4.7 Article

Liquid bridge splitting enhances normal capillary adhesion and resistance to shear on rough surfaces

期刊

JOURNAL OF COLLOID AND INTERFACE SCIENCE
卷 607, 期 -, 页码 514-529

出版社

ACADEMIC PRESS INC ELSEVIER SCIENCE
DOI: 10.1016/j.jcis.2021.08.133

关键词

Surface tension; Capillary adhesion; Roughness; Shear resistance

资金

  1. EPSRC [EP/N509711/1]
  2. Corpus Christi Shand Green-MI Scholarship
  3. European Research Council under the European Union [637334]
  4. Philip Leverhulme Prize

向作者/读者索取更多资源

The splitting of bridges significantly enhances adhesion force between rough surfaces, with the enhancement increasing with surface roughness; maximizing the number of bridges can increase total adhesion force by an order of magnitude. Shear resistance increases linearly with translation velocity and the behavior of many shearing bridges is quantified.
Hypothesis: 'Bridge splitting' is considered in the case of capillary adhesion: a fixed total volume of liquid is split into multiple capillary bridges. Previous studies have shown that bridge splitting only enhances the capillary-induced adhesion force between two planar surfaces in specific circumstances. We hypothesise that bridge splitting significantly enhances the total adhesion force between rough surfaces, since mobile wetting bridges can naturally migrate to narrower gaps. This migration of capillary bridges should also provide a resistance to shear. Numerical experiments: We theoretically consider an idealized system of many liquid bridges confined between two solid surfaces. By numerically calculating the shape of a single bridge, the total adhesion force is found as the number of bridges and roughness are varied. The resistance to shear is also calculated in the limit of strong surface tension or small shears. Findings: Bridge splitting on a rough surface significantly enhances the adhesion force, with an enhancement that increases with the amplitude of the roughness; maximising over the number of bridges can increase the total adhesion force by an order of magnitude. Resistance to shear is shown to increase linearly with the translation velocity, and the behaviour of many such shearing bridges is quantified. (c) 2021 Elsevier Inc. All rights reserved.

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