Scalable, data-assimilated models predict large-scale shoreline response to waves and sea-level rise

Sean Vitousek; Kilian Vos; Kristen D. Splinter; Kai Alexander Parker; Andrea C. O'Neill; Amy C. Foxgrover; Maya Kumari Hayden; Jennifer Anne Thomas; Li H. Erikson; Patrick L. Barnard

doi:10.1038/s41598-024-77030-4

Scalable, data-assimilated models predict large-scale shoreline response to waves and sea-level rise

Scientific Reports

By: Sean Vitousek, Kilian Vos, Kristen D. Splinter, Kai Alexander Parker, Andrea C. O'Neill, Amy C. Foxgrover, Maya Kumari Hayden, Jennifer Anne Thomas, Li H. Erikson, and Patrick L. Barnard

https://doi.org/10.1038/s41598-024-77030-4

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Abstract

Coastal change is a complex combination of multi-scale processes (e.g., wave-driven cross-shore and longshore transport; dune, bluff, and cliff erosion; overwash; fluvial and inlet sediment supply; and sea-level-driven recession). Historical sea-level-driven coastal recession on open ocean coasts is often outpaced by wave-driven change. However, future sea-level-driven coastal recession is expected to increase significantly in tandem with accelerating rates of global sea-level rise. Few models of coastal sediment transport can resolve the multitude of coastal-change processes at a given beach, and fewer still are computationally efficient enough to achieve large-scale, long-term simulations, while accounting for historical behavior and uncertainties in future climate. Here, we show that a scalable, data-assimilated shoreline-change model can achieve realistic simulations of long-term coastal change and uncertainty across large coastal regions. As part of the modeling case study of the U.S. South Atlantic Coast (Miami, Florida to Delaware Bay) presented here, we apply historical, satellite-derived observations of shoreline position combined with daily hindcasted and projected wave and sea-level conditions to estimate long-term coastal change by 2100. We find that 63 to 94% of the shorelines on the U.S. South Atlantic Coast are projected to retreat past the present-day extent of sandy beach under 1.0 to 2.0 m of sea-level rise, respectively, without large-scale interventions.

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Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Scalable, data-assimilated models predict large-scale shoreline response to waves and sea-level rise
Series title	Scientific Reports
DOI	10.1038/s41598-024-77030-4
Volume	14
Publication Date	November 14, 2024
Year Published	2025
Language	English
Publisher	Nature
Contributing office(s)	Pacific Coastal and Marine Science Center
Description	28029, 12 p.
Country	United States
State	North Carolina
Other Geospatial	Cape Hatteras