具有局部时间响应的等离子体纳米结构:时变光子学的平台

A. Kharitonov, A. I. Minibaev, S. Kharintsev
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引用次数: 0

摘要

时变介质为控制电磁场开辟了前所未有的能力。这是由于当介质的一个光学参数在时间上突然切换时,产生了新型的光-物质相互作用。后者意味着开关时间短于波的振荡周期。这一要求使得在光学光谱范围内实现适合应用的时变材料变得具有挑战性。这项工作致力于发展一种实现具有大深度和调制速度的折射率时变介质的方法。我们开发了一个系统,由等离子体天线耦合到具有epsilon-near-zero (ENZ)特性的非线性材料。由脉冲激光激发调制的等离子体- enz混合结构是时变光子学研究的一个很有前途的平台。然而,等离子体元件的光学响应通常很慢,在10-100 fs的数量级上。这源于等离子体激发的长寿命。在这里,我们提出了一种机制,允许人们实现超短,小于1秒,等离子体寿命。其机理是基于介电常数实部色散的减小。为此,我们使用了氧氮化钛(TiOxNy),这是一种具有可调谐光学特性的等离子体材料。我们利用不同的磁控溅射参数合成了一系列的TiOxNy薄膜。这使我们实现了一种独特的行为,如在近红外范围内宽带平色散的介电函数。在这些条件下,光响应在时间上变成局部的。本研究结果为时变介质光子器件的设计和实际实现提供了新的机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Plasmonic nanostructures with local temporal response: a platform for time-varying photonics
Time-varying media open up unprecedented abilities for controlling electromagnetic fields. This is due to novel forms of light-matter interactions that arise when one of the optical parameters of the medium is abruptly switched in time. The latter means that the switching time is shorter than the period of wave oscillations. This requirement makes it challenging to implement time-varying materials suitable for applications in the optical spectral range. This work is devoted to the development of an approach for implementing time-varying media with a large depth and speed of modulation of the refractive index. We exploit a system, consisting of plasmonic antennas coupled to nonlinear material with epsilon-near-zero (ENZ) properties. Hybrid plasmonic-ENZ structures modulated by pulsed laser excitation have been recently proposed as a promising platform for time-varying photonics. However, the optical response of plasmonic components is typically slow, on the order of 10-100 fs. This stems from the long lifetime of plasmonic excitations. Here, we propose a mechanism that allows one to achieve an ultrashort, less than 1 fs, plasmon lifetime. The mechanism is based on reducing of the spectral dispersion of the real part of permittivity. For this purpose, we used titanium oxynitride (TiOxNy), which represents a plasmonic material with tunable optical properties. We synthesized a series of TiOxNy thin films using various parameters of magnetron sputtering. This allowed us to achieve a unique behavior, such as broadband flat dispersion of the dielectric function in the near-infrared range. Under these conditions, the optical response becomes local in time. The results of this study provide novel opportunities for designing and practical implementation of photonic devices based on time-varying media.
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