Tornadoes: The science behind the destruction

Scientists probe the mysteries of violent twisters.

By Brian Clark Howard
Published 24 May 2019, 12:39 BST
Photograph by Colt Forney, National Geographic Your Shot

How tornadoes form and how they die is not fully understood, yet scientists probing those mysteries—and aiming to improve warning systems—have pinpointed key risk factors.

A tornado, or twister, is a violently rotating column of air that extends between the Earth's surface and a cloud, usually a cumulonimbus cloud. Most tornadoes last for less than ten minutes, says Harold Brooks, a research meteorologist with the National Oceanic and Atmospheric Administration's (NOAA) National Severe Storms Laboratory (NSSL) in Norman, Oklahoma.

Large tornadoes usually last longer—around 30 minutes, Brooks adds. The most powerful twisters have wind speeds of more than 300 miles (483 kilometers) per hour, which can rip buildings off their foundations. They can be more than two miles (3.2 kilometers) wide, and can spin across the ground for dozens of miles.

The more common tornadoes have wind speeds of less than 110 miles (177 kilometers) per hour, are about 250 feet (76 meters) across, and travel only a few miles before they dissipate.

Tornadoes kill an average of 60 people a year in the U.S., mostly from flying or falling debris, reports NOAA. (See "Interactive: Forces of Nature.") Half of those deaths are caused by the strongest one percent of the most violent storms, says Brooks.

How tornadoes form

The most intense tornadoes emerge from what are called supercell thunderstorms. For such a storm to form, you first "need the ingredients for a regular thunderstorm," says Brooks.

Those ingredients include warm moisture near the surface and relatively cold, dry air above. "The warm air will be buoyant, and like a hot-air balloon it will rise," says Brooks.

A supercell requires more: winds that increase in strength and change direction with height. "Then the updraft tends to rotate, and that makes a supercell," explains Brooks.

The supercell churns high in the air and, in about 30 percent of cases, it leads to the formation of a tornado below it. This happens when air descending from the supercell causes rotation near the ground.

Even then, "we still don't know why some thunderstorms create tornadoes while others don't," tornado-chaser Tim Samaras said in early 2013. Samaras was a scientist and National Geographic grantee who was killed by a twister on May 31, 2013, in El Reno, Oklahoma. (Read "The Last Chase" in National Geographic magazine.)

Brooks says scientists believe strong changes in winds in the first kilometer of the atmosphere and high relative humidity are important for the formation of tornadoes. He adds that there also needs to be a downdraft in just the right part of the storm.

Tornado formation also requires a "Goldilocks" situation, in which air must be cold but not too cold. It should be a few degrees more frigid than surrounding air, Brooks says.

He adds, "We don't understand how tornadoes die: Eventually the air gets too cold and it chokes off the inflow of new air into the storm, but we don't know the details."

Where and when twisters strike

Tornadoes have been observed on every continent except Antarctica. They have been most documented in North America, where an estimated 1,200 strike the United States each year, but they frequently appear in many other countries.

The most notoriously affected region in the United States, called "Tornado Alley," includes the Great Plains states of Kansas, Nebraska, and the Dakotas, as well as parts of Texas. Large-scale weather patterns tend to converge on that area, making tornadoes more likely.

Still, the state that receives the highest number of tornadoes per square mile is Florida, according to the American Meteorological Society. Indiana, Illinois, Iowa, and Louisiana also have many tornadoes per square mile.

Tornadoes can happen at any hour of the day and any time of the year, though they are most common in the spring, especially during May and June in North America.

In many countries, including the United States, Canada, and continental Europe, the strength of tornadoes is often measured by the Fujita scale or the updated Enhanced Fujita Scale. An F0 or EF0 tornado damages trees but substantial structures are left unharmed; a tornado in the strongest category—F5 or EF5 —blows away buildings.

Since measuring wind speeds inside a twister is extremely difficult, scientists typically rely on damage to estimate velocities.

The difficulties of forecasting

Tornadoes are much harder to forecast than are hurricanes, which are larger storms that last a lot longer. According to NOAA, the average amount of time between a tornado warning and the arrival of a storm is about 13 minutes. (A tornado warning means a twister has been sighted, while a tornado watch means one is possible.)

The National Severe Weather Laboratory's Warn-on-Forecast research project is aiming to improve forecasting, although the work is challenging, says Brooks.

The project uses powerful software to crunch data on temperatures, moisture, and other atmospheric variables. Sometimes the system "makes really good forecasts, and other times it doesn't," says Brooks.

As computers get faster and data improves, accuracy may rise, he suggests. In the meantime, better understanding of the atmosphere will also help with other endeavors, such as planning for wind farms or the placement of solar panels.

Brooks adds, "It's not completely clear that increasing the lead time for tornado [forecasts] is going to benefit the general public, because we're not sure how people are going to respond to that information." Many people ignore current tornado watches, for instance, thinking the threat is unlikely.

But, Brooks says, "there are probably audiences out there that will be able to take good advantage of it, such as emergency managers and vulnerable populations that might take a long time to get prepared."

Predicting the path of a tornado across the landscape can also be challenging. Brooks says tornadoes tend to follow the general movement of the thunderstorm they are associated with, but the route can be erratic.

"It's kind of like walking a dog," he says. "You get down the block, but in the middle the dog goes back and forth."

This story was originally published on April 28, 2014 and updated on May 21, 2019.
loading

Explore Nat Geo

  • Animals
  • Environment
  • History & Culture
  • Science
  • Travel
  • Photography
  • Space
  • Adventure
  • Video

About us

Subscribe

  • Magazines
  • Disney+

Follow us

Copyright © 1996-2015 National Geographic Society. Copyright © 2015-2024 National Geographic Partners, LLC. All rights reserved