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Characterization of wetting using topological principles.

Chenhao Sun1, James E McClure2, Peyman Mostaghimi1

  • 1School of Minerals & Energy Resources Engineering, University of New South Wales, Kensington, NSW 2052, Australia.

Journal of Colloid and Interface Science
|June 11, 2020
PubMed
Summary
This summary is machine-generated.

A new topological approach offers a robust measure for wetting behavior in complex systems, outperforming traditional contact angle measurements at lower resolutions.

Keywords:
Gauss-Bonnet theoremGaussian curvatureGeometric state of fluidsInterfacial curvatureMultiphase flowPorous mediaTopological principlesWetting behavior

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Area of Science:

  • Surface science and physical chemistry.
  • Multiphase flow and fluid dynamics.
  • Topological physics and geometry.

Background:

  • Wetting behavior is crucial for natural phenomena and technological applications.
  • Traditional contact angle measurements, based on geometrical curvature and Young's equation, face limitations in complex systems.
  • The representativeness of contact angle for intricate wetting scenarios remains an open question.

Purpose of the Study:

  • To introduce and validate a novel topological principle for characterizing wetting states.
  • To assess the robustness and sensitivity of this topological approach against traditional methods.
  • To explore the potential of topological concepts for studying complex multiphase systems.

Main Methods:

  • Introduction of a macroscopic contact angle derived from the deficit curvature of fluid interfaces.
  • Sessile droplet simulations and multiphase experiments on porous materials (sintered glass, Bentheimer sandstone).
  • Comparative analysis with traditional contact angle measurement techniques.

Main Results:

  • The topological principle aligns with thermodynamic principles under simple conditions.
  • The proposed approach yields results comparable to local contact angle measurements at high image resolutions.
  • At lower resolutions, the topological method demonstrates superior accuracy and robustness against resolution-dependent artifacts.

Conclusions:

  • The developed topological approach provides a more accurate and robust measure of wetting in complex systems.
  • This method offers advantages over traditional contact angle measurements, especially under varying resolution conditions.
  • The study opens new avenues for characterizing wetting in complex systems and advancing theoretical understanding of multiphase phenomena.