Monodispersed 3D MnWO4–TiO2 composite nanoflowers photocatalysts for environmental remediation

Hassan, M. Shamshi; Amna, Touseef; Al‐Deyab, Salem S.; Khil, Myung-Seob

doi:10.1016/j.cap.2015.03.022

Cited by 25 publications

(8 citation statements)

References 21 publications

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“…Please do not adjust margins Please do not adjust margins reactivity, etc. 19 However, their photocatalytic performance is very low due to limited light absorption in the visible region. 20 Recently, many efforts have been made to use MnWO4 for the photocatalytic decomposition of organic pollutants and hydrogen generation.…”

Section: H2omentioning

confidence: 99%

CdS decorated MnWO₄ nanorod nanoheterostructures: a new 0D–1D hybrid system for enhanced photocatalytic hydrogen production under natural sunlight

et al. 2021

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Section: H2omentioning

confidence: 99%

CdS decorated MnWO₄ nanorod nanoheterostructures: a new 0D–1D hybrid system for enhanced photocatalytic hydrogen production under natural sunlight

et al. 2021

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“…For instance, Jia [ 157 ] and Wang et al [ 158 ] deposited CdS on the surface of CdWO 4 via an ion-exchange and in situ growth route, and the fabricated Z-scheme CdS/CdWO 4 hybrid exhibited significantly enhanced photocatalytic performance for H 2 evolution compared to that of the pure CdWO 4 and CdS. As discusses in the previous section, the MWO 4 with a small M 2+ cation has a narrow band-gap energy, which can be considered an efficient solar energy harvester to connect with wide band-gap semiconductors for constructing MWO 4 -based heterojunctions [ 159 – 161 ]. Thus, Jiang et al [ 162 ] fabricated an MnWO 4 /TiO 2 heterojunction with excellent mechanical adhesion by the in situ growth of MnWO 4 on a porous TiO 2 film; it presented extremely high photocatalytic performance for degrading MB because of its high crystallinity, large surface area, and strong mechanical properties (Fig.…”

Section: Strategies For Enhanced Photocatalytic Activitymentioning

confidence: 99%

Nanostructured Ternary Metal Tungstate-Based Photocatalysts for Environmental Purification and Solar Water Splitting: A Review

et al. 2018

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Visible-light-responsive ternary metal tungstate (MWO4) photocatalysts are being increasingly investigated for energy conversion and environmental purification applications owing to their striking features, including low cost, eco-friendliness, and high stability under acidic and oxidative conditions. However, rapid recombination of photoinduced electron–hole pairs and a narrow light response range to the solar spectrum lead to low photocatalytic activity of MWO4-based materials, thus significantly hampering their wide usage in practice. To enable their widespread practical usage, significant efforts have been devoted, by developing new concepts and innovative strategies. In this review, we aim to provide an integrated overview of the fundamentals and recent progress of MWO4-based photocatalysts. Furthermore, different strategies, including morphological control, surface modification, heteroatom doping, and heterojunction fabrication, which are employed to promote the photocatalytic activities of MWO4-based materials, are systematically summarized and discussed. Finally, existing challenges and a future perspective are also provided to shed light on the development of highly efficient MWO4-based photocatalysts.

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“…[21][22][23][24] Consequently, many researchers have paid much attention to the photocatalytic activity of MnWO 4 prepared by various methods such as the sol-gel method, hydrothermal method, microwave-assisted method, molten salt method, and so on. [25][26][27][28][29][30] However, an overwhelming drawback of these MnWO 4 products is that the majority of the as-synthesized materials are in the form of a nano-sized powder, which is a difficulty associated with recovering dispersions of the catalyst for recycling and future use after the photocatalytic reaction. 31 In fact, one of the key factors for the degradation of organic pollutants in water is the separation and recovery of photocatalysts from water.…”

Section: Introductionmentioning

confidence: 99%

New strategy for the in situ synthesis of single-crystalline MnWO₄/TiO₂photocatalysts for efficient and cyclic photodegradation of organic pollutants

et al. 2016

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MnWO 4 nano photocatalysts with plate shapes and in high yields are in situ synthesized on the surface of a porous TiO 2 film by the conventional plasma electrolytic oxidation (PEO) method combined with a subsequent ambient annealing process. Transmission electron microscopy (TEM) analysis shows that the MnWO 4 nano photocatalysts are single crystals free of structural defects and scanning electron microscopy (SEM) observation on the cross-section reveals that these MnWO 4 nano photocatalysts are in situ grown on the porous TiO 2 film surface with strong adhesion. The morphology and dimension size can be selectively tailored through controlling the reaction time, showing the simplicity and versatility of the proposed method.In addition, the photodegradation of methylene blue (MB) solution using the MnWO 4 /TiO 2 photocatalysts demonstrated the superior photocatalytic performance with high efficiency and excellent photostability. A high photodegradation rate of MB solution of over 90% in 60 min has been achieved and a superior cyclic capability is also obtained. The superior photocatalytic performance of MnWO 4 /TiO 2 photocatalysts can be mainly attributed to the good crystallinity, all-surface covering and strong mechanical properties of the MnWO 4 nanostructures with TiO 2 film. The prevailing advantage of the PEO method in combination with the ambient annealing process will open up more opportunity for the rational synthesis of a wide range of oxide photocatalysts ranging from tungstate to titanate, molybdate and vanadate for promising catalytic applications in diverse fields.

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Monodispersed 3D MnWO4–TiO2 composite nanoflowers photocatalysts for environmental remediation

Cited by 25 publications

References 21 publications

CdS decorated MnWO₄ nanorod nanoheterostructures: a new 0D–1D hybrid system for enhanced photocatalytic hydrogen production under natural sunlight

CdS decorated MnWO₄ nanorod nanoheterostructures: a new 0D–1D hybrid system for enhanced photocatalytic hydrogen production under natural sunlight

Nanostructured Ternary Metal Tungstate-Based Photocatalysts for Environmental Purification and Solar Water Splitting: A Review

New strategy for the in situ synthesis of single-crystalline MnWO₄/TiO₂photocatalysts for efficient and cyclic photodegradation of organic pollutants

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Monodispersed 3D MnWO4–TiO2 composite nanoflowers photocatalysts for environmental remediation

Cited by 25 publications

References 21 publications

CdS decorated MnWO4 nanorod nanoheterostructures: a new 0D–1D hybrid system for enhanced photocatalytic hydrogen production under natural sunlight

CdS decorated MnWO4 nanorod nanoheterostructures: a new 0D–1D hybrid system for enhanced photocatalytic hydrogen production under natural sunlight

Nanostructured Ternary Metal Tungstate-Based Photocatalysts for Environmental Purification and Solar Water Splitting: A Review

New strategy for the in situ synthesis of single-crystalline MnWO4/TiO2photocatalysts for efficient and cyclic photodegradation of organic pollutants

Contact Info

Product

Resources

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CdS decorated MnWO₄ nanorod nanoheterostructures: a new 0D–1D hybrid system for enhanced photocatalytic hydrogen production under natural sunlight

CdS decorated MnWO₄ nanorod nanoheterostructures: a new 0D–1D hybrid system for enhanced photocatalytic hydrogen production under natural sunlight

New strategy for the in situ synthesis of single-crystalline MnWO₄/TiO₂photocatalysts for efficient and cyclic photodegradation of organic pollutants