A warning from ancient tree rings: The Americas are prone to catastrophic, simultaneous droughts

Ongoing drought has dried up a lagoon near Santiago, Chile.

For 10 years, central Chile has been gripped by unrelenting drought. With 30% less rainfall than normal, verdant landscapes have withered, reservoirs are low, and more than 100,000 farm animals have died. The dry spell has lasted so long that researchers are calling it a “megadrought,” rivaling dry stretches centuries ago. It’s not so different from the decadelong drought that California, some 8000 kilometers away, endured until last year.

By analyzing tree ring records, scientists have now found evidence that such tandem droughts are more than a coincidence: They are surprisingly common over the past 1200 years, and they may often share a common cause—an abnormally cool state of the eastern Pacific Ocean known as La Niña. “We did not expect there to be as much coherence as we see,” says Nathan Steiger, a paleoclimatologist at Columbia University who presented the work last month at a meeting of the American Geophysical Union. “They just happen together.” The results suggest that, in the future, extreme aridity could strike all along the Americas’ western coast.

Evidence for synchronous, hemispherewide droughts first emerged in a 1994 study in Nature, which documented dead tree stumps in the middle of lakes and rivers in both Patagonia and California’s Sierra Nevada. For trees to grow in stream- and lakebeds, the droughts must have lasted for decades, and at least one of these megadroughts seemed to have hit both continents simultaneously.

But pinning down the exact timing wasn’t possible in the 1990s. Ancient drought is typically detected in variations in the width of tree rings, but tree ring records then were spotty. Since, however, tree ring scientists have put together “drought atlases” that provide consistent records for much of the world. “We’ll have most hemispheric land areas covered by the end of the year,” says Ed Cook, a tree ring scientist at Columbia.

Steiger combined these records with thousands of other proxies for dryness and temperature from trees, corals, ocean sediments, and ice cores, and fed them into a global climate model. Aligning itself to the records, it generated a global view of the changing climate, even in places with sparse proxies. The model confirmed that, from 800 to 1600 C.E., multiple megadroughts occurred simultaneously across the hemispheres. “It’s there,” Cook says. “Without question, it’s there.”

Besides correlating the varied climate records, the model also identified the key factors driving the climate variations. Steiger and his co-authors, including Cook, first used the new tool to look at megadroughts in the U.S. Southwest. Their study, published last year in Science Advances, is “amazing,” says David Stahle, a tree ring scientist at the University of Arkansas in Fayetteville. “It’s a bit like … they took those black-and-white films and colorized them.” They found that megadroughts in the Southwest were influenced by three factors: an anomalously warm North Atlantic Ocean, small global temperature rises driven by factors such as a brightening Sun, and, especially, La Niña. The cold cousin of El Niño, La Niña can persist for years, deflecting rainstorms away from their usual tracks.

In the new work, the team finds that La Niña is almost the sole driver of the South American megadroughts. And because La Niña affects conditions on both sides of the equator, it could plausibly trigger simultaneous droughts in both hemispheres.

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