[1] Chang S C, Bharathan J, Yang Y, et al. Dual-color polymer light-emitting pixels processed by hybrid inkjet printing ［J］.Appl. Phys. Lett. 1998, 73(18):2561-2563.

[2] Guo L H, Xu S H, Ma X M, et al. Dual-color plasmonic enzymelinked immunosorbent assay based on enzyme-mediated etching of Au nanoparticles ［J］, Scientific Reports, 2016, 6:32755.

[3] Wang P, Liu S S, Luo W J, et al. Arrayed van der Waals Broadband detectors for Dual band detection［J］. Advanced Materials, 2017, 29(16):1604439.

[4] Hu W D, Ye Z H, Liao L, et al. A 128×128 long-wavelength/mid-wavelength two-color HgCdTe infrared focal plane array detector with ultra-low spectral crosstalk ［J］. Optics Letters, 2014,39(17):5130-5133.

[5] Rajavel R D, Jamba D M, Jensen J E, et al. Molecular beam epitaxial growth and performance of HgCdTe-based simultaneous-mode two-color detectors ［J］. Journal of Electronic Materials, 1998, 27(6): 747-751.

[6] Reine M B, Hairston A, O’Dette P, et al. Simultaneous MW/LW dual-band MOCVD HgCdTe 64×64 FPAs［J］. Proceedings of SPIE, 1998, 3379: 200-212.

[7] Rajavel R D, Jamba D M, Jensen J E, et al. Molecular beam epitaxial growth and performance of integrated multispectral HgCdTe photodiodes for the detection of mid-wave infrared radiation ［J］. Journal of Crystal Growth, 1998,184:1272-1278.

[8] Tennant W E, Thomas M, Kozlowski L J, et al. A novel simultaneous unipolar multispectral integrated technology approach for HgCdTe IR detectors and focal plane arrays ［J］. Journal of Electronic Materials, 2001, 30(6):590-594.

[9] Schneider H, Maier T, Fleissner J, et al. Infrared focal plane array based on MWIR/LWIR dual-band QWIPs: detector optimization and array properties ［J］. Proceedings of SPIE, 2005, 5726: 35-42.

[10] Gunapala S D, Bandara S V, Liu J K,et al. Demonstration of Megapixel Dual-Band QWIP Focal Plane Array ［J］. IEEE Journal of Quantum Electronics, 2010, 46(2):285-293.

[11] Li X, Zhu C X, Zhu X, et al. Background limited ultraviolet photodetectors of solar-blind ultraviolet detection ［J］. Applied Physics Letters, 2013, 103(17):896-630.

[12] Williams D L, Davey S T, Kashyap R, et al. Ultraviolet absorption studies on photosensitive germanosilicate preforms and fibers ［J］. Appl. Phys. Lett. 1991, 59(7):762-764.

[13] Liu X, Jiang L, Zou X, et al. Scalable integration of indium zinc oxide/photosensitive-nanowire composite thin-film transistors for transparent multicolor photodetectors array ［J］. Advanced Materials, 2014, 26(18):2919-2924.

[14] Miao J S, Hu W D, Guo N, et al. High-responsivity Graphene/InAs nanowire Heterojunction near-Infrared photodetectors with distinct photocurrent On/Off ratios ［J］. Small, 2015, 11(8):936-942.

[15] Qin Q, Zhu X C, Yang W Y. The development of Pt/CdS schottky barrier ultraviolet detector ［J］. Infrared Technology, 2006, 28(4):234-237.

[16] Forsyth N M, Dharmadasa I M, Sobiesierski Z, et al. Schottky barrier to CdS and their important in Schottky barrier theories ［J］. Semiconductor Science and Technology,1989, 4(1):57.

[18] Sondheimer E H. The mean free path of electrons in metals ［J］. Advances in Physics, 1952,1(1):1-42.

[19] Fischer G, Hoffmann H. Oscillations of the electrical conductivity with film thickness in very thin platinum films ［J］. Solid State Commun. 1980,35:793-796.

[20] Marcos de Oliveira Melo, Luciana Almeida Silva. Visible light-induced hydrogen production from glycerol aqueous solution on hybrid Pt-CdS-TiO2 photocatalysts ［J］. Journal of Photochemistry and Photobiology A:Chemistry, 2011, 226: 36-41.

[21] Ashley T, Baker I M, Burke T M, et al. InSb focal plane array (FPAs) grown by molecular beam epitaxy (MBE) ［J］. Proceedings of SPIE, 2000, 4028:398-403.

[22] Bai J, Hu W D, Guo N, et al. Performance optimization of InSb infrared focal-plane arrays with diffractive microlenses ［J］. Journal of Electronic Materials, 2014, 43(8): 2795-2801.

[23] Guo N, Hu W D, Chen X S, et al. Investigation of radiation collection by the InSb infrared focal plane arrays with micro-optic structures ［J］. Journal of Electronic Materials,2013, 42:3181-3185.