150-million-year post-mortem reveals baby pterosaurs perished in a violent storm
University of Leicester scientists have identified two extraordinary new fossils -- tiny prehistoric flying reptiles, pterosaurs, with broken wings
image:
An artist’s impression of a tiny Pterodactylus hatchling struggling against a raging tropical storm, inspired by fossil discoveries. Artwork by Rudolf Hima.
view moreCredit: Artwork by Rudolf Hima.
The cause of death for two baby pterosaurs has been revealed by University of Leicester palaeontologists in a post-mortem 150 million years in the making.
Detailed in a new study in the journal Current Biology, their findings show how these flying reptiles were tragically struck down by powerful storms that also created the ideal conditions to preserve them and hundreds more fossils like them.
The Mesozoic, or age of reptiles, is often imagined as a time of giants. Towering dinosaurs, monstrous marine reptiles, and vast-winged pterosaurs dominate museum halls and the public consciousness. But this familiar picture is skewed. Just as today’s ecosystems are mostly populated by small animals, so too were ancient ones. The difference? Fossilisation tends to favour the largest and the most robust organisms. Small, fragile creatures rarely make it into the palaeontological record.
On rare occasions, however, nature conspires to preserve the delicate and the diminutive inhabitants of these lost worlds. One of the most famous examples is the 150-million-year-old Solnhofen Limestones of southern Germany. These lagoonal deposits are renowned for their exquisitely preserved fossils, including many specimens of pterosaurs, the flying reptiles of the Mesozoic.
Yet here lies a mystery: while Solnhofen has yielded hundreds of pterosaur fossils, nearly all are very small, very young individuals, perfectly preserved. By contrast, larger, adult pterosaurs are rarely found, and when they are, they’re represented only by fragments (often isolated skulls or limbs). This pattern runs counter to expectations: larger, more robust animals should stand a better chance of fossilisation than delicate juveniles.
Lead author of the study Rab Smyth, from the University of Leicester’s Centre for Palaeobiology and Biosphere Evolution, was funded by the Natural Environment Research Council through the CENTA Doctoral Training Partnership
Rab said: “Pterosaurs had incredibly lightweight skeletons. Hollow, thin-walled bones are ideal for flight but terrible for fossilisation. The odds of preserving one are already slim and finding a fossil that tells you how the animal died is even rarer.”
The discovery of two baby pterosaurs with broken wings has helped to solve this mystery. These tiny fossils, though easily overlooked, are powerful evidence of ancient tropical storms and how they shaped the fossil record.
Ironically nicknamed Lucky and Lucky II by the researchers, the two individuals belong to Pterodactylus, the first pterosaur ever scientifically named. With wingspans of less than 20 cm (8 inches) these hatchlings are among the smallest of all known pterosaurs. Their skeletons are complete, articulated and virtually unchanged from when they died. Except for one detail. Both show the same unusual injury: a clean, slanted fracture to the humerus. Lucky’s left wing and Lucky II’s right wing were both broken in a way that suggests a powerful twisting force, likely the result of powerful gusts of wind rather than a collision with a hard surface.
Catastrophically injured, the pterosaurs plunged into the surface of the lagoon, drowning in the storm driven waves and quickly sinking to the seabed where they were rapidly buried by very fine limy muds stirred up by the death storms. This rapid burial allowed for the remarkable preservation seen in their fossils.
Like Lucky I and II, which were only a few days or weeks old when they died, there are many other small, very young pterosaurs in the Solnhofen Limestones, preserved in the same way as the Luckies, but without obvious evidence of skeletal trauma. Unable to resist the strength of storms these young pterosaurs were also flung into the lagoon. This discovery explains why smaller fossils are so well preserved – they were a direct result of storms – a common cause of death for pterosaurs that lived in the region.
Larger, stronger individuals, it seems, were able to weather the storms and rarely followed the Luckies stormy road to death. They did eventually die though but likely floated for days or weeks on the now calm surfaces of the Solnhofen lagoon, occasionally dropping parts of their carcasses into the abyss as they slowly decomposed.
“For centuries, scientists believed that the Solnhofen lagoon ecosystems were dominated by small pterosaurs,” said Smyth. “But we now know this view is deeply biased. Many of these pterosaurs weren’t native to the lagoon at all. Most are inexperienced juveniles that were likely living on nearby islands that were unfortunately caught up in powerful storms.”
Co-author Dr David Unwin from the University of Leicester added: "When Rab spotted Lucky we were very excited but realised that it was a one-off. Was it representative in any way? A year later, when Rab noticed Lucky II we knew that it was no longer a freak find but evidence of how these animals were dying. Later still, when we had a chance to light-up Lucky II with our UV torches, it literally leapt out of the rock at us - and our hearts stopped. Neither of us will ever forget that moment.”
- ‘Fatal accidents in neonatal pterosaurs and selective sampling in the Solnhofen fossil assemblage’ is published in Current Biology, DOI: 10.1016/j.cub.2025.08.006 Link: https://doi.org/10.1016/j.cub.2025.08.006
- Funding Acknowledgement
This research was supported by the Central England NERC Training Alliance (CENTA), under grant number NE/S007350/1.
Journal
Current Biology
Article Title
Fatal accidents in neonatal pterosaurs and selective sampling in the Solnhofen fossil assemblage
Article Publication Date
5-Sep-2025
The hatchling Pterodactylus, nicknamed Lucky, illuminated UV light. Both part and counterpart show the delicate bones of this tiny pterosaur, capturing a fractured wing in extraordinary detail.
Lucky II, another hatchling Pterodactylus, preserved as a part and partial counterpart under UV light. Like the other individual, it has a fractured wing, providing rare insight into how even the youngest pterosaurs experienced injuries.
Skeletal reconstructions of the two Pterodactylus hatchlings are shown in flight position, with broken bones marked in red. UV images reveal clear breaks in the upper arm bones. A silhouette of a house mouse (Mus musculus) is included for scale.
(A) Most of the time, pterosaurs stood little chance of becoming fossils. Decaying larger individuals sometimes left behind scattered bones that reached the lagoon floor, but smaller pterosaurs were usually lost without trace.
(B) Storms, however, created very different conditions. Powerful winds and waves dragged the bodies of small and young pterosaurs into deeper waters. At the same time, these storms stirred up salty water from the lagoon floor. This water contained almost no oxygen, and when it mixed with the surface waters, it triggered sudden die-offs of marine life. These toxic waters acted as a barrier to scavengers and decay, allowing pterosaur bodies to sink largely untouched.
The final step came when lime-rich mud, carried by the storm, rapidly buried the remains. This quick covering not only protected soft tissues from decay but also preserved fragments of larger pterosaurs that had been deposited earlier. Together, these rare conditions explain why fossils from Solnhofen are so well preserved.
Credit
University of Leicester
