Research: Arctic’s role as climate moderator threatened
By Eric Sorensen, WSU science writer
SAN FRANCISCO – Scientists in a rare and sometimes dangerous study of the Arctic have found that the region’s thinning sea ice is more prone to melting and storms, threatening its role as a moderator of the planet’s climate.
The researchers reached this conclusion after spending several months last year, much of it on a ship frozen into the ice, as part of the first wintertime expedition to examine the younger, thinner sea ice that typifies the “new Arctic.” They discussed their findings today in the fall meeting of the American Geophysical Union.
Thin ice more vulnerable
“Many things we experienced took us by surprise,” said Mats Granskog, a research scientist at the Norwegian Polar Institute and chief scientist of the Norwegian young sea ICE, or N-ICE2015 project. “We saw that the new Arctic, with much thinner sea ice only three to four feet thick, functions much differently from the Arctic we knew only 20 years ago, when the ice was much thicker.”
While they can’t specifically link what they saw to climate change, the N-ICE researchers said they worry that the reduced sea-ice coverage and thickness will lead to even more melting, the so-called “Arctic amplification:” Half of the solar energy that hits Arctic snow gets reflected back into space. But when the snow is replaced by open water, when “white turns to blue,” most of the energy gets absorbed and in turn helps melt even more ice.
The researchers said what ice is left is particularly vulnerable. The thinner and younger ice works differently, said Granskog. It moves faster, breaks up more easily and is more vulnerable to winds and storms.
WSU researcher studies how winds stress ice
Von Walden, a Washington State University professor of civil and environmental engineering, spent a month on the project and documented the first observations of how winter storms affect the surface energy balance of the young, thinner sea ice. He saw how high winds move the ice, stressing and breaking it.
The winds also transport large amounts of heat and moisture. One winter storm raised the surface temperature from -40 F to 32 F in less than 48 hours, while the moisture in the air increased by 10 times. These storms also bring clouds.
All of these factors significantly warm the surface at a time when there is no sunlight, he said.
New algae blooms act differently
Amelie Meyer, an oceanographer for the Norwegian Polar Institute, saw how storms can move the ice so fast that warm, 40 F water rises tens to hundreds of feet to melt the underside of the ice. In the summer, as much as 10 inches of ice could melt in one day.
At one point, the scientists saw vast stretches of ice break up in a few hours, forcing them to scramble and even wade through frozen water to retrieve their equipment.
The researchers also observed the first phytoplankton bloom under snow-covered ice, as additional light passing through leads, or cracks, triggers its early growth. Traditional Arctic under-ice blooms tend to sink to the deep ocean, sequestering carbon in a sort of “carbon pump.” But this bloom did not sink as much as expected due to a different algae that grew in it.
Such changes could have significant implications for Arctic ecology and the movement of carbon, the researchers said.
Links to photos, video and documents related to this announcement, including a fact sheet and photo credit information, can be found at http://fallmeeting.agu.org/2016/press-item/first-results-from-the-norwegian-young-sea-ice-expedition/.
News media contact:
Eric Sorensen, WSU science writer, 509-335-4846, eric.sorensen@wsu.edu
