通过控制非模型纳米粒子催化剂中的应变和配体效应,实现金属表面位点的化学和催化活性工程化

IF 11.3 1区 化学 Q1 CHEMISTRY, PHYSICAL
Bill Yan,  and , Suljo Linic*, 
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引用次数: 0

摘要

反应物在异相催化剂表面位点上的结合能是许多化学反应公认的催化活性描述指标。然而,通过对催化剂表面位点进行工程设计来系统地操纵结合能已被证明具有挑战性。在此,我们提出了一种纳米颗粒催化剂结构,该结构包含一个由可混和金属原子组成的合金核心,合金核心周围环绕着一层不同的材料,表面覆盖着一层具有催化活性的金属。合金核心控制着纳米粒子的晶格应变,从而控制着表面原子之间的距离,而次表层原子则对表面原子产生配体效应。我们的研究表明,这一类材料能让我们高精度地系统控制吸附剂的结合能。我们通过开发非模型纳米粒子催化剂来说明我们的发现,该催化剂采用成分可控的金铜合金作为核心,金作为周围层,铂作为活性表面金属。一氧化碳电化学剥离测量结果表明,通过改变合金核心的成分,可以系统地调整表面铂位点上的一氧化碳结合能。我们的分析表明,铂的一氧化碳结合能的变化是金层的配体效应和金铜合金核心的应变效应共同作用的结果。所介绍的催化剂结构允许精确调节应变和配体效应,以调整任何催化材料的局部化学环境,这可能有助于下一代催化剂的开发。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Engineering Chemical and Catalytic Activity of Metal Surface Sites by Controlling Strain and Ligand Effects in Nonmodel Nanoparticle Catalysts

Engineering Chemical and Catalytic Activity of Metal Surface Sites by Controlling Strain and Ligand Effects in Nonmodel Nanoparticle Catalysts

Binding energy of reactants on heterogeneous catalyst surface sites is a well-established catalytic activity descriptor for many chemical reactions. However, systematically manipulating the binding energies by engineering the catalytic surface sites has proven challenging. Herein, we propose a nanoparticle catalyst structure that contains an alloy core composed of miscible metal atoms, surrounded by layers of a different material, and covered by a layer of catalytically active metal. The alloy core controls the lattice strain of the nanoparticle and therefore the distance between the surface atoms, while the subsurface layer atoms induce a ligand effect on the surface atoms. We show that this class of materials allows us to systematically control the adsorbate binding energies with high precision. We illustrate our findings by developing nonmodel nanoparticle catalysts that employ an AuCu alloy with controlled composition as the core, Au as the surrounding layers, and Pt as the active surface metal. Electrochemical CO stripping measurements suggest that the CO binding energy on the surface Pt sites can be systematically tuned by varying the composition of the alloy core. Our analysis suggests that the change in the CO binding energy of Pt is the result of the combined ligand effect from the Au layers and strain effect from the AuCu core. The presented catalyst structure allows for precise modulation of the strain and ligand effect for tuning the local chemical environment of any catalytic materials, which may aid the development of next-generation catalysts.

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来源期刊
ACS Catalysis
ACS Catalysis CHEMISTRY, PHYSICAL-
CiteScore
20.80
自引率
6.20%
发文量
1253
审稿时长
1.5 months
期刊介绍: ACS Catalysis is an esteemed journal that publishes original research in the fields of heterogeneous catalysis, molecular catalysis, and biocatalysis. It offers broad coverage across diverse areas such as life sciences, organometallics and synthesis, photochemistry and electrochemistry, drug discovery and synthesis, materials science, environmental protection, polymer discovery and synthesis, and energy and fuels. The scope of the journal is to showcase innovative work in various aspects of catalysis. This includes new reactions and novel synthetic approaches utilizing known catalysts, the discovery or modification of new catalysts, elucidation of catalytic mechanisms through cutting-edge investigations, practical enhancements of existing processes, as well as conceptual advances in the field. Contributions to ACS Catalysis can encompass both experimental and theoretical research focused on catalytic molecules, macromolecules, and materials that exhibit catalytic turnover.
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