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Masood Salavati Niasar

Masood Salavati Niasar

Professor

College: Faculty of Chemistry

Department: Inorganic Chemistry

Degree: Ph.D

CV Personal Website
FA
Masood Salavati Niasar

Professor Masood Salavati Niasar

College: Faculty of Chemistry - Department: Inorganic Chemistry Degree: Ph.D |

My affiliation

Institute of Nano Science and Nano Technology, University of Kashan, Kashan, P.O. Box 87317-51167, I. R. Iran.

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Tailoring the photocatalytic activity of novel magnetically separable ZnFe12O19-chitosan bionanocomposites: A green preparation, structural characterization and comparative study

Authorsزهرا خلج امیرحسینی – رزیتا منصف – سید امیرحسین احسانی زاده - Waleed Khaled Younis Albahadly- Hasan Sh Majdi - Ahmed Ali Amir- Ashour H. Dawood – مسعود صلواتی نیاسری
JournalInternational Journal of Hydrogen Energy
Dor Codehttps://doi.org/10.1016/j.ijhydene.2023.06.130
Paper TypeOriginal Research
Published At2023-06-27
Journal GradeISI
Journal TypeElectronic
Journal CountryUnited Kingdom
Journal IndexSCOPUS ,JCR

Abstract

Nowadays, the evaluation of nano-catalyts and photocatalytic technology for inactivating environmental pollution is identified as a priority. Although a series of semiconductor nanomaterials have been proven for this aim, suppression of charge carrier recombination and the absorption of solar light are still challenging. In this study, a novel visible-lightresponsive bionanocomposite of ZnFe12O19-chitosan (ZF-C) is designed by a facile twostep approach. The utilization of two natural stabilizer and capping agents including turnip and carrot juices is developed to adopt nucleation and growth mechanism of asfabricated crystals. In addition, benefiting from green templates, various quantities of these precursors show a strong impact on the construction of products in terms of structure and shape. The physic-chemical results confirmed creation of uniform ZF nanoparticles employing 20 mL of turnip juices. The band gap energy of ZF-C nanocomposites was found to be 1.55 eV, offering highly light absorption property in visible area. Moreover, the optimum photocatalyst had a specific surface area of 3.37 m2 g 1 . This research encompasses the first insights of photocatalytic efficiencies of ZF and [ZF-Cx] (x: 5.0%, 10.0% and 15.0%) nanocomposites toward five toxic dyes such as methyl violet (MV), erythrosine (EY), methylene blue (MB), methyl orange (MO), and rhodamine B (RhB) under visible light. As a proof-of-concept, the nanocomposites with 10.0% of chitosan matrix could exhibit higher photocatalyst performance about 94.12% EY removal after 120 min, which is 1.15 times better than that of pristine ZF nanostructures. Based on active species trapping experiments, a possible photodegradation pathway of EY dye over the [ZF-C10] nanocomposites has been reported. These findings describes a revolutionary way for selecting [ZF-C10] nanostructure as eco-friendly and magnetically recyclable photocatalysts in dye-containing effluents.