[1] TYO J S, GOLDSTEIN D L, CHENAULT D B et al. Review of passive imaging polarimetry for remote sensing applications[J]. Applied Optics, 45, 5453-5469(2006).

[2] YAMADA I, NISHII J, SAITO M. Incident angle and temperature dependence of WSi wire-grid polarizer[J]. Infrared Physics & Technology, 63, 92-96(2014).

[3] PATRIZIA M, COLLEONI M, VIDAL B. Flexible sub-THz metal wire grid polarizer based on an EGaIn24.5 alloy[J]. IEEE Transactions on Terahertz Science and Technology, 6, 757-759(2016).

[4] KONG Yuanyuan, LUO Haihan, LIU Dingquan. Design of a mid-infrared Al wire-grid polarizer on Si substrates[J]. Micronanoelectronic Technology, 55, 461-467(2018).

[5] FU Xiuhua, LIN Xiaomin, ZHANG Gong et al. Development of infrared wide band polarizing elements with subwavelength metal wire grids[J]. Chinese Journal of Lasers, 48, 0903002(2021).

[6] ZHAO Z, MA T, XIAO J R et al. Compact and efficient wire grid reflecting polarizersat 121.6 nm[J]. Physica Scripta, 98, 015007(2023).

[7] KONG Yuanyuan. Structure design and characteristics study of medium-wave infrared metal wire grid polarizer[D](2018).

[8] EKINCI Y, SOLAK H H, DAVID C et al. Bilayer Al wire-grids as broadband and high-performance polarizers[J]. Optics Express, 14, 2323-2334(2006).

[9] CHEN Juan, YAN Lianshan, PAN Wei et al. Arbitrary polarization transformation based on two-dimensional metallic rectangular gratings[J]. Acta Optica Sinica, 31, 243-247(2011).

[10] ARAKAWA E, CALLCOTT T, CHANG Y[M]. Handbook of Optical Constants of Solids, 421-433(1997).

[11] LU Bin. Study on high performance metal wire grid terahertz polarizer[D](2016).

[12] LALANNE P, MORRIS G M. Highly improved convergence of the coupled-wave method for TM polarization[J]. Journal of the Optical Society of America A, 13, 779-784(1996).

[13] RODRÍGUEZ-DE MARCOS L V, LARRUQUERT J I, MÉNDEZ J A et al. Self-consistent optical constants of MgF2, LaF3, and CeF3 films[J]. Optical Materials Express, 7, 989(2017).

[14] SU J C, CHOU S C. Performance comparison of polarized white light emitting diodes using wire-grid polarizers with polymeric and glass substrates[J]. Optics & Laser Technology, 100, 40-44(2018).

[15] BUCHNEV O, BELOSLUDTSEV A, FEDOTOV V A. Polarization discrimination and surface sensing with a near-IR nanostructured hybrid mirror[J]. Optics Letters, 47, 4036(2022).

[16] WU J, ZHOU C H, CAO H C et al. Broadband polarizing beam splitter with metal-wire nanograting in near infrared region[J]. Optics & Laser Technology, 47, 166-170(2013).

[17] KIM S, KIM D, LEE Y J et al. Broadband high-performance terahertz polarizer based on a dense array of 5 nm gap slit antennas[J]. Optics Express, 30, 30038-30046(2022).

[18] JEON J, CHUN B S, SEO Y et al. Improving infra-red polarized imaging efficiency in a bilayer wire-grid polarizer[J]. Nanoscale Advances, 5, 633-639(2023).

[19] WANG C Y, CHAO Y Y, LIANG J J et al. Large-area wire grid polarizer with high transverse magnetic wave transmittance and extinction ratio for infrared imaging system[J]. Advanced Photonics Research, 4, 2200218(2023).

[20] YAMADA I, KINTAKA K, NISHII J et al. Transmittance enhancement of a wire-grid polarizer by antireflection coating[J]. Applied Optics, 48, 316-320(2009).

[21] CHEN Ying, WANG Jie, GAO Tao et al. Fabrication of large-scale free-standing terahertz wire grid polarizer by femtosecond laser micro-machining[J]. Laser & Optoelectronics Progress, 57, 308-312(2020).

[22] WANG B, LI H T, SHU W H et al. Improving the extinction ratio by a novel sandwiched two-layer grating polarizer[J]. Modern Physics Letters B, 29, 1550057(2015).