用于气体传感的二维平板光子晶体几何结构优化

2011 International Students and Young Scientists Workshop "Photonics and Microsystems" Pub Date : 2011-07-08 DOI:10.1109/STYSW.2011.6155863

A. Zakrzewski, M. Wielichowski, S. Patela

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引用次数: 2

摘要

优化了二维平板光子晶体(PhC)的几何结构，使其成为近红外光谱气体传感器的有源元件。假定传感器在慢光状态下工作。二维理论模型基于电磁场时域有限差分(FDTD)传播。考虑了线性缺陷的二维光子晶体结构。根据以下标准进行优化:最大光耦合效率、最大光提取效率和最大光气重叠。在模拟中，输出信号采集是通过输出条形波导来完成的。抗反射部分适用于单个PhC几何类型，用于防止在PhC内的慢光状态下传播的高群光速度造成的过度反射。将带和不带抗反射截面的配置进行比较。三角形晶格二维PhC类型是:线缺陷晶体和线缺陷晶体，具有额外的一排孔，改善光气重叠。

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Optimization of 2D slab photonic crystal geometry for gas sensing

The two-dimensional (2D) slab photonic crystal (PhC) geometry is optimized for the application of the PhC as a near-infrared spectroscopic gas sensor's active element. Sensor operation in the slow-light regime is assumed. The 2D theoretical model is based on the finite-difference time-domain (FDTD) propagation of the electromagnetic field. Linear-defect 2D photonic crystal structures are considered. Optimization is performed according to the following criteria: maximum light coupling efficiency, maximum light extraction efficiency, and maximum light-gas overlap. In the simulations, output signal collection is performed by means of either an output strip waveguide. Antireflection sections suited for individual PhC geometry types, are applied to prevent excessive reflections resulting from the high group velocity of light propagating in the slow-light regime within the PhC. Configurations with and without antireflection sections are compared. Triangular-lattice 2D PhC types are: line-defect crystals and line-defect crystals featuring an additional row of holes that improve the light-gas overlap.

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2011 International Students and Young Scientists Workshop "Photonics and Microsystems"

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