Facile Fabrication of Superhydrophobic Polymer Membranes with Hierarchical Structure for Efficient Oil/Water Separation

• Published in: Fibers and polymers Vol. 23; no. 9; pp. 2365 - 2372
• Main Authors: Kim, Da-Seul, Kang, Jeongmin, Jung, Jae-Yeong, Hwang, Minsik, Seo, Soonmin, Kim, Ju-Hyung
• Format: Journal Article
• Language: English
• Published: Seoul The Korean Fiber Society 01.09.2022; Springer Nature B.V; 한국섬유공학회
• Subjects: Chemistry; Chemistry and Materials Science; Communication; Cost effectiveness; Coupling agents; Formability; Hexanes; Hydrophobic surfaces; Hydrophobicity; Membranes; Nanoparticles; Polymer Sciences; Polymers; Polyurethane resins; Separation; Separators; Structural hierarchy; Surface energy; Wettability; 섬유공학; Surface functionalization; Silica nanoparticles; Polymer membranes; Oil/water separation; Hydrophobicity
• ISSN: 1229-9197; 1875-0052
• DOI: 10.1007/s12221-022-0062-1

Superhydrophobic polymer membranes provide highly promising methods for efficient oil/water separation because of their cost effectiveness, and environmental friendliness. A variety of polymers have been widely used for the membrane fabrication, among which polyurethane acrylate (PUA) presents strong advantages of excellent mechanical strength with high deformability and chemical stability. In this study, we present a facile and rapid method for the fabrication of PUA-based superhydrophobic membranes with hierarchical structure, enabling efficient oil/water separation. For this work, PUA membranes with uniform pores were prepared via soft lithography, on which silica nanoparticles were deposited. The nanoparticles were preferentially functionalized with a silane coupling agent to lower the surface energy, and then spray-coated onto the PUA membrane supports to spontaneously form the hierarchical structure possessing superhydrophobic properties and excellent wettability to oil. Efficient oil/water separation was successfully demonstrated using a mixture of hexane and water with a separation efficiency of ∼97 %, and the membranes could withstand a high pressure of ∼2.0 kPa. We anticipate that these results will significantly contribute not only to the fabrication of superhydrophobic membranes with uniform pores but also the development of more diversified polymer-based membranes and separators leading to a wide range of applications.