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Co2+-laddered heterojunction a next-generation solar-photocatalyst: Unusually improved activity for the decomposition of pharmaceuticals, dyes, and microplastics

Lopis, AD and Choudhari, KS and Sai, R and Sudarshana, . and Kanakikodi, KS and Maradur, SP and Kulkarni, SD (2024) Co2+-laddered heterojunction a next-generation solar-photocatalyst: Unusually improved activity for the decomposition of pharmaceuticals, dyes, and microplastics. In: Materials Research Bulletin, 176 .

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Official URL: https://doi.org/10.1016/j.materresbull.2024.112836

Abstract

Novel and versatile photocatalysts that can work under direct sunlight are in high demand especially for mitigating water contamination. Some of the burgeoning pollutants in water are textile dyes, organic molecules, pharmaceutical products etc. In view of their extensive use, polymer wastes such as microplastics in water bodies are a new cause of concern. Using direct sunlight for the degradation of such pollutants needs the development of solar photocatalysts. We report on a novel next-generation solar-photocatalyst, consisting laddered-heterojunction formed between Co2+- substituted zinc-ferrite core & zinc-oxide shell, to harvest full-solar-spectrum in scavenger-free photodegradation of dyes, pharmaceuticals and microplastics. Using in-house developed protocols and Microwave-assisted-solvothermal-technique (MAST), nanospheres of �20�40 nm were synthesized first followed by ZnO shell growth in a controlled manner (�80�180 nm) to obtain the core-shell photocatalyst nanospheres using another microwave approach. The absorption of the photocatalyst could be extended upto 852 nm by judiciously doping with Co2+- enabling the utilization of UV�Vis-NIR region of sunlight. As evident from the valence band spectra, the Co2+ substitution introduced free electrons in the conduction band of ZnFe2O4 that resulted in the formation of laddered type-1 heterojunction. With the optimized Co2+content and ZnO-shell thickness, solar-photocatalytic degradation of Methyl-Orange enhanced 6-&12-times respectively. Complete degradation of antibiotics like Ciprofloxacin (CF), Norfloxacin (NF), and Ofloxacin (OF) under direct sunlight was achieved within an hour. This unusual enhanced activity was attributed to the inclusion of Co2+, conducive band positions leading to higher absorption and reduced recombination. We also showed the degradation of polypropylene microfibers used in face masks to combat the COVID-19 outbreak could also be degraded., indicating their potential to combat microplastic pollution. Our novel photocatalyst holds promise for sunlight-assisted degradation of a wide range of hazardous pollutants. © 2024

Item Type: Journal Article
Publication: Materials Research Bulletin
Publisher: Elsevier Ltd
Additional Information: The copyright for this article belongs to Elsevier Ltd.
Keywords: Antibiotics; Azo dyes; Heterojunctions; II-VI semiconductors; Iron compounds; Nanospheres; Phenols; Photocatalytic activity; Photodegradation; Polypropylenes; Shells (structures); Water pollution; Water treatment; Zinc oxide, High demand; Improved activities; Microplastics; Organic molecules; Pharmaceutical products; Polymer wastes; Textile dyes; Water contamination; Waterbodies; ZnO shells, Organic pollutants
Department/Centre: Division of Interdisciplinary Sciences > Centre for Nano Science and Engineering
Date Deposited: 20 May 2024 12:01
Last Modified: 20 May 2024 12:01
URI: https://eprints.iisc.ac.in/id/eprint/84734

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