[1] A Rogalski. Recent progress in infrared detector technologies. Infrared Physics & Technology, 54, 136-154(2011).
[2] Lee J, Rodriguez C, Blackwell R. BAE Systems'' 17 mm LWIR camera ce f civil, commercial, military applications [C]SPIE, 2013, 8704: 459464.
[3] R Schmidt, A Basu, A W Brinkman, et al. Electron-hopping modes in NiMn2O4+δ materials. Applied Physics Letters, 86, 73501-73501(2005).
[4] G Zheng, L Jiang, W Zhou, et al. Mechanism of high qualified Mn-Co-Ni-O thin films grown at low temperature. Applied Surface Science, 644, 158672(2024).
[5] Yokoyama T, Abe Y, Meguro T, et al. Preparation electrical properties of sintered bodies composed of monophase spinel Mn_(2–X)Co_2XNi_(1–X)O_4 (0 ≦ X≦ 1) derived from rocksalttype oxides[J]. Japanese Journal of Applied Physics , 1996, 35(11): 57755780.
[6] R Li, Q Fu, X Zou, et al. Mn-Co-Ni-O thin films prepared by sputtering with alloy target. Journal of Advanced Ceramics, 9, 64-71(2020).
[7] R Schmidt, A W Brinkman. Preparation and characterisation of NiMn2O4 films. International Journal of Inorganic Materials, 3, 1215-1217(2001).
[8] Y Q Gao, Z B Zhang, W Zhou, et al. Mechanism of Cu dopant in transition metal oxide Mn1.56Co(0.96-x)Ni0.48CuxO4+δ(0≤x≤0.2) thin films. Thin Solid Films, 701, 137935(2020).
[9] J Wu, Z Huang, Y Hou, et al. Structural, electrical, and magnetic properties of Mn2.52-xCoxNi0.48O4 films. Journal of Applied Physics, 107, 053716(2010).
[10] W Zhou, Y Yin, J Wu, et al. Improvements in electrical properties, low frequency noise and detection performance of a Mn-based bilayer thin film infrared detector. Sensors and Actuators A: Physical, 283, 196-203(2018).
[11] Z Huang, W Zhou, C Ouyang, et al. High performance of Mn-Co-Ni-O spinel nanofilms sputtered from acetate precursors. Scientific Reports, 5, 10899(2015).
[12] Fei Zang, Yangcheng Ou, Wei Zhou, . Annealing effect on the properties of Mn-Co-Ni-O film detector. Journal of Infrared and Millimeter Waves, 35, 287-293(2016).
[13] F Zhang, J Ju, D Huo, et al. Photoelectric and photocatalytic properties of long-time annealing Mn–Co–Ni–O thin film. Journal of Materials Science:Materials in Electronics, 34, 523(2023).
[14] W Kong, W Wei, B Gao, et al. A study on the electrical properties of Mn-Co-Ni-O thin films grown by radio frequency magnetron sputtering with different thicknesses. Applied Surface Science, 423, 1012-1018(2017).
[15] R Schmidt, A Basu, A W Brinkman. Production of NTCR thermistor devices based on NiMn2O4+δ. Journal of the European Ceramic Society, 24, 1233-1236(2004).
[16] J H Wei, W Ren, H Lu, et al. Synthesis of medium entropy Mn1.56Co0.96Ni0.48O4 films by solid-state reaction. Journal of Solid State Chemistry, 306, 122742(2022).
[17] G Ji, A Chang, J Xu, et al. Low-temperature (<300 ℃) growth and characterization of single-[100]-oriented Mn-Co-Ni-O thin films. Materials Letters, 107, 103-106(2013).
[18] W Zhou, J Wu, C Ouyang, et al. Optical properties of Mn-Co-Ni-O thin films prepared by radio frequency sputtering deposition. Journal of Applied Physics, 115, 093512(2014).
[19] J Wu, Z Huang, W Zhou, et al. Investigation of cation distribution, electrical, magnetic properties and their correlation in Mn2–xCo2xNi1–xO4 films. Journal of Applied Physics, 115, 113703(2014).
[20] W Zhou, L Zhang, C Ouyang, et al. Micro structural, electrical and optical properties of highly (220) oriented spinel Mn-Co-Ni-O film grown by radio frequency magnetron sputtering. Applied Surface Science, 311, 443-447(2014).
[21] Y Yin, J Wu, W Zhou, et al. Effects of deposition temperature on microstructure, cation distribution and electrical properties of Mn1.56Co0.96Ni0.48O4 thin films grown by RF magnetron sputtering. Journal of Alloys and Compounds, 822, 153705(2020).
[22] A Stein, S W Keller, T E Mallouk. Turning down the heat: Design and mechanism in solid-state synthesis. Science, 259, 1558-1564(1993).
