Narrow-band and polarization cut-offfiltering based on the bionic structure of unidirectional microvilli array

2017 IEEE International Conference on Manipulation, Manufacturing and Measurement on the Nanoscale (3M-NANO) Pub Date : 2017-08-01 DOI:10.1109/3M-NANO.2017.8286294

Qifan Zhu, Zhiying Liu, Yuegang Fu, Chun-Jie Hao

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Abstract

Based on assumption of the visual system characteristics of the unidirectional microvilli array, this paper simulated the bionic model. The unidirectional microvilli array is simulated and it is simplified as cylinders, which is composed of material with index of refraction of n2 periodically arranged and is surrounded by medium with index of refraction of n1. Then, the bionic structure is equivalent to numbers of binary grating layers with different periods and thicknesses. Based on the effective medium theory (EMT) and transfer matrix method, this paper analyzed the relation between the transmittance of s-and p-modes and wavelengths in visible spectrum (400nm-700nm) for this bionic model. The result shows that the bionic model can work as a polarizer in two different narrow spectral ranges, and in two orthogonal polarization direction and can achieve the function of narrow-band and polarization cut-off filtering. Changing the thicknesses of the binary grating layers, the spectrum band of two spectral ranges would be different.

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基于单向微绒毛阵列仿生结构的窄带极化截止滤波

本文在假设单向微绒毛阵列视觉系统特性的基础上，对仿生模型进行了仿真。对单向微绒毛阵列进行了模拟，并将其简化为圆柱体，由折射率为n2的材料周期性排列，周围是折射率为n1的介质。然后，将仿生结构等效为不同周期和厚度的二元光栅层数。基于有效介质理论(EMT)和传递矩阵法，分析了该仿生模型的- p模式透射率与可见光谱波长(400nm-700nm)之间的关系。结果表明，该仿生模型可以在两个不同的窄光谱范围和两个正交偏振方向上作为偏振器，并能实现窄带滤波和偏振截止滤波的功能。改变二元光栅层的厚度，两个光谱范围的光谱带会有所不同。

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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2017 IEEE International Conference on Manipulation, Manufacturing and Measurement on the Nanoscale (3M-NANO)

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