Rates of Cavity Filling by Liquids

Authors

Dongjin Seo, Brigham Young University - ProvoFollow
Alex M. Schrader, University of California, Santa Barbara
Szu-Ying Chen, University of California, Santa Barbara
Yair Kaufman, Ben-Gurion University of the Negev
Thomas R. Cristiani, University of California, Santa Barbara
Steven H. Page, The Procter & Gamble Co.
Peter H. Koenig, The Procter & Gamble Co.
Yonas Gizaw, The Procter & Gamble Co.
Dong Woog Lee, Ulsan National Institute of Science and Technology
Jacob N. Israelachvili, University of California, Santa Barbara

Keywords

wetting transition, wetting dynamics, wenzel, Cassie-Baxter

Abstract

Understanding the fundamental wetting behavior of liquids on surfaces with pores or cavities provides insights into the wetting phenomena associated with rough or patterned surfaces, such as skin and fabrics, as well as the development of everyday products such as ointments and paints, and industrial applications such as enhanced oil recovery and pitting during chemical mechanical polishing. We have studied, both experimentally and theoretically, the dynamics of the transitions from the unfilled/partially filled (Cassie–Baxter) wetting state to the fully filled (Wenzel) wetting state on intrinsically hydrophilic surfaces (intrinsic water contact angle < 90°, where the Wenzel state is always the thermodynamically favorable state, while a temporary metastable Cassie–Baxter state can also exist) to determine the variables that control the rates of such transitions. We prepared silicon wafers with cylindrical cavities of different geometries and immersed them in bulk water. With bright-field and confocal fluorescence microscopy, we observed the details of, and the rates associated with, water penetration into the cavities from the bulk. We find that unconnected, reentrant cavities (i.e., cavities that open up below the surface) have the slowest cavity-filling rates, while connected or non-reentrant cavities undergo very rapid transitions. Using these unconnected, reentrant cavities, we identified the variables that affect cavity-filling rates: (i) the intrinsic contact angle, (ii) the concentration of dissolved air in the bulk water phase (i.e., aeration), (iii) the liquid volatility that determines the rate of capillary condensation inside the cavities, and (iv) the presence of surfactants.

Original Publication Citation

D. Seo,A.M. Schrader,S. Chen,Y. Kaufman,T.R. Cristiani,S.H. Page,P.H. Koenig,Y. Gizaw,D.W. Lee, & J.N. Israelachvili, Rates of cavity filling by liquids, Proc. Natl. Acad. Sci. U.S.A. 115 (32) 8070-8075, https://doi.org/10.1073/pnas.1804437115 (2018).

BYU ScholarsArchive Citation

Seo, Dongjin; Schrader, Alex M.; Chen, Szu-Ying; Kaufman, Yair; Cristiani, Thomas R.; Page, Steven H.; Koenig, Peter H.; Gizaw, Yonas; Lee, Dong Woog; and Israelachvili, Jacob N., "Rates of Cavity Filling by Liquids" (2018). Faculty Publications. 8372.
https://scholarsarchive.byu.edu/facpub/8372

Document Type

Peer-Reviewed Article

Publication Date

2018-07-19

Publisher

National Academy of Sciences

Language

English

College

Ira A. Fulton College of Engineering

Department

Chemical Engineering

University Standing at Time of Publication

Associate Professor

Copyright Status

© 2018. Published under the PNAS license.

Copyright Use Information

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