Morphology of Air Nanobubbles Trapped at Hydrophobic Nanopatterned Surfaces

Citations Over TimeTop 10% of 2010 papers

Abstract

The details of air nanobubble trapping at the interface between water and a nanostructured hydrophobic silicon surface are investigated using X-ray scattering and contact angle measurements. Large-area silicon surfaces containing hexagonally packed, 20 nm wide hydrophobic cavities provide ideal model surfaces for studying the morphology of air nanobubbles trapped inside cavities and its dependence on the cavity depth. Transmission small-angle X-ray scattering measurements show stable trapping of air inside the cavities with a partial water penetration of 5-10 nm into the pores, independent of their large depth variation. This behavior is explained by consideration of capillary effects and the cavity geometry. For parabolic cavities, the liquid can reach a thermodynamically stable configuration-a nearly planar nanobubble meniscus-by partially penetrating into the pores. This microscopic information correlates very well with the macroscopic surface wetting behavior.

Related Papers

• → RETRACTED: Application of the small-angle X-ray scattering technique for structural analysis studies: A review(2017)36 cited
• → Structural Characterization of Nucleic Acid Nanoparticles Using SAXS and SAXS-Driven MD(2023)6 cited
• → Small angle X-ray scattering of nanoporous membranes: Effects of geometry and concentration(2022)5 cited
• → IntegrativeSAXS‐Driven Computational Modeling of Biomolecular Complexes(2018)1 cited
• → SAXS investigations of polyethylene modified with methacrylic acid(1993)