基于对称双环嵌套管的低损耗弱耦合六模空芯负曲率光纤

惠战强; 刘瑞华; 高黎明; 韩冬冬; 李田甜; 巩稼民

doi:10.7498/aps.73.20231785

摘要

本文设计了一种具有对称双环嵌套管结构的新型低损耗少模空芯负曲率光纤, 该光纤支持LP₀₁, LP₁₁, LP₂₁, LP₀₂, LP_31a, LP_31b共6种纤芯模式. 所设计的光纤以SiO₂作为基底材料, 采用特殊的对称双环嵌套结构将包层区域进行划分, 能够有效地减小纤芯模式与包层模式的耦合. 使用有限元法对该少模空芯负曲率光纤的结构参数进行优化, 并分析了纤芯各个模式的限制损耗和弯曲损耗. 仿真结果表明, 所提出的少模空芯负曲率光纤能够同时支持弱耦合的6种纤芯模式独立传输(相邻模式间的有效折射率差均大于10^–4, 有效地避免了纤芯内模式间的耦合). 在400 nm带宽(1.23—1.63 μm, 覆盖O, E, S, C, L波段)范围内, 纤芯中的6个模式均保持低损耗稳定传输. 各模式限制损耗在1.4 μm处达到最低, 其中基模LP₀₁模式的限制损耗最低, 为4.3×10^–7 dB/m. 此外, 当弯曲半径为7 cm时, 各模式在一定工作波长范围内均保持低弯曲损耗传输. 公差分析表明, 当结构参数偏移±1%时, 该少模空芯负曲率光纤仍然可以保持低损耗弱耦合的传输特性.

关键词:

Abstract

Few-mode optical fibers have played an increasingly important role in breaking through the transmission capacity limitations of single-mode optical fiber and alleviating the bandwidth crisis in optic fiber communication systems in recent years. Nevertheless, traditional solid core few-mode optical fibers usually suffer optical fiber nonlinearity and mode coupling, leading to mode crosstalk between channels. Hollow core negative curvature fibers (HC-NCF) have attracted widespread attention due to their advantages, such as low latency, low nonlinearity, low dispersion, low transmission loss, and large operating bandwidth. In this work, a novel low-loss few-mode HC-NCF with symmetrically double ring nested tube structure is designed, which supports six core modes including LP₀₁, LP₁₁, LP₂₁, LP₀₂, LP_31a, and LP_31b. The designed optical fiber is based on silica dioxide substrate and adopts a unique symmetrical double ring nested cladding structure, which can effectively suppress the coupling between the core mode and the cladding mode. The finite element method (FDE) is used to numerically analyze the properties of the proposed few-mode HC-NCF and optimize the structural parameters of the few-mode HC-NCF. Moreover, the confinement loss and bending loss of all core modes are investigated. The simulation results show that the proposed few-mode HC-NCF can support the independent transmission of six weakly coupled core modes (with the effective refractive index difference greater than 1×10^–4 between the adjacent core modes, which greatly avoids the coupling between the adjacent modes in the fiber core). In the 400 nm bandwidth (1.23–1.63 μm, covering the O, E, S, C, and L bands), all six modes in the fiber core maintain low loss transmission. Moreover, in the range of 1.3–1.63 μm, the confinement loss (CL) of LP₀₁, LP₁₁ and LP₂₁ mode are all less than 1×10^–3 dB/m, and the CL of LP₀₂ and LP_31b mode are both less than 3×10^–3 dB/m. The CL of each mode reaches the lowest value at 1.4 μm, and the LP₀₁ mode has the lowest CL of 4.3×10^–7 dB/m. In addition, for a bending radius of 7 cm, each mode maintains the low bending loss characteristic in a certain operating wavelength range. In the range of 1.23–1.61 μm, the BL of LP₀₁ is less than 4.5×10^–4 dB/m, and the BL of LP₁₁ is less than 1.3×10^–3 dB/m. The tolerance analysis shows that even with the deviation of structural parameters of ±1%, the few-mode HC-NCF can still maintain the characteristic of low-loss and weak coupling. The designed few-mode HC-NCF has ultra-low CL and bending-insensitive characteristics while supporting independent transmission of six modes, which will find huge potential applications in future high performance mode division multiplexing systems.

Keywords:

作者及机构信息

1.
西安邮电大学电子工程学院, 西安　710121

2.
西安市微波光子与光通信技术重点实验室, 西安　710121

通信作者: 惠战强, zhanqianghui@xupt.edu.cn

基金项目: 国家自然科学基金(批准号: 61875165)、陕西省重点研发计划(批准号: 2022GY-008)、陕西省自然科学研究计划(批准号: 2022JQ-638)、陕西省创新能力支撑计划项目(批准号: 2022PT-15)、陕西省教育厅协同创新项目(批准号: 20JY060)和705所重点实验室开放基金(批准号: 705JCH2023-3.2)资助的课题.

Authors and contacts

1.
School of Electronic Engineering, Xi’an University of Posts and Telecommunications, Xi’an 710121, China

2.
Xi’an Key Laboratory of Microwave Photonics and Optical Communication Technology, Xi’an 710121, China

Corresponding author: Hui Zhan-Qiang, zhanqianghui@xupt.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 61875165), the Key Research and Development Program of Shaanxi Province, China (Grant No. 2022GY-008), the Natural Science Research Program of Shaanxi Province, China (Grant No. 2022JQ-638), the Innovation Capability Support Program of Shaanxi Province, China (Grant No. 2022PT-15), the Collaborative Innovation Projects of Education Office of Shaanxi Province, China (Grant No. 20JY060), and the Open Fund for 705 Key Laboratory, China (Grant No. 705JCH2023-3.2).

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参考文献

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施引文献

图 1 对称双环嵌套管少模HC-NCF的横截面结构图

Fig. 1. Cross sectional structure of few-mode HC-NCF with symmetrically double ring nested tube structure.

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图 2 当纤芯半径R = 16 μm和k = 0.4时, 改变g对模式传输特性的影响　(a) 有效折射率; (b) CL

Fig. 2. When the core radius R = 16 μm and k = 0.4, the impact of changing g on mode transmission characteristics: (a) Effective refractive index; (b) CL.

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图 3 少模HC-NCF中纤芯模式的模场分布图

Fig. 3. Mode field distribution of guided core modes in the few-mode HC-NCF.

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图 4 当纤芯半径R = 16 μm, g = 0.5 μm, 改变k对模式传输特性的影响　(a) 有效折射率; (b) 相邻模式有效折射率差; (c) CL; (d) 相邻模式间DGD

Fig. 4. Impact of changing k on mode transmission characteristics for R = 16 μm and g = 0.5 μm: (a) Effective refractive index; (b) difference of effective refractive index of adjacent modes; (c) CL; (d) DGD between adjacent modes.

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图 5 k = 0.25, LP_31a 模的模场分布　(a) 二维平面图; (b) 三维立体图

Fig. 5. Mode field distribution of LP_31a modes at k = 0.25: (a) 2D plane diagram; (b) 3D stereo diagram.

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图 6 当g = 0.5 μm, k = 0.4时, 改变纤芯半径R对模式传输的影响　(a) 有效折射率; (b) 相邻模式有效折射率差; (c) CL; (d) 相邻模式间的DGD

Fig. 6. Impact of changing R on mode transmission characteristics for g = 0.5 μm and k = 0.4: (a) Effective refractive index; (b) difference of effective refractive index of adjacent modes; (c) CL; (d) DGD between adjacent modes.

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图 7 当g = 0.5 μm, k = 0.4, R = 24 μm时, 波长变化对模式传输的影响　(a) 有效折射率; (b) 相邻模式有效折射率差; (c) CL; (d) 相邻模式间的DGD

Fig. 7. Variation of changing wavelength on mode transmission characteristics for g = 0.5 μm, k = 0.4 and R = 16 μm: (a) Effective refractive index; (b) difference of effective refractive index of adjacent modes; (c) CL; (d) DGD between adjacent modes.

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图 8 当g = 0.5 μm, k = 0.4, R = 24 μm时, 不同弯曲半径对模式传输的影响　(a) 预期基线; (b) 有效折射率; (c) 相邻模式有效折射率差; (d) BL

Fig. 8. Variation of changing bending radius on mode transmission characteristics for g = 0.5 μm, k = 0.4: (a) Expected baseline; (b) effective refractive index; (c) difference of effective refractive index of adjacent modes; (d) BL.

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图 9 当弯曲半径R_b= 7 cm时, 不同波长对模式传输的影响　(a) 相邻模式有效折射率差; (b) BL

Fig. 9. Variation of changing wavelength on mode transmission with bending radius R_b = 7 cm: (a) Difference of effective refractive index of adjacent modes; (b) BL.

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图 10 嵌套管壁厚参数t偏移+1%时, 相邻模式有效折射率差和CL的变化

Fig. 10. With nested tube wall thickness parameter t deviation +1%, the change of effective refractive index difference of adjacent mode and CL.

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图 11 嵌套管壁厚参数t偏移–1%时, 相邻模式有效折射率差和CL的变化

Fig. 11. With nested tube wall thickness parameter t deviation –1%, the change of effective refractive index difference of adjacent mode and CL.

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图 12 参数k偏移+1%时, 相邻模式有效折射率差和CL的变化

Fig. 12. With parameter k deviation +1%, the change of effective refractive index difference of adjacent mode and CL.

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图 13 参数k偏移–1%时, 相邻模式有效折射率差和CL的变化

Fig. 13. With parameter k deviation -1%, the change of effective refractive index difference of adjacent mode and CL.

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表 1 少模HC-NCF性能比较

Table 1. Performance comparison of few-mode HC-NCF

结构	中心波长/µm	支持模式数	基模最低限制损耗/(dB·m^–1)	工作带宽/nm	弯曲半径/cm	弯曲损耗/(dB·m^–1)
Wang Z, et al. (2020)^[46]	1.55	2	1.7×10^–4 @1.53 µm	340	10	6.6×10^–4 (200 nm)
Goel C, et al. (2021)^[47]	1.00	5	1.4×10^–5@1 µm	—	20	5×10^–3
Ou J, et al. (2022)^[48]	1.55	2	7.4×10^–7@1.06 µm	800	—	—
Liu H, et al. (2022)^[49]	1.55	5	3.4×10^–7@1.38 µm	300	6	3×10^–4 (210 nm)
Our work	1.55	6	4.3×10^–7@1.4 µm	330	7	4.5×10^–4 (420 nm)

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map

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