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Zeray Alemseged

  • Zeray Alemseged Slideshow

    5 Photos
    Showing a skull cast to a museum visitor Conducting survey in Dikika Zeray Alemseged and student examine Dikika fossils Sedimentary exposure in the Dikika area Excavating a 3.4 million-year-old rhino fossil
  • The “Most Curious” Species

  • Dikika: Remote, Hostile, and Hot

  • Evolution of Diet

  • Our Role in Biodiversity


Dr. Zeresenay “Zeray” Alemseged studies the origin and evolution of early human ancestors, and the environmental factors that influence their evolution. His objective: to unearth and analyze clues to their biology and behavior, and to identify milestone evolutionary events that ultimately led to the emergence of modern Homo sapiens.


In 2006, Dr. Zeray Alemseged made an indelible mark in the field of anthropology when he reported finding the nearly complete fossilized remains of a 3.3 million-year-old Australopithecus afarensis child in his native country of Ethiopia. Known as the “world’s oldest child,” it is the most complete skeleton of a human ancestor discovered to date, and represents a major advancement in our understanding of human and pre-human evolution.

Alemseged was born in the historic town of Axum, in northern Ethiopia. A curious kid, he often snuck into school before he was old enough to attend, just for the joy of learning. After earning a degree in geology, Alemseged was assigned to work in Ethiopia’s National Museum, home to the famous 3.2 million-year-old A. afarensis fossil “Lucy,” which revolutionized the study of human evolution when it was unearthed by Donald Johanson in 1974. Inspired by his experience there, Alemseged decided to pursue a Ph.D. in anthropology at the University of Paris. He ultimately returned to Ethiopia in search of more evidence about our early hominin ancestors.

Following a hunch, Alemseged set his sights on the Pliocene site of Dikika—an isolated region of the Afar Depression about 400 miles from his hometown—as an optimal place to look for new fossils during his first field season. Other scientists had historically avoided the area, due to a centuries-old tribal conflict that made it too dangerous to work in. Alemseged succeeded in convincing both sides to allow him to work there.

Thanks to his perseverance (and his negotiation skills), Alemseged’s hunch paid off on December 10, 2000. While surveying a hillside and sifting through the dirt and rubble, he and his team discovered the fossilized skeleton of a 3.3 million-year-old baby girl. To find any human remains that old is remarkable; to find the remains of a 3-year-old child, whose fragile bones would have been very attractive to scavengers, was truly extraordinary.

Like “Lucy,” the Dikika child was a member of the species A. afarensis. Nicknamed “Selam,” which means “peace” in several Ethiopian languages, the fossil was excavated over the course of four field seasons. Selam is not only the most complete ancient infant unearthed so far, she is also perhaps the most diagnostic example of her species. Unlike Lucy’s more famous but less complete skeleton, Selam’s remains include fingers, a foot, a full torso, and—most importantly—a face.

Zeray Alemseged

When Zeray Alemseged officially announced the discovery of Selam to the scientific community, the story garnered news coverage around the globe and personal congratulations from the President of Ethiopia. In the years since, Alemseged has been making headway on a long list of questions that Selam’s fossilized bones can help answer about the anatomical, behavioral, and developmental evolution of early human ancestors, and their divergence from the apes.

One of the first topics Alemseged tackled was related to locomotion—how Selam and her kin got around 3.3 million years ago. The hip, leg, and foot bones of Australopithecus afarensis indicate that Selam’s was an upright-walking species, but the timing of when our ancestors abandoned tree-climbing behavior—a key milestone in human evolution—remains a subject of debate. This is largely because prior to the discovery of Selam, no intact shoulder blades were available to study.

“Because shoulder blades are paper-thin, they rarely fossilize,” Alemseged explains. “When they do, they’re almost always fragmentary. Finding a pair of shoulder blades completely intact and attached to a skeleton of a known and pivotal species was like hitting the jackpot.”

In a 2012 study published on the cover of the journal Science, Alemseged and his colleagues found Selam’s fragile scapulae to be quite ape-like. This finding suggested that A. afarensis was still a capable climber despite its bipedal lower body, which means our ancestors abandoned tree-climbing much later than many researchers had previously suggested.

Alemseged continues to study Selam. He also serves as head of the Dikika Research Project, which he founded in 1999, conducting annual field work in Dikika and neighboring regions of the Afar region in search of additional evidence of our ancestors’ evolutionary journey.

parallel cutmarks

We wouldn’t be where we are today without tools. In fact, tool use is a key part of what defines us as modern humans, but of course we didn’t start out with refrigerators or cars. Early human technologies consisted of sharp flakes of stone, which our ancestors began using and making tools from far earlier than previously thought. In 2010, an international team of scientists led by Zeray Alemseged discovered evidence in the Afar region of Ethiopia that Australopithecus afarensis was using stone tools and eating meat roughly 3.4 million years ago, pushing the timeframe of human tool use and manufacture back by nearly a million years.

The team found fossilized bones bearing evidence that suggested cut marks caused by stone tools being used to carve off meat, along with percussion marks of the sort made when breaking bones to extract marrow. Previously, the oldest known evidence of butchering with stone tools came from Bouri, Ethiopia, where several cut-marked bones were dated to about 2.5 million years ago.

“Tool use fundamentally altered the way in which our early ancestors interacted with nature, allowing them to eat new types of food and exploit new territories” says Alemseged. “It also led to tool making—a critical step in our evolutionary path that eventually enabled advanced technologies such as airplanes, MRI machines, and iPhones.”

Case in point: the modern archaeologist’s toolkit, a juxtaposition of simple and high-tech instruments, each of which plays a crucial role. In the field, where roads, water, and power supplies are few and far between, hand-held GPS devices have transformed the data collection process. These high-tech tools integrate many data points—from location coordinates and notes about the geologic setting to photos taken with a built-in camera—into one “geodatabase” that can be synched with a laptop at the end of each day, making documentation more efficient and complete. For some tasks, however, nothing beats a delicate touch. Alemseged still sifts through dirt and sand manually, using brushes and picks to carefully remove sediment from fragile objects.

In his lab, it took Alemseged more than 10 years with a microscope and dental drill to remove Selam’s skeleton from its dense sandstone encasement grain by grain. Once freed, the skull was taken to a diagnostic center in Nairobi, Kenya for a high-powered CT scan. The imagery revealed a mixture of deciduous (baby) and permanent teeth, which provided valuable clues as to Selam’s sex and her age at death without compromising the specimen’s integrity. Technology has advanced since the original CT scans, and synchrotron techniques with super-resolution microscopes now allow for an even closer look, revealing fine details like growth lines in fossilized teeth. Originally developed for materials science applications, these specialized microscopes are only available at a handful of sites worldwide.

human migration map

The evolutionary road to modern Homo sapiens took many twists and turns, as Academy visitors can see in Human Odyssey, an addition to Tusher African Hall curated by Zeray Alemseged. The following milestones represent some of the major turning points along that journey:

About 6–7 million years ago:
The earliest human ancestor diverges from the ape family and begins the transition toward walking upright. Genetic evidence confirms that our closest living relative is the chimpanzee, with which we share more than 98% of our DNA.

About 4 million years ago:
Habitually walking members of the genus Australopithecus make their first appearance in the fossil record. Large teeth with thick enamel allowed these hominids to begin eating tubers and other abrasive foods for the first time. Tool use may have emerged with this genus.

About 2.5–3 million years ago:
Our ancestors begin making and using stone tools to eat meat. Animal fossils from this time period show evidence of butchering.

About 1.5–2 million years ago:
Homo erectus emerges for the first time. With long legs and short arms, this early human is well adapted to walking long distances and begins to cover a much larger range, eventually becoming the first hominid to spread out of Africa and into other continents.

About 800,000 years ago:
Although it is difficult to document because of the frequent occurrence of natural fires, scientists believe that human ancestors first began controlling fire around this time.

130,000–195,000 years ago:
Humans (Homo sapiens sapiens) are now fully modern. Compared to earlier members of the genus Homo, modern humans have larger brains and lighter skeletons.

Have a Question?


Q: How is the development of early human ancestors relevant to life today?


A: When people look at each other, they tend to focus on differences—in hair, skin, shape, culture, and so on—but in reality, 99.7 percent of our genes are identical. Understanding more about our species’ evolutionary history can make us think differently about how we are all related.

Humans are also part of a larger community of plant and animal species that are connected, not just through food chains and proximity, but through time. It’s a community much bigger than the neighborhoods, states, and countries that we tend to identify with. Studying our ancestors allows us to reflect upon who we are today, how we got here, and how we relate to our non-human relatives. When you feel that you belong to a community, you have a stake in sustaining and protecting that community, which is fundamentally in all of our best interest. The Academy is heavily invested in this endeavor.

Read all the questions

More about Dr. Alemseged


Department: Anthropology


Expeditions: 40

Current Expedition: Afar Depression, Ethiopia



Dikika Research Project

Department of Anthropology

Human Odyssey exhibit


Related Content:

Evidence of Tool Use

What Makes Us Human? on PBS

Becoming Human on Nova

African Voices on CNN

The Search for Humanity’s Roots: TED Talk