By analyzing nickel isotopes preserved in the 66-million-year-old debris left by the Chicxulub impact, researchers conclude that the asteroid responsible for Earth’s last mass extinction most likely belonged to an exceptionally rare class of primitive meteorites called carbonaceous chondrites of the Ornans type (CO chondrites).
By analyzing nickel isotopes preserved in the 66-million-year-old debris left by the Chicxulub impact, researchers conclude that the asteroid responsible for Earth’s last mass extinction most likely belonged to an exceptionally rare class of primitive meteorites called carbonaceous chondrites of the Ornans type (CO chondrites). Carbonaceous chondrites make up only 5% of meteorites so far sampled on Earth. CO chondrites make up a tiny fraction of that group.
They are some of the most primitive and untouched materials in the Solar System. “CO chondrites are definitely not like the typical meteors you find in museum collections,” said Professor Philippe Claeys, a researcher at Vrije Universiteit and the University of British Columbia. “A CO contains much less volatile elements — like carbon, zinc, water and particularly sulfur — 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 sulfur contained in the impactor was the smoking gun.” “The fine debris thrown into the atmosphere would have the primary factor.” In their study, Professor Claeys and colleagues conducted high-precision nickel isotope measurements of samples collected over years from a thin layer of clay created across the globe by the Chicxulub impact.
“This is challenging work. Only a minute fraction of the projectile is preserved in the planet’s KT clay layer because the entire meteorite vaporized upon impact,” Professor Claeys said. Many questions remain about the origins of the Chicxulub impactor.
Potential sources include distant, debris-rich regions of the outer Solar System or even the outer area of the asteroid belt near Jupiter. “The Chicxulub impactor was roughly 10 to 15 km,” Professor Claeys said. “It hit at an estimated 64,000 km/h forming the massive crater.”
“The impact zone is buried underneath the Yucatán Peninsula in Mexico.” “Being impacted by such a rare, distant projectile really underscores how unlucky the dinosaurs were.” The study was published today in the
Source and reference
journal Science Advances. _____ Georgy V. Makhatadze et al. 2026 The origin of Cretaceous-Palaeogene impactor revealed by nickel isotopes. Science Advances 12 (29); doi: 10.1126/sciadv.aef4858
Read original source- Published
- Jul 17, 2026
- Updated
- Jul 17, 2026
- Source
- Sci.news: Breaking Science News
- Category
- Technology
- Read time
- 2 min
Key facts
Why this matters locally
This technology story matters locally because it may affect readers, businesses, commuters, families, or public services in British Columbia.
Local impact
BC Post links this item to British Columbia coverage so readers can follow related city updates, weather, traffic, events, and category news in one place.
Timeline
Source and credit
BC Post may summarize, organize, and add local context for reader clarity. Original reporting remains with the listed publisher.