"The Greenland ice sheet is falling apart – new study"
the headline of an article in The Conversation published Feb. 4.
Written by Tom Chudley, a glaciologist who holds a PhD in polar studies from Cambridge University, and is now a fellow in the department if Geography, Durham University.
Below is the conclusion of the article.
TOM CHUDLEY IN THE CONVERSATION
"It shouldn’t be particularly surprising to scientists that crevasses are getting larger across Greenland. As the ocean warms, the ice sheet has sped up in response, increasing the stresses acting upon its surface.
"However, observations from satellites and in-person fieldwork are so poor that to date, we had no idea how extensively or quickly this process has been occurring.
"Mapping cracksIn a new study, my colleagues and I mapped crevasses across the entirety of the Greenland ice sheet in 2016 and 2021.
"To do this, we used the “ArcticDEM”: three-dimensional surface maps of the polar regions based on high resolution satellite images. By applying image-processing techniques to over 8,000 maps, we could estimate how much water, snow or air would be needed to “fill” each crevasse across the ice sheet. This enabled us to calculate their depth and volume, and examine how they evolved.
"We found that from 2016 to 2021, there were significant increases in crevasse volume across fast-flowing sectors of the Greenland ice sheet.
"In the southeast of the ice sheet, an area that has been particularly vulnerable to ocean-induced acceleration and retreat in the past few years, crevasse volume increased by over 25%.
"However, against our expectations, crevasse volume across the whole ice sheet increased by only 4.3%. That’s much closer to an overall balance than the extremes observed in certain sectors. What had happened?
"In fact, the significant increases elsewhere were being offset by a single source: an outlet glacier known as Sermeq Kujalleq (Danish: Jakobshavn Isbræ).
"Sermeq Kujalleq is the fastest-flowing glacier on the planet, reaching speeds of nearly 50 metres a day and providing an outsized proportion of Greenland’s total sea-level rise contribution. In 2016, responding to an influx of cold water from the north Atlantic ocean, the glacier slowed and thickened. As it did this, the crevasses on the surface began to close – offsetting increases across the rest of the ice sheet.
"This slowdown was short-lived. Since 2018, Sermeq Kujalleq has once again reverted to acceleration and thinning in response to ongoing warming. We won’t be able to rely on it to offset ice-sheet-wide increases in crevassing in the future.
Cracks grow into icebergs
"Crevasses play an integral part in the life cycle of glaciers, and as they grow they hold the potential to further accelerate ice-sheet loss. They deliver surface meltwater into the belly of the ice sheet: once inside, water can act to warm the ice or lubricate the bed that the glacier slides over, both of which can make the ice sheet flow faster into the ocean.
"Meanwhile, where the ice meets the sea, crevasses form the initial fractures from which icebergs can break off, increasing the output of icebergs into the ocean.
"In short, crevasses underpin the dynamic processes that occur across Greenland and Antarctica. However, these processes are very poorly understood, and their future evolution is the single largest uncertainty in our predictions of sea-level rise.
"Together, the increased discharge of ice holds the potential to add up to 10 metres of additional sea-level rise by 2300 (75% of all cities with more than 5 million inhabitants exist less than 10m above sea level).
"We need to better understand these processes – including crevasses – so that informed sea-level projections can form the basis of our responses to the global challenges that climate change presents.
"Since 2023, an international coalition of polar scientists has been urging the world to limit warming to 1.5˚C to avoid the most catastrophic melt scenarios for global glaciers and ice sheets.
"Last month, the EU’s Copernicus Climate Change Service confirmed that 2024 was the first year in which average global temperatures exceeded this threshold.Every fraction of a degree matters.
"We may still be able to save ourselves from the worst of the damage the climate change will bring – but we are desperately running out of time."
