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UCL Home  /  Geography  /  News & Events  /  News  /  News Archive  /  August 2015  /  Heat release from stagnant deep sea helped end last Ice Age

Heat release from stagnant deep sea helped end last Ice Age

New research led by David Thornalley published in Science

Heat release from stagnant deep sea helped end last Ice Age

The build-up and subsequent release of warm, stagnant water from the deep Arctic Ocean and Nordic Seas played a role in ending the last Ice Age within the Arctic region, according to new research led by Dr David Thornalley (UCL Geography).

The study, published in Science on 14 August, examined how the circulation of the ocean north of Iceland – the combined Arctic Ocean and Nordic Seas, called the “Arctic Mediterranean” – changed after the end of the last Ice Age (~20,000-30,000 years ago).

Today, the ocean is cooled by the atmosphere during winter, producing large volumes of dense water that sink and flush through the deep waters. However, in contrast to this vigorous modern circulation, the research found that, during the last Ice Age, the Arctic Mediterranean became like a giant stagnant pond, with deep waters not being replenished for up to 10,000 years.

This is thought to have been caused by the thick and extensive layer of sea ice and fresh water that covered much of the Arctic Mediterranean, preventing the atmosphere from cooling and densifying the underlying ocean.

David explains: “As well as being stagnant, these deep waters were also warm. Sitting around at the bottom of the ocean, they slowly accumulated geothermal heat from the seafloor, until a critical point was reached when the ocean became unstable.”

“Suddenly, the heat previously stored in the deep Arctic Mediterranean was released to the upper ocean. The timing of this event coincides with the occurrence of evidence for a massive release of meltwater into the Nordic Seas. We hypothesize that this input of melt water was caused by the release of deep ocean heat, which melted icebergs, sea-ice and surrounding marine-terminating ice sheets.”

The study highlights the important impact that changes in ocean circulation can have on climate, due to the ocean’s capacity to redistribute vast quantities of heat around the globe. For example, scientists are currently concerned that ongoing changes in ocean circulation may result in warmer subsurface water, causing enhanced melting and retreat of certain ice sheets in Greenland and Antarctica.

In this study, researchers from UCL, Woods Hole Oceanographic Institute and other partner institutions analysed the composition of calcite shells of small single-celled organisms (called foraminifera) found in ocean floor sediment. These record the chemistry of the deep ocean at the time they were living, enabling the researchers to reconstruct past changes in ocean circulation.

 

See:

Thornalley, D.J.R., Bauch, H.A., Gebbie, G., Guo, W., Zielger, M., Barker, S & Skinner, L. (2015). A warm and poorly ventilated deep Arctic Mediterranean during the last glacial period. Science, 349, 706-710.

 

For “Arctic Mediterranean”, see also: http://www.eoearth.org/view/article/150193/


Image

Changes in Arctic Mediterranean at end of Ice Age


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