Two-step ion beam treatment for superhydrophilic fluorinated polymers

Abstract

Plasma treatment is a widely used simple and ecofriendly method to improve the surface wettability of polymers. However, this is challenging for fluorinated polymers because of their robust CF bonds with low surface energies. Here, we demonstrated a simple approach, involving Ar-H2 and O2-H2 two-step ion beam treatments, to achieve superhydrophilic fluorinated polymer surfaces. The effects of surface roughness and chemical composition on the water contact angle (WCA) were studied using X-ray photoelectron spectroscopy, scanning electron microscopy, and atomic force microscopy. After the single H2 ion beam treatment on fluorinated ethylene propylene films, the WCA decreased from 110.2° to 35.2° due to defluorination and oxidation effects. However, the H2 ion beam treatment alone has a limited effect on the root-mean-square (RMS) roughness, which hinders achieving superhydrophilicity. In contrast, the WCA significantly decreased to 1.3° and 1.2°, respectively after the Ar-H2 and O2-H2 two-step ion beam treatments. Although the chemical composition after these treatments was similar to that after the single H2 ion beam treatment, the RMS roughness increased upon the Ar and O2 ion beam treatments because of the formation of nanostructures. Our results show that nanostructures with abundant polar oxygen bonds are required to obtain superhydrophilic surfaces in fluorinated polymers.