Fabrication and Performance of a Heterogeneous-Helical-Cladding Fiber

Xiao, Sun; Yang, Zijun; Chen, Sheng; Yang, Guangli; Zhang, Liaolin; Wei, Wei

doi:10.1109/jphot.2021.3103668

Cited by 4 publications

(2 citation statements)

References 20 publications

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“…Another approach to solving the problem of obtaining fiber 3D structures is the use of twisted fibers, either with an initially standard refractive index 10,11 or already undergone a certain processing. The latter, in particular, can be understood as an optical fiber with a periodic structure made in its core by ultraviolet burning, i.e.…”

Section: Analysis Of Known Approaches To the Practical Implementation...mentioning

confidence: 99%

On the problem of forming a 3D refractive index profile in a fiber and compatible components and possible solutions

Vinogradova,

Meshkov,

Gizatulin

et al. 2023

Optical Technologies for Telecommunications 2022

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The article is devoted to the study of issues related to the developments of methods for manufacturing 3D refractive index profiled fiber and fiber-compatible structures. Based on the results of the analysis of published works, it was established that there are no tested approaches with generality to solving this problem. Therefore, the method proposed by the authors seems relevant, which can be classified as a technique for bulk transformation of material properties, which makes it possible to approximately select, and then adjust (with refinement) the volumetric refractive index profile of the selected area to the simulated value. In this article, the authors present the results of the formation of a guiding structure along the boundary of a profiled area. The method of three-beam UV burning and the method of focused ion burning were studied. It has been found that in the second case, significant differences in the refractive index can be obtained. Therefore, the second method may be of interest for the manufacture of large-sized components.

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Section: Analysis Of Known Approaches To the Practical Implementation...mentioning

confidence: 99%

On the problem of forming a 3D refractive index profile in a fiber and compatible components and possible solutions

Vinogradova,

Meshkov,

Gizatulin

et al. 2023

Optical Technologies for Telecommunications 2022

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“…Increasing the size of the mode field is the most efficient technique to address this issue of high power density. Nevertheless, it introduces negative impacts including poor beam quality and an increase in high-order modes (HOMs) [11] . 1 China(e-mail: shenx@njupt.edu.cn; 464189489@qq.com; kongmm@ njupt.edu.cn; weiwei@njupt.edu.cn).…”

Section: Introductionmentioning

confidence: 99%

Investigation of a Large-Mode-Area Fiber Designed for 2.0 μm Based on Multi-Layer Holes Resonance

Shen,

Sun,

Kong

et al. 2023

IEEE Photonics J.

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This work proposes a novel large mode area fiber with multi-layer holes of 2.0 μm based on electromagnetic field theory and finite element analysis. Modifying the structure parameters can reduce the fundamental mode confinement loss to less than 0.1 dB/m, and the lowest high-order mode confinement loss may be greater than 10.0 dB/m. The fiber has exceptional single-mode transmission performance due to its high loss ratio. The effective mode field area is 3849 μm 2 , and the single mode core diameter is 80.0 μm. To obtain a larger mode field diameter, the construction used here includes a smaller cladding diameter in the already available large mode field fiber. The cladding parameters may be changed independently, making it convenient and adaptable to obtain the best simulation results. Compared to the large-mode field fiber standard, which has excellent single mode operation performance, the loss ratio of this design is substantially larger. Additionally, it can effectively sustain single mode operation when the wavelength shifts from 1.65 to 2.10 μm, which is advantageous for developing 2.0 μm fiber lasers.

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Mode transmission performance study of a novel heterogeneous helical cladding fiber with an isolation ring

Shen,

Zhou,

2024

Opt Quant Electron

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Fabrication and Performance of a Heterogeneous-Helical-Cladding Fiber

Cited by 4 publications

References 20 publications

On the problem of forming a 3D refractive index profile in a fiber and compatible components and possible solutions

On the problem of forming a 3D refractive index profile in a fiber and compatible components and possible solutions

Investigation of a Large-Mode-Area Fiber Designed for 2.0 μm Based on Multi-Layer Holes Resonance

Mode transmission performance study of a novel heterogeneous helical cladding fiber with an isolation ring

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