Intracavity spatiotemporal metasurfaces

IF 20.6 1区 物理与天体物理 Q1 OPTICS
Wenhe Jia, Chenxin Gao, Yongmin Zhao, Liu Li, Shun Wen, Shuai Wang, C. Bao, C. Jiang, Changxi Yang, Yuanmu Yang
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引用次数: 7

Abstract

Abstract. Optical metasurfaces are endowed with unparallel flexibility to manipulate the light field with a subwavelength spatial resolution. Coupling metasurfaces to materials with strong optical nonlinearity may allow ultrafast spatiotemporal light field modulation. However, most metasurfaces demonstrated thus far are linear devices. Here, we experimentally demonstrate simultaneous spatiotemporal laser mode control using a single-layer plasmonic metasurface strongly coupled to an epsilon-near-zero (ENZ) material within a fiber laser cavity. While the geometric phase of the metasurface is utilized to convert the laser’s transverse mode from a Gaussian beam to a vortex beam carrying orbital angular momentum, the giant nonlinear saturable absorption of the ENZ material enables pulsed laser generation via the Q-switching process. The direct integration of a spatiotemporal metasurface in a laser cavity may pave the way for the development of miniaturized laser sources with tailored spatial and temporal profiles, which can be useful for numerous applications, such as superresolution imaging, high-density optical storage, and three-dimensional laser lithography.
腔内时空超表面
摘要光学超表面被赋予了无与伦比的灵活性,可以以亚波长的空间分辨率操纵光场。将超表面耦合到具有强光学非线性的材料可以允许超快的时空光场调制。然而,迄今为止演示的大多数元表面都是线性设备。在这里,我们通过实验证明了使用单层等离子体元表面与光纤激光腔内的ε近零(ENZ)材料强耦合的同时时空激光模式控制。虽然超表面的几何相位用于将激光的横模从高斯光束转换为携带轨道角动量的涡旋光束,但ENZ材料的巨大非线性可饱和吸收使得能够通过Q开关过程产生脉冲激光。时空超表面在激光腔中的直接集成可以为开发具有定制的空间和时间轮廓的小型化激光源铺平道路,这可以用于许多应用,如超分辨率成像、高密度光学存储和三维激光光刻。
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来源期刊
CiteScore
22.70
自引率
1.20%
发文量
49
审稿时长
18 weeks
期刊介绍: Advanced Photonics is a highly selective, open-access, international journal that publishes innovative research in all areas of optics and photonics, including fundamental and applied research. The journal publishes top-quality original papers, letters, and review articles, reflecting significant advances and breakthroughs in theoretical and experimental research and novel applications with considerable potential. The journal seeks high-quality, high-impact articles across the entire spectrum of optics, photonics, and related fields with specific emphasis on the following acceptance criteria: -New concepts in terms of fundamental research with great impact and significance -State-of-the-art technologies in terms of novel methods for important applications -Reviews of recent major advances and discoveries and state-of-the-art benchmarking. The journal also publishes news and commentaries highlighting scientific and technological discoveries, breakthroughs, and achievements in optics, photonics, and related fields.
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