Vermont Public is independent, community-supported media, serving Vermont with trusted, relevant and essential information. We share stories that bring people together, from every corner of our region. New to Vermont Public? Start here.

© 2024 Vermont Public | 365 Troy Ave. Colchester, VT 05446

Public Files:
WVTI · WOXM · WVBA · WVNK · WVTQ
WVPR · WRVT · WOXR · WNCH · WVPA
WVPS · WVXR · WETK · WVTB · WVER
WVER-FM · WVLR-FM · WBTN-FM

For assistance accessing our public files, please contact hello@vermontpublic.org or call 802-655-9451.
Play Live Radio
Next Up:
0:00
0:00
0:00 0:00
Available On Air Stations

Why Typhoon Haiyan Caused So Much Damage

This map from the NOAA Environmental Visualization Laboratory shows the amount of heat energy available to Typhoon Haiyan between Oct. 28 and Nov. 3. Darker purple indicates more available energy. Typhoons gain their strength by drawing heat out of the ocean. The path of the storm is marked with the black line in the center of the image.
NOAA Environmental Visualization Laboratory
This map from the NOAA Environmental Visualization Laboratory shows the amount of heat energy available to Typhoon Haiyan between Oct. 28 and Nov. 3. Darker purple indicates more available energy. Typhoons gain their strength by drawing heat out of the ocean. The path of the storm is marked with the black line in the center of the image.

The deadly typhoon that swept through the Philippines was one of the strongest ever recorded. But storms nearly this powerful are actually common in the eastern Pacific. Typhoon Haiyan's devastation can be chalked up to a series of bad coincidences.

Typhoons — known in our part of the world as hurricanes — gain their strength by drawing heat out of the ocean. Tropical oceans are especially warm, which is why the biggest storms, Category 4 and Category 5, emerge there. These storms also intensify when there's cool air over that hot ocean.

"The Pacific at this time of year is very ripe and juicy for big typhoons," says Kerry Emanuel, a climate scientist at the Massachusetts Institute of Technology. "Once or twice a year we get a Category 5 typhoon out there."

"But it's a great rarity, fortunately, that a storm just happens to reach peak intensity when it's making landfall. And that's what happened in this case."

As it approached one large island in the Philippines, the storm pushed up into a broad bay. That created a 13-foot storm surge that caused widespread devastation at the head of that bay, in the city of Tacloban.

Typhoon Haiyan struck the Leyte Gulf, in the Philippines, nearly dead-on, creating a 13-foot storm surge that funneled water into Tacloban city.
/ NOAA Office of Coast Survey
/
NOAA Office of Coast Survey
Typhoon Haiyan struck the Leyte Gulf, in the Philippines, nearly dead-on, creating a 13-foot storm surge that funneled water into Tacloban city.

Mountains also wring rainwater out of storms like these. And then there's the wind.

"So we had a triple whammy, of surge, very high winds and strong rainfall," Emanuel says.

Super Typhoon Haiyan could be the strongest on record, but scientists can't say for sure because they don't have direct measurements of the wind speed. Hurricane scientists usually fly into storms heading toward the United States to measure wind speed and barometric pressure. And the U.S. Navy used to do that for storms in the western Pacific. But Emanuel says budget cuts ended that practice decades ago.

"Since then, we've had to rely on satellites, mostly, to estimate typhoon intensity," he says. "And satellites are very good at detecting the presence of typhoons but they're not so great when it comes to estimating how strong they are."

Scientists at the U.S. Navy/Air Force's Joint Typhoon Warning Center infer that Haiyan produced sustained wind speeds of around 190 or 195 mph at its peak. John Nielsen-Gammon, the Texas state climatologist at Texas A&M University, says gusts blew up to 230 mph, which is as fast as a speeding race car.

"Imagine instead of having just one car, imagine millions of raindrops and debris moving at the same speed past you, and you're trying to stand in the middle of it," Nielsen-Gammon says. "That's the kind of force such a hurricane can generate."

The strongest hurricane or typhoon winds on record were from Camille, which struck the U.S. Gulf Coast in 1969. But its 190 mph winds don't tell the whole story. The diameter of the storm matters as well.

"Camille was a very small storm, maybe about one-fifth the size of Haiyan," he says. "So it caused a lot of devastation but over a relatively limited area."

To find out whether Haiyan had record-breaking winds, scientists may turn to amateurs for information.

"Any major storm will attract storm chasers, and Haiyan was no different," Nielsen-Gammon says. "So there were people who traveled to Tacloban specifically to get footage of the storm, and they took along some instruments. So we'll probably get some data out of that."

Of course, that number is only one way to measure the overall severity of a typhoon. The mounting death toll will be another.

And climate scientists like Nielsen-Gammon and Emanuel say that as the planet continues to heat up, so will the oceans. And that means there will be more energy available for storms — and likely more Class 4 and 5 typhoons.

Copyright 2022 NPR. To see more, visit https://www.npr.org.

Award-winning journalist Richard Harris has reported on a wide range of topics in science, medicine and the environment since he joined NPR in 1986. In early 2014, his focus shifted from an emphasis on climate change and the environment to biomedical research.
Latest Stories