Semiconductor Optoelectronics, Volume. 45, Issue 3, 420(2024)
Preparation and UV Photodetection Properties of a Co3O4/Fe2O3 Heterojunction Composite
[3] [3] LiCX ,Liu Y T ,Zhang K ,et al. Study on multiple receiver systems in non-line-of-sightultravioletcommunication systems [J] . J. of China Univ. Posts Telecommun. ,2014 ,21(2) :104-108.
[4] [4] Ulianova V ,Zazerin A ,Pashkevich G ,et al. High performance ultraviolet radiation sensors based on zinc oxide nanorods[J] . Sens. Actuators ,A ,2015 ,234: 113-119.
[10] [10] Hu J ,Chen J ,Ma T ,et al. Research advances in ZnO nanomaterials-based UV photode tectors: A review [ J] . Nanotechnology ,2023 ,34(23) : 232002.
[11] [11] LiZ ,Yan T ,Fang X. Low-dimensional wide-bandgap semiconductors for UV photodetectors [ J] . Nat. Rev. Mater. ,2023 ,8(9) : 587-603.
[13] [13] PatelM ,Kumar M ,Kim H S ,et al. Reactive sputtering growth of Co3O4 thin films for all metal oxide device: a semitransparent and self-powered ultraviolet photodetector [J] . Mater. Sci. Semicond. Process. ,2018 ,74: 74-79.
[14] [14] LiM H ,Oh W D ,Lin K Y A ,et al. Development of 3- dimensional Co3O4 catalysts with various morphologies for activation of oxone to degrade 5-sulfosalicylic acid in water [J] . Sci. TotalEnviron. ,2020 ,724: 138032.
[15] [15] Ren Q ,Mo S ,Peng R ,et al. Controllable synthesis of 3D hierarchical Co3O4 nanocatalysts with various morphologies for the catalytic oxidation of toluene[J] . J. Mater. Chem. A ,2018 ,6(2) : 498-509.
[16] [16] Liu W ,Liu R ,Zhang X. Controllable synthesis of 3D hierarchical Co3O4 catalysts and their excellent catalytic performance for toluene combustion[J] . Appl. Surf. Sci. ,2020 ,507: 145174.
[17] [17] Kong Q ,Feng W ,Xie X ,et al. Morphology-controlled synthesis ofCo3O4 materials and its electrochemical catalytic properties towards oxygen evolution reaction[ J] . Catal. Lett. ,2018 ,148(12) : 3771-3778.
[18] [18] SabouriZ ,LabbafS ,KarimzadehF ,et al. Fe3O4/bioactive glass nanostructure: A promising therapeutic platform for osteosarcoma treatment[J] . Biomed. Mater. ,2021 ,16(3) :035016.
[19] [19] Zhu B ,Song D ,Jia T ,et al. Effective visible lightdriven photocatalytic degradation of ciprofloxacin overflower-like Fe3O4/Bi2WO6 composites[J] . ACS Omega ,2021 ,6(2) : 1647-1656.
[20] [20] Chao G ,Zhang L ,Tian J ,et al. Pd-SnO2 : Heterojunction catalysts anchored on graphene sheets for enhanced oxygen reduction[J] . Compos. Commun. ,2021 ,25: 100703.
[21] [21] ShaM A ,Meenu P C ,SumiV S ,et al. Tuning of electron transferby Ni-P decoration on CeO2-TiO2 heterojunction for enhancement in photocatalytic hydrogengeneration [ J ] . Mater. Sci. Semicond. Process. ,2020 ,105: 104742.
[22] [22] Wang F ,Ou R ,Yu H ,et al. Photoelectrocatalytic PNP removal using C3N4 nanosheets/α-Fe2O3 nanoarrays photoanode: Performance ,mechanism and degradation pathways[J] . Appl. Surf. Sci. ,2021 ,565: 150597.
[24] [24] Kuryatkov V ,Chandolu A ,Borisov B ,et al. Solar-blind ultraviolet photodetectors based on superlattices of AlN/AlGa(In) N[J] . Appl. Phys. Lett. ,2003 ,82(9) : 1323-1325.
[25] [25] Han M ,HuL ,Zhou Y ,etal. Z-schemein a Co3 (PO4) 2/α- Fe2O3 photocatalysis system foroverallwatersplitting under visiblelight[J] . Catal. Sci. Technol. ,2018 ,8(3) : 840-846.
[26] [26] Yan S ,ShiY ,Tao Y ,et al. Enhanced persulfate-mediated photocatalytic oxidation of bisphenol A using bioelectricity and a g-C3N4/Fe2O3 heterojunction[J] . Chem. Eng. J. ,2019 ,359: 933-943.
[27] [27] Yang Y ,Zhu C ,Zhang Y ,et al. Construction of Co3O4/ Fe2O3 nanosheets on nickel foam as efficient electrocatalyst for the oxygen evolution reaction[J] . J. Phys. Chem. Solids ,2021 ,148: 109680.
[28] [28] Liu W ,Xiang W ,Guan N ,et al. Enhanced catalytic performance for toluene purification over Co3O4/MnO2 catalyst through the construction of different Co3O4-MnO2 interface[J] . Sep. Purif. Technol. ,2022 ,278: 119590.
[29] [29] MahalaP ,Patel M ,Ban D K ,et al. High-performing self- driven ultravioletphotodetectorbyTiO2/Co3O4 photovoltaics [J] . J. Alloys Compd. ,2020 ,827: 154376.
[30] [30] Duan B ,MeiL. A Z-scheme Fe2O3/g-C3N4 heterojunction for carbon dioxide to hydrocarbon fuel under visible illuminance[J] . J. ColloidInterf. Sci. ,2020 ,575: 265-273.
[31] [31] Zhao B ,Wang F ,Chen H ,et al. An ultrahigh responsivity ( 9. 7 mA · W- 1 ) self-powered solar-blind photodetector based on individual ZnO-Ga2O3 heterostructures[J] . Adv. Funct. Mater. ,2017 ,27: 1700264.
[32] [32] Boruah BD ,Misra A. Energy-efficient hydrogenated zinc oxide nanoflakes for high performance self-powered ultravioletphotodetector[J] . ACSAppl. Mater. Interfaces ,2016 ,8(28) : 18182-18188.
[33] [33] Chen H ,YuP ,Zhang Z ,et al. Ultrasensitive self-powered solar-blind deep-ultraviolet photodetector based on all-solid- state polyaniline/MgZnO bilayer[J] . Small ,2016 ,12(42) :5809-5816.
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LILihua, PENG Shaolong, CONG Wenbo, WANG Hang, WANG Yuxin, HUANG Jinliang. Preparation and UV Photodetection Properties of a Co3O4/Fe2O3 Heterojunction Composite[J]. Semiconductor Optoelectronics, 2024, 45(3): 420
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Received: Jan. 2, 2024
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Published Online: Oct. 15, 2024
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