What is Storm Surge?

Storm Surge is a change in normal tide levels caused by winds and atmospheric pressure associated with a storm.  Its primary components are: pressure setup (water level change due to lower atmospheric pressure), geostrophic adjustment (adjustments due to Coriolis forces), and wind setup (water level change due to wind).  Additionally, waves riding on top of the surge and tide, increase the water level via wave setup and wave runup.

Conceptually, winds from a storm create a current in the water.  The winds push the surface water forward, it sinks, flows under the storm and comes back up behind the storm only to be pushed forward again. storm surge over deep water
Unfortunately the reverse flow occurs at roughly 200 to 400 feet deep, so the cycle gets disrupted as the storm moves over shallower water.  The result is the water piles up in front of the storm and eventually splashes and sloshes overland. storm surge over shallow water

Storm intensity, forward speed, size, central pressure, shape, and angle of approach to the coast all determine how strong the surge will be. The shape of the bays and estuaries and slope of the ocean bottom also play a large role.  For instance, given the same storm, coastal areas adjacent to a steeply sloping ocean bottom will experience less storm surge than areas adjacent to shallow slopes.

Models and Guidance

MDL develops and maintains a suite of models to produce storm surge guidance for both tropical and extra-tropical storms.  The key difference is that tropical storms (e.g., hurricanes), are more readily modeled by a parametric wind model, whereas extra-tropical storms (e.g., winter storms), are broader and require a gridded wind field.

 

Deterministic: For tropical (e.g. hurricane) storm surge, MDL developed the Sea Lake and Overland Surges from Hurricanes (SLOSH) model, which uses an internal parametric wind model to provide surface forcing for the finite difference equations that solve the Navier-Stokes equations of motion.  For extra-tropical storm surge, MDL developed the Extra-Tropical Storm Surge (ETSS) model which uses surface wind and pressure grids from the Global Forecast System (GFS) for surface forcing.

 

 

Real-Time Ensemble: Since the primary uncertainty in storm surge guidance is the uncertainty of the wind, MDL created real-time ensemble versions.  For the tropical version, MDL created the Probabilistic tropical-cyclone storm Surge (P-Surge) model by using the National Hurricane Center's (NHC) official forecast and its 5-year average errors to derive an ensemble of SLOSH model runs.  For the extra-tropical version, MDL created the Probabilistic Extra-Tropical Storm Surge (PETSS) model by using the winds and pressure grids from the Global Ensemble Forecast System (GEFS).

 

 

Climatological Ensemble: Further, since hurricane evacuations are based on the potential for hurricane storm surge, MDL developed the concept of estimating that potential by (a) establishing an ensemble of all the ways a particular Saffir-Simpson category storm can make landfall, and then (b) taking the maximum of the result of running each ensemble member through the tropical storm surge model.

 

Storm Surge

Contact Storm Surge

For further information about MDL's Storm Surge initiatives, please contact Arthur.Taylor@noaa.gov.