Microstructure-alone induced transition from hydrophilic to hydrophobic wetting state on silicon

•Microstructure- alone induced transition from inherently hydrophilic to hydrophobic surface.•Wetting transition achieved using microstructures consisting of re-entrant microcavities.•EDX results confirmed that silicon was the only element present on the microfabricated surfaces.•A liquid droplet on...

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Bibliographic Details
Published in:Applied surface science 2015-06, Vol.339, p.137-143
Main Authors: Ems, Henry, Ndao, Sidy
Format: Article
Language:English
Subjects:
Air entrapment
Contact angle
Droplets
Hydrophobic
Hydrophobicity
Microcavities
Microstructure
Re-entrant microcavities
Silicon
Surface energy
Wetting
Wetting transition
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Summary:•Microstructure- alone induced transition from inherently hydrophilic to hydrophobic surface.•Wetting transition achieved using microstructures consisting of re-entrant microcavities.•EDX results confirmed that silicon was the only element present on the microfabricated surfaces.•A liquid droplet on the microstructured surface is believed to be sitting in a Cassie state. Surface hydrophobicity is primarily attained through the use of low surface energy materials. Experimental attempts to turn hydrophilic surfaces to hydrophobic have consisted of coating and thin film deposition. However, in many applications low surface energy materials and coatings are not practical, though hydrophobicity is still desired. In this paper, we demonstrate the transition from hydrophilic to hydrophobic wetting states on an intrinsically hydrophilic surface (contact angle less than 45°) using only surface microstructuring. The surface microstructures consist of re-entrant microcavities which interfere with the complete wetting of the surface, causing a liquid droplet to sit on the surface in a Cassie wetting state. The microstructures were fabricated on a silicon-on-insulator (SOI) wafer through steps of photolithography, etching, and bonding. Contact angle measurements demonstrated the ability of the microfabricated surfaces to sustain large contact angles above 100°, compared to a bare silicon surface which has a contact angle of 40°. Energy-dispersive X-ray spectroscopy showed silicon to be the only chemical element on the surface, while optical observations with an inverted microscope hinted to the existence of a Cassie wetting state.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2015.02.135