What do these larger, higher fires mean for the West’s water supply?

McGrath: It’s certainly concerning. We’re adding yet another impact or yet another process that’s modifying what we’ve come to rely on as a stable, reliable water resource. And the fact that warming temperatures are already leading to significant changes in the snowpack. And that’s resulted in earlier stream flow. Lower amounts of snow-water equivalent stored in the snowpack.

What is the impact of these fires?

McGrath: Every year that there’s more wildfires burning in the West. We’re basically accumulating this impact across the region. Because it can last a decade or longer. The forest doesn’t recover immediately. It’s not like the canopy comes back the next year. These trees, the trunks that remain there, will continue to flake off this soot, this dark material, and lower the albedo (i.e., the measure of reflectance). So it’s concerning that given that climate model projections show the West will be warmer and drier in the future, and that we’re going to see wildfire years like 2020 at shorter recurrence intervals, so they’ll occur more frequently. That these impacts accumulate is a really concerning factor. And you start saying: “Whoa. Actually a large portion of the western U.S. that accumulates these seasonal snowpacks, has and will be impacted by wildfires.”

How were you able to measure snowpack and its effects?

McGrath: We can map from satellites really nicely, when the seasonal snow melts in the spring, and by combining that with known fire perimeters, we’re able to show that mountain ranges like the Sierra Nevada, the Cascades, the Wasatch, the southern Rockies, they all saw significant increase in wildfire activity, in portions of these mountain ranges that accumulate significant snowpacks. Kampf: We measured the snowpack in burned and unburned areas, at different elevations. And we found that the burning led to the snow not accumulating as much, so the peak snow — at the end of the snow accumulation season — was lower, and then probably the bigger effect is that the snow melted much more quickly and sooner. That part of the study we did on the ground. ... We went out and did snow surveys. The paper mixes the big picture, West-wide analysis with the smaller, local, on-the-ground collecting measurements component.

How does a wildfire lead to faster melting?

Kampf: When it’s not covered with debris or soot, [snow] is very reflective, so sunlight hits the snow, and that’s why people get sunburned on their chins or under their noses when they’re skiing. It reflects back that sunlight. When the snow gets darker it’s not reflecting as much sunlight so it warms up more quickly. It’s quite a noticeable effect. Anytime the wind blows it will blow ash off of the trees. They will lose bits of branches and bits of bark and if there are needles those will fall down. So all of that material, that burned material, is pretty loose and it just falls on the snow. McGrath: You remove that [tree] canopy. And that can modify how much snow can accumulate on the ground, but then we see these really significant impacts in the spring, when more energy is able to reach the snow surface, because you no longer have a canopy there shading it. And then secondly the snow surface is darker and so that means more of this incoming radiation is absorbed. So as a result of that, what we found is that the snowpack melted out much earlier. And that’s not a totally novel finding. That’s been shown in other study areas. But we’re talking less than 10 studies, probably total, that have really been able to document this fire impact.

Where was the effect of the fires most visible?

Kampf: At the lower elevations. That’s where we really saw this stark difference. We’d go to the burned area in April. No snow left, nothing. And there’d still be snow, pretty decent snowpack, in the unburned areas at the same time ... The higher elevations get more snow, so those ash layers continue to get covered up through the spring.

National

Wildfires are burning higher in the West, threatening water supplies

By Joshua Partlow

September 22, 2022 at 3:59 p.m. EDT

The burned landscape resulting from the Cameron Peak Fire is seen on Sept. 21, 2021 in Larimer County, Colo. (RJ Sangosti/MediaNews Group/The Denver Post via Getty Images)

6 min

Two years ago, a wildfire started burning in Colorado’s Arapaho National Forest. Fanned by high winds and parched conditions, the East Troublesome fire raced up the slopes of the Rocky Mountains, at one point crossing over the Continental Divide amid 12,000-foot-tall peaks. It would become the second largest wildfire in state history, and it happened to start on the same October day that another fire to the northeast, the Cameron Peak fire, would be crowned Colorado’s largest ever fire.

Beyond their size, the two massive 2020 blazes represented prime examples of a troubling trend as our atmosphere warms: wildfires are burning at higher altitudes in the major mountain ranges of the West, including in areas that are normally cloaked in deep snows in winter.

Winter snowpack that melts slowly in the spring and summer is a primary water source for the West. And so these trends of more fire at higher elevations and faster melting represent “a major threat to a critical water reservoir for the region,” said Dan McGrath, a Colorado State University scientist.

McGrath, co-author Stephanie Kampf and colleagues at Colorado State used these Colorado fires as a starting point for a study published earlier this week that shows how wildfires are spreading deeper into seasonally snowy zones, speeding up melting in a region already enduring a historic drought.

These maps illustrate the seriousness of the western drought

Sampling snow at different elevations in the burned area from the big Colorado fires of 2020, the authors found that snow melted up to nearly a month earlier in charred areas compared to non-burned forests nearby. They attributed this in part to a dynamic that has been documented in earlier studies — particularly by Portland State University professor Kelly Gleason — where ash and soot from the fire scar blows over snow, darkening it and causing it to absorb more energy and melt quicker.

Using historic wildfire maps and snow records, the authors also found that between 1984 and 2020 wildfires have burned 70 percent of what they call “late snow zones” — areas that don’t typically melt until May or later — in western mountains. More forest burned in 2020 in these areas than in the previous 36 years combined, the authors found.

McGrath noted that snowpack across the western United States has declined by 15 to 30 percent over the past 70 years; while the timing of peak snowpack has shifted earlier in most places and total snow-covered season has decreased by more than two weeks.

The Post talked to McGrath and Kampf, the lead author on the paper in the Proceedings of the National Academy of Sciences, about the West’s dwindling snowpack and why it is so harmful.

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