Tailoring Pd content for optimal stability in FeCoNiCu multielement alloy electrocatalysts for oxygen evolution reaction.

IF 3.1 3区化学 Q2 CHEMISTRY, PHYSICAL

Faraday Discussions Pub Date : 2025-10-10 DOI:10.1039/d5fd00084j

Bing Zhu, Qiqi Huang, Okkyun Seo, Yee Yan Tay, Jiayi Tang, Huayu Gu, Tong Li, Dongshuang Wu

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引用次数: 0

Abstract

Multielemental alloys (MEAs) based on Earth-abundant 3d transition metals hold significant promise as low-cost electrocatalysts for the oxygen evolution reaction (OER), but their long-term stability under oxidative conditions remains a major challenge. In this study, we investigate the effect of palladium incorporation on the electrochemical performance and structural durability of FeCoNiCu MEA nanoparticles. Building upon our previous findings that trace Pd addition significantly enhances catalyst durability, an accelerated durability test (ADT) performed at 100 mA cm^-2 reveals that the degradation rate (0.356 mV h^-1) decreased dramatically to approximately 1/350th that of Pd-free FeCoNiCu (125 mV h^-1). In this study, we systematically synthesized a series of Pd-FeCoNiCu alloys with Pd contents ranging from 0.177 to 1.97 at%. Advanced characterization techniques including inductively coupled plasma optical emission spectroscopy (ICP-OES), electron microscopy, synchrotron-based spectroscopy, and electrochemical measurements, were employed to elucidate the correlation between composition, structure, and performance. Our findings reveal a highly non-linear dependence of catalyst performance on Pd content: an optimal range (0.336-0.389 at%) enables long-range d-d/sp orbital hybridization that delocalizes the local density of states (LDOS) of surrounding 3d metals, thereby suppressing oxidative dissolution. In contrast, higher Pd concentrations lead to Pd-Pd interactions, localize electronic perturbation, and accelerate degradation. This volcano-type correlation between Pd content and durability, highlights a general strategy for engineering catalyst longevity via minimal noble-metal doping and spatially cooperative electronic modulation.

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为优化析氧反应中FeCoNiCu多元素合金电催化剂的稳定性而调整Pd含量。

基于地球上丰富的三维过渡金属的多元素合金（MEAs）作为析氧反应（OER）的低成本电催化剂具有重要的前景，但其在氧化条件下的长期稳定性仍然是一个主要挑战。在这项研究中，我们研究了钯掺入对FeCoNiCu MEA纳米粒子电化学性能和结构耐久性的影响。在我们之前的研究结果的基础上，痕量Pd的添加显著提高了催化剂的耐久性，在100 mA cm-2下进行的加速耐久性测试（ADT）显示，降解率（0.356 mV h-1）急剧下降到约为无Pd FeCoNiCu （125 mV h-1）的1/350。在本研究中，我们系统地合成了一系列Pd- feconicu合金，Pd含量在0.177 ~ 1.97（%）之间。采用电感耦合等离子体发射光谱（ICP-OES）、电子显微镜、同步辐射光谱和电化学测量等先进表征技术来阐明其组成、结构和性能之间的相关性。我们的研究结果揭示了催化剂性能对Pd含量的高度非线性依赖：最佳范围（0.336-0.389 at%）可以实现远程d-d/sp轨道杂化，使周围3d金属的局部态密度（LDOS）离域，从而抑制氧化溶解。相反，较高的Pd浓度导致Pd-Pd相互作用，局部电子摄动，加速降解。这种火山型钯含量与耐久性之间的相关性，强调了通过最少的贵金属掺杂和空间协同电子调制来延长工程催化剂寿命的一般策略。

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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来源期刊

Faraday Discussions 化学-物理化学

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259

期刊介绍： Discussion summary and research papers from discussion meetings that focus on rapidly developing areas of physical chemistry and its interfaces