Post-Wildfire Hazards: Toward a Better Understanding of When and How
Slope Failure May Occur
Boulder, Colo., USA: Across the western U.S., severe wildfires fueled by
tinder-dry vegetation have already burned more than 3.2 million hectares (8
million acres [as of the time of this press release])—an area the size of
Maryland—in 2020, and nearly six times that area burned this year in
Australia. And even though neither country’s worst-ever fire year is not
yet over, concerns are already mounting regarding the next hazard these
regions will face: dangerous and destructive debris flows.
Debris flows are fast-moving slurries of soil, rock, water, and vegetation
that are especially perilous because they usually occur without any
warning. Some debris flows are powerful enough to cart off everything in
their paths, including trees, boulders
(https://www.youtube.com/watch?v=OTuHQOHjC6Q), vehicles—and even homes.
Two years ago in Montecito, California, 23 people were killed and more than
400 homes damaged by a series of debris flows spawned by intense rain
falling on hills scorched by what at the time had been the largest fire in
California history.
To better understand the origin of these hazards, researchers at the
U.S. Geological Survey
(USGS; https://www.usgs.gov/natural-hazards/landslide-hazards) studied
slope failure at two sites in Southern California’s San Gabriel Mountains.
The first site burned in 2016 during the San Gabriel Complex fire, whereas
a second, nearby site was charred during the 2014 Colby fire.
The findings, presented Wednesday during the annual meeting of The Geological Society
of America, indicate there were major differences in slope failure between
the first and the third years following incineration. The results will help
inform land managers and residents about when and where debris flows and
other types of slope failure are more likely to occur.
“In the first year after each fire, we observed debris flows generated by
rainfall runoff,” says Francis Rengers, a USGS research geologist who led
the study. “But as we continued monitoring, we were surprised to see that a
storm with a higher rainfall intensity than the first year’s storms,
resulted in more than 280 shallow landslides, rather than debris flows, in
the third year.”
In contrast to debris flows, which have fluid-like behavior, landslides
glide as cohesive masses along a rupture plane. The researchers, including
scientists from the University of Arizona, the Desert Research Institute,
the USGS, and the German Research Centre (GFZ) believe this difference is
due to changes in how much water can infiltrate into the ground during
storms that follow wildfires. Because severe wildfires make soils more
water-repellent, Rengers says, rainfall tends to run off burned ground. “If
water is not soaking in,” he explains, “it’s flowing over the surface.” By
removing ground cover, wildfires also reduce a hillslope’s roughness, which
helps the slurry pick up speed. Incineration can also allow rainfall on
bare soil to create what he calls a “surface seal” that further increases
runoff.
Because landslides have much shorter runouts than debris flows, they pose
different hazards. “The landslides we observed would primarily impact local
infrastructure in the forest, such as roads, transmission lines, and
culverts,” Rengers explains. By contrast, he says, debris flows move
sediment much further downstream and therefore pose a hazard beyond the
steep, mountainous hillslopes. “Runoff-generated debris flows threaten
lives and property, including homes,” he says.
The results offer a ray of hope that the threat of slope failure has a
limited duration: the researchers found that within five years, the density
of landslides on burnt slopes in the San Gabriels was nearly equal to the
density in unburned regions. This indicates the vegetation in this region
recovers within half a decade.
Based on these observations, the researchers have developed a new
conceptual model of post-wildfire slope failure that has three distinct
stages. During the ‘no-recovery’ phase, increased runoff makes debris flows
more prevalent. Within a couple of years, increasing water percolation,
combined with the decay of roots from vegetation destroyed in the fire,
make the slopes more susceptible to landsliding during the ‘initial
recovery’ stage. After about five years, new roots become established
enough to stabilize the hillside in the final ‘fully recovered’ phase.
In the future, the researchers plan to investigate whether this same model
applies to other regions, such as the Rockies and the Pacific Northwest,
which also experienced severe wildfires this year. For now, the results
have immediate and practical applications for land managers who are dealing
with the 2020 aftermath. “Our model suggests that debris flows will be the
primary concern during the next one to two years, at least in the burn
scars in Southern California, and after that the concern will shift toward
shallow landslide hazards” says Rengers. “I hope our work offers land
managers useful expectations regarding how these processes are likely to
evolve and helps them prioritize post-wildfire mitigation and planning.”
Presentation: The Evolving Types of Mass Failure After a Wildfire
Online at:
https://gsa.confex.com/gsa/2020AM/meetingapp.cgi/Paper/354344
1:45 p.m. EDT, Wed., 28 October
https://www.usgs.gov/media/images/debris-flows-montecito-california
The aftermath of the 9 Jan. 2018 debris flows in Montecito, California.
Credit: U.S. Geological Survey.
https://www.usgs.gov/media/images/debris-flow-damage-california
Debris flow damage in California. Credit: Susan Cannon, U.S. Geological
Survey.
https://www.youtube.com/watch?v=OTuHQOHjC6Q
Video: Post-wildfire debris flow: 2016 Fish Fire, Las Lomas Canyon. Credit:
U.S. Geological Survey.
Contact:
Heidi Koontz
Public Affairs Specialist
U.S. Geological Survey
Lakewood, Colo.
hkoontz@usgs.gov
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