Latest news with #Solnhofen
Yahoo
7 days ago
- Science
- Yahoo
Numerous Fossils Reveal Jurassic Fish Killed in Same, Bizarre Way
An extinct genus of ray-finned fish that lived during the Jurassic period seems to have had quite the penchant for overreaching. A new analysis of fossilized Tharsis fish reveals that the carnivorous marine animals seem to have frequently met their end with large cephalopods known as belemnites lodged quite fatally in their gullets. According to paleontologists Martin Ebert and Martina Kölbl-Ebert of Ludwig Maximilian University of Munich in Germany, Tharsis fish found in the 152 million-year-old Solnhofen Plattenkalk (limestone) formation in Germany appear in multiple instances to have died while attempting to swallow a belemnite nearly as long as themselves. "A recent review of collection material … uncovered several specimens of Tharsis from the Late Jurassic Plattenkalk deposits of the Solnhofen Archipelago with belemnites wedged in mouth and gill apparatus," they write in their paper. "In all cases, the rostrum [beak] reexits through the gill apparatus, whereas the broad phragmocone [internal shell] of the belemnite is firmly lodged in the mouth opening." Related: Ancient Tyrannosaur's Last Victims Can Still Be Seen Inside Its Stomach Tharsis fish were what are known as micro-carnivores; animals that eat very small animals such as larvae and zooplankton, in this case by using suction to gulp down their food. Their fossils are quite common. Belemnites, which resembled squid with a long hooded body and multiple arms, lived in the open ocean, left far fewer fossils. Interestingly, the belemnite fossils found in the Plattenkalk basins of Eichstätt and Solnhofen often consist of an internal shell overgrown with bivalves – suggesting that the belemnite was dead, kept buoyant in the water column by a gas-filled shell colonized by other animals, such as clam-like molluscs, feasting on the decaying soft tissue. Tharsis fish were unlikely to be looking for food amid the hostile conditions of the seafloor, nor would the fish have been preying directly on the belemnites – but the researchers believe they know why the dead, drifting cephalopods may have posed such a choking hazard for the hapless fish. "Apparently, these micro-carnivore fish were in the habit of sucking remnants of decaying soft tissue or overgrowth such as algae or bacterial growth from floating objects, but when a streamlined floating belemnite rostrum accidentally was sucked into the mouth, they were no longer able to get rid of these deadly objects," the paleontologists write in their paper. "Even though the fish tried to pass the obstructive item through its gills, there was no way of getting rid of it, leading to death by suffocation." Sounds deeply unpleasant, really. The research has been published in Scientific Reports. 'Ball Lightning' Caught on Film After Storm in Canada Expired Cans of Salmon From Decades Ago Contained a Huge Surprise Melting Glaciers Could Reawaken Hundreds of Earth's Volcanoes
New York Times
14-05-2025
- Science
- New York Times
This Dinosaur Had Feathers and Probably Flew Like a Chicken
In 1861, scientists discovered Archaeopteryx, a dinosaur with feathers, in 150-million-year-old limestones in Solnhofen, Germany. They didn't know it at the time, but that fossilized skeleton — and the several that followed — provided a key piece of evidence for the theory of evolution, as well as for the fact that birds were actually dinosaurs. Archaeopteryx specimens have, 'maybe more than any other fossil, changed the way that we see the world,' said Jingmai O'Connor, a paleontologist at the Field Museum in Chicago. Over 164 years, researchers have pored over every detail of available specimens, trying to puzzle out how birds came to fly. Therefore, you might expect that such a well-studied fossil species wouldn't be capable of surprises. But in a paper published on Wednesday in the journal Nature, Dr. O'Connor and a team of researchers revealed previously unrecorded soft tissues and skeletal details from a new specimen, known as the Chicago Archaeopteryx. What they found also helps explain why some feathered dinosaurs got off the ground, if only for short-haul flights. Sussing out Archaeopteryx's abilities in flight and how it fit in its environment has long been tricky, Dr. O'Connor said. A majority of specimens are cartoonishly flattened by geology, making it difficult to discern important skeletal details. And while its earliest discoverers and most modern scientists have concluded that the species could likely take off, particular bodily features have left paleontologists seeking more data. The latest specimen, acquired by the Field Museum in 2022 and on public display since 2024, allowed Dr. O'Connor's team to begin addressing some of the anatomical uncertainties. When the fossil arrived at the museum, it didn't look like much. The specimen was the same color as the surrounding rock, and most of the soft-tissue remains were difficult to see, Dr. O'Connor said. The researchers CT-scanned the fossil, building a digital map of the skeleton to help guide their preparation of the slab. They also had a secret weapon: By a quirk of chemistry, soft-tissue remains preserved in certain sediments glow under UV light, allowing the team to avoid accidentally removing feathers or skin textures while uncovering bone. That technique was not available to fossil preparators in the 1800s. Unlike other specimens, the bones of the Chicago Archaeopteryx were preserved in three dimensions, and Dr. O'Connor's team could better evaluate the skull's palate. That showed the earliest signs of an evolutionary trajectory toward the skulls of modern birds, which are more mobile than those of prehistoric birds, Dr. O'Connor said. In another lucky accident of fossilization, the carcass's wings were separated from the body, leaving them 'clearly and pristinely preserved,' Dr. O'Connor said. Upon close inspection, the team confirmed that rather than having two layers of wing feathers, as observed in earlier specimens, Archaeopteryx actually had three. In modern birds, that third layer helps link the shorter forearm to the body to create a continuous lift surface, which allows birds to sustain flight. Dr. O'Connor noted that the shape of the wing is a contrast with other feathered nonbird dinosaurs, whose long feathers 'hard stop at the elbow,' she said, making them useful but ultimately flightless decorations. While the lack of a breastbone still means that the bird was likely to have been a relatively poor flyer, toe pads preserved in the Chicago Archaeopteryx's feet add evidence to the assumption that the species was adept at life on the ground, Dr. O'Connor said. The species would therefore have lived like a Jurassic chicken or roadrunner: capable of flying in short bursts when necessary, but otherwise preferring to sprint. The newly reported features are a nice addition to existing understandings of Archaeopteryx, and they offer direct support for current hypotheses about the species' abilities and its relationship to the origins of flight, said Michael Pittman, a paleontologist at the Chinese University of Hong Kong who was not involved with the study. 'This study nicely underscores the importance of discovering new fossils, even of well-known and well-studied specimens,' he said. Dr. O'Connor agreed. 'This specimen's going to keep me busy for years,' she said.
