We studied how the Antarctic ice sheet advanced and retreated over 10,000 years. It holds warnings for the future
Jones
Alarming stories from Antarctica are now more frequent than ever; the ice surface is melting, floating ice shelves are collapsing and glaciers are flowing faster into the ocean.
Antarctica will be the largest source of future sea-level rise. Yet scientists don’t know exactly how this melting will unfold as the climate warms.
Our latest research looks at how the Antarctic ice sheet advanced and retreated over the past 10,000 years. It holds stark warnings, and possibly some hope, for the future.
The current imbalance
Future sea-level rise presents one of the most significant challenges of climate change, with economic, environmental and societal impacts expected for coastal communities around the globe.
While it seems like a distant issue, the changes in Antarctica may soon be felt on our doorsteps, in the form of rising sea levels.
Antarctica is home to the world’s largest single mass of ice: the Antarctic ice sheet. This body of glacier ice is several kilometres thick, nestled on top of solid land. It covers entire mountain ranges beneath it.
The ice sheet “flows” over the land from the Antarctic interior and towards the surrounding ocean. As a whole it remains a solid mass, but its shape slowly deforms as the ice crystals move around.
While the ice sheet flows outward, snowfall from above replenishes it. This cycle is supposed to keep the system in balance, wherein balance is achieved when the ice sheet is gaining the same amount of ice as it’s losing to the ocean each year.
However, satellites keeping watch from above show the ice sheet is currently not in balance. Over the past 40 years, it has lost more ice than it has gained. The result has been global rising sea levels.
But these historical observations span only four decades, limiting our understanding of how the ice sheet responds to climate change over much longer periods.
We wanted to look further back in time – before satellites – and even before the first polar explorers. For this, we needed natural archives.
Digging up Antarctica’s past
We brought together various natural archives to unearth how the Antarctic ice sheet changed over the past 10,000 years or so. These included:
- ice cores collected from Antarctica’s remote interior, which can show us how snow accumulated in the past
- rocks collected from exposed mountain peaks, which reveal how the ice sheet has thickened or thinned with time
- sediment cores collected from the seafloor, which reveal how the ice sheet margin – where the edge of the land ice meets the ocean – advanced or retreated
- lake mud and old beaches, which reveal how the coastline changed in response to the ice sheet growing or shrinking.
When we started our research, I wasn’t sure what to expect. After all, this period of time was long considered fairly dull, with only small changes to the ice margin.
Nevertheless, we studied the many different natural archive one by one. The work felt like a 1000-piece jigsaw puzzle, full of irregular-shaped pieces and seemingly no straight edge. But once we put them together, the pieces lined up and the picture was clear.
Most striking was a period of ice loss that took place in all regions of Antarctica about 10,000 to 5,000 years ago. It resulted in many metres of sea-level rise globally.
In some regions of Antarctica, however, this ice loss was then followed by ice gain during the past 5,000 years – and a corresponding global sea-level fall – as the ice sheet margin advanced to where it is today.
A warning
Understanding how and why the Antarctic ice sheet changed in this fashion offers lessons for the future.
The first lesson is more of a warning. The period of ice loss from 10,000 to 5,000 years ago was rapid, occurring at a similar rate to the most dramatically changing parts of the Antarctic ice sheet today.
We think it was likely the result of warm ocean water melting the underside of floating ice shelves – something that has also happened in recent decades. These ice shelves hold back the ice on land, so once they’re removed the ice on the land flows faster into the ocean.
In the future, it’s predicted ice loss will accelerate as the ice sheet retreats into basins below sea level. This may already be under way in some regions of Antarctica. And based on what happened in the past, the resulting ice loss could persist for centuries.
Bouncing back
The second lesson from our work may bring some hope. Some 5000 years ago the ice sheet margin stopped retreating in most locations, and in some regions actually started to advance. One explanation for this relates to the previous period of ice loss.
Before the ice began melting away, the Antarctic ice sheet was much heavier, and its weight pushed down into the Earth’s crust (which sits atop a molten interior). As the ice sheet melted and became lighter, the land beneath it would have lifted up – effectively hauling the ice out of the ocean.
Another possible explanation is climate change. At Antarctica’s coastal fringe, the ocean may have temporarily switched from warmer to cooler waters around the time the ice sheet began advancing again. At the same time, more snowfall took place at the top of the ice sheet.
Our research supports the idea that the Antarctic ice sheet is poised to lose more ice and raise sea levels – particularly if the ocean continues to warm.
It also suggests uplift of the land and increased snowfall have the potential to slow or offset ice loss. However, this effect is not certain.
The past can never be a perfect test for the future. And considering the planet is warming faster now than it was back then, we must err on the side of caution.
This article originally appeared on The Conversation.
About the Authors
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Richard jones
Research Fellow, School of Earth Atmosphere and Environment
Richard's work seeks to better understand the response of polar ice sheets, and corresponding sea level, to a changing climate. His research primarily focuses on the behaviour of ice sheets in the geological past, using a combination of geochronological and numerical modelling approaches.
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