Rapid fluorescent mapping of electrochemically induced local pH changes

Advanced Sensor and Energy Materials Pub Date : 2022-12-01 DOI:10.1016/j.asems.2022.100030

Jia Gao , Rui-Yang Zhao , Yi-Guang Wang , Ruo-Chen Xie , Wei Wang

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引用次数: 2

Abstract

We present a fluorescent microscopic method using an ultra-pH-sensitive polymeric probe to rapidly map within subsecond the pH distribution resulting from oxygen reduction reaction electrocatalysed by an array of platinum nanoparticles. Upon voltammetry of the surface-supported Pt catalysts, fluorescent quenching waves are observed to depend on the electrode potential. The spatiotemporal fluorescent evolution is then confirmed under a constant potential control to be due to the local pH change as a function of diffusing time by an estimation of the proton diffusion coefficient $(L α t^{1 / 2})$ . On these bases, the fluorescent measurements at short reaction times can provide quantitative information regarding the one and two dimensional pH distributions, which are shown to exhibit the expected shape of a typical diffusion-driven concentration gradient. Such imaging of proton/pH profiles may find important applications such as efficient screening of different micro/nanoscale electrocatalysts.

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电化学诱导的局部pH变化的快速荧光定位

我们提出了一种荧光显微方法，使用超pH敏感聚合物探针在亚秒内快速绘制由一系列铂纳米颗粒电催化的氧还原反应产生的pH分布。在表面负载Pt催化剂的伏安法上，观察到荧光猝灭波依赖于电极电位。然后通过质子扩散系数(Lαt1/2)的估计，在恒定电位控制下，确认了时空荧光演变是由于局部pH变化作为扩散时间的函数引起的。在此基础上，在短反应时间内的荧光测量可以提供有关一维和二维pH分布的定量信息，这些分布显示出典型扩散驱动浓度梯度的预期形状。这种质子/pH谱的成像可能会找到重要的应用，如有效筛选不同的微/纳米级电催化剂。

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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Advanced Sensor and Energy Materials

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