Effect of Superhydrophobic Surfaces for Wetting in Micro-Systems

To develop energy efficient microfluidic systems it is important to minimize the adhesion of the liquid to the surfaces in the system. One of the proposed methods in the literature is to use superhydrophobic surfaces, i.e. surfaces with contact angles above 150 degrees (for water). However, the issu...

Full description

Saved in:
Bibliographic Details
Published in2004 International Conference on MEMS, NANO and Smart Systems (ICMENS'04) p. 329
Main Authors Li, W., Mohamadi, R., Amirfazli, A.
Format Conference Proceeding
LanguageEnglish
Published IEEE 2004
Subjects
Adhesives
Contact angle
Energy barrier
Energy efficiency
Equations
Hysteresis
Liquids
Mechanical engineering
Micro-texture
Super-hydrophobic surface
Thermodynamics
Wetting
Online AccessGet full text

Cover

More Information
Summary:To develop energy efficient microfluidic systems it is important to minimize the adhesion of the liquid to the surfaces in the system. One of the proposed methods in the literature is to use superhydrophobic surfaces, i.e. surfaces with contact angles above 150 degrees (for water). However, the issue that is not generally considered in depth in literature is the role of contact angle hysteresis (the difference between advancing and receding contact angles). In other words, to have an energy efficient droplet actuation system for microfluidics it is not sufficient to use surfaces that have large contact angles, but they also should have low contact angle hysteresis (CAH). Contact angle hysteresis is a common phenomenon in wetting. It is important but difficult to theoretically investigate CAR to optimally design superhydrophobic surfaces for micro-systems. We will present a universal approach to calculate CAR based on a free energy analysis for micro-textured surfaces. Thermodynamic status of contact angles and calculation of free the energy barrier are significantly simplified by using a representative 2D model instead of a 3D model with minimum loss of generality. A pillar surface structure is chosen as a typical example (see Figure 1). It is demonstrated that this approach can predict CAR and equilibrium contact angles that are consistent with predictions of Wenzel's and Cassie's equations. This approach can also provide a criterion for transition between noncomposite and composite structures (i.e. free spreading of liquids on a surface or achieving minimum contact area between a liquid drop and surfaces in a channel). Recent experimental results for wetting of superhydrophobic surfaces will also be discussed.
ISBN:9780769521893
0769521894
DOI:10.1109/ICMENS.2004.1508969