1 day Ago
March 31, 2025 This article has been reviewed according to Science X's editorial process and policies . Editors have highlightedthe following attributes while ensuring the content's credibility: fact-checked peer-reviewed publication trusted source proofread by University of Waterloo In the first study to consider the long-term evolution of the rivers that flow beneath glaciers, researchers have new insights into the future of Antarctica's melting ice that may change the way climate scientists predict the effects of a warming planet. The study , "The past, present, and future evolution of the Aurora Subglacial Basin's subglacial drainage system," appears in Nature Communications .
Researchers from the University of Waterloo's Faculty of Environment led the project that studied the Aurora Subglacial Basin and modeled its subglacial hydrology—the flow of water at the base of the ice. They compared drainage systems at various times, ranging from 34 million years ago to 75 years from now. They found that these rivers are dynamic, changing from one period to another.
The Aurora Subglacial Basin is in East Antarctica and is grounded below sea level, a particularly unstable configuration that could lead to rapid and irreversible retreat, and an increase of four meters in the global ocean level if all the ice in the region melted. "Many studies say the past is an analog of what might happen in the future. But if we don't now consider subglacial rivers, we're missing out on a critical part of the picture," said Anna-Mireilla Hayden, a Ph.
D. candidate and the first author of the study. "It's important that scientists who model ice sheets account for hydrology because it could reduce uncertainty in estimates of sea level rise.
" The research revealed that the water pathways beneath glaciers have relocated and will continue to shift in the future. Changes in where the river drains into the ocean can impact water circulation beneath floating ice and enhance weaknesses in the vulnerable regions where ice flows from the land into the ocean. It could cause the ice to break off and contribute to an even faster ice flow and a greater increase in the rise of the world's oceans than previously suggested.
"It's critical that projections of sea level rise include as much relevant information as possible so that the world can take appropriate measures to lessen the devastation to global coastal communities," said Dr. Christine Dow, professor in the Faculty of Environment and Canada Research Chair in Glacial Hydrology and Ice Dynamics. "While we do not directly predict the amount seas will rise in this study, our analysis over extensive time periods of history illustrates that the influence of these subglacial rivers is both significant and highly changeable over time.
The role of subglacial water in ice dynamics must be part of the conversation, or else we don't have the full picture." Dr. Tyler Pelle, a postdoctoral researcher at the Scripps Institute of Oceanography in the U.
S., contributed to this work. More information: Anna-Mireilla Hayden et al, The past, present, and future evolution of Aurora Subglacial Basin's subglacial drainage system, Nature Communications (2025).
DOI: 10.1038/s41467-025-57700-1 Journal information: Nature Communications Provided by University of Waterloo.
