WETTING CHARACTERISTICS OF LIQUID-DROPS AT HETEROGENEOUS SURFACES

Well-defined heterogeneous surfaces consisting of hydrophobic and hydrophilic regions were prepared on gold (a 2000 Angstrom gold him supported on an Si/SiO2/Ti substrate) by patterning self-assembled monolayers (SAMs), using an elastomer stamp. One surface was composed of alternating and parallel hydrophobic (2.5 Irm) and hydrophilic (3 mu m) strips, and the second surface consisted of alternating hydrophilic squares (3 mu m x 3 Irm) separated by hydrophobic strips (2.5 mu m). The wetting characteristics of these well-defined heterogeneous solid surfaces were examined by contact angle measurements. The contact angles for water drops, which varied in pH from 5.8 to 10.0, were measured with the strips both tangential to and normal to the three-phase contact line. The experimental contact angles are in good agreement with theory as calculated from the Cassie equation when the three-phase contact line is non-contorted (i.e. the three-phase contact line is situated along the hydrophobic strip). On the other hand, when the strips are normal to the drop edge, corrugation of the three-phase contact line affects the contact angle significantly. Contact angles, measured with the strips normal to the drop edge, were lower by 7-16 degrees than those calculated from the Cassie equation. Analysis of these measurements, together with contact angle/drop size measurements for fully hydrophobic and hydrophilic surfaces, demonstrate the validity of a modified Cassie equation that includes a term describing the line tension contribution.