When smoke rises from wildfires in the western United States, it pummels clouds with tiny airborne particles. What happens next with these clouds has been largely unstudied. But during the 2018 wildfire season, researchers embarked on a series of seven research flights, including over the Pacific Northwest, to help fill this gap.
Using airborne instruments to analyze small cumulus clouds affected by the smoke, the scientists found that these clouds contained, on average, five times as many water droplets as unaffected clouds. The new research suggests that wildfires could lead to clouds producing less rain in the U.S. West, feeding into drought conditions and potentially increasing future wildfire risk.
But the environmental dynamics involved are complex, says Cynthia Twohy. She’s a San Diego–based atmospheric scientist at NorthWest Research Associates, a research organization specializing in geophysical and space sciences headquartered in Redmond, Wash. For instance, Twohy and her colleagues found that “the ratio of light-absorbing to light-scattering particles in the smoke was somewhat lower than measured in many prior studies,” she says.
“The take-home message is that while other studies have shown wildfire smoke has an absorbing (warming) influence that can be important for cloud formation and development, these impacts may be less in the western U.S., because the smoke is not as dark,” Twohy says. The impact of the lighter smoke is still an open question. “It’s just another way that smoke-cloud interactions are a wild card in the region.”
The team used onboard probes to sample clouds affected by wildfire smoke and compare them to their more pristine counterparts. The probes measured how many cloud droplets were present in the samples, the size range of those droplets and the liquid water content of the clouds.
A special tube mounted on the exterior of the plane to collect and evaporate cloud droplets was used to “reveal the particles that the droplets were condensed on,” says Robert Yokelson, an atmospheric chemist at the University of Montana in Missoula who was not involved with the research. This process enabled the researchers to confirm what the original smoke particles were made of, a technique that Yokelson calls “neat.”
Using airborne instruments to analyze small cumulus clouds affected by the smoke, the scientists found that these clouds contained, on average, five times as many water droplets as unaffected clouds. The new research suggests that wildfires could lead to clouds producing less rain in the U.S. West, feeding into drought conditions and potentially increasing future wildfire risk.
But the environmental dynamics involved are complex, says Cynthia Twohy. She’s a San Diego–based atmospheric scientist at NorthWest Research Associates, a research organization specializing in geophysical and space sciences headquartered in Redmond, Wash. For instance, Twohy and her colleagues found that “the ratio of light-absorbing to light-scattering particles in the smoke was somewhat lower than measured in many prior studies,” she says.
“The take-home message is that while other studies have shown wildfire smoke has an absorbing (warming) influence that can be important for cloud formation and development, these impacts may be less in the western U.S., because the smoke is not as dark,” Twohy says. The impact of the lighter smoke is still an open question. “It’s just another way that smoke-cloud interactions are a wild card in the region.”
The team used onboard probes to sample clouds affected by wildfire smoke and compare them to their more pristine counterparts. The probes measured how many cloud droplets were present in the samples, the size range of those droplets and the liquid water content of the clouds.
A special tube mounted on the exterior of the plane to collect and evaporate cloud droplets was used to “reveal the particles that the droplets were condensed on,” says Robert Yokelson, an atmospheric chemist at the University of Montana in Missoula who was not involved with the research. This process enabled the researchers to confirm what the original smoke particles were made of, a technique that Yokelson calls “neat.”
