Ancient "terror bird" used powerful beak to jab like an agile boxer
The ancient "terror bird" Andalgalornis couldn't fly, but it used its unusually large, rigid skull -- coupled with a hawk-like hooked beak -- for a fighting strategy reminiscent of boxer Muhammad Ali. The agile creature repeatedly attacked and retreated, landing well-targeted, hatchet-like jabs to take down its prey, according to a new study published this week in the online, open-access journal PLoS ONE by an international team of scientists. The study is the first detailed look at the predatory style of a member of an extinct group of large, flightless birds known scientifically as phorusrhacids but popularly labelled "terror birds" because of their fearsome skull and often imposing size. Terror birds evolved about 60 million years ago in isolation in South America, an island continent until the last few million years, radiating into about 18 known species ranging in size up to the 2.1 metre-tall Kelenken. Read more
X-Rays Reveal Chemical Link Between Birds and Dinosaurs
Researchers have found that a 150 million year old "dinobird" fossil, long thought to contain nothing but fossilised bone and rock, has been hiding remnants of the animal's original chemistry. Using the bright X-ray beam of the Stanford Synchrotron Radiation Lightsource, located at the Department of Energy's SLAC National Accelerator Laboratory, an international team of palaeontologists, geochemists and physicists has revealed this transformative glimpse into one of the most important fossils ever discovered: the Archaeopteryx, a half-dinosaur/half-bird species. Read more
Title: Archaeopteryx feathers and bone chemistry fully revealed via synchrotron imaging Authors: U. Bergmann, R. W. Morton, P. L. Manning, W. I. Sellers, S. Farrar, K. G. Huntley, R. A. Wogelius, and P. Larson
Evolution of flight in maniraptoran dinosaurs is marked by the acquisition of distinct avian characters, such as feathers, as seen in Archaeopteryx from the Solnhofen limestone. These rare fossils were pivotal in confirming the dinosauria-avian lineage. One of the key derived avian characters is the possession of feathers, details of which were remarkably preserved in the Lagerstätte environment. These structures were previously simply assumed to be impressions; however, a detailed chemical analysis has, until now, never been completed on any Archaeopteryx specimen. Here we present chemical imaging via synchrotron rapid scanning X-ray fluorescence (SRS-XRF) of the Thermopolis Archaeopteryx, which shows that portions of the feathers are not impressions but are in fact remnant body fossil structures, maintaining elemental compositions that are completely different from the embedding geological matrix. Our results indicate phosphorous and sulphur retention in soft tissue as well as trace metal (Zn and Cu) retention in bone. Other previously unknown chemical details of Archaeopteryx are also revealed in this study including: bone chemistry, taphonomy (fossilisation process), and curation artifacts. SRS-XRF represents a major advancement in the study of the life chemistry and fossilisation processes of Archaeopteryx and other extinct organisms because it is now practical to image the chemistry of large specimens rapidly at concentration levels of parts per million. This technique has wider application to the archaeological, forensic, and biological sciences, enabling the mapping of "unseen" compounds critical to understanding biological structures, modes of preservation, and environmental context.
Fossils that capture snapshots of a dinosaur species at different growth stages show that its feathers changed dramatically during its development, according to Chinese researchers in a paper published in Nature today1. Two Similicaudipteryx specimens were recovered, one from early adulthood and one younger juvenile. Both belong to a group of egg-stealing dinosaurs known as oviraptorosaurs, and they seem to follow a maturation pattern not seen in modern birds. Read more
China has made yet another astounding discovery that is transforming everything we thought we knew about dinosaurs - a 160 million-year-old creature that supports the claim that modern day birds are in fact dinosaur descendants. Read more
New dinosaur discovery solves evolutionary bird puzzle
A newly discovered fossil has shed light on why a group of dinosaurs looks like birds, say scientists. Haplocheirus sollers may not be as charismatic as T. rex or as agile as a pterodactyl but it's thought to solve a long standing puzzle. Researchers believe its short arms and large claw show how bird-like dinosaurs evolved independently of birds. The 3m-long skeleton, found on an expedition to China's Gobi desert, is described in the journal Science.
The colour of some feathers on dinosaurs and early birds has been identified for the first time, reports a paper published in Nature this week. The research found that the theropod dinosaur Sinosauropteryx had simple bristles - precursors of feathers - in alternate orange and white rings down its tail, and that the early bird Confuciusornis had patches of white, black and orange-brown colouring. Future work will allow precise mapping of colours and patterns across the whole bird. Read more
Meet Sinosauropteryx, a very spiky little dinosaur. A team of scientists from China and the UK has now revealed that the bristles of this 125 million-year-old dinosaur were in fact ginger-coloured feathers. The researchers say that the diminutive carnivore had a "Mohican" of feathers running along its head and back. It also had a striped tail.
One of the earliest feathered dinosaurs seems to have been a successful glider. Scientists believe modern birds are descended from dinosaurs, and examples of feathered dinos have been found dated to 120 million years ago. In an effort to determine the flight abilities of the animals, researchers built models of these early birds and launched them into the air. The result: They glide nicely. Read more