Uncertain seas: probabilistic modeling of future coastal flood zones

Amante, Christopher

doi:10.1080/13658816.2019.1635253

Cited by 16 publications

(15 citation statements)

References 86 publications

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“…There is a rich heritage of treating elevation error probabilistically [52,[55][56][57], and the method has been successfully applied and its advantages demonstrated in numerous recent sea-level rise and inundation assessment studies [21,46,49,53,[58][59][60][61][62]. For users of an assessment conducted with the probabilistic method, the stated probability indicates the likelihood, or chance, that the mapped area will be impacted at the specified increased water level, for example a 68% chance (or at least 68 times out of 100) that the area will be inundated.…”

Section: Probabilisticmentioning

confidence: 99%

Inundation Exposure Assessment for Majuro Atoll, Republic of the Marshall Islands Using A High-Accuracy Digital Elevation Model

et al. 2020

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Majuro Atoll in the central Pacific has high coastal vulnerability due to low-lying islands, rising sea level, high wave events, eroding shorelines, a dense population center, and limited freshwater resources. Land elevation is the primary geophysical variable that determines exposure to inundation in coastal settings. Accordingly, coastal elevation data (with accuracy information) are critical for assessments of inundation exposure. Previous research has demonstrated the importance of using high-accuracy elevation data and rigorously accounting for uncertainty in inundation assessments. A quantitative analysis of inundation exposure was conducted for Majuro Atoll, including accounting for the cumulative vertical uncertainty from the input digital elevation model (DEM) and datum transformation. The project employed a recently produced and validated DEM derived from structure-from-motion processing of very-high-resolution aerial imagery. Areas subject to marine inundation (direct hydrologic connection to the ocean) and low-lying lands (disconnected hydrologically from the ocean) were mapped and characterized for three inundation levels using deterministic and probabilistic methods. At the highest water level modeled (3.75 ft, or 1.143 m), more than 34% of the atoll study area is likely to be exposed to inundation (68% chance or greater), while more than 20% of the atoll is extremely likely to be exposed (95% chance or greater). The study demonstrates the substantial value of a high-accuracy DEM for assessing inundation exposure of low-relief islands and the enhanced information from accounting for vertical uncertainty.

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Section: Probabilisticmentioning

confidence: 99%

Inundation Exposure Assessment for Majuro Atoll, Republic of the Marshall Islands Using A High-Accuracy Digital Elevation Model

et al. 2020

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“…Many low-lying areas that are sensitive to coastal flooding during storm events will be overwhelmed with just 25 cm of sea-level rise along the California coastline; in combination with a 1:100 year storm event this could cause substantial flooding that would impact 150,000 residents and cause up to $30 billion damage [92]. Future sea-level rise will increase 'tail waters' and reduce the rate at which low-lying coastal and estuarine areas are able to drain floodwater, increasing the likelihood of further inundation from subsequent storm or rainfall events [93]. Extreme events can cause initial damage from flooding, but lack of drainage, potentially exacerbated by subsequent events, can cause knock-on effects to impact economic sectors in relation to closure of ports and harbours or disruption of transport of goods, and critical services (e.g., power, water, and communications), essential for public safety.…”

Section: Implications For Inundation Under Future Sea-level Scenariosmentioning

confidence: 99%

Sensitivity of Flood Hazard and Damage to Modelling Approaches

Lyddon

Brown

Leonardi

et al. 2020

JMSE

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Combination of uncertainties in water level and wave height predictions for extreme storms can result in unacceptable levels of error, rendering flood hazard assessment frameworks less useful. A 2D inundation model, LISFLOOD-FP, was used to quantify sensitivity of flooding to uncertainty in coastal hazard conditions and method used to force the coastal boundary of the model. It is shown that flood inundation is more sensitive to small changes in coastal hazard conditions due to the setup of the regional model, than the approach used to apply these conditions as boundary forcing. Once the threshold for flooding is exceeded, a few centimetres increase in combined water level and wave height increases both the inundation and consequent damage costs. Improved quantification of uncertainty in inundation assessments can aid long-term coastal flood hazard mitigation and adaptation strategies, to increase confidence in knowledge of how coastlines will respond to future changes in sea-level.

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“…In addition to the discount rate assumption, our housing market impairment analysis makes a series of simplifying assumptions: First, we assume that once a property is inundated by SLR, the value of the property falls to zero, which is an assumption in line with previous research (Bernstein et al, 2019). In reality, additional flood risks from nuisance flooding or enhanced storm surge would also erode economic value well before terminal impairment from SLR inundation (Amante, 2019;Ghanbari et al, 2019;Beltrán et al, 2019). Second, our approach assumes no foresight on the part of homeowners, who would likely begin to discount property values well before terminal impairment or might take steps to protect their properties (e.g., by erecting protective flood walls).…”

Section: Discount Rates Time Value and Value Impairment Estimatesmentioning

confidence: 99%

“…Accurate, high-resolution DEMs are needed to both delineate areas with low elevations below a projected sea-level and to determine hydrologic connectivity. Natural terrain features (e.g., gullies, hills) and man-made terrain features (e.g., culverts, levees) can enhance or impede the flow of water and affect flooding at inland elevations (Li et al, 2009;Poulter and Halpin, 2008;Gesch, 2009;Zhang et al, 2013;Amante, 2019). The spatial resolution of the DEM is an important factor in coastal flood modeling, as it determines the ability to resolve these terrain features (e.g., gullies, hills, culverts, and levees) that can affect hydrologic connectivity.…”

Section: Local Topographymentioning

confidence: 99%

“…As sea-levels slowly rise, these locations will likely face increased nuisance flooding (Moftakhari et al, 2015;Sweet et al, 2017), enhanced storm surge inundation (Amante, 2019), and permanent change of coastlines. In extreme cases, some coastal areas may experience out-migration, and city planners may need to implement policies to facilitate population departure (Wrathall et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Housing Market Value Impairment from Future Sea-level Rise Inundation

Amante¹,

Dice²,

Rodziewicz³

et al. 2020

RWP

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The rate of future global sea-level rise will likely increase due to elevated ocean temperatures and increases in land-ice melt. Nearly 40 percent of the U.S. population lives in coastal communities, and coastal properties are expected to become more prone to coastal flooding in the coming decades due to relative sea-level rise caused by both global and local factors. Understanding how this projected sea-level rise translates to lost economic value is critical to the decisions of insurance companies, banks, governments, investors, and regulatory agencies. We use probability distributions of local sea-level rise projections, National Oceanic and Atmospheric (NOAA) coastal digital elevation models, and CoreLogic housing data to estimate a range of housing market value impairments from future sea-level rise in 15 major U.S. coastal cities as well as the associated timing of those impairments. Our estimates include only residential properties with four or fewer units and thus provide a lower bound estimate of economic risk from sea-level rise. We estimate that within these 15 major U.S. coastal metros, sea-level rise will inundate between 2,000 and 28,000 properties by 2100 in a relatively low greenhouse gas concentration scenario and between 7,000 to 77,000 properties under an unlikely, extreme greenhouse gas concentration scenario.

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Uncertain seas: probabilistic modeling of future coastal flood zones

Cited by 16 publications

References 86 publications

Inundation Exposure Assessment for Majuro Atoll, Republic of the Marshall Islands Using A High-Accuracy Digital Elevation Model

Inundation Exposure Assessment for Majuro Atoll, Republic of the Marshall Islands Using A High-Accuracy Digital Elevation Model

Sensitivity of Flood Hazard and Damage to Modelling Approaches

Housing Market Value Impairment from Future Sea-level Rise Inundation

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