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高非线性平坦色散光子晶体光纤的研究 被引量:6

Research of photonic crystal fiber with high nonlinear flattened dispersion property
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摘要 为了研究最内层空气孔的大小以及空气孔的占空比改变对光子晶体光纤的非线性系数、色散的影响,采用全矢量有限元方法,进行了理论分析和实验验证,取得了非线性系数、色散系数随频率和结构参量的变化数据。结果表明,三角晶格结构的非线性系数大,色散较平坦,能够在400nm~1160nm保持单模传输,非线性系数达到172km-1.W-1,在0.65μm~1.0μm范围内具有超平坦色散。这一结果对光通信领域的研究是有帮助的。 In order to analyze the dependence of the nonlinear coefficient and dispersion property on the structural parameters of the inner air hole size and the changing of the air hole fraction, by using the full vector finite element method, the nonlinear coefficient and dispersion property as a function of frequency and design parameters were investigated. According to the analysis results, the nonlinear coefficient of photonic crystal fiber with hexagonal structure is significantly increased and the dispersion is fiat. It is shown from numerical results that it is possible to design photonie crystal fiber of hexagonal structure with single mode transmission during 400nm -1160nm and high nonlinear coefficient achieves 172km^-1·W^-1, dispersion becomes flattened between 0. 65μm-1.0μm. This result is helpful to the research of optical communication.
作者 简多 刘敏 何丁丁 李丹 廖洲一
机构地区 重庆大学通信工程学院
出处 《激光技术》 CAS CSCD 北大核心 2013年第2期187-190,共4页 Laser Technology
基金 国家自然科学基金资助项目(61007049)
关键词 光纤光学 非线性 色散平坦 全矢量有限元法 光子晶体光纤 fiber optics nonlinearity flattened dispersion full vector finite element method photonic crystal fiber
分类号 TN929.11 [电子电信—通信与信息系统]
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激光技术
2013年 第2期

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