Foundations of Plasmonics

IF 35 1区 物理与天体物理 Q1 PHYSICS, CONDENSED MATTER
Yang Wang, E. W. Plummer, K. Kempa
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引用次数: 118

Abstract

Plasma physics is a very mature field, studied extensively for well over a century. The cross-disciplinary field of plasmonics (electromagnetics of metallic nanostructures), on the other hand, with its potential for an extraordinary light control through novel class of materials and the resulting applications, has become very fashionable only recently. Inevitably, as a result of this rapid development, the deep connections with the mother discipline, the plasma physics, have sometimes been overlooked. The goal of this work is to review some of these basic connections, which are relevant, and ultimately helpful for researchers in the new field. We focus on the solid-state structured plasmas and address the issue of classical versus quantum treatments. We discuss the little known subtleties of the surface plasmons at metallic surfaces (e.g. multipole plasmons) and their consequences on plasmonics of the textured metallic films. Plasmonics of nanoparticles has been preceded by studies of plasma effects in metallic clusters and semiconducting quantum dots (QDs). In this context, we discuss the little known connection between the Mie resonance in metallic particles and the collective resonance in wide parabolic quantum wells (QWs) and QDs. Researchers dealing with plasmonics of thin films can benefit from earlier studies of plasmons in the semiconductor modulation doped heterojunctions and QWs, with its rich spectrum of intersubband and two-dimensional plasmons. In non-equilibrium plasmonic systems, generation of plasmons can be stimulated, leading to the exciting possibility of the plasmon instability. Extraordinarily complex is the plasmonics of carbon nanotubes and graphene, with its numerous van Hove, one- and three-dimensional plasmons, and we discuss how the plasmonics of metamaterials can benefit from this complexity. Finally, we discuss a few applications, which could directly benefit from plasmonics, including medical and the novel class of solar cells.
等离子体基础
等离子体物理学是一个非常成熟的领域,已经被广泛研究了一个多世纪。另一方面,等离子体电磁学(金属纳米结构的电磁学)的跨学科领域,通过新型材料和由此产生的应用,具有非凡的光控制潜力,直到最近才变得非常流行。不可避免的是,由于这种快速发展,它与母学科等离子体物理学的深刻联系有时被忽视了。这项工作的目的是回顾这些基本的联系,这些联系是相关的,并最终对新领域的研究人员有所帮助。我们专注于固态结构等离子体,并解决经典与量子处理的问题。我们讨论了金属表面等离子体的鲜为人知的微妙之处(如多极等离子体)及其对金属薄膜等离子体的影响。在研究纳米粒子的等离子体动力学之前,研究了金属团簇和半导体量子点(QDs)中的等离子体效应。在此背景下,我们讨论了金属粒子中的Mie共振与宽抛物量子阱(QWs)和QDs中的集体共振之间鲜为人知的联系。研究薄膜等离子体的研究人员可以从半导体调制掺杂异质结和量子阱中等离子体的早期研究中受益,因为它们具有丰富的亚带间等离子体和二维等离子体谱。在非平衡等离子体系统中,等离子体的产生可以被激发,从而导致等离子体不稳定的激发可能性。碳纳米管和石墨烯的等离子体非常复杂,具有众多的范霍夫、一维和三维等离子体,我们讨论了超材料的等离子体如何从这种复杂性中受益。最后,我们讨论了一些可以直接受益于等离子体的应用,包括医疗和新型太阳能电池。
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来源期刊
Advances in Physics
Advances in Physics 物理-物理:凝聚态物理
CiteScore
67.60
自引率
0.00%
发文量
1
期刊介绍: Advances in Physics publishes authoritative critical reviews by experts on topics of interest and importance to condensed matter physicists. It is intended for motivated readers with a basic knowledge of the journal’s field and aims to draw out the salient points of a reviewed subject from the perspective of the author. The journal''s scope includes condensed matter physics and statistical mechanics: broadly defined to include the overlap with quantum information, cold atoms, soft matter physics and biophysics. Readership: Physicists, materials scientists and physical chemists in universities, industry and research institutes.
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