飞秒激光直接写入光纤布拉格光栅的高速高分辨率扫描技术

IF 3.1 3区物理与天体物理 Q2 Engineering

Optik Pub Date : 2025-02-01 DOI:10.1016/j.ijleo.2024.172168

Hun-Kook Choi , Young-Jun Jung , Bong-Ahn Yu , Yeung Lak Lee , Young-Chul Noh , Ik-Bu Sohn

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引用次数: 0

摘要

我们采用激光扫描系统和相位掩模两种制造方法来制造光纤布拉格光栅（FBG）。我们使用了微型扫描适配器，通过扫描仪和物镜在光纤内部实现高速、高分辨率的激光聚焦。在调整扫描仪重复速度的同时不断移动光纤固定平台，就能产生不同周期的微图案。这种方法可以检测多个波长的 FBG 信号。利用高速、高分辨率的激光扫描系统进行激光直写，有助于产生 FBG，而无需去除光纤涂层。这种方法提供了一种通过调整扫描仪和平台移动速度来控制 FBG 波长、信号强度和带宽的直接方法。与传统方法相比，使用飞秒激光制造 FBG 还具有降低材料依赖性的额外优势，无需额外的加工步骤即可在各种光纤中制造 FBG。

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Femtosecond laser direct writing of Fiber Bragg Grating with high-speed and high-resolution scanning technique

We employed two fabrication methods, a laser scanning system and a phase mask, to produce Fiber Bragg Gratings (FBGs). A micro-scanning adapter was used to enable high-speed and high-resolution laser focusing inside the optical fiber via a scanner and an objective lens. By continuously moving the fiber-fixed stage while adjusting the scanner repetition speed, micropatterns with various periods were generated. This approach allowed for the detection of FBG signals at multiple wavelengths. Laser direct writing, utilizing a high-speed and high-resolution laser scanning system, facilitated FBG production without the need to remove the fiber coating. This method provided a straightforward way to control the FBG wavelength, signal intensity, and bandwidth by adjusting the scanner and stage movement speeds. The use of femtosecond lasers for FBG fabrication offers the additional advantage of reduced material dependence, enabling FBG production in various optical fibers without requiring additional processing steps compared to conventional methods.

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来源期刊

Optik 物理-光学

CiteScore

6.90

自引率

12.90%

发文量

1471

审稿时长

46 days

期刊介绍： Optik publishes articles on all subjects related to light and electron optics and offers a survey on the state of research and technical development within the following fields: Optics: -Optics design, geometrical and beam optics, wave optics- Optical and micro-optical components, diffractive optics, devices and systems- Photoelectric and optoelectronic devices- Optical properties of materials, nonlinear optics, wave propagation and transmission in homogeneous and inhomogeneous materials- Information optics, image formation and processing, holographic techniques, microscopes and spectrometer techniques, and image analysis- Optical testing and measuring techniques- Optical communication and computing- Physiological optics- As well as other related topics.