[1] Zadravec D, Franks J W, Rogers K A et al. A multi-spectral optical system (1.55 µm and 8-12 μm) of GASIR®1 design and coating aspects[J]. Proceedings of SPIE, 7298, 72982L(2009).

[2] Pang W, Fu X H, Xing Z et al. High performance infrared antireflection films on ZnS substrate for 8-12 μm[J]. Journal of Changchun University of Science and Technology (Natural Science Edition), 31, 46-47, 39(2008).

[3] Zhao H, Jin Y L, Zu C K et al. Study progress on chalcogenide glasses surface coating technology for temperature adaptive infrared thermal imaging system[J]. Materials Review, 31, 72-76(2017).

[4] Curatu G. Design and fabrication of low-cost thermal imaging optics using precision chalcogenide glass molding[J]. Proceedings of SPIE, 7060, 706008(2008).

[5] Gibson D, Bayya S, Nguyen V et al. GRIN optics for multispectral infrared imaging[J]. Proceedings of SPIE, 9451, 94511P(2015).

[6] Zakery A, Elliott S R. Optical properties and applications of chalcogenide glasses: a review[J]. Journal of Non-Crystalline Solids, 330, 1-12(2003).

[7] Wang J, Wu Y H, Jiang B et al. Application of chalcogenide glass in designing a long wavelength infrared athermalized wide-angle lens[J]. Acta Photonica Sinica, 45, 1211003(2016).

[8] Yang J Q, Peng Q Q, Liu L et al. Design of refractive/diffractive hybrid optical athermalization lens based on chalcogenide glass[J]. Laser & Infrared, 47, 225-229(2017).

[9] Fu Q, Zhang X. Athermalization of the medium-wave infrared optical system based on chalcogenide glasses[J]. Infrared and Laser Engineering, 44, 1467-1471(2015).

[10] Cha D H, Kim H J, Hwang Y et al. Fabrication of molded chalcogenide-glass lens for thermal imaging applications[J]. Applied Optics, 51, 5649-5656(2012).

[11] Shi H D, Zhang X, Qu H M et al. Design of large relative aperture infrared athermalized optical system with chalcogenide glasses[J]. Acta Optica Sinica, 35, 0622002(2015).

[12] Shi G W, Zhang X, Wang L J et al. Application of the new chalcogenide glass in design of low cost thermal imaging systems[J]. Infrared and Laser Engineering, 40, 615-619(2011).

[13] Tang J F, Gu P F, Liu X[M]. Modern optical thin film technology(2006).

[15] Singh P K, Dwivedi D K. Chalcogenide glass: fabrication techniques, properties and applications[J]. Ferroelectrics, 520, 256-273(2017).

[16] Bai Y, Liao Z Y, Li H et al. Application of the chalcogenide glass in modern infrared thermal imaging systems[J]. Chinese Optics, 7, 449-455(2014).

[17] Guimond Y M, Bellec Y. High-precision IR molded lenses[J]. Proceedings of SPIE, 5252, 103-110(2004).

[18] Dai S X, Chen H G, Li M Z et al. Chalcogenide glasses and their infrared optical applications[J]. Infrared and Laser Engineering, 41, 847-852(2012).

[19] Luo S J, Huang F Y, Zhan D J et al. Development of chalcogenide glasses for infrared thermal imaging system[J]. Laser & Infrared, 40, 9-13(2010).

[20] Guimond Y M, Franks J, Bellec Y. Comparison of performances between GASIR molded optics and existing IR optics[J]. Proceedings of SPIE, 5406, 114-120(2004).

[21] Jiang B, Wu Y H, Dai S X et al. Application of chalcogenide glasses in designing vehicle-mounted infrared imaging lens for civilian applications[J]. Infrared and Laser Engineering, 44, 1739-1745(2015).

[22] Lu Y J, Song B A, Dong W et al. Application of chalcogenide glass in car night-vision system[J]. Infrared and Laser Engineering, 43, 2815-2818(2014).

[23] Nath J, Panjwani D, Peale R E et al. Chalcogenide glass thin-film optics for infrared applications[J]. Proceedings of SPIE, 9085, 908507(2014).

[24] Tripathi S, Kumar B, Dwivedi D K. Chalcogenide glasses: thin film deposition techniques and applications in the field of electronics[C](2018).

[25] Shiryaev V S, Sukhanov M V, Velmuzhov A P et al. Core-clad terbium doped chalcogenide glass fiber with laser action at 5.38 μm[J]. Journal of Non-Crystalline Solids, 567, 120939(2021).

[26] Liu S, Tang J Z, Liu Z J et al. Fabrication and properties of low-loss chalcogenide optical fiber based on the extrusion method[J]. Acta Optica Sinica, 36, 1006002(2016).

[27] Zhai C C, Zhang B, Qi S S et al. Fabrication and properties of flexible chalcogenide fiber image bundles[J]. Acta Optica Sinica, 35, 0806005(2015).

[28] Feng X, Yang Z Y, Shi J D. Progress in chalcogenide glass photonic crystal fibers with ultra-large mode area[J]. Chinese Journal of Lasers, 49, 0101006(2022).

[29] Zhang H, Guo H T, Xu Y T et al. Research progress in chalcogenide glass fibers for infrared laser delivery[J]. Chinese Journal of Lasers, 49, 0101007(2022).

[30] Han T R, Fu X H, Jia Z H et al. Study on processing technic of large diameter aspheric chalcogenide glass[J]. Journal of Changchun University of Science and Technology (Natural Science Edition), 40, 60-64(2017).

[31] Liu X L, Li H, Guo Z D et al. Chalcogenide infrared glass polishing process[J]. Journal of Xi’an Technological University, 39, 394-399(2019).

[33] Jiang Y S. Progress in optical glass(4)[J]. Glass & Enamel, 38, 45-50(2010).

[34] Tang K, Kong M H, Li D Y et al. Effect of cooling gap on molding quality of small diameter dual aspherical chalcogenide glass lenses[J]. Infrared and Laser Engineering, 47, 1142001(2018).

[35] Zhang F, Wang Z B, Zhang Y L et al. Ultra-precision molding of chalcogenide glass aspherical lens[J]. Proceedings of SPIE, 9683, 96831I(2016).

[36] Gao C L. Design and research on molding system of chalcogenide glass[D](2019).

[37] Zhou T F, Zhu Z C, Liu X H et al. A review of the precision glass molding of chalcogenide glass (ChG) for infrared optics[J]. Micromachines, 9, 337(2018).

[38] Zhou T F, Xie J Q, Liang Z Q et al. Advances and prospects of molding for optical Microlens array[J]. Chinese Optics, 10, 603-618, 703(2017).

[39] Zhang Y, Yan G P, You K Y et al. Study on α-Al2O3 anti-adhesion coating for molds in precision glass molding[J]. Surface and Coatings Technology, 391, 125720(2020).

[40] Cheng H. Study on the purification and molding technology of chalcogenide glass[D](2017).

[41] Xue G Q. Study on the homogeneity and molding technology of chalcogenide glass[D](2016).

[42] Lin C G, Guo X Y, Wang X F et al. Precision molding of As2Se3 chalcogenide glass aspheric lens[J]. Infrared and Laser Engineering, 48, 0742002(2019).

[43] Huang G Y, Yang R, Chen C et al. Research on precision molding process of Ge-Se-Te chalcogenide glass aspheric lens[J]. Glass, 48, 8-13(2021).

[51] Huddleston J, Novak J, Moreshead W V et al. Investigation of As40Se60 chalcogenide glass in precision glass molding for high-volume thermal imaging lenses[J]. Proceedings of SPIE, 9451, 94511O(2015).

[54] Pan Y G, Liu Z, Wang B et al. Research on film thickness uniformity of electron beam evaporation spherical fixture system[J]. Laser & Optoelectronics Progress, 58, 0531001(2021).

[55] Bao G H, Wang B, Xie Y J et al. Film thickness error in electron beam evaporation with revolving structure[J]. Laser & Optoelectronics Progress, 58, 1131001(2021).

[56] Zhang X H, Guimond Y, Bellec Y. Production of complex chalcogenide glass optics by molding for thermal imaging[J]. Journal of Non-Crystalline Solids, 326/327, 519-523(2003).

[57] Rozé M, Calvez L, Rollin J et al. Optical properties of free arsenic and broadband infrared chalcogenide glass[J]. Applied Physics A, 98, 97-101(2009).

[60] Zhou W C, Zhang L, Yi A Y. Design and fabrication of a compound-eye system using precision molded chalcogenide glass freeform microlens arrays[J]. Optik, 171, 294-303(2018).

[61] Sun Z, Jia M C, Fu Z L et al. High-performance disease diagnosis fluorescent probe based on new type structure YbF3∶Er3+@SiO2@GQDs[J]. Chemical Engineering Journal, 406, 126755(2021).

[62] Guimond Y M, Bellec Y. IR molded optics for thermal imaging[J]. Proceedings of SPIE, 5074, 807-813(2003).

[63] Hilton A R, Kemp S[M]. Chalcogenide glasses for infrared optics, 126(2009).

[64] Fu X H, Jiang H Y, Zhang J et al. Preparation of short and medium wave infrared anti-reflective coating based on chalcogenide glass[J]. Chinese Journal of Lasers, 44, 0903002(2017).

[65] Fu X H, Wang H F, Zhang J et al. Development of infrared antireflection coating for molded chalcogenide glass elements[J]. Acta Optica Sinica, 41, 2031003(2021).

[66] Jin Y L, Fu K H, Zhao H et al. Design and manufacture of infrared antireflection coatings on As40Se60 chalcogenide glass[J]. Bulletin of the Chinese Ceramic Society, 36, 94-97, 121(2017).

[67] Fu X H, Huang H Y, Zhang J et al. Anti-reflection protective film of chalcogenide glass substrate and its environmental adaptability[J]. Acta Optica Sinica, 40, 2131002(2020).

[68] Yu Y. Study of the deposition of DLC film by PECVD[D](2010).

[69] Liu J. Preparation of diamond-like carbon films by RF magnetron sputtering[D](2017).

[70] Park C S, Choi S G, Jang J N et al. Effect of boron and silicon doping on the surface and electrical properties of diamond like carbon films by magnetron sputtering technique[J]. Surface and Coatings Technology, 231, 131-134(2013).

[71] Zhu J Q, Han J C[M]. Infrared antireflective and protective coatings(2015).

[72] Chen Q Y, Shi K M, Su M H et al. Progress of diamond-like carbon films[J]. Journal of Materials Engineering, 45, 119-128(2017).

[73] Cherezova L A, Muranova G A, Mikhaĭlov A V. Antireflection-coating optical items made from materials for the IR range by creating porous microstructures on the surface[J]. Journal of Optical Technology, 79, 121-122(2012).

[75] Rogers K, Ward J, Guimond Y. iDLC: hard coat for chalcogenide glass and other IR materials[J]. Proceedings of SPIE, 6545, 65450V(2007).

[77] Lee J H, Kim H, Lee W H et al. Surface modification of chalcogenide glass for diamond-like-carbon coating[J]. Applied Surface Science, 478, 802-805(2019).

[78] Kim J I, Kim J K, Jang Y J. Stress relaxation through thermal gradient structure of tetrahedral amorphous carbon thin film deposited on Ge-Se-Sb-based chalcogenide glass[J]. Diamond and Related Materials, 100, 107547(2019).

[79] Khajurivala K M. Erosion resistant anti-reflection coating for ZnSe, CZnS, chalcogenide, and glass substrates[J]. Proceedings of SPIE, 8012, 801242(2011).