The
Deep Greenland Sea Is Warming Faster Than the World Ocean
Increase
of water temperature in the deep Greenland Sea. Mean temperature (°C)
from 2000 m to the bottom in the central Greenland Sea (74-76°N,
0-6°W) from 1950 to 2009 (red line). The shading shows the range of
temperature from 2000 m (warmer limit) to the bottom (colder limit).
(Credit: Alfred-Wegener-Institut)
25
September, 2013
Sep.
25, 2013 — Recent warming of the Greenland Sea Deep Water is about
ten times higher than warming rates estimated for the global ocean.
Scientists from the Alfred Wegener Institute, Helmholtz Centre for
Polar and Marine Research recently published these findings in the
journal Geophysical Research Letters. For their study, they analysed
temperature data from 1950 to 2010 in the abyssal Greenland Sea,
which is an ocean area located just to the south of the Arctic Ocean.
Since
1993, oceanographers from the Alfred Wegener Institute, Helmholtz
Centre for Polar and Marine Research (AWI), have carried out
regularly expeditions to the Greenland Sea on board the research ice
breaker Polarstern to investigate the changes in this region. The
programme has always included extensive temperature and salinity
measurements. For the present study, the AWI scientists have combined
these long term data set with historical observations dating back to
the year 1950. The result of their analysis: In the last thirty
years, the water temperature between 2000 metres depth and the sea
floor has risen by 0.3 degrees centigrade.
'This
sounds like a small number, but we need to see this in relation to
the large mass of water that has been warmed' says the AWI scientist
and lead author of the study, Dr. Raquel Somavilla Cabrillo. 'The
amount of heat accumulated within the lowest 1.5 kilometres in the
abyssal Greenland Sea would warm the atmosphere above Europe by 4
degrees centigrade. The Greenland Sea is just a small part of the
global ocean. However, the observed increase of 0.3 degrees in the
deep Greenland Sea is ten times higher than the temperature increase
in the global ocean on average. For this reason, this area and the
remaining less studied polar oceans need to be taken into
consideration'.
The
cause of the warming is a change in the subtle interplay of two
processes in the Greenland Sea: the cooling by deep convection of
very cold surface waters in winter and the warming by the import of
relatively warm deep waters from the interior Arctic Ocean. "Until
the early 1980s, the central Greenland Sea has been mixed from the
top to the bottom by winter cooling at the surface making waters
dense enough to reach the sea floor" explains Somavilla. "This
transfer of cold water from the top to the bottom has not occurred in
the last 30 years. However, relatively warm water continues to flow
from the deep Arctic Ocean into the Greenland Sea. Cooling from above
and warming through inflow are no longer balanced, and thus the
Greenland Sea is progressively becoming warmer and warmer."
These
modified conditions provide AWI scientists with unique research
opportunities: "We use these changes as a natural experiment.
The warming allows us to calculate how much water flows from the deep
central Arctic into the Greenland Sea" says Prof. Dr. Ursula
Schauer, head of the Observational Oceanography Department at the
Alfred Wegener Institute, about this project and adds: "We
observe here a distinct restructuring of the Arctic Ocean. This is a
very slow process, and its documentation requires long term
observations."
To
fully understand, how the world's oceans react to climate change,
scientists need to investigate the Arctic Ocean in more detail. 'Due
to its large volume and its thermal inertia the deep ocean is a
powerful heat buffer for climate warming. Especially, the polar
oceans are scarcely studied. If we want to understand the role of the
deep ocean in the climate system, we need to expand the measurements
to remote regions like the Arctic," AWI-scientist Schauer says.
For that, she has already planned further Polarstern expeditions. In
2015, Ursula Schauer and her group will go back to the Arctic.
Glossary:
Why are the deep waters from the interior Arctic Ocean warm?
The
mean temperature of the deep water masses from the interior Arctic
Ocean is -0.9 degrees centigrade. That is much warmer than the
surface waters of the Greenland Sea, which cool down to -1.8 degrees
in winter. However, where does the warmth of the deep Arctic waters
come from? It is the result of a long chain reaction, happening in
the shallow seas on the edge of the Arctic Ocean -- right there,
where in winter sea ice formation takes place. When the sea ice is
formed the salt, which is present in the water, does not get
enclosed. It leaves the ice instead and increases the salinity and
density of the water layer below the ice.
Due
to their rising density these waters get heavier and start sinking.
One can compare this sinking process of the water masses with a
snowball falling down a freshly snow-covered slope. The longer the
snowball rolls, the more snow get attached to its body. That means,
while rolling down the Arctic shelf, the salty sinking water masses
come across a layer of warm Atlantic water. They take part of the
heat and salt in this Atlantic layer and transport it to deeper
levels in the Arctic Ocean. At the bottom of the Arctic Ocean these
sinking water masses form a body of warm deep water that later on
streams out of the Arctic Ocean into the Greenland Sea.
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