材料科学
超疏水涂料
涂层
生物污染
复合材料
胶粘剂
含氟聚合物
磨损(机械)
纳米技术
耐久性
纳米复合材料
弹性体
聚合物
纳米尺度
接触角
润湿
纳米颗粒
聚氨酯
图层(电子)
表面改性
粘附
聚酯纤维
防水剂
解耦(概率)
水溶液
韧性
作者
Yukun Ren,Bucheng Li,Junhua Zhang
标识
DOI:10.1021/acsami.6c03110
摘要
The realization of fully waterborne superhydrophobic coatings that simultaneously deliver high mechanical durability and long-term environmental stability remains a long-standing challenge. This challenge mainly arises from the intrinsic incompatibility between extremely hydrophobic building blocks and aqueous media, as well as the mechanical fragility of hierarchical surface structures. Here, we report a fully waterborne and mechanically robust superhydrophobic coating enabled by a rationally designed, two-step spray strategy. A waterborne polyurethane adhesive underlayer serves as an elastic structural regulator and stress-dissipating scaffold, while a fluorine-rich top layer composed of in situ–generated fluorinated silica nanoparticles and a waterborne fluoroethylene vinyl ether resin constructs a stable hierarchical micro/nanostructure with ultralow surface energy. The optimized coating exhibits outstanding superhydrophobicity and strong resistance to water impalement under high-velocity water jets. Notably, the coating maintains superhydrophobicity after 600 Taber abrasion cycles, outperforming most reported waterborne systems. Additionally, the fluorinated hierarchical interface imparts excellent chemical resistance, long-term environmental durability, and remarkable anti-icing performance, e.g., prolonged freezing delay and ultralow ice adhesion strength. This work establishes a general, environmentally benign strategy for engineering high-performance waterborne superhydrophobic coatings by structurally decoupling robustness and wettability. It also offers a scalable platform for durable antifouling and ice-mitigation applications under harsh operating conditions.
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