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CU Boulder PhD student Liam Jasperse-Sjolander is helping elephant behavioral observation get off the ground—and into the air above Africa

Walking through the quiet, lush rainforests of Gabon, on Africa’s equatorial west coast, forest elephants have a knack for appearing and disappearing just as quickly.��

Because they travel in small groups through the thick jungles, forest elephants are much less noticeable—and thus much harder to observe—than their cousins that live on the wide-open African savannas.

For Liam Jasperse-Sjolander, a University of Colorado Boulder environmental studies PhD student, that quiet grace is part of the magic of his fieldwork. “They can be very silent, very unassuming,” he says. “Suddenly you’ll see this gigantic creature in the forest, and the next instant they’re gone.”��

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CU Boulder PhD student Liam Jasperse-Sjolander has been studying elephant behavior since 2016. (Photo: Alain-Djessy Banguiya)

Jasperse-Sjolander has spent years traveling through Gabon and other African countries tracking elephant behavior in a variety of ways: using radio collars, camera traps and, more recently, drones.��

And he’s been publishing his findings along the way. In 2025 alone, Jasperse-Sjolander co-authored three publications, one based on data from dung collection in Gabon and two on the benefits and potential ramifications of drones in observations.��

Now he’s working to collate years of field data collected from these studies—identifying behavioral patterns and their ecological implications—for his dissertation, and pondering what’s next in his research.

Discovering Africa��

Growing up, Jasperse-Sjolander didn’t always know where his love of the outdoors would take him. “I just wanted to do something outside,” he says of his childhood in Colorado. “I was either going to work in science or go run off into the woods to fend for myself.”

Ultimately, he chose the former, earning an undergraduate degree in environmental biology from McGill University in Montreal. During those years he got his first taste of fieldwork, spending a semester learning about conservation and field ecology in Kenya, Uganda and Tanzania—and falling in love with Africa. Why?

“From a conservation perspective I think that many areas still feel wild, with so many megafauna worth protecting. And I love the beautiful diversity and vibrancy of cultures and traditions there.”

That’s why, after finishing his undergraduate studies, he headed right back, signing on as a research assistant for a Duke University PhD student Amelia Meier, who was tracking forest elephants in the Wonga Wongué Presidential Reserve in Gabon. Jasperse-Sjolander was eager to get in the field and watch the elephants with his own eyes, and was pleased to see that Meier was interested in mixing old-school observation methods with some new technologies.

“Her approach was really interesting and it kind of opened my eyes to studying behavior in the field in new ways,” he says.

On the ground in Gabon

That approach required a few radio collars—and sorting through an awful lot of dung. Jasperse-Sjolander and his colleagues would track the forest elephants’ movements, then follow along at a safe distance to capture dung samples for later lab analysis.��

The data they collected showed the makeup of the fruits and seeds the elephants were consuming in the forest, and laid the foundation for��. The article sought to model how elephants may play a role in reseeding forests with trees and other large plant species that can consume large amounts of carbon dioxide.��

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Forest elephants, once thought to be a subspecies of African savanna elephants, were recognized as their own species in 2021 by the International Union for Conservation of Nature. Part of Liam Jasperse-Sjolander’s work is to help establish a behavioral baseline. “It's really hard to protect a critically endangered species if you don't know what they're doing and where they're going.” (Photo: Liam Jasperse-Sjolander)��

The results of the study showed wide variety in when and how the elephants disperse seeds, making it difficult to use a one-size-fits-all model for predicting how they will impact their local ecology.��

“A lot of climate initiatives will put an emphasis on elephants being ‘gardeners of the forest,’” says Jasperse-Sjolander. These initiatives’ models assume that if elephants are in the area, carbon will in turn increase by a certain amount. “But if that’s not true in a country the size of Gabon, that’s certainly not true on an international scale.”��

While there is still more work to do to better understand this interaction, Jasperse-Sjolander’s work in the field was pivotal to reaching this next step in the research. ��

In the air in Kenya��

Now Jasperse-Sjolander is taking his fieldwork to new heights by studying how drones can be used to track elephants’ movements, eating patterns and group sizes—without disturbing the creatures. “This new format opens up a lot of doors for seeing behavior that we haven’t seen before,” says Jasperse-Sjolander.

In 2024 Jasperse-Sjolander was contracted by��, an African non-governmental organization dedicated to the preservation of elephants and their habitats, to analyze how drones may impact different elephant groups. “Before we start using drones to study behavior, we have to make sure that we're not negatively affecting the elephants,”��says Jasperse-Sjolander.������

Jasperse-Sjolander analyzed the behavioral data Save the Elephants had captured during trial runs of the drones with 14 distinct elephant groups in the Samburu National Reserve in Kenya. The results, which were published in November 2025 in��, were positive: While some of the elephants exhibited a few changes in baseline behavior—like eating a bit less or staying more alert—after multiple trial runs the group seemed generally unphased.��

The researchers performing the trials adhered to some general common-sense protocols about how far to stay from the group.��

“We always would launch the drone at least a half kilometer away from the group, since it's really at takeoff that it's the most noisy and disturbing,” says Jasperse-Sjolander. “Then we flew at a height of 120 meters (around 400 feet), which is the maximum height you can fly drones in Kenya. So we're basically as far away as we can be.”

Even at that distance, the latest high-tech drones can still capture high-resolution images; researchers can also use the drones’ embedded infrared camera to follow the elephants at night. That camera allowed researchers to follow some elephants for 24 hours and learn more than they ever knew about the animals’ sleep patterns.��

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Even at heights of 400 feet, drones’ high-resolution lenses allow researchers to capture important information, such as back length measurements, a common indicator of age. (Photo: Save the Elephants)��

“Previously we’d estimated that they only sleep for 15 minutes, but we found that sometimes they’ll all lay down together in a dry riverbed and sleep for a full two hours,” says Jasperse-Sjolander.��

“We didn’t really know before what elephants were doing at night,” he adds.. “And so we’re uncovering all these layers of elephant behavior that can help the population.” Knowing where they spend most of their time, when they leave an area and when they are most vulnerable to poaching are all important considerations in the business of saving elephants, he explains.��

In May 2025, Jasperse-Sjolander and the Save the Elephants team also published about how to maximize these drones’ capabilities, even when there are restrictions on their flight (e.g., in Kenya, where drones are highly regulated). “It can still be a very useful piece of equipment,” says Jasperse-Sjolander, noting that the device’s infrared camera and potential for measuring elephant shoulder height (another common indicator of age) can all be used on the ground, and can take the place of other, more expensive equipment.��

In the lab in Colorado

Now, with so much fieldwork data under his belt, Jasperse-Sjolander is back at CU working to finalize his dissertation, comparing behavior between forest and savanna elephants. He’ll build on his master’s coursework (also earned at CU Boulder), which looked specifically at the different behaviors of forest elephants in Gabon—which is 90% forest, 10% savanna—when they’re in the two different biomes.����

“Most forest elephant groups are just a mother around their calf and maybe a few relatives,” says Jasperse-Sjolander, explaining that the patchily distributed fruit trees that the elephants feed on are not enough to sustain groups much larger than that.��

But, when they emerge from the forest, these groups connect with other small groups.

“Elephants are still very social, and it’s important for them to keep those links and have that larger association network,” says Jasperse-Sjolander, adding that the elephants’ time in the savanna is also important for the exchange of information.�� ��

Jasperse-Sjolander’s dissertation will expand the boundaries of his comparison of forest and savanna elephant behaviors to take more of a continent-wide approach to understanding the variations between and among them.��

And after that? Jasperse-Sjolander is hoping to head back to Africa for a longer contract with a non-governmental organization like Save the Elephants, where he can use learnings from his PhD to advance our understanding of elephant behavior even further.��

“I like just being in Africa and being in the field,” he says. While many researchers in his field go back and forth between the U.S. and Africa, “I like to live and embody the places I study.”

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