[1] Gurgenian H K. Another source of MCT detectors[J]. Laser Focus World, 1992, 28: 51.

[2] Reibel Y, Rublado L, Bonnouvrier G, et al. Latest developments in advanced MCT infrared cooled detectors[J]. Electro-Optical and Infrared Systems: Technology and Applications VIII, 2011: 8185: 818503.

[3] Reddy M, Peterson J M, Lofgreen D D, et al. HgCdTe growth on 6 cm×6 cm CdZnTe substrates for large-format dual-band infrared focal-plane arrays[J]. Journal of Electronic Materials, 2010, 39(7): 974-980.

[4] Johnson S M, James J B, Ahlgren W L, et al. Heteroepitaxial HgCdTe/ CdZnTe/Gaas/Si materials for infrared focal plane arrays[J]. Long -wavelength Semiconductor Devices, Materials, and Processes, 1991, 216: 141-146.

[5] SHENG F F, ZHOU C H, SUN S W, et al. Influences of Te-rich and Cd-rich precipitates of CdZnTe substrates on the surface defects of HgCdTe liquid-phase epitaxy materials[J]. J. Electron Mater, 2014, 43: 1397-1402.

[6] Yoshikawa M. Dislocations in Hg1.xCdxTe/Cd1.zZnzTe epilayers grown by liquid-phase epitaxy[J]. J. Appl. Phys., 1988, 63: 1533-1540.

[7] Yoshikawa M. Dislocations in Hg1-xCdxTe/Cd1-zZnzTe epilayers grown by liquid-phase epitaxy[J]. J. Appl. Phys., 1988, 63: 1533-1540.

[8] Sen S, Konkel W H, Tighe S J, et al. Crystal-growth of large-area single-crystal CdTe and CdZnTe by the computer-controlled vertical modified-Bridgman process[J]. J. Cryst Growth, 1988, 86: 111-117.

[10] Rubaldo L, Guinedor P, Brunner A, et al. Achievement of high image quality MCT sensors with Sofradir vertical industrial model[C]//Proc. of SPIE, 2018, 10624: 106240U.

[11] Ahluwalia G K, Patro R. Infrared Detectors[M]. Springer International Publishing, 2017.

[12] Johnson S M, Delyon T J, Cockrum C A, et al. Direct growth of CdZnTe/Si substrates for large-area HgCdTe infrared focal-plane arrays[J]. J. Electron Mater, 1995, 24: 467-473.

[13] Aguirre M, Canepa H, Heredia E, et al. Photovoltaic Hg1-xCdxTe(MCT) detectors for infrared radiation[J]. An Asoc Quim Argent, 1996, 84: 67-72.

[14] Belas E, Buga′r M, Grill R, et al. Elimination of inclusions in (CdZn) Te substrates by post-grown annealing[J]. J. Electron. Mater., 2007, 36: 1025.

[15] YANG G, Bolotnikov A E, Fochuk P M, et al. Post-growth thermal annealing study of CdZnTe for developing room-temperature X-ray and gamma-ray detectors[J]. Journal of Crystal Growth, 2013, 379: 16-20.

[16] YANG G, Bolotnikov A E, Fochuk P M, et al. Effects of thermal annealing on the structural properties of CdZnTe crystals[C]// Proceedings of SPIE-The International Society for Optical Engineering, 2011, 8142(6): 814217.

[17] Segall M D, Lindan P, Probert, M J, et al. First-principles simulation: ideas, illustrations and the CASTEP code[J]. Journal of Physics Condensed Matter, 2002, 14(11): 2717-2744.

[18] Fornes T D, Carruthers S B, Huffman N D. Method for Shielding a Substrate From Electromagnetic Interference[P]. US: PCT/US2010/ 038264[2010-12-16].

[19] Koyama A, Hichiwa A, Hirano R. Recent progress in CdZnTe crystals[J]. Journal of Electronic Materials, 1999, 28: 683-687.