利用氧化锌纳米结构定制二次谐波发射:增强方向性

IF 1.9 4区 物理与天体物理 Q3 OPTICS
E. Petronijevic
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引用次数: 0

摘要

在纳米尺度上定制非线性光学特性是当今纳米光子学的热门话题,有望应用于从传感到超快光通信等多个领域。在这里,我们介绍了一种设计简单半导体纳米结构的数值方法,这种结构能够定制近场和远场的二次谐波发射。我们从氧化锌纳米球的线性模拟入手,揭示了散射的多极性质。接着,我们展示了同样的纳米球在 800 纳米波长下激发时如何操纵发射的二次谐波的指向性。我们观察到,在 400 纳米波长下表现出 Kerker 条件的纳米球会在正向发射二次谐波场。我们进一步研究了不对称(椭圆体几何形状)如何调整二次谐波的指向性。最后,我们引入了具有低旋光响应的几何形状,并观察到二次谐波远场取决于 800 纳米波长处激发纳米结构的光的手性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Tailoring second harmonic emission by ZnO nanostructures: enhancement of directionality
Tailoring nonlinear optical properties at the nanoscale is a hot topic in nowadays nanophotonics, promising for applications spanning from sensing to ultrafast optical communications. Here we present a numerical approach of designing a simple semiconductor nanostructure able to tailor second harmonic emission in the near- and far-field. We start from linear simulations of ZnO nanospheres, which reveal multipolar nature of the scattering. Next, we show how the same nanospheres, excited at 800 nm, manipulate the directivity of the emitted second harmonic. We observe that the nanospheres which exhibit Kerker condition at 400 nm, emit the second harmonic field in the forward direction. We further investigate how the asymmetry (ellipsoid geometry) tailors the second harmonic directivity. We finally introduce geometry with low chiro-optical response, and observe that the second harmonic far-field depends on the handedness of the light exciting the nanostructure at 800 nm.
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来源期刊
CiteScore
2.40
自引率
0.00%
发文量
12
审稿时长
5 weeks
期刊介绍: Rapid progress in optics and photonics has broadened its application enormously into many branches, including information and communication technology, security, sensing, bio- and medical sciences, healthcare and chemistry. Recent achievements in other sciences have allowed continual discovery of new natural mysteries and formulation of challenging goals for optics that require further development of modern concepts and running fundamental research. The Journal of the European Optical Society – Rapid Publications (JEOS:RP) aims to tackle all of the aforementioned points in the form of prompt, scientific, high-quality communications that report on the latest findings. It presents emerging technologies and outlining strategic goals in optics and photonics. The journal covers both fundamental and applied topics, including but not limited to: Classical and quantum optics Light/matter interaction Optical communication Micro- and nanooptics Nonlinear optical phenomena Optical materials Optical metrology Optical spectroscopy Colour research Nano and metamaterials Modern photonics technology Optical engineering, design and instrumentation Optical applications in bio-physics and medicine Interdisciplinary fields using photonics, such as in energy, climate change and cultural heritage The journal aims to provide readers with recent and important achievements in optics/photonics and, as its name suggests, it strives for the shortest possible publication time.
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