Local destabilization can cause complete loss of West Antarctica's ice masses
The huge West Antarctic ice sheet would collapse completely if the comparatively small Amundsen Basin is destabilized, scientists find
- Date:
- November 2, 2015
- Source:
- Potsdam Institute for Climate Impact Research (PIK)
- Summary:
- A full discharge of ice into the ocean is calculated to yield about 3 meters of sea-level rise. Recent studies indicated that this area of the ice continent is already losing stability, making it the first element in the climate system about to tip. The new publication for the first time shows the inevitable consequence of such an event. According to the computer simulations, a few decades of ocean warming can start an ice loss that continues for centuries or even millennia.
The huge West Antarctic ice sheet would collapse completely if the comparatively small Amundsen Basin is destabilized, scientists of the Potsdam Institute for Climate Impact Research find. A full discharge of ice into the ocean is calculated to yield about 3 meters of sea-level rise. Recent studies indicated that this area of the ice continent is already losing stability, making it the first element in the climate system about to tip. The new publication for the first time shows the inevitable consequence of such an event. According to the computer simulations, a few decades of ocean warming can start an ice loss that continues for centuries or even millennia.
"What we call the eternal ice of Antarctica unfortunately turns out not to be eternal at all," says Johannes Feldmann, lead author of the study to be published in the Proceedings of the National Academy of Sciences (PNAS). "Once the ice masses get perturbed, which is what is happening today, they respond in a non-linear way: there is a relatively sudden breakdown of stability after a long period during which little change can be found."
"A few decades can kickstart change going on for millennia"
This is what is expressed by the concept of tipping elements: pushed too far, they fall over into another state. This also applies to, for instance, the Amazon rainforest, and the Indian Monsoon system. In parts of Antarctica, the natural ice-flow into the ocean would substantially and permanently increase.
Ocean warming is slowly melting the ice shelves from beneath, those floating extensions of the land ice. Large portions of the West Antarctic ice sheet are grounded on bedrock below sea level and generally slope downwards in an inland direction. Ice loss can make the grounding line retreat, thereby exposing more and more ice to the slightly warmer ocean water -- further accelerating the retreat.
"In our simulations 60 years of melting at the presently observed rate are enough to launch a process which is then unstoppable and goes on for thousands of years," Feldmann says. This would eventually yield at least 3 meters of sea-level rise. "This certainly is a long process," Feldmann says. "But it's likely starting right now."
The greenhouse-gas emission factor
"So far we lack sufficient evidence to tell whether or not the Amundsen ice destabilization is due to greenhouse gases and the resulting global warming," says co-author and IPCC sea-level expert Anders Levermann, also from the Potsdam Institute. "But it is clear that further greenhouse-gas emission will heighten the risk of an ice collapse in West Antarctica and more unstoppable sea-level rise."
"That is not something we have to be afraid of, because it develops slowly," concludes Levermann. "But it might be something to worry about, because it would destroy our future heritage by consuming the cities we live in -- unless we reduce carbon emission quickly."
Story Source:
The above post is reprinted from materials provided by Potsdam Institute for Climate Impact Research (PIK). Note: Materials may be edited for content and length.
Journal Reference:
- Johannes Feldmann, Anders Levermann. Collapse of the West Antarctic Ice Sheet after local destabilization of the Amundsen Basin. Proceedings of the National Academy of Sciences, 2015; 201512482 DOI: 10.1073/pnas.1512482112
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