调整纳米颗粒结构和表面应变以优化催化性能。

Tuning nanoparticle structure and surface strain for catalysis optimization.

机构信息

Department of Chemistry, Brown University , Providence, Rhode Island 02912, United States.

出版信息

J Am Chem Soc. 2014 May 28;136(21):7734-9. doi: 10.1021/ja5030172. Epub 2014 May 16.

Abstract

Controlling nanoparticle (NP) surface strain, i.e. compression (or stretch) of surface atoms, is an important approach to tune NP surface chemistry and to optimize NP catalysis for chemical reactions. Here we show that surface Pt strain in the core/shell FePt/Pt NPs with Pt in three atomic layers can be rationally tuned via core structural transition from cubic solid solution [denoted as face centered cubic (fcc)] structure to tetragonal intermetallic [denoted as face centered tetragonal (fct)] structure. The high activity observed from the fct-FePt/Pt NPs for oxygen reduction reaction (ORR) is due to the release of the overcompressed Pt strain by the fct-FePt as suggested by quantum mechanics-molecular mechanics (QM-MM) simulations. The Pt strain effect on ORR can be further optimized when Fe in FePt is partially replaced by Cu. As a result, the fct-FeCuPt/Pt NPs become the most efficient catalyst for ORR and are nearly 10 times more active in specific activity than the commercial Pt catalyst. This structure-induced surface strain control opens up a new path to tune and optimize NP catalysis for ORR and many other chemical reactions.

摘要

控制纳米粒子（NP）表面应变，即表面原子的压缩（或拉伸），是一种调节 NP 表面化学性质和优化 NP 催化化学反应的重要方法。在这里，我们表明，通过从立方固溶体[表示为面心立方（fcc）]结构到四面体金属间[表示为面心四方（fct）]结构的核心结构转变，可以合理地调节具有三层 Pt 的核壳 FePt/Pt NPs 中的表面 Pt 应变。高活性的 fct-FePt/Pt NPs 观察到氧还原反应（ORR）是由于 fct-FePt 释放了过压缩的 Pt 应变，这是由量子力学-分子力学（QM-MM）模拟提出的。当 FePt 中的 Fe 部分被 Cu 取代时，Pt 应变对 ORR 的影响可以进一步优化。结果，fct-FeCuPt/Pt NPs 成为最有效的 ORR 催化剂，其比商业 Pt 催化剂的比活性高近 10 倍。这种结构诱导的表面应变控制为调节和优化 ORR 和许多其他化学反应中的 NP 催化作用开辟了新途径。

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调整纳米颗粒结构和表面应变以优化催化性能。

Tuning nanoparticle structure and surface strain for catalysis optimization.

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