Impact of hydrophobic surfaces on capillary wetting

Impact of hydrophobic surfaces on capillary wetting

The dynamic wetting behavior as first step in reconstitution of heterogeneous model food powders was investigated in the present work. Therefore, we studied the capillary rise of water into single pores and pore systems containing hydrophilic and hydrophobic walls. A two-wall setup was developed to...

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Bibliographic Details
Published in:Powder technology Vol. 328; pp. 367 - 374
Main Authors: Kammerhofer, J., Fries, L., Dupas, J., Forny, L., Heinrich, S., Palzer, S.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-04-2018
Subjects:
Capillary wetting
Cassie-Baxter equation
Equilibrium height
Heterogeneous systems
Hydrophobic surface
Wetting time
Equilibrium height
Heterogeneous systems
Wetting time
Cassie-Baxter equation
Capillary wetting
Hydrophobic surface
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Summary:The dynamic wetting behavior as first step in reconstitution of heterogeneous model food powders was investigated in the present work. Therefore, we studied the capillary rise of water into single pores and pore systems containing hydrophilic and hydrophobic walls. A two-wall setup was developed to realize the capillary rise in a single gap containing walls with two different contact angles but a constant pore size. The equilibrium penetration height was measured and compared to calculated heights using advancing contact angles inserted in a model equation. Wetting experiments in a Washburn setup were performed with respect to the investigation of water penetration into a heterogeneous pore network which leads to a variable pore size during the rise. In order to determine the effect of contact angle, three different glass materials at varied levels of hydrophobicity were prepared. Furthermore, a focus was put on understanding the impact of the pore network on the wetting kinetics by mixing two size fractions of glass beads. The equilibrium heights determined in heterogeneous single gaps fit well with the calculated heights by inserting advancing contact angles into the model equation. The results of the powder systems show a significant impact on the wetting with an increasing hydrophobic fraction, while an increased hydrophobic contact angle further increased the wetting time only at higher quantities of the hydrophobic component in the sample. Furthermore, our findings emphasize the complexity of wetting into a system with heterogeneity in pore size and contact angle. [Display omitted] •The wetting time increases with an increasing hydrophobic fraction.•Increased hydrophobic contact angles affect the wetting only at higher quantities.•Wetting is dominated by hydrophilic contact angle at hydrophobic content <30 wt%.•Wetting is dominated by hydrophobic contact angle at hydrophobic content >30 wt%.
ISSN:0032-5910
1873-328X
DOI:10.1016/j.powtec.2018.01.033