Superhydrophobic meta-aramid papers prepared by the surface-embedded spray coating strategy

“…The superhydrophobic properties of the PFDT/PDA composite coatings were further performed, as shown in Figure 1e,f. 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° 40–42 . 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.…”

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

“…The superhydrophobic properties of the PFDT/PDA composite coatings were further performed, as shown in Figure 1e,f. 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° 40–42 . 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.…”

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

Excellent mechanical durability of superhydrophobic surface based on fiber array for biological applications

Rapid attainment of full wettability through surface PEGylation of hydrophobic polyvinylidene fluoride membranes via spray-coating for enhanced anti-biofouling performances