Network concepts to describe channel importance and change in multichannel systems: test results for the Jamuna River, Bangladesh

Marra, Wouter A.; Kleinhans, Maarten G.; Addink, E.A.

doi:10.1002/esp.3482

Cited by 74 publications

(93 citation statements)

References 39 publications

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“…New methodological procedures from graph theory need to be developed, so we propose here a brief description of the state of the art of previous studies in which the influence of a spatial network structure on material or immaterial fluxes has been thoroughly explored using graph theory. Although such studies have focused on geography (Cole and King, 1968;Gleyze, 2008), social networks (Freeman, 1979) or, more recently, ecology (Ludwig et al, 2002;Belisle, 2005), they have developed metrics and discussed concepts particularly relevant to geomorphology: the relationship between connectivity and the total amount of fluxes passing through the system, and the identification of local hotspots where any change may have an impact on the whole system (Marra et al, 2014;FoufoulaGeorgiou, 2014, 2015;Masselink et al, 2017). In such studies, one key requirement is to provide a hierarchy of the influence of nodes within the network.…”

Section: Graph Theory Applications To Structural Connectivitymentioning

confidence: 99%

Assessment of structural sediment connectivity within catchments: insights from graph theory

Cossart

Fressard

2017

Earth Surf. Dynam.

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Abstract.To describe the sedimentary signal delivered at catchment outlets, many authors now refer to the concept of connectivity. In this framework, the sedimentary signal is seen as an emergent organization of local links and interactions. The challenge is thus to open the black boxes that remain within a sediment cascade, which requires both accurate geomorphic investigations in the field (reconstruction of sequences of geomorphic evolution, description of sediment pathways) and the development of tools dedicated to sediment cascade modeling. More precisely, the development of tools devoted to the study of connectivity in geomorphology is still in progress, although graph theory offers promising perspectives (Heckmann and Schwanghart, 2013). In this paper, graph theory is applied to abstract the network structure of sediment cascades, keeping only the nodes (sediment sources, sediment stores, outlet) and links (linkage by a transportation agent), represented as vertices and edges. From the description of the assemblages of sedimentary flows, we provide three main indices to explore how small-scale processes may result in significant broad-scale geomorphic patterns. The main hypothesis guiding this work is that the network structure dictates how sediment inputs from various sources interact at tributary junctions and finally at the outlet of a cascading system. First, we use the flow index to assess the potential contribution of each node to the sediment delivery at the outlet. Second, we measure the influence of each node regarding how it is accessible from both sediment sources and the outlet (using the Shimbel index). Third, we propose a new connectivity index named "Network Structural Connectivity index" (NSC) revealing whether the potential contribution of a node is lower or higher than expected from its location within the network. These indices are first computed for a conceptual sediment cascade network and then applied to a catchment located in the southern French Alps. We demonstrate that this index may be used to simulate sediment transfer and help in identifying the hotspots of geomorphic change. In the present case, we try to predict how a sediment cascade may be impacted by an edge disruption or a reconnection.

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Section: Graph Theory Applications To Structural Connectivitymentioning

confidence: 99%

Assessment of structural sediment connectivity within catchments: insights from graph theory

Cossart

Fressard

2017

Earth Surf. Dynam.

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“…The channel networks of estuaries range significantly in complexity, from single thread straight channels to multi-channel systems that bifurcate and recombine. Analysing estuary channel connectivity can provide insight into estuarine dynamics, as has been done for tributary networks (Rodríguez-Iturbe and Rinaldo, 1997), deltas (Tejedor et al, 2015a,b), and braided rivers (Marra et al, 2014), but no formal analysis of estuary topologic and dynamic connectivity exists. In this study, we extract channel networks for estuaries around the world and apply spectral graph theory (Tejedor et al, 2015a,b) to characterise their topologic and dynamic connectivity.…”

Section: Resultsmentioning

confidence: 99%

Book of Abstracts NCK days 2017, 15 – 17 March, Royal Netherlands Naval College (KIM) – Den Helder

Groot

Vries²,

Arens³

et al. 2017

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“…Typically, a network is represented as a collection of nodes symbolizing junctions, inlets and outlets, and links symbolizing stream paths. Topology-based metrics have been developed to quantitatively analyze and compare surface water networks in three structurally distinct categories: (i) tributary rivers, where the flux converges from several upstream inlets to a single downstream outlet (Bertuzzo et al, 2007;Rodriguez-Iturbe & Rinaldo, 1997), (ii) braided rivers, where a single stream undergoes multiple branching/merging and eventually joins into a single stream (Foufoula-Georgiou & Sapozhnikov, 2001;Howard et al, 1970;Marra et al, 2014;Sapozhnikov & Foufoula-Georgiou, 1996, 1999, and (iii) deltas, where the flux is distributed from a single upstream inlet to several downstream outlets (Edmonds et al, 2011;Passalacqua, 2017;Smart & Moruzzi, 1971;Tejedor et al, 2015aTejedor et al, , 2015b. These studies have significantly advanced our understanding of rivers and streams as networks.…”

Section: Introductionmentioning

confidence: 99%

Controllability of Surface Water Networks

Riasi

Yeghiazarian

2017

Water Resources Research

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To sustainably manage water resources, we must understand how to control complex networked systems. In this paper, we study surface water networks from the perspective of structural controllability, a concept that integrates classical control theory with graph‐theoretic formalism. We present structural controllability theory and compute four metrics: full and target controllability, control centrality and control profile (FTCP) that collectively determine the structural boundaries of the system's control space. We use these metrics to answer the following questions: How does the structure of a surface water network affect its controllability? How to efficiently control a preselected subset of the network? Which nodes have the highest control power? What types of topological structures dominate controllability? Finally, we demonstrate the structural controllability theory in the analysis of a wide range of surface water networks, such as tributary, deltaic, and braided river systems.

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Network concepts to describe channel importance and change in multichannel systems: test results for the Jamuna River, Bangladesh

Cited by 74 publications

References 39 publications

Assessment of structural sediment connectivity within catchments: insights from graph theory

Assessment of structural sediment connectivity within catchments: insights from graph theory

Book of Abstracts NCK days 2017, 15 – 17 March, Royal Netherlands Naval College (KIM) – Den Helder

Controllability of Surface Water Networks

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