posted on 2023-02-10, 16:35authored byMahtab Masouminia, Kari Dalnoki-Veress, Charles-François de Lannoy, Benzhong Zhao
Wettability plays a significant role in controlling multiphase
flow in porous media for many industrial applications, including geologic
carbon dioxide sequestration, enhanced oil recovery, and fuel cells.
Microfluidics is a powerful tool to study the complexities of interfacial
phenomena involved in multiphase flow in well-controlled geometries.
Recently, the thiolene-based polymer called NOA81 emerged as an ideal
material in the fabrication of microfluidic devices, since it combines
the versatility of conventional soft photolithography with a wide
range of achievable wettability conditions. Specifically, the wettability
of NOA81 can be continuously tuned through exposure to UV–ozone.
Despite its growing popularity, the exact physical and chemical mechanisms
behind the wettability alteration have not been fully characterized.
Here, we apply different characterization techniques, including contact
angle measurements, X-ray photoelectron spectroscopy (XPS), and atomic
force microscopy (AFM) to investigate the impact of UV–ozone
on the chemical and physical properties of NOA81 surfaces. We find
that UV–ozone exposure increases the oxygen-containing polar
functional groups, which enhances the surface energy and hydrophilicity
of NOA81. Additionally, our AFM measurements show that spin-coated
NOA81 surfaces have a roughness less than a nanometer, which is further
reduced after UV–ozone exposure. Lastly, we extend NOA81 use
cases by creating (i) 2D surface with controlled wettability gradient
and (ii) a 3D column packed with monodisperse NOA81 beads of controlled
size and wettability.