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Bedform migration in a mixed sand and cohesive clay intertidal environment and implications for bed material transport predictions. / Lichtman, Ian D.; Baas, Jacobus Hugo; Amoudry, Laurent O. et al.
In: Geomorphology, Vol. 315, 15.08.2018, p. 17-32.

Research output: Contribution to journalArticlepeer-review

HarvardHarvard

Lichtman, ID, Baas, JH, Amoudry, LO, Thorne, PD, Malarkey, J, Hope, JA, Peakall, J, Paterson, DM, Bass, SJ, Cooke, RD, Manning, AJ, Davies, AG, Parsons, DR & Ye, L 2018, 'Bedform migration in a mixed sand and cohesive clay intertidal environment and implications for bed material transport predictions', Geomorphology, vol. 315, pp. 17-32. https://doi.org/10.1016/j.geomorph.2018.04.016

APA

Lichtman, I. D., Baas, J. H., Amoudry, L. O., Thorne, P. D., Malarkey, J., Hope, J. A., Peakall, J., Paterson, D. M., Bass, S. J., Cooke, R. D., Manning, A. J., Davies, A. G., Parsons, D. R., & Ye, L. (2018). Bedform migration in a mixed sand and cohesive clay intertidal environment and implications for bed material transport predictions. Geomorphology, 315, 17-32. https://doi.org/10.1016/j.geomorph.2018.04.016

CBE

Lichtman ID, Baas JH, Amoudry LO, Thorne PD, Malarkey J, Hope JA, Peakall J, Paterson DM, Bass SJ, Cooke RD, et al. 2018. Bedform migration in a mixed sand and cohesive clay intertidal environment and implications for bed material transport predictions. Geomorphology. 315:17-32. https://doi.org/10.1016/j.geomorph.2018.04.016

MLA

VancouverVancouver

Lichtman ID, Baas JH, Amoudry LO, Thorne PD, Malarkey J, Hope JA et al. Bedform migration in a mixed sand and cohesive clay intertidal environment and implications for bed material transport predictions. Geomorphology. 2018 Aug 15;315:17-32. Epub 2018 May 1. doi: 10.1016/j.geomorph.2018.04.016

Author

RIS

TY - JOUR

T1 - Bedform migration in a mixed sand and cohesive clay intertidal environment and implications for bed material transport predictions

AU - Lichtman, Ian D.

AU - Baas, Jacobus Hugo

AU - Amoudry, Laurent O.

AU - Thorne, Peter D.

AU - Malarkey, Jonathan

AU - Hope, Julie A.

AU - Peakall, Jeffrey

AU - Paterson, David M.

AU - Bass, Sarah J.

AU - Cooke, Richard D.

AU - Manning, Andrew J.

AU - Davies, Alan G.

AU - Parsons, Daniel R.

AU - Ye, Leiping

PY - 2018/8/15

Y1 - 2018/8/15

N2 - Many coastal and estuarine environments are dominated by mixtures of non-cohesive sand and cohesive mud. The migration rate of bedforms, such as ripples and dunes, in these environments is important in determining bed material transport rates to inform and assess numerical models of sediment transport and geomorphology. However, these models tend to ignore parameters describing the physical and biological cohesion (resulting from clay and extracellular polymeric substances, EPS) in natural mixed sediment, largely because of a scarcity of relevant laboratory and field data. To address this gap in knowledge, data were collected on intertidal flats over a spring-neap cycle to determine the bed material transport rates of bedforms in biologically-active mixed sand-mud. Bed cohesive composition changed from below 2 volume % up to 5.4 volume % cohesive clay, as the tide progressed from spring towards neap. The amount of EPS in the bed sediment was found to vary linearly with the clay content. Using multiple linear regression, the transport rate was found to depend on the Shields stress parameter and the bed cohesive clay content. The transport rates decreased with increasing cohesive clay and EPS content, when these contents were below 2.8 vol% and 0.05 weight%, respectively. Above these limits, bedform migration and bed material transport was not detectable by the instruments in the study area. These limits are consistent with recently conducted sand-clay and sand-EPS laboratory experiments on bedform development. This work has important implications for the circumstances under which existing sand-only bedform migration transport formulae may be applied in a mixed sand-clay environment, particularly as 2.8 vol% cohesive clay is well within the commonly adopted definition of ‘clean sand’.

AB - Many coastal and estuarine environments are dominated by mixtures of non-cohesive sand and cohesive mud. The migration rate of bedforms, such as ripples and dunes, in these environments is important in determining bed material transport rates to inform and assess numerical models of sediment transport and geomorphology. However, these models tend to ignore parameters describing the physical and biological cohesion (resulting from clay and extracellular polymeric substances, EPS) in natural mixed sediment, largely because of a scarcity of relevant laboratory and field data. To address this gap in knowledge, data were collected on intertidal flats over a spring-neap cycle to determine the bed material transport rates of bedforms in biologically-active mixed sand-mud. Bed cohesive composition changed from below 2 volume % up to 5.4 volume % cohesive clay, as the tide progressed from spring towards neap. The amount of EPS in the bed sediment was found to vary linearly with the clay content. Using multiple linear regression, the transport rate was found to depend on the Shields stress parameter and the bed cohesive clay content. The transport rates decreased with increasing cohesive clay and EPS content, when these contents were below 2.8 vol% and 0.05 weight%, respectively. Above these limits, bedform migration and bed material transport was not detectable by the instruments in the study area. These limits are consistent with recently conducted sand-clay and sand-EPS laboratory experiments on bedform development. This work has important implications for the circumstances under which existing sand-only bedform migration transport formulae may be applied in a mixed sand-clay environment, particularly as 2.8 vol% cohesive clay is well within the commonly adopted definition of ‘clean sand’.

KW - Bedform migration

KW - Sediment tranport

KW - Mixed cohesive clay-sand

KW - Physical and biological cohesion

KW - Current and wave forcing

KW - Tidal flats

U2 - 10.1016/j.geomorph.2018.04.016

DO - 10.1016/j.geomorph.2018.04.016

M3 - Article

VL - 315

SP - 17

EP - 32

JO - Geomorphology

JF - Geomorphology

SN - 0169-555X

ER -