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Deep
ocean current may slow due to climate change
21
March, 2014
Far
beneath the surface of the ocean, deep currents act as conveyer
belts, channeling heat, carbon, oxygen and nutrients around the
globe.
A
new study by the University of Pennsylvania's Irina Marinov and
Raffaele Bernardello and colleagues from McGill University has found
that recent climate change may be acting to slow down one of these
conveyer belts, with potentially serious consequences for the future
of the planet's climate.
"Our
observations are showing us that there is less formation of these
deep waters near Antarctica," Marinov said. "This is
worrisome because, if this is the case, we're likely going to see
less uptake of human produced, or anthropogenic, heat and carbon
dioxide by the ocean, making this a positive feedback loop for
climate change."
Marinov
is an assistant professor in Penn's School of Arts and Sciences'
Department of Earth and Environmental Science, while Bernardello was
a postdoctoral investigator in the same department and has just moved
to the National Oceanography Centre in the United Kingdom. They
collaborated with Casimir de Lavergne, Jaime B. Palter and Eric D.
Galbraith of McGill University on the study, which was published
in Nature Climate Change.
Oceanographers
have noticed that Antarctic Bottom Waters, a massive current of cold,
salty and dense water that flows 2,000 meters under the ocean's
surface from near the Antarctic coast toward the equator has been
shrinking in recent decades. This is cause for concern, as the
current is believed to "hide" heat and carbon from the
atmosphere. The Southern Ocean takes up approximately 60 percent of
the anthropogenic heat produced on Earth and 40 to 50 percent of the
anthropogenic carbon dioxide.
"The
Southern Ocean is emerging as being very, very important for
regulating climate," Marinov said.
Along
with colleagues, Marinov used models to discern whether the shrinking
of the Antarctic Bottom Waters could be attributed to anthropogenic
climate change.
They
looked to an unusual phenomenon that had been observed from satellite
images taken between 1974 and 1976. The images revealed a large
ice-free area within the Weddell Sea. Called a polynya, this opening
in the sea ice forms when warm water of North Atlantic origin is
pushed up toward the Southern Ocean's surface. In a separate process,
brine released during the sea-ice formation process produces a
reservoir of cold, salty waters at the surface of the Weddell Sea.
Because this situation is not stable, the heavy surface waters mix
with the warmer, lighter waters underneath in a process called
open-sea convection.
Polynyas
were not observed again in the Weddell Sea after 1976, leading
researchers to believe they –- and hence open-sea convection -–
were rare events.
In
the new study, however, the team suggests that polynyas were likely
more common in the pre-industrial era, before anthropogenic climate
change took hold.
The
reason has to do with the fact that climate change has led to more
precipitation around the Antarctic continent, which leads to greater
levels of fresh water at the surface. Fresh water is more buoyant
than saltwater and thus doesn't sink through the layers of the ocean
as saltier water does, leading to fewer polynyas and less open-sea
convection in the Southern Ocean.
"This
is important because this process of deep convection that happens in
polynyas is a big contribution to the Antarctic Bottom Waters, these
deep currents that feed the rest of the ocean," Marinov noted.
Examining
20,000 data points, the researchers showed that the Southern Ocean
surface has freshened during the last 60 years. They also found that
vertical gradients of salinity and density have increased in the
Southern Ocean, suggesting that mixing has been reduced.
Using
the latest generation of climate models, 36 finely tuned and complex
models that simulate climate change patterns, they found that, in
most of the models, convective events, such as the polynyas captured
by satellite images in the 1970s, were much more common in
pre-industrial conditions, before anthropogenic climate change took
hold.
"We
see that the convective process is shutting down as the water gets
fresher and fresher," Marinov said.
Seven
of the models suggest that increased fresh water in the Southern
Ocean could stop the convection from occurring altogether by 2030,
and most models show strong decreases in convection during the 21st
century, reducing the Antarctic Bottom Waters' formation.
This
has implications for current and future climate change, the
researchers said. The absence of polynyas in recent decades could
mean that heat is getting trapped in the deeper ocean, possibly
contributing to the recent "hiatus" in global atmospheric
warming and the increase in Antarctic sea ice extent that have been
observed in recent years.
But
overall, Marinov said, "the slow down of polynyas will likely be
a positive feedback on warming, as the convective process is shutting
down and reducing the amount of new, anthropogenic carbon and heat
being taken out of the atmosphere. We are pursuing these implications
in our current work."
In
a related paper, published this month in the Journal of
Climate, Bernardello, Marinov and colleagues examine how the
ocean's natural ability to store carbon might respond as the climate
warms.
The
ocean contains about 50 times more carbon than the atmosphere, making
it a crucial but sometimes overlooked player in climate change
regulation.
This
ability, Marinov noted, stems in large part because of tiny organisms
called phytoplankton that live near the ocean's surface.
"They
are all microscopic so we don't see them, but they are mighty,"
Marinov said. "They account for 50 percent of the photosynthesis
that occurs on the planet."
I
n
conducting photosynthesis, the phytoplankton take up carbon, which is
then passed down through the deep ocean layers as these organisms and
the organisms that eat them die and decompose. If it were not for
this process, atmospheric carbon dioxide levels would be about 200
parts per million higher than the currently observed 400 ppm.
The
Penn-led team considered how wind, temperature and salinity may
change during the 21st century and how these phenomena affect the
natural ability of the ocean to store carbon.
Running
climate simulations into the future, their findings suggest that the
phytoplankton-driven biological carbon pump will strengthen, leading
to increased carbon storage in the ocean. Yet this effect is not
enough to outweigh the fact that a warmer ocean will not be able to
hold onto as much carbon
dioxide gas.
"Gases
are more soluble in colder liquids," Marinov said. "With
climate change we predict that the ocean will lose some of its deep,
natural carbon in the future, partly because the temperature warming
effect is so strong."
Looking
ahead, Marinov plans to add to this complex picture of the ocean's
role inclimate
change.
She will participate in an effort to increase sampling from remote
parts of the Southern Ocean, blending physical, biological and
chemical analyses with further modeling.
"More
and more, people interested in ocean and
climate sciences must also be interested in interdisciplinarity, in
linking physics, biology, chemistry in the global climate context,"
she said.
More
information: "Cessation
of deep convection in the open Southern Ocean under anthropogenic
climate change." Casimir de Lavergne, et al. Nature
Climate Change(2014)
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