用于甲醇电催化氧化的三金属六八面体 Au@PdPt 纳米粒子的简单合成

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-11-14 DOI:10.1021/acs.jpcc.4c06337
Cuixia Bi, Xiaolong Yin, Zhixiu Wang, Hongyan Zhao, Guangqiang Liu
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引用次数: 0

摘要

本研究采用种子介导技术合成了三金属 Au@PdPt 纳米粒子(NPs),它们具有六八面体(HOH)Au 内核和支化 PdPt 合金外壳。制备过程包括合成具有高指数{651}面的 HOH Au NPs 作为纳米模板,然后在这些 NPs 上外延生长 Pd 和 Pt,得到 HOH Au@PdPt NPs。HOH Au@PdPt NPs 的尺寸和组成以及 PdPt 合金壳的厚度(从 2 纳米到 4 纳米、5 纳米和 8 纳米)可通过改变 Pd 和 Pt 前驱体的数量进行精确调节。通过金、钯和铂之间的协同效应,以及多分支钯铂合金壳增加的接触面积,这些 Au@PdPt NPs 的催化效率得到了显著提高。在甲醇电氧化过程中,HOH Au@PdPt NPs 的催化活性取决于铂的含量,呈现出独特的火山型模式。值得注意的是,HOH Au@Pd0.3Pt0.3 NPs 在酸性条件下具有最佳的甲醇氧化催化性能,与商用铂黑催化剂相比,表现出更优越的电催化性能。其 ECSA 值、质量和比活性分别为 47.21 m2 g-1、0.93 A mg-1 和 1.97 mA cm-2。通过精确设计和控制三金属 Au@PdPt NPs 的尺寸、组成和形态,这项研究可用于制造具有特殊性能的催化剂。
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Facile Synthesis of Trimetallic Hexoctahedral Au@PdPt Nanoparticles for Electrocatalytic Oxidation of Methanol
In this study, trimetallic Au@PdPt nanoparticles (NPs) were synthesized by a seed-mediated technique, possessing a hexoctahedral (HOH) Au core with a branched PdPt alloy shell. The fabrication process involved the synthesis of HOH Au NPs exhibiting high-index {651} facet as nanotemplates, followed by the epitaxial growth of Pd and Pt on these NPs to yield HOH Au@PdPt NPs. The size and composition of HOH Au@PdPt NPs as well as the thickness of PdPt alloy shells (from 2 to 4, 5, and 8 nm) can be precisely adjusted by varying the quantity of Pd and Pt precursors. The catalytic efficacy of these Au@PdPt NPs was significantly enhanced through the synergistic effect between Au, Pd, and Pt, along with the increased contact areas afforded by multibranched PdPt alloy shells. For methanol electro-oxidation, the catalytic activity of HOH Au@PdPt NPs depends on the Pt content showing a distinctive volcano-type pattern. Remarkably, the HOH Au@Pd0.3Pt0.3 NPs demonstrate optimum catalytic performance for methanol oxidation in acidic conditions, exhibiting superior electrocatalytic properties compared to commercial Pt black catalysts. Their ECSA value, mass, and specific activities are 47.21 m2 g–1, 0.93 A mg–1, and 1.97 mA cm–2, respectively. This research can be exploited to fabricate catalysts possessing exceptional properties by precisely designing and controlling the size, composition and morphology of the trimetallic Au@PdPt NPs.
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4.30%
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567
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