用于增强光控制的等离子体元平台

Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XIX Pub Date : 2021-08-02 DOI:10.1117/12.2594697

A. Davoyan

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引用次数: 0

摘要

在这次演讲中，我将讨论我们在等离子体纳米结构中的光限制如何导致光操纵和控制的新制度方面的工作。首先，我将讨论色散工程可能导致控制非线性光-材料相互作用的新制度，包括相位不匹配和宽带操作。我将讨论在这样的系统中经典光和量子光的产生。其次，我将重点介绍我们在磁化纳米等离子体结构研究方面的理论工作。具体来说，正如我将演示的那样，磁化与平面系统中自然存在的对称性破缺相结合，导致光传播的拓扑非平凡状态，这表现为单向传播和旋转模式。最后，我将讨论我们在超薄膜金属纳米结构中的光吸收实验工作及其在光电子学方面的潜在应用。

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Plasmonic metaplatforms for enhanced light control

In this talk I will discuss our work on the way light confinement within plasmonic nanostructures leads to new regimes of light manipulation and control. Firstly, I will discuss the way dispersion engineering may lead to new regimes for controlling nonlinear light-material interaction, including phase mismatch-free and broadband operation. I will discuss generation of classical and quantum light in such systems. Secondly, I will highlight our theoretical works on the study of magnetized nanoplasmonic structures. Specifically, as I will demonstrate magnetization combined with the symmetry breaking naturally available in plamonic systems leads to topologically nontrivial regimes of light propagation, which is manifested in one-way propagating and rotating modes. Lastly, I will discuss our experimental work on light absorption within ultrathin film metallic nanostructures and potential applications for optoelectronics.

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来源期刊

Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XIX

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