Fossils of Armored Dinosaur With Bony Spikes Discovered, Capable of Withstanding Car Crash Impacts
A remarkable fossil of a nodosaur, a plant-eating dinosaur, has been found to possess an armor so strong that it could endure the impact of a high-speed car crash. Discovered in Alberta, Canada, the fossil belongs to Borealopelta markmitchelli, a species that roamed the Earth approximately 110 million years ago during the Early Cretaceous period. This discovery is one of the best-preserved dinosaur fossils ever unearthed, offering scientists an unparalleled look at the defensive structures of this ancient creature.
New Insights into the Nodosaur’s Defense Mechanisms
Led by biomechanical paleontologist Dr. Michael Habib from UCLA, the research revealed fascinating details about the nodosaur’s protective features. The fossil’s bony armor was covered by a keratin sheath, which was found to be much thicker than previously assumed. In some areas, the keratin layer measured nearly 16 centimeters—significantly thicker than the keratin found on modern animals like cattle horns. This thick, robust coating, combined with the dinosaur’s bony spikes, provided a formidable defense against predators and likely helped it survive in a dangerous environment.
Unbelievable Strength of the Nodosaur’s Armor
According to the study, the nodosaur’s armor was capable of withstanding more than 125,000 joules of energy per square meter—an amount of force equivalent to that of a high-speed car collision. This discovery sheds light on the advanced defensive capabilities of the nodosaur, suggesting that its armor was not just for protection from predators but could also serve as a weapon or shield in combat between rival males of the same species. The armor’s ability to absorb such immense force highlights the evolutionary advantage that such a defense would have provided during its time.
Significance of the Discovery and Future Research
The fossil of Borealopelta markmitchelli offers rare insights into the complex evolutionary mechanisms that allowed dinosaurs to thrive in their environments. The study emphasizes the remarkable resilience and adaptability of these ancient creatures, which are only now being fully understood through modern scientific research. This discovery could have wider implications for paleontology, providing more information about how dinosaurs used their physical traits for survival and giving us a clearer understanding of life in the Cretaceous period. As new technologies and techniques emerge, more discoveries like this may continue to reshape our understanding of prehistoric life.