Oceanographer’s
hurricane models deliver more precise forecasts
The illustration of the Port of
Galilee shows how the modeling tool could predict precise storm damage. (Isaac
Ginis)
Isaac Ginis said that it is
notoriously difficult to forecast hurricanes in New England.
When storms move north, they develop a more complex wind structure than those remaining in the Southeast and Gulf of Mexico, their paths become more erratic, and the region’s complicated topography makes predicting their movement over land especially challenging.
In addition, the relatively short rivers in New England fill up quickly when it rains and cause more flooding than in many other areas.
When storms move north, they develop a more complex wind structure than those remaining in the Southeast and Gulf of Mexico, their paths become more erratic, and the region’s complicated topography makes predicting their movement over land especially challenging.
In addition, the relatively short rivers in New England fill up quickly when it rains and cause more flooding than in many other areas.
A new series of hurricane models
Ginis and his colleagues are developing at the University of Rhode Island’s
Graduate School of Oceanography will address these difficulties and make
forecasting hurricanes in New England more precise. The models will even
predict the storm impact on particular roads, bridges and buildings in the
area.
“We’re working to improve existing models and create new modeling capabilities to address concerns about coastal flooding due to storm surge, inland flooding due to heavy rainfall and the challenges of predicting winds over land,” said Ginis, a professor of oceanography who was the first to incorporate ocean conditions into hurricane models. His models have been used by the National Hurricane Center for more than 20 years.
Funded by the Department of Homeland
Security in partnership with the University of North Carolina at Chapel Hill,
this research effort will result in a real-time forecast system for southern
New England that will enable public officials and first responders to get
accurate updates every 30 minutes.
The URI team will improve the
existing Advanced Circulation Model used by Homeland Security, the National
Oceanic and Atmospheric Administration and other agencies for storm surge
prediction.
The new version will feature much higher resolution for the New England area and incorporate new capabilities, such as combined coastal and inland flooding forecasts and predictions for storm impacts on critical infrastructure.
The new version will feature much higher resolution for the New England area and incorporate new capabilities, such as combined coastal and inland flooding forecasts and predictions for storm impacts on critical infrastructure.
“We’re going to deliver a fully-automated
system with all hazard predictions, wind speeds, coastal and inland flooding
predictions and 3D visualizations in one forecast system,” he said. “It will be
the first place in the country to have a fully-integrated hazard and impact
analysis.”
Ginis and his research team
collaborated with the URI Department of Marine Affairs and the Rhode Island
Emergency Management Agency to interview facility managers around the state to
identify vulnerabilities and concerns about buildings, roads, bridges and other
infrastructure.
For instance, a fire chief indicated that 120-mile-per-hour winds would likely disable the department’s communications antenna. Another noted that eight inches of water on a roadway would prevent emergency vehicles from reaching those in need.
For instance, a fire chief indicated that 120-mile-per-hour winds would likely disable the department’s communications antenna. Another noted that eight inches of water on a roadway would prevent emergency vehicles from reaching those in need.
“All infrastructure has a threshold
when it will stop functioning properly,” Ginis said. “We’ll be able to predict
those thresholds and mark on a map in real-time when those thresholds are
reached.”
Three-dimensional visualizations of
storm impacts will also be developed and integrated into the hurricane hazard
prediction models. These tools will enable emergency managers and first
responders to more clearly understand storm impacts.
In addition, the forecast models
will feature refinements to existing wave and storm surge models, enabling more
accurate predictions of coastal flooding.
“To do that, we need to have very
high spatial resolution of the coastline, bathymetry and topography,” Ginis
said. “We’ve refined our calculations to improve the resolution of the model by
a factor of 10.”
To predict inland flooding, he has
partnered with a hydrologist at Florida State University to create a model that
will forecast the flooding of the various river watersheds in the region.
According to Ginis, where most
hurricane models tend to go wrong is in the prediction of wind speed over land
because of the change in friction between the water and the land.
“When a storm makes landfall, the
wind experiences major changes that are affected by the local topography,” he
said. “You have to take into account the area’s land cover — forest, crops,
urban — to predict the surface winds at high resolution over those land uses.”
Ginis recently made a presentation
about this element of the model at a hurricane conference in Florida, and the
National Hurricane Center has already expressed interest, since no existing
models are as refined for predicting hurricane wind speed over land.
The University of Rhode Island’s
Graduate School of Oceanography (GSO) is one of the world’s premier
oceanographic institutions. Founded in 1961, the GSO has built a reputation for
excellence in deep water oceanographic research, coastal planning and
management, sustainable fisheries and monitoring the health of Narragansett
Bay. With operations worldwide, GSO research, education and outreach
programs train the next generation of scientists and policymakers, while
ensuring Rhode Island’s K-12 teachers and students gain an appreciation for the
importance of ocean science through a variety of hand-on programs.
On Nov. 6, Rhode Islanders will
vote on referendum No. 2, a $70 million higher education general obligation
bond that includes $45 million for upgrades to the Narragansett Bay Campus. If
approved, proceeds from the bond will be used to improve the GSO’s pier
(required to accommodate a newly awarded Regional Class Research Vessel from
the National Science Foundation valued at more than $100 million), construct a
20,000-square-foot Ocean Technology building, a Marine Operations building and
fund other necessary improvements to campus facilities
