Toward Global Stochastic River Flood Modeling

Global flood models integrate flood maps of constant probability in space, ignoring the correlation between sites and thus potentially misestimating the risk posed by extreme events. Stochastic flood models alleviate this issue through the simulation of flood events with a realistic spatial structur...

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Bibliographic Details
Published in:Water resources research 2020-08, Vol.56 (8), p.n/a
Main Authors: Wing, Oliver E. J., Quinn, Niall, Bates, Paul D., Neal, Jeffrey C., Smith, Andrew M., Sampson, Christopher C., Coxon, Gemma, Yamazaki, Dai, Sutanudjaja, Edwin H., Alfieri, Lorenzo
Format: Article
Language:English
Subjects:
Arid climates
Aridity
Computer simulation
Correlation
Dependence
Environmental risk
Flood control
Flood mapping
Flood models
Flood risk
Flooding
Floods
Geological surveys
Global precipitation
hydraulic modelling
Hydrologic models
Hydrologic networks
hydrological modelling
Hydrology
Mathematical models
Modelling
Mountain climates
Probability
Probability theory
Proliferation
Rain
Rainfall
Rainfall simulators
Rainfall-runoff relationships
Risk
River discharge
River flow
Rivers
Runoff
Runoff models
Simulation
spatial dependence
Statistical analysis
Statistical models
Stream discharge
Stream flow
Surveying
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Summary:Global flood models integrate flood maps of constant probability in space, ignoring the correlation between sites and thus potentially misestimating the risk posed by extreme events. Stochastic flood models alleviate this issue through the simulation of flood events with a realistic spatial structure, yet their proliferation at large scales has historically been inhibited by data quality and computer availability. In this paper, we show, for the first time, the efficacy of modeled river discharge reanalyses in the characterization of flood spatial dependence in the absence of a dense stream gauge network. While global hydrological models may show poor correspondence with absolute observed river flows, we find that the rate at which they can simulate the joint occurrence of relative flow exceedances at two given locations is broadly similar to when a gauge‐based statistical model is used. Evidenced over the United States, flood events simulated using observed gauge data from the U.S. Geological Survey versus those generated using modeled streamflows have similar (i) distributions of site‐to‐site correlation strength, (ii) relationships between event size and return period, and, importantly, (iii) loss distributions when incorporated into a continental‐scale flood risk model. Extremal dependence is generally quantified less accurately on larger rivers, in arid climates, in mountainous terrain, and for the rarest high‐magnitude events. However, local‐scale errors are shown to broadly cancel each other out when combined, producing an unbiased flood spatial dependence model. These findings suggest that building accurate stochastic flood models worldwide may no longer be a distant aspiration. Plain Language Summary Global flood risk is commonly estimated through flood inundation maps with a defined probability of occurrence. These flood simulations have a key drawback in that they fail to capture the spatial patterns exhibited during real flood events, instead modeling the same probability of flooding on every river at once. Solutions which rely on networks of gauged river flow observations will necessarily break down in the majority of the world's regions which lack such a resource. In this paper, we use historic river flows simulated by global rainfall‐runoff models (rather than observed flows) into a statistical model which captures the spatial correlation of flow extremes. If we examine the relative flow exceedance probabilities from these hydrological model
ISSN:0043-1397
1944-7973
DOI:10.1029/2020WR027692