Self-Replenishing Dual Structured Superhydrophobic Coatings Prepared by Drop-Casting of an All-In-One Dispersion

Robust dual structured superhydrophobic coatings which replenish spontaneously their surface chemical composition on new multi‐scale structured surfaces, recreated upon damage, are described. The surface repair occurs at room temperature, via intrinsic elements of the coatings, all covalently bonded...

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Bibliographic Details
Published in:Advanced functional materials 2014-02, Vol.24 (7), p.986-992
Main Authors: Esteves, A. C. C., Luo, Y., van de Put, M. W. P., Carcouët, C. C. M., de With, G.
Format: Article
Language:English
Subjects:
Abrasion resistance
Chemical composition
Coatings
Dispersions
Life cycle costs
Low cost
Maintenance
Repair
self-healing
self-replenishing
superhydrophobic
topography
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Summary:Robust dual structured superhydrophobic coatings which replenish spontaneously their surface chemical composition on new multi‐scale structured surfaces, recreated upon damage, are described. The surface repair occurs at room temperature, via intrinsic elements of the coatings, all covalently bonded. These coatings can be prepared from all‐in‐one dispersions by a simple drop‐cast method, with different thicknesses and on various substrates. The critical factors to optimize the self‐replenishment are described and three main design principles are postulated. The superhydrofobicity of the coatings is maintained even after 500 abrasion cycles. The principles reported can be extended towards self‐healing other surface‐dependent functionalities, that is, anti‐bacteria, anti‐fouling, or drag‐reduction, which will maintain high performance levels all through their life‐cycle with low cost and energy demand for maintenance and surface repair. Robust surface‐structured superhydrophobic coatings with raspberry‐like morphology prepared from all‐in‐one dispersions and a simple drop‐cast method, self‐replenish their surface chemical composition on new multi‐scale topographic surfaces, self‐regenerated upon damage. The surface repair occurs spontaneously using intrinsic elements of the coating. Design principles for functional materials perform at high level all through their life‐cycle, with low cost and energy demand for maintenance and repair.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201301909