Engineering of ZnO nanostructures for efficient solar photocatalysis

[Display omitted] •Engineering of ZnO nanostructures using microwave assisted method.•Physicochemical characterization of ZnO nanostructures.•Detailed investigation of the role of synthesis conditions on the morphology and photocatalytic performance. Highly photoactive metal oxide catalyst can be de...

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Bibliographic Details
Published in:Materials letters 2018-05, Vol.219, p.76-80
Main Authors: Das, Abinash, Malakar, P., Nair, Ranjith G.
Format: Article
Language:English
Subjects:
Carrier recombination
Catalysts
Current carriers
Irradiation
Materials science
Metal oxides
Methylene blue
Microwave
Microwaves
Nanoflower
Nanorods
Nanostructure
Nanostructured materials
Photocatalysis
Photocatalyst
Photon absorption
Photonics
Solar energy
Zinc oxide
Zinc oxides
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Summary:[Display omitted] •Engineering of ZnO nanostructures using microwave assisted method.•Physicochemical characterization of ZnO nanostructures.•Detailed investigation of the role of synthesis conditions on the morphology and photocatalytic performance. Highly photoactive metal oxide catalyst can be developed by engineering the nanostructure of the material. The present study reports the engineering of ZnO nanostructures using the microwave technique. The physicochemical characterization reveals the role of microwave irradiation power and reaction temperature on ZnO nanostructure engineering. The structural and surface analyses of the samples prepared at room temperature and 180 °C, in various microwave power, confirms the formation of nanorods. The higher reaction temperature has favored the nanorods to a flower like structures and increase in microwave power leads to the formation of denser, uniform nanoflowers, with enlarged petal diameter. The photocatalytic performance of the samples was evaluated using Methylene Blue (MB) as probe pollutant under solar irradiation. All the samples showed relatively high photocatalytic performance in terms of rate constant and photonic efficiency. However, the sample prepared at 180 °C and 360 W showed superior photocatalytic performance than the rest, which can be attributed to the effective photon absorption along with reduced charge carrier recombination. This study opens a new low-cost method for engineering the nanostructure for improving the photocatalytic performance.
ISSN:0167-577X
1873-4979
DOI:10.1016/j.matlet.2018.02.057