In true Mencken style (“The whole aim of practical politics is to keep the populace alarmed by menacing it with an endless series of hobgoblins, all of them imaginary.” ) an AP story on the front page of the Arizona Daily Star speculates on dire consequences that may occur if a hurricane meets the oil slick in the Gulf of Mexico.
Here is what the National Oceanic and Atmospheric Administration (NOAA) says about such a possibility:
Most hurricanes span an enormous area of the ocean (200-300 miles) — far wider than the current size of the spill. If the slick remains small in comparison to a typical hurricane’s general environment and size, the anticipated impact on the hurricane would be minimal. The oil is not expected to appreciably affect either the intensity or the track of a fully developed tropical storm or hurricane. The oil slick would have little effect on the storm surge or near-shore wave heights.
The high winds and seas will mix and “weather” the oil which can help accelerate the biodegradation process. The high winds may distribute oil over a wider area, but it is difficult to model exactly where the oil may be transported. Movement of oil would depend greatly on the track of the hurricane. Storms’ surges may carry oil into the coastline and inland as far as the surge reaches. Debris resulting from the hurricane may be contaminated by oil from the Deepwater Horizon incident, but also from other oil releases that may occur during the storm. A hurricane’s winds rotate counter-clockwise. Thus, in very general terms: A hurricane passing to the west of the oil slick could drive oil to the coast. A hurricane passing to the east of the slick could drive the oil away from the coast. However, the details of the evolution of the storm, the track, the wind speed, the size, the forward motion and the intensity are all unknowns at this point and may alter this general statement.
Evaporation from the sea surface fuels tropical storms and hurricanes. Over relatively calm water (such as for a developing tropical depression or disturbance), in theory, an oil slick could suppress evaporation if the layer is thick enough, by not allowing contact of the water to the air. With less evaporation one might assume there would be less moisture available to fuel the hurricane and thus reduce its strength. However, except for immediately near the source, the slick is very patchy. At moderate wind speeds, such as those found in approaching tropical storms and hurricanes, a thin layer of oil such as is the case with the current slick (except in very limited areas near the well) would likely break into pools on the surface or mix as drops in the upper layers of the ocean. (The heaviest surface slicks, however, could re-coalesce at the surface after the storm passes.) This would allow much of the water to remain in touch with the overlying air and greatly reduce any effect the oil may have on evaporation. Therefore, the oil slick is not likely to have a significant impact on the hurricane.
All of the sampling to date shows that except near the leaking well, the subsurface dispersed oil is in parts per million levels or less. The hurricane will mix the waters of the Gulf and disperse the oil even further.
The experience from hurricanes Katrina and Rita (2005) was that oil released during the storms became very widely dispersed.
Besides NOAA, other sources say that storms disperse and/or bury oil already on the beach. Tar balls are common on Galveston Island beaches but less so after a storm. The Marshes should fare the same way. If anything, hurricanes have a tendency to leave beaches cleaner than they found them.