Extraordinary transmission through aluminum metal with superperiodic micro-cell arranged in a long-range periodic structure

2007 7th IEEE Conference on Nanotechnology (IEEE NANO) Pub Date : 2007-08-01 DOI:10.1109/NANO.2007.4601189

Yi-Tsung Chang, Y. Ye, Chia-Yi Chen, M. Tsai, Si‐Chen Lee

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Abstract

Enhanced optical transmission through an Al film with perforated short-range 3times3, 4times4 and 5times5 hole arrays arranged in a long-range periodic structure is investigated. This three finite squared holes array constitutes an individual micro-cell, respectively. The measured transmission peak wavelength reveals that the surface plasmons are Fabry-Perot type resonance to different integer order. The ratio of periodicity between the super-periodic structure p and the NtimesN micro-cell d determines the integer order (where N is number of isolated hole; N=3, 4 and 5). Namely, when p/d>4, the order 4 and 5 surface plasmon modes with average hole spacing p/4 and p/5 are observed in 4times4 micro-cell array, respectively. The transmission intensities of order 4 mode are the strongest, and those of order 5 modes are barely seen. But as p/d approaches 5, the order 4 mode gradually disappear with the emergence of order 5 mode. The 3times3 and 5times5 micro-cell array have the same result. These phenomena suggest that the surface plasmons are Fabry-Perot type resonance within a super unit cell. The dispersion relations of surface plasmons are also observed.

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超常传输通过铝金属与超周期微电池排列在长周期结构

研究了以长程周期结构排列的3times3、4times4和5times5孔阵列穿孔铝膜的增强光传输。这三个有限的平方孔阵列分别构成一个单独的微电池。透射峰波长测量结果表明，表面等离子体为不同整数阶的法布里-珀罗型共振。超周期结构p与NtimesN微单元d之间的周期性之比决定了整数阶数(其中N为隔离孔数;N= 3,4和5)，即当p/d>4时，在4times4微单元阵列中分别观测到平均空穴间距为p/4和p/5的4阶和5阶表面等离子体模。4阶模式的传输强度最强，而5阶模式的传输强度几乎看不到。但当p/d接近5时，4阶模态逐渐消失，出现5阶模态。3times3和5times5微单元阵列的结果相同。这些现象表明，表面等离激元是超单晶胞内的法布里-珀罗型共振。还观察了表面等离子体的色散关系。

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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2007 7th IEEE Conference on Nanotechnology (IEEE NANO)

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