pH-Dependant Electrochemical Oxidation of Small Molecules on Glassy Carbon, Platinum and Gold

IF 2.7 3区化学 Q2 CHEMISTRY, ANALYTICAL

Electroanalysis Pub Date : 2025-01-22 DOI:10.1002/elan.12013

Samuel V. Somerville, Manusha Dissanayake, Yoshiki Soda, Tania M. Benedetti, Richard D. Tilley, J. Justin Gooding

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Abstract

Composite electrodes often consisting of a purportedly inactive support material modified with a variety of nanomaterials, surface chemistry and coatings are commonly employed as electroanalytical devices for detection of biologically relevant molecules. However, these electrodes are often used in various electrolytes and biological fluids treated in a variety of ways making comparisons between materials difficult. Additionally, nanomaterial designers have developed techniques capable of controlling the local solution environment at the interface of electrodes. Herein, we present a study of the electro-oxidation of glucose, ascorbic acid, uric acid and dopamine on glassy carbon, platinum and gold. Peak potential and current versus pH are presented to provide a database and resource to aid in the deconvolution of the electrochemical response produced by these materials. Additionally, in light of recent developments in pH control within nanoconfined electrodes, a study of how altering the pH of an electrolyte allows for the separation of previously overlapping peaks is presented.

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玻璃碳、铂和金上小分子电化学氧化的ph依赖性研究

复合电极通常由用各种纳米材料、表面化学和涂层修饰的据称无活性的支撑材料组成，通常用作检测生物相关分子的电分析装置。然而，这些电极通常用于以各种方式处理的各种电解质和生物流体，这使得材料之间的比较变得困难。此外，纳米材料设计者已经开发出能够控制电极界面局部溶液环境的技术。在此，我们提出了葡萄糖，抗坏血酸，尿酸和多巴胺在玻碳，铂和金上的电氧化研究。峰电位和电流随pH值的变化提供了一个数据库和资源，以帮助对这些材料产生的电化学响应进行反卷积。此外，鉴于最近在纳米限制电极内pH控制的发展，如何改变电解质的pH值允许先前重叠峰的分离的研究被提出。

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来源期刊

Electroanalysis 化学-电化学

CiteScore

6.00

自引率

3.30%

发文量

222

审稿时长

2.4 months

期刊介绍： Electroanalysis is an international, peer-reviewed journal covering all branches of electroanalytical chemistry, including both fundamental and application papers as well as reviews dealing with new electrochemical sensors and biosensors, nanobioelectronics devices, analytical voltammetry, potentiometry, new electrochemical detection schemes based on novel nanomaterials, fuel cells and biofuel cells, and important practical applications. Serving as a vital communication link between the research labs and the field, Electroanalysis helps you to quickly adapt the latest innovations into practical clinical, environmental, food analysis, industrial and energy-related applications. Electroanalysis provides the most comprehensive coverage of the field and is the number one source for information on electroanalytical chemistry, electrochemical sensors and biosensors and fuel/biofuel cells.