Issue 35, 2017

Influence of surface tension in the surfactant-driven fracture of closely-packed particulate monolayers

Abstract

A phase-field model is used to capture the surfactant-driven formation of fracture patterns in particulate monolayers. The model is intended for the regime of closely-packed systems in which the mechanical response of the monolayer can be approximated as that of a linearly elastic solid. The model approximates the loss in tensile strength of the monolayer with increasing surfactant concentration through the evolution of a damage field. Initial-boundary value problems are constructed and spatially discretized with finite element approximations to the displacement and surfactant damage fields. A comparison between model-based simulations and existing experimental observations indicates a qualitative match in both the fracture patterns and temporal scaling of the fracture process. The importance of surface tension differences is quantified by means of a dimensionless parameter, revealing thresholds that separate different regimes of fracture. These findings are supported by newly performed experiments that validate the model and demonstrate the strong sensitivity of the fracture pattern to differences in surface tension.

Graphical abstract: Influence of surface tension in the surfactant-driven fracture of closely-packed particulate monolayers

Article information

Article type
Paper
Submitted
23 Jun 2017
Accepted
29 Jul 2017
First published
31 Jul 2017
This article is Open Access
Creative Commons BY license

Soft Matter, 2017,13, 5832-5841

Influence of surface tension in the surfactant-driven fracture of closely-packed particulate monolayers

C. Peco, W. Chen, Y. Liu, M. M. Bandi, J. E. Dolbow and E. Fried, Soft Matter, 2017, 13, 5832 DOI: 10.1039/C7SM01245D

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