Skip to content

Storm-permitting climate modeling highlights storm frequency’s role in future extreme sea level changes along US East and Gulf coasts

Published Article

United States

Publication date: January 8, 2026

View resource

High‑resolution CESM simulations show that future storm‑driven extreme sea levels will change unevenly across U.S. coasts. Tropical cyclone and nor’easter frequency shifts drive opposing regional trends, challenging assumptions of stationarity and highlighting the need for high‑resolution models to improve coastal risk assessment in a warming climate.

Subject Tags

  • Climate impacts
  • Coastal
  • Climate risks

Abstract

Storm-induced coastal extreme sea levels (ESLs) pose severe threats to infrastructure, economies, and ecosystems. However, projecting future ESL changes is hindered by the coarse resolution of climate models used in assessment reports, which fail to accurately capture tropical cyclones (TCs) and nor’easters. Here, we demonstrate that high-resolution Community Earth System Model (CESM) simulations realistically reproduce observed wind- and pressure-induced daily-mean extreme dynamic sea levels (DSLs), including the most extreme events. Under a high-emission scenario, we show that 50-year return DSLs (DSL50) decrease along the U.S. Texas and Northeast coasts but increase along the U.S., Louisiana, and Southeast coasts from 2006 to 2100, creating substantial spatial discrepancies between total DSL50 changes and mean DSL rise. Along the Gulf and Southeast coasts, DSL50 trends are primarily driven by TC frequency changes, while nor’easter frequency changes tend to govern trends along the Northeast coast. These findings challenge the traditional assumption of stationarity in storm-induced ESLs, underscore the importance of high-resolution climate models for regional coastal risk assessment, and represent a critical step toward more accurate projections of future ESLs in a warming climate.

Citation

Xu, G., Chang, P., Danabasoglu, G., Castruccio, F. S., Yeager, S., Zhang, Q., ... & Shepard, C. C. (2026). Storm-permitting climate modeling highlights storm frequency’s role in future extreme sea level changes along US East and Gulf coasts. npj Climate and Atmospheric Science9(1), 8.

TNC Authors

  • Susan Bates
    Coastal Science Pgm Manager • Virginia
    The Nature Conservancy
    Email: susan.bates@tnc.org

  • Christine C. Shepard
    Director of Science • Florida
    The Nature Conservancy
    Email: cshepard@tnc.org