Science

Scientists unravel cause of deadly California 'firenado'

Scientists say they have figured out the recipe for a rare fire tornado that raged during this summer's deadly Carr Fire in Northern California.

A key factor was the development of a fast-growing, ice-topped cloud generated by the fire itself

July 26 image from video released by Cal Fire shows a fire tornado over Lake Keswick Estates near Redding, Calif. A new study says a rare fire tornado that raged during the deadly wildfire this summer in Northern California was created by a combination of scorching weather, erratic winds and an ice-topped cloud that towered kilometres into the atmosphere. (Cal Fire via Associated Press)

A rare fire tornado that raged during this summer's deadly Carr Fire in Northern California was created by a combination of scorching weather, erratic winds and an ice-topped cloud that towered kilometres into the atmosphere, according to a study.

The churning funnel of smoke and flame killed a firefighter as it exploded in what already was a vast and devastating wildfire in July on the edge of Redding, about 400 kilometres north of San Francisco.

The wildfire claimed eight lives and destroyed more than 1,000 homes before it was contained on Aug. 30.

The study released Wednesday in the Geophysical Research Letters journal used satellite and radar data to suggest how a monstrous "firenado" the size of three football fields developed on July 26.

It said the firenado was formed in much the same way as a regular tornado, which differs from the "fire whirls" formed only by heat from a wildfire.

California fires spawn 'firenado' phenomenon

8 years ago
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Swirling column of flame moves slowly towards highway

The only other documented case of such a firenado was during the 2003 Canberra fires in Australia, according to the study.

A key factor was the development of a cloud generated by the fire itself that was ice-topped and grew quickly, doubling in length in just 15 minutes. It reached as high as 11.9 kilometres (39,000 feet or 7.4 miles), according to the study, which was published on Nov. 21.

The development of that pyrocumulonimbus cloud "helped stretch the underlying column of air, concentrating the rotation near the surface" and causing tornado-strength winds that reached 230 km/h, according to the study.

"This paints a clear picture of the sequence of events leading to the vortex development and intensification," said Neil Lareau of the University of Nevada, Reno, who co-authored the paper.

Potential warning

Other factors included record high temperatures, low humidity and a "near-surface cyclonic wind shear zone," according to the study. A wind shear occurs when the wind speed or direction suddenly changes, so that the wind actually is blowing in two opposite directions.

The wind shear near the ground set up the spin that developed the fire tornado plume, Lareau said.

"These observations may help forecasters and scientists identify — and potentially warn — for future destructive fire-generated vortices," according to the study.

Lareau is an assistant professor in the Physics Department of the College of Science. The article was co-authored by Nicholas Nausler of the Storm Prediction Center in Norman, Okla., and John Abatzoglou from the Department of Geography at the University of Idaho in Moscow, Idaho.