Influence of substrate on shielding effectiveness of metallic mesh under oblique incidence condition

LU Zhen-gang; TAN Jiu-bin; LIU Yong-meng; LIU Jian; ZHANG Hui

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Influence of substrate on shielding effectiveness of metallic mesh under oblique incidence condition

更新时间：2020-08-12

- Influence of substrate on shielding effectiveness of metallic mesh under oblique incidence condition
- Optics and Precision Engineering Vol. 14, Issue 3, Pages: 360-367(2006)
- 作者机构：
  
  哈尔滨工业大学超精密光电仪器工程研究所,黑龙江哈尔滨 150001
- 作者简介：
- 基金信息：
- DOI：
  CLC： TN713;O484.1
- Received：10 October 2005，
  
  Revised：06 February 2006，
  
  Published Online：30 June 2006，
  
  Published：30 June 2006
- 稿件说明：
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LU Zhen-gang, TAN Jiu-bin, LIU Yong-meng, et al. Influence of substrate on shielding effectiveness of metallic mesh under oblique incidence condition[J]. Optics and precision engineering, 2006, 14(3): 360-367.
DOI：

LU Zhen-gang, TAN Jiu-bin, LIU Yong-meng, et al. Influence of substrate on shielding effectiveness of metallic mesh under oblique incidence condition[J]. Optics and precision engineering, 2006, 14(3): 360-367. DOI：

摘要

提出了双层膜系分析方法

该方法采用独立网栅等效薄膜模型

将网栅对衬底干涉的影响引入分析

克服了Kohin方法仅考虑衬底干涉的不精确性

并避免了其分析独立网栅的透波率公式在高频和大入射角时存在的不准确性。用紫外光刻在石英衬底上制备了周期为320 μm

线宽为4.5 μm的网栅

测得S波30°入射时12~18 GHz的屏蔽效率大于16 dB

略低于理论值但变化趋势一致

证实了双层膜法的有效性。进而分析衬底影响表明:入射为S波及小于衬底布儒斯特角

的P波时屏蔽效率降低

而入射为大于

的P

波时屏蔽效率反常增加;屏蔽效率变化最大值随入射角变化;优化衬底厚度可在不影响网栅透光能力的同时获得最佳屏蔽效果。

Abstract

A double film method was employed to accurately estimate the influence of substrate on shielding effectiveness. By using the equivalent film model of free-standing mesh and preparing a thin mesh film on its substrate

this paper considers its influence on substrate interference to overcome the uncertainty of Konin’s method that merely considers the interference of the substrate itself

and to avoid the inaccuracy of Kohin’s transmission formulas of free-standing mesh at high frequency and large incident angle. To identify its validity

the metallic mesh with line width of 4.5 μm and period of 320 μm was fabricated on quartz glass by UV-lithography. The measuring results show that the shielding effectiveness is greater than 16 dB under 30°

-polarized incidence at 12~18 GHz

it is slightly below the theoretical value and has the same change trend with that. The analysis using the new method shows that for

-polarization

the shielding effectiveness decreases with oblique incidence; for

-polarization

it decreases also when incident angle is less than Brewster angle

but it increases abnormally when inciclent angle is larger than

and the largest alteration value varies with incident angle. Optimal shielding effectiveness can be obtained by optimizing substrate thickness without affect on the transparent property.

关键词

Keywords

references

. 卢俊,张靓,孙连春. Y 形和Y 环形单元特性的实验对比研究[J]. 光学精密工程,2005,13(2):219-224. LU J,ZHANG J,SUN L C.Experimental comparison of the characteristics of Y element and Y loop element[J].Optics and Precision Engineering,2005,13(2):219-224.(in Chinese)

. DRUPP R P,BOSSARD J A,YE Y H.Infrared single-layer metallodielectric photonic crystals[J].Applied Physics Letters, 2004,85(10):1835-1837.

. SAULEAU R,COQUET P,et al.Radiation characteristics and performance of millimeter-wave horn-fed Gaussian beam antennas[J]. IEEE Transactions on Antennas and Propagation,2003,51(3):378-387.

. DRYSDALE T D,GREGORY I S.Transmittance of a tunable filter at terahertz frequencies[J].Applied Physics Letters,2004,85(22):5173-5175.

. KLEIN C A. Microwave shielding effectiveness of EC-coated dielectric slabs[J]. IEEE Transactions on Microwave Theory and Techniques,1990,38(3):321-324.

. KOHIN M,WEIN S J.Analysis and design of transparent conductive coatings and filters[J].Optical Engineering, 1993,32(5):911-925.

. 冯晓国,方梁,孙连春. 金属网栅结构参数设计与制作 . 光学精密工程,2005,13(1):59-64. FENG X G,FANG L,SUN L C. Characteristic dimension design and fabrication of metallic mesh[J]. Optics and Precision Engineering,2005,13(1):59-64.(in Chinese)

. ULRICH R. Far-infrared properties of metallic mesh and its complementary structure[J].Infrared Physics,1967,7: 37-55.

. WHITBOURN L B,COMPTON R C.Equivalent-circuit for metal grid reflectors at a dielectric boundary[J].Applied Optics,1985,24(2):217-220.

. SAULEAU R,COQUET P.Beam focusing using 60 GHz Fabry-Perot resonators with uniform and non-uniform metal grids[J]. Electronics Leters,2003,39(4):341-342.

. 高劲松,孙连春,郑宣明,等. 红外透明导电金属网栅薄膜[J]. 光学技术,2001,27(6):558-559. GAO J S,SUN L C,ZHENG X M,et al. IR transparent conductive metallic mesh film[J]. Optical Technique, 2001,27(6):558-559. (in Chinese)

. 车英,董连和,王也. 红外增透膜与远红外低通滤波器[J]. 兵工学报,2003,24(1):62-64. CHE Y,DONG L H,WANG Y.Transparent infrared coatings and far infrared low-pass filter[J].Acta Armamentarii, 2003,24(1):62-64. (in Chinese)

. 李凤友,卢振武,谢永军,等. 激光直写方法制作透明导电金属网栅[J]. 光子学报,2002,31(10):1270-1272. LI F Y,LU Z W,XIE Y J,et al.Transparent conductive metallic film mesh fabricated by laser direct writing techniques[J]. Acta Photonica Sinica,2002,31(10): 1270-1272. (in Chinese)

. 梁铨延.物理光学[M]. 北京:机械工业出版社,1987. LIANG Q Y.Physical Optics[M]. Beijing: China Machine Press,1987.(in Chinese)

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