3D printable hydrophobic ink is highly desirable to simply print hydrophobic objects for various applications, such as oil/water separation. However, printable hydrophobic monomers/inks are limited which seriously restricts the fabrication and application of 3D printing hydrophobic objects. Herein, simulating the crown, trunk, and roots of trees from the molecular levels, coatings/objects were designed and prepared using a 6-functional hyperbranching polyurethane acrylate (PUA) monomer as the "trunk", mono-acrylate terminated polydimethylsiloxane (Vi-PDMS) as the "leaf", and tripropylene glycol diacrylate (TPGDA) as the "root". The printed objects with excellent mechanical properties and stable hydrophobicity with CAs and SAs in the range of 80 degrees-110 degrees and 10 degrees-30 degrees, respectively, and could be used in a variety of environments (e.g., acid-based solution, seawater) for a month. Cylindrical, ladder, and mushroom-shaped micro-nano structures could be prepared to improve the hydrophobicity of the printed objects to achieve CAs up to similar to 170 degrees. The antiadhesion tough teeth and microchannels could be prepared facilely with the hydrophobic inks. This work demonstrates a simple and rapid method to manufacture various complex and sophisticated hydrophobic coatings/objects and a broader strategy for 3D printing technology.

• 单位
  广州大学