Integrating field and laboratory approaches for ripple development in mixed sand–clay–EPS

Baas, Jaco H.; Baker, Megan L.; Malarkey, Jonathan; Bass, Sarah; Manning, Andrew J.; Hope, Julie A.; Peakall, Jeff; Lichtman, Ian D.; Ye, Leiping; Davies, Alan M.; Parsons, D.; Paterson, David M.; Thorne, Peter D.

doi:10.1111/sed.12611

Cited by 26 publications

(26 citation statements)

References 45 publications

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“…The cohesive nature of EPS reduces both bedload transport and bedform development such as ripple formation and size (Baas et al, ; Lichtman et al, ; Parsons et al, ), which can significantly affect large‐scale geomorphological features of sediment. Biostabilization, by altering sedimentary properties and processes, can lead to the formation of large ridge and runnel systems (Weerman et al, ) and state changes in sedimentary habitats (Van De Koppel et al, ).…”

Section: Individual Ecosystem Functions and Servicesmentioning

confidence: 99%

The role of microphytobenthos in soft‐sediment ecological networks and their contribution to the delivery of multiple ecosystem services

2019

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1. Sediment dwelling, microscopic primary producers, that occupy sediments in the photic zone, are commonly referred to as microphytobenthos (MPB). The MPB are essential components of soft-sediment systems, but are often overlooked when assessing coastal ecosystem functionality and service delivery. 2. The MPB are involved in several complex interactions and feedback that underpin the delivery of vital ecosystem services. MPB profoundly influence the flow and cycling of carbon and nutrients, such as nitrogen, directly and indirectly underpinning highly productive shallow water marine food webs. The MPB can also stabilize sediments through the formation of biofilms, and significantly improve water quality by mediating the benthic-pelagic coupling of nutrients, sediment and pollutants. 3. The functional role of the MPB is compromised by increasing anthropogenic pressures such as nutrient enrichment, sedimentation, herbicides and emerging contaminants such as microplastic pollution. However, MPB are extremely good at buffering the effects of these land-sourced stressors at the interface between land and sea. 4. Synthesis. Society often appreciates the final provisioning of goods and services from our coastal marine environments. However, provisioning services are only possible due to the multitude of supporting and regulating services that underpin them. Microphytobenthos (MPB) are central to benthic ecological networks, and contribute to ecosystem service delivery through various pathways. Understanding the critical role of MPB in complex networks is therefore essential to appreciate their importance in ecosystem function and service delivery into the future. K E Y W O R D S benthic microalgae, ecosystem services, estuarine systems, microphytobenthos, service delivery, soft-sediment ecology 816 | Journal of Ecology HOPE Et al.

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Section: Individual Ecosystem Functions and Servicesmentioning

confidence: 99%

The role of microphytobenthos in soft‐sediment ecological networks and their contribution to the delivery of multiple ecosystem services

2019

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“…Additionally, clay winnowing, a hydrodynamic sorting process which suspends the finer clay but leaves the coarser sand in the bed (e.g., Cizeau et al, 1999), played a significant role in the transformation of ripples in mixed sand-clay to an increasingly sandy composition in the experiments of Baas et al (2013) and Wu et al (2018). Importantly, Baas et al (2019) has recently highlighted the role of bed cohesion in decreasing current ripple dimensions in the Dee Estuary, U.K., demonstrating that previous laboratory findings are applicable in natural environments. There has, however, been very little research on the dynamics of ripples in mixed sand-clay beds under combined wave-current flows, which are crucial to the sediment dynamics in the majority of estuaries and coastal seas.…”

Section: Introductionmentioning

confidence: 99%

Discontinuity in Equilibrium Wave-Current Ripple Size and Shape Caused by a Winnowing Threshold in Cohesive Sand-Clay Beds

Wu¹,

Fernández²,

Baas³

et al. 2022

Preprint

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Sediments composed of mixed cohesive clay and non-cohesive sand are widespread in a range of aquatic environments. The dynamics of ripples in mixed sand–clay substrates have been studied under pure current and pure wave conditions. However, the effect of cohesive clay on ripple development under combined currents and waves has not been examined, even though combined flows are common in estuaries, particularly during storms. Based on a series of large flume experiments on ripple development under combined flows, we identified a robust inverse relationship between initial bed clay content, C0, and ripple growth rate. The experimental results also revealed two distinct types of equilibrium combined-flow ripples on mixed sand–clay beds: (a) large asymmetrical ripples with dimensions and plan geometries comparable to clean-sand counterparts for C0 ≤ 10.6%; and (b) small, flat ripples for C0 > 11%. The increase in bed cohesion contributed to this discontinuity, expressed most clearly in a sharp reduction in equilibrium ripple height, and thus a significant reduction in bed roughness, which implies that the performance of existing ripple predictors can be improved by the incorporation of this physical cohesive effect. These improvements are particularly important for sediment transport and morphodynamic models in muddy estuarine environments. For C0 ≤ 10.6%, strong clay winnowing efficiency under combined flows resulted in the formation of equilibrium clean-sand ripples and clay loss at depths far below the ripple base. In natural environments, this ‘deep cleaning’ of bed clay may cause a concurrent sudden release of a large amount of pollutants during storms, and lead to a sudden reduction in post-storm resistance to erosion of mixed sand–clay substrates.

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“…7B). Laboratory (Malarkey et al 2015; Parsons et al 2016) and field investigations (Lichtman et al 2018; Baas et al 2019) have recently illustrated the influence of low EPS contents distributed deeper into the sediment bed. In these investigations, microbially produced EPS hampered sediment transport, bedform development, and bedform migration without the presence of a visible biofilm on the surface (see also Chen et al 2017).…”

Section: Discussionmentioning

confidence: 99%

Interactions between sediment microbial ecology and physical dynamics drive heterogeneity in contextually similar depositional systems

Hope

Malarkey

Baas

et al. 2020

Limnology & Oceanography

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This study focuses on the interactions between sediment stability and biological and physical variables that influence the erodibility across different habitats. Sampling at short-term temporal scales illustrated the persistence of the microphytobenthos (MPB) biomass even during periods of frequent, high physical disturbance. The role of MPB in biological stabilization along the changing sedimentary habitat was also assessed. Key biological and physical properties, such as the MPB biomass, composition, and extracellular polymeric substances, were used to predict the sediment stability (erosion threshold) of muddy and sandy habitats within close proximity to one another over multiple days, and within emersion periods. The effects of dewatering, MPB growth, and productivity were examined as well as the resilience and recovery of the MPB community after disturbance from tidal currents and waves. Canonical analysis of principal components (CAP) ordinations were used to visualize and assess the trends observed in biophysical properties between the sites, and marginal and sequential distance-based linear models were used to identify the key properties influencing erodibility. While the particle size of the bed was important for differences between sites in the CAP analysis, it contributed less to the variability in sediment erodibility than key biological parameters. Among the biological predictors, MPB diversity explained very little variation in marginal tests but was a significant predictor in sequential tests when MPB biomass was also considered. MPB diversity and biomass were both key predictors of sediment stability, contributing 9% and 10%, respectively, to the final model compared to 2% explained by grain size.

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Integrating field and laboratory approaches for ripple development in mixed sand–clay–EPS

Cited by 26 publications

References 45 publications

The role of microphytobenthos in soft‐sediment ecological networks and their contribution to the delivery of multiple ecosystem services

The role of microphytobenthos in soft‐sediment ecological networks and their contribution to the delivery of multiple ecosystem services

Discontinuity in Equilibrium Wave-Current Ripple Size and Shape Caused by a Winnowing Threshold in Cohesive Sand-Clay Beds

Interactions between sediment microbial ecology and physical dynamics drive heterogeneity in contextually similar depositional systems

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