[1] Yingxian MA, Sutcharitchan CHAYANIS, Qian MENG et al. Application of polarized light microscope and λ wavelength compensator in the microscopic identification of crude drugs. World Science and Technology-Modernization of Traditional Chinese Medicine, 24, 3364-3374(2022).

[2] Mengling CAI. Application of polarized light microscope in the detection of paper fibers in Mustang archives. Conservation and Archaeological Science, 33, 52-60(2021).

[3] Zhiqi WANG, Baohua GUO, Jun XU. Application of polarization optical microscopy in characterization of polymer crystal structure. Acta Polymerica Sinica, 54, 130-150(2023).

[4] J C RAMELLA-ROMAN. SAYTASHEV I, PICCINIC M. A review of polarization-based imaging technologies for clinical and preclinical applications. Journal of Optics, 22, 123001(2020).

[5] I E IVANOV, L H YEH, J A PEREZ-BERMEJO et al. Correlative imaging of the spatio-angular dynamics of biological systems with multimodal instant polarization microscope. Biomedical Optics Express, 13, 3102-3119(2022).

[6] Fang WU, Yang BU, Zhifan LIU et al. Design and analysis of deep ultraviolet double-layer metal grating polarizer. Acta Physica Sinica, 70, 184-194(2021).

[7] Kejun ZHONG, Yanjun FU, Guangyu JIANG. Design of sub-wavelength grating for improving efficiency of OLED substrate. Journal of Applied Optics, 39, 701-706(2018).

[8] T SASAKI, H KUSHIDA, M SAKAMOTO et al. Liquid crystal cells with subwavelength metallic gratings for transmissive terahertz elements with electrical tenability. Optics Communications, 431, 63-67(2018).

[9] D N MINH, L DASOL, R JUNSUK. Control of light absorbance using plasmonic grating based perfect absorber at visible and near-infrared wavelengths. Scientific Reports, 7, 2611(2017).

[10] Y ITSUNARI, N JUNJI, S MITSUNORI. Modeling, fabrication, and characterization of tungsten silicide wire-grid polarizer in infrared region. Applied Optics, 47, 4735-4738(2008).

[11] T WEBER, T KÄSEBIER, A SZEGHALMI et al. High aspect ratio deep UV wire grid polarizer fabricated by double patterning. Microelectronic Engineering, 98, 433-435(2012).

[12] W HE, Y FENG, Z HU et al. Sensors with multifold nanorod metasurfaces array based on hyperbolic metamaterials. IEEE Sensors Journal, 20, 1801-1806(2020).

[13] S AHN, K LEE, J KIM. Fabrication of a 50 nm half-pitch wire grid polarizer using nanoimprint lithography. Nanotechnology, 16, 1874-1877(2005).

[14] Jiangtao YANG, Jian'an WANG, Yin WANG et al. Study on preparation technology of subwavelength metal grating polarizer. Infrared Technology, 43, 8-12(2021).

[15] Y WANG, X H FU, Y Y CHEN et al. The development progress of surface structure diffraction gratings: from manufacturing technology to spectroscopic applications. Applied Sciences, 12, 6503(2022).

[16] Jinkui CHU, Qianyi WANG, Zhiwen WANG et al. Abnormal transmission characteristics of TE polarized light in double-layer metal nanogratings. Acta Physica Sinica, 64, 274-280(2015).

[17] C L WU, C H HSUEH, J H LI. Surface plasmons excited by multiple layer grating. Optics Express, 27, 1660-1671(2019).

[18] X F JING, Y X JIN. Transmittance analysis of diffraction phase grating. Applied Optics, 50, C11-C18(2011).

[19] A D RAKIC. Algorithm for the determination of intrinsic optical constants of metal films: application to aluminum. Applied Optics, 34, 4755-4767(1995).

[20] C XU, Q XU, J MA et al. Research on the polarization and temperature characteristics of subwavelength aluminum gratings. Journal of Optics, 16, 105711(2014).

[21] Guoguo KANG, Qiaofeng TAN, Weili CHEN et al. Experimental study on the design, fabrication and polarization imaging of subwavelength wire grating. Acta Physica Sinica, 60, 337-343(2011).

[22] G M MOHARAM, B E GRANN, A D POMMET et al. Formulation for stable and efficient implementation of the rigorous coupled-wave analysis of binary gratings. Journal of the Optical Society of America, 12, 1068-1076(1995).

[23] E NAVARRO, B GIMENA, J CRUZ. Modelling of periodic structures using the finite difference time domain method combined with the Floquet theorem. Electronics Letters, 29, 446-447(1993).

[24] J G SUN, C X ZHENG. Numerical scattering analysis of TE plane waves by a metallic diffraction grating with local defects. Journal of the Optical Society of America. A-Optics, Image Science, and Vision, 26, 156-162(2009).

[25] M FIONNUALA, Q JING, G KELSEY et al. Structural, optical, and electrical properties of silver gratings prepared by nanoimprint lithography of nanoparticle ink. Applied Surface Science, 537, 147892(2020).

[26] A A ELISEEV, V O RAVODINA. Optics and spectroscopy principle for the design of interference light filters with two multilayers. Russian Physics Journal, 41, 996-1000(1999).

[27] M HONKANEN, V KETTUNEN, M KUITTINEN et al. Inverse metal-stripe polarizers. Applied Physics B-Lasers and Optics, 68, 81-85(1999).

[28] W T EBBESEN, J H LEZEC, F H GHAEMI et al. Extraordinary optical transmission through sub-wavelength hole arrays. Nature: International Weekly Journal of Science, 391, 667(1998).

[29] Chunlei TAN, Yongxiang YI, Guoping WANG. Transmission optical properties of one-dimensional metal grating. Acta Physica Sinica, 1063-1067(2002).

[30] Q CAO, P LALANNE. Negative role of surface plasmons in the transmission of metallic gratings with very narrow slits. Physical Review Letters, 88, 057403(2002).

[31] Baoyu SUN, Jichen XU, Yan GU et al. Preparation of large-area grating structure by vibration-assisted nanoimprint. Journal of Applied Optics, 43, 124-130(2022).