Infrared imaging with nonlinear silicon resonator governed by high-Q quasi-BIC states

IF 2 4区物理与天体物理 Q3 OPTICS

Journal of Optics Pub Date : 2024-05-12 DOI:10.1088/2040-8986/ad44a9

Gabriel Sanderson, Ze Zheng, Elizaveta Melik-Gaykazyan, George S D Gordon, Richard Cousins, Cuifeng Ying, Mohsen Rahmani and Lei Xu

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引用次数: 0

Abstract

Nonlinear light-matter interactions have emerged as a promising platform for various applications, including imaging, nanolasing, background-free sensing, etc. Subwavelength dielectric resonators offer unique opportunities for manipulating light at the nanoscale and miniturising optical elements. Here, we explore the resonantly enhanced four-wave mixing (FWM) process from individual silicon resonators and propose an innovative FWM-enabled infrared imaging technique that leverages the capabilities of these subwavelength resonators. Specifically, we designed high-Q silicon resonators hosting dual quasi-bound states in the continuum at both the input pump and signal beams, enabling efficient conversion of infrared light to visible radiation. Moreover, by employing a point-scanning imaging technique, we achieve infrared imaging conversion while minimising the dependence on high-power input sources. This combination of resonant enhancement and point-scanning imaging opens up new possibilities for nonlinear imaging using individual resonators and shows potential in advancing infrared imaging techniques for high-resolution imaging, sensing, and optical communications.

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利用由高 Q 值准 BIC 状态支配的非线性硅谐振器进行红外成像

非线性光-物质相互作用已成为成像、纳米激光、无背景传感等各种应用的理想平台。亚波长介质谐振器为在纳米尺度上操纵光和微型化光学元件提供了独特的机会。在此，我们探索了单个硅谐振器的共振增强四波混合（FWM）过程，并提出了一种利用这些亚波长谐振器功能的创新型 FWM 红外成像技术。具体来说，我们设计的高 Q 硅谐振器在输入泵浦光束和信号光束的连续体中承载了双准束缚态，从而实现了红外光到可见光辐射的高效转换。此外，通过采用点扫描成像技术，我们实现了红外成像转换，同时最大限度地减少了对高功率输入源的依赖。这种共振增强与点扫描成像的结合为使用单个谐振器进行非线性成像开辟了新的可能性，并显示出在推进红外成像技术用于高分辨率成像、传感和光通信方面的潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Optics OPTICS-

CiteScore

4.50

自引率

4.80%

发文量

237

审稿时长

1.9 months

期刊介绍： Journal of Optics publishes new experimental and theoretical research across all areas of pure and applied optics, both modern and classical. Research areas are categorised as: Nanophotonics and plasmonics Metamaterials and structured photonic materials Quantum photonics Biophotonics Light-matter interactions Nonlinear and ultrafast optics Propagation, diffraction and scattering Optical communication Integrated optics Photovoltaics and energy harvesting We discourage incremental advances, purely numerical simulations without any validation, or research without a strong optics advance, e.g. computer algorithms applied to optical and imaging processes, equipment designs or material fabrication.