Welcome to the CCHT! We develop computational models for wind waves and coastal circulation, and then apply these models to high-resolution simulations of ocean behavior. Our goals are to understand how coastlines are threatened during storms, how materials are transported in the coastal environment, and how to convey these hazard risks for use in decision support. Our research spans the disciplines of coastal engineering, numerical methods, computational mathematics, and high-performance computing.

In this web site, we share our research progress, from development to application, and from coding to publishing. Learn more about What We Do and how to Join Our Team.

Climate Change Effects on Flooding During Hurricane Sandy

Hurricane Sandy devastated the Northeast US coastline in 2012. In New York City, it caused power outages that affected nearly 2 million people, forced evacuations of 6500 patients from hospitals and nursing homes, prevented 1.1 million children from attending school for a week, and disrupted the daily travel of about 11 million commuters. Many of these impacts were related to flooding of critical infrastructure, including nearly 90,000 buildings, and more than $5 billion in damages in the mass transit system. The maximum observed water level at the tidal gauge located at the southern tip of Manhattan was 5.3 m above the station datum and 2.8 m above the expected tide. This additional water, known as storm surge, was pushed from the open sea by strong winds during the storm. Sandy was one of several recent storms to cause flooding along the US Gulf and Atlantic coasts, including Katrina and Rita (2005), Gustav and Ike (2008), Irene (2011), Isaac (2012), and Hermine and Matthew (2016). Climatic changes are causing these storms to be larger and more intense, last longer, and move farther northward. Their impacts will be more severe to communities in coastal regions in the future.

JC Dietrich (2018). “Vignette: Climate Change Effects on Flooding During Hurricane Sandy (2012).” Disaster Epidemiology: Methods and Applications, Academic Press, JA Horney, ed., 153-156, DOI: 10.1016/B978-0-12-809318-4.00020-4.

CCHT Visited by Dr. Navid Tahvildari

The CCHT hosted a visit by Dr. Navid Tahvildari of Old Dominion University. His research interests include waves and wave-induced processes and storm surge and their interactions with sediments, aquatic vegetation, and infrastructure.

During his visit, he met with faculty members and graduate students in the coastal engineering team at NC State. He also presented in our EWC seminar series about “Nonlinear Dynamics of Surface Waves in Dissipative Environments.” It was great to connect with Dr. Tahvildari.

Dr. Navid Tahvildari starts his seminar during his visit to the CCHT.

Nelson Tull wins Student Poster Award

CCHT MS student Nelson Tull won the Student Poster Award at the ASBPA National Coastal Conference 2017. This award is chosen by attendees from among all of the student posters and is reflective of both compelling research activities and excellent presentation skills.

Congratulations to Nelson!

Nelson Tull accepts the Student Poster Award during the awards luncheon at the ASBPA National Coastal Conference.

Poster: ASBPA Coastal Conference 2017

N Tull, JC Dietrich, TE Langan, H Mitasova, BO Blanton, JG Fleming, RA Luettich. “Improving Accuracy of Real-Time Storm Surge Inundation Predictions Using GRASS GIS.” ASBPA National Coastal Conference 2017, Fort Lauderdale, Florida, 25 October 2017.

Poster presented by Nelson Tull at the ASBPA National Coastal Conference 2017.

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Sensitivity of Storm Surge Predictions to Atmospheric Forcing during Hurricane Isaac

Storm surge and overland flooding can be predicted with computational models at high levels of resolution. To improve efficiency in forecasting applications, surge models often use atmospheric forcing from parametric vortex models, which represent the surface pressures and wind fields with a few storm parameters. The future of storm surge prediction could involve real-time coupling of surge and full-physics atmospheric models; thus, their accuracies must be understood in a real hurricane scenario. The authors compare predictions from a parametric vortex model (using forecast tracks from the National Hurricane Center) and a full-physics coupled atmosphere-wave-ocean model during Hurricane Isaac (2012). The predictions are then applied within a tightly coupled, wave and surge modeling system describing the northern Gulf of Mexico and the floodplains of southwest Louisiana. It is shown that, in a hindcast scenario, a parametric vortex model can outperform a data-assimilated wind product, and given reasonable forecast advisories, a parametric vortex model gives reasonable surge forecasts. However, forecasts using a full-physics coupled model outperformed the forecast advisories and improved surge forecasts. Both approaches are valuable for forecasting the coastal impacts associated with tropical cyclones

JC Dietrich, A Muhammad, M Curcic, A Fathi, CN Dawson, SS Chen, RA Luettich (2018). “Sensitivity of Storm Surge Predictions to Atmospheric Forcing during Hurricane Isaac.Journal of Waterway, Port, Coastal, and Ocean Engineering, 144(1), DOI: 10.1061/(ASCE)WW.1943-5460.0000419