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局域表面等离子体共振辅助光催化综述:物理场的影响及多场解耦中的机遇

Review on LSPR assisted photocatalysis: effects of physical fields and opportunities in multifield decoupling.

作者信息

Lv Sijia, Du Yanping, Wu Feitong, Cai Yichong, Zhou Tao

机构信息

China-UK Low Carbon College, Shanghai Jiao Tong University Shanghai 201306 China

出版信息

Nanoscale Adv. 2022 Apr 28;4(12):2608-2631. doi: 10.1039/d2na00140c. eCollection 2022 Jun 14.

DOI:10.1039/d2na00140c
PMID:36132289
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9416914/
Abstract

Since nano scale local surface plasmon resonance (LSPR) can broaden the visible absorption region, enhance the local electromagnetic field and produce a thermal effect simultaneously, the appropriate utilization of the LSPR effect is a noteworthy research direction towards visible light driven photocatalysts with high efficiency and low cost. In this study, the influence mechanism of the optical, electric, magnetic, and thermal physical fields on the photocatalytic efficiency of the LSPR system is for the first time reviewed, based on which the research bottlenecks of this method including the accurate predesign and regulation of the photocatalyst, the interpretation of electron movement and energy transfer mechanism, are specifically analyzed. Due to the micro-nano localization of LSPR, auxiliary methods are needed to reflect the micro electromagnetic and temperature field distribution which are otherwise formidable to measure experimentally. Alternatively, numerical methods with decoupling calculations of nano-scale physical fields are necessary to develop. Therefore, the development potential of different numerical simulation methods including mainstream FDTD, FEM and DDA is subsequently expounded, providing opportunities in resolving the bottleneck issues associated with photocatalysis. It is worth mentioning that although many important advances have been achieved in the preparation and application of LSPR assisted photocatalysts, the convincing function mechanism of LSPR is still lacking due to its multifield synergistic enhancement effect.

摘要

由于纳米尺度的局域表面等离子体共振(LSPR)能够拓宽可见光吸收区域、增强局部电磁场并同时产生热效应,因此合理利用LSPR效应是实现高效低成本可见光驱动光催化剂的一个值得关注的研究方向。本研究首次综述了光、电、磁和热物理场对LSPR体系光催化效率的影响机制,并在此基础上具体分析了该方法的研究瓶颈,包括光催化剂的精确预设计与调控、电子运动和能量转移机制的阐释等。由于LSPR的微纳局域特性,需要借助辅助手段来反映难以通过实验测量的微观电磁场和温度场分布。另外,有必要开发用于纳米尺度物理场解耦计算的数值方法。因此,随后阐述了包括主流的时域有限差分法(FDTD)、有限元法(FEM)和离散偶极子近似法(DDA)在内的不同数值模拟方法的发展潜力,为解决光催化相关瓶颈问题提供了契机。值得一提的是,尽管在LSPR辅助光催化剂的制备和应用方面已取得许多重要进展,但由于其多场协同增强效应,LSPR令人信服的作用机制仍然缺乏。

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