• Title of article

    Justification of biexponential rate law of spreading over heterogeneous and rough surfaces

  • Author/Authors

    Slavchov، نويسنده , , Radomir and Dutschk، نويسنده , , Victoria and Heinrich، نويسنده , , Gert and Radoev، نويسنده , , Boryan، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2010
  • Pages
    9
  • From page
    252
  • To page
    260
  • Abstract
    Both surface roughness and chemical heterogeneity can be viewed as surface energy fluctuations acting as energy barriers for the three phase contact (TPC) line motion. This viewpoint provides a way to obtain the TPC line propagation rate as a function of the TPC contact angle in the frame of either nucleation rate theory or Eyringʹs absolute rate theory. In this study, a general biexponential rate law is deduced, and the wetting kinetic characteristics are related to statistical characteristics of the surface chemical heterogeneity and roughness, experimentally available from surface image analysis. A step mechanism for TPC line propagation is proposed; the barrier for a step is due to solid surface roughness and liquid surface corrugation, and the absolute frequency of steps is estimated through the dispersion relation of the capillary waves at the liquid surface. The free energy vs. TPC contact angle diagram of a randomly rough surface is deduced and found to be very similar to Dettre–Johnsonʹs diagrams of periodically rough surfaces. The TPC propagation rate law is generally asymmetric, in accordance with the available experimental data. A comparison with experimental dynamic contact angle hysteretic curves gives reasonable values of the modelʹs parameters.
  • Keywords
    Wetting kinetics , Heterogeneous surface , Surface roughness , Three phase contact line , capillary waves , Nucleation Theory
  • Journal title
    Colloids and Surfaces A Physicochemical and Engineering Aspects
  • Serial Year
    2010
  • Journal title
    Colloids and Surfaces A Physicochemical and Engineering Aspects
  • Record number

    1938938