材料科学
自愈
光热治疗
纳米技术
复合材料
医学
病理
替代医学
作者
Yuanlong Wu,Lei Dong,Xin Shu,Lei Chen,Youfa Zhang,Qianping Ran
标识
DOI:10.1016/j.matdes.2025.114262
摘要
• Polydopamine@Silica raspberry-like core-shell nanoparticles were synthesized to enhance surface roughness, light absorption, and solvent dispersion stability. • A fluorine-free superhydrophobic fabric was developed using a one-step spraying process incorporating photothermal and self-healing functionalities. • The coated fabric exhibits strong resistance to abrasion, chemical exposure, and high-speed water droplet impact. • Surface damage can be spontaneously repaired, restoring water repellency and enabling effective anti-icing and light-driven de-icing performance in cold environments. Functional fabrics are essential for cold-environment protection, but conventional textiles often lack sufficient resistance to moisture and freezing. Although superhydrophobic fabrics offer water repellency and self-cleaning, their practical application is hindered by poor durability, fluorinated compounds, and limited anti-icing performance. Here, we present a fluorine-free, scalable strategy to fabricate durable photothermal superhydrophobic fabrics (PSF) using a one-step spraying method. The design is based on raspberry-like polydopamine–silica (PDA@SiO 2 ) core–shell nanoparticles and a supramolecular polymer matrix. This architecture enhances broadband absorption, mechanical robustness, and dispersion stability. The resulting PSF exhibits a high water contact angle (162.6°), strong liquid impingement resistance, and excellent mechanical and chemical durability. After O 2 plasma treatment, the surface spontaneously recovers its superhydrophobicity, confirming its self-healing ability. Anti-icing performance is demonstrated by a freezing delay time of 838 s at −20 °C and a reduced ice adhesion strength of 23.5 kPa. Under 1.0 kW/m 2 irradiation, the surface temperature reaches 75.2 °C within 330 s and melts surface ice within 613 s. Photothermal stability is maintained after repeated bending and laundering. This study provides a sustainable pathway toward multifunctional textiles that integrate photothermal conversion, self-healing, ice resistance, and fluorine-free superhydrophobicity for cold-weather applications.
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