“Greenland’s margin has many outlet glaciers that act as fast conveyor belts of ice. Thousands of surface lakes act as taps that deliver meltwater to the ice base, turning it into a slippery bathtub. Because it is difficult to see beneath them we surmised until recently that the glaciers slip over hard rock, but we realise now that they often slip over sloppy wet sediments instead. In a warming Arctic climate more ice will melt and make the sediments even sloppier and more slippery, so that fast ice flow can occur long into the future. This discovery leaves us concerned because we have so far accepted the exact opposite – that Greenland’s icy conveyor would slow down.” Professor Bernd Kulessa of the College of Science at Swansea University, lead researcher
Researchers at Swansea University and Norway, Sweden, UK and Canada found that Greenland’s glaciers are likely to speed up ice flow to the oceans. The seismic surveys concluded that the ice streams are not sliding over hard rock, as previously thought, but over sediment. As the earth’s fever continues to rise, more and more meltwater will be delivered to the base of the glacier via moulins and cracks in the ice. The sediment over time will get “weaker and even more slippery”. The research was published in Science Advances.
Previous research has identified two possible mechanisms for controlling the speed of the ice flow.
The first is self-regulation, which proposes that glaciers slow down at the end of the summer because large networks of channels drain water away at the base, increasing frictional resistance to ice flow.
The second is to do with the soft sediments that recent research has shown underlie glaciers; in this model, changing patterns of water flow alternately weaken or strengthen the sediment, making it more or less slippery, and thus enhancing or decreasing the speed of ice flow.
The team’s aim was to test the sediment theory for the first time using measurements on the ice sheet.
They carried out seismic surveys at a surface lake on the Greenland Ice Sheet, where the ice is around 1.2 km thick. This involves using a series of controlled explosions to send acoustic waves through the glacier, which then bounce back to a series of geophones –small microphones - set up on the glacier. The data are then analysed to delineate and characterise the physical properties of the sediment underneath the ice.
- sediment played the key role in controlling ice sheet flow;
- variability in meltwater supply controls sediment's slipperiness;
- weakening of subglacial sediment leads to accelerated ice flow.
They conclude that:
- The future response of the ice sheet to climate warming will be more complex than a simple case of the flow slowing down due to self-regulation
- Understanding how widespread sediments are and how their properties change with meltwater supply is essential if we are to build up an accurate picture of future patterns of ice flow
Wow! Raw footage of Daugaard-Jensen glacier.
Greenland now a major driver of rising seas: study
A new study published in Nature Climate Change found that the Greenland ice sheet is now supplying 25 percent of total sea level increase compared with just five percent 20 years earlier.
The findings add to growing concern among scientists that the global watermark is climbing more rapidly than forecast only a few years ago, with potentially devastating consequences.
Hundreds of millions of people around the world live in low-lying deltas that are vulnerable, especially when rising seas are combined with land sinking due to depleted water tables, or a lack of ground-forming silt held back by dams.
Major coastal cities are also threatened, while some small island states are already laying plans for the day their drowning nations will no longer be livable.
"This result is important because the Intergovernmental Panel on Climate Change (IPCC)"—the UN science advisory body—"makes a very conservative projection of total sea level rise by the end of the century," at 60 to 90 centimetres (24 to 35 inches), said Peter Wadhams, a professor of ocean physics at the University of Oxford who did not take part in the research.
That estimate, he added, assumes that the rate at which ocean levels rise will remain constant.
"Yet there is convincing evidence—including accelerating losses of mass from Greenland and Antarctica—that the rate is actually increasing, and increasing exponentially."