A process based model of cohesive sediment resuspension under bioturbators' influence

Cozzoli, Francesco; Gjoni, Vojsava; Pasqua, Michela Del; Hu, Zhan; Ysebaert, Tom; Herman, Peter M. J.; Bouma, Tjeerd J.

doi:10.1016/j.scitotenv.2019.03.085

Cited by 31 publications

(84 citation statements)

References 139 publications

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“…(N m −2 ) of the sediment (Cozzoli et al, 2019;Wrede et al, 2018). As a result, the sediment flux of cohesive sediment computed by the Partheniades-Krone formulation (eq.…”

Section: Relations Between Species Abundance and Bioturbation Effectsmentioning

confidence: 99%

Benthic species as mud patrol ‐ modelled effects of bioturbators and biofilms on large‐scale estuarine mud and morphology

Brückner

Schwarz

Coco

et al. 2021

Earth Surf Processes Landf

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Sediment-stabilizing and -destabilizing organisms, i.e. microphytobenthos (biofilms) and macrozoobenthos (bioturbators), affect the erodibility of muddy sediments, potentially altering large-scale estuarine morphology. Using a novel eco-morphodynamic model of an idealized estuary, we investigate eco-engineering effects of microphytobenthos and two macrozoobenthic bioturbators. Local mud erodibility is based on species pattern predicted through hydrodynamics, soil mud content, competition and grazing. Mud resuspension and export is enhanced under bioturbation and prevented under biostabilization through respective exposure and protection of the supra-and intertidal. Bioturbation decreases mud thickness and bed elevations, which increases net mud fluxes. Microphytobenthos reduces erosion, leading to a local mud increase of intertidal sediments.

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“…(N m −2 ) of the sediment (Cozzoli et al, 2019;Wrede et al, 2018). As a result, the sediment flux of cohesive sediment computed by the Partheniades-Krone formulation (eq.…”

Section: Relations Between Species Abundance and Bioturbation Effectsmentioning

confidence: 99%

Benthic species as mud patrol ‐ modelled effects of bioturbators and biofilms on large‐scale estuarine mud and morphology

Brückner

Schwarz

Coco

et al. 2021

Earth Surf Processes Landf

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“…As erosion is fundamentally linked to lateral hydrodynamic processes, it is rarely included in one-dimensional (vertical) sediment reactive-transport models. Additionally, the same animal can have both stabilizing and destabilizing effects on the sediment, making it difficult to include such effects in models (Le Hir et al, 2007;Cozzoli et al, 2019). However, there are several examples of models coupling resuspension of sediment and benthic microalgae to fauna, including effects of infaunal bivalves (Willows et al, 1998;Wood and Widdows, 2002;Orvain et al, 2012;Rakotomalala et al, 2015) and epifaunal snail tracks (Orvain et al, 2003(Orvain et al, , 2012.…”

Section: Bioresuspensionmentioning

confidence: 99%

“…van Prooijen et al ( 2011) developed a more process-based model for cohesive (muddy) sediment resuspension by deposit-feeding activities of L. balthica based on the individual rate, area and maximum depth of feeding and density of individuals. A recent study by Cozzoli et al (2019) proposed another process-based model for cohesive sediment resuspension mediated by a variety of bioturbators and demonstrated metabolic rate as a general indicator of impacts of biological activities on sediment resuspension. They concluded that the overall metabolic rate of the bioturbators was well correlated with changes in hydrodynamic energy gradients of suspended cohesive sediments, and a better predictor than size, density or biomass of the fauna.…”

Section: Bioresuspensionmentioning

confidence: 99%

“…Traitbased descriptions of pelagic groups are emerging in ecosystem models (Follows et al, 2007;Andersen et al, 2015). In general, metabolism seems to be a better predictor of biogenic mixing and resuspension than biomass, advocating the modeling approaches of Blackford (1997) and Cozzoli et al (2019). As metabolic rate is increasingly recognized as master parameter for the 'pace of life' (Gillooly et al, 2001;Brown et al, 2004b;McClain et al, 2012), this provides a promising avenue for parameterization of the 'pace of bioturbation'.…”

Section: Coupling Benthic Fauna and Benthic Biogeochemistrymentioning

confidence: 99%

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Understanding Environmental Changes in Temperate Coastal Seas: Linking Models of Benthic Fauna to Carbon and Nutrient Fluxes

et al. 2020

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Coastal seas are highly productive systems, providing an array of ecosystem services to humankind, such as processing of nutrient effluents from land and climate regulation. However, coastal ecosystems are threatened by human-induced pressures such as climate change and eutrophication. In the coastal zone, the fluxes and transformations of nutrients and carbon sustaining coastal ecosystem functions and services are strongly regulated by benthic biological and chemical processes. Thus, to understand and quantify how coastal ecosystems respond to environmental change, mechanistic modeling of benthic biogeochemical processes is required. Here, we discuss the present model capabilities to quantitatively describe how benthic fauna drives nutrient and carbon processing in the coastal zone. There are a multitude of modeling approaches of different complexity, but a thorough mechanistic description of benthic-pelagic processes is still hampered by a fundamental lack of scientific understanding of the diverse interactions between the physical, chemical and biological processes that drive biogeochemical fluxes in the coastal zone. Especially shallow systems with long water residence times are sensitive to the activities of benthic organisms. Hence, including and improving the description of benthic biomass and metabolism in sediment diagenetic as well as ecosystem models for such systems is essential to increase our understanding of their response to environmental changes and the role of coastal sediments in nutrient and carbon cycling. Major challenges and research priorities are (1) to couple the dynamics of zoobenthic biomass and metabolism to sediment reactive-transport in models, (2) to test and validate model formulations against real-world data to better incorporate the context-dependency of processes in heterogeneous coastal areas in models and (3) to capture the role of stochastic events.

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“…In addition, suspended sediment concentration is not measured in the current study due to instrument shortage, but it is a relevant input variable influencing bed dynamics (Dai et al, 2016(Dai et al, , 2018. Thus, a general machine learning predictor for intertidal morphodynamics would benefit from (1) data sets of large spatiotemporal coverage to eliminate class imbalance, (2) comprehensive data sets including all relevant variables including also biological processes (e.g., Cozzoli et al, 2019), and (3) adoption of more advanced machine learning techniques such as Recurrent Neural networks and Long Short-Term Memory (LSTM) networks (Kratzert et al, 2018;Pape et al, 2007Pape et al, , 2010. These suggestions may provide a way forward for machine learning applications in analyzing intertidal bed level dynamics data.…”

Section: 1029/2020wr027257mentioning

confidence: 99%

A Novel Instrument for Bed Dynamics Observation Supports Machine Learning Applications in Mangrove Biogeomorphic Processes

Zhou

Wang

et al. 2020

Water Resources Research

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Short‐term bed level changes play a critical role in long‐term coastal wetland dynamics. High‐frequency observation techniques are crucial for better understanding of intertidal biogeomorphic evolution. Here, we introduce an innovative instrument for bed level dynamics observation, that is, LSED‐sensor (Laser based Surface Elevation Dynamics sensor). The LSED‐sensors inherit the merits of the previously introduced optical SED sensors as it enables continuous high‐frequency monitoring with relatively low cost of labor and acquisition. As an iteration of the optical SED‐sensors, the LSED‐sensors avoid touching the measuring object (i.e., bed surface), and they do not rely on daylight by adapting laser‐ranging technique. Furthermore, the new LSED‐sensors are equipped with a real‐time data transmission function, enabling automatic observation networks covering multiple (remote) sites. During a 22‐day field survey in a mangrove wetland, good agreement (R2 = 0.7) has been obtained between the automatic LSED‐sensor measurement and an accurate ground‐truth measurement method, that us, Sedimentation Erosion Bars. The obtained LSED‐sensor data were subsequently used to develop machine learning predictors, which revealed the effect of vegetation is a main driver in the accumulative and daily bed level changes. We expect that the LSED‐sensors can further support machine learning applications to extract new knowledge on coastal biogeomorphic processes.

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A process based model of cohesive sediment resuspension under bioturbators' influence

Cited by 31 publications

References 139 publications

Benthic species as mud patrol ‐ modelled effects of bioturbators and biofilms on large‐scale estuarine mud and morphology

Benthic species as mud patrol ‐ modelled effects of bioturbators and biofilms on large‐scale estuarine mud and morphology

Understanding Environmental Changes in Temperate Coastal Seas: Linking Models of Benthic Fauna to Carbon and Nutrient Fluxes

A Novel Instrument for Bed Dynamics Observation Supports Machine Learning Applications in Mangrove Biogeomorphic Processes

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