Antarctica's Role in Sea Level Rise Unveiled

Sources of uncertainty

The team of researchers, led by Australian Antarctic Division glaciologist Dr Ben Galton-Fenzi, reviewed research on the key processes and potential feedbacks that can accelerate AIS retreat.

"We examined how Antarctica will contribute to sea-level change in the coming decades to centuries and where the uncertainties lie that make it difficult to project future behaviour of the ice sheet," Dr Galton-Fenzi said.

"Then we looked at what processes and regions should be the focus of future scientific research to reduce these uncertainties."

If the AIS were to completely melt, global sea levels would rise by about 58 metres. The huge East Antarctic Ice Sheet (covering two thirds of the continent) would contribute about 52 metres of this sea-level rise, while the West Antarctic Ice Sheet and the Antarctic Peninsula would make up the rest.

In the simplest terms, the Antarctic Ice Sheet grows due to snowfall that compresses into ice, and shrinks due to iceberg calving and melting from beneath the ice shelves.

However, there are many complex interactions and feedback mechanisms involved in these physical processes and how the ice moves that make it difficult to predict ice sheet behaviour. Critical thresholds if they are crossed can dramatically amplify the contribution of Antarctica to sea-level rise.

Also contributing to the uncertainty are limitations with current climate and ice sheet models in simulating these physical processes and feedback mechanisms, and a lack of data that can capture physical processes at the right time and spatial scales.

Sea-level rise is also uneven across the globe due to what are known as "gravitational, rotational and deformational effects".

"When the Antarctic Ice Sheet loses mass from ice melting into the ocean, it weakens the gravitational pull of the continent, causing the sea level to drop close to the continent, but rise in more distant locations," Dr Galton-Fenzi said.

"The loss of ice mass and the redistribution of water in the ocean also cause changes in the rotation and shape of the Earth, which adds to the spatial variability in sea level."

Areas for action

Among the priority areas for future research identified by the team are high resolution measurements focused on regions thought to be particularly vulnerable to rapid change, to better understand the physical processes impacting on the ice sheet.

Improved understanding based on these observations can then be used to improve models and analytical tools which, in turn, improve projections of sea-level rise that can inform effective policy decisions.

"By reducing the uncertainties associated with the Antarctic Ice Sheet and sea-level rise, we'll give policymakers and decision-makers better information to develop coastal planning measures, resilient infrastructure and adaption strategies," Dr Galton-Fenzi said.

"Interdisciplinary and international collaboration, particularly in regions vulnerable to rapid retreat in the East Antarctic Ice Sheet, will enhance our overall research quality and accelerate progress in reducing the level of uncertainty."

The research will appear in Antarctica and the Earth System, published by Taylor & Francis Group, in early 2025.

More information

• Galton-Fenzi, B.K., Gold, M. and Souter, D. (2024) Outlook for Policy Makers: The Antarctic Ice Sheet and Sea Level, Australian Antarctic Division Data Centre. [PDF link below]
• Opening the floodgates - a science briefing on Antarctica and sea-level rise
• Galton-Fenzi, B.K., H. A. Fricker, J.N. Bassis, A.J. Crawford, N. Gomez and C. Schoof. (In press, 2025) The Antarctic Ice Sheet and sea level: contemporary changes and future projections, in M. Meredith, J. Melbourne-Thomas, M. Raphael and A. Naveira Garabato (eds), "Antarctica and Planet Earth", Taylor & Francis Group. (Link when published: https://doi.org/10.4324/9781003406471)