Scientists in the USGS National Assessment of Coastal Change Hazards Project Ready for 2018 Hurricane Season

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The 2018 hurricane season got an early start with sub-tropical storm Alberto forming on May 25.

This article is part of the June 2018 issue of the Sound Waves newsletter

The 2018 hurricane season got an early start this year with sub-tropical storm Alberto forming on May 25. Scientists with the USGS National Assessment of Coastal Change Hazards (NACCH) project were ready to provide data and tools to guide response and recovery efforts for Alberto.

Since 2011, NACCH project researchers have provided forecasts of coastal erosion based on lidar-derived beach morphology and modeled storm waves and water levels. Scenario-based forecasts are updated every year using simulated hurricane waves and surge and the most recent beach morphology from the USGS. These scenarios can be used to plan for potential future storm impacts.

Map of southeast United States with lines along coast to show different forecasts for coastal change for 5 hurricanes.

Coastal change forecasts were produced for five different storms during the 2017 hurricane season.

Screenshot of a computer model system with a view of a coastline on the left, and data readouts like graphs on the right.

The Operational Total Water Level and Coastal Change Forecast Viewer shows the timing and elevation of extreme water levels along with dune crest and toe height for Miami Beach, Florida, during the approach of Hurricane Irma.

During a landfalling storm, storm-specific probabilities of coastal change are made using real-time waves and surge forecasts from NOAA. Both scenario-based and real-time forecasts of coastal erosion are available in the Coastal Change Hazards Portal and are updated as conditions change. During the extremely active 2017 hurricane season, project scientists posted 25 separate forecasts identifying where beaches along the Atlantic and Gulf coasts were at risk of dune erosion, overwashing, or inundation. 

In collaboration with the National Weather Service (NWS), the NACCH project has also developed an Operational Total Water Level and Coastal Change Forecast Viewer. This viewer is updated several times a day with real-time water levels from the NWS Nearshore Wave Prediction System and is currently available for over 3000 kilometers of the Gulf of Mexico and Atlantic coasts from Florida through Maine. The viewer includes predictions of the timing and magnitude of water levels at the shoreline and potential impacts to coastal dunes. Observations collected by USGS water-science offices during Hurricanes Irma and Nate are being used to validate the model.

View from atop a building looking down at a beach with high waves and little sand.

The video camera at Madeira Beach shows elevated water levels at the beach on May 24, 2017.

The NACCH project is constantly working to improve forecasts of coastal change through observations and research. Video cameras at Madeira Beach and Sand Key, Florida, collect observations of the coast that can be used to monitor a range of processes, such as beach and dune erosion during extreme storm events. These observations are used to evaluate models for predicting water levels at the shoreline driven by surge and waves, and to help improve our understanding of coastal processes during storms when traditional surveys are too dangerous.

Unmanned aircraft systems (UAS), commonly referred to as drones, are another tool for NACCH project scientists to obtain rapid-response observations of the coast. Equipped with a small digital camera, a UAS can be deployed to collect aerial imagery before and after storm events. With a flight time of 10-15 minutes, the UAS can capture images from a stationary position to create standard image products for extracting water levels, shoreline position, and bathymetry. Additionally, the UAS can fly along the coast capturing multiple snapshot images, from which elevation data can be extracted using a new technique termed structure-from-motion (SfM). Preliminary SfM analysis from Madeira Beach has been used to measure the changes due to Irma and subsequent recovery.

Data readout shows changes in elevation at a beach using varying color intensities.

Elevation change at Madeira Beach, Florida, due to Hurricane Irma, produced by applying structure-from-motion techniques to UAS (drone) aerial imagery. The blue color indicates sand loss on the lower beach and the red color indicates sand gain on the upper beach. Figure credit: Jenna Brown, USGS.

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Date published: June 29, 2018

Sound Waves Newsletter - June 2018

USGS hurricane response in 2017 helps prepare for 2018 season, and USGS researchers are ready; a special, USGS-led tsunami hazards issue of the journal Marine Geology receives award as one of the top three most-cited issues in 2016 and 2017; a USGS researcher visits South Korea to share expertise on offshore mapping; and more in this June 2018 issue of Sound Waves.