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BiVO4 photocatalysis design and applications to oxygen production and degradation of organic compounds: a review

Bismuth vanadate, BiVO4, is a visible-light response semiconductor for photocatalysis applications such as organic pollutants degradation, oxygen production and carbon dioxide reduction. However, as a single-phase photocatalyst, BiVO4 efficiency is limited by the unpreferable recombination of the p...

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Main Authors: Nguyen, T.D., Nguyen, V.-H., Nanda, S., Vo, D.-V.N., Nguyen, V.H., Van Tran, T., Nong, L.X., Nguyen, T.T., Bach, L.-G., Abdullah, B., Hong, S.-S., Van Nguyen, T.
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Published: Springer Science and Business Media Deutschland GmbH 2020
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85087049337&doi=10.1007%2fs10311-020-01039-0&partnerID=40&md5=27e0834648ab5824fa2f3fd8c4e4fdea
http://eprints.utp.edu.my/32421/
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spelling my.utp.eprints.324212022-03-29T02:55:46Z BiVO4 photocatalysis design and applications to oxygen production and degradation of organic compounds: a review Nguyen, T.D. Nguyen, V.-H. Nanda, S. Vo, D.-V.N. Nguyen, V.H. Van Tran, T. Nong, L.X. Nguyen, T.T. Bach, L.-G. Abdullah, B. Hong, S.-S. Van Nguyen, T. Bismuth vanadate, BiVO4, is a visible-light response semiconductor for photocatalysis applications such as organic pollutants degradation, oxygen production and carbon dioxide reduction. However, as a single-phase photocatalyst, BiVO4 efficiency is limited by the unpreferable recombination of the photoexcited electron (e�) and hole (h+). Thus, strategies have been designed to enhance the photocatalytic efficiency by promoting the separation of electrons and holes. This can be done by controling the morphology and crystallographic facets of BiVO4, and by building p�n junction photocatalytic systems with a combination of n-type semiconductors (BiVO4) and p-type semiconductors or a monoclinic�tetragonal heterostructure of BiVO4. In particular, a direct p�n junction photocatalytic system with tetragonal zircon-structured BiVO4 (t-z) and monoclinic scheelite-structured BiVO4 (m-s) combination has recently attracted attention. Here we review the synthesis of the monoclinic�tetragonal heterostructured BiVO4 photocatalyst (m�t BiVO4) by calcination, hydrothermal, microwave-assisted hydrothermal and solvothermal methods. m�t BiVO4 formation and the transmission phase between t-z and m-s are controlled by the calcining temperature, precursor pH, metal doping content, type of solvent, implementation of precursors and reaction conditions. We discuss m�t BiVO4 crystal structure, optical characteristics and photocatalytic principles. Successful formation of BiVO4 crystals with a m-s/t-z heterostructure is based on data from X-ray diffraction (XRD), Raman and ultraviolet�visible diffuse reflectance spectroscopy (UV�Vis DRS). In the m�t BiVO4 heterostructure, a direct p�n junction photocatalytic system is established. When this system is exposed to visible light, the electrons in the conduction band of m-s BiVO4, a n-type semiconductor, migrate easily to the conduction band of t-z BiVO4, while the holes on valence band of t-z BiVO4, a p-type semiconductor, move to the valence band of m-s BiVO4 through an internal electric field. As a result, the e�/h+ charge carriers are spatially separated. © 2020, Springer Nature Switzerland AG. Springer Science and Business Media Deutschland GmbH 2020 Article NonPeerReviewed https://www.scopus.com/inward/record.uri?eid=2-s2.0-85087049337&doi=10.1007%2fs10311-020-01039-0&partnerID=40&md5=27e0834648ab5824fa2f3fd8c4e4fdea Nguyen, T.D. and Nguyen, V.-H. and Nanda, S. and Vo, D.-V.N. and Nguyen, V.H. and Van Tran, T. and Nong, L.X. and Nguyen, T.T. and Bach, L.-G. and Abdullah, B. and Hong, S.-S. and Van Nguyen, T. (2020) BiVO4 photocatalysis design and applications to oxygen production and degradation of organic compounds: a review. Environmental Chemistry Letters, 18 (6). pp. 1779-1801. http://eprints.utp.edu.my/32421/
institution Universiti Teknologi Petronas
building UTP Resource Centre
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Petronas
content_source UTP Institutional Repository
url_provider http://eprints.utp.edu.my/
description Bismuth vanadate, BiVO4, is a visible-light response semiconductor for photocatalysis applications such as organic pollutants degradation, oxygen production and carbon dioxide reduction. However, as a single-phase photocatalyst, BiVO4 efficiency is limited by the unpreferable recombination of the photoexcited electron (e�) and hole (h+). Thus, strategies have been designed to enhance the photocatalytic efficiency by promoting the separation of electrons and holes. This can be done by controling the morphology and crystallographic facets of BiVO4, and by building p�n junction photocatalytic systems with a combination of n-type semiconductors (BiVO4) and p-type semiconductors or a monoclinic�tetragonal heterostructure of BiVO4. In particular, a direct p�n junction photocatalytic system with tetragonal zircon-structured BiVO4 (t-z) and monoclinic scheelite-structured BiVO4 (m-s) combination has recently attracted attention. Here we review the synthesis of the monoclinic�tetragonal heterostructured BiVO4 photocatalyst (m�t BiVO4) by calcination, hydrothermal, microwave-assisted hydrothermal and solvothermal methods. m�t BiVO4 formation and the transmission phase between t-z and m-s are controlled by the calcining temperature, precursor pH, metal doping content, type of solvent, implementation of precursors and reaction conditions. We discuss m�t BiVO4 crystal structure, optical characteristics and photocatalytic principles. Successful formation of BiVO4 crystals with a m-s/t-z heterostructure is based on data from X-ray diffraction (XRD), Raman and ultraviolet�visible diffuse reflectance spectroscopy (UV�Vis DRS). In the m�t BiVO4 heterostructure, a direct p�n junction photocatalytic system is established. When this system is exposed to visible light, the electrons in the conduction band of m-s BiVO4, a n-type semiconductor, migrate easily to the conduction band of t-z BiVO4, while the holes on valence band of t-z BiVO4, a p-type semiconductor, move to the valence band of m-s BiVO4 through an internal electric field. As a result, the e�/h+ charge carriers are spatially separated. © 2020, Springer Nature Switzerland AG.
format Article
author Nguyen, T.D.
Nguyen, V.-H.
Nanda, S.
Vo, D.-V.N.
Nguyen, V.H.
Van Tran, T.
Nong, L.X.
Nguyen, T.T.
Bach, L.-G.
Abdullah, B.
Hong, S.-S.
Van Nguyen, T.
spellingShingle Nguyen, T.D.
Nguyen, V.-H.
Nanda, S.
Vo, D.-V.N.
Nguyen, V.H.
Van Tran, T.
Nong, L.X.
Nguyen, T.T.
Bach, L.-G.
Abdullah, B.
Hong, S.-S.
Van Nguyen, T.
BiVO4 photocatalysis design and applications to oxygen production and degradation of organic compounds: a review
author_facet Nguyen, T.D.
Nguyen, V.-H.
Nanda, S.
Vo, D.-V.N.
Nguyen, V.H.
Van Tran, T.
Nong, L.X.
Nguyen, T.T.
Bach, L.-G.
Abdullah, B.
Hong, S.-S.
Van Nguyen, T.
author_sort Nguyen, T.D.
title BiVO4 photocatalysis design and applications to oxygen production and degradation of organic compounds: a review
title_short BiVO4 photocatalysis design and applications to oxygen production and degradation of organic compounds: a review
title_full BiVO4 photocatalysis design and applications to oxygen production and degradation of organic compounds: a review
title_fullStr BiVO4 photocatalysis design and applications to oxygen production and degradation of organic compounds: a review
title_full_unstemmed BiVO4 photocatalysis design and applications to oxygen production and degradation of organic compounds: a review
title_sort bivo4 photocatalysis design and applications to oxygenâ productionâ and degradation of organic compounds: a review
publisher Springer Science and Business Media Deutschland GmbH
publishDate 2020
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-85087049337&doi=10.1007%2fs10311-020-01039-0&partnerID=40&md5=27e0834648ab5824fa2f3fd8c4e4fdea
http://eprints.utp.edu.my/32421/
_version_ 1738657384906096640
score 13.214268

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