Sediment Connectivity: A Framework for Analyzing Coastal Sediment Transport Pathways

Pearson, Stuart; Prooijen, Bram C. van; Elias, Edwin; Vitousek, Sean; Wang, Zheng Bing

doi:10.1002/essoar.10502451.1

Cited by 8 publications

(8 citation statements)

References 102 publications

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“…Quantifying these sediment fluxes is critical for sustainable coastal management (Hanley et al., 2014; Hendriks et al., 2020; Mulder et al., 2011). Measurements of these fluxes can be used to derive sediment budgets (Wang et al., 2018), better understand the physical processes underlying sediment transport (White, 1998), and quantify sediment pathways and connectivity (Pearson et al., 2020). They also allow us to calibrate and improve numerical sediment transport models (Amoudry & Souza, 2011; Roelvink & Reniers, 2012).…”

Section: Introductionmentioning

confidence: 99%

Characterizing the Composition of Sand and Mud Suspensions in Coastal and Estuarine Environments Using Combined Optical and Acoustic Measurements

et al. 2021

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Quantifying and characterizing suspended sediment is essential to successful monitoring and management of estuaries and coastal environments. To quantify suspended sediment, optical and acoustic backscatter instruments are often used. Optical backscatter systems are more sensitive to mud particles (< 63µm) and flocs, whereas acoustic Accepted ArticleThis article is protected by copyright. All rights reserved.Confidential manuscript submitted to JGR-Oceans allows us to estimate whether there are more sand or mud particles floating through the water. The relationship between "seeing" and "hearing" can be described in a single number, the sediment composition index (SCI). We successfully tested this approach in laboratory experiments and then applied it to a site on the coast of the Netherlands. This approach gives us a new way to understand environments that are both sandy and muddy.

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Section: Introductionmentioning

confidence: 99%

Characterizing the Composition of Sand and Mud Suspensions in Coastal and Estuarine Environments Using Combined Optical and Acoustic Measurements

et al. 2021

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“…There are various approaches to assessing structural connectivity in hydrology and geomorphology. If we take a river network, the structural connectivity of the network can be defined based on the pathways connecting all links through which water can potentially flow, resulting in a graph structure most often in the form of a tree [56,57], with the exception of braided streams [58], deltas [59,60] or, for a more broad example, coastal sediment pathways [61]. Thus, the structural connectivity of river networks can be quantified using, for example, the pairwise connectivity of its underlying tree structure -an approach that has been used both for natural and synthetic river networks [62].…”

Section: Application To Geomorphologymentioning

confidence: 99%

A stylised view on structural and functional connectivity in dynamical processes in networks

Voutsa¹,

Battaglia²,

Bracken³

et al. 2021

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The relationship of network structure and dynamics is one of most extensively investigated problems in the theory of complex systems of the last years. Understanding this relationship is of relevance to a range of disciplines -from Neuroscience to Geomorphology. A major strategy of investigating this relationship is the quantitative comparison of a representation of network architecture (structural connectivity) with a (network) representation of the dynamics (functional connectivity). Analysing such SC/FC relationships has over the past years contributed substantially to our understanding of the functional role of network properties, such as modularity, hierarchical organization, hubs and cycles.Here, we show that one can distinguish two classes of functional connectivity -one based on simultaneous activity (co-activity) of nodes the other based on sequential activity of nodes. We delineate these two classes in different categories of dynamical processesexcitations, regular and chaotic oscillators -and provide examples for SC/FC correlations of both classes in each of these models. We expand the theoretical view of the SC/FC relationships, with conceptual instances of the SC and the two classes of FC for various application scenarios in Geomorphology, Freshwater Ecology, Systems Biology, Neuroscience and Social-Ecological Systems.Seeing the organization of a dynamical processes in a network either as governed by coactivity or by sequential activity allows us to bring some order in the myriad of observations relating structure and function of complex networks.

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“…In this case, the water and sediments in the sea area become the main carriers of nutrient transport. For example, based on the concept of connectivity, Pearson applied the method of studying sediment path migration to the study of coastal sediment dynamics and proposed a new view of coastal system connectivity [57]. In areas with low flow rates, due to the lack of the physical force of ocean currents, organic matter is not evenly distributed in space, and most of the time, it relies on organisms as the medium to complete the process of nutrient transport [58,59].…”

Section: The Main Driving Factors Of Habitat Connectivitymentioning

confidence: 99%

Research Progress on Habitat Connectivity in Temperate Waters

S¹,

Wang²,

Z³

et al. 2021

Preprint

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Ecological connectivity, as a research method related to spatial ecology and conservation biology, has attracted increasing attention from researchers at home and abroad in recent years. Habitat connectivity, as a key link in ecological connectivity, is of great significance to promote offshore ecological restoration and protection. However, there has been less systematic research about habitat connectivity, which lacks corresponding theories and practices. Therefore, this paper discusses habitat connectivity from three aspects: (1) the concept of habitat connectivity is introduced and clarified, (2) the application of connectivity in artificial habitat and adjacent waters and its relationship with biodiversity conservation are reviewed and illustrated with examples, and (3) the future development trends of this research direction are summarized and prospected, in order to provide a scientific basis and useful reference for the related work of offshore restoration projects in China. Generally, this paper argues that an increase in human behavior irreversibly destroys the connectivity of marine habitats and threatens the temporal scales of biodiversity and ecosystem services. Therefore, the theoretical research results and practical experience of ecological connectivity should be fully applied to marine ecosystems, and the restoration of degraded ecosystems should be encouraged and supported in ways that promote natural recovery.

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Sediment Connectivity: A Framework for Analyzing Coastal Sediment Transport Pathways

Cited by 8 publications

References 102 publications

Characterizing the Composition of Sand and Mud Suspensions in Coastal and Estuarine Environments Using Combined Optical and Acoustic Measurements

Characterizing the Composition of Sand and Mud Suspensions in Coastal and Estuarine Environments Using Combined Optical and Acoustic Measurements

A stylised view on structural and functional connectivity in dynamical processes in networks

Research Progress on Habitat Connectivity in Temperate Waters

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