Highly active ZnO-based biomimetic fern-like microleaves for photocatalytic water decontamination using sunlight

[Display omitted] •Simple electrosynthesis of biomimetic micro/nanofern fractal structures as enhanced sunlight photocatalysts is established.•Efficient ZnO modification approaches are proposed for tuning ZnO electronic properties to enable visible light absorption.•Enhanced light trapping and the e...

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Bibliographic Details
Published in:Applied catalysis. B, Environmental Environmental, 2019-07, Vol.248, p.129-146
Main Authors: Serrà, Albert, Zhang, Yue, Sepúlveda, Borja, Gómez, Elvira, Nogués, Josep, Michler, Johann, Philippe, Laetitia
Format: Article
Language:English
Subjects:
Bioinspiration
Biomimetic
Biomimetics
Catalysis
Catalysts
Catalytic activity
Decontamination
Decoration
Efficiency
Electrochemistry
Electrodeposition
Electronic properties
Electroplating
Environmental degradation
Fabrication
Ferns
Fotocatàlisi
Fractals
Galvanoplàstia
Methylene blue
Morphology
Nanoestructures
Nanostructures
Near infrared radiation
Nickel
Nitrophenol
Persistent organic pollutants
Photocatalysis
Photocatalysts
Photodegradation
Photovoltaic cells
Pollutants
Recyclability
Rhodamine
Structural hierarchy
Sulfidation
Sunlight
Sunlight photocatalysis
Trapping
Ultraviolet radiation
Zinc oxide
Òxid de zinc
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Summary:[Display omitted] •Simple electrosynthesis of biomimetic micro/nanofern fractal structures as enhanced sunlight photocatalysts is established.•Efficient ZnO modification approaches are proposed for tuning ZnO electronic properties to enable visible light absorption.•Enhanced light trapping and the electronic modifications enable boosting the sun light photocatalytic efficiency.•ZnO@ZnS core@shell micro/nanoferns exhibit excellent photocatalytic activity, photocorrosion resistance and recyclability. Here we present the highly enhanced sunlight photocatalytic efficiency and photocorrosion resistance of biomimetic ZnO-modified micro/nanofern fractal architectures, which are synthesized by using a novel, simple, inexpensive and green electrochemical deposition approach in high stirring conditions. Such fern-like hierarchical structures simultaneously combine enhanced angle independent light trapping and surface/bulk modifications of the ZnO morphology to drastically increase: i) the light trapping and absorption in the visible near-infrared range, and ii) the surface to volume ratio of the architecture. This combination is crucial for boosting the sunlight photocatalytic efficiency. To modulate the electronic properties for extending the operation of the ZnO photocatalysts into the visible domain we have used three different modification approaches: sulfidation (leading to a ZnS shell), Ag decoration, and Ni-doping. The different ZnO-modified bioinspired fern-like fractal structures have been used to demonstrate their efficiency in the photodegradation and photoremediation of three different persistent organic pollutants –methylene blue, 4-nitrophenol, and Rhodamine B – under UV light, simulated and natural UV-filtered sunlight. Remarkably, the ZnO@ZnS core@shell structures exhibited an outstanding photocatalytic activity compared to the pristine ZnO catalyst, with over 6-fold increase in the pollutant degradation rate when using solar light. In fact, the catalytic performance of the ZnO@ZnS micro/nanoferns for the photoremediation of persistent organic pollutants is comparable to or better than the most competitive state-of-the-art ZnO photocatalysts, but showing a negligible photocorrosion. Ag-decorated ZnO, and Ni-doped ZnO exhibited similar excellent visible-sunlight photodegradation efficiency. Although the Ni-doped photocatalysts showed a relatively poor photocorrosion resistance, it was acceptable for Ag-decorated ZnO. Therefore, the easy fabrication an
ISSN:0926-3373
1873-3883
DOI:10.1016/j.apcatb.2019.02.017