Abstract
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 vol% up to 5.4 vol% 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 wt%, 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”.
Highlights
A linear fit was used to describe the changes in bed cohesive clay fraction at Sites 1 and 2, which were dominated by wave action and spring tide, respectively (Fig. 4)
The reduction in forcing allows clay to settle out of the water column and be worked into the bed by various physical and biological processes. This general trend can be seen in the inverse relationship between the duration of tidal inundation and clay content shown in Fig. 10a, where the duration of tidal inundation is a proxy for flow strength
The results demonstrate that, once the effect of waves had been accounted for, the bedform migration rate and the bed material transport rate of mixed sediments in the field were significantly different from that of sand-only bedforms even when clay and extracellular polymeric substances (EPS) fractions in the bed were below 2.8 vol% and 0.05 wt%, respectively
Summary
⁎ Corresponding author at: National Oceanography Centre, Joseph Proudman Building, 6 Brownlow Street, Liverpool L3 5DA, United Kingdom. Many of these environments are dominated by mixtures of sand and mud (Flemming, 2002; Waeles et al, 2008). While reasonably accurate sediment transport predictors are available for pure sands, a knowledge gap exists for the behavior of mixed sediments composed of natural cohesive mud (clay and silt) and non-cohesive sand (Souza et al, 2010; Amoudry and Souza, 2011; Manning et al, 2011; Spearman et al, 2011; Aldridge et al, 2015). Lichtman et al / Geomorphology 315 (2018) 17–32 results from the production of extracellular polymeric substances (EPS) by microphytobenthos and larger benthic organisms (Paterson and Black, 1999; van de Koppel et al, 2001; Black et al, 2002; Winterwerp and van Kesteren, 2004; Wotton, 2004; Tolhurst et al, 2009)
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