Among the vast expanse of Antarctica lies the Thwaites Glacier, the world’s widest glacier measuring about 80 miles on the western edge of the continent. Despite its size, the massive landform is losing about 50 billion tons of ice more than it is receiving in snowfall, which places it in a precarious position in respect to its stability.
Accelerating ice loss has been observed since the 1970s, but it is unclear when this significant melting initiated — until now. A new study published in the journal PNAS, led by researchers at the University of Houston, suggests that significant glacial retreat began in the 1940s. Their results on the Thwaites Glacier coincide with previous work that studied retreat on Pine Island Glacier and found glacial retreat began in the ’40s as well.
“What is especially important about our study is that this change is not random nor specific to one glacier,” said Rachel Clark, corresponding author, who graduated from UH last year with a doctorate in geology. “It is part of a larger context of a changing climate. You just can’t ignore what’s happening on this glacier.”
Clark and the study authors posit that the glacial retreat was likely kicked off by an extreme El Niño climate pattern that warmed the west Antarctic. Since then, the authors say, the glacier has not recovered and is currently contributing to 4% of global sea-level rise.
“It is significant that El Niño only lasted a couple of years, but the two glaciers, Thwaites and Pine Island, remain in significant retreat,” said Julia Wellner, UH associate professor of geology and U.S. lead investigator of the Thwaites Offshore Research project, or THOR, an international collaboration whose team members are authors of the study.
“Once the system is kicked out of balance, the retreat is ongoing,” she added.
Their findings also make it clear the retreat at the glaciers’ grounding zone, or the area where the glaciers lose contact with the seabed and start to float, was due to external factors.
“The finding that both Thwaites Glacier and Pine Island Glacier share a common history of thinning and retreat corroborates the view that ice loss in the Amundsen Sea sector of the West Antarctic ice sheet is predominantly controlled by external factors, involving changes in ocean and atmosphere circulation, rather than internal glacier dynamics or local changes, such as melting at the glacier bed or snow accumulation on the glacier surface,” said Claus-Dieter Hillenbrand, U.K. lead investigator of THOR and study co-author.
“A significant implication of our findings is that once an ice sheet retreat is set in motion, it can continue for decades, even if what started it gets no worse,” added James Smith, a marine geologist at the British Antarctic Survey and study co-author. “It is possible that the changes we see today on Thwaites and Pine Island glaciers — and potentially across the entire Amundsen Sea embayment — were essentially set in motion in the 1940s.”
Dating of Sediment Cores Plays Key Role in Study
Clark and the team used three primary methods to reach their conclusion. One of those methods was marine sediment core collection that was closer to the Thwaites Glacier than ever before. They retrieved the cores during their trip to the Amundsen Sea near Thwaites in early 2019 aboard the Nathaniel B. Palmer icebreaker and research vessel. The researchers then used the cores to reconstruct the glacier’s history from the early Holocene epoch to the present. The Holocene is the current geological epoch that began after the last ice age, roughly 11,700 years ago.
CT scans were used to take x-rays of the sediment to gather details from its history. Geochronology, or the science of dating earth materials, was then used to reach the conclusion that significant ice melt began in the ’40s.
Clark used 210Pb (lead-210), an isotope that’s naturally buried in the sediment cores and is radioactive, as the most important isotope in her geochronology. This process is similar to radiocarbon dating, which measures the age of organic materials as far back as 60,000 years.
“But lead-210 has a short half-life of about 20 years, whereas something like radiocarbon has a half-life of about 5,000 years,” Clark said. “That short half-life allows us to build a timeline for the past century that’s detailed.”
This methodology is important because although satellite data exists to help scientists understand glacial retreat, these observations only go as far back as a few decades, a time frame that is too short to determine how Thwaites responds to ocean and atmosphere changes. Pre-satellite records are needed for scientists to understand the glacier’s longer-term history, which is why sediment cores are used.
Study Informs Future Modeling to Reduce Uncertainty of Sea-Level Rise
Thwaites Glacier plays a vital role in regulating the West Antarctic ice sheet stability and, thus, global sea-level rise, according to Antarctic researchers.
“The glacier is significant not only because of its contribution to sea-level rise but because it is acting as a cork in the bottle holding back a broader area of ice behind it,” Wellner said. “If Thwaites is destabilized, then there’s potential for all the ice in West Antarctica to become destabilized.”
If Thwaites Glacier were to collapse entirely, global sea levels are predicted to rise by 65 cm (25 in).
“Our study helps to better understand what factors are most critical in driving thinning and retreat of glaciers draining the West Antarctic ice sheet into the Amundsen Sea,” Hillenbrand said. “Therefore, our results will improve numerical models that attempt to predict the magnitude and rate of future Antarctic ice sheet melting and its contributions to sea levels.”
Researchers with THOR are part of an even larger initiative, the International Thwaites Glacier Collaboration, a joint U.S.-U.K. partnership to reduce uncertainty in the projection of sea-level rise from Thwaites Glacier.
The study’s authors are Clark, Wellner and Georgina Garcia-Barrera of the University of Houston; Hillenbrand, James Smith, Robert Larter and Kelly Hogan of the British Antarctic Survey; Rebecca Totten, Asmara Lehrmann and Victoria Fitzgerald of the University of Alabama; Lauren Simkins and Allison Lepp of the University of Virginia; Alastair Graham of the University of South Florida; Frank Nitsche of Columbia University; James Kirkham of the University of Cambridge and the British Antarctic Survey; Werner Ehrmann of the University of Leipzig; and Lukas Wacker of Ion Beam Physics.
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