FAIRBANKS, Alaska — Hundreds of wildfires are continually whipping across this state this summer, leaving in their wake millions of acres of charred trees and blackened earth.
At the Fairbanks compound of the state’s Division of Forestry recently, workers were busy washing a mountain of soot-covered fire hoses, which stood in piles roughly six feet high and 100 feet long. About 3,500 smokejumpers, hotshot crews, helicopter teams and other workers have traveled to Alaska this year from across the country and Canada. And they have collectively deployed about 830 miles of hose this year to fight fires.
An hour north of the state’s second-biggest city, firefighters were attacking flames stretching across more than 31,000 acres, including an area close to the Trans-Alaska pipeline system, which stretches from Prudhoe Bay to Valdez. And that’s just one of about 300 fires at any given time.
“People don’t fathom how big Alaska is. You can have a 300,000-acre fire, and nobody knows anything about it, because nothing’s been done about it, because of where it is,” says Tim Mowry, spokesman for the Alaska Division of Forestry.
The staggering 2015 Alaska wildfire season may soon be the state’s worst ever, with almost 5 million acres already burned — an area larger than Connecticut. The pace of the burn has moderated in the last week, but scientists say the fires are just the latest indicator of a climatic transformation that is remaking this state — its forests, its coasts, its glaciers, and perhaps most of all, the frozen ground beneath — more than any other in America.
Alaska has already warmed by more than 3 degrees Fahrenheit in the past half-century, much more than the continental United States. The consequences have included an annual loss of 75 billion metric tons of ice from its iconic glaciers — including those covering the slopes of Denali, the highest peak in North America — and the destabilization of permafrost, the frozen ground that underlies 80 percent of the state and whose thaw can undermine buildings, roads and infrastructure.
Also pummeled are the state’s Arctic coastlines, which are facing intense erosion as seas rise and declining sea ice exposes shores and barrier islands to punishing waves. The situation has grown so bad that some native communities, including tiny Kivalina, Alaska, sitting on a barrier island along the Chukchi Sea, may now have to be relocated, given the dangerous loss of land to the sea.
Earlier snowmelt transforms the state further. In 2015, the starting place of the Iditarod sled dog race had to be relocated north, to Fairbanks, because there wasn’t enough snow on the ground in some places.
But arguably the most dramatic change — threatening to transform the state’s 126 million acres of forests and, perhaps, worsen climate change in the process — is occurring with the state’s wildfires.
Alaska’s forests make up 17 percent of the U.S. total, and while they’ve always burned, they may now be entering a major new combustive period. The blazes are so intense and extensive that they could transform an entire ecosystem, even as the fires also hasten the thawing of permafrost — which itself contains vast quantities of ancient carbon, ready to be emitted to the air.
“The more severe the fire, the deeper that it burns through the organic layer, the higher the chance it will go through this complete conversion,” says Ted Schuur, an ecologist at Northern Arizona University who spends summers in Fairbanks and specializes in studying permafrost. “What happens in the summer of 2015 has the potential to change the whole trajectory of [the burned area] for the next 100 years or more.”
The nearly 5 million acres burned in Alaska so far this year dwarfs all burning across all states in the Lower 48. Three of Alaska’s top five wildfire seasons have occurred since the year 2004, with 16 million acres burned between them (2004, 2005 and 2015).
Indeed, the 2015 fire season is a poster child for how strongly climatic factors influence wildfire dangers — it’s one in which most fires have been caused by lightning, rather than people. The whole system was simply ready to burn.
In May, Alaska experienced its hottest temperatures in 91 years of record-keeping, 7.1 degrees Fahrenheit above average. As a result, seasonal snowmelt was well ahead of schedule, allowing the ground to dry out sooner.
In late June, 152 fires were lighted in a single weekend, mostly by lightning strikes. Since then, the number of acres burned has leapt forward by sometimes as much as 300,000 a day. The current record year, 2004, saw 6.59 million acres burned, but 2015 is ahead of its pace — although thanks to recent rainfall, the pace of burn has slowed.
This year is part of a trend that should continue as Alaska gets warmer and drier, says Scott Rupp, a professor of forestry at the University of Alaska at Fairbanks, who also heads the university’s Scenarios Network for Alaska + Arctic Planning. “What we’ve been seeing in the last two decades is an increase in the extent of area burned from year to year and a fairly substantial increase in the frequency of these very large fire years,” Rupp says.
More troubling to climate scientists, the fires could contribute to the worsening of climate change.
On a walk into an unburned black spruce forest south of Fairbanks recently, ecologist Schuur dug a foot down into the soft and spongy duff layer with his pruning saw, pulling out a long core of organic material. “This is, like, 50 percent carbon,” he said. Reaching down half an arm’s length into the hole, through the duff layer’s cooling insulation, one can then touch frozen Earth: the beginning of the permafrost layer.
Intense wildfires burn not only trees — sending the carbon they contain into the atmosphere — but also deep into the duff layer, sending up still more carbon. Sometimes, fires burn all the way down to the mineral soil. When that happens, the frozen ground loses its insulation, even as the scorched earth then absorbs more heat from Alaska’s steady summer sun — and permafrost can thaw, sometimes so much that the ground sinks and becomes bumpy and hilly as it loses solid ice mass.
“Everything’s connected,” says Bob Bolton, a hydrologist at the University of Alaska at Fairbanks. “The climate, the permafrost, the water, the fires. You can’t look at one without looking at the other. Changes in one changes everything else. It’s a really, really sensitive system.”
That’s why changing it can have such big affects. Indeed, the trees that return after an intense Alaskan fire tend to be aspens and birches, which are more fire-resistant, rather than evergreen spruces. The change could have major consequences, such as harming habitats for iconic species such as caribou, which feed on lichen that grow at the bases of black spruce. But it also means that vast Alaska wildfires may not only be worsening because of climate change — but also have climate change consequences.
“What’s happening here really is affecting everyone in the world, because we’re all linked by our atmosphere,” says Nancy Fresco, a researcher at the University of Alaska at Fairbanks, who studies Arctic ecosystems and climate adaptation.
Press link for more: Chris Mooney |washingtonpost.com
Reblogged this on patricktsudlow and commented:
What our politicians do not seem to understand, is that climate change is an exponential occurrence. Which means, we need to be drastically reducing our Green House Gas (#GHG) emissions. Not continuing with exploitation of fossil fuels or burning biomass. The human race does not have fifty years, catastrophic climate change can occur any time now. So even nuclear, which is not renewable or carbon free, will not prevent the inevitable if we do not reduce our emissions.
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Please explain where you see an exponential
Sorry about the delay in replying to you. The rise in carbon emissions alone, has been an exponential rise. Added to the increased methane being released by continued fossil fuel extraction, plus from areas of permafrost thawing. All the positive feedbacks will just accelerate the process. http://bradblog.com/?p=11287
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