基于亚波长人工微结构的电磁波减反增透研究进展

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英文篇名：Antireflection coatings based on subwavelength artificial engineering microstructures 作者：姚尧 ; 沈悦 ; 郝加明 ; 戴宁 英文作者：Yao Yao;Shen Yue;Hao Jia-Ming;Dai Ning;School of Materials Science and Engineering, Shanghai University;State Key Laboratory of Infrared Physics, Shanghai Institute of Technical Physics,Chinese Academy of Sciences; 关键词：减反 ; 表面等离激元 ; 超构材料 ; 干涉相消 英文关键词：antireflection;;surface plasmons;;metamaterials;;destructive interference 中文刊名：WLXB 英文刊名：Acta Physica Sinica 机构：上海大学材料科学与工程学院;中国科学院上海技术物理研究所红外物理国家重点实验室; 出版日期：2019-07-23 出版单位：物理学报 年：2019 期：v.68 基金：国家重点基础研究发展计划(批准号:2017YFA0205800);; 国家自然科学基金(批准号:61471345);; 上海市“科技创新行动计划”(批准号:16JC1403500)资助的课题~~ 语种：中文; 页：WLXB201914015 页数：18 CN：14 ISSN：11-1958/O4 分类号：196-213

摘要

电磁波抗反射技术在太阳能电池、光学透镜、红外传感、探测器等众多应用场景中至关重要,长久以来一直是先进光学系统、光电器件研究领域热点方向之一.本文简略回顾了传统的减反的理论与方法;侧重介绍了近几年来基于亚波长人工微结构材料的电磁波减反增透相关研究进展,主要内容包括局域表面等离激元抑制光反射增强光耦合,传播表面等离激元局域共振模式诱导高透隧穿,超构材料诱导金属透明,人工微结构超表面红外、太赫兹减反等若干典型工作;探讨了亚波长人工微结构光学减反领域未来的发展方向与其所可能遇到的问题挑战.
        When light passes through an interface between two media with different refractive indices, part of light energy is reflected and thus causes an inevitable optical reflection. Optical anti-reflection is of great importance for applications in a wide range such as solar cells, optical lenses, infrared sensors, and photo-detectors, which has long been a research topic in the fields of optical systems and optoelectronic devices. In this article, the recent research progress of the optical anti-reflection based on subwavelength artificial engineering materials is reviewed. Having made a brief review of conventional anti-reflection methods, we focus on the overview of the newly developed techniques for optical anti-reflection, such as eliminating reflection by exciting the localized surface plasmons, the enhancement of transmission induced by the excitation of propagating surface plasmons,making metals transparent by the help of metamaterials, and the reduction of anti-reflection in long wavelength infrared and terahertz spectral ranges by using metasurfaces. Compared with the conventional anti-reflection methods, the new technique usually does not suffer the limitation of material, and it benefits from enhanced light absorption and wide incidence angle response. The new technique also enables the design of anti-reflection over wide or a multiple wavelength band. Finally, the future opportunities and challenges for further developing the subwavelength artificial engineering microstructures in optical anti-reflection are also predicted.

引文

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