Smart nanocontainer-based anticorrosive bio-coatings: Evaluation of quercetin for corrosion protection of aluminium alloys

[Display omitted] •Hybrid of silica nanoparticles with phytochemical as an inhibitor was prepared.•Structural modification of quercetin with pH changes influenced the reaction kinetics.•Reaction products of quercetin had an effect on the anticorrosive response.•Bio-nanocomposite particle loaded epox...

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Bibliographic Details
Published in:Progress in organic coatings 2019-11, Vol.136, p.105276, Article 105276
Main Authors: Ulaeto, Sarah B., Nair, Anju V., Pancrecious, Jerin K., Karun, Akhil S., Mathew, Gincy Marina, Rajan, T.P.D., Pai, B.C.
Format: Article
Language:English
Subjects:
Alloy development
Aluminum base alloys
Antibacterial
Autoxidation
Bacteria
Bacterial corrosion
Bio-nanocomposite
Corrosion inhibitors
Corrosion prevention
Corrosion protection
Corrosion tests
Eco-friendly coatings
Electrochemical corrosion
Immersion tests (corrosion)
Metabolites
Nano-silica carrier
Nanocomposites
Organic chemistry
Protective coatings
Silicon dioxide
Submerging
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Summary:[Display omitted] •Hybrid of silica nanoparticles with phytochemical as an inhibitor was prepared.•Structural modification of quercetin with pH changes influenced the reaction kinetics.•Reaction products of quercetin had an effect on the anticorrosive response.•Bio-nanocomposite particle loaded epoxy coating provided active anticorrosion.•Antibacterial inhibition of the epoxy coatings was observed. The present investigation describes a new contribution to the development of active anticorrosive films. The “phytochemical” Quercetin (QCT), a known secondary metabolite of plants, loaded in silica nanocontainers as the natural organic inhibitor was utilized to obtain active anticorrosive coatings. With an artificial defect induced on the epoxy nanocomposite coating and subsequent corrosion reactions, active corrosion protection was triggered. The optimum performance was achieved from the 1.0 wt.% loaded coatings. The unscratched nanocomposite coatings were also examined and revealed enhanced corrosion protection in comparison with the unmodified epoxy coating. The anticorrosive action of the bio-coatings was controlled by the release and reactions of the inhibiting component from the coating at pH 10. The corrosion protection offered by QCT was due to the chemical transformation experienced by QCT with pH influence involving possible autoxidation and polymerization processes. Both immersion and electrochemical corrosion tests were employed in the study to systematically evaluate the corrosion protection. Furthermore, a primary investigation was conducted to assess the antibacterial property of the bio-coatings which offered significant antibacterial protection to the aluminium alloy surfaces by inhibiting the growth of the biofilm-forming bacteria Pseudomonas nitroreducens. These findings encourage the exploration of bio-based coatings for enhanced anticorrosion protection of aluminium alloys.
ISSN:0300-9440
1873-331X
DOI:10.1016/j.porgcoat.2019.105276