Chapter 11. Plasmonic Photocatalysts for Environmental Applications

Nanoparticle Design and Characterization for Catalytic Applications in Sustainable Chemistry Pub Date : 2019-05-10 DOI:10.1039/9781788016292-00309

C. K. Waters, B. Cojocaru, F. Lin, L. Woodard, R. Richards, V. Pârvulescu

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Abstract

There is a continued and growing interest in sustaining and improving our environment. Research scientists are exploring new avenues using plasmonic photocatalysts as a way to catapult advances in the field. Plasmonic photocatalysts have gained significant attention in recent decades owing to the phenomena associated with localized surface plasmon resonance (LSPR). Gold (Au), silver (Ag), and copper (Cu) are the most widely studied and will be highlighted in this chapter. This chapter includes fundamental concepts related to LSPR and the significance of employing plasmons as a method to increase photocatalytic reaction rates and improve product selectivity. Plasmon-enhanced catalytic reaction types including C–X bond activation and low carbon footprint applications are highlighted in this chapter. This chapter does not include an exhaustive list of applications for which plasmonic photocatalysts can be used, but rather provides insight into the vast possibilities of how phenomena related to LSPR and plasmon-enhanced catalytic processes can have a lasting effect on how we store, use, and convert energy in chemical bonds.

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第十一章。环境应用的等离子体光催化剂

人们对维持和改善环境的兴趣不断增长。研究科学家正在探索使用等离子体光催化剂的新途径，作为推动该领域进步的一种方式。近几十年来，由于与局部表面等离子体共振(LSPR)有关的现象，等离子体光催化剂得到了广泛的关注。金(Au)，银(Ag)和铜(Cu)是研究最广泛的，将在本章中重点介绍。本章包括与LSPR相关的基本概念，以及利用等离子体激元作为提高光催化反应速率和提高产物选择性的方法的意义。等离子体增强的催化反应类型包括C-X键激活和低碳足迹应用在本章中强调。本章不包括等离子体光催化剂应用的详尽列表，而是提供了与LSPR和等离子体增强催化过程相关的现象如何对我们如何存储，使用和转换化学键中的能量产生持久影响的巨大可能性。

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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Nanoparticle Design and Characterization for Catalytic Applications in Sustainable Chemistry

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