During her summer travels to her native Belgium, University of Arizona professor Valerie Trouet noticed something that turned casual curiosity into a major scientific discovery. When the sun hid behind the clouds in an overcast sky and people put on sweaters instead of summer clothes, the weather tended to be warm and dry in Italy, Greece and the Balkans, popular summer escapes for tourists from the cooler climates of central and northern Europe.
At the U of A’s Laboratory of Tree-Ring Research, Trouet studies tree-rings to gather clues about what past climates were like, reading wavy, wooden lines like a linguist might decipher an ancient text. What if, she mused, the key to understanding the capricious summers in Europe could be hidden in trees, silent witnesses to centuries of warm and cold, sunshine, rain and snow?
Trouet assembled an international collaboration to collect tree-ring samples across Europe. The team published its results – the first reconstruction of the jet stream over the past 700 years – on Tuesday in the journal Nature.
The jet stream and the Black Death
Jet streams are concentrated bands of wind in the upper atmosphere that travel around the globe in the northern and southern hemispheres. Their exact locations are not fixed; in response to changes in the position and intensity of high- and low-pressure weather systems, they may shift north or south or change their course, resembling a swiftly running stream at some times and a slow, meandering river at others.
The jet stream, it turns out, largely determines summer climate in Europe, and it does so in a seesaw-type pattern that climate researchers call a “dipole.”
“When the jet stream is in an extreme northern position, we get cooler and wetter conditions over the British Isles and warmer and drier conditions over the Mediterranean and the Balkans,” explained study co-author Ellie Broadman, a former postdoctoral research fellow at the Laboratory of Tree-Ring Research who is now a biologist at the U.S. Geological Survey’s Sequoia-Kings Canyon Field Station. “This is related to the climate conditions we are witnessing right now, such as catastrophic flooding in central Europe.”
Hotter conditions over the Balkans cause more moisture than normal to evaporate from the Mediterranean Sea and rain down further north. Conversely, when the jet stream migrates further south, it drags warmer and drier air over the British Isles and pushes cooler temperatures and more moisture toward southeastern Europe.
Measurements of the jet stream have only been around since the late 1940s, Trouet said. By using tree-ring samples from across Europe as proxies for temperature, the research team was able to reconstruct jet stream variation over the past 700 years.
Each year, trees add a ring consisting of less dense wood in the spring and denser wood in the summer. By analyzing tree rings under a microscope, dendrochronologists can compile an archive of past climates.
“We link tiny, subcellular cell wall features in the wood to atmospheric winds that weave through the atmosphere many miles above the Earth, which is fascinating,” Trouet said.
Remarkably, the team found past patterns of the jet stream reflected on a societal level, recorded in historic documents.
“Europe has a long history of writing things down,” Trouet said. “For example, there were monks in Ireland who started recording storms that happened in the 600s, the early Middle Ages, and you have centuries-long records of grape harvests, grain prices and epidemics.”
By comparing historical records to the jet stream reconstruction, Trouet’s team discovered that the climate dipole created by the jet stream has influenced European society for the past 700 years and likely much longer.
“Epidemics happened more frequently in the British Isles when the jet stream was further north,” Trouet said. “Because summers were wet and cold, people stayed indoors, and the conditions were more conducive to spreading diseases.”
From 1348 to 1350, the plague, known as the Black Death, raged in Ireland. At that time, the jet stream was in an extreme, far-north position over Europe.
The findings provide critical data to improve climate models that researchers rely on to predict future climate, Broadman said. Much research has focused on how the jet stream is affected as a result of global warming.
“It’s hard to do that if you only have 60 years’ worth of data, which is why a reconstruction going back 700 years is very useful,” she said. “It allows you to actually compare the past to what’s been happening since we started putting greenhouse gasses into the atmosphere.”
Harvest failures, wildfires and extreme weather
Scientists have observed a trend showing the jet stream is gradually shifting northward, independent of its seasonal or more short-term variations.
“When you combine our reconstruction with harvest failures, you see that this trend likely leads to issues with major cereal crops and other types of weather extremes,” Trouet said. “It gives you a preview of the kinds of extreme events and societal outcomes we could expect if that trajectory continues.”
The findings also set a precedent for a future trajectory of jet stream variation and extreme weather events, such as wildfires, Trouet said.
“We showed that wildfires in the Balkans historically happened substantially more when the jet stream was in that northern position that creates dry and hot conditions,” she said. “And that is exactly what we’re seeing this summer. The results that we’re seeing in our reconstruction act out in real life.”
“When you look at how the jet stream’s natural variability alone has impacted societies, you can get an idea of what might happen if you add more heat in the atmosphere and more variability,” Broadman added. “Being able to say, ‘OK, maybe we need to watch out for this or that particular jet stream configuration’ can be very helpful for predictions of climate related extremes.”