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Deposition of zinc cobaltite nanoparticles onto bismuth vanadate for enhanced photoelectrochemical water splitting

Majumder, S. and Quang, N.D. and Hung, N.M. and Chinh, N.D. and Kim, C. and Kim, D. (2021) Deposition of zinc cobaltite nanoparticles onto bismuth vanadate for enhanced photoelectrochemical water splitting. Journal of Colloid and Interface Science, 599. pp. 453-466. ISSN 219797

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Abstract

During the past few decades, photoelectrochemical (PEC) water splitting has attracted significant attention because of the reduced production cost of hydrogen obtained by utilizing solar energy. Significant efforts have been invested by the scientific community to produce stable ternary metal oxide semiconductors, which can enhance the stability and increase the overall production of oxygen. Herein, we present the ternary metal oxide deposition of ZnCo2O4 as a route to obtain a novel photocatalyst layer on BiVO4 to form BiVO4/ZnCo2O4 a novel composite photoanode for PEC water splitting. The structural, topographical, and optical analyses were performed using field emission scanning electron microscopy, X-ray diffraction, high-resolution transmission electron microscopy, and UV–Vis spectroscopy to confirm the structure of the ZnCo2O4 grafted over BiVO4. A remarkable 4.4-fold enhancement of the photocurrent was observed for the BiVO4/ZnCo2O4 composite compared with bare BiVO4 under visible illumination. The optimum loading of ZnCo2O4 over BiVO4 yields unprecedented stable photocurrent density with an apparent cathodic shift of 0.46 V under 1.5 AM simulated light illumination. This is also evidenced by the flat-band potential change through Mott–Schottky analysis, which reveals the formation of p-ZnCo2O4 on n-BiVO4. The improvement in the PEC performance of the composite with respect to bare BiVO4 is ascribed to the formation of thin passivating layer of p-ZnCo2O4 on n-BiVO4 which improves the kinetics of interfacial charge transfer. Based on our study, we have gained an in-depth understanding of the BiVO4/ZnCo2O4 composite as high potential in efficient PEC water splitting devices. © 2021 Elsevier Inc.

Item Type: Article
Divisions: Faculties > Faculty of Mechanical Engineering
Identification Number: 10.1016/j.jcis.2021.04.116
Uncontrolled Keywords: Bismuth; Charge transfer; Deposition; Field emission microscopes; High resolution transmission electron microscopy; Hydrogen production; MOS devices; Optical emission spectroscopy; Oxide semiconductors; Photocurrents; Photoelectrochemical cells; Scanning electron microscopy; Solar energy; Zinc; Zinc compounds; Field emission scanning electron microscopy; In-depth understanding; Interfacial charge transfer; Metal oxide deposition; Metal oxide semiconductor; Photoelectrochemical water splitting; Photoelectrochemicals; Scientific community; Bismuth compounds; bismuth vanadate; fluorine; inorganic compound; metal oxide; nanocomposite; tin oxide; unclassified drug; water; zinc cobaltite nanoparticle; zinc nanoparticle; Article; chemical structure; current density; electrochemical analysis; field emission scanning electron microscopy; high resolution transmission electron microscopy; illumination; impedance spectroscopy; kinetics; light absorption; photocatalysis; polarimetry; porosity; priority journal; simulation; ultraviolet visible spectroscopy; X ray diffraction
Additional Information: Language of original document: English.
URI: http://eprints.lqdtu.edu.vn/id/eprint/8582

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