Capsizing Icebergs on the Rise in Greenland
Icebergs in Greenland are flipping over like dominoes more often than they have in the past.
In a fjord near Jakobshavn Glacier in Greenland, glaciologist Jason Amundson captured this 900-meter-high iceberg capsizing, ice crystals flaring up around it like stage smoke. A process like this can take about five minutes and send waves churning through the floating ice around it. “It sounds sort of like thunder, or trains in the distance,” says Amundson, who’s also an assistant professor of geophysics at the University of Alaska Southeast. (For more on Jakobshavn Glacier, listen to this SciFri segment.)
This picture, taken seven years ago, represents a scene that’s become common in Greenland: More and more, icebergs are flipping over after they calve, or break away, from glaciers, according to Amundson. The reason has to do with the dimensions of the bergs—they’re slimmer than they used to be. The narrower the berg, the less stable it is, and the more likely it is to overturn.
Icebergs used to break off in much larger, tabular chunks, according to Amundson. But “we don’t tend to see that kind of calving anymore,” he says, “It tends to be this kind of sliver that ends up calving,” like the one in his photograph.
The reason can likely be attributed to changes in climate and ocean conditions that have resulted in the loss of floating ice shelves, which are essentially extensions of glaciers that protrude from land into the sea. Melting ice shelves are thinner and more inclined to break as they retreat toward the land, where the ice encounters a natural stress that makes it bend. “This provides a natural fulcrum or ‘breaking point’ for the ice,” says Justin Burton, a physics professor at Emory University in Georgia who studies iceberg calving in Greenland.
Amundson adds that as glacial ice retreats, it flows faster, resulting in more fractures in the ice. “So that could contribute to the [narrower] size and shape of the icebergs,” he says.
A better understanding of calving behavior could shed light on how ice cover and sea levels might change in the future. “People want to model the coverage of ice on our planet because it’s an important indicator of climate change,” says Burton. “But in order to model it, you have to know how much is coming in and going out.”
Burton and Amundson are currently applying the tools of seismology to study iceberg calving. “Some of the calving events, like the one in the photo, produce seismic signals that are detectable globally,” says Amundson. If researchers can figure out how to interpret those signals, they might learn more about what’s happening at the interface between glaciers and the ocean.