化学机械平面化
联轴节(管道)
光电子学
材料科学
光纤
超短脉冲
非线性系统
领域(数学)
纤维
光学
饱和吸收
近场和远场
光纤激光器
制作
消散波
非线性光学
物理
激光器
超透镜
纳米技术
电磁场
工作(物理)
近场光学
孤子
宽带
作者
Chao Zeng,Ding Luo,Xiaotong Zhang,B. Zhang,Jincheng Hu,Ruixue Si,Chenxu Liu,Chenyang Zhao,Xin Xie,Yueqing Du,Xuetao Gan,Jianlin Zhao,Yanxiao Sun,Dong Mao
标识
DOI:10.1002/lpor.202502639
摘要
ABSTRACT Metafibers, optical fibers integrated with metasurfaces, have recently emerged as a transformative platform for miniaturized fiber‐optic components with advanced functionalities. However, existing metafibers are largely limited to fiber tip integration, where metasurfaces interact dominantly with localized guided modes, thus failing to exploit the inherent potential of fiber sidewalls for long‐range evanescent field interaction. Here, we propose a novel metafiber paradigm—integrating metasurfaces on planarized fiber sidewalls—to fully harness the evanescent field mechanism. To this end, we develop a robust in situ fabrication method via a fiber‐substrate planarization strategy, enabling direct, large‐area, and high‐fidelity metasurface patterning on side‐polished fibers (SPFs). Numerical simulations reveal that long‐range resonant near‐field coupling drives cumulative amplification of the evanescent field within the metasurface layer, leading to significant enhancement of both linear and nonlinear optical responses. As a proof of concept, we present a nonlinear metafiber by integrating a 1‐cm‐long gold nanorod‐based metasurface onto an SPF, demonstrating a high‐performance saturable absorber (SA). This metafiber SA enables all‐fiber ultrafast lasers across all soliton regimes with ultralow mode‐locking thresholds. This work establishes a universal methodology for planarized sidewall‐integrated metafibers, reshaping the landscape of metafibers, and provides a versatile lab‐on‐fiber platform for enhanced linear and nonlinear optics.
科研通智能强力驱动
Strongly Powered by AbleSci AI