[1] [1] William Lawson Donald, Scott Young Alexer. Photosensitive cells, radiation filters semiconduct materials f use in such cells filters: US, 2953690[P]. 19600920.

[2] W D Lawson, S Nielson, E H Putley, et al. Preparation and properties of HgTe and mixed crystals of HgTe-CdTe. Journal of Physics and Chemistry of Solids, 9, 325-329(1959).

[3] [3] Antoni Rogalski. Infrared Detects[M]. 2nd ed. Boca Raton, Flida: CRC Press, 2011.

[4] [4] Rogalski A. Next decade in infrared detects[C]Proc of SPIE, 2017, 10433: 104330 L.

[5] A Rogalski, J Antoszewski, L Faraone. Third-generation infrared photodetector array. Journal of Applied Physics, 105, 091101(2009).

[6] [6] NASA. About Webb Innovations'' Infrared Detects[DBOL]. (20150101) [20220117]. https:www.jwst.nasa.govcontentaboutinnovationsinfrared.htmlutm_source=FBPAGE&utm_medium=NASA%27s+James+Webb+Space+Telescope&utm_campaign=NASASocial&linkId=122682902.

[7] [7] Paul Jerram, James Beletic. Teledyne’s high perfmance infrared detects f Space missions[C]Proc of SPIE, 2018, 11180: 111803 D.

[8] [8] Teledyne Imaging. HAWAII4RG (H4RG) IR Visible FPAs[EBOL]. (20220115) [20220117]. https:www.teledyneimaging.comenaerospacedefenseproductssenssoverviewinfraredhgcdtemcthawaii4 rg.

[9] E A Patten, P M Goetz, M F Vilela, et al. High-performance MWIR/LWIR dual-band 640×480 HgCdTe/Si FPAs. Journal of Electronic Materials, 39, 2215-2219(2010).

[10] P Madejczyk, W Gawron, A Keblowski, et al. Higher operating temperature IR detectors of the MOCVD HgCdTe heterostructures. Journal of Electronic Materials, 49, 6908-6917(2020).

[11] A Rogalski. Material considerations for third generation infrared photon detectors. Infrared Physics & Technology, 50, 240-252(2007).

[12] Lei Wen, Antoszewski Jarek, Faraone Lorenzo. Progress, challenges, and opportunities for HgCdTe infrared materials and detectors. Applied Physics Reviews, 2, 041303(2015).

[13] Kopytko Małgorzata, Kebłowski Artur, Gawron Waldemar, et al. MOCVD grown HgCdTe barrier detectors for MWIR high-operating temperature operation. Optical Engineering, 54, 105105(2015).

[14] A Rogalski. HgCdTe infrared detector material: History, status and outlook. Reports on Progress in Physics, 68, 2267-2336(2005).

[15] [15] Lynne Patrick. Selex ES Detect Developments[EBOL]. (20160110) [20220117]. https:slideplayer.comslide4408122.

[16] [16] Rothman J, de Bniol E, Lasfargues G, et al. HgCdTe APDs f lowphoton number IR detection[C]Proc of SPIE, 2017, 10111: 1011119.

[17] [17] Rothman J, Foubert K, Lasfargues G, et al. High operating temperature SWIR HgCdTe APDs f remote sensing[C]Proc of SPIE, 2014, 9254: 92540 P.

[18] Xiaoli Sun, B Abshire James, A Krainak Michael, et al. HgCdTe avalanche photodiode array IR and visible FPAS lidar applications. Optical Engineering, 58, 067103(2019).

[19] [19] Xiaoli Sun, James B Abshire, Jeffrey D Beck. HgCdTe eAPD detect arrays with single photon sensitivity f space lidar applications[C]Proc of SPIE, 2014, 9114: 91140 K.

[20] X L Sun, J B Abshire, J D Beck, et al. HgCdTe avalanche photodiode detectors for airborne and spaceborne lidar at infrared wavelengths. Optics Express, 25, 16589-16602(2017).