NASA’s AIRS instrument tracked a record-breaking heat wave as it
intensified in the Pacific Northwest last June. AIRS remains a vital resource
for weather forecasting, and 20 years after launch it has also become a
resource for understanding the role of climate change in weather events like
this. Credits: NASA/JPL-Caltech
The Atmospheric Infrared Sounder helps researchers predict weather, analyze
air pollution, monitor volcanoes, and track a changing climate. And there’s
more.
On April 13, a blizzard dropped 4 feet of snow on Minot, North Dakota, as a
drought-fueled wildfire burned in Ruidoso, New Mexico, and severe storms
spawned eight tornadoes in Kentucky. NASA’s Atmospheric Infrared Sounder (AIRS) helped weather forecasters predict these events, as it’s been
doing since it was launched in 2002. But now AIRS also helps researchers
calculate the role climate change plays in these extreme weather events. It has
become indispensable in other ways that couldn’t be foreseen when the weather
instrument launched aboard NASA’s Aqua satellite in May 2002.
“Understanding what happened in the first couple of decades of the 21st
century is critical to understanding climate change, and there’s no better
record than AIRS to study that,” said Joao Teixeira, AIRS science team leader
at NASA’s Jet Propulsion Laboratory in Southern California. “I see us as
guardians of this precious dataset that will be our legacy for future
generations.”
AIRS measures infrared – heat – radiation from the air below the satellite
to create three-dimensional maps of atmospheric temperature and water vapor,
the main ingredients for any kind of weather. The instrument proved to be an
almost immediate success: Within three years after AIRS’ launch, assessments of
forecasts made by professional meteorologists showed that incorporating AIRS
data in weather forecasting models produced a significant increase in accuracy.
Launched in 2002 aboard NASA’s Aqua satellite, AIRS creates 3D maps of air
and surface temperature, water vapor, and cloud properties. Its data forms a
“fingerprint” of the state of the atmosphere for a given time and place, contributing
to climate data for future generations. Credits: NASA/JPL-Caltech
Looking Beyond Weather
The AIRS instrument is a spectrometer that breaks radiation into
wavelengths, just as a prism does. But where earlier spectrometers in space had
15 or 20 detectors that each observed broad bands of infrared wavelengths, AIRS
has 2,378 detectors that each senses a specific wavelength, and every detector
makes close to 3 million measurements a day. This enormous advance in data
quality and quantity not only succeeded in improving weather forecasting, but
inspired a new generation of similar spaceborne instruments from space agencies
around the world.
In 2002, getting this technology ready to launch required an innovative
design and skillful construction to accommodate the thousands of detectors. The
instrument’s creators eventually arranged the detectors in 17 long lines, each
of them two detectors wide (for redundancy in case one failed) by about 150
detectors long, and packaged them onto a single focal plane assembly. “When I
first saw it, I said, ‘You’ve got to be kidding me,’” said Tom Pagano, AIRS’
project manager at JPL. “It was a major engineering achievement for the time.”
Other advances, like the development of a frictionless cryocooler to cool AIRS’
detectors, led to an instrument that has lasted an extremely long time and is
extraordinarily stable.
“Due to the amazing engineering, the data we have now is almost the same
quality as it was 20 years ago, when the instrument was new,” Teixeira said.
Stability is essential for scientists to pinpoint the small but persistent
signals of climate change from out of the noise of year-to-year variations in
weather. As the global temperature creeps upward toward 1.5 degrees Celsius
higher than pre-industrial times, AIRS’ two decades of consistent and
multifaceted measurements provide a satellite record of global warming that is
second to none. There are other satellite records of individual greenhouse
gases or of surface temperature, for example, but no other global data record
matches the time span and wide range of wavelengths in the AIRS dataset.
Legacy Building
When AIRS launched, the mission team aspired to collect data for 15 years,
said Pagano. “We put an unimaginable amount of effort into making an instrument
that wouldn’t fail in orbit. It was the philosophy of how we built these
instruments on the Aqua satellite.”
And as the data has kept coming, researchers have found more and more uses
for it. Researchers recently used AIRS data to detect atmospheric waves from
the eruption of the Hunga Tonga-Hunga
Ha’apai volcano. Earlier this year, researchers also used
AIRS data to quantify the link between humidity and influenza
outbreaks. In addition, AIRS data is used to track clouds,
carbon dioxide, methane, ozone, and other gases and pollutants whose spectral
signatures fall within the range of infrared wavelengths AIRS detects.
The AIRS team and other researchers are still looking into even more
applications of the dataset. “There’s more to mine from this instrument,”
Pagano said. “It has such rich information content.”
No comments:
Post a Comment