[1] Lightsey P A, Atkinson C, Clampin M et al. James Webb Space Telescope: large deployable cryogenic telescope in space[J]. Optical Engineering, 51, 011003(2012).

[2] Stubbs C W, High F W, George M R et al. Toward more precise survey photometry for PanSTARRS and LSST: measuring directly the optical transmission spectrum of the atmosphere[J]. Publications of the Astronomical Society of the Pacific, 119, 1163-1178(2007).

[3] Simard L, Crampton D, Ellerbroek B et al. The TMT instrumentation program[J]. Proceedings of SPIE, 7735, 773523(2010).

[4] Mouroulis P, Wilson D W, Maker P D et al. Convex grating types for concentric imaging spectrometers[J]. Applied Optics, 37, 7200-7208(1998).

[5] Chen H Y, Chen X H, Pan Q et al. Design of total internal reflection immersed gratings with high diffraction efficiency and low polarization sensitivity[J]. Acta Optica Sinica, 43, 2205003(2023).

[6] Oka K, Yamada A, Komai Y et al. Optimization of a volume phase holographic grism for astronomical observation using a photopolymer[J]. Proceedings of SPIE, 5005, 8-19(2003).

[7] Baldry I K, Bland-Hawthorn J, Robertson J G. Volume phase holographic gratings: polarization properties and diffraction efficiency[J]. Publications of the Astronomical Society of the Pacific, 116, 403-414(2004).

[8] Barden C S, Arns A J, Colburn S W. Volume-phase holographic gratings and their potential for astronomical applications[J]. Proceedings of SPIE, 3355, 866-876(1998).

[9] Arns J A, Colburn W S, Barden S C. Volume phase gratings for spectroscopy, ultrafast laser compressors, and wavelength division multiplexing[J]. Proceedings of SPIE, 3779, 313-323(1999).

[10] Saunders W, Flügel-Paul T, Zhang K. Higher dispersion and efficiency Bragg gratings for optical spectroscopy[J]. Proceedings of SPIE, 10706, 107065C(2018).

[11] Zhang K, Xin Q, Wang L et al. Mauna Kea Spectrographic Explorer (MSE): a new optical design for the multi-object high-resolution spectrograph[J]. Proceedings of SPIE, 12184, 121847O(2022).

[12] Zeitner U D, Dekker H, Burmeister F et al. High efficiency transmission grating for the ESO CUBES UV spectrograph[J]. Experimental Astronomy, 55, 281-300(2023).

[13] Zhou C, Seki T, Sukegawa T et al. Large-scale, high-efficiency transmission grating for terawatt-class Ti: sapphire lasers at 1 kHz[J]. Applied Physics Express, 4, 072701(2011).

[14] Zhou C, Seki T, Kitamura T et al. Wavefront analysis of high-efficiency, large-scale, thin transmission gratings[J]. Optics Express, 22, 5995-6008(2014).

[15] Wang Y N, Chen Z W, Cai M Q et al. High-efficiency broadband polarization-independent binary fused silica gratings for large astronomical telescopes[J]. Applied Optics, 60, 9925-9932(2021).

[16] Li Q F, Xu G W, Li J et al. Fabrication of X-ray absorption gratings by filling tungsten nanoparticles[J]. Semiconductor Optoelectronics, 40, 786-788, 890(2019).

[17] Wang Q, Ding Y, Tan C et al. Dual resonance temperature sensor of a long-period grating written in a liquid-filled photonic crystal fiber[J]. Journal of Quantum Optics, 24, 84-92(2018).

[18] Gao Y, Dong B C, Tan C et al. Three-parameter measurement based on cascaded Bragg gratings in magnetic fluid-infiltrated photonic crystal fiber[J]. Journal of Optoelectronics·Laser, 28, 1344-1350(2017).

[19] Collin R E. Reflection and transmission at a slotted dielectric interface[J]. Canadian Journal of Physics, 34, 398-411(1956).

[20] Rytov S M. Electromagnetic properties of a finely stratified medium[J]. Journal of Experimental and Theoretical Physics of the Academy of Sciences of the USSR, 2, 466-475(1956).

[21] Clausnitzer T, Limpert J, Zöllner K et al. Highly efficient transmission gratings in fused silica for chirped-pulse amplification systems[J]. Applied Optics, 42, 6934-6938(2003).

[22] Clausnitzer T, Kley E B, Tünnermann A et al. Ultra low-loss low-efficiency diffraction gratings[J]. Optics Express, 13, 4370-4378(2005).

[23] Tishchenko A V. Phenomenological representation of deep and high contrast lamellar gratings by means of the modal method[J]. Optical and Quantum Electronics, 37, 309-330(2005).

[24] Clausnitzer T, Kämpfe T, Kley E B et al. An intelligible explanation of highly-efficient diffraction in deep dielectric rectangular transmission gratings[J]. Optics Express, 13, 10448-10456(2005).

[25] Roden J A, Gedney S D. Convolution PML (CPML): an efficient FDTD implementation of the CFS-PML for arbitrary media[J]. Microwave and Optical Technology Letters, 27, 334-339(2000).

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

[27] Clausnitzer T, Kämpfe T, Kley E B et al. Investigation of the polarization-dependent diffraction of deep dielectric rectangular transmission gratings illuminated in Littrow mounting[J]. Applied Optics, 46, 819-826(2007).

[28] Feng J J, Zhou C H, Zheng J J et al. Modal analysis of deep-etched low-contrast two-port beam splitter grating[J]. Optical Communication, 281, 5298-5301(2008).

[29] Zhao H J[M]. Subwavelength grating optics, 30-39(2017).

[30] Macleod H A[M]. Thin-film optical filters, 72-90(2016).