Sunlight-Driven Photocatalytic Active Fabrics through Immobilization of Functionalized Doped Titania Nanoparticles

Frequent washing of textiles poses a serious hazard to the ecosystem, owing to the discharge of harmful effluents and the release of microfibers. On one side, the harmful effluents from detergents are endangering marine biota, while on the other end, microplastics are observed even in breastfeeding...

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Bibliographic Details
Published in:Polymers 2023-06, Vol.15 (13), p.2775
Main Authors: Arfa, Ume, Alshareef, Mubark, Nadeem, Nimra, Javid, Amjed, Nawab, Yasir, Alshammari, Khaled F, Zubair, Usman
Format: Article
Language:English
Subjects:
Biochemical oxygen demand
Chemical oxygen demand
Cotton
Cotton fabrics
Coupling agents
Degradation
Desiccants
Detergents
Dyes
Electrical conductivity
Ethylenediaminetetraacetic acid
Fabrics
Immobilization
Light
Mechanical properties
Methylene blue
Microfibers
Nanoparticles
Nitrates
Photocatalysis
Plastic pollution
Pollutants
Sol-gel processes
Sunlight
Surface active agents
Surfactants
Textiles
Titanium dioxide
Water quality
Zinc
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Summary:Frequent washing of textiles poses a serious hazard to the ecosystem, owing to the discharge of harmful effluents and the release of microfibers. On one side, the harmful effluents from detergents are endangering marine biota, while on the other end, microplastics are observed even in breastfeeding milk. This work proposes the development of sunlight-driven cleaning and antibacterial comfort fabrics by immobilizing functionalized Zn-doped TiO nanoparticles. The research was implemented to limit the use of various detergents and chemicals for stain removal. A facile sol-gel method has opted for the fabrication of pristine and Zn-doped TiO nanoparticles at three different mole percentages of Zn. The nanoparticles were successfully functionalized and immobilized on cotton fabric using silane coupling agents via pad-dry-cure treatment. As-obtained fabrics were characterized by their surface morphologies, availability of chemical functionalities, and crystallinity. The sunlight-assisted degradation potential of as-functionalized fabrics was evaluated against selected pollutants (eight commercial dyes). The 95-98% degradation of dyes from the functionalized fabric surface was achieved within 3 h of sunlight exposure, estimated by color strength analysis with an equivalent exposition of bactericidal activities. The treated fabrics also preserved their comfort and mechanical properties. The radical trapping experiment was performed to confirm the key radicals responsible for dye degradation, and h ions were found to be the most influencing species. The reaction pathway followed the first order kinetic model with rate constant values of 0.0087 min and 0.0131 min for MB and MO dyes, respectively.
ISSN:2073-4360
2073-4360
DOI:10.3390/polym15132775