Press Release
13 June 2018

Sea ice loss and wave action trigger rapid ice shelf disintegrations in the Antarctic

The National Snow and Ice Data Center (NSIDC) is part of the Cooperative Institute for Research in Environmental Sciences at the University of Colorado Boulder.

View from Cape DisappointmentLooking out from Cape Disappointment at the ice front of Scar Inlet, this photograph shows blue water on fast ice and then the shelf edge in the distance. Photo credit: Ted Scambos, NSIDC. High-resolution image

A new study finds that when Antarctica’s massive ice shelves lack a protective buffer of sea ice, ocean swells from the north flex the shelves and can weaken their stabilizing seaward edge. Regular inundation by summer meltwater as the seaward edge breaks away can also contribute to rapid ice shelf disintegration.

Because ice shelves slow the flow of ice from the massive Antarctic Ice Sheet, rapidly disintegrating shelves have troubling implications for sea level rise.

“Sea ice here acts like the bumpers on a car—with the bumpers in place, the car can take a shock and not be damaged. Take them off, and every hit adds up,” said Ted Scambos, study co-author and senior research scientist at the National Snow and Ice Data Center at the University of Colorado Boulder.

Ice shelves are thick plates of ice, fed by tributary glaciers. They are floating seaward extensions of the grounded ice sheet.

Since 1995, three large ice shelves on the Antarctic Peninsula—the Larsen A, Larsen B, and Wilkins—have suddenly and dramatically disintegrated.

Happening over a few weeks, or sometimes only a few days, the ice shelf disintegrations mark an unprecedented departure from the more typical and natural recurring calving of larger icebergs every decade or so.

Until recently, researchers thought that intense surface melt due to a warming climate and ice fracturing were the sole culprits. The new findings suggest that loss of sea ice and the calving of the seaward edge into narrow ‘sliver’ icebergs are the trigger that initiates a rapid ice shelf disintegration.

“Our study breaks new ground in how it implicates sea ice change in sea level rise,” said Rob Massom, the study’s lead author and a senior research scientist at the Australian Antarctic Division and Antarctic Climate and Ecosystems Cooperative Research Centre.

“It introduces ocean wave-induced breakage of the outer margins of ice shelves following loss of a protective sea ice buffer as the straw that breaks the camel’s back, triggering large-scale disintegration of ice shelves weakened by widespread melting and fracturing,” Massom said.

Thwaites Glacier frontThis photograph shows part of the ice front near Thwaites Glacier, with snowed-over icebergs near the grounding line. It was taken from the window of a NASA Operation IceBridge flight in November 2011. Photo credit: NASA.  High-resolution image

Massom, Scambos, and colleagues analyzed disintegration events on three ice shelves that had been stable for centuries or even millennia: the Larsen A Ice Shelf in 1995, the Larsen B Ice Shelf in 2002, and the Wilkins Ice Shelf in 2008 and 2009.

The researchers confirmed that atmospheric warming led to increased meltwater on the surfaces of the shelves. Pooled meltwater then percolated downward through crevasses, initiating a hydrofracturing process that weakened the ice.

But the team’s analysis revealed a previously under-appreciated link to sea ice: each disintegration occurred during periods with little or no sea ice cover along the ice shelf edge. Without the protective buffer of sea ice, the ice shelves became exposed to wave action that flexed the already fractured ice.

“What we’ve found is that increased flexing of the outer parts of ice shelves by waves sets the ice up for destruction. Even though the movement is tiny, over time the shelf is weakened,” Scambos said.

In each case, ocean swells began impacting the ice shelf edge. As the shelves flexed, pre-existing fractures along the seaward edge chipped off as long, thin, sliver-shaped icebergs instead of the larger tabular icebergs more typical of Antarctic ice shelf calvings. Rapidly losing swaths of the stabilizing keystone blocks from the seaward edge left the remaining ice shelf ripe for runaway collapse.

“Other ice shelves can survive for centuries if they don’t have surface meltwater—or if the water can run off easily,” Scambos said. The Nansen Ice Shelf, for instance, is less susceptible to hydrofracturing because a large drainage system helps funnel meltwater off the shelf surface. “But with meltwater ponding and a legacy of weakening from sea ice loss, you can destroy a shelf in just a few weeks,” Scambos said. “It starts with these keystone blocks being broken out.”

These shelves form a crucial interface between warming oceans and the massive Antarctic ice sheets flowing toward the coasts.

Because ice shelves are already floating in the ocean and displacing their volume, similar to ice cubes in a glass of water, they do not contribute directly to sea level rise when they break up or disintegrate.

Ice shelves do, however, provide a backpressure that moderates glacier flow speed. Once the ice shelves are gone, so is the backpressure, allowing the glaciers to flow more rapidly into the ocean. It is this land-based ice that ultimately contributes to sea level rise.

“We hope that our new findings will both increase awareness of the importance of interactions and linkages between different component parts of the global cryosphere, and also focus and motivate efforts to better understand and model the coupled ice sheet-sea ice-atmosphere-ocean system around Antarctica,” Massom said. “This represents an important pathway towards reducing current large uncertainty in predictions of the response of the Antarctic cryosphere to climate change and its contribution to sea level rise.”

The Antarctic Ice Sheet contains enough ice to raise sea level by approximately 57 meters (187 feet), about half the length of a football or soccer field. Worldwide, more than 100 million people currently live within one meter of mean sea level, making it critical for researchers to understand the fate of remaining ice shelves, to enable more accurate assessments of future Antarctic ice discharge into the ocean.

The new study was published today in the journal Nature. The study was co-authored by Sharon Stammerjohn of the Institute of Arctic and Alpine Research at the University of Colorado Boulder, Luke Bennetts from the University of Adelaide, Phillip Reid of the Australian Bureau of Meteorology, and Vernon Squire of the University of Otago.

-end-

Skiing researchersThis photograph shows the Larsen B embayment region in February 2016. Researchers Erin Pettit and Phil 'Chucky' Stevens ski toward the Scar Inlet region, with the Antarctic Peninsula to the right. Photo credit: Ted Scambos, NSIDC. High-resolution image

Larsen CThis photograph shows the northern Larsen C Ice Shelf, looking north, in November 2011. Photo credit: Ted Scambos, NSIDC. High-resolution image

Scar InletThe sheared area of the northeast side of Scar Inlet Ice Shelf is visible in this photograph, looking south from Cape Disappointment. Photo credit: Ted Scambos, NSIDC. High-resolution image

Study citation

Massom, Robert A., Theodore A. Scambos, Luke G. Bennetts, Phillip Reid, Vernon A. Squire, and Sharon Stammerjohn. Antarctic ice shelf disintegration triggered by sea ice loss and ocean swell. Nature 2018, doi:10.1038/s41586-018-0212-1.

Read the research article at https://www.nature.com/articles/s41586-018-0212-1.

Read the Australian Antarctic Division release at http://www.antarctica.gov.au/news/2018/ocean-waves-following-sea-ice-loss-trigger-antarctic-ice-shelf-collapse.

Media contacts

Agnieszka Gautier & Laura Naranjo
National Snow and Ice Data Center, University of Colorado Boulder
press@nsidc.org, +1.303.492.1497