Stephanie Drago scite author profile

As runoff patterns shift with a changing climate, it is critical to effectively communicate current and future flood risks, yet existing flood hazard maps are insufficient. Modifying, extending, or updating flood inundation extents is difficult, especially over large scales, because traditional floodplain mapping approaches are data and resource intensive. Low-complexity floodplain mapping techniques are promising alternatives, but their simplistic representation of process falls short of capturing inundation patterns in all situations or settings. To address these needs and deficiencies, we formalize and extend the functionality of the Height Above Nearest Drainage (i.e., HAND) floodplain mapping approach into the probHAND model by incorporating an uncertainty analysis. With publicly available datasets, the probHAND model can produce probabilistic floodplain maps for large areas relatively rapidly. We describe the modeling approach and then provide an example application in the Lake Champlain Basin, Vermont, USA. Uncertainties translate to on-the-ground changes to inundated areas, or floodplain widths, in the study area by an average of 40%. We found that the spatial extent of probable inundation captured the distribution of observed and modeled flood extents well, suggesting that low-complexity models may be sufficient for representing inundation extents in support of flood risk and conservation mapping applications, especially when uncertainties in parameter inputs and process simplifications are accounted for. To improve the accuracy of flood hazard datasets, we recommend investing limited resources in accurate topographic datasets and improved flood frequency analyses. Such investments will have the greatest impact on decreasing model output variability, therefore increasing the certainty of flood inundation extents.

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Multi‐scale drivers of spatial patterns in floodplain sediment and phosphorus deposition

Diehl

Underwood

Triantafillou

et al. 2022

Earth Surf Processes Landf

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The capacity for floodplains to capture sediment and filter pollutants is spatially variable and depends on the complex interactions of geomorphic, geologic, and hydrologic variables that operate at multiple scales. In this study, we integrated watershedscale and local assessments to improve our understanding of floodplain depositional patterns. We developed a dataset of event-scale observations of sediment and phosphorus deposition rates distributed at 129 plots across large environmental gradients of floodplain topography, valley geometry, and watershed characteristics in the Lake Champlain Basin, Vermont. Plot-scale observations were used to evaluate the crossscale influence of environmental factors and were summarized into site-scale averages to explore regional trends. Consistent with other studies, floodplain deposition generally scaled with drainage area, but trends were longitudinally discontinuous and depended on variations in valley width and slope. While variability in deposition patterns at the watershed-scale was large (average of 2.0 (0.2-9.8) kg sediment m À2 yr À1 ; average of 1.4 (0.2-6.5) g phosphorus m À2 yr À1 ), the range in deposition rates locally across a floodplain was greater (average of 4.6 (0.06-21.7) kg sediment

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Stephanie Drago

Improving flood hazard datasets using a low-complexity, probabilistic floodplain mapping approach

Multi‐scale drivers of spatial patterns in floodplain sediment and phosphorus deposition

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