[1] Guo Xudong, Dong Tingting, Fu Yuegang, et al. Development of bionic moth-eye anti-reflective conical micro-nano structure[J]. Infrared and Laser Engineering, 2017, 46(9): 0910002. (in Chinese)

[2] Sun Xipeng, Xiao Zhibin, Du Yongchao. Design of broadband antireflection coating for new gallium arsenide solar[J]. Acta Optica Sinica, 2016, 36(4):0431002. (in Chinese)

[3] Raut H K. Robust and durable polyhedral oligomeric silsesquioxane-based antireflective nanostructures with broadband quasi-omnidirectional properties[J]. Energy Environ, 2013, 10(6): 1929-1937.

[4] Bernhard C G. Structural and functional adaptation in a visual system[J]. Endeavour, 1967, 2(6): 79-84.

[5] Leem J W. Nanostructured encapsulation coverglasses with wide-angle broadband antireflection and self-cleaning properties for III-V multi-junction solar cell applications[J]. Solar Energy Mater Solar Cells, 2014:120(10): 555-560.

[6] Kong Xiangdong, Fu Yuegang, Xia Liangping, et al. Analysis of Ag nanoparticle resist in fabrication of transmission-enhanced subwavelength structures[J]. Nanophotonics, 2016, 10(4): 046017.

[7] Dong Xiaoxuan, Shen Su, Chen Linsen. Fabrication of moth-eye antireflection nanostructure through a silver mirror reaction[J]. Acta Photonica Sinica, 2014, 43(7):0722001. (in Chinese)

[8] Dong Tingting. Research on the optical mechanism of bionic moth-eye antireflection micro-nano structure[D]. Changchun: Changchun University of Science and Technology, 2016: 61. (in Chinese)

[9] Takeharu Okuno. Development of a subwavelength structure coating (SWC) and its application to imaging lenses[C]//SPIE, 2010, 7652: 765203.

[10] Tadanaga K, Katata N, Minami T. Super-water-repellent Al2O3 coating films with high transparency[J]. J Am Ceram Soc, 1997, 80(4): 1040-1042.