Co3O4@BiVO4复合薄膜的制备及其光电性能

摘要/Abstract

摘要： 本文以FTO导电玻璃作为基底,通过水热法成功制备出了形貌可控的Co₃O₄薄膜样品,利用制备出的Co₃O₄薄膜样品作为基底,控制旋涂BiVO₄的次数,在其表面成功制得不同BiVO₄量的Co₃O₄@BiVO₄复合薄膜样品。利用X射线衍射仪(XRD)和场发射扫描电子显微镜(FESEM)等对复合薄膜的物相和微观形貌进行分析,并采用UV-3600紫外-可见分光光度计和电化学工作站对其光吸收性能和光电性能进行了测定。结果表明:所制备的Co₃O₄@BiVO₄复合薄膜表面连续、均匀、致密;相较于纯Co₃O₄薄膜,Co₃O₄@BiVO₄复合薄膜的光吸收能力增强;光照下Co₃O₄@BiVO₄复合薄膜的光电性能优于纯Co₃O₄薄膜;经旋涂三次的Co₃O₄@BiVO₄-3复合薄膜光电性能最佳,其最大光电流约为纯Co₃O₄薄膜最大光电流的18.4倍,该器件响应度为105.5 μA/W,探测率可达1.988×10¹¹ Jones。

关键词: Co₃O₄, BiVO₄, 复合薄膜, 光电性能, 光电流, 探测率

Abstract: In this paper, FTO conductive glass was used as a substrate to successfully prepare Co₃O₄ thin films with controlled morphology by hydrothermal method. Using the prepared Co₃O₄ thin films as the base, Co₃O₄@BiVO₄ composite thin films with varying amounts of BiVO₄ were successfully prepared by controlling the number of spin-coating cycles. The phase composition and microstructure were analyzed using X-ray diffraction (XRD) and field-emission scanning electron microscopy (FESEM). Additionally, their optical absorption and photoelectric properties were measured using a UV-3600 UV-Vis spectrophotometer and an electrochemical workstation. Results indicate that, based on the XRD patterns of the Co₃O₄@BiVO₄ composite thin films, the composite materials were successfully prepared. From the FESEM images, it can be observed that the prepared Co₃O₄@BiVO₄ composite thin films possess a continuous, uniform, and dense surface, with the Co₃O₄ thin films growing uniformly as nanowires, and the spin-coated BiVO₄ uniformly coating the surfaces of Co₃O₄ nanowires in a block-like manner. The optical absorption spectrum reveals enhanced light absorption of the Co₃O₄@BiVO₄ composite thin films compared to pure Co₃O₄ thin films. Under zero bias voltage and illumination, the photoelectrical performance of the Co₃O₄@BiVO₄ composite thin films surpasses that of pure Co₃O₄ thin films. Electrochemical test results demonstrate that the Co₃O₄@BiVO₄-3 composite thin films, which were spun-coated three times, showing optimal photoelectrical performance, with a maximum photocurrent approximately 18.4 times that of pure Co₃O₄ thin films. The responsivity of the device is 105.5 μA/W, with a detectivity of up to 1.988×10¹¹ Jones.

Key words: Co₃O₄, BiVO₄, composite film, photoelectric property, photocurrent, detectivity

中图分类号:

TB383.2

从文博, 彭韶龙, 王航, 李丽华, 黄金亮. Co₃O₄@BiVO₄复合薄膜的制备及其光电性能[J]. 人工晶体学报, 2024, 53(10): 1729-1737.

CONG Wenbo, PENG Shaolong, WANG Hang, LI Lihua, HUANG Jinliang. Preparation and Photoelectric Properties of Co₃O₄@BiVO₄ Composite Thin Films[J]. JOURNAL OF SYNTHETIC CRYSTALS, 2024, 53(10): 1729-1737.

参考文献

[1] 金雨玲, 李林丽, 刘亚靖, 等. 高活性Co₃O₄/Fe₃O₄复合纳米材料的制备及其热催化性能研究[J]. 功能材料, 2023, 54(8): 8157-8162+8171.
JIN Y L, LI L L, LIU Y J, et al. Preparation andthermocatalytic properties of highly active Co₃O₄/Fe₃O₄ composite nanomaterials[J]. Journal of Functional Materials, 2023, 54(8): 8157-8162+8171 (in Chinese).
[2] 冯淑鑫, 冯姗, 石鸿定, 等. 四氧化三钴光催化剂的研究进展[J]. 化工管理, 2023(1): 94-96+112.
FENG S X, FENG S, SHI H D, et al. Research progress of cobalt trioxide photocatalyst[J]. Chemical Enterprise Management, 2023(1): 94-96+112 (in Chinese).
[3] ABU-MELHA S. Remarkable effect of single-doped and double-doped nano Co₃O₄ on the photodegradation of dianix blue dye[J]. Journal of Cluster Science, 2024, 35(2): 405-417.
[4] 张政煜. Co基非均相催化剂活化PMS去除有机污染物的进展[J]. 广州化学, 2022, 47(5): 9-17.
ZHANG Z Y. Progress of activation peroxymonosulfate by cobalt-based heterogeneous for removal of organic pollutants[J]. Guangzhou Chemistry, 2022, 47(5): 9-17 (in Chinese).
[5] WU T T, DAI G L, XU J J, et al. Structural design of organic battery electrode materials: from DFT to artificial intelligence[J]. Rare Metals, 2023, 42(10): 3269-3303.
[6] PARK B, HAN M, PARK J, et al. A photoacoustic finder fully integrated with a solid-state dye laser and transparent ultrasound transducer[J]. Photoacoustics, 2021, 23: 100290.
[7] WU H Z, FU S F, WANG S H, et al. Electrical current visualization sensor based on magneto-electrochromic effect[J]. Nano Energy, 2022, 98: 107226.
[8] WANG Z L, WEI Y B, YANG D S. Bioinspired nanochannel-assisted broadband absorber for solar energy harvesting[J]. Plasmonics, 2023, 18(6): 2177-2186.
[9] KIM J H, LEE J S. Elaborately modified BiVO₄ photoanodes for solar water splitting[J]. Advanced Materials, 2019, 31(20): e1806938.
[10] JO W J, KANG H J, KONG K J, et al. Phase transition-induced band edge engineering of BiVO₄ to split pure water under visible light[J]. Proceedings of the National Academy of Sciences of the United States of America, 2015, 112(45): 13774-13778.
[11] LONG M C, CAI W M, CAI J, et al. Efficient photocatalytic degradation of phenol over Co₃O₄/BiVO₄ composite under visible light irradiation[J]. The Journal of Physical Chemistry B, 2006, 110(41): 20211-20216.
[12] CHANG X X, WANG T, ZHANG P, et al. Enhanced surface reaction kinetics and charge separation of p-n heterojunction Co₃O₄/BiVO₄ photoanodes[J]. Journal of the American Chemical Society, 2015, 137(26): 8356-8359.
[13] WANG Y L, YU D, WANG W, et al. Synthesizing Co₃O₄-BiVO4/g-C₃N₄ heterojunction composites for superior photocatalytic redox activity[J]. Separation and Purification Technology, 2020, 239: 116562.
[14] 李蒋, 王雁, 张秀芳, 等.Co₃O₄/BiVO₄复合阳极活化过一硫酸盐强化光电催化降解双酚A[J]. 环境科学, 2018, 39(8): 3713-3718.
LI J, WANG Y, ZHANG X F, et al. Enhancement of photoelectrocatalytic degradation of bisphenol A with peroxymonosulfate activated by a Co₃O₄/BiVO₄ composite photoanode[J]. Environmental Science, 2018, 39(8): 3713-3718 (in Chinese).
[15] LI J, WANG Y, ZHAO S, et al. Electrospun nanostructured Co₃O₄/BiVO₄ composite films for photoelectrochemical applications[J]. Journal of Colloid and Interface Science, 2019, 539: 442-447.
[16] HOU C C, LI T T, CHEN Y, et al. Improved photocurrents for water oxidation by using metal-organic framework derived hybrid porous Co₃O₄@carbon/BiVO₄ as a photoanode[J]. ChemPlusChem, 2015, 80(9): 1465-1471.
[17] SOBAHI T R, AMIN M S, MOHAMED R M. Photocatalytic degradation of methylene blue dye by F-doped Co₃O₄ nanowires[J]. Desalination and Water Treatment, 2017, 74: 346-353.
[18] KIM J H, LEE J S. BiVO₄-based heterostructured photocatalysts for solar water splitting: a review[J]. Energy and Environment Focus, 2014, 3(4): 339-353.
[19] NI S M, GUO F Y, WANG D B, et al. Effect of MgO surface modification on the TiO₂ nanowires electrode for self-powered UV photodetectors[J]. ACS Sustainable Chemistry & Engineering, 2018, 6(6): 7265-7272.
[20] WANG H, WANG H, LI L H, et al. Self-powered broadband photodetectors material based on Co₃O₄-ZnO heterojunction with bottlebrush nanostructure[J]. ACS Applied Electronic Materials, 2023, 5(6): 3224-3231.
[21] OMNÈS F, MONROY E, MUÑOZ E, et al. Wide bandgap UV photodetectors: a short review of devices and applications[C]//SPIE Proceedings, Gallium Nitride Materials and Devices II. San Jose, CA. SPIE, 2007: 111-125.
[22] HUI Q, LI Q K, WANG S, et al. Highly efficient flexible BiVO₄ thin-film photodetector with good bending robustness on mica substrates[J]. The Journal of Physical Chemistry C, 2023, 127(36): 18219-18226.
[23] HAN Z Y, DAI M J, ZENG Z C, et al. Highly stable and fast response photodetector based on double perovskite Cs₂AgBiCl₆ crystals[J]. Journal of Physics D Applied Physics, 2024, 57(21): 215102.
[24] KATHIRVEL A, UMA MAHESWARI A, BATABYAL S K, et al. BiFeO₃-thiourea/carbon heterostructure based self-powered white light photodetector[J]. Materials Letters, 2021, 284: 128906.
[25] YIN Z H, ZENG Y, YANG D M, et al. Multifunctional optoelectronic device based on CuO/ZnO heterojunction structure[J]. Journal of Luminescence, 2023, 257: 119762.

Co₃O₄@BiVO₄复合薄膜的制备及其光电性能

Preparation and Photoelectric Properties of Co₃O₄@BiVO₄ Composite Thin Films

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