等离子纳米结构中的热电子动力学:基础、应用和被忽视的方面

IF 27.2 Q1 OPTICS eLight Pub Date : 2024-08-16 DOI:10.1186/s43593-024-00070-w
Jacob Khurgin, Anton Yu. Bykov, Anatoly V. Zayats
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引用次数: 0

摘要

导电材料和纳米结构表面附近的光吸收会激发非平衡高能电荷载流子:费米级以上的电子或费米级以下的空穴。当这些所谓的热载流子停留在材料内部时,就会产生非线性、克尔型光学效应,这对于用光控制光非常重要。它们还可以转移到纳米结构的周围环境中,从而产生光电流,或者与邻近的分子和介质相互作用,诱发光化学转化。了解质子纳米结构中热载流子的动力学及相关效应对于开发超快探测器和非线性光学元件、宽带光催化、增强型纳米级光电器件、纳米级和超快温度控制以及其他未来技术非常重要。在这篇综述中,我们将讨论等离子体激发热电子的基本原理,重点关注被忽视的方面、理论描述和实验研究方法,并描述金属界面热电子过程的原型过程和最有前景的应用实例。
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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Hot-electron dynamics in plasmonic nanostructures: fundamentals, applications and overlooked aspects

Light absorption near a surface of conductive materials and nanostructures leads to the excitation of nonequilibrium, high-energy charge carriers: electrons above the Fermi level or holes below it. When remaining inside a material, these so-called hot carriers result in nonlinear, Kerr-type, optical effects important for controlling light with light. They can also transfer into the surroundings of the nanostructures, resulting in photocurrent, or they can interact with adjacent molecules and media, inducing photochemical transformations. Understanding the dynamics of hot carriers and related effects in plasmonic nanostructures is important for the development of ultrafast detectors and nonlinear optical components, broadband photocatalysis, enhanced nanoscale optoelectronic devices, nanoscale and ultrafast temperature control, and other technologies of tomorrow. In this review, we will discuss the fundamentals of plasmonically-engendered hot electrons, focusing on the overlooked aspects, theoretical descriptions and experimental methods to study them, and describe prototypical processes and examples of most promising applications of hot-electron processes at the metal interfaces.

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CiteScore
30.40
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