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The Southern Ocean
may slow the
rate of global warming by absorbing significantly more heat and carbon
dioxide
than previously thought, according to new research. The Southern
Hemisphere westerly
winds have moved southward in the last 30 years. A new climate model
predicts
that as the winds shift south, they can do a better job of transferring
heat
and carbon dioxide from the surface waters surrounding The new finding
surprised the
scientists, said lead researcher Joellen L. Russell. "We think it will
slow global warming. It won't reverse or stop it, but it will slow the
rate of
increase." The new model
Russell and her
colleagues developed provides a realistic simulation of the Southern
Hemisphere
westerlies and Southern Ocean circulation. Previous climate
models did not
have the winds properly located. In simulations of present-day climate,
those
models distorted the ocean's response to future increases in greenhouse
gases. "Because these winds
have
moved poleward, the Southern Ocean around Antarctica is likely to take
up 20
percent more carbon dioxide than in a model where the winds are poorly
located," said Russell, an assistant professor of geosciences at The
University of Arizona in “More heat
stored in the ocean
means less heat stored in the atmosphere. That's also true for carbon
dioxide,
the major greenhouse gas." "But there are
consequences," Russell said. "This isn't an unqualified good, even if
more carbon dioxide and heat goes into the ocean." As the atmosphere
warms, storing
more heat in the ocean will cause sea levels to rise even faster as the
warmed
water expands, she said. Adding more [CO2] to the oceans will change
their
chemistry, making the water more acidic and less habitable for some
marine
organisms. Russell and her
colleagues
conducted the study while she was a researcher at Her co-authors on
the article,
"The Southern Hemisphere Westerlies in a Warming World: Propping open
the
Door to the Deep Ocean,” are GFDL researchers Keith W. Dixon,
Anand
Gnanadesikan, Ronald J. Stouffer and J.R. Toggweiler. The article will
be
published in the December 15 issue of the Journal of Climate. NOAA
funded the
work. The researchers
characterize the
Southern Ocean as "the crossroads of the global ocean's water masses,
connecting the The current set of
computer
models that scientists use to predict future climate differ in the
degree to
which heat is sequestered by the Southern Ocean. The models vary in how
they
represent the behavior of the Southern Hemisphere westerlies and the
Antarctic
Circumpolar Current, the largest current on the planet. The team's model
does a better
job of depicting the location and observed southward shift of the
Southern
Hemisphere atmospheric winds than do previous global climate
circulation
models. The new model developed at GFDL shows that the poleward shift
of the
westerlies intensifies the strength of the winds as they whip past the
tip of
South America and circumnavigate "It's like a huge
blender," Russell said as she held up a globe and demonstrated how the
winds whirl around the southernmost continent. Those winds, she said,
propel
the Antarctic Circumpolar Current. The current drives the upwelling of
cold
water from more than two miles deep. The heavy, cold water comes to the
surface
and then sinks back down, carrying the carbon dioxide and heat with it.
The new model
forecasts this
shift in the winds will continue into the future as greenhouse gases
increase. Stouffer said,
“The poleward
intensification of the westerlies will allow the ocean to remove
additional
heat and anthropogenic carbon dioxide from the atmosphere. Thus, the
deep ocean
has the potential to slow the atmospheric warming through the increased
storage
of heat and carbon.” The team's next step
will be
figuring out how warming, ice-melt and ongoing shifts in the Southern
Hemisphere westerlies will affect the biogeochemistry of the Southern
Ocean and
the global budgets for heat and carbon dioxide.
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