材料科学
涂层
聚二甲基硅氧烷
润湿
生物污染
接触角
多孔性
超疏水涂料
粘附
复合材料
纳米颗粒
纳米复合材料
化学工程
聚四氟乙烯
纳米技术
产量(工程)
热的
作者
Khawla Alsamhary,Nouf M. Al‐Enazi,Hossein Ali Khonakdar
标识
DOI:10.1016/j.colsurfa.2025.139036
摘要
Superhydrophobic surfaces that retain their functionality after thermal stress are of great interest for self-cleaning and antifouling applications, offering enhanced durability. Herein, we compared one-step and two-step spray-coating methods for preparing nanocomposite coatings based on polydimethylsiloxane (PDMS) and polytetrafluoroethylene nanoparticles (nano-PTFE) on steel substrates, emphasizing how the coating architecture influences morphology, wettability, thermal stability, and bacterial adhesion. Based on morphological analysis, the one-step route produced sparsely exposed nano-PTFE at the surface, resulting in water contact angles (WCAs) of 100°-120° and sliding angles (SAs) of 35°-45°. The two-step method resulted in a dense coverage of nano-PTFE and hierarchical micro/nanostructures, which facilitated Cassie-type wetting and superhydrophobicity (WCA = 158°, SA = 5°). Incorporation of nano-TiO₂ into the two-step coating further increased surface porosity and raised the WCA to 163°, and decreased the SA to 2°. Under repeated high-temperature cycling at 120 °C, the PDMS/nano-PTFE coating lost superhydrophobicity after ~70 cycles, whereas the TiO 2 -loaded coating preserved self-cleaning behavior beyond 100 cycles. Bacterial adhesion assays (reported as log CFU/cm 2 ) showed 1.5-log (~96.8%) and 2.2-log (~99.4%) reductions compared to bare steel for the PDMS/nano-PTFE and PDMS/nano-PTFE/TiO 2 coatings, respectively. The antibacterial properties of superhydrophobic coatings were tested after successive heating cycles, and only the TiO 2 -loaded coating maintained its antibacterial efficacy without a significant decrease. The obtained results elucidate the structure-wettability-durability relationships and highlight hierarchical nanoparticle architectures that yield thermally stable and antifouling surfaces, making them suitable for biomedical applications. • The one-step method results in sparsely exposed PTFE nanoparticles (WCA=100-120°) • The two-step approach produces dual-scale structures, leading to superhydrophobicity. • Adding TiO₂ to the two-step coating improves the self-cleaning properties. • The prepared coatings showed excellent resistance against repeated thermal heating. • The PDMS/PTFE/TiO₂ coating achieves an antibacterial rate of 99.4% and retains it after exposure to 100 heating cycles.
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