Study on Broad Spectrum Photoelectric Properties of Graphene MIS Junction

Bei Li; Changlong Cai; Haifeng Liang; Feihu Fan; Ben Tu

doi:10.3788/LOP202259.1904001

[1] Zeng L H, Wang M Z, Hu H et al. Monolayer graphene/germanium Schottky junction as high-performance self-driven infrared light photodetector[J]. ACS Applied Materials & Interfaces, 5, 9362-9366(2013).

[2] Liu W, Ye Z H. Development of infrared photoelectric detectors abroad[J]. Laser and Infrared, 41, 365-370(2011).

[3] Yang F, Cong H, Yu K et al. Ultrathin broadband germanium-graphene hybrid photodetector with high performance[J]. ACS Applied Materials & Interfaces, 9, 13422-13429(2017).

[4] Arakawa Y, Nakamura T, Urino Y et al. Silicon photonics for next generation system integration platform[J]. IEEE Communications Magazine, 51, 72-77(2013).

[5] Fang X Y. Study on graphene/silicon Schottky junction photodetector[D], 15-17(2020).

[6] Yang Q. Optical response characteristics of graphene laminated structure and dual-band detection method[D], 25-20(2020).

[7] Jin W Z, Zhao H X, Ding Z Q et al. Research progress of graphene photodetectors[J]. Journal of Ningbo University of Technology, 31, 1-7(2019).

[8] Yao J, Miao X, Wang S et al. Preparation of graphene-MoS2 vertical heterojunction for high-responsivity photodetectors[J]. Laser & Optoelectronics Progress, 58, 1516024(2021).

[9] Periyanagounder D, Gnanasekar P, Varadhan P et al. High performance, self-powered photodetectors based on a graphene/silicon Schottky junction diode[J]. Journal of Materials Chemistry C, 6, 9545-9551(2018).

[10] Kim C, Yoo T J, Chang K E et al. Highly responsive near-infrared photodetector with low dark current using graphene/germanium Schottky junction with Al2O3 interfacial layer[J]. Nanophotonics, 10, 1573-1579(2021).

[11] Cai W, Wang C, Fang X H et al. Progress in transfer technologies and related supporting materials for graphene film synthesized by chemical vapor deposition[J]. Materials for Mechanical Engineering, 39, 7-13(2015).

[12] Card H C, Rhoderick E H. Studies of tunnel MOS diodes I. Interface effects in silicon Schottky diodes[J]. Journal of Physics D: Applied Physics, 4, 1589-1601(1971).

[13] Kim S, Jo I, Dillen D C et al. Direct measurement of the Fermi energy in graphene using a double-layer heterostructure[J]. Physical Review Letters, 108, 116404(2012).

[14] Henni Y, Ojeda Collado H P, Nogajewski K et al. Rhombohedral multilayer graphene: a magneto-Raman scattering study[J]. Nano Letters, 16, 3710-3716(2016).

[15] Giovannetti G, Khomyakov P A, Brocks G et al. Doping graphene with metal contacts[J]. Physical Review Letters, 101, 026803(2008).

[16] Wang W M, Shi Y C, Zakharov A A et al. Flat-band electronic structure and interlayer spacing influence in rhombohedral four-layer graphene[J]. Nano Letters, 18, 5862-5866(2018).

[17] Xie C, Mak C, Tao X M et al. Photodetectors based on two-dimensional layered materials beyond graphene[J]. Advanced Functional Materials, 27, 1603886(2017).

[18] Gan T. Photoelectric properties of graphene and its detector technology[D], 22-60(2016).

[19] Zhu M. Study on the performance of graphene/silicon heterojunction photodetector[D], 35-40(2015).