What Lies Beneath A Hurricane
What Lies Beneath a Hurricane
Two orbiting NASA satellites are giving scientists
an unprecedented view of what goes on beneath the obscuring cloud
tops of great swirling storms.
Sept. 11, 2000 -- As this year's Atlantic hurricane season reaches its peak, scientists are using two orbiting research satellites to peer into the hearts of storms in ways that were never before possible. Unlike most weather satellites that can only take pictures of a hurricane's cloud tops, NASA's QuikScat and Tropical Rainfall Measurement Mission (TRMM) satellites carry microwave sensors that can "see" through the clouds and scrutinize conditions -- including rainfall, wind and water temperature -- at the ocean's surface. These new data could allow researchers to detect tropical depressions earlier and to predict where hurricanes are headed with greater accuracy.
Right: This satellite image of Hurricane Alberto churning across the northern Atlantic Ocean was captured by the OrbView-2 satellite on August 21, 2000. NASA's QuikScat and TRMM missions are beginning to show scientists what's underneath the obscuring clouds of these great storms. [more information]
"I think the rain and the wind together is a very powerful tool to study hurricanes," said Dr. Timothy Liu, project scientist for the QuikScat mission at NASA's Jet Propulsion Laboratory.
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Other radar-based satellites can measure wind speed, Liu said, but "the only thing that can measure the wind vector -- that is, the speed and the direction together -- is the scatterometer."
A scatterometer works by sending a beam of microwave radiation toward the ocean surface at an angle. The beam, which passes undisturbed through clouds, gets scattered by the ocean surface, and some of the microwaves bounce back toward the satellite. A rougher ocean surface, which indicates higher winds, will reflect more radiation back toward the satellite than a smooth surface will.
Below: A snapshot of the speed and direction of ocean surface winds taken by QuikScat. Pink and yellow represent high velocity winds, and purple and blue represent slower winds. The white lines and arrows indicate direction. Courtesy JPL. [more information]
Part of the reason for this, Liu said, is that the satellite photographs used by the National Hurricane Center show only the cloud tops of forming hurricanes, which sometimes can be obscured from view by higher clouds.
Another key to understanding and predicting hurricanes is rainfall. Rainfall snapshots are produced by the TRMM (Tropical Rainfall Measuring Mission) satellite, which is a joint mission between NASA and the National Space Development Agency (NASDA) of Japan.
"The big impact that the rainfall data can have is that the rainfall in these tropical storms are signatures of the amount of latent heat that's being released into the atmosphere," said Dr. Marshall Shepherd, a research meteorologist at NASA's Goddard Space Flight Center.
Incorporating rainfall data from TRMM into computer weather models "gives the model a better handle on the energetics that are required to drive the circulation, to drive the hurricane and also affect its path," Shepherd said.
Left: An image of Typhoon Bilis, which recently struck Taiwan and China, combining wind data from QuikScat and rainfall data from TRMM. The background color represents rainfall levels, and the red arrows indicate wind speed and direction. An image like this provides a useful snapshot of the typhoon for scientists. Courtesy JPL.
The TRMM satellite can also use its microwave sensors to measure ocean surface temperatures beneath a hurricane.
"Hurricanes are intimately tied to the sea surface temperature," Shepherd said. "There's generally kind of a threshold temperature (above which) hurricanes like to form. If you have all of the other a priori conditions in place, and if you have ample warm sea surface temperature and moisture, then you can get a hurricane that likes to grow," Shepherd said.
Higher sea surface temperatures mean more evaporation of ocean water into the air. As that moisture condenses into clouds, it releases heat to the air that causes the air to rise. The rising air creates a low pressure area beneath it that pulls the surrounding air spiraling inward, perpetuating the hurricane.
"It's that conversion of latent heating that's carried from the water vapor when it condenses to form the clouds in the hurricane -- that's really the fuel supply that powers the hurricane engine,'" Shepherd said. "We tend to think of hurricanes as big heat engines."
Low sea surface temperatures can spell death for a hurricane, as in 1998 when the "wake" of cold water behind Hurricane Bonnie caused Hurricane Danielle, which was following close behind, to dissipate.
Left: TRMM Microwave Imager (TMI) sea-surface temperatures from August 22 - Sept. 23, 1998. Blues represent cooler water, greens and yellows are warmer water. A translucent map of clouds photographed by a NOAA GOES satellite is overlaid on the map to show Hurricane Bonnie approaching the Carolina Coast (upper left) and Hurricane Danielle following roughly in its path (lower right). TMI is the first satellite microwave sensor capable of accurately measuring sea surface temperature through clouds.
Traditional weather satellites that use infrared sensors can also measure sea surface temperature, but "the big advantage that the TRMM microwave imager has ... is that microwave instruments can see through clouds, whereas infrared instruments (on traditional weather satellites) can only give you sea surface temperatures in clear regions," Shepherd said.
While the kind of rainfall and sea surface temperature data
produced by TRMM holds great potential for improving hurricane
forecasting, TRMM is not primarily a hurricane-monitoring satellite.
"Things like hurricane monitoring ... are extra benefits of the satellite, but its main mission is to measure rainfall," Shepherd said. "TRMM is a research mission -- it wasn't designed to be used in an operational setting.
"But where (the data) can be used, I'm sure it is ...."
Images of Earth by QuikScat - A catalog of images produced by QuikScat and TRMM, including short descriptions.
TRMM home page - The home page of the Tropical Rainfall Measuring Mission.
TRMM archive - An archive of images and movies from the TRMM satellite.
Scatterometry overview - A brief tutorial on scatterometry and its use on QuikScat for measuring ocean surface winds.
Seaflux - Near real-time images of global ocean surface winds from the QuikScat satellite.
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