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Cambridge Researchers Reconstruct First Complete Dinosaur Skeleton

The Tyrannosaurus rex dubbed Sue, the largest and best-preserved example of this well-known meat-eating dinosaur, is pictured in its new exhibition suite at the Field Museum in Chicago, Illinois, US. Dec. 18, 2018 | Reuters.
The Tyrannosaurus rex dubbed Sue, the largest and best-preserved example of this well-known meat-eating dinosaur, is pictured in its new exhibition suite at the Field Museum in Chicago, Illinois, US. Dec. 18, 2018 | Reuters.
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Cambridge Researchers Reconstruct First Complete Dinosaur Skeleton

The Tyrannosaurus rex dubbed Sue, the largest and best-preserved example of this well-known meat-eating dinosaur, is pictured in its new exhibition suite at the Field Museum in Chicago, Illinois, US. Dec. 18, 2018 | Reuters.
The Tyrannosaurus rex dubbed Sue, the largest and best-preserved example of this well-known meat-eating dinosaur, is pictured in its new exhibition suite at the Field Museum in Chicago, Illinois, US. Dec. 18, 2018 | Reuters.

A team from the University of Cambridge has managed to construct the first complete skeleton of a dinosaur known as "Scelidosauru," after more than a century and a half on its discovery. This achievement has been announced in the latest issue of the Zoological Journal of the Linnean Society of London.

The skeleton of this dinosaur was collected more than 160 years ago on west Dorset's (a county to the southwest of England) Jurassic Coast. The rocks in which it was fossilized are around 193 million years old, close to the dawn of the Age of Dinosaurs.

This remarkable specimen was sent to Richard Owen at the British Museum, the man who invented the word dinosaur. He published two short papers on its anatomy, but many details were left unrecorded. Owen did not reconstruct the animal as it might have appeared in life and made no attempt to understand its relationship to other known dinosaurs of the time. In short, he "re-buried" it in the literature of the time, and so it has remained ever since: known, yet obscure and misunderstood.

Over the past three years, Dr. David Norman from Cambridge's Department of Earth Sciences has been working to finish the work which Owen started, preparing a detailed description and biological analysis of the skeleton of Scelidosaurus.

The results of Norman's work, published as four separate studies in the Zoological Journal of the Linnean Society of London, not only reconstruct what Scelidosaurus looked like in life, but reveal that it was an early ancestor of ankylosaurs, the armor-plated 'tanks' of the Late Cretaceous Period.

The new study also revealed that the skull of the Scelidosaurus had horns on its back edge, in addition to several bones that have never been recognized in any other dinosaur. It's also clear from the rough texturing of the skull bones that it was, in life, covered by hardened horny scutes, a little bit like the scutes on the surface of the skulls of living turtles. In fact, its entire body was protected by skin that anchored an array of stud-like bony spikes and plates.

Now that its anatomy is understood, it is possible to examine where Scelidosaurus sits in the dinosaur family tree, said Norman in a report by the University of Cambridge.

It had been regarded for many decades as an early member of the group that included the stegosaurs, but that was based on a poor understanding of its anatomy. Now it seems that Scelidosaurus is an ancestor of the ankylosaurs alone.

"It is unfortunate that such an important dinosaur, discovered at such a critical time in the early study of dinosaurs, was never properly described. But, as they say, better late than never," he concluded.

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Fast-forming Alien Planet has Astronomers Intrigued

An artist's depiction of a planet and its host star with a misaligned disk of material, and a binary companion in the background, is shown in this undated handout image. NASA/JPL-Caltech/R. Hurt, K. Miller (Caltech/IPAC)/Handout via REUTERS
An artist's depiction of a planet and its host star with a misaligned disk of material, and a binary companion in the background, is shown in this undated handout image. NASA/JPL-Caltech/R. Hurt, K. Miller (Caltech/IPAC)/Handout via REUTERS
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Fast-forming Alien Planet has Astronomers Intrigued

An artist's depiction of a planet and its host star with a misaligned disk of material, and a binary companion in the background, is shown in this undated handout image. NASA/JPL-Caltech/R. Hurt, K. Miller (Caltech/IPAC)/Handout via REUTERS
An artist's depiction of a planet and its host star with a misaligned disk of material, and a binary companion in the background, is shown in this undated handout image. NASA/JPL-Caltech/R. Hurt, K. Miller (Caltech/IPAC)/Handout via REUTERS

Astronomers have spotted orbiting around a young star a newborn planet that took only 3 million years to form - quite swift in cosmic terms - in a discovery that challenges the current understanding of the speed of planetary formation.
This infant world, estimated at around 10 to 20 times the mass of Earth, is one of the youngest planets beyond our solar system - called exoplanets - ever discovered. It resides alongside the remnants of the disk of dense gas and dust circling the host star - called a protoplanetary disk - that provided the ingredients for the planet to form.
The star it orbits is expected to become a stellar type called an orange dwarf, less hot and less massive than our sun. The star's mass is about 70% that of the sun and it is about half as luminous. It is located in our Milky Way galaxy about 520 light-years from Earth, Reuters reported. A light-year is the distance light travels in a year, 5.9 trillion miles (9.5 trillion km).
"This discovery confirms that planets can be in a cohesive form within 3 million years, which was previously unclear as Earth took 10 to 20 million years to form," said Madyson Barber, a graduate student in the department of physics and astronomy at the University of North Carolina at Chapel Hill and lead author of the study published this week in the journal Nature.
"We don't really know how long it takes for planets to form," UNC astrophysicist and study co-author Andrew Mann added. "We know that giant planets must form faster than their disk dissipates because they need a lot of gas from the disk. But disks take 5 to 10 million years to dissipate. So do planets form in 1 million years? 5? 10?"
The planet, given the names IRAS 04125+2902 b and TIDYE-1b, orbits its star every 8.8 days at a distance about one-fifth that separating our solar system's innermost planet Mercury from the sun. Its mass is in between that of Earth, the largest of our solar system's rocky planets, and Neptune, the smallest of the gas planets. It is less dense than Earth and has a diameter about 11 times greater. Its chemical composition is not known.
The researchers suspect that the planet formed further away from its star and then migrated inward.
"Forming large planets close to the star is difficult because the protoplanetary disk dissipates away from closest to the star the fastest, meaning there's not enough material to form a large planet that close that quickly," Barber said.
The researchers detected it using what is called the "transit" method, observing a dip in the host star's brightness when the planet passes in front of it, from the perspective of a viewer on Earth. It was found by NASA's Transiting Exoplanet Survey Satellite, or TESS, space telescope.
"This is the youngest-known transiting planet. It is on par with the youngest planets known," Barber said.
Exoplanets not detected using this method sometimes are directly imaged using telescopes. But these typically are massive ones, around 10 times greater than our solar system's largest planet Jupiter.
Stars and planets form from clouds of interstellar gas and dust.
"To form a star-planet system, the cloud of gas and dust will collapse and spin into a flat environment, with the star at the center and the disk surrounding it. Planets will form in that disk. The disk will then dissipate starting from the inner region near the star," Barber said.
"It was previously thought that we wouldn't be able to find a transiting planet this young because the disk would be in the way. But for some reason that we aren't sure of, the outer disk is warped, leaving a perfect window to the star and allowing us to detect the transit," Barber added.