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| Icebergs at Jakobshavn, one of four glaciers that scientists have used to model the activity of all large Greenland glaciers. The new study finds that this method of modeling is too simplistic to accurately capture how Greenland's ice is changing and contributing to sea level rise [Credit: Beata Csatho] |
"The great importance of our data is that for the first time, we have a comprehensive picture of how all of Greenland's glaciers have changed over the past decade," Csatho says.
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| The surface of the Greenland Ice Sheet. A new study uses NASA data to provide the first detailed reconstruction of how the ice sheet and its many glaciers are melting. The research was led by UB geologist Beata Csatho [Credit: Beata Csatho] |
The project was a massive undertaking, using satellite and aerial data from NASA's ICESat spacecraft and Operation IceBridge field campaign to reconstruct how the height of the Greenland Ice Sheet changed at nearly 100,000 locations from 1993 to 2012.
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| Ice calving into a proglacial lake in Greenland [Credit: Beata Csatho] |
The study had two major findings:
• First, the scientists were able to provide new estimates of annual ice loss at high spatial resolution.
• Second, the research revealed that current models fail to accurately capture how the entire Greenland Ice Sheet is changing and contributing to rising oceans.
The second point is crucial to climate change modelers.
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| This image shows where NASA has taken surface elevation measurements on the Greenland Ice Sheet. The paths of the ICESat satellite are colored in gray and the tracks of the airborne mission Operation IceBridge are in purple [Credit: NASA's Goddard Space Flight Center Scientific Visualization Studio] |
But the new research shows that activity at these four locations may not be representative of what is happening with glaciers across the ice sheet. In fact, glaciers undergo patterns of thinning and thickening that current climate change simulations fail to address, Csatho says.
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| This NASA visualization shows surface elevation changes in the Greenland Ice Sheet’s southeast region from 2003-12. Thinning is shown in green, blue and purple [Credit: NASA's Goddard Space Flight Center Scientific Visualization Studio] |
The team identified areas of rapid shrinkage in southeast Greenland that today's models don't acknowledge. This leads Csatho to believe that the ice sheet could lose ice faster in the future than today's simulations would suggest.
The results will be published on Dec. 15 in the Proceedings of the National Academy of Sciences.
How much ice is the Greenland Ice Sheet losing?
To analyze how the height of the ice sheet was changing, Csatho and UB research professor and photogrammetrist Anton Schenk, PhD, developed a computational technique called Surface Elevation Reconstruction And Change detection to fuse together data from NASA satellite and aerial missions.
The analysis found that the Greenland Ice Sheet lost about 243 metric gigatons of ice annually -- equivalent to about 277 cubic kilometers of ice per year -- from 2003-09, the period for which the team had the most comprehensive data. This loss is estimated to have added about 0.68 millimeters of water to the oceans annually.
The figures are averages, and ice loss varied from year to year, and from region to region.
Why are today's projections of sea level rise flawed, and how can we fix them?
Glaciers don't just gradually lose mass when the temperature rises. That's one reason it's difficult to predict their response to global warming.
In the study, scientists found that some of Greenland's glaciers thickened even when the temperature rose. Others exhibited accelerated thinning. Some displayed both thinning and thickening, with sudden reversals.
As a step toward building better models of sea level rise, the research team divided Greenland's 242 glaciers into 7 major groups based on their behavior from 2003-09.
"Understanding the groupings will help us pick out examples of glaciers that are representative of the whole," Csatho says. "We can then use data from these representative glaciers in models to provide a more complete picture of what is happening."
In a new project, she and colleagues are investigating why different glaciers respond differently to warming. Factors could include the temperature of the surrounding ocean; the level of friction between a glacier and the bedrock below; the amount of water under a glacier; and the geometry of the fjord.
"The physics of these processes are not well understood," Csatho says.
Author: Charlotte Hsu | Source: University at Buffalo [December 15, 2014]