Surface tension effects on energy dissipation by small scale, experimental breaking waves
Surface tension effects on energy dissipation by small scale, experimental breaking waves
Much of the existing knowledge about breaking waves comes from physical model experiments scaled using Froude's law. A widely held assumption is that surface tension effects are not significant at typical laboratory scales and specifically for waves longer than 2 m. Since, however, smaller wavelengths are not untypical in small to medium scale laboratory facilities, a consideration of surface tension effects is indeed important. Although some emphasis has been given in the past, little is known regarding the importance of surface tension following impingement of the breaking-wave crest and especially on the overall energy dissipation by laboratory breaking waves.
To answer this question a laboratory study was conducted comparing the energy dissipation rate by waves breaking in fresh-water and in a 10% isopropyl-alcohol and distilled water solution of lower surface tension. It was found that when waves shorter than 4 mand smaller than 0.11 mbreak under the weakened influence of surface tension they dissipate up to 65% more wave energy. Visual observations link the increased wave energy dissipation with greater breaking intensity, increased air entrainment and longer bubble lifetime. Overall, the results presented here indicate that the inability to maintain Weber similarity (ratio of fluid inertia to its surface tension) has a more significant effect on the intensity of wave energy dissipation than previously assumed.
wave breaking, surface tension, small scale
826-836
Stagonas, Dimitris
8aa975d1-679e-49d8-943b-0a3fe2a085ba
Warbrick, David
52b45cea-41b1-4408-9edf-a59e899e01b7
Muller, Gerald
f1a988fc-3bde-429e-83e2-041e9792bfd9
Magagna, Davide
63c89201-845a-479b-a66a-c5cb35cf1aa2
September 2011
Stagonas, Dimitris
8aa975d1-679e-49d8-943b-0a3fe2a085ba
Warbrick, David
52b45cea-41b1-4408-9edf-a59e899e01b7
Muller, Gerald
f1a988fc-3bde-429e-83e2-041e9792bfd9
Magagna, Davide
63c89201-845a-479b-a66a-c5cb35cf1aa2
Stagonas, Dimitris, Warbrick, David, Muller, Gerald and Magagna, Davide
(2011)
Surface tension effects on energy dissipation by small scale, experimental breaking waves.
Coastal Engineering, 58 (9), .
(doi:10.1016/j.coastaleng.2011.05.009).
Abstract
Much of the existing knowledge about breaking waves comes from physical model experiments scaled using Froude's law. A widely held assumption is that surface tension effects are not significant at typical laboratory scales and specifically for waves longer than 2 m. Since, however, smaller wavelengths are not untypical in small to medium scale laboratory facilities, a consideration of surface tension effects is indeed important. Although some emphasis has been given in the past, little is known regarding the importance of surface tension following impingement of the breaking-wave crest and especially on the overall energy dissipation by laboratory breaking waves.
To answer this question a laboratory study was conducted comparing the energy dissipation rate by waves breaking in fresh-water and in a 10% isopropyl-alcohol and distilled water solution of lower surface tension. It was found that when waves shorter than 4 mand smaller than 0.11 mbreak under the weakened influence of surface tension they dissipate up to 65% more wave energy. Visual observations link the increased wave energy dissipation with greater breaking intensity, increased air entrainment and longer bubble lifetime. Overall, the results presented here indicate that the inability to maintain Weber similarity (ratio of fluid inertia to its surface tension) has a more significant effect on the intensity of wave energy dissipation than previously assumed.
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e-pub ahead of print date: 12 June 2011
Published date: September 2011
Keywords:
wave breaking, surface tension, small scale
Organisations:
Water & Environmental Engineering Group
Identifiers
Local EPrints ID: 354871
URI: http://eprints.soton.ac.uk/id/eprint/354871
ISSN: 0378-3839
PURE UUID: 7d335829-d10c-49fb-baeb-54e90533d4d5
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Date deposited: 29 Jul 2013 14:18
Last modified: 14 Mar 2024 14:25
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Author:
Dimitris Stagonas
Author:
David Warbrick
Author:
Davide Magagna
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