Argentina’s mega-storms attract army of meteorologists

Massive project aims to improve predictions of intense lightning, hail and flash floods in the shadow of the Andes mountains.

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Cordoba, Argentina Storm

Towering thunderstorms regularly roll over central Argentina.Credit: Marcos Furer

Some of the worst thunderstorms on the planet are about to give up their secrets.

Deadly downpours, grapefruit-sized hail and severe lightning regularly pepper the eastern side of the Andes mountains in Argentina. These storms often flood towns and destroy vineyards in the region's booming wine industry, but remain poorly understood. About 160 atmospheric scientists — mostly from the United States, Argentina and Brazil — have descended on central Argentina to change that.

Their ultimate goal is to improve severe weather warnings, so that people know to avoid areas where flash floods are likely, or to prepare their vineyards for an incoming hailstorm.

The US$30-million project kicked into high gear on 1 November, as researchers headed to the centre of the country with storm-chasing equipment brought in from the United States, including radar scanners mounted on the backs of trucks. The atmospheric-sciences experiment, called Remote sensing of Electrification, Lightning, And Mesoscale/microscale Processes with Adaptive Ground Observations (RELAMPAGO, which is Spanish for lightning), is the biggest of this type ever conducted outside the United States.

“It’s the craziest activity I have ever been in in my life,” says Paola Salio, an atmospheric scientist at the University of Buenos Aires and the Argentina lead on the project. “But it is also like a dream come true.”

Storm chasers

From now until mid-December, the scientists hope to chase at least a dozen severe storms to study air temperature, wind speed and direction, rainfall amounts, the number of lightning strikes and other factors. They want to use those data to improve models of how descending air on the eastern side of the Andes triggers towering thunderstorms that can regularly reach 18 kilometres into the atmosphere. Such storms are taller and more powerful than typical thunderstorms elsewhere, which might grow 12 kilometres high.

The line of thunderstorms that often form along the Andes looks very similar to the ones in the central United States that often produce tornadoes. But the Argentinian storms are larger and, for some reason, don’t spawn tornadoes nearly as often as the US storms do.

“That’s one of the mysteries we want to answer, why there are so few tornadoes,” says Steve Nesbitt, an atmospheric scientist at the University of Illinois in Urbana-Champaign who heads RELAMPAGO.

In addition, the researchers will drive hundreds of kilometres southwest of their base near Córdoba to target systems that produce strong hail in Mendoza province. Brazilian scientists will also watch any systems that travel farther east into their country.

A second, related project called CACTI (Cloud, Aerosol, and Complex Terrain Interactions) will focus on how atmospheric particles such as dust or haze influence storm development. Funding for RELAMPAGO and CACTI comes from national research agencies and institutions in the United States — such as the National Science Foundation and the Department of Energy — Argentina and Brazil.

Network upgrade

The work would not have been possible a couple of years ago, before Argentina beefed up its national weather radar system. In 2011, the government approved a network of ‘dual-polarization’ radars that transmit and receive radio waves in two orientations — which can distinguish between different types of precipitation, such as hail, rain and snow.

Workers installed the first of these upgraded radars in Córdoba in 2015, says Celeste Saulo, director of Argentina’s national weather service in Buenos Aires. There are seven other dual-polarization radars operating around the country, and three more should be up and running by December, she adds.

RELAMPAGO scientists plan to compare the data from the Córdoba radar with those from their truck-based instruments — which can reach more rural areas and capture additional information on how storms grow — to gain a better picture of how severe weather works in central Argentina.

The project also has a major citizen-science component. Local residents have been trained to collect and measure hailstones, as well as videotape rising stream levels when it rains, says Carlos Marcelo García, a hydrologist at the National University of Córdoba. "They will be fundamental actors in the project," he says.

Seeing the future

After the season is over and the storm-chasing equipment is packed away, Argentinian meteorologists aim to build on the lessons learned, says Saulo. During RELAMPAGO, the weather service will test a type of forecasting system that continually ingests updated weather data to improve forecasts. The system is similar to ones used by meteorologists in the United States and Europe. Argentina’s weather agency wants to use the system going forward, Saulo says. “At the end of the road, we will have benefited because we will better know our storms,” she says.

RELAMPAGO could even provide a glimpse of the future, says Kristen Rasmussen, an atmospheric scientist at Colorado State University in Fort Collins. As global temperatures rise, the warming atmosphere will provide more energy to feed thunderstorms around the world. Rasmussen has run computer simulations on how those changes could result in storms that resemble the powerful ones now seen in Argentina1.

“What we’re seeing in South America could be more like what we will see in a future climate,” she says. This means that other parts of the world could soon get a taste of the storms that Argentina knows so well.

Nature 563, 166 (2018)

doi: 10.1038/d41586-018-07268-2
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  1. 1.

    Rasmussen, K. L. & Houze, R. A. Jr Mon. Weather Rev. 144, 2351-2374 (2016).

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