First-Principles Insights into Plasmon-Induced Catalysis.

IF 11.7 1区化学 Q1 CHEMISTRY, PHYSICAL Annual review of physical chemistry Pub Date : 2021-04-20 Epub Date: 2021-12-02 DOI:10.1146/annurev-physchem-061020-053501

John Mark P Martirez, Junwei Lucas Bao, Emily A Carter

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引用次数: 25

Abstract

The size- and shape-controlled enhanced optical response of metal nanoparticles (NPs) is referred to as a localized surface plasmon resonance (LSPR). LSPRs result in amplified surface and interparticle electric fields, which then enhance light absorption of the molecules or other materials coupled to the metallic NPs and/or generate hot carriers within the NPs themselves. When mediated by metallic NPs, photocatalysis can take advantage of this unique optical phenomenon. This review highlights the contributions of quantum mechanical modeling in understanding and guiding current attempts to incorporate plasmonic excitations to improve the kinetics of heterogeneously catalyzed reactions. A range of first-principles quantum mechanics techniques has offered insights, from ground-state density functional theory (DFT) to excited-state theories such as multireference correlated wavefunction methods. Here we discuss the advantages and limitations of these methods in the context of accurately capturing plasmonic effects, with accompanying examples.

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等离子体诱导催化的第一性原理。

金属纳米粒子(NPs)的尺寸和形状控制增强光学响应被称为局域表面等离子体共振(LSPR)。LSPRs导致放大的表面和粒子间电场，从而增强与金属NPs耦合的分子或其他材料的光吸收和/或在NPs本身内产生热载流子。当由金属NPs介导时，光催化可以利用这种独特的光学现象。这篇综述强调了量子力学建模在理解和指导当前尝试结合等离子体激发来改善多相催化反应动力学方面的贡献。从基态密度泛函理论(DFT)到激发态理论(如多参考相关波函数方法)，一系列第一性原理量子力学技术提供了见解。本文讨论了这些方法在精确捕获等离子体效应方面的优点和局限性，并给出了相应的例子。

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

Annual review of physical chemistry 化学-物理化学

CiteScore

28.00

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0.00%

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期刊介绍： The Annual Review of Physical Chemistry has been published since 1950 and is a comprehensive resource for significant advancements in the field. It encompasses various sub-disciplines such as biophysical chemistry, chemical kinetics, colloids, electrochemistry, geochemistry and cosmochemistry, chemistry of the atmosphere and climate, laser chemistry and ultrafast processes, the liquid state, magnetic resonance, physical organic chemistry, polymers and macromolecules, and others.

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