Sticky stuff: Redefining bedform prediction in modern and ancient environments

Schindler, Rob; Parsons, Daniel R.; Ye, Leiping; Hope, Julie A.; Baas, Jaco H.; Peakall, Jeff; Manning, Andrew J.; Aspden, Rebecca J.; Malarkey, Jonathan; Simmons, S.; Paterson, David M.; Lichtman, Ian D.; Davies, Alan M.; Thorne, Peter D.; Bass, Sarah

doi:10.1130/g36262.1

Cited by 93 publications

(70 citation statements)

References 20 publications

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“…Although a simple relationship between suspended clay concentration in flows and the percentage mud matrix in the resultant deposits does not exist, and bed clay fractions are not available for the present experiments, it is likely that bedforms are modified at a concentration appreciably lower than 15% mud in the matrix. This was confirmed by Baas et al (2013), who showed that current ripples are almost fully suppressed at a depth-averaged flow velocity of c. 0.4 m s −1 and bed clay fractions above 13%, by Schindler et al (2015) for dunes, where even small amounts of clay in the bed showed dramatic effects on bedform size, and by Whitehouse et al (2000), whose data compilation shows that 5-15% clay is sufficient to change from bed-flow interaction dominated by non-cohesive processes to bed-flow interaction dominated by cohesive processes. It is therefore evident that in future research, even the smallest primary mud fractions in sandstones that possess primary current stratification should be considered in the reconstruction of flow dynamics and depositional processes.…”

Section: Main Applicationsmentioning

confidence: 59%

“…Wang et al 1988;Liang et al 2007). The available data suggest that these mixedsediment bedforms are smaller than in pure sand, even at clay bed fractions below 3% (Basaniak & Verhoeven 2008;Baas et al 2013;Schindler et al 2015;Fig. 8).…”

Section: Bedforms and Primary Current Stratification In Cohesive Sedimentioning

confidence: 97%

“…This under-representation of cohesive sediments is all the more surprising as cohesive mud and clay are ubiquitous in most aquatic environments and sedimentary facies ( Fig. 1; Healy et al 2002;Schindler et al 2015). Of particular importance, cohesive clay causes flows to change their turbulence properties in a non-linear, yet predictable, manner (Baas & Best 2002), suspended sediment to change its dynamic behaviour (Winterwerp & van Kesteren 2004;Schieber et al 2007;Mehta 2013), and deposits to become more difficult to erode than pure sand (Mitchener & Torfs 1996).…”

Section: Rationale and Objectivesmentioning

confidence: 99%

“…This influence has been shown to be highly significant; adding even a small volume of clay particles to a flow or to a sand bed leads to the development of bedform types with shapes and dimensions that are vastly different from those in pure sand (e.g. Lowe 1988;Baas et al , 2011Baas et al , 2013Schindler et al 2015). To further demonstrate this influence, we also present a new comprehensive dataset on bedform dynamics below rapidly decelerated cohesive (mud-sand) sediment flows that extends the parameter space proposed by Baas et al (2011) that focused on current ripples, to incorporate two further flow conditions: upper-stage plane beds and washed-out ripples.…”

Section: Rationale and Objectivesmentioning

confidence: 99%

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Predicting bedforms and primary current stratification in cohesive mixtures of mud and sand

Baas

Best

Peakall

2015

JGS

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147

253

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Section: Main Applicationsmentioning

confidence: 59%

Section: Bedforms and Primary Current Stratification In Cohesive Sedimentioning

confidence: 97%

Section: Rationale and Objectivesmentioning

confidence: 99%

Section: Rationale and Objectivesmentioning

confidence: 99%

See 2 more Smart Citations

Predicting bedforms and primary current stratification in cohesive mixtures of mud and sand

Baas

Best

Peakall

2015

JGS

Self Cite

147

253

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“…Biofilms have been shown to play a fundamental role in sediment dynamics and the subsequent diagenesis of marginal marine sedimentary systems (Stal, 2003), affecting grain-size heterogeneity (Garwood et al, 2015), sediment stability (Vignaga et al, 2013), sediment transport, and bedform stability Schindler et al, 2015). Intertidal biofilms typically result from the secretion of extracellular polymeric substances (EPSs) (adhesive mucilage) by microphytobenthic (MPB) communities that are composed of algae (diatoms, euglenids, crysophyceans, dinoflagellates), cyanobacteria, and other photosynthetic bacteria (Jesus et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Biofilm origin of clay-coated sand grains

Wooldridge

Worden

Griffiths

et al. 2017

Geology

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The presence of clay-sized particles and clay minerals in modern sands and ancient sandstones has long presented an interesting problem, because primary depositional processes tend to lead to physical separation of fine-and coarse-grained materials. Numerous processes have been invoked to explain the common presence of clay minerals in sandstones, including infiltration, the codeposition of flocculated muds, and bioturbation-induced sediment mixing. How and why clay minerals form as grain coats at the site of deposition remains uncertain, despite clay-coated sand grains being of paramount importance for subsequent diagenetic sandstone properties. We have identified a new biofilm mechanism that explains clay material attachment to sand grain surfaces that leads to the production of detrital clay coats. This study focuses on a modern estuary using a combination of field work, scanning electron microscopy, petrography, biomarker analysis, and Raman spectroscopy to provide evidence of the pivotal role that biofilms play in the formation of clay-coated sand grains. This study shows that within modern marginal marine systems, clay coats primarily result from adhesive biofilms. This bio-mineral interaction potentially revolutionizes the understanding of clay-coated sand grains and offers a first step to enhanced reservoir quality prediction in ancient and deeply buried sandstones.

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The role of biophysical cohesion on subaqueous bed form size

Parsons

Schindler

Hope

et al. 2016

Geophysical Research Letters

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125

132

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Biologically active, fine‐grained sediment forms abundant sedimentary deposits on Earth's surface, and mixed mud‐sand dominates many coasts, deltas, and estuaries. Our predictions of sediment transport and bed roughness in these environments presently rely on empirically based bed form predictors that are based exclusively on biologically inactive cohesionless silt, sand, and gravel. This approach underpins many paleoenvironmental reconstructions of sedimentary successions, which rely on analysis of cross‐stratification and bounding surfaces produced by migrating bed forms. Here we present controlled laboratory experiments that identify and quantify the influence of physical and biological cohesion on equilibrium bed form morphology. The results show the profound influence of biological cohesion on bed form size and identify how cohesive bonding mechanisms in different sediment mixtures govern the relationships. The findings highlight that existing bed form predictors require reformulation for combined biophysical cohesive effects in order to improve morphodynamic model predictions and to enhance the interpretations of these environments in the geological record.

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Sticky stuff: Redefining bedform prediction in modern and ancient environments

Cited by 93 publications

References 20 publications

Predicting bedforms and primary current stratification in cohesive mixtures of mud and sand

Predicting bedforms and primary current stratification in cohesive mixtures of mud and sand

Biofilm origin of clay-coated sand grains

The role of biophysical cohesion on subaqueous bed form size

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