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Reframing the challenge of living with wildfire

Reframing the challenge of living with wildfire

What the extreme fire seasons of 1910 and 2020–and 2,500 years of forest history–tell us about the future of wildfires in the West


Strong winds blew across mountain slopes after a record-setting warm, dry summer. Small fires began to blow up into huge conflagrations. Towns in crisis scrambled to escape as fires bore down.

This could describe any number of recent events, in places as disparate as , ,  and . But this fire disaster happened over 110 years ago in the Northern Rocky Mountains of Idaho and Montana.

The “” of 1910 still holds the record for the largest fire season in the Northern Rockies. Hundreds of fires burned over 3 million acres – roughly the size of Connecticut – most in just two days. The fires destroyed towns, killed 86 people and galvanized public policies committed to putting out every fire.

Today, as the climate warms, fire seasons like in 1910 are becoming more likely. The  was an example. But are extreme fire seasons like these really that unusual in the context of history? And, when fire activity begins to surpass anything experienced in thousands of years – as research suggests is happening in the Southern Rockies – what will happen to the forests?

Kyra Clark-Wolf

Boulder researcher Kyra Clark-Wolf holds a sediment core pulled from a lake containing evidence of fires over thousands of years. (Photo and top image: Philip Higuera)

As paleoecologists, we study how and why ecosystems changed in the past. In a multiyear project, highlighted in  , we tracked how often forest fires occurred in high-elevation forests in the Rocky Mountains over the past 2,500 years, how those fires varied with the climate and how they affected ecosystems. This long view provides both hopeful and concerning lessons for making sense of today’s extreme fire events and impacts on forests.

Lakes record history going back millennia

When a high-elevation forest burns, fires consume tree needles and small branches, killing most trees and lofting charcoal in the air. Some of that charcoal lands on lakes and sinks to the bottom, where it is preserved in layers as sediment accumulates.

After the fire, trees regrow and also leave evidence of their existence in the form of pollen grains that fall on the lake and sink to the bottom.

By  of those lake sediments, like a straw pushed into a layer cake from above, we were able to measure the amounts of charcoal and pollen in each layer and reconstruct the history of fire and forest recovery around a dozen lakes across the footprint of the 1910 fires.

Lessons from Rockies’ long history with fire

The  that high-elevation, or subalpine, forests in the Northern Rockies in Montana and Idaho have consistently bounced back after fires, even during periods of  and more frequent burning than we saw in the 20th century.

High-elevation forests only burn about once  on average.  that the amount of burning in subalpine forests of the Northern Rockies over the 20th and 21st centuries remained within the bounds of what those forests experienced over the previous 2,500 years. Even today, the Northern Rockies , including  after extensive fires .

But  in high-elevation forests of the Southern Rockies in Colorado and Wyoming tells a different story.

The record-setting 2020 fire season, with , helped push the rate of burning in high-elevation forests in Colorado and Wyoming into  relative to the past 2,000 years.

Infographic of high-altitude climate change

Long-term changes in climate, forest density and fire frequency over the past 4,800 years in one high-elevation forest in the Northern Rockies, reconstructed from lake sediments. The red dots reflect timing of past fires. (Infographic: Kyra Clark-Wolf)

Climate change is also having bigger impacts on  in warmer, drier regions of the West, including the , the . When fires are followed by especially warm, dry summers, seedlings can’t establish and forests struggle to regenerate. In some places, shrubby or grassy vegetation replace trees altogether.

Changes happening now in the Southern Rockies could serve as an early warning for what to expect further down the road in the Northern Rockies.

Warmer climate, greater fire activity, higher risks

Looking back thousands of years, it’s hard to ignore the consistent links between the climate and the prevalence of wildfires.

Warmer, drier springs and summers  to make extensive fire seasons more likely. This was the case  in the Northern Rockies and  in the Southern Rockies.

When, where and how climate change will push the rate of burning in the rest of the Rockies into uncharted territory is harder to anticipate. The difference between 1910 and 2020 was that 1910 was followed by decades with low fire activity, whereas 2020 was part of an overall trend of increasing fire activity linked with global warming. Just one fire like 1910’s Big Burn in the coming decades, in the context of 21st-century fire activity, would push the Northern Rockies beyond any known records.

Lessons from the long view

The clock is ticking.

 as the climate warms, and it will be . Human activity is also raising the risk of fires starting.

The Big Burn of 1910 left a lasting impression because of the devastating impacts on lives and homes and,  and many other recent fire disasters, because of the  in igniting them.

Accidental ignitions – from downed power lines, escaped campfires, dragging chains, railroads – expand , and . The fire that , is the most recent example.

So what can we do?

 from vehicles, power plants and other sources can help slow warming and the impacts of climate change on wildfires, ecosystems and communities.  can , protecting humans and .

 – building with fire-resistant materials, reducing accidental ignitions and increasing preparedness for extreme events – can  while maintaining the critical role that fires have played in forests across the Rocky Mountains for millennia.

is a post-doctoral research associate in ecology in at Boulder; Philip Higuera is a professor of fire ecology at the University of Montana

This article is republished from under a Creative Commons license. Read the .