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  • 标题:Efficient MoWO 3 /VO 2 /MoS 2 /Si UV Schottky photodetectors; MoS 2 optimization and monoclinic VO 2 surface modifications
  • 本地全文:下载
  • 作者:Mohamed A. Basyooni ; Shrouk E. Zaki ; Mohamed Shaban
  • 期刊名称:Scientific Reports
  • 电子版ISSN:2045-2322
  • 出版年度:2020
  • 卷号:10
  • 期号:1
  • 页码:1-18
  • DOI:10.1038/s41598-020-72990-9
  • 出版社:Springer Nature
  • 摘要:The distinctive properties of strongly correlated oxides provide a variety of possibilities for modulating the properties of 2D transition metal dichalcogenides semiconductors; which represent a new class of superior optical and optoelectronic interfacing semiconductors. We report a novel approach to scaling-up molybdenum disulfide (MoS2) by combining the techniques of chemical and physical vapor deposition (CVD and PVD) and interfacing with a thin layer of monoclinic VO2. MoWO3/VO2/MoS2 photodetectors were manufactured at different sputtering times by depositing molybdenum oxide layers using a PVD technique on p-type silicon substrates followed by a sulphurization process in the CVD chamber. The high quality and the excellent structural and absorption properties of MoWO3/VO2/MoS2/Si with MoS2 deposited for 60 s enables its use as an efficient UV photodetector. The electronically coupled monoclinic VO2 layer on MoS2/Si causes a redshift and intensive MoS2 Raman peaks. Interestingly, the incorporation of VO2 dramatically changes the ratio between A-exciton (ground state exciton) and trion photoluminescence intensities of VO2/(30 s)MoS2/Si from 1. By increasing the deposition time of MoS2 from 60 to 180 s, the relative intensity of the B-exciton/A-exciton increases, whereas the lowest ratio at deposition time of 60 s refers to the high quality and low defect densities of the VO2/(60 s)MoS2/Si structure. Both the VO2/(60 s)MoS2/Si trion and A-exciton peaks have higher intensities compared with (60 s) MoS2/Si structure. The MoWO3/VO2/(60 s)MoS2/Si photodetector displays the highest photocurrent gain of 1.6, 4.32 × 108 Jones detectivity, and ~ 1.0 × 1010 quantum efficiency at 365 nm. Moreover, the surface roughness and grains mapping are studied and a low semiconducting-metallic phase transition is observed at ~ 40 °C.
  • 其他摘要:Abstract The distinctive properties of strongly correlated oxides provide a variety of possibilities for modulating the properties of 2D transition metal dichalcogenides semiconductors; which represent a new class of superior optical and optoelectronic interfacing semiconductors. We report a novel approach to scaling-up molybdenum disulfide (MoS 2 ) by combining the techniques of chemical and physical vapor deposition (CVD and PVD) and interfacing with a thin layer of monoclinic VO 2 . MoWO 3 /VO 2 /MoS 2 photodetectors were manufactured at different sputtering times by depositing molybdenum oxide layers using a PVD technique on p-type silicon substrates followed by a sulphurization process in the CVD chamber. The high quality and the excellent structural and absorption properties of MoWO 3 /VO 2 /MoS 2 /Si with MoS 2 deposited for 60 s enables its use as an efficient UV photodetector. The electronically coupled monoclinic VO 2 layer on MoS 2 /Si causes a redshift and intensive MoS 2 Raman peaks. Interestingly, the incorporation of VO 2 dramatically changes the ratio between A-exciton (ground state exciton) and trion photoluminescence intensities of VO 2 /(30 s)MoS 2 /Si from  1. By increasing the deposition time of MoS 2 from 60 to 180 s, the relative intensity of the B-exciton/A-exciton increases, whereas the lowest ratio at deposition time of 60 s refers to the high quality and low defect densities of the VO 2 /(60 s)MoS 2 /Si structure. Both the VO 2 /(60 s)MoS 2 /Si trion and A-exciton peaks have higher intensities compared with (60 s) MoS 2 /Si structure. The MoWO 3 /VO 2 /(60 s)MoS 2 /Si photodetector displays the highest photocurrent gain of 1.6, 4.32 × 10 8 Jones detectivity, and ~ 1.0 × 10 10 quantum efficiency at 365 nm. Moreover, the surface roughness and grains mapping are studied and a low semiconducting-metallic phase transition is observed at ~ 40 °C.
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