"We can demonstrate that during the last glacial period, the water column in the area of the seasonal sea-ice zone was more mixed in autumn and winter than previously thought," says Dr Andrea Abelmann, from the Alfred Wegener Institute. The marine geologist and first author of the study explains, "Only in the short southern spring and summer, for just a few months in the year, was there a marked stratification at the ocean's surface. Up until now, researchers assumed that during the last glacial period there was a layer of freshwater -- created by melting icebergs -- that sat on the ocean like a lid all year round.
Such a lid would have greatly reduced the supply of nutrients from the ocean's depths to the surface leading to low biological production. However, the new findings show that in the last glacial period in the seasonal sea-ice zone, which was twice as large as it is today, the water was well mixed to a depth of a few hundred metres. This allowed nutrients to reach the surface from deeper levels. In addition, melting ice in spring released the trace element iron, which had been transported with dust from South America. This created ideal conditions for microscopic, exoskeleton algae (diatoms): they were able to effectively utilise the nutrients to bind carbon during photosynthesis and so store CO2. When they died, these phytoplankton sank to the ocean floor thousands of metres below. In this process, also known as the biological pump, atmospheric CO2
For their study, the researchers used newly developed methods to reconstruct sedimentary deposits from the Atlantic section of the Southern Ocean. They compared isotope measurements on the silica skeletons of diatoms, which store environmental signals from the ocean's surface, with isotope signals from radiolarians, which live in deeper water layers. They then compared the findings from different ocean depths with results from climate models simulations to identify seasonal changes. This enabled the research team to reconstruct, for the first time, a detailed picture of the environmental conditions at the ocean's surface, as well as in deeper water layers, over the last 30,000 years.
"Our findings show that changes in the ecosystem in the area of the seasonal sea-ice zone in the Southern Ocean contributed to CO2
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Journal Reference:
- Andrea Abelmann, Rainer Gersonde, Gregor Knorr, Xu Zhang, Bernhard Chapligin, Edith Maier, Oliver Esper, Hans Friedrichsen, Gerrit Lohmann, Hanno Meyer, Ralf Tiedemann.
The seasonal sea-ice zone in the glacial Southern Ocean as a carbon sink. Nature Communications, 2015; 6: 8136 DOI: 10.1038/ncomms9136
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