Frozen for 6 million years, Antarctic ice rewrites Earth’s climate story

According to a study published on October 28 in the Proceedings of the National Academy of Sciences, the ice is about 6 million years old. Tiny air bubbles sealed within the ice provide a rare and direct glimpse into Earth's ancient atmosphere, offering scientists an unmatched record of the planet's past climate.

A Glimpse Into a Warmer Ancient World

The oldest sample collected from the Allan Hills dates back 6 million years, a period when geological records indicate Earth was significantly warmer and sea levels were much higher than they are today.

The research effort was led by Sarah Shackleton of the Woods Hole Oceanographic Institution and John Higgins of Princeton University. Both are part of the National Science Foundation-funded Center for Oldest Ice Exploration (COLDEX), a multi-institution collaboration of 15 U.S. research partners coordinated by Oregon State University.

"Ice cores are like time machines that let scientists take a look at what our planet was like in the past," explained Shackleton, who has worked on several Antarctic drilling expeditions. "The Allan Hills cores help us travel much further back than we imagined possible."

Ed Brook, COLDEX Director and paleoclimatologist at Oregon State University, described the find as the center's most important discovery so far. The NSF Science and Technology Center, established in 2021, was created to explore the Antarctic ice sheet, the largest reservoir of frozen water on Earth.

"We knew the ice was old in this region," Brook said. "Initially, we had hoped to find ice up to 3 million years old, or maybe a little older, but this discovery has far exceeded our expectations."

A Global Race to Reach Deeper Into Time

COLDEX is among several international teams striving to extend the ice core record beyond its previous 800,000-year limit. A European project recently announced a continuous deep core reaching 1.2 million years in East Antarctica, but the Allan Hills samples push the timeline back several million years further, though in discrete fragments rather than a single continuous core.

The COLDEX researchers work at a remote field site in the Allan Hills, spending months drilling through one to two hundred meters of ice near the edge of the Antarctic ice sheet. In this region, rugged terrain and ice flow patterns act together to preserve extremely old ice closer to the surface. By contrast, obtaining continuous cores from the Antarctic interior typically requires drilling to depths of more than 2,000 meters.

"We're still working out the exact conditions that allow such ancient ice to survive so close to the surface," said Shackleton. "Along with the topography, it's likely a mix of strong winds and bitter cold. The wind blows away fresh snow, and the cold slows the ice to almost a standstill. That makes Allan Hills one of the best places in the world to find shallow old ice, and one of the toughest places to spend a field season."

The age of the Allan Hills samples was determined directly from the ice itself using precise measurements of an isotope of the noble gas argon. This approach allows scientists to date the ice without relying on surrounding sediments or other indirect evidence.

Although the record is not continuous, the samples are far older than any previously studied ice. As Higgins noted, "Tthe team has built up a library of what we call 'climate snapshots' roughly six times older than any previously reported ice core data, complementing the more detailed younger data from cores in the interior of Antarctica."

Reconstructing 6 Million Years of Cooling

Analysis of oxygen isotopes in the ice revealed that the region cooled by about 12 degrees Celsius (roughly 22 degrees Fahrenheit) over the past 6 million years. This is the first direct evidence quantifying how much Antarctica's climate has cooled since that ancient warm period.

Future research will focus on reconstructing concentrations of greenhouse gases and ocean heat levels preserved within the ice bubbles -- key clues to understanding the natural forces driving long-term climate change.

A new COLDEX expedition is scheduled to return to the Allan Hills in the coming months for additional drilling. The team hopes to recover even older samples and produce a more detailed record of Earth's ancient atmosphere.

"Given the spectacularly old ice we have discovered at Allan Hills, we also have designed a comprehensive longer-term new study of this region to try to extend the records even further in time, which we hope to conduct between 2026 and 2031," Brook said.

Collaboration and Support

Contributors to the study include Julia Marks Peterson, Christo Buizert, and Jenna Epifanio of Oregon State; Valens Hishamunda, Austin Carter, and Michael Bender of Princeton; Lindsey Davidge, Eric Steig, and Andrew Schauer of the University of Washington; Sarah Aarons, Jacob Morgan, and Jeff Severinghaus of Scripps Institution of Oceanography at the University of California, San Diego; Andrei V. Kurbatov and Douglas Introne of the University of Maine; Yuzhen Yan of Tongji University; and Peter Neff of the University of Minnesota.

COLDEX is supported by the NSF Office of Polar Programs; the NSF Office of Integrative Activities' Science and Technology Center Program; and Oregon State University. Field operations in Antarctica are carried out with support from the U.S. Antarctic Program and NSF funding, with drilling assistance from the NSF U.S. Ice Drilling Program and sample storage managed by the NSF Ice Core Facility in Denver, Colorado.