Enhanced signal to noise ratio of single entity electrochemistry signal of platinum nanoparticles using passive silver ultramicroelectrode

IF 1.7 4区化学

Bulletin of the Korean Chemical Society Pub Date : 2024-10-28 DOI:10.1002/bkcs.12905

Seongkyeong Yoon, Jaedo Na, Sun Gyu Moon, Heewon Kim, Ki Jun Kim, Seong Jung Kwon

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Abstract

The single-entity electrochemistry (SEE) of electrocatalytic platinum (Pt) single nanoparticles (NPs) on a less electrocatalytic silver (Ag) ultramicroelectrode (UME) surface was investigated using the electrocatalytic amplification method. Two characteristic types of current responses—current staircases and blips (or spikes)—were observed during single NP collision experiments, depending on the applied potential at the Ag UME. Notably, at applied potentials of 0.13 and 0.17 V, the Ag UME becomes passive due to the formation of a delicate oxide layer, resulting in a highly stable background current. This leads to an enhanced signal-to-noise (S/N) ratio, attributed to the low background current, when using Ag UME compared to commonly used UMEs such as Au, C, Ni, and Hg for the SEE of Pt NPs. The exceptionally low background current can provide a significant advantage for detailed observation of SEE signals and further mechanistic studies based on the current response.

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利用无源银超微电极提高铂纳米粒子单体电化学信号的信噪比

利用电催化放大法研究了电催化铂（Pt）单个纳米粒子（NPs）在电催化较弱的银（Ag）超微电极（UME）表面上的单实体电化学（SEE）。在单个 NP 碰撞实验中，观察到两种特征类型的电流响应--阶梯电流和突波（或尖峰）--取决于 Ag UME 的外加电位。值得注意的是，在 0.13 和 0.17 V 的施加电位下，由于形成了微妙的氧化层，Ag UME 变得被动，从而产生了高度稳定的背景电流。与常用的用于铂氮氧化物 SEE 的 UME（如金、铜、镍和汞）相比，银 UME 的本底电流低，从而提高了信噪比（S/N）。超低的背景电流可为详细观察 SEE 信号和基于电流响应的进一步机理研究提供显著优势。

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来源期刊

Bulletin of the Korean Chemical Society Chemistry-General Chemistry

自引率

23.50%

发文量

182

期刊介绍： The Bulletin of the Korean Chemical Society is an official research journal of the Korean Chemical Society. It was founded in 1980 and reaches out to the chemical community worldwide. It is strictly peer-reviewed and welcomes Accounts, Communications, Articles, and Notes written in English. The scope of the journal covers all major areas of chemistry: analytical chemistry, electrochemistry, industrial chemistry, inorganic chemistry, life-science chemistry, macromolecular chemistry, organic synthesis, non-synthetic organic chemistry, physical chemistry, and materials chemistry.