End of an era: Northern Hemisphere losing its last dry-snow region
Last July, something unprecedented in the 34-year satellite record happened: 98 percent of the Greenland Ice Sheet’s surface melted, compared to roughly 50 percent during an average summer. Snow that usually stays frozen and dry turned wet with meltwater. Now, new research led by the Cooperative Institute for Research in Environmental Sciences (CIRES) shows that last summer’s extreme melt could soon be the new normal.
“Greenland is warming rapidly, and such ice-sheet-wide surface-melt events will occur more frequently over the next couple of decades,” said Dan McGrath, a University of Colorado Boulder doctoral student who works at CIRES. McGrath is lead author of a paper published online May 20 in Geophysical Research Letters and which reports a significant warming trend on the Greenland Ice Sheet.
McGrath and his coauthors calculate that by 2025, ice-sheet-wide melt events will have a 50 percent chance of occurring each year. That would signal the loss of the last major dry-snow zone—regions where the snow stays almost perpetually frozen—in the Northern Hemisphere, McGrath said.
In the study, the researchers used air and snow temperature data from meteorological stations and boreholes to generate a 60-year record of air temperatures at the Summit research station, the highest and coldest station on the ice sheet. From 1982 to 2011, near-surface temperatures increased by an average of 0.09 degrees Celsius every year.
“This is six times faster than the global average,” McGrath said.
The warming at Summit is also accelerating. From 1950 to 2011, the average rate of warming was 0.02 degrees Celsius per year. But from 1992 to 2011, that number jumped to 0.12 degrees Celsius per year.
This warming has had a dramatic effect on the ice sheet’s structure, the scientists report. The ice sheet’s ablation zone—the lower parts that lose more snow and ice each year than they accumulate—is expanding up the ice sheet by about 145 feet per year.
“This increases the area over which the ice sheet sheds mass while shrinking the zone that gains mass,” McGrath said. “That will have an obvious impact on the ice sheet’s mass balance.”
Additionally, the dry-snow line—above which the snow doesn’t melt—is migrating up the ice sheet by about 115 feet per year.
“These zones are indicators of the health of the ice sheet,” McGrath said. “And the changes we are observing are an early but important sign that the ice sheet is in transition.”
The changes could increase the amount of solar radiation the ice sheet absorbs (since wet snow reflects less sunlight than dry snow) and, hence, the melt rate as well. It also could potentially speed up the ice sheet’s flow, though more work needs to be done to untangle these impacts.
These findings are supported by results from other researchers who have found that the ice sheet is losing more than 275 billion tons of ice per year (equivalent to the weight of 750,000 Empire State Buildings). “This imbalance is making a significant contribution to sea-level rise,” McGrath said.
The summit of the Greenland Ice Sheet has experienced surface melt in the past, McGrath says. But the melt events in the past were rare, happening once every century or two—in fact, only eight times in the last 1,500 years—the exception rather than the norm. Now the norm is shifting toward a new, slushy set point.
“Progressive increases in surface melt have occurred throughout the satellite record, but the last decade has been exceptional,” McGrath said. “If each of these events keeps being so far above the average, the average will change to reflect that.”
The scientists’ findings come at a time when Arctic sea ice extent is also at record lows.
“Ice-sheet-wide melting coupled with the loss of Arctic sea ice points to profound changes occurring to the Arctic climate system,” McGrath said. “These are not small, insignificant events we’re witnessing.”
NASA Cryospheric Sciences funded this research, with additional field logistical support provided by NSF Office of Polar Programs. Coauthors include former CIRES Director Konrad Steffen, CIRES adjunct research associate William Colgan, former CIRES doctoral student Atsuhiro Muto, and current CIRES doctoral student Nicolas Bayou.
CIRES is a joint institute of the National Oceanic and Atmospheric Administration (NOAA) and the University of Colorado Boulder.
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