Chen Yong, He Bo, Lee Junghoon, Patankar Neelesh A
Department of Mechanical Engineering, Northwestern University, 2145 Sheridan Road, Evanston, IL 60208-3111, USA.
J Colloid Interface Sci. 2005 Jan 15;281(2):458-64. doi: 10.1016/j.jcis.2004.07.038.
Surface roughness amplifies the water-repellency of hydrophobic materials. If the roughness geometry is, on average, isotropic then the shape of a sessile drop is almost spherical and the apparent contact angle of the drop on the rough surface is nearly uniform along the contact line. If the roughness geometry is not isotropic, e.g., parallel grooves, then the apparent contact angle is no longer uniform along the contact line. The apparent contact angles observed perpendicular and parallel to the direction of the grooves are different. A better understanding of this problem is critical in designing rough superhydrophobic surfaces. The primary objective of this work is to determine the mechanism of anisotropic wetting and to propose a methodology to quantify the apparent contact angles and the drop shape. We report a theoretical and an experimental study of wetting of surfaces with parallel groove geometry.
表面粗糙度会增强疏水材料的疏水性。如果粗糙度几何形状平均而言是各向同性的,那么静置液滴的形状几乎是球形的,并且液滴在粗糙表面上的表观接触角沿接触线几乎是均匀的。如果粗糙度几何形状不是各向同性的,例如平行凹槽,那么表观接触角沿接触线就不再均匀。垂直于和平行于凹槽方向观察到的表观接触角是不同的。更好地理解这个问题对于设计粗糙超疏水表面至关重要。这项工作的主要目标是确定各向异性润湿的机制,并提出一种量化表观接触角和液滴形状的方法。我们报告了一项关于具有平行凹槽几何形状表面润湿的理论和实验研究。