Just as waves ripple across a pond when a tossed stone disturbs the
water's surface, gravity waves ripple toward space from disturbances in
the lower atmosphere.
Gravity waves are born when air masses are pushed up or down -- by a
thunderstorm, perhaps, or when wind is forced up and over a mountain
range -- but in the lower atmosphere, their impacts usually remain
regional. By the time they reach the upper atmosphere, however, the
waves have built in amplitude and extent. There, they can dominate
atmospheric processes on a much larger scale, sometimes threatening the
reliability of Earth-based communication systems.
For the first time, scientists have found a way to "watch" the
propagation of gravity waves toward space -- and the view is
captivating. The trick, according to a team of researchers led by NCAR
Senior Scientist Hanli Liu, was to push the NCAR-based Whole Atmosphere
Community Climate Model to a resolution that is fine enough to pick up
gravity waves at their source, when they're still relatively small.
"We've never seen a global picture of gravity waves in the upper
atmosphere before, either from observations or simulations, even though
we have suspected their importance up there," said Liu, who studies the
upper atmosphere at NCAR's High Altitude Observatory. "This is the first
time we have been able to capture these waves with a computer model of
the whole atmosphere."
The standard version of the model gets only a blurry look at
phenomena that take place on scales less than 2,000 km (about 1,243
miles) across -- and it's blind to anything smaller than 200 km. The
higher-resolution model has much sharper vision all the way down to 200
km. The intense computing power of the NCAR-Wyoming Supercomputing
Center's Yellowstone system made the higher-resolution runs possible.
In a study published in the journal Geophysical Research Letters,
Liu and his colleagues demonstrated the finer-scaled model's abilities
by showing how gravity waves such as those created by a tropical cyclone
east of Australia grew as they traveled upwards. The model shows that
what starts out as a localized phenomenon extends across the entire
Pacific Region at 100 km above Earth's surface.
"For the middle and lower atmosphere, if you miss the gravity wave,
you're not missing too much," Liu said. "But it's a different story in
the upper atmosphere."
Disturbances in the upper atmosphere -- which can endanger
satellites, skew GPS readings, and shut down radio transmissions -- are
often thought about as originating from the Sun, where solar storms can
kick off geomagnetic storms around Earth. But the ionosphere, the upper
reaches of the atmosphere affected by this kind of space weather, is
also influenced by disturbances originating on Earth.
These Earth-born disturbances can be difficult for scientists to
disentangle when solar storm activity is strong, but the relative
tranquility of the Sun during the last solar cycle has given scientists
an opportunity to home in on the disturbances reaching the ionosphere
from below, creating a fuller picture of processes in the ionosphere.
"When gravity waves propagate to the bottom side of the ionosphere,
they can kick off instabilities," Liu said. "If you want to have a
better understanding of space weather -- the ionosphere -- you need this
kind of modeling capability.
This is taken from Science Daily
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