The Timber Chronicles

On a shelf in Erika Wise’s office sits an unassuming tree core sample. Marked by alternating shades of rich amber and sepia, it’s only about half a centimeter in width and a foot long. It might not look like much, but it contains about 300 years-worth of data.

Wise studies climate trends from the past millennium through tree-ring science, known as dendrochronology. Paleoclimatologists like Wise use clues in the environment like tree rings, ice cores, and lake sediments to access information about historical trends.

“I think most paleoclimatologists are actually quite interested in future climate change,” she says. “When you want to look at the future we rely on models, and the models can only be calibrated using previous data.”

 Over the course of the next century, worldwide temperatures are expected to rise between 2.5 and 10 degrees Fahrenheit, according to the Intergovernmental Panel on Climate Change.  

By focusing on the past, Wise and her peers hope to gain insight on what’s to come.

Reading the trees

On the crest of a sweeping Wyoming valley, Wise looks down at the gushing Yellowstone River. In the distance, the river surges over a large waterfall before winding its way through the imposing gorge below. Nearby, she finds the perfect cluster of trees. Over the years she has become an expert in spotting old ones – ideal research subjects for her work.

“They just look a bit different. They don’t have the normal, healthy shape of a tree,” she says. “You kind of just get an eye for it.” 

Wise slowly drills into the trunk using an increment bore to gather a sample, about the width of a straw. The segment starts at the tree’s outer bark and continues all the way to its center.

Over the course of two weeks, she will collect about 300 of these specimen, sampling around 150 trees.

Back in the lab at UNC, her analysis begins.

While an approximate age can be assigned to a tree according to its number of rings, trees can also put on a false ring or grow an incomplete ring during a particularly harsh year. To avoid miscalculation, the cores are microscopically analyzed using crossdating, which matches them to a master record.

With the tree’s exact age obtained, the researchers dive into analyzing weather trends. They start by measuring ring widths, which correlate with variation in temperature and precipitation. Wise identifies drought by thin rings, meaning the tree’s growth was limited that year.  

“There’s been a lot of work to pull out more and more information from what’s stored in the trees,” Wise says. “There’s so much still to learn.” 

Methods have recently expanded, uncovering specific seasonal information through analysis of wood density, isotope values, and measurement of the samples’ dark and light variations, called early and late wood.

“We’re working to get out better seasonal information by some of these new methods, but in general, we have one value a year,” she says. “And that can limit what you actually understand about that year.”

To branch out beyond one value per year, Wise partnered with Cary Mock, a colleague at the University of South Carolina. Mock also studies historical climate trends, but approaches the topic through an entirely different method. 

Comparing notes

As a historical climatologist, Mock uses human documents — like newspapers, diaries, and shipping records — to study previous patterns.

“Each of these different methods, whether you talk about tree rings or historical records, has strong points and weak points,” Wise says.

While dendrochronology typically only provides one data point per year, written reports used by historical climatologists are more detailed, with some measurements taken multiple times per day. On the other hand, historical climatologists’ information can be limited to where humans live, but dendrochronology’s strength is in the spatial coverage trees provide. By teaming up, Wise and Mock can fill in gaps of their respective records. 

While the commute from Chapel Hill to the West Coast is long, the region gives Wise particular insight on extreme weather events. She’s especially interested in climate whiplash — when the weather flips from one end of the spectrum to the other, like a long drought followed by intense flooding. 

“A lot of our storm systems come off the Pacific and can affect the whole country,” she says. “And the West is really a place of extremes.”

When Wise began at UNC in 2010, she assumed her research would follow her to the East Coast, but the deeper she went in her studies, the more questions arose. One of these questions pertains to when and why historical and environmental records diverge.

“One thing we’re doing is looking at if the tree ring records and the historical documents disagree, why do they disagree? Is it because the trees aren’t capturing certain seasons that are important?”

Wise and Mock hope by combining their approaches, the two will be able to put together a highly detailed 20-year record of climate on the West Coast, helping lay the foundation of future models. 

“I think people all over the world are concerned about these extreme events and wondering if they are becoming more so because of climate change,” Wise says. “The more we know about the parameters of those events in the past allows us to, hopefully, better model them and understand how they might change in the future.”

Erika Wise is an associate professor in the Department of Geography within the UNC College of Arts & Sciences and head of the Climate and Tree Ring Environmental Science (C-TRĒS) research group.

Cary Mock is a professor in the Department of Geography and associate professor in the Environment and Sustainability Program and Institute for Southern Studies at the University of South Carolina.