非线性谐振光子学中的时间耦合模式理论:从基本原理到二维材料、色散、损耗和增益的现代系统

Thomas Christopoulos, Odysseas Tsilipakos, Emmanouil E. Kriezis
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摘要

时间耦合模式理论(CMT)是一种广受赞誉和广泛应用的理论框架,用于对任何集成或自由空间光子谐振结构的连续波(CW)响应和时间动态进行建模。在其问世后的 30 年中,CMT 的应用范围不断扩大,也可用于描述各种非线性相互作用(自相位和跨相位调制、可饱和吸收、频率产生、增益等)。在本教程中,我们将全面介绍 CMT 的基本原理和多年来的发展历程,展示其在分析和设计线性和非线性谐振光子系统方面的巨大能力。重要的是,我们将重点放在现代开放式纳米光子谐振器的例子上,这些谐振器采用了当代的块状或片状(2D)材料,可能具有损耗和色散特性。对于所研究的每一种线性/非线性效应,我们都采用细致入微、循序渐进的方法,从建立物理现象的精确模型开始,到将其引入 CMT 框架,再到有效求解所产生的方程组。我们的工作凸显了 CMT 作为一种高效、精确和多功能理论工具的优点。我们希望这本书既可以作为任何读者的入门参考书,也可以作为一本全面的手册,介绍如何将广泛的线性和非线性效应纳入 CMT 框架。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Temporal coupled-mode theory in nonlinear resonant photonics: From basic principles to contemporary systems with 2D materials, dispersion, loss, and gain
Temporal coupled-mode theory (CMT) is an acclaimed and widely used theoretical framework for modeling the continuous wave (CW) response and temporal dynamics of any integrated or free-space photonic resonant structure. It was initially employed to understand how energy is coupled into and out of a cavity and how it is exchanged between different resonant modes. In the 30 years that followed its establishment, CMT has been expanded to describe a broad range of nonlinear interactions as well (self- and cross-phase modulation, saturable absorption, frequency generation, gain, etc.). In this tutorial, we thoroughly present the basic principles and the evolution of CMT throughout the years, showcasing its immense capabilities for the analysis and design of linear and nonlinear resonant photonic systems. Importantly, we focus on examples of modern, open nanophotonic resonators incorporating contemporary bulk or sheet (2D) materials that may be lossy and dispersive. For each linear/nonlinear effect under study we follow a meticulous, step-by-step approach, starting from an accurate model of the physical phenomenon and proceeding to its introduction in the CMT framework all the way to the efficient solution of the resulting system of equations. Our work highlights the merits of CMT as an efficient, accurate, and versatile theoretical tool. We envision that it can serve both as an introductory reference for any reader, as well as a comprehensive handbook on how to incorporate a broad range of linear and nonlinear effects in the CMT framework.
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