Effect of High Local Diffusive Mass Transfer on Acidic Oxygen Reduction of Pt Catalysis

Wenzhan Wu, Pengzhu Lin, Bin Liu, Jianbo Xu, Jing Sun, T. Zhao
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Abstract

In this study, we utilized a platinum ultramicroelectrode (UME) as a model platform for platinum electrocatalysts in acidic electrolytes to study the effects of local mass transfer on the oxygen reduction reaction (ORR), which plays a significant role in fuel cell with reduced pt loading. Finite element simulations showed that the UME exhibits size-dependent ultrathin diffusion layers during the electrochemical process. Submicron-scale UMEs can achieve ultrahigh localized mass transfer, which is unattainable through other experimental techniques. By conducting catalytic experiments under various mass transfer conditions, we found that the mass transfer limiting current is significantly lower than the value predicted by the four-electron process equation. Additionally, the apparent electron transfer number (napp) decreases as the mass transfer coefficient (m0) increases. Furthermore, as m0 increases, the half-wave potential shifts toward more negative values, allowing for the evaluation of the intrinsic activity of the catalysts over a broader potential range. Due to the UME technique's capacity to conveniently control local mass transfer, we foresee its potential application in understanding the effects of chemical microenvironments on complex electrochemical reactions, including ORR and other processes.
高局部扩散传质对铂催化酸性氧还原的影响
在这项研究中,我们利用铂超微电极(UME)作为酸性电解质中铂电催化剂的模型平台,研究了局部传质对氧还原反应(ORR)的影响,氧还原反应在减少铂负载的燃料电池中发挥着重要作用。有限元模拟显示,UME 在电化学过程中表现出与尺寸相关的超薄扩散层。亚微米级 UME 可以实现超高的局部传质,这是其他实验技术无法实现的。通过在各种传质条件下进行催化实验,我们发现传质极限电流明显低于四电子过程方程预测的值。此外,表观电子转移数(napp)随着传质系数(m0)的增大而减小。此外,随着 m0 的增加,半波电位也会向更负的值移动,从而可以在更宽的电位范围内评估催化剂的内在活性。由于 UME 技术能够方便地控制局部传质,我们预计它有望应用于了解化学微环境对复杂电化学反应(包括 ORR 和其他过程)的影响。
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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