光热治疗
砂纸
材料科学
涂层
复合材料
磨损(机械)
粘附
光热效应
接触角
图层(电子)
超疏水涂料
环氧树脂
表面能
纳米技术
润湿
复合数
环境友好型
工作(物理)
表面粗糙度
表面改性
光学涂层
表面光洁度
科技与社会
作者
Liang Yin,Xiaosen Wang,Fapeng Zhang,Yangyang Jia,Yujie Liu,Jia‐Yi Wang,Qiang He
摘要
ABSTRACT Currently, most superhydrophobic materials suffer from problems such as complex preparation, reliance on fluorine‐containing reagents, poor mechanical durability, and unclear photothermal anti‐icing mechanism. To address these bottlenecks, we proposed and implemented an innovative integrated strategy. Through an environmentally friendly one‐step spraying process, we combined the high adhesion of epoxy resin, the low surface energy of polydimethylsiloxane, and the photothermal and structural functions of micro‐nano SiO 2 /NiO, successfully constructing a composite coating that possesses excellent mechanical stability, long‐lasting superhydrophobicity, and efficient photothermal response. The contact angle of the coating reached 161.3°, and the sliding angle was 2°. It maintains superhydrophobicity even after 100 sandpaper abrasion cycles and 20 icing/deicing cycles, along with a highly efficient photothermal response. Anti‐icing and de‐icing tests show that at −5°C, −10°C, and −15°C, the coating delays icing by 20.5, 19.9, and 23.9 times compared to the substrate, respectively. Under 1.0 sun illumination, it melts a −15°C ice layer completely within 103 s and retains stable performance after rigorous environmental testing. This work not only provides a high‐performance anti‐icing coating but also demonstrates a universal design strategy that can synergistically enhance mechanical durability, surface superhydrophobicity, and photothermal conversion performance. It offers an indispensable solution for the surface protection of critical equipment in extreme environments.
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