Greenland’s ice loss accelerating rapidly, gravity-measuring
satellites reveal
August 10, 2006
AUSTIN, Texas—A new analysis of data from twin satellites has revealed that the melting of Greenland’s ice sheet has increased dramatically in the past few years, with much of the loss occurring primarily along one shoreline potentially affecting weather in Western Europe.
The loss of ice has been occurring about five times faster from Greenland’s southeastern region in the past two years than in the previous year and a half. The dramatic changes were documented during a University of Texas at Austin study of Greenland’s mass between 2002 and 2005.
The study, by lead author Jianli Chen, a research scientist at the university's Center for Space Research (CSR) who earned his doctoral degree in geophysics at the Jackson School of Geosciences, was published today in the journal Science. Chen's co-authors are Clark Wilson, chairman of the Jackson School's Department of Geological Sciences and holder of the Wallace E. Pratt Professorship in Geophysics, and Byron Tapley, director of the CSR and holder of the Clare Cockrell Williams Centennial Chair in Engineering
at the College of Engineering.
Related results on the significant loss of ice from Antarctica were published in Science in March by other researchers participating in the Gravity Recovery and Climate Experiment (GRACE) mission. The GRACE mission is funded by NASA and the German Aerospace Center, and led by Tapley.
“Our latest GRACE findings are the most complete measurement of ice-mass loss for Greenland,” said Tapley. “The sobering thing to see is that the whole process of glacial melting is stepping up much more rapidly than before.”
Antarctica is considered the largest, and Greenland the second largest, reservoir of fresh water on Earth, with the latter containing about 10 percent of the world’s fresh water. Melting of ice from these two regions is expected to impact sea level and ocean circulation, and potentially the future of climates worldwide.
The Greenland study, for example, suggests that the amount of fresh water contributed from the melting of its ice sheet could add 0.56 millimeters annually to a global increase in sea levels, higher than all previously published measurements.
“These findings are consistent with the most recent independent measurements of Greenland’s mass done by other techniques like satellite radar interferometry, but in this case they provide a direct measure of ice-mass changes,” said Wilson, who
as co-author helped analyze the estimates for Greenland.
Within the subpolar zone that includes Greenland, the rapid rise in meltwater along its eastern coast could add to other warming-related factors believed to be weakening the counterclockwise flow of the North Atlantic Current. For instance, the increased meltwater could change how more buoyant fresh water mixes with salt water in a branch of this flow called the Norwegian Current. This change could lower the temperatures of water, and thus wind, that travels past the west coast of Ireland and Great Britain.
That ocean temperature change would occur because the current might not move northward past Norway before returning to more southerly latitudes. Warmer, southerly waters would be stalled from moving northward if that happened, resulting in chillier winters in parts of Western Europe.
“If enough fresh water enters the Norwegian Current,” Tapley said, “and you interrupt return flow, then there could be climate effects in Europe.”
The twin GRACE satellites provide the most comprehensive monthly estimates of Greenland’s ice-mass balance The satellites are sensitive to the gravitational pull of mass changes on Earth, which produce micrometer-scale variations in the distance (137 miles or 220 kilometers) that separates the two satellites as they fly in formation over Earth.
Lead author Chen developed a method to improve the effective spatial resolution of mass change estimates. The method used the known locations of major glaciers as information in estimating the sources of mass change.
“By using this special filtering procedure,” Chen said, “we teased out additional details of mass changes in Greenland along its Southeastern and Northeastern shores separately.”
The estimates showed that 69 percent of the ice-mass loss in recent years came from eastern Greenland. Of the 57 cubic miles (239 cubic kilometers) of water mass lost on average each year, 39 cubic miles (164 cubic kilometers) were from the eastern shoreline. More than half of that eastern loss involved ice from the glacier complex in southeast Greenland.
“This melting process may be approaching a point where it won’t be centuries before Greenland’s ice melts, but a much shorter time-frame,” Tapley said, noting that it isn’t possible to tell how much sooner this will be.
Tapley, in the College of Engineering, and Wilson, in the Jackson School of Geosciences, lead grants funded primarily by NASA to pursue research questions related to large-scale mass changes impacting Earth's features.
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GRACE is managed for NASA by the Jet Propulsion Laboratory, and is in its fifth year of a 10-year mission. The University of Texas Center for Space Research in the College of Engineering has overall mission responsibility, and GeoForschungsZentrum Potsdam (GFZ) in Potsdam, Germany, handles German mission elements. Science data processing, distribution, archiving and product verification are managed jointly by JPL, The University of Texas at Austin, and GFZ.
For more information about this study from the Center for Space Research, contact Becky Rische in the College of Engineering, brische@mail.utexas.edu ,
512-471-7272.
For more information about research at the Jackson School, contact J.B. Bird at
jbird@jsg.utexas.edu,
512-232-9623.
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