain a stable and reproducible result for this kind of measurement.</p><p>Randles published relatively few papers, but many of them are of great importance and his theoretical treatments of electrochemical systems have been included in all electrochemistry textbooks.</p><p>The author declares that he has no conflict of interest.</p>","PeriodicalId":93746,"journal":{"name":"Electrochemical science advances","volume":null,"pages":null},"PeriodicalIF":2.9000,"publicationDate":"2023-02-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/elsa.202300005","citationCount":"0","resultStr":"{\"title\":\"Electrochemical contributions: John Edward Brough Randles (1912–1998)\",\"authors\":\"Evgeny Katz\",\"doi\":\"10.1002/elsa.202300005\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>John Edward Brough Randles (Figure 1) was an English electrochemist who made important contributions to the theoretical background of polarography, cyclic voltammetry, and electrochemical impedance spectroscopy. Many modern techniques of electrochemistry are descended from his work, including cyclic voltammetry, anodic stripping voltammetry, and various types of hydrodynamic voltammetry. The Randles-Ševčík equation applied on linear sweep voltammetry and cyclic voltammetry, and the Randles equivalent circuit used in the modeling of impedance spectra are named after him.</p><p>The earliest electrochemical work of Randles performed with an oscillopolarograph (cathode ray polarograph) resulted in the development of linear sweep voltammetry.<sup>[</sup><span><sup>1, 2</sup></span><sup>]</sup> In addition to the experimental work, Randles solved a theoretical problem for expressing the current for diffusion-controlled electrochemical reactions by applying an ingenious graphical method.<sup>[</sup><span><sup>3</sup></span><sup>]</sup></p><p>Another important contribution of Randles to electrochemistry was in the theoretical analysis of Faraday impedance spectra published in 1947.<sup>[</sup><span><sup>4</sup></span><sup>]</sup> The Randles equivalent circuit has been applied to the analysis of the impedance spectra including interfacial electron transfer (Faradaic component), capacitance and diffusion contributions to the impedance. It became the most frequently used theoretical treatment of impedance spectra. It should be noted that similar results were obtained by Russian scientists Dolin and Erschler in 1940, but the papers published in the Russian language have not been seen by the electrochemical community.</p><p>The Randles equivalent circuit (Figure 2) is one of the simplest and most common circuit models of electrochemical impedance. It includes a solution resistance, a double-layer capacitor, and a charge transfer or polarization resistance. While the Randles equivalent circuit is frequently sufficient for modeling simple electrochemical systems, it can be used as a starting point for more sophisticated models, for example, based on more resistances and capacitances organized in parallel or in a sequence.</p><p>It should be noted that John Randles was not only working on solving theoretical problems in electrochemistry, but he was a very good experimentalist. 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引用次数: 0
摘要
John Edward Brough Randles(图1)是一位英国电化学家,他对极谱法、循环伏安法和电化学阻抗谱的理论背景做出了重要贡献。许多现代电化学技术都是从他的工作中发展而来的,包括循环伏安法、阳极溶出伏安法和各种类型的流体动力学伏安法。用于线性扫描伏安法和循环伏安法的Randles-Ševčík方程和阻抗谱建模的Randles等效电路都是以他的名字命名的。兰德尔斯用示波极谱仪(阴极射线极谱仪)进行的最早的电化学工作导致了线性扫描伏安法的发展。[1,2]在实验工作之外,Randles运用一种巧妙的图解方法解决了扩散控制电化学反应的电流表示的理论问题。[3]兰德尔斯对电化学的另一个重要贡献是1947年发表的法拉第阻抗谱的理论分析。[4]应用兰德尔斯等效电路分析了界面电子转移(法拉第分量)、电容和扩散对阻抗的贡献。它成为阻抗谱最常用的理论处理方法。值得注意的是,俄罗斯科学家Dolin和Erschler在1940年也获得了类似的结果,但电化学学界并没有看到用俄语发表的论文。Randles等效电路(图2)是电化学阻抗最简单、最常见的电路模型之一。它包括溶液电阻、双层电容器和电荷转移或极化电阻。虽然Randles等效电路通常足以模拟简单的电化学系统,但它可以作为更复杂模型的起点,例如,基于并联或顺序组织的更多电阻和电容。值得注意的是,约翰·兰德尔斯不仅致力于解决电化学中的理论问题,而且还是一位非常优秀的实验家。作为他实验工作的一个例子,可以提到兰德尔斯测量的汞滴和电解质溶液之间的伏特电位差。[5]值得注意的是,伟大的俄罗斯电化学家亚历山大·弗鲁姆金(Alexander Frumkin)未能为这种测量获得稳定且可重复的结果。Randles发表的论文相对较少,但其中许多都是非常重要的,他对电化学系统的理论处理被包括在所有的电化学教科书中。作者宣称他没有利益冲突。
Electrochemical contributions: John Edward Brough Randles (1912–1998)
John Edward Brough Randles (Figure 1) was an English electrochemist who made important contributions to the theoretical background of polarography, cyclic voltammetry, and electrochemical impedance spectroscopy. Many modern techniques of electrochemistry are descended from his work, including cyclic voltammetry, anodic stripping voltammetry, and various types of hydrodynamic voltammetry. The Randles-Ševčík equation applied on linear sweep voltammetry and cyclic voltammetry, and the Randles equivalent circuit used in the modeling of impedance spectra are named after him.
The earliest electrochemical work of Randles performed with an oscillopolarograph (cathode ray polarograph) resulted in the development of linear sweep voltammetry.[1, 2] In addition to the experimental work, Randles solved a theoretical problem for expressing the current for diffusion-controlled electrochemical reactions by applying an ingenious graphical method.[3]
Another important contribution of Randles to electrochemistry was in the theoretical analysis of Faraday impedance spectra published in 1947.[4] The Randles equivalent circuit has been applied to the analysis of the impedance spectra including interfacial electron transfer (Faradaic component), capacitance and diffusion contributions to the impedance. It became the most frequently used theoretical treatment of impedance spectra. It should be noted that similar results were obtained by Russian scientists Dolin and Erschler in 1940, but the papers published in the Russian language have not been seen by the electrochemical community.
The Randles equivalent circuit (Figure 2) is one of the simplest and most common circuit models of electrochemical impedance. It includes a solution resistance, a double-layer capacitor, and a charge transfer or polarization resistance. While the Randles equivalent circuit is frequently sufficient for modeling simple electrochemical systems, it can be used as a starting point for more sophisticated models, for example, based on more resistances and capacitances organized in parallel or in a sequence.
It should be noted that John Randles was not only working on solving theoretical problems in electrochemistry, but he was a very good experimentalist. As an example of his experimental work, the Volta potential difference between a mercury droplet and an electrolyte solution measured by Randles can be mentioned.[5] Notably, the great Russian electrochemist Alexander Frumkin had failed to obtain a stable and reproducible result for this kind of measurement.
Randles published relatively few papers, but many of them are of great importance and his theoretical treatments of electrochemical systems have been included in all electrochemistry textbooks.
The author declares that he has no conflict of interest.