Ice sheet surface melt is accelerating in Greenland and slowing in Antarctica, finds study

Surface ice in Greenland has been melting at an increasing rate in recent decades, while the trend in Antarctica has moved in the opposite direction, according to researchers at the University of California, Irvine and Utrecht University in the Netherlands.

For a paper published recently in Geophysical Research Letters, the scientists studied the role of Foehn and katabatic winds, downslope gusts that bring warm, dry air into contact with the tops of glaciers. They said that melting of the Greenland ice sheet related to these winds has gone up by more than 10% in the past 20 years; the impact of the winds on the Antarctic ice sheet has decreased by 32%.

“We used regional climate model simulations to study ice sheets in Greenland and Antarctica, and the results showed that downslope winds are responsible for a significant amount of surface melt of the ice sheets in both regions,” said co-author Charlie Zender, UCI professor of Earth system science. “Surface melt leads to runoff and ice shelf hydrofracture that increase freshwater flow to oceans—causing sea level rise.”

While the impact of the winds is substantial, he said, the distinct behaviors of global warming in the Northern and Southern hemispheres are causing contrasting outcomes in the regions.

In Greenland, wind-driven surface melt is compounded by the massive island “becoming so warm that sunlight alone (without wind) is enough to melt it,” according to Zender. The 10% growth in wind-driven melt combined with warmer surface air temperatures has resulted in a 34% increase in total surface ice melt. He attributes this outcome in part to the influence of global warming on the North Atlantic Oscillation, an index of sea level pressure difference. The shifting of NAO to a positive phase has led to below-normal pressure across high latitudes, ushering warm air over Greenland and other Arctic areas.

The authors found that in contrast with Greenland, total Antarctic surface melt has decreased by about 15% since 2000. The bad news is that this reduction is largely due to 32% less downslope wind-generated melt on the Antarctic Peninsula, where two vulnerable ice shelves have already collapsed. Zender said it’s fortunate that the Antarctic stratospheric ozone hole discovered in the 1980s continues to recover, which temporarily helps to insulate the surface from further melt.

“The ice sheets in Greenland and Antarctica keep over 200 feet of water out of the ocean, and their melt has raised global sea level by about three-quarters of an inch since 1992,” said Zender, who holds a joint appointment in UCI’s Department of Computer Science. “Although Greenland has been the No. 1 driver of sea level rise in recent decades, Antarctica is close behind and catching up and will eventually dominate sea level rise. So it’s important to monitor and model melt as both ice sheets deteriorate, including the ways climate change alters the relationship between wind and ice.”

He said he hopes that the research on the role of Foehn and katabatic winds in polar regions will help the climate science community strengthen the physical fidelity of Earth system models.

Zender was joined on this project by Matthew Laffin and Wenshan Wang of UCI’s Department of Earth System Science and Melchior van Wessem and Brice Noel of the University of Utrecht’s Institute for Marine and Atmospheric Research.

More information:
Matthew K. Laffin et al, Wind‐Associated Melt Trends and Contrasts Between the Greenland and Antarctic Ice Sheets, Geophysical Research Letters (2023). DOI: 10.1029/2023GL102828

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University of California, Irvine

Ice sheet surface melt is accelerating in Greenland and slowing in Antarctica, finds study (2023, October 16)

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