Superefficient and robust polymer coating for bionic manufacturing of superwetting surfaces with “rose petal effect” and “lotus leaf effect”

[Display omitted] •A superefficient approach is proposed to produce a superhydrophobic UHMWPE coating.•Superhydrophobic UHMWPE surfaces can be tuned between Cassie impregnating state and Cassie state.•UHMWPE surfaces displayed promising applicability in droplet transportation and self-cleaning.•UHMW...

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Bibliographic Details
Published in:Progress in organic coatings 2021-02, Vol.151, p.106090, Article 106090
Main Authors: Sun, Shuangjie, Li, Heng, Guo, Yahao, Mi, Hao-Yang, He, Ping, Zheng, Guoqiang, Liu, Chuntai, Shen, Changyu
Format: Article
Language:English
Subjects:
Adhesion
Bionics
Cleaning
Corrosion prevention
Cyclohexanone
Drag reduction
Hydrophobic surfaces
Hydrophobicity
Impregnation
Lotus leaf effect
Morphology
Polymer coatings
Robustness
Rose petal effect
Self-cleaning
Staining
Substrates
Superhydrophobic
Ultra high molecular weight polyethylene
Ultrahigh molecular weight polyethylene
Xylene
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Summary:[Display omitted] •A superefficient approach is proposed to produce a superhydrophobic UHMWPE coating.•Superhydrophobic UHMWPE surfaces can be tuned between Cassie impregnating state and Cassie state.•UHMWPE surfaces displayed promising applicability in droplet transportation and self-cleaning.•UHMWPE surfaces possess preeminent stability and durability against various liquids and mechanical impact. Mimicking the superwetting behaviors of nature creatures is advantageous for the development of multifunctional surfaces. Superhydrophobic surfaces are desired for applications such as self-cleaning, drag reduction, anti-staining, anti-corrosion, oil-water separation, etc. Herein, a superefficient approach is proposed to produce a robust ultrahigh molecular weight polyethylene (UHMWPE) coating on various substrates by dripping and drying UHMWPE solutions. The superhydrophobic surfaces can be tuned between Cassie impregnating state and Cassie state, which resembles the “rose petal effect” and “lotus leaf effect”, respectively, by simply adjusting the quenching temperature and the solvent system. UHMWPE/ortho-xylene biphasic solution resulted in a wrinkled morphology with a high-adhesion superhydrophobic surface, while the UHMWPE/ortho-xylene/cyclohexanone triple-phase solution led to a highly porous morphology with a low-adhesion superhydrophobic surface. The micro-nano structured surfaces displayed promising applicability in droplet transportation, selective oil absorption, anti-staining, and self-cleaning. They also possess superior stability and durability against various liquids and mechanical impact. This work provides a highly efficient approach to produce versatile bionic superhydrophobic coatings with tunable superwetting states.
ISSN:0300-9440
1873-331X
DOI:10.1016/j.porgcoat.2020.106090