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Auburn researcher co-authors new study finding deciduous trees offset carbon loss from Alaskan boreal fires, published in Science

By April 15, 2021 June 3rd, 2021 No Comments

Heather Alexander, assistant professor of forest ecology in the School of Forestry and Wildlife Sciences at Auburn University, is co-author of a new research study published this week in the journal Science demonstrating that the deciduous trees replacing burned spruce forests more than make up for carbon and nitrogen loss, storing more carbon and accumulating it four times faster over a 100-year fire interval.

More severe and frequent fires in the Alaskan boreal forest are releasing vast stores of carbon and nitrogen from burned trees and soil into the atmosphere, a trend that is widely thought to accelerate climate warming.

The study, led by a team of researchers at the Center for Ecosystem Science and Society at Northern Arizona University, counters this theory and suggests that faster-growing, less flammable deciduous forests may act as a stabilizing ‘firebreak’ against escalating fire patterns and nutrient loss in the region.

“I was surprised that deciduous trees could replenish lost carbon so effectively and efficiently,” said Alexander. “Even though considerable carbon is combusted and emitted into the atmosphere when black spruce forests burn severely, the deciduous trees that often replace them have an amazing ability to recapture and store carbon in their aboveground leaves and wood.”

The study began in the wake of the dramatic 2004 fire season in Alaska when an area seven times the long-term average burned. Historically, more than half of this forested terrain has been dominated by black spruce, but after fire, faster-growing aspen and birch are replacing some of these stands.

The team, made up of researchers from Northern Arizona University, University of Alaska Fairbanks, Auburn University, University of Florida and University of Saskatchewan, surveyed 75 black spruce stands that burned in 2004 and followed their recovery over the next 13 years. They also collected a range of data from trees and soils of different ages and burn severities to construct a chronosequence, a kind of scientific time-lapse that lets researchers fast-forward through a 100-year fire cycle to see how forests recover and change.

“In 2005, I thought that there was no way these forests could recover the carbon they lost in this fire,” said Michelle Mack, a professor of biology at Northern Arizona University and the lead author of the study. “The literature is full of papers suggesting deeper, more severe fires burn more carbon than can be replaced before the next fire. But not only did we see these deciduous trees make up for those losses, they did so rapidly.”

The team found that the new aspen and birch trees where the black spruce burned accumulated carbon and nitrogen more quickly than the spruce, storing most of it in their wood and leaves as opposed to the soil organic layer. And at the end of a projected 100-year cycle, the deciduous stands had recovered as much nitrogen as was lost to fire, and more carbon than was lost, resulting in an increase in the net ecosystem carbon balance. Calculating this balance is critical as scientists work to understand the way these northern forests are changing and the effects of those changes on the global carbon picture.

“In a region with only five common tree species, this study shows how changes in tree composition can dramatically alter patterns of carbon storage in boreal forests,” said Jill Johnstone, a northern researcher at University of Alaska-Fairbanks and co-author of the study.

“Carbon is just one piece of the puzzle,” said Mack, who said deciduous forests have other important feedbacks, or interconnected effects, on climate. “We know these forests help cool regional climate, and we know that they are less ignitable, so fires are less likely to spread. Taken together, these effects create a relatively strong set of stabilizing climate feedbacks in the boreal forest.”

But there is a lot that researchers don’t know about the fate of deciduous boreal forests in a warmer world.

“As mature deciduous trees die, will they be replaced with trees with the same structure, composition and carbon storage abilities?” Alexander asked. “And will they recover from fire with the same carbon storage capacities?”

“Shifts from slow-growing black spruce to fast-growing deciduous species could balance out the impacts of the intensifying fire regime in the boreal forest,” said Isla Myers-Smith, a global change ecologist at University of Edinburgh who was not involved in the study. “But it remains to be seen how carbon gains balance losses in future with accelerated warming at high latitudes.”

Mack said continued climate warming may undo the carbon-sequestering gains these trees represent.

“The carbon should reside longer on the landscape because deciduous forests are less flammable. But flammability isn’t a constant,” Mack said. “The climate will pass a threshold where things get so hot and dry, even deciduous forests will burn. So, one question we need to ask is, how strong will the mitigating effect of low flammability be, and how long will it last?”

Permafrost carbon also complicates the picture. Though many of the sites in this study did not have permafrost near the soil surface, the permanently frozen ground is found across the boreal biome. As it thaws, permafrost releases stores of carbon and methane, potentially offsetting the storage gains by deciduous trees, Mack said.

“We will eventually pass a temperature threshold where negative feedbacks aren’t enough,” Mack said.

Janaki Alavalapati, dean of Auburn’s School of Forestry and Wildlife Sciences, added, “Boreal forests cover a large amount of the Earth’s terrestrial surface and store a huge portion of terrestrial carbon. They also have large impacts on climate through albedo, or surface energy reflectance. Any change in their composition or structure could be very important to global carbon and energy cycling, and thus climate.

“Dr. Alexander’s team has potentially unveiled a more accurate formula for carbon accounting that will help us better understand the role of boreal forests in climate feedbacks.”

The study was supported by the U.S. Department of Defense Strategic Environmental Research and Development Program, the NASA Arctic Boreal Vulnerability Experiment, the U.S. Joint Fire Sciences program and the Bonanza Creek Long-term Ecological Research Program, a program of the U.S. National Science Foundation and the USDA Forest Service.

(Written by Kate Peterson and Jamie Anderson)

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