Comparing Patterns of Hurricane Washover into Built and Unbuilt Environments

Extreme geohazard events can change landscape morphology by redistributing huge volumes of sediment. Event-driven sediment deposition is typically studied in unbuilt settings - despite the ubiquity of occurrence and high economic cost of these geohazard impacts in built environments. Moreover, sedimentary consequences of extreme events in built settings tend to go unrecorded because they are rapidly cleared, at significant expense, from streets and roads to facilitate emergency response. Reducing disaster costs requires an ability to predict disaster impacts, which itself requires comprehensive measurement and study of the physical consequences of geohazard events. Here, using a database of poststorm aerial imagery, we measure plan-view geometric characteristics of sandy washover deposits in built and unbuilt settings following five different hurricane strikes along the Atlantic and Gulf Coasts of the US since 2011. We identify systematic similarities and differences between washover morphology in built and unbuilt environments, which we further explore with a simplified numerical model. Our findings suggest that spatial characteristics of the built environment (termed fabric) - specifically, the built fraction of the depositional zone - exerts a fundamental control on the form of large deposits. Accounting for the influence of built fabric on the morphodynamics of flow-driven geohazards is a tractable step toward improved forecasts of hazard impacts and disaster risk reduction.

Automated summary

Research shows that the characteristics of sediment deposits from geohazard events in built environments exhibit systematic similarities and differences compared to those in unbuilt environments. The built fabric in the environment exerts a fundamental control on the form of large deposits. Considering the influence of built fabric on the morphodynamics of flow-driven geohazards is a feasible step towards improving forecasts of hazard impacts and reducing disaster risks.