Mother Jones
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This story first appeared on the Wired website and is reproduced here as part of the Climate Desk collaboration.
For nearly two weeks, the nation has been transfixed by wildfire spreading through Yosemite National Park, threatening to pollute San Francisco’s water supply and destroy some of America’s most cherished landscapes. As terrible as the Rim Fire seems, though, the question of its long-term effects, and whether in some ways it could actually be ecologically beneficial, is a complicated one.
Some parts of Yosemite may be radically altered, entering entire new ecological states. Yet others may be restored to historical conditions that prevailed for for thousands of years from the last Ice Age’s end until the 19th century, when short-sighted fire management disrupted natural fire cycles and transformed the landscape.
In certain areas, “you could absolutely consider it a rebooting, getting the system back to the way it used to be,” said fire ecologist Andrea Thode of Northern Arizona University. “But where there’s a high-severity fire in a system that wasn’t used to having high-severity fires, you’re creating a new system.”
The Rim Fire now covers 300 square miles, making it the largest fire in Yosemite’s recent history and the sixth-largest in California’s. It’s also the latest in a series of exceptionally large fires that over the last several years have burned across the western and southwestern United States.
Fire is a natural, inevitable phenomenon, and one to which western North American ecologies are well-adapted, and even require to sustain themselves. The new fires, though, fueled by drought, a warming climate and forest mismanagement—in particular the buildup of small trees and shrubs caused by decades of fire suppression—may reach sizes and intensities too severe for existing ecosystems to withstand.
The Rim Fire may offer some of both patterns. At high elevations, vegetatively dominated by shrubs and short-needled conifers that produce a dense, slow-to-burn mat of ground cover, fires historically occurred every few hundred years, and they were often intense, reaching the crowns of trees. In such areas, the current fire will fit the usual cycle, said Thode.
Decades- and centuries-old seeds, which have remained dormant in the ground awaiting a suitable moment, will be cracked open by the heat, explained Thode. Exposed to moisture, they’ll begin to germinate and start a process of vegetative succession that results again in forests.
At middle elevations, where most of the Rim Fire is currently concentrated, a different fire dynamic prevails. Those forests are dominated by long-needled conifers that produce a fluffy, fast-burning ground cover. Left undisturbed, fires occur regularly.
“Up until the middle of the 20th century, the forests of that area would burn very frequently. Fires would go through them every five to 12 years,” said Carl Skinner, a U.S. Forest Service ecologist who specializes in relationships between fire and vegetation in northern California. “Because the fires burned as frequently as they did, it kept fuels from accumulating.”
A desire to protect houses, commercial timber and conservation lands by extinguishing these small, frequent fires changed the dynamic. Without fire, dead wood accumulated and small trees grew, creating a forest that’s both exceptionally flammable and structurally suited for transferring flames from ground to tree-crown level, at which point small burns can become infernos.
Though since the 1970s some fires have been allowed to burn naturally in the western parts of Yosemite, that’s not the case where the Rim Fire now burns, said Skinner. An open question, then, is just how big and hot it will burn.
Aerial diagram (above) and three-dimensional recreation (below) of 10-acre plot prior to logging in 1929 (left) and in 2008, after 79 years of fire suppression (right). USDA/USFS/Pacific Southwest Research Station
Where the fire is extremely intense, incinerating soil seed banks and root structures from which new trees would quickly sprout, the forest won’t come back, said Skinner.
Those areas will become dominated by dense, fast-growing shrubs that burn naturally every few years, killing young trees and creating a sort of ecological lock-in.
If the fire burns at lower intensities, though, it could result in a sort of ecological recalibration, said Skinner. In his work with fellow US Forest Service ecologist Eric Knapp at the Stanislaus-Tuolumne Experimental Forest, Skinner has found that Yosemite’s contemporary, fire-suppressed forests are actually far more homogeneous and less diverse than a century ago.
The fire could “move the forests in a trajectory that’s more like the historical,” said Skinner, both reducing the likelihood of large future fires and generating a mosaic of habitats that contain richer plant and animal communities.
“It may well be that, across a large landscape, certain plants and animals are adapted to having a certain amount of young forest recovering after disturbances,” said forest ecologist Dan Binkley of Colorado State University. “If we’ve had a century of fires, the landscape might not have enough of this.”
As of now it’s not known which parts of Yosemite have burned at tipping-point levels and which have stayed within historical, possibly rejuvenating parameters. That will become apparent in years to come. In the meantime, said Binkley, the Rim Fire and other megafires of recent years have demonstrated that fire should not always be fought.
“If you want to preserve something, you have to put it in a jar and pickle it. If you have a living forest, getting older and older, it’s not something we have an option to conserve in an unchanging way,” he said. “Some fires are going to be necessary if we want to sustain these old forests.”
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