Performance analysis of 2D photonic crystal with line defect

INTERNATIONAL CONFERENCE ON INVENTIVE MATERIAL SCIENCE APPLICATIONS : ICIMA 2019 Pub Date : 2019-10-25 DOI:10.1063/1.5131598

Karuna Gamare, R. B. Jain

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引用次数: 6

Abstract

Photonic crystal is a periodic arrangement of dielectric rods positioned in air at optimal spacing. Photonic crystal properties depend on the geometrical parameters such as material, radius of rods, lattice constant etc. This paper examines Photonic Band Gap (PBG) due to change in radius of rods and lattice constant of 2D photonic crystal structure. A detailed study of the PBG of 2D photonic crystal structure has been presented using Finite Element Method (FEM). A line defect is introduced into the photonic crystal structure and its impact on PBG has been investigated. The results show that after increase in radius of rods PBG becomes wider, whereas increase in lattice constant decreases the width of bandgap.Photonic crystal is a periodic arrangement of dielectric rods positioned in air at optimal spacing. Photonic crystal properties depend on the geometrical parameters such as material, radius of rods, lattice constant etc. This paper examines Photonic Band Gap (PBG) due to change in radius of rods and lattice constant of 2D photonic crystal structure. A detailed study of the PBG of 2D photonic crystal structure has been presented using Finite Element Method (FEM). A line defect is introduced into the photonic crystal structure and its impact on PBG has been investigated. The results show that after increase in radius of rods PBG becomes wider, whereas increase in lattice constant decreases the width of bandgap.

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具有线缺陷的二维光子晶体性能分析

光子晶体是在空气中以最佳间距周期性排列的介电棒。光子晶体的性质与材料、棒半径、晶格常数等几何参数有关。本文研究了二维光子晶体结构中棒半径和晶格常数的变化对光子带隙的影响。本文采用有限元法对二维光子晶体结构的PBG进行了详细的研究。在光子晶体结构中引入线缺陷，研究了线缺陷对PBG的影响。结果表明，随着棒半径的增大，带隙宽度增大，而晶格常数的增大使带隙宽度减小。光子晶体是在空气中以最佳间距周期性排列的介电棒。光子晶体的性质与材料、棒半径、晶格常数等几何参数有关。本文研究了二维光子晶体结构中棒半径和晶格常数的变化对光子带隙的影响。本文采用有限元法对二维光子晶体结构的PBG进行了详细的研究。在光子晶体结构中引入线缺陷，研究了线缺陷对PBG的影响。结果表明，随着棒半径的增大，带隙宽度增大，而晶格常数的增大使带隙宽度减小。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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INTERNATIONAL CONFERENCE ON INVENTIVE MATERIAL SCIENCE APPLICATIONS : ICIMA 2019

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