Permafrost Experiments Mimic Alaska’s Climate-Changed Future

This story originally appeared on High Country News and is part of the Climate Desk collaboration.

Struggling to keep my balance, I teeter along a narrow plankway that wends through the rolling foothills near Denali National Park and Preserve. Just ahead, Northern Arizona University ecologist Ted Schuur, a lanky 6-footer, leads the way to Eight Mile Lake, his research field site since 2003. Occasionally I slip off the planks onto the squishy vegetative carpet below. The feathery mosses, sedges and diminutive shrubs that grow here—Labrador tea, low bush cranberry, bog rosemary—are well-adapted to wet, acidic soils.

Rounding the top of a knoll, we look down on an expanse of tundra that bristles with so many sensors and cables that it resembles an outdoor ICU ward. At the center of the site stands a gas-sensing tower that sniffs out the carbon dioxide drifting through the air from as far away as a quarter of a mile. At ground level, polycarbonate chambers placed atop the tundra whoosh as their tops periodically shut, then open, then shut again. Their job, I learn, is to trap the carbon dioxide rising from the surface and shunt it to an instrument that measures the amount.

The objective is to keep a running tally of CO₂ as it’s inhaled and exhaled by plants and soil microbes, but not merely in the here and now. By artificially warming selected patches of tundra, Schuur’s open-air experiment aims to mimic the future, when air temperatures in Alaska are expected to be significantly higher. By 2100, the state is projected to see an additional warming of at least 4 to 5 degrees Fahrenheit over what’s already occurred, and that’s under the most optimistic scenario. Already, the tundra here is leaking carbon dioxide to the atmosphere, according to recent satellite-based measurements. The question Schuur is hoping to answer: As the region continues to warm, just how much more carbon dioxide will it contribute to the global pool?

Along with terrestrial and aquatic plants, the soil microbes that decompose organic matter are major players in the global carbon cycle. In the lingo of climate science, plants are “sinks” for carbon. Through the sunlight-driven process of photosynthesis, they lock up more carbon dioxide than they release, thus keeping it out of the atmosphere. By contrast, soil microbes that decompose organic matter are “sources” that burp out micro-bubbles of CO₂ night and day, winter and summer.

Schuur draws my attention to the stack of drift-catching snow fences that, come October, researchers will array around half a dozen experimental plots, then laboriously remove again in April. Snow is an excellent insulator, he explains: “It’s like a giant blanket.” Beneath the drifts, Schuur and his colleagues have found, the ground can stay a good 3 to 4 degrees Fahrenheit warmer than it does in the unfenced control plots, thereby accelerating the warming that occurs in spring.

The impacts of this manipulation are many. Triggered by the extra warmth, subsidence caused by slumping permafrost has lowered the surface of the experimental plots by several feet. The depth to which the soil thaws at the end of summer has likewise increased, indicating that the top layer of what used to be permafrost has added more organic matter to the microbial dining table.

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Most dramatic of all is the speed-up in the carbon cycle that Schuur and his colleagues have observed. Plants in the experimental plots grow faster, and sop up more carbon dioxide, than do plants in the cooler control plots. Soil microbes in the experimental plots have likewise increased their metabolic rate. But plants lock up carbon only during the growing season, whereas microbial activity continues year round. On an annual basis, the CO₂ microbes release more than offsets the amount removed by plants.

Given the present rate of temperature rise, the imbalance between plant uptake and microbial release of CO₂ may well grow. By the end of the century, Schuur says, the amount of carbon the world’s permafrost zone transfers to the atmosphere each year could be in the range of 1 billion tons, comparable to the present-day emissions of Germany or Japan.

Still unaccounted for, though, is the significant amount of carbon that appears to have vanished from underlying soils—about 20 times the amount Schuur and his colleagues have detected in the air. “Wow,” Schuur remembers saying to himself when he realized the size of the discrepancy. “This is a surprise.” Perhaps water seeping downslope is ferrying the missing carbon into streams, rivers and lakes, including Eight Mile Lake, or shunting it to swampy, oxygen-poor pockets of soil ruled by microbes that convert carbon to methane.

How much of the carbon coming out of permafrost will be transformed into methane? That’s another question Schuur is starting to tackle, for while methane is less abundant than CO₂, it has 30 times the heat-trapping power over the course of a century. On the way back to the car, Schuur points out a clump of cotton grass whose partly hollow stems pipe methane into the atmosphere. “What matters is not that carbon goes in and out,” he says. “The important question is, what’s the net effect?”

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