Researchers identify class of 'oddball' meteorite that killed the dinosaurs
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Dr. Philippe Claeys, a visiting professor at the University of British Columbia, in front of an exhibit at the Pacific Museum of Earth.
view moreCredit: Credit: University of British Columbia.
A rare CO chondrite meteorite was the probable impactor that struck Earth 66 million years ago, wiping out 75 per cent of Earth's species, including non-avian dinosaurs.
The findings, published today in Science Advances by researchers at the University of British Columbia (UBC), Paris, Brussels and Vienna, used advanced nickel isotope analysis of samples to narrow down the composition of the deadly Cretaceous-Palaeogene meteorite.
“Carbonaceous chondrites of the Ornans class are definitely not like the typical meteors you find in museum collections,” says Dr. Philippe Claeys, who worked on the study as a visiting professor at UBC.
“A CO contains much less volatile elements—like carbon, zinc, water and particularly sulphur—than other classes of meteorites we’ve discovered so far on Earth. It doesn’t alter our theory of what caused the extinction event—but it makes it less likely that sulphur contained in the impactor was the smoking gun. The fine debris thrown into the atmosphere would have the primary factor.”
Researchers from Institut de Physique du Globe and Université de Paris conducted high-precision nickel isotope measurements of samples collected over years from a thin layer of clay created across the globe by the impact.
“This is challenging work,” adds Dr. Claeys, a professor with Vrije Universiteit Brussel currently visiting the Pacific Centre for Isotopic and Geochemical Research with Earth, Ocean and Atmospheric Sciences at UBC. “Only a minute fraction of the projectile is preserved in the planet’s KT clay layer because the entire meteorite vaporized upon impact.”
Many questions remain about the origins of the world-shattering meteorite. Potential sources include distant, debris-rich regions of the outer Solar System or even the outer area of the asteroid belt near Jupiter.
A rare impactor
Carbonaceous chondrites make up only five per cent of meteorites so far sampled on Earth. Carbonaceous chondrites of the Ornans class — CO chondrites — make up a tiny fraction of that group. They are some of the most primitive and untouched materials in the solar system.
“Being impacted by such a rare, distant projectile really underscores how unlucky the dinosaurs were,” says Dr. Claeys.
The Cretaceous-Paleogene impactor was roughly 10 to 15 kilometres or six miles wide. It hit at an estimated 64,000 km/h forming the massive Chicxulub crater. The impact zone is buried underneath the Yucatán Peninsula in Mexico.
Journal
Science Advances
Method of Research
Experimental study
Subject of Research
Not applicable
Article Title
The origin of Cretaceous-Palaeogene impactor revealed by nickel isotopes
Article Publication Date
17-Jul-2026
Dr. Philippe Claeys, a visiting professor at the University of British Columbia, in front of an exhibit at the Pacific Museum of Earth.
Credit
Credit: University of British Columbia.
Residue of the Cretaceous-Paleogene impact. Dark clay-rich KT boundary layer in Stevn’s Klint, Denmark used in the study.
Credit
Credit: Dr. Philippe Claeys.
An asteroid doomed the dinosaurs. But did it drive tuna evolution?
Yale University
A long-held theory suggests that the asteroid strike that killed off non-avian dinosaurs — and most large marine predators — 66 million years ago created an ecological opportunity that spurred the rapid evolution of tunas, and other large, fast, and warm-blooded predators.
The idea is that tunas and their carnivorous counterparts filled a niche left by their massive, predatory predecessors, much like how mammals replaced the world’s non-avian dinosaurs after the K-Pg extinction event.
But that theory doesn’t quite hold water, according to a new Yale study that provides new insights into how these economically important fishes evolved their imposing size, speed, and ability to regulate their body temperatures in cold seas.
For the study, researchers combined genetic data with fossil specimens to create the most complete time-calibrated evolutionary tree available for Scombridae, a family that includes tunas and mackerels along with about half of living warm-blooded, ray-finned fish species.
Their analysis placed the origins of Scombridae near the time of the asteroid strike. However, it also showed that tunas, mackerels, and related predatory fishes independently evolved large body sizes and endothermy — the ability to regulate body temperature — long after the K-Pg extinction.
“Our results demonstrate the K-Pg extinction did not trigger the evolution of tunas and related large, endothermic predators,” said Chase Brownstein, a graduate student in ecology and evolutionary biology in Yale’s Graduate School of Arts and Sciences, and the study’s lead author. “We show that the body plans of these predators evolved over tens of millions of years and that there is no connection between the origins of endothermy and large body sizes in these lineages. More broadly, this paper highlights the need to be cautious when interpreting the evolution of species’ body plans directly from evolutionary trees.”
The study published on July 8 in the journal Proceedings of the Royal Society B. Thomas Near, professor of ecology and evolutionary biology in Yale’s Faculty of Arts and Sciences (FAS), is the study’s senior author.
According to their findings, differing types of endothermy — a trait that helps tunas and other predatory fish swim fast — evolved independently three times in Scombridae lineages, with at least two of the three occurring 10 to 15 million years after the asteroid strike. Endothermy and the animals’ large body sizes were thought to be linked, but the study showed that there is little evidence for this. Instead, increases in body size occurred sporadically throughout the evolution of tunas and other Scombridae lineages. All told, the body plans of today’s tunas and mackerel evolved over the course of 50 million years, the researchers said.
The dataset for the time-calibrated evolutionary tree included tissue and DNA samples collected from several institutions, including the Yale Peabody Museum.
The study of Earth’s biodiversity and this specific research, is a key part of Yale Planetary Solutions — a campuswide initiative that unites leaders and innovators across disciplines to catalyze solutions to the most critical threats facing people and the planet, Near said.
Better understanding the evolutionary biology of tunas, a nutrient-rich food source for people worldwide, can support conservation efforts, he added. Populations of the commercially important Atlantic bluefin tuna, he noted, have dramatically declined over the last several decades due to overfishing.
It also has potential implications for the study of human health, he said.
“Understanding that endothermy independently evolved multiple times in tunas and mackerels provides insight into the fundamental machinery underlying metabolism and thermoregulation,” said Near, who is also the Bingham Oceanographic Curator of Ichthyology at the Peabody Museum. “These are systems that are central to disease and health conditions in humans, such as obesity, diabetes, and metabolic syndrome. To be clear, there is no explicit connection here, but studying how our biodiversity has dealt with similar challenges over the long sweep of time is relevant to better understanding human health.”
Coauthors of the study are Laura R.V. Alencar of Yale, Holly K. Kindsvater of Virginia Polytechnic Institute and State University, Christine E. Thacker of the Santa Barbara Museum of Natural History and the Natural History Museum of Los Angeles County, Dylan K. Wainwright of Purdue University, and Richard C. Harrington of the Marine Resources Institute at the South Carolina Department of Natural Resources.
The research was supported by the Yale Training Program in Genetics, the Bingham Oceanographic Fund of the Yale Peabody Museum, and the National Science Foundation.
Article Title
The prolonged reemergence of megapredatory pelagic fishes
Article Publication Date
8-Jul-2026
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