Surface water connectivity dynamics of a large scale extreme flood

Trigg, Mark A.; Michaelides, Katerina; Neal, Jeffrey; Bates, Paul

doi:10.1016/j.jhydrol.2013.09.035

Cited by 74 publications

(51 citation statements)

References 42 publications

(59 reference statements)

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“…We examined the flow snapshots for this period and found that overland flow is gradually drained out of the topography, but the maximum lag distance of the connected flow pathways remains at approximately half of the maximum lag distance of the watershed, that is, connected flow can still extend across half of the watershed scale (regardless of flows in stream channel or floodplain). This finding is consistent with other studies that have described how, during recession limbs, flow slowly spills out of low laying areas (depressions) but remains connected within the scale of these areas (e.g., Trigg, Michaelides, Neal, & Bates, 2013) 3.3 | Role of depressions on overland flow connectivity changes across spatial scales-direction…”

Section: Role Of Depressions On Overland Flow Connectivity Changes supporting

confidence: 91%

The effects of topographic depressions on multiscale overland flow connectivity: A high‐resolution spatiotemporal pattern analysis approach based on connectivity statistics

Harbor

2019

Hydrological Processes

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In watershed modelling, the traditional practice of arbitrarily filling topographic depressions in digital elevation models has raised concerns. Advanced high‐resolution remote sensing techniques, including airborne scanning laser altimetry, can identify naturally occurring depressions that impact overland flow. In this study, we used an ensemble physical and statistical modelling approach, including a 2D hydraulic model and two‐point connectivity statistics, to quantify the effects of depressions on high‐resolution overland flow patterns across spatial scales and their temporal variations in single storm events. Computations for both models were implemented using graphic processing unit‐accelerated computing. The changes in connectivity statistics for overland flow patterns between airborne scanning laser altimetry‐derived digital elevation models with (original) and without (filled) depressions were used to represent the shifts of overland flow response to depressions. The results show that depressions can either decrease or increase (to a lesser degree and shorter duration) the probability that any two points (grid locations) are hydraulically connected by overland flow pathways. We used macro‐connectivity states (Φ) as a watershed‐specific indicator to describe the spatiotemporal thresholds of connectivity variability caused by depressions. Four states of Φ are identified in a studied watershed, and each state represents different magnitudes of connectivity and connectivity changes (caused by depressions). The magnitude of connectivity variability corresponds to the states of Φ, which depend on the topological relationship between depressions, the rising/recession limb, and the total rainfall amount in a storm event. In addition, spatial distributions of connectivity variability correlate with the density of depression locations and their physical structures, which cause changes in streamflow discharge magnitude. Therefore, this study suggests that depressions are “nontrivial” in watershed modelling, and their impacts on overland flow should not be neglected. Connectivity statistics at different spatial scales and time points within a watershed provide new insights for characterizing the distributed and accumulated effects of depressions on overland flow.

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Section: Role Of Depressions On Overland Flow Connectivity Changes supporting

confidence: 91%

The effects of topographic depressions on multiscale overland flow connectivity: A high‐resolution spatiotemporal pattern analysis approach based on connectivity statistics

Harbor

2019

Hydrological Processes

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“…There has been a recent tendency toward merging the concept of hyporheic flow, which occurs at all times [ Buffington and Tonina , ], with classical concepts of bank storage [ Pinder and Sauer , ; Sophocleous , ] and overbank flow [ Mertes , ; Tockner et al ., ; Trigg et al ., ] that are caused by fluctuating water levels during spates and floods. The effect that river flooding has on hyporheic flow through bar and riffle features has been widely investigated [ Gariglio et al ., ; Nowinski et al ., ; Shope et al ., ; Francis et al ., ; Käser et al ., ; Wondzell and Swanson , ; Harvey et al ., ].…”

Section: Mechanisms Of Exchange At the Surface‐subsurface Interfacementioning

confidence: 99%

Hyporheic flow and transport processes: Mechanisms, models, and biogeochemical implications

et al. 2014

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Fifty years of hyporheic zone research have shown the important role played by the hyporheic zone as an interface between groundwater and surface waters. However, it is only in the last two decades that what began as an empirical science has become a mechanistic science devoted to modeling studies of the complex fluid dynamical and biogeochemical mechanisms occurring in the hyporheic zone. These efforts have led to the picture of surface-subsurface water interactions as regulators of the form and function of fluvial ecosystems. Rather than being isolated systems, surface water bodies continuously interact with the subsurface. Exploration of hyporheic zone processes has led to a new appreciation of their wide reaching consequences for water quality and stream ecology. Modern research aims toward a unified approach, in which processes occurring in the hyporheic zone are key elements for the appreciation, management, and restoration of the whole river environment. In this unifying context, this review summarizes results from modeling studies and field observations about flow and transport processes in the hyporheic zone and describes the theories proposed in hydrology and fluid dynamics developed to quantitatively model and predict the hyporheic transport of water, heat, and dissolved and suspended compounds from sediment grain scale up to the watershed scale. The implications of these processes for stream biogeochemistry and ecology are also discussed.

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“…Remote sensing methods have the ability to acquire information on inundation and surface water connectivity over large areas relatively cheaply (Bates, 2004;Chen et al, 2013;Trigg et al, 2013;Dzubakova et al, 2015). However, affordable remotely sensed products have limited application for evaluating wetland connectivity.…”

Section: Introductionmentioning

confidence: 99%

Impact of climate change on floodplain inundation and hydrological connectivity between wetlands and rivers in a tropical river catchment

Karim

Petheram

Marvanek

et al. 2015

Hydrological Processes

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Surface water connectivity between waterbodies in a river–floodplain system is considered one of the key determinants of habitat quality, biodiversity and ecological integrity. This manuscript presents results from an investigation into the potential changes in floodplain inundation and connectivity between wetlands and rivers under projected future climates, in a large river catchment in Western Australia. The study was conducted using a two‐dimensional hydrodynamic model (MIKE 21), and the modelling domain included the floodplain reaches encompassing the ecologically important wetlands. A lumped rainfall–runoff model (SIMHYD) was used to estimate local runoff and inflows from ungauged catchments. A SRTM derived 30‐m elevation data was used to parameterize land topography and stream networks in the hydrodynamic model. Hydraulic roughness parameters were estimated using a land cover map, which was developed using a combination of aerial photography, topographic maps and Google Earth imagery. The hydrodynamic model was calibrated using stream gauge data and flood inundation maps derived from Moderate Resolution Imaging Spectroradiometer imagery. Model simulated stage heights were combined with land topography to identify floodplain pathways that connect wetlands with rivers. The connectivity of 30 off‐stream wetlands was evaluated under present and future climates. The duration of connection of the individual wetlands to the main river channel varied from 1 to 40 days depending on flood magnitude and duration. Topographic relief, location on the floodplain and magnitude and duration of the flood were found to be key factors governing the level of connectivity, and the relationship between return period of flood and inundated area was found to be non‐linear. Modelling under a drier future climate indicated that the duration of connectivity of wetlands could be up to 20% less than under the current climate, whilst under a wetter climate the connectivity could be 5% longer. The results of this study provide potential use for future studies on movement and recruitment patterns of aquatic biota, wetland habitat characteristics and water quality and wetland biodiversity assessment. Copyright © 2015 John Wiley & Sons, Ltd.

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Surface water connectivity dynamics of a large scale extreme flood

Cited by 74 publications

References 42 publications

The effects of topographic depressions on multiscale overland flow connectivity: A high‐resolution spatiotemporal pattern analysis approach based on connectivity statistics

The effects of topographic depressions on multiscale overland flow connectivity: A high‐resolution spatiotemporal pattern analysis approach based on connectivity statistics

Hyporheic flow and transport processes: Mechanisms, models, and biogeochemical implications

Impact of climate change on floodplain inundation and hydrological connectivity between wetlands and rivers in a tropical river catchment

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