A study led by USGS outlines a multifaceted climate-driven crisis facing communities along the Southeast Atlantic coast of the United States
Coastal flooding (no storm), shallow groundwater exposure and erosion (unimpeded model case) for one meter of sea-level rise and observed vertical land motion (VLM) across the Southeast Atlantic coast.
Excerpt from this report from the US Geological Survey:
A study led by USGS outlines a multifaceted climate-driven crisis facing communities along the Southeast Atlantic coast of the United States. As sea level rises, increased flooding, land subsidence, beach erosion, and rising groundwater levels threaten the safety, property, and infrastructure of millions.
While previous research has largely focused on flooding, the new study highlights additional threats such as groundwater hazards, land subsidence, and beach erosion. These hazards, often underappreciated in climate discussions, will be amplified by sea levels projected to rise by one meter over the next century. The study estimates that up to 70% of coastal residents and $1 trillion in property could face challenges from shallow and emerging groundwater. This risk is 15 times greater than the exposure to daily tidal flooding alone.
Storm activity, which is becoming more intense with climate change, adds another layer of complexity. The study projects that storm-driven flooding over the next century, including storm surge and wave-driven water levels, could expose roughly 50% of coastal residents and $770 billion in property to severe flooding, an increase by an order of magnitude compared to daily flood impacts.
The study also warns of dramatic shoreline changes, with up to 80% of present-day beaches at risk of being completely eroded. This loss would not only devastate ecosystems and tourism but also weaken natural flood defenses, leaving coastal areas more vulnerable. Compounding these issues is the high rate of land subsidence already affecting more than one million residents in the region. This gradual sinking of the ground will intensify flooding and groundwater hazards, further challenging adaptation efforts.
