Metamaterial, plasmonic and nanophotonic devices

IF 19 1区 物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY Reports on Progress in Physics Pub Date : 2017-02-06 DOI:10.1088/1361-6633/aa518f
F. Monticone, A. Alú
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引用次数: 145

Abstract

The field of metamaterials has opened landscapes of possibilities in basic science, and a paradigm shift in the way we think about and design emergent material properties. In many scenarios, metamaterial concepts have helped overcome long-held scientific challenges, such as the absence of optical magnetism and the limits imposed by diffraction in optical imaging. As the potential of metamaterials, as well as their limitations, become clearer, these advances in basic science have started to make an impact on several applications in different areas, with far-reaching implications for many scientific and engineering fields. At optical frequencies, the alliance of metamaterials with the fields of plasmonics and nanophotonics can further advance the possibility of controlling light propagation, radiation, localization and scattering in unprecedented ways. In this review article, we discuss the recent progress in the field of metamaterials, with particular focus on how fundamental advances in this field are enabling a new generation of metamaterial, plasmonic and nanophotonic devices. Relevant examples include optical nanocircuits and nanoantennas, invisibility cloaks, superscatterers and superabsorbers, metasurfaces for wavefront shaping and wave-based analog computing, as well as active, nonreciprocal and topological devices. Throughout the paper, we highlight the fundamental limitations and practical challenges associated with the realization of advanced functionalities, and we suggest potential directions to go beyond these limits. Over the next few years, as new scientific breakthroughs are translated into technological advances, the fields of metamaterials, plasmonics and nanophotonics are expected to have a broad impact on a variety of applications in areas of scientific, industrial and societal significance.
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超材料、等离子体和纳米光子器件
超材料领域为基础科学开辟了广阔的前景,也为我们思考和设计新兴材料特性的方式带来了范式转变。在许多情况下,超材料概念有助于克服长期存在的科学挑战,例如光磁性的缺乏和光学成像中衍射所施加的限制。随着超材料的潜力及其局限性变得越来越清晰,这些基础科学的进步已经开始对不同领域的几个应用产生影响,对许多科学和工程领域产生深远的影响。在光学频率上,超材料与等离子体场和纳米光子学的结合可以以前所未有的方式进一步推进控制光传播、辐射、局部化和散射的可能性。在这篇综述文章中,我们讨论了近年来在超材料领域的进展,特别侧重于该领域的基本进展如何使新一代的超材料、等离子体和纳米光子器件成为可能。相关的例子包括光学纳米电路和纳米天线、隐形斗篷、超散射体和超吸收体、用于波前整形和基于波的模拟计算的超表面,以及有源、非互易和拓扑器件。在整篇论文中,我们强调了与实现高级功能相关的基本限制和实际挑战,并提出了超越这些限制的潜在方向。在接下来的几年里,随着新的科学突破转化为技术进步,超材料、等离子体和纳米光子学领域有望对科学、工业和社会意义领域的各种应用产生广泛的影响。
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来源期刊
Reports on Progress in Physics
Reports on Progress in Physics 物理-物理:综合
CiteScore
31.90
自引率
0.00%
发文量
45
审稿时长
6-12 weeks
期刊介绍: Reports on Progress in Physics is a highly selective journal with a mission to publish ground-breaking new research and authoritative invited reviews of the highest quality and significance across all areas of physics and related areas. Articles must be essential reading for specialists, and likely to be of broader multidisciplinary interest with the expectation for long-term scientific impact and influence on the current state and/or future direction of a field.
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