基于嵌入粒子形态控制的新型纳米复合材料折射率调谐机制

Sipan Liu, Md. Didarul Islam, Z. Ku, A. Urbas, J. Derov, D. Boyd, Woohong Kim, J. Sanghera, J. Ryu
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引用次数: 1

摘要

研究了包埋纳米颗粒的形态和分布对复合材料有效折射率的影响。本文的研究是基于纳米复合材料制成的法布里-普氏干涉腔的有限元模型。通过模拟反射谱可以得到复合材料的有效RI。在颗粒体积分数恒定的条件下,粒径较大、位于电场强区域、沿电场振荡方向边长较长的嵌入颗粒是增强有效RI的因素。对于4 μm入射光波,将直径控制在24.8 nm ~ 212 nm,由中聚集(高电场区)向上下聚集(低电场区)分布,矩形柱状粒子沿电场振荡方向的最短边向最长边增加,有效RI分别从1.687增加到1.719,从1.638增加到1.745,从1.66增加到1.901。从纳米颗粒的光散射损失中可以识别出潜在的RI位移原理。这一发现为下一代实时RI调谐结构和器件提供了一种新的思路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Novel Nanocomposite Refractive Index Tuning Mechanism Based on Controlling Embedded Particle Morphology
This study investigates the embedded nanoparticles’ morphology and distribution effects on the effective refractive index (RI) of composite. The study is based on the FEA model for the Fabry-Pérot interference cavity made from the nanocomposite film. The composites’ effective RI can be derived from the simulation reflection spectrum. In constant particle volume fraction condition, the embedded particles with a larger diameter, locating at the region with high electric field and having longer side length along the electric field oscillating direction, are identified as the factors to reinforce the effective RI. For 4 μm incident light-wave, as controlling the diameter from 24.8 nm to 212 nm, distribution from middle-gathered (high electric field region) to top-bottom gathered (low electric field region), and the rectangular cylinder particle shortest side along electric field oscillating direction to longest side along electric field oscillating direction, the effective RI increasing from 1.687 to 1.719, 1.638 to 1.745 and 1.66 to 1.901, respectively. The underlying RI shifting principle is recognized from the light scattering loss by embedded nanoparticles. This discovering provides one novel idea for next-generation real-time RI tuning structure and device.
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