Warming in Arctic weakens circumpolar wind that hems in cold air, letting it spill south

Climate change, harsh winters tied


Millions of people in northern Europe are still battling snow and ice, wondering why they are being punished with bitter cold when — officially — spring has arrived and Earth is in the grip of global warming.

Yet some scientists, eyeing the fourth year in a row of exceptionally harsh late winter weather in parts of Europe and North America, suggest warming is precisely the problem. In a complex tango between ocean and atmosphere, warming is causing icy polar air to be displaced southward, they contend.

“The linkage is becoming clearer and clearer . . . although the science has not yet been settled,” said Dim Coumou of the Potsdam Institute for Climate Impact Research near Berlin.

The theory derives from a long-studied Arctic phenomenon called a positive feedback — in plain words, a vicious circle.

Rising temperatures are melting the Arctic’s floating cap of sea ice, especially in summer. In 1979, when satellite measurements began, summer ice covered some 7 million sq. km, roughly equivalent to 90 percent the area of Australia. Last summer, ice hit its lowest extent on record, at just 3.4 million sq. km.

Take away reflective ice, and you have a dark sea that absorbs solar radiation, which in turn reinforces the melting, and so on.

But the theory suggests the added heat, stored over a vast area of surface water, is also gradually released into the atmosphere during the Arctic autumn. It increases air pressure and moisture in the Arctic, reducing the temperature differential with lower latitudes.

What happens next is that the polar vortex, a powerful circular wind that pens in Arctic air, begins to weaken. A mass of moist cold air spills southward, bringing snow and chill down into North America and Europe.

The cold air tends to stay there because of changes to the jet stream. Instead of circling the Northern Hemisphere in a sturdy and predictable fashion, this high-altitude wind takes a looping path over the United States, the Atlantic and Europe. The southern parts of the loops get a bout of cold weather that becomes stalled in place.

“Heat that is stored in the (Arctic) ocean can rapidly transfer to the atmosphere, and this affects the dynamics” of Northern Hemisphere weather patterns, Coumou said in an interview. “We’ve had a couple of winters (in Europe) where you’ve had rather shorter-term cold spells, of a duration of maybe 10, 20, 30 days. . . . It’s been the same in the continental U.S. and Canada, where they’ve seen similar quite bizarre cold spells but of a relatively shorter period.”

Charles Greene, director of the Ocean Resources and Ecosystems Program at Cornell University in New York, said Arctic warming added a joker or two to the climate pack. “With the changes in sea ice, we set up a situation where we stack the deck, increasing the probability of these invasions of cold Arctic air,” he said. “But what’s less predictable is which regions in the midlatitudes will get hit. We’re not sure yet how it will interact with other parts of the climate system in any given year, for instance how it will interact with El Nino and La Nina.”

Greene also postulates that Superstorm Sandy last October wreaked its havoc because of a high-pressure zone over Greenland, possibly strengthened by changes triggered by sea-ice loss in the Arctic. Like a barrier closing off a street, this mass of air forced Sandy to turn sharply west so that it slammed into the U.S. East Coast. Normally, late season hurricanes follow a northeastern track and peter out at sea.