NASA study sheds new light on the future of a key Antarctic glacier
Scientists at NASA found evidence that West Antarctica’s Thwaites Glacier, currently responsible for about 1 percent of global sea level rise, will continue to melt, but slower than previously thought. The study is a first, having combined computer models that interact and evolve together.
Thwaites Glacier covers an area nearly as large as the state of Washington (70,000 square miles, or 182,000 square kilometers). Satellite measurements show that its rate of ice loss has doubled since the 1990s and the glacier has the potential to add several inches to global sea levels.
NASA’s Jet Propulsion Laboratory scientist Helene Seroussi led a new study that is the first to combine two computer models, one of the Antarctic ice sheet and one of the Southern Ocean, in such a way that the models interact and evolve together throughout an experiment — creating what scientists call a coupled model.
According to a press release, Seroussi and colleagues at JPL and the University of California at Irvine (UCI) used an ocean model developed at the Massachusetts Institute of Technology in Cambridge with an ice sheet model developed at JPL and UCI. They used data from NASA’s Operation Icebridge and other airborne and satellite observations, both to set up the numerical model simulations and to check how well the models reproduced observed changes.
Glaciers have beds just as rivers do, and most glacier beds slope downhill in the same direction the glacier is flowing, as a riverbed does. Thwaites Glacier’s bed does the opposite: it slopes uphill in the direction of flow. The bedrock under the glacier’s ocean front is higher than bedrock farther inland, which has been pushed down over the millennia by its heavy burden of ice.
Thwaites has lost so much ice that it floats where it used to be attached to bedrock. That has opened a passageway underneath the glacier where ocean water can seep in.
In this part of Antarctica, the warm, salty, deep ocean current that circles the continent comes near land, and warm water can flow onto the continental shelf. This warm seawater now seeps beneath Thwaites Glacier, melting it from below.
As the glacier continues to melt, grow thinner and float off bedrock farther and farther inland, new cavities will continue to open up. Because the bedrock slopes downhill, there’s no natural barrier to stop this process. Earlier modeling studies assumed that water in the new cavities would continue to melt the glacial underside at the same rate that it’s melting now.
Seroussi’s coupled model found that water circulation is more restricted in these narrow spaces, and as a result, the water will melt the ice more slowly than previously thought.
Seroussi noted that critical factors affecting Thwaites, such as how nearby ocean temperatures will change, are still unknown and represented by different scenarios in different studies. However, “Our results shift the estimates for sea level rise to smaller numbers regardless of the scenario,” she said.
The study is titled “Continued retreat of Thwaites Glacier, West Antarctica, controlled by bed topography and ocean circulation.”