Fabrication of multi-functional and breathable superhydrophobic cotton fabric based on curcumin/ZIF-8 through mild thiol-ene click chemistry reaction

Yuan, Hua-Bin; Cheng, Jin; Sha, Desheng; Zhao, ManMan; Xing, Tieling; Chen, Guoqiang

doi:10.1016/j.apsusc.2023.158882

Cited by 3 publications

(1 citation statement)

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“…The water droplet could quickly roll to the edge of the coating within 0.260 s (Figure 1e), suggesting a sliding angle of less than 1 . [40][41][42] In addition, a water droplet held by a syringe needle could be easily detached from the coating surface without any water residue and adhesion behavior from contact to departure, only the change in the shape of the water drop from sphere to oval due to mechanical squeezing (Figure 1f), implying the better the hydrophobicity of the coating surface. It can be seen that we reported a strategy to greatly accelerate polymerization process of DA and the formation rate of superhydrophobic coatings with higher water contact angles (162.2 ) and smaller sliding angles (<1 ) by using trigger nZVI/H 2 O 2 and one-pot method.…”

Section: Algae Adhesion Testmentioning

confidence: 99%

One‐pot construction of polydopamine‐based superhydrophobic coating with enhanced chemical stability and anti‐fouling performance

Xia,

Xu,

Chen

et al. 2024

J of Applied Polymer Sci

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A facile strategy to construct superhydrophobic coatings was carried out by one‐pot process using novel nano zero‐valent iron and hydrogen peroxide as trigger in ethanol and Tris buffer mixed system containing dopamine and 1H,1H,2H,2H‐perfluorodecanethiol (PFDT) for the first time. The polydopamine (PDA) modified by PFDT composite coating can be deposited onto various substrates including glass slides, polyurethane sheets, polytetrafluoroethylene wafers, 304 stainless steel sheets, and polyurethane sponges, revealing excellent hydrophobicity with the water contact angles from 157.1° to 162.2° and the sliding angle lower than 1°. The flourier transformed infrared spectroscopy and x‐ray photoelectron spectroscopy information of the composite coating demonstrated the successful covalent interaction between catechol group in PDA and thiol group of PFDT via Michael addition reaction. As‐prepared PFDT/PDA composite coatings exhibited enhanced chemical stability in highly acidic solutions for 6 days, alkaline aqueous solutions for 5 days, salty solutions (3.5 wt%) for 28 days, and polar organic solvents for 24 h, respectively, as well as resistance to algae adhesion. The excellent corrosion resistance and chemical stability of the composite coating and their simple, time saving and inexpensive construction process are expected to be widely applied in various areas, including marine anti‐corrosion, anti‐fouling, and oil–water separation.

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Section: Algae Adhesion Testmentioning

confidence: 99%