提高光纤芯的性能:等离子体金属活化的作用

IF 0.8 Q3 MULTIDISCIPLINARY SCIENCES
Hussein Taqi John, Oday Jawad Kadhim, Imad Kamil Zayer, M S Aziz, A A Salim
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引用次数: 0

摘要

具有定制特性的光纤芯对各种高性能应用的要求越来越高。基于这个想法,使用各种等离子体金属(铍、铬和镍)激活光纤芯,以提高其折射率、灵敏度和带宽。利用有限元分析(FEM)确定了不同波长和芯半径对LP01、LP11和LP21三种模式传播的影响。采用COMSOL MULTIPHYSICS软件进行计算。通过改变激活等离子体金属的纤芯半径和波长来控制能量的正向和反向传播以及模态色散关系。计算了三种模式的有效折射率、衰减、传播常数和扩散系数随波长和纤芯半径的变化规律,在波长较短时达到最大值。无论光纤芯中金属活化的类型如何,半径为200 nm的纤芯对LP01模式折射率的影响更为显著。在不同的金属夹杂物中,所有模式的色散关系(折射率与频率)都是强正的,半径以200、400、600 nm的数量级递增。等离子体金属Cr和Ni表现出最好的效果,而Be需要高V值才能在较窄的范围内得到LP01,而其他模式出现的范围比V更大。本研究结果可能对高性能光纤芯的开发有帮助。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Improved Performance of Optical Fiber Core: Role of Plasmonic Metals Activation
Optical fiber core with customized characteristics became demanding for diverse high performance applications. Based on this idea, the optical fiber core was activated using various plasmonic metals (beryllium, chromium, and nickel) to improve its refractive index, sensitivity and bandwidth. The influence of various wavelengths and core radii on three modes (LP01, LP11 and LP21) propagation was determined using finite element analysis (FEM). The COMSOL MULTIPHYSICS software was used for the computation. The fiber core radii of the plasmonic metal activated and wavelengths were varied to control the forward and backward energy propagation as well as the modal dispersion relation. Quantities like effective refractive index, attenuation, propagation constant and diffusion coefficient for the three modes as a function of wavelengths and fiber core radii were calculated, which showed maximum values at shorter wavelengths. Irrespective of the type of metal activation in the fiber core, the refractive index of LP01 mode for the core of radius 200 nm was more significantly affected compared to others. Regardless of different metals inclusion, the dispersion relation (refractive index versus frequency) for all modes was strongly positive, showing increasing values for radius in the order of 200, 400, 600 nm. Plasmonic metals Cr and Ni displayed best effect, while Be required high values of V to get LP01 in a narrow range and other modes appeared in a larger range than V. Present results may be useful for the development of high performance optical fiber core.
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来源期刊
CiteScore
1.40
自引率
0.00%
发文量
45
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