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Abstract
The collapse of a catenoidal soap film when the rings supporting it are moved beyond a critical separation is a classic problem in interface motion in which there is a balance between surface tension and the inertia of the surrounding air, with film viscosity playing only a minor role. Recently [Goldstein et al., Phys. Rev. E, 2021, 104, 035105], we introduced a variant of this problem in which the catenoid is bisected by a glass plate located in a plane of symmetry perpendicular to the rings, producing two identical hemicatenoids, each with a surface Plateau border (SPB) on the glass plate. Beyond the critical ring separation, the hemicatenoids collapse in a manner qualitatively similar to the bulk problem, but their motion is governed by the frictional forces arising from viscous dissipation in the SPBs. We present numerical studies of a model that includes classical laws in which the frictional force f(v) for SPB motion on wet surfaces is of the form f(v) similar to Ca-n, where Ca is the capillary number. Our experimental data on the temporal evolution of this process confirms the expected value n = 2/3 for mobile surfactants and stress-free interfaces. This study can help explain the fragmentation of bubbles inside very confined geometries such as porous materials or microfluidic devices.
Original language | English |
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Pages (from-to) | 4944-4952 |
Number of pages | 9 |
Journal | Soft Matter |
Volume | 18 |
Issue number | 26 |
Early online date | 22 Jun 2022 |
DOIs | |
Publication status | Published - 14 Jul 2022 |
Keywords
- AIR ENTRAINMENT
- STABILITY
- MOTION
- FOAM
- BREAKUP
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Dive into the research topics of 'Collapse of a hemicatenoid bounded by a solid wall: Instability and dynamics driven by surface Plateau border friction'. Together they form a unique fingerprint.Datasets
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Supporting material for "Collapse of a hemicatenoid bounded by a solid wall: instability and dynamics driven by surface Plateau border friction"
Cox, S., Prifysgol Aberystwyth | Aberystwyth University, 29 Jun 2022
DOI: 10.20391/61ff954f-76d6-4611-b2a9-45d85a2fd879
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Projects
- 1 Finished
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Flow of Gas-Liquid Foams in Narrow Complex Geometries
Cox, S. (PI)
Engineering and Physical Sciences Research Council
01 Apr 2016 → 31 Mar 2019
Project: Externally funded research