2015
DOI: 10.1002/2014wr016577
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Delta channel networks: 1. A graph‐theoretic approach for studying connectivity and steady state transport on deltaic surfaces

Abstract: River deltas are intricate landscapes with complex channel networks that self-organize to deliver water, sediment, and nutrients from the apex to the delta top and eventually to the coastal zone. The natural balance of material and energy fluxes, which maintains a stable hydrologic, geomorphologic, and ecological state of a river delta, is often disrupted by external perturbations causing topological and dynamical changes in the delta structure and function. A formal quantitative framework for studying delta c… Show more

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Cited by 98 publications
(148 citation statements)
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“…The graph-theoretic framework presented in the companion paper [Tejedor et al, 2015] allowed us to identify upstream (contributing) and downstream (nourishment) subnetworks for any given delta vertex (node), including the apex-to-shoreline subnetworks, referred to also as outlet subnetworks. It also allowed us to compute the steady-state flux propagation in the delta channels and to construct vulnerability maps that quantify how a change in any upstream delta link would affect the shoreline Having established the mathematical machinery based on spectral graph theory that efficiently allows to perform the above computations, we now ask the question as to what quantitative metrics one can build that summarize the topologic complexity of delta networks (reflecting their channel connectivity), as well as their dynamic complexity (reflecting how flux dynamic exchanges happen within the network).…”
Section: Introductionmentioning
confidence: 99%
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“…The graph-theoretic framework presented in the companion paper [Tejedor et al, 2015] allowed us to identify upstream (contributing) and downstream (nourishment) subnetworks for any given delta vertex (node), including the apex-to-shoreline subnetworks, referred to also as outlet subnetworks. It also allowed us to compute the steady-state flux propagation in the delta channels and to construct vulnerability maps that quantify how a change in any upstream delta link would affect the shoreline Having established the mathematical machinery based on spectral graph theory that efficiently allows to perform the above computations, we now ask the question as to what quantitative metrics one can build that summarize the topologic complexity of delta networks (reflecting their channel connectivity), as well as their dynamic complexity (reflecting how flux dynamic exchanges happen within the network).…”
Section: Introductionmentioning
confidence: 99%
“…These subnetworks can be topologically very simple (a straight path of channels) or very complex (multiple splitting and merging paths); see Figures 1a and 1b for an example for Wax Lake and Niger deltas as presented in Tejedor et al, [2015] which marks such outlet subnetworks. The topologic structure of each of the subnetworks is embedded within the whole delta channel network topology to result in various degrees of ''dependence'' among the subnetworks.…”
Section: Introductionmentioning
confidence: 99%
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“…In previous studies, Mossy and Wax Lake deltas have been compared to inverted tributary networks based purely on their visual resemblance (Tejedor et al, 2015a). The analysis of control profiles provides a quantitative tool to substantiate these comparisons.…”
Section: Control Profilementioning
confidence: 99%
“…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%