Technology: What do you get when you cross a thunderstorm with a wildfire?
There are few things more ominous than a looming thundercloud. Add a wildfire to the mix and the result can be a towering tempest of thick smoke, smoldering embers and superheated air. Fire-fuelled thunderstorms are naturally occurring weather systems that sometimes spin up as a result of smoke and heat billowing from intense wildfires. These extreme storms, called pyrocumulonimbus (pyroCb), occur infrequently but when they do they can lead to tragic results.
The making of a fire storm
Wildfires give off intense heat, forcing large amounts of smoke and hot air to rise. As the mixture moves higher into the troposphere, the lowest layer of Earth’s atmosphere, it cools and expands as the air pressure drops. Moisture in the air soon condenses, forming big puffy clouds called pyrocumulus clouds.
When conditions in the atmosphere are just right, including a hot, dry layer of air near the ground and a cooler, wetter layer above it, the atmosphere can become convectively unstable. Increasingly turbulent air sets water droplets and ice crystals in pyrocumulus clouds on a collision course, building up an electrical charge and turning the system into a towering thunderhead.
The soaring pyroCbs, which rarely produce rain on the ground even though they are thunderstorms, can even rise out of the troposphere and extend into the stratosphere tens of kilometres above the surface.
As dark as night
Not surprisingly, pyroCbs can be incredibly dangerous. On 7 February 2009, the most devastating day of fires in Australia’s history spawned at least three pyroCbs that carried embers 30 kilometres from their source and sparked lightning that ignited additional fires 100 kilometres away. Known as the Black Saturday bushfires, these fires collectively burned 4 500 square kilometres and claimed 173 lives.
A pyroCb that formed during the Carr Fire near Redding, California, in 2018 had such strong winds that it created a tornado-strength fire vortex and a pyroCb in Canberra, Australia, in 2003 was so extreme that it released a torrent of black hail and turned the daytime sky as dark as night.
Fortunately, these events are still relatively rare, although recent research from Australia suggests that climate change may cause conditions there to become more favourable for the formation of pyroCbs in the future.
Nick Nauslar, who forecasts fire weather for the National Oceanic and Atmospheric Administration’s National Weather Service, said that about 25–50 pyroCb events occur around the world each year. He said that predicting exactly when the storms will occur remains a challenge for scientists.
“They are still really difficult to forecast,” Nauslar said. Even though scientists can check the weather conditions before a fire, they can’t describe exactly how a wildfire will affect the lower atmosphere and change the weather conditions. The effort to study pyroCbs “is still so young and there’s still so much to learn,” Nauslar said.
Smoke high above
A major signature of pyroCbs is their impact on the stratosphere. But until recently, scientists didn’t think wildfires could inject soot, aerosols, and organic compounds high into the atmosphere. The “idea that a firestorm could act like a volcano and inject material into the stratosphere was completely unknown,” said Mike Fromm, a meteorologist at the US Naval Research Laboratory in Washington, DC Fromm has studied pyroCbs since the late 1990s using satellite instruments.
Smoke particles from pyroCbs can stay in the atmosphere for days to weeks and, in extreme cases, months. Smoke from a massive pyroCb in Canada in 2017 remained suspended in the upper stratosphere for eight months, according to a recent study in Science in which researchers considered the lofted pyroCb particles as a proxy to investigate the potential climatic and atmospheric effects of smoke plumes from nuclear explosions.
PyroCbs won’t be causing a nuclear winter anytime soon but Fromm told Science News that an open question about pyroCb plumes is whether they could damage ozone in the stratosphere. “We’re still trying to understand and quantify and calculate [whether] there is, in fact, a climate impact of these plumes,” Fromm told Eos.
Source: Jenessa Duncombe (@jrdscience), News Writing and Production Fellow