光学纳米结构中的结构光-物质相互作用(演讲记录)

N. Litchinitser, Jingbo Sun, M. Shalaev, T. Xu, Yun Xu, A. Pandey
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引用次数: 1

摘要

我们表明,超材料独特的光学特性为“工程”光本身打开了无限的前景。例如,我们展示了一种利用超材料在少模光纤中进行复杂光操纵的新方法,强调了超材料的独特特性,即操纵电场和磁场分量的能力,为工程复杂的光偏振状态开辟了新的自由度。我们讨论了几种超紧凑结构光产生的方法,包括基于超紧凑纳米波导阵列的纳米级光束转换器,其通道直径呈圆形梯度分布,可将传统激光束转换为具有可配置轨道角动量的涡流。基于单一双轴双曲超材料的小型化像散光学元件,能够将厄米高斯光束转换为携带轨道角动量的涡旋光束,反之亦然。这种光束转换器很可能实现新一代片上或全光纤结构光的应用。我们还提出了我们的初步理论研究,预测基于涡流的非线性光学过程,如二次谐波产生或依赖于相位匹配的参数放大,也将在负折射率材料中得到强烈的改变。这些研究可能会发现多维信息编码、安全通信和量子密码学的应用,因为自旋和轨道角动量都可以用来编码信息;自发参数下转换的色散工程以及片上光电信号处理。
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Structured light-matter interactions in optical nanostructures (Presentation Recording)
We show that unique optical properties of metamaterials open unlimited prospects to “engineer” light itself. For example, we demonstrate a novel way of complex light manipulation in few-mode optical fibers using metamaterials highlighting how unique properties of metamaterials, namely the ability to manipulate both electric and magnetic field components, open new degrees of freedom in engineering complex polarization states of light. We discuss several approaches to ultra-compact structured light generation, including a nanoscale beam converter based on an ultra-compact array of nano-waveguides with a circular graded distribution of channel diameters that coverts a conventional laser beam into a vortex with configurable orbital angular momentum and a novel, miniaturized astigmatic optical element based on a single biaxial hyperbolic metamaterial that enables the conversion of Hermite-Gaussian beams into vortex beams carrying an orbital angular momentum and vice versa. Such beam converters is likely to enable a new generation of on-chip or all-fiber structured light applications. We also present our initial theoretical studies predicting that vortex-based nonlinear optical processes, such as second harmonic generation or parametric amplification that rely on phase matching, will also be strongly modified in negative index materials. These studies may find applications for multidimensional information encoding, secure communications, and quantum cryptography as both spin and orbital angular momentum could be used to encode information; dispersion engineering for spontaneous parametric down-conversion; and on-chip optoelectronic signal processing.
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