Wave ripple development on mixed clay‐sand substrates: effects of clay winnowing and armoring
Wave ripple development on mixed clay‐sand substrates: effects of clay winnowing and armoring
Based on bed form experiments in a large-scale flume, we demonstrate that the rate of development of wave ripples on a mixed sand-clay bed under regular waves is significantly lower than on a pure-sand bed, even at clay fractions as low as 4.2%, and that this rate of development decreases exponentially from 4.2% to 7.4% clay. These experiments also showed that, despite the slow growth of the bed forms in the mixed sand-clay, the equilibrium length and height of the wave ripples were independent of the initial bed clay fraction. Given that the ripple crests were composed of pure sand at the end of all the experiments that started with well-mixed sand-clay, it is inferred that the clay was removed from the bed during the development of the wave ripples through winnowing into the water column, and possibly also by sieving into the subsurface, where the final clay fractions were found to be higher than the initial clay fractions. These clay removal processes are interpreted to have facilitated the wave ripples to reach equilibrium lengths and heights that are similar to those in pure sand. Clay-carrying pore flow initiated by pressure gradients between the wave ripple troughs and crests might also have contributed to the accumulation of clay in the sediment below the wave ripples. The formation of the clay-enriched “armoring” layer in the substrate is likely to further reduce erosion rates and could influence the dispersion of nutrients and pollutants in coastal seas.
2784-2801
Wu, Xuxu
539e8018-671f-4bcd-a199-d600e0f7763e
Baas, Jaco H.
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Parsons, Daniel R.
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Eggenhuisen, Joris T.
157ad755-8819-48cb-8694-6bbffa20b727
Amoudry, Laurent
af4f699a-89e7-4a04-8e1e-2d744b2da932
Cartigny, Matthieu J.B.
bda1b79b-7e11-4790-8238-b86d80a88bb3
McLelland, Stuart
a4060297-1fb9-4721-bc50-4ec36b0499ee
Mouazé, Dominique
527cb30d-920a-423b-9160-cd5d0fc11d62
Ruessink, Gerben
781e4422-fa20-408a-8931-559383dfb7df
5 November 2018
Wu, Xuxu
539e8018-671f-4bcd-a199-d600e0f7763e
Baas, Jaco H.
f7fe84d8-c3ac-4fb6-924c-54e816f9c1f6
Parsons, Daniel R.
59f2673a-9c73-437a-8865-52d52830a3aa
Eggenhuisen, Joris T.
157ad755-8819-48cb-8694-6bbffa20b727
Amoudry, Laurent
af4f699a-89e7-4a04-8e1e-2d744b2da932
Cartigny, Matthieu J.B.
bda1b79b-7e11-4790-8238-b86d80a88bb3
McLelland, Stuart
a4060297-1fb9-4721-bc50-4ec36b0499ee
Mouazé, Dominique
527cb30d-920a-423b-9160-cd5d0fc11d62
Ruessink, Gerben
781e4422-fa20-408a-8931-559383dfb7df
Wu, Xuxu, Baas, Jaco H., Parsons, Daniel R., Eggenhuisen, Joris T., Amoudry, Laurent, Cartigny, Matthieu J.B., McLelland, Stuart, Mouazé, Dominique and Ruessink, Gerben
(2018)
Wave ripple development on mixed clay‐sand substrates: effects of clay winnowing and armoring.
Journal of Geophysical Research: Earth Surface, 123 (11), .
(doi:10.1029/2018JF004681).
Abstract
Based on bed form experiments in a large-scale flume, we demonstrate that the rate of development of wave ripples on a mixed sand-clay bed under regular waves is significantly lower than on a pure-sand bed, even at clay fractions as low as 4.2%, and that this rate of development decreases exponentially from 4.2% to 7.4% clay. These experiments also showed that, despite the slow growth of the bed forms in the mixed sand-clay, the equilibrium length and height of the wave ripples were independent of the initial bed clay fraction. Given that the ripple crests were composed of pure sand at the end of all the experiments that started with well-mixed sand-clay, it is inferred that the clay was removed from the bed during the development of the wave ripples through winnowing into the water column, and possibly also by sieving into the subsurface, where the final clay fractions were found to be higher than the initial clay fractions. These clay removal processes are interpreted to have facilitated the wave ripples to reach equilibrium lengths and heights that are similar to those in pure sand. Clay-carrying pore flow initiated by pressure gradients between the wave ripple troughs and crests might also have contributed to the accumulation of clay in the sediment below the wave ripples. The formation of the clay-enriched “armoring” layer in the substrate is likely to further reduce erosion rates and could influence the dispersion of nutrients and pollutants in coastal seas.
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Accepted/In Press date: 4 October 2018
e-pub ahead of print date: 4 October 2018
Published date: 5 November 2018
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Local EPrints ID: 491659
URI: http://eprints.soton.ac.uk/id/eprint/491659
ISSN: 2169-9003
PURE UUID: de39c243-3d4e-4668-8032-17261c2bb5fc
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Date deposited: 03 Jul 2024 09:43
Last modified: 11 Jul 2024 02:18
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Contributors
Author:
Xuxu Wu
Author:
Jaco H. Baas
Author:
Daniel R. Parsons
Author:
Joris T. Eggenhuisen
Author:
Laurent Amoudry
Author:
Matthieu J.B. Cartigny
Author:
Stuart McLelland
Author:
Dominique Mouazé
Author:
Gerben Ruessink
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