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探索核壳型电催化剂制备的第一步:在载体金纳米颗粒上铜欠电位沉积的原位表征。

Exploring the first steps in core-shell electrocatalyst preparation: in situ characterization of the underpotential deposition of Cu on supported Au nanoparticles.

机构信息

School of Chemistry, University of Southampton, Highfield, Southampton SO17 1BJ, United Kingdom.

出版信息

J Am Chem Soc. 2011 Dec 7;133(48):19448-58. doi: 10.1021/ja206763e. Epub 2011 Nov 11.

DOI:10.1021/ja206763e
PMID:22032178
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3548434/
Abstract

The underpotential deposition (upd) of a Cu shell on a non-Pt nanoparticle core followed by galvanic displacement of the Cu template shell to form core-shell electrocatalyst materials is one means by which the Pt-based mass activity targets required for commercialization of PEM fuel cells may be reached. In situ EXAFS measurements were conducted at both the Au L(3) and the Cu K absorption edges during deposition of Cu onto a carbon-supported Au electrocatalyst to study the initial stages of formation of such a core-shell electrocatalyst. The Au L(3) EXAFS data obtained in 0.5 mol dm(-3) H(2)SO(4) show that the shape of the Au core is potential dependent, from a flattened to a round spherical shape as the Cu upd potential is approached. Following the addition of 2 mmol dm(-3) Cu, the structure was also measured as a function of the applied potential. At +0.2 V vs Hg/Hg(2)SO(4), the Cu(2+) species was found to be a hydrated octahedron. As the potential was made more negative, single-crystal studies predict an ordered bilayer of sulfate anions and partially discharged Cu ions, followed by a complete/uniform layer of Cu atoms. In contrast, the model obtained by fitting the Au L(3) and Cu K EXAFS data corresponds first to partially discharged Cu ions deposited at the defect sites in the outer shell of the Au nanoparticles at -0.42 V, followed by the growth of clusters of Cu atoms at -0.51 V. The absence of a uniform/complete Cu shell, even at the most negative potentials investigated, has implications for the structure, and the activity and/or stability, of the core-shell catalyst that would be subsequently formed following galvanic displacement of the Cu shell.

摘要

在非 Pt 纳米颗粒核上进行欠电位沉积 (upd) 的 Cu 壳,然后通过电置换 Cu 模板壳形成核壳电催化剂材料,是达到质子交换膜燃料电池商业化所需的基于 Pt 的质量活性目标的一种手段。在将 Cu 沉积到碳负载的 Au 电催化剂上的过程中,在 Au L(3) 和 Cu K 吸收边缘进行了原位 EXAFS 测量,以研究这种核壳电催化剂形成的初始阶段。在 0.5 mol dm(-3) H(2)SO(4) 中获得的 Au L(3) EXAFS 数据表明,Au 核的形状取决于电位,随着 Cu upd 电位的接近,从扁平形状变为球形。在添加 2 mmol dm(-3) Cu 后,还测量了结构作为施加电位的函数。在 +0.2 V vs Hg/Hg(2)SO(4) 下,发现 Cu(2+) 物种是水合八面体。随着电位变得更负,单晶研究预测会有一层有序的硫酸盐阴离子和部分放电的 Cu 离子双层,然后是完全/均匀的一层 Cu 原子。相比之下,通过拟合 Au L(3) 和 Cu K EXAFS 数据获得的模型首先对应于在 Au 纳米颗粒外壳的缺陷位置沉积的部分放电的 Cu 离子,在 -0.42 V,然后在 -0.51 V 时,Cu 原子的团簇开始生长。即使在研究的最负电位下,也没有完整/均匀的 Cu 壳,这对随后通过电置换 Cu 壳形成的核壳催化剂的结构、活性和/或稳定性都有影响。

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