About 15 percent of the world’s tropical cyclones occur in the
northern Indian Ocean, but because of high population densities along low-lying coastlines, the storms have caused nearly 80 percent of cyclone-related deaths around the world. Incomplete
atmospheric data for the
Bay of Bengal and
Arabian Sea make it difficult for regional forecasters to provide enough warning for mass evacuations.
In the wake of last year’s Cyclone Nargis -- one of the most catastrophic cyclones on record -- a team of
NASA researchers re-examined the storm as a test case for a new data integration and mathematical modeling approach. They compiled satellite data from the days leading up to the May 2 landfall of the storm and successfully "
hindcasted" Nargis' path and landfall in Burma.
"
Hindcasting" means that the modelers plotted the precise course of the storm. In addition, the retrospective results showed how forecasters might now be able to produce multi-day advance warnings in the
Indian Ocean and improve advance forecasts in other parts of the world. Results from their study were published March 26 in
Geophysical Research Letters.
"There is no event in nature that causes a greater loss of life than
Northern Indian Ocean cyclones, so we have a strong motivation to improve advance warnings," said the study’s lead author,
Oreste Reale, an atmospheric scientist with the
Goddard Earth Sciences and Technology Center, a partnership between
NASA and the University of Maryland-Baltimore County.
In late
April 2008, weather forecasters tracking cyclone Nargis initially predicted the storm would make landfall in Bangladesh. But the storm veered unexpectedly to the east and intensified from a category 1 storm to a category 4 in just 24 hours. When it made landfall in Burma (Myanmar) on May 2, the storm and its surge killed more than 135,000 people, displaced tens of thousands, and destroyed about $12 billion in property.
In the months that followed, Reale and his U.S.-based team tested the
NASA-created Data Assimilation and Forecasting System known as
GEOS-5 and its
NASA/NOAA-created analysis technique using data from the days leading up to
Nargis because the storm was particularly fatal and highly characteristic of cyclones in the
northern Indian Ocean.
Cyclones in the Bay of Bengal – stretching from the southern tip of India to Thailand – are particularly difficult to analyze because of "
blind spots" in available
atmospheric data for individual storms, as well as the small dimensions of the Bay, which ensure that storms do not have much time to develop or circulate. In most instances, regionally strong wind shear suppresses cyclone development.
But when tropical cyclones do form, flooding waves and storm surges can quickly reach the narrow basin’s shores. And that unusual wind shear, which is fueled by large temperature contrasts between sea and land, can also lead to erratic storm tracks.
Forecasting is also made particularly difficult by the "
blind spots," Reale noted. Land-based weather
stations monitor the edges of the bay, but they cannot see much when a storm is brewing several hundred miles from the coastline.
Forecasters from the India Meteorological Department and the U.S. Navy’s Joint Typhoon Warning Center lack access to the fleet of "
hurricane hunting" airplanes that fly through Atlantic storms. They have to rely on remote satellite measurements that can only assess atmospheric and ocean temperatures under "
clear-sky," or cloudless, conditions -- not exactly common in the midst of a
cyclone.
In their modeling experiment, Reale’s team detected and tracked Nargis’ path by employing novel 3-dimensional satellite imagery and atmospheric profiles from the
Atmospheric Infrared Sounder (
AIRS) instrument aboard
NASA’s Aqua satellite to see into the heart of the storm.
AIRS has become increasingly important to weather forecasting because of its ability to show changes in atmospheric temperature and moisture at varying altitudes. Until recently, many weather modelers were only using
AIRS data from cloud-free skies.
In 2007,
atmospheric scientist Joel Susskind of
NASA Goddard Space Flight Center, Greenbelt, Md., successfully demonstrated through a technique developed by
NASA research scientist Moustafa Chahine that accurate atmospheric temperatures could be obtained using real (versus hypothetical data in a 2003 Susskind study)
AIRS partly-cloudy data. Reale’s team used the temperature data products from Susskind’s work to run the NASA model with the added information from partially-cloudy areas of sky that traditionally got left out.
AIRS cloudy-sky data can now be integrated into what are called shared data assimilation systems, which combine millions of data points from
Earth-observing satellites, instrumented ocean buoys, ground-based sensors, aircraft-based instruments, and man-on-the-scene observations. Data assimilation transforms the data into digital local maps that models can "
read" to produce either hindcasts or advance projections of future weather conditions.
Lau, chief of
Goddard’s Laboratory for Atmospheres, believes that regional forecasting agencies monitoring the region can readily access
AIRS’ data daily and optimize forecasts for cyclones in the
Indian Ocean. According to Lau, the same technique can be useful to forecasts of
hurricanes in the Atlantic and typhoons in the western Pacific, particularly when the storm is formed over open oceans out of flight range of hurricane-hunting airplanes.
"With this approach, we can now better define cyclones at the early stages and track them in the models to know what populations may be most at risk," explained
Reale. "And every 12 hours we gain in these forecasts means a gain in our chances to reduce loss of life."
Related Links:> NASA's Hurricane/Tropical Cyclone Web Site> NASA’s AIRS Instrument> Images of Cyclone Nargis from Space> How Do Tropical Cyclones Form?> NASA Study Finds 'Pre-Existing Condition' Fueled Killer Cyclone
To commemorate the Hubble Space Telescope's 19 years of historic, trailblazing science, the orbiting telescope has photographed a peculiar system of galaxies known as Arp 194. This interacting group contains several galaxies, along with a "cosmic fountain" of stars, gas, and dust that stretches over 100,000 light-years.
