Facile fabrication of fluorine-free, transparent and self-cleaning superhydrophobic coatings based on biopolymer castor oil

•A hydrophobic PUA was prepared in which castor oil accounts for more than 56% wt.•A transparent superhydrophobic surface was constructed by using PUA and fused SiO2.•The coating showed high transmittance above 80% in visible-light region.•The WCA of the as-prepared coating can reach 158.5°. A highl...

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Published in	Materials letters Vol. 230; pp. 84 - 87
Main Authors	Wang, Qing, Chen, Guangxue, Tian, Junfei, Yu, Zhaohui, Deng, Qianjun, Yu, Mingguang
Format	Journal Article
Language	English
Published	Amsterdam Elsevier B.V 01.11.2018 Elsevier BV
Subjects	Abrasion Abrasives Biopolymers Castor oil Cleaning Coatings Contact angle Contaminants Fluorine Hydrophobic surfaces Hydrophobicity Materials science Microstructure Nanoparticles Oil Optoelectronics Polymer matrix composites Polymeric composites Polyurethane resins Self-cleaning Silicon dioxide Superhydrophobic coating Transparent Polymeric composites Self-cleaning Transparent Microstructure Superhydrophobic coating Castor oil
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Abstract	•A hydrophobic PUA was prepared in which castor oil accounts for more than 56% wt.•A transparent superhydrophobic surface was constructed by using PUA and fused SiO2.•The coating showed high transmittance above 80% in visible-light region.•The WCA of the as-prepared coating can reach 158.5°. A highly transparent self-cleaning superhydrophobic surface was constructed via a facile and environmentally friendly strategy by using biomass-based polyurethane and fused SiO2 nanoparticles. By simply controlling the amounts of castor oil (CO) and SiO2, the coating presented excellent superhydrophobic with high water contact angle (158.5°) and low sliding angle (3.9°), as well as the transmittance of the coating was above 80% in visible-light region. Moreover, the coatings showed remarkable robustness against abrasion of 5 cycles without an apparent decrease of superhydrophobicity and possessed excellent self-cleaning properties against dirty contaminant. Therefore, such transparent and self-cleaning superhydrophobic coating could make it an ideal material for application in optoelectronics, liquid-repellent coatings, and oil-water separation.
AbstractList	A highly transparent self-cleaning superhydrophobic surface was constructed via a facile and environmentally friendly strategy by using biomass-based polyurethane and fused SiO2 nanoparticles. By simply controlling the amounts of castor oil (CO) and SiO2, the coating presented excellent superhydrophobic with high water contact angle (158.5°) and low sliding angle (3.9°), as well as the transmittance of the coating was above 80% in visible-light region. Moreover, the coatings showed remarkable robustness against abrasion of 5 cycles without an apparent decrease of superhydrophobicity and possessed excellent self-cleaning properties against dirty contaminant. Therefore, such transparent and self-cleaning superhydrophobic coating could make it an ideal material for application in optoelectronics, liquid-repellent coatings, and oil-water separation. •A hydrophobic PUA was prepared in which castor oil accounts for more than 56% wt.•A transparent superhydrophobic surface was constructed by using PUA and fused SiO2.•The coating showed high transmittance above 80% in visible-light region.•The WCA of the as-prepared coating can reach 158.5°. A highly transparent self-cleaning superhydrophobic surface was constructed via a facile and environmentally friendly strategy by using biomass-based polyurethane and fused SiO2 nanoparticles. By simply controlling the amounts of castor oil (CO) and SiO2, the coating presented excellent superhydrophobic with high water contact angle (158.5°) and low sliding angle (3.9°), as well as the transmittance of the coating was above 80% in visible-light region. Moreover, the coatings showed remarkable robustness against abrasion of 5 cycles without an apparent decrease of superhydrophobicity and possessed excellent self-cleaning properties against dirty contaminant. Therefore, such transparent and self-cleaning superhydrophobic coating could make it an ideal material for application in optoelectronics, liquid-repellent coatings, and oil-water separation.
Author	Yu, Mingguang Tian, Junfei Wang, Qing Chen, Guangxue Deng, Qianjun Yu, Zhaohui
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Keywords	Polymeric composites Self-cleaning Transparent Microstructure Superhydrophobic coating Castor oil
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Snippet	•A hydrophobic PUA was prepared in which castor oil accounts for more than 56% wt.•A transparent superhydrophobic surface was constructed by using PUA and... A highly transparent self-cleaning superhydrophobic surface was constructed via a facile and environmentally friendly strategy by using biomass-based...
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SubjectTerms	Abrasion Abrasives Biopolymers Castor oil Cleaning Coatings Contact angle Contaminants Fluorine Hydrophobic surfaces Hydrophobicity Materials science Microstructure Nanoparticles Oil Optoelectronics Polymer matrix composites Polymeric composites Polyurethane resins Self-cleaning Silicon dioxide Superhydrophobic coating Transparent
Title	Facile fabrication of fluorine-free, transparent and self-cleaning superhydrophobic coatings based on biopolymer castor oil
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