ZnSe衬底表面亚波长增透结构的设计及误差分析

以矢量严格耦合波(RCWA)理论为基础，通过遗传算法优化设计了圆柱形ZnSe亚波长微增透结构，获得了具有较好增透效果的结构参数；重点讨论分析了实际加工过程中圆柱形方向偏差及整体面形轮廓偏差对抗反射特性的影响；还对多台阶ZeSe增透性能随高度的变化进行了分析。结果表明：当圆柱形微结构周期为3.3 μm,高度为1.7517 μm,占空比为0.7566时,在8~14 μm波段范围具有较好的整体增透效果；占空比偏差，高度偏差及圆柱体面形轮廓偏差对结构的平均透射性能都具有较大的影响；圆锥形ZnSe微结构的透射性能随着高度和划分层数的增加呈现一定的规律分布，且相比圆柱形最优微结构,平均透射性能有了较大幅度的提高。

Abstract

Based on the rigorous couple-wave analysis (RCWA) method, columned ZnSe sub-wavelength micro-structure by genetic algorithm (GA) is optimized and optimum structure parameters are obtained. The effect of structure parameter error and profile shape error of columned ZnSe structure on the anti-reflective properties in actual manufacturing process is discussed. The transmittance of the multilevel ZnSe gratings with coned profile is also presented as a function of the structure height. The results show that the columned ZnSe micro-structure can have excellent average anti-reflective properties between 8 μm and 14 μm at normal incidence when the structure period, height and filling factor are 3.3 μm, 1.7517 μm and 0.7566, respectively. The errors of filling factor, height and profile shape have a big influence on the average transmittance. The transmittance of the ZnSe microstructure with coned profile shows some regular distribution with the increase of structure height and the number of divided layers, and it has a great improvement as compared with the optimized columned ZnSe micro-structure.

参考文献

[1] D W Zhang, Z W Lu, W X Yu, et al.. Electromagnetic diffraction analysis of 2-D antireflective subwavelength grating with coned profile[J]. Chinese J Lasers, 2002, 11(4): 273-280.

[2] D S Hobbs, B D Macleod, J R Riccobono. Update on the development of high performance anti-reflecting surface relief micro-structures[C]. SPIE, 2007, 6545: 65450Y.

[3] 钟敏霖, 范培迅. 激光纳米制造技术的应用[J]. 中国激光, 2011, 38(6): 0601001.

Zhong Minlin, Fan Peixun. Applications of laser nano manufacturing technologies[J]. Chinese J Lasers, 2011, 38(6): 0601001.

[4] D Maystre. A new general integral theory for dielectric coated gratings[J]. J Opt Soc Am, 1978, 68(4): 490-495.

[5] R Petit. Electromagnetic Theory of Gratings[M]. Berlin: Springer-Veriag, 1980.

[6] M Neviere, R Petit, M Cadinhac, et al.. About the theory of optical grating coupler-waveguide systems[J]. Opt Commun, 1973, 8(2): 113-117.

[7] M G Moharam, D A Pommet, E B Grann, et al.. Stable implementation of the rigorous coupled-wave analysis for surface-relif gratings: enhanced transmittance matrix approach[J]. J Opt Soc Am A, 1995, 12(5): 1077-1086.

[8] M G Moharam, E B Grann, D A Pommet, et al.. Formulation for stable and efficient implementation of the rigorous coupled-wave analysis of binary gratings[J]. J Opt Soc Am A, 1995, 12(5): 1068-1076.

[9] P Lalanne. Improved formulation of the coupled-wave method for two-dimensional gratings[J]. J Opt Soc Am A, 1997, 14(7): 1592-1598.

[10] M G Moharam, T K Gaylord. Three-dimensional vector coupled-wave analysis of planar grating diffraction[J]. J Opt Soc Am, 1983, 73(9): 1105-1112.

[11] L F Li. Note on the S-matrix propagation algorithm[J]. J Opt Soc Am A, 2003, 20(4): 655-660.

[12] E B Grann, M G Moharam, D A Pommet. Artificial uniaxial and biaxial dielectrics with use of two-dimensional sub-wavelength binary gratings[J]. J Opt Soc Am A, 1994, 11(10): 2695-2703.

[13] L F Li. Use of Fourier series in the analysis of discontinuous period structures[J]. J Opt Soc Am A, 1996, 13(9): 1870-1876.

[14] D S Hobbs, B D MacLeod. Design, fabrication and measured performance of anti-reflecting surface textures in infrared transmitting materials[C]. SPIE, 2005, 5786: 349-364.

[15] B D MacLeod, D S Hobbs. Low-cost anti-reflection technology for automobile displays[C]. Journal of the Society for Information Display, Automotive Display Conference, 2004.

[16] D A Pommet, E B Grann, M G Moharam. Effects of process errors on the diffraction characteristics of binary dielectric gratings[J]. Appl Opt, 1995, 34(14): 2430-2435.

[17] D Lehr, M Helgert, M Sundermann, et al.. Simulating different manufactured antireflective sub-wavelength structures considering the influence of local topographic variations[J]. Opt Express, 2010, 18(23): 23878-23890.

[18] 鱼卫星, 卢振武, 王鹏, 等. 二维表面浮雕结构的矢量衍射分析[J]. 光学学报, 2001, 21(8): 980-986.

Yu Weixing, Lu Zhenwu, Wang Peng, et al.. Vector analysis of two-dimensional surface-relief structure diffraction[J]. Acta Optica Sinica, 2001, 21(8): 980-986.

[19] D W Zhang, Z W Lu, W X Yu, et al.. Electromagnetic diffraction analysis of columned grid gratings[J]. J Opt A: Pure Appl Opt, 2002, 4(2): 180-186.

[20] 曹召良, 卢振武, 李凤友, 等. 二维抗反射亚波长周期结构光栅的设计分析[J]. 光学精密工程, 2002, 10(6): 537-541.

Cao Zhaoliang, Lu Zhenwu, Li Fengyou, et al.. Design consideration of two-dimensional antireflective sub-wavelength periodic gratings[J]. Optics and Precision Engineering, 2002, 10(6): 537-541.

[21] 鱼卫星, 卢振武, 王鹏, 等. 锥形轮廓亚波长二维表面浮雕结构的矢量衍射特性[J]. 光子学报, 2001, 30(3): 331-335.

Yu Weixing, Lu Zhenwu, Wang Peng, et al.. Vector diffracted characteristic of tapered profile two dimensional subwavelength surface-relief structure[J]. Acta Photonica Sinica, 2001, 30(3): 331-335.

[22] 曹召良, 卢振武, 李凤有, 等. 亚波长介质光栅的制作误差分析[J]. 光子学报, 2004, 33(1): 76-80.

Cao Zhaoliang, Lu Zhenwu, Li Fengyou, et al.. Analysis of fabrication error of subwavelength dielectric gratings[J]. Acta Photonica Sinica, 2004, 33(1): 76-80.

[23] 许嘉俊, 邢廷文. 可见光二维小孔矢量衍射分析[J]. 光学学报, 2011, 31(12): 1205003.

Xu Jiajun, Xing Tingwen. Analysis of two-dimensional pinhole vector diffraction in visible light[J]. Acta Optica Sinica, 2011, 31(12): 1205003.

[24] 孙艳军, 冷雁冰, 董连和. 蓝宝石红外窗口抗反射浮雕结构研究[J]. 红外技术, 2011, 33(2): 92-95.

Sun Yanjun, Leng Yanbing, Dong Lianhe, et al.. Study on antireflective relief periodic structure of sapphire infrared window[J]. Infrared Technology, 2011, 33(2): 92-95.

[25] 孔伟金, 王书浩, 魏世杰, 等. 宽光谱高衍射效率脉宽压缩光栅设计能性能分析[J]. 光学学报, 2011, 31(10): 1005001.

Kong Weijin, Wang Shuhao, Wei Shijie, et al.. Design and diffraction property of broad waveband high-diffraction-efficiency grating for chirped pulse compressor[J]. Acta Optica Sinica, 2011, 31(10): 1005001.

尚鹏, 熊胜明. ZnSe衬底表面亚波长增透结构的设计及误差分析[J]. 中国激光, 2014, 41(1): 0116004. Shang Peng, Xiong Shengming. Design and Error Analysis of Sub-Wavelength Antireflective Micro-Structure on Surface of ZnSe Substrate[J]. Chinese Journal of Lasers, 2014, 41(1): 0116004.

ZnSe衬底表面亚波长增透结构的设计及误差分析

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