Greenland`s ice sheet 'plumbing' system revealed
A team of researchers have shed light on the impact of climate change on plumbing system that governs the water flow in subglacial lake under the Greenland ice sheet.
Washington D.C: A team of researchers have shed light on the impact of climate change on plumbing system that governs the water flow in subglacial lake under the Greenland ice sheet.
A team of experts, led by Dr Steven Palmer from the University of Exeter, has studied the water flow paths from one such subglacial lake, which drained beneath the ice sheet in 2011.
The study shows, for the first time, how water drained from the lake - via a subglacial tunnel. Significantly, the authors present satellite observations that show that a similar event happened in 1995, suggesting that this lake fills and drains periodically.
Lead author Dr Steven Palmer said that the research reveals details about the plumbing system beneath the Greenland ice sheet, which is important because the configuration of that system has an impact on the flow speed of the overlying ice.
However, unlike Antarctic subglacial lakes, which are sustained through melting of the ice sheet base, the study shows that this subglacial lake has been fed by surface meltwater flowing down a nearby moulin - a circular, vertical shaft found within a glacier.
The scientists predict that as the Arctic continues to warm, increasing volumes of surface meltwater routed to the ice sheet bed will cause subglacial lake drainage to become more common in the future.
Because the way in which water moves beneath ice sheets strongly affects ice flow speeds, this increased drainage frequency could affect the sensitivity of the ice sheet to climate change, impacting the rate of future sea level change.
Palmer added that they have made the first observations of how the Greenland ice sheet responds to subglacial lake drainage, but more research is required to understand the long-term impacts of these events. It is possible that draining subglacial lakes act to release the pressure at the ice sheet base, meaning that if they drain more frequently in the future, they may actually result in slower ice sheet flow overall.
The study is published in the journal Nature Communications.