Hexagonal-inner-cladding fluorotellurite fiber based on hot-extrusion

IF 3.1 3区 物理与天体物理 Q2 INSTRUMENTS & INSTRUMENTATION
Weisheng Xu , Hepan Zhu , Zhichao Fan , Shengchuang Bai , Shixun Dai , Qiuhua Nie , Xunsi Wang
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Abstract

Laser output power can be significantly enhanced by a double-cladding fiber, as it possesses a large area of inner-cladding for pumping. However, the coupling efficiency of the double-cladding fiber (DCF) is impacted by the shape of the inner cladding. In this study, the simulation results showed that, the hexagonal inner cladding fiber exhibits the highest absorption efficiency of 94.07 % among the fibers with various typical shapes using the three-dimensional ray tracing method at a length of 100 mm. For the experiments, a type of fluorotellurite (TBY, TeO2-BaF2-Y2O3) glass was chosen for its high capacity of rare-earth ions adoption. Subsequently, a finely structured erbium-doped hexagonal DCF was fabricated based on the hot-extrusion method for the first time, with a minimum loss of 1.25 dB/m at 1310 nm. Additionally, the coupling efficiency of the hexagonal DCF was recorded to be 39.47 % at a fiber length of 53 cm, based on the energy distribution experiment. The damage threshold of the hexagonal DCF at 980 nm could be increased to above 26.5 W, nearly doubling that of the single-cladding fiber. Furthermore, a wider fluorescence spectrum with a full width at half maximum (FWHM) of 30 nm was demonstrated by the hexagonal double-cladding fiber, which indicates its potential for high-power laser applications.
基于热挤压技术的六边形内包层碲氟石光纤
双包层光纤具有大面积的内包层,可用于泵浦,因此可显著提高激光输出功率。然而,双包层光纤(DCF)的耦合效率会受到内包层形状的影响。在这项研究中,模拟结果表明,使用三维光线追踪方法,在长度为 100 毫米的各种典型形状的光纤中,六角形内包层光纤的吸收效率最高,达到 94.07%。在实验中,选择了一种氟碲玻璃(TBY,TeO2-BaF2-Y2O3),因为它具有很高的稀土离子吸收能力。随后,基于热挤压方法首次制造出了结构精细的掺铒六边形 DCF,其在 1310 纳米波长处的最小损耗为 1.25 dB/m。此外,根据能量分布实验,在光纤长度为 53 厘米时,六边形 DCF 的耦合效率为 39.47%。六边形 DCF 在 980 纳米波长的损伤阈值可提高到 26.5 W 以上,几乎是单包层光纤的两倍。此外,六边形双包层光纤的荧光光谱更宽,半最大全宽(FWHM)为 30 nm,这表明它具有应用于高功率激光的潜力。
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来源期刊
CiteScore
5.70
自引率
12.10%
发文量
400
审稿时长
67 days
期刊介绍: The Journal covers the entire field of infrared physics and technology: theory, experiment, application, devices and instrumentation. Infrared'' is defined as covering the near, mid and far infrared (terahertz) regions from 0.75um (750nm) to 1mm (300GHz.) Submissions in the 300GHz to 100GHz region may be accepted at the editors discretion if their content is relevant to shorter wavelengths. Submissions must be primarily concerned with and directly relevant to this spectral region. Its core topics can be summarized as the generation, propagation and detection, of infrared radiation; the associated optics, materials and devices; and its use in all fields of science, industry, engineering and medicine. Infrared techniques occur in many different fields, notably spectroscopy and interferometry; material characterization and processing; atmospheric physics, astronomy and space research. Scientific aspects include lasers, quantum optics, quantum electronics, image processing and semiconductor physics. Some important applications are medical diagnostics and treatment, industrial inspection and environmental monitoring.
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