基于超透射现象的带通滤光膜潜在失效模式分析

孙哲; 任玉; 石晶; 宋晨智; 周建伟; 蔡红星

光学技术, 2022, 48 (2): 184, 网络出版: 2022-04-21

基于超透射现象的带通滤光膜潜在失效模式分析

Potential failure mode analysis of band pass filter film based on super transmission phenomenon

论文大纲

孙哲 ^*任玉石晶宋晨智周建伟蔡红星

作者单位

长春理工大学理学院吉林省光谱探测科学与技术重点实验室, 吉林长春 130022

近红外双玻孔阵带通滤光膜表面等离激元 near infrared double glass hole array band pass filter surface plasmon

摘要

文章在理论方面利用亚波长孔阵结构透射峰位关系公式, 针对光谱探测器件所需要的具备单峰窄带透射特性的介质-金属-介质的三层结构”双玻孔阵”结构模型的窄带单峰透射结果, 基于现有的加工工艺对较常出现的上沿过刻、孔底残留和孔底过刻三种实验误差进行了潜在失效模式分析, 与标准双玻孔阵模型对比结果, 分析得到加工误差对窄带单峰透射的各种影响及产生的机理。对利用双玻孔阵结构的异常透射原理对入射光进行选择性透过制备出的新型像素级滤光膜系的制备工艺有一定的指导意义。

Abstract

In theory, the formula of transmission peak position of subwavelength hole array structure is used, aiming at the narrow-band single peak transmission results of the dielectric metal dielectric three-layer structure "double glass hole array" structure model with single peak narrow-band transmission characteristics required by the spectral detector device, and based on the existing processing technology for the more common upper edge over etching, double glass hole array structure The potential failure modes of residual hole bottom and over etching hole bottom are analyzed. Compared with the standard double glass hole array model, the effects of processing errors on narrow-band single peak transmission and the mechanism are analyzed. It has a certain guiding significance for the preparation of a new type of pixel level filter film system by using the abnormal transmission principle of double glass hole array structure to selectively transmit the incident light.

参考文献

[1] Arbabi A, Arbabi E ,Horie Y, et al. Planar metasurface retroreflector［J］. Nature Photonics,2017,11(7):415-420.

[2] T Peyronel, O Firstenberg, Q Y Liang, et al. Quantum nonlinearoptics with single photons enabled by strongly interacting atoms［J］. Nature,2012,488(7409):57-6.

[3] Wang L, Kruk S, Tang H, et al. Grayscale transparent metasurface holograms［J］. Optica,2016,3(12):1504-1505.

[4] Li G, Zhang S, Zentgraf T. Nonlinear photonic metasurfaces［J］. Acta Physica Sinica,2017,2:17010.

[5] Shane Colburn, Alan Zhan, Arka Majumdar. Varifocal zoom imaging with large area focal length adjustable metalenses［J］. Optica,2018:825-831.

[6] Xie Z, Yu W, Wang T, et al. Plasmonic nanolithography: A review［J］. Plasmonics,2011,6(3):565.

[7] Zi Lan, Deng Junhong, et al. Facile metagrating holograms with broadband and extreme angle tolerance［J］. Light Science & Applications,2018,7(2):78.

[8] Walter Felicitas, Li Guixin, Meier Cedrik, et al. Ultrathin nonlinear metasurface for optical image encoding［J］. Nano Letters,2017,17(5):3171-3175.

[9] Wang Z , Yi S, Chen A, et al. Single-shot on-chip spectral sensors based on photonic crystal slabs［J］. Nature Communications,2019,10(1):1-6.

[10] Edward H. Adelson James, R Bergen. The plenoptic function and the elements of early vision［J］. Computational Models of Visual Processing1991:3-20.

[11] Yuyi Feng, Paul Leiderer, Ruizhe Zhao, et al, Giant polarization anisotropic optical response from anodic aluminum oxide templates embedded with plasmonic metamaterials［J］. Optics Express,2020,28(20):29513-29528.

[12] Ruan Z, Qiu M . Enhanced transmission through periodic arrays of subwavelength holes: the role of localized waveguide resonances［J］. Physical Review Letters,2006,96(23):233901.

[13] Krishnan A, EbbesenT W, PendryJ, et al. l.Evanescently coupled resonancein surface plasmonenhanced transmission［J］. Opt.Communicate,2001,200(1):1-7.

[14] Janssen O T A, Urbach H P. On the phase of plasmons excited by slitsinametal film［J］. Opt. Express,2006,14(24):11823-11832.

[15] 宋晨智, 石晶, 任玉, 等. 短波红外单波长滤光膜系模型设计［J］.光学技术2020,46(04):398-403.

[16] 邵伟佳. 基于表面等离子体激元的光学滤波片与完美吸收超材料的设计及数值模拟［D］.中国科学技术大学,2014.

[17] Genet C, Ebbesen T W. Light in tiny holes［J］. Nature,2007,445(7123):205-212.

[18] 刘志锋. 亚波长孔阵列的异常光学、声学透射［D］.南京大学,2011.

孙哲, 任玉, 石晶, 宋晨智, 周建伟, 蔡红星. 基于超透射现象的带通滤光膜潜在失效模式分析[J]. 光学技术, 2022, 48(2): 184. SUN Zhe, REN Yu, SHI Jing, SONG Chenzhi, ZHOU Jianwei, CAI Hongxing. Potential failure mode analysis of band pass filter film based on super transmission phenomenon[J]. Optical Technique, 2022, 48(2): 184.

基于超透射现象的带通滤光膜潜在失效模式分析

关于本站 Cookie 的使用提示

全站搜索

基于超透射现象的带通滤光膜潜在失效模式分析

相关论文

相关资讯

关于本站 Cookie 的使用提示

全站搜索