Validation of a 30 m resolution flood hazard model of the conterminous <scp>U</scp>nited <scp>S</scp>tates

Wing, Oliver; Bates, Paul; Sampson, Chris; Smith, Andrew M.; Johnson, Kris; Erickson, Tyler

doi:10.1002/2017wr020917

Cited by 260 publications

(367 citation statements)

References 50 publications

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“…These layers are of significantly higher quality and spatial coverage than those that have previously informed exposure and risk estimations. Validation of the new hazard layers [16] suggests they are of commensurate quality to local studies carried out by US government agencies. These new high-resolution analyses with a realistic representation of flood physics indicate that the population exposed to serious flooding in CONUS is 2.6-3.1 times higher than previous estimates.…”

Section: Introductionmentioning

confidence: 82%

Estimates of present and future flood risk in the conterminous United States

Wing¹,

Bates

Smith³

et al. 2018

Environ. Res. Lett.

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315

209

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Section: Introductionmentioning

confidence: 82%

Estimates of present and future flood risk in the conterminous United States

Wing¹,

Bates

Smith³

et al. 2018

Environ. Res. Lett.

Self Cite

315

209

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“…Through five decades of development, LSMs have been augmented from simple bucket models (Manabe, ) to comprehensive Earth system models that simulate water cycle, energy cycle, carbon cycle, and even nutrient cycle (Oleson et al, ; Tian et al, ). Besides developing a very complicated system that is expected to consider as many biogeophysical and biogeochemical processes as possible, another direction is to make LSMs useful for applications (Wood et al, ), for example, water resources management (Wada et al, ), flood/drought early warning (Wing et al, ), and detection and attribution of hydrological changes (Yuan et al, ). The latter direction requires developing high‐resolution LSMs that can provide locally relevant information (Bierkens et al, ).…”

Section: Introductionmentioning

confidence: 99%

High‐Resolution Land Surface Modeling of Hydrological Changes Over the Sanjiangyuan Region in the Eastern Tibetan Plateau: 1. Model Development and Evaluation

Yuan

Wang

et al. 2018

J Adv Model Earth Syst

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High‐resolution modeling became popular in recent years due to the availability of multisource observations, advances in understanding fine‐scale processes, and improvements in computing facilities. However, modeling of hydrological changes over mountainous regions is still a great challenge due to the sensitivity of highland water cycle to global warming, tightly coupled hydrothermal processes, and limited observations. Here we show a successful high‐resolution (3 km) land surface modeling over the Sanjiangyuan region located in the eastern Tibetan plateau, which is the headwater of three major Asian rivers. By developing a new version of a Conjunctive Surface‐Subsurface Process model named as CSSPv2, we increased Nash‐Sutcliffe efficiency by 62–130% for streamflow simulations due to the introduction of a storage‐based runoff generation scheme, reduced errors by up to 31% for soil moisture modeling after considering the effect of soil organic matter on porosity and hydraulic conductivity. Compared with ERA‐Interim and Global Land Data Assimilation System version 1.0 reanalysis products, CSSPv2 reduced errors by up to 30%, 69%, 92%, and 40% for soil moisture, soil temperature, evapotranspiration, and terrestrial water storage change, respectively, as evaluated against in situ and satellite observations. Moreover, CSSPv2 well captured the elevation‐dependent ground temperature warming trends and the decreased frozen dates during 1979–2014, and significant increasing trends (p < 0.05) in evapotranspiration and terrestrial water storage during 1982–2011 and 2003–2014 respectively, while ERA‐Interim and Global Land Data Assimilation System version 1.0 showed no trends or even negative trends. This study implies the necessity of developing high‐resolution land surface models in realistically representing hydrological changes over highland areas that are sentinels to climate change.

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“…Additionally, flood maps depicting historical flooding events are advantageous for productive, nontechnical dialogue aimed at reducing flood vulnerabilities. Collaborative flood modeling aligns with the strategic plans of FEMA to support local leadership of FRM, creating a process for local stakeholders to contemplate flooding, map risks in ways that align with local decision‐making needs, and enhance deliberations over strategies and projects to manage risks. It can be thought of as a bottom‐up alternative to what has become a top‐down process of flood hazard mapping that is limiting important dialogue about flooding (Soden et al, ) and prone to significant errors (NRC 2009, Wing et al, , NASEM 2019).…”

Section: Discussionmentioning

confidence: 99%

“…Damages have been escalating for decades (Cartwright, 2005;Hinkel et al, 2014;Jongman et al, 2012;Sundermann et al, 2014), and a U.S. record was set in 2017 with over $300 billion in disaster losses, mainly from hurricanes and flooding (National Oceanic and Atmospheric Administration, 2018). Cities around the world (Hanson et al, 2011, Hinkel et al, 2014, Kron, 2013 and municipalities across the United States (Kulp & Strauss, 2017) are threatened by coastal flooding, and nearly 41 million Americans live within 100-year flood zones associated with fluvial and pluvial flooding (Wing et al, 2017). Gall et al (2011) report that flood losses in the United States are not just growing in an absolute sense, after adjusting for inflation, but on a per capita basis and suggest that impacts are even greater than reported because of inadequate monitoring and assessment.…”

Section: Introductionmentioning

confidence: 99%

Collaborative Modeling With Fine‐Resolution Data Enhances Flood Awareness, Minimizes Differences in Flood Perception, and Produces Actionable Flood Maps

et al. 2020

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Existing needs to manage flood risk in the United States are underserved by available flood hazard information. This contributes to an alarming escalation of flood impacts amounting to hundreds of billions of dollars per year and countless disrupted lives and affected communities. Making information about flood hazards useful for the range of decisions that dictate the consequences of flooding poses many challenges. Here, we describe collaborative flood modeling, whereby researchers and end‐users at two coastal sites co‐develop fine‐resolution flood hazard models and maps responsive to decision‐making needs. We find, first of all, that resident perception and awareness of flooding are enhanced more by fine‐resolution depth contour maps than Federal Emergency Management Agency (FEMA) flood hazard classification maps and that viewing fine‐resolution depth contour maps helps to minimize differences in flood perception across subgroups within the community, generating a shared understanding. We also find that collaborative flood modeling supports the engagement of a wide range of end‐users in contemplating the risks of flooding and provides strong evidence that the co‐produced knowledge can be readily adopted and applied for Flood Risk Management (FRM). Overall, collaborative flood modeling advances FRM by providing multiple points of entry for diverse groups of end‐users to contemplate the spatial extent, intensity, timing, chance, and consequences of flooding, thus enabling the web of decision‐making related to flooding to be better informed with the best available science. This transdisciplinary approach emphasizes vulnerability reduction and is complementary to FEMA Flood Insurance Rate Maps used for flood insurance administration.

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Validation of a 30 m resolution flood hazard model of the conterminous United States

Cited by 260 publications

References 50 publications

Estimates of present and future flood risk in the conterminous United States

Estimates of present and future flood risk in the conterminous United States

High‐Resolution Land Surface Modeling of Hydrological Changes Over the Sanjiangyuan Region in the Eastern Tibetan Plateau: 1. Model Development and Evaluation

Collaborative Modeling With Fine‐Resolution Data Enhances Flood Awareness, Minimizes Differences in Flood Perception, and Produces Actionable Flood Maps

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