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集成光子学中的超连续谱:产生、应用、挑战与展望。

Supercontinuum in integrated photonics: generation, applications, challenges, and perspectives.

作者信息

Brès Camille-Sophie, Della Torre Alberto, Grassani Davide, Brasch Victor, Grillet Christian, Monat Christelle

机构信息

Photonic Systems Laboratory (PHOSL), Ecole Polytechnique Fédérale de Lausanne, 1015 Lausanne, Switzerland.

Université de Lyon, Institut des Nanotechnologies de Lyon (INL) UMR CNRS 5270, Ecole Centrale de Lyon, 69131 Ecully, France.

出版信息

Nanophotonics. 2023 Mar 1;12(7):1199-1244. doi: 10.1515/nanoph-2022-0749. eCollection 2023 Apr.

DOI:10.1515/nanoph-2022-0749
PMID:36969949
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10031268/
Abstract

Frequency conversion in nonlinear materials is an extremely useful solution to the generation of new optical frequencies. Often, it is the only viable solution to realize light sources highly relevant for applications in science and industry. In particular, supercontinuum generation in waveguides, defined as the extreme spectral broadening of an input pulsed laser light, is a powerful technique to bridge distant spectral regions based on single-pass geometry, without requiring additional seed lasers or temporal synchronization. Owing to the influence of dispersion on the nonlinear broadening physics, supercontinuum generation had its breakthrough with the advent of photonic crystal fibers, which permitted an advanced control of light confinement, thereby greatly improving our understanding of the underlying phenomena responsible for supercontinuum generation. More recently, maturing in fabrication of photonic integrated waveguides has resulted in access to supercontinuum generation platforms benefiting from precise lithographic control of dispersion, high yield, compact footprint, and improved power consumption. This Review aims to present a comprehensive overview of supercontinuum generation in chip-based platforms, from underlying physics mechanisms up to the most recent and significant demonstrations. The diversity of integrated material platforms, as well as specific features of waveguides, is opening new opportunities, as will be discussed here.

摘要

非线性材料中的频率转换是产生新光频率的一种极其有用的方法。通常,它是实现与科学和工业应用高度相关的光源的唯一可行方法。特别是,波导中的超连续谱产生,定义为输入脉冲激光的极端光谱展宽,是一种基于单程几何结构跨越遥远光谱区域的强大技术,无需额外的种子激光器或时间同步。由于色散对非线性展宽物理过程的影响,随着光子晶体光纤的出现,超连续谱产生取得了突破,光子晶体光纤允许对光限制进行先进控制,从而极大地增进了我们对超连续谱产生背后现象的理解。最近,光子集成波导制造技术的成熟,带来了超连续谱产生平台,这些平台受益于对色散的精确光刻控制、高成品率、紧凑的占地面积和更低的功耗。本综述旨在全面概述基于芯片的平台中的超连续谱产生,从其基本物理机制到最新和最重要的演示。集成材料平台的多样性以及波导的特定特性正在带来新的机遇,将在此进行讨论。

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