An action thriller by Jock Miller


Fossil fuel has an ageless affinity with dinosaurs. To create oil, dinosaurs died.


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The perfect energy storm is sweeping over the United States: Japan’s Fukushima nuclear plant meltdown has paralyzed nuclear expansion globally, BP’s Gulf of Mexico oil spill has stalled deep water drilling, Arab oil countries are in turmoil causing doubt about access to future oil, the intensity of hurricanes hitting the Gulf’s oil rigs and refineries has intensified due to global warming, and the nation’s Strategic Oil Supply is riding on empty.

As the energy storm intensifies, the nation’s access to Arab oil, once supplying over sixty percent of our fossil fuel, is being threatened causing people to panic for lack of gas at the pumps, stranding cars across the country and inciting riots.


The U.S. Military is forced to cut back air, land, and sea operations sucking up 58% of every barrel of oil to protect the nation; U.S. commercial airlines are forced to limit flights for lack of jet fuel; and businesses are challenged to power up their factories, and offices as the U.S. Department of Energy desperately tries to provide a balance of electric power from the network of aged power plants and transmission lines that power up the nation.

The United States must find new sources of domestic fossil fuel urgently or face an energy crisis that will plunge the nation into a deep depression worse than 1929.

The energy storm is very real and happening this very moment. But, at the last moment of desperation, the United States discovers the world’s largest fossil fuel deposit found in a remote inaccessible mountain range within Alaska’s Noatak National Preserve surrounding six and a half million acres.

Preventing access to the oil is a colony of living fossil dinosaurs that will protect its territory to the death.

Nobody gets out alive; nobody can identify the predator--until Dr. Kimberly Fulton, Curator of Paleontology at New York’s Museum of Natural History, is flown into the inaccessible area by Scott Chandler, the Marine veteran helicopter pilot who’s the Park’s Manager of Wildlife. All hell breaks loose when Fulton’s teenage son and his girlfriend vanish into the Park.


Will the nation’s military be paralyzed for lack of mobility fuel, and will people across America run out of gas and be stranded, or will the U.S. Military succeed in penetrating this remote mountain range in northwestern Alaska to restore fossil fuel supplies in time to save the nation from the worst energy driven catastrophe in recorded history?

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How Did Pterosaurs Fly?




 Virtual Wind Tunnel 700.309

Visit the exhibition to experiment with principles of pterosaur aerodynamics in an interactive virtual tunnel.
© AMNH/D. Finnin

Flight allowed pterosaurs to travel long distances, exploit new habitats, escape predators, and swoop down from above to seize their prey. They spread across the world and branched out into an enormous array of species, including the largest animals ever to take wing.
BUILT TO FLY

Like other flying animals, pterosaurs generated lift with their wings. They needed to perform the same kinds of motions as birds and bats, but their wings evolved independently, developing their own distinct aerodynamic structure.

Nemicolopterus 700.309
Nemicolopterus crypticus was recently discovered in northeastern China, in a region once dotted with wetlands, lakes, and forests. This tiny pterosaur may have darted through forests hunting for insects.
© AMNH 2014

Pterosaurs flew with their forelimbs. Their long, tapering wings evolved from the same body part as our arms. As pterosaurs’ arm and hand bones evolved for flying, they lengthened, and the bones of one finger—the equivalent of our ring finger—became extraordinarily long. Like the mast on a ship, these bones supported the wing surface, a thin flap of skin that was shaped like a sail.


WING BONES

Although many animals can glide through the air, pterosaurs, birds, and bats are the only vertebrates that have evolved to fly by flapping their wings. All three groups descended from animals that lived on the ground, and their wings evolved in a similar way: their forelimbs gradually became long, bladelike, and aerodynamic.

Istiodactylus 700.309

The medium-sized Istiodactylus evolved during the Cretaceous, and its contemporaries included the largest flying animals ever known, such as Pteranodon longiceps and Quetzalcoatlus northropi.
© AMNH 2014

Large pterosaurs needed strong limbs to get off the ground, but thick bones would have made them too heavy. The solution? A pterosaur’s wing bones were hollow tubes, with walls no thicker than a playing card. Like bird bones, they were flexible and lightweight, while strengthened by internal struts.

INSIDE THE WINGS

Recent discoveries show that pterosaur wing membranes were more than simple flaps of skin. Long fibers extended from the front to the back of the wings forming a series of stabilizing supports, so the membranes could be stretched taut, or folded up like a fan. Separate muscle fibers helped pterosaurs adjust the tension and shape of their wings, and veins and arteries kept the wings nourished with blood.

Rhamphorhynchus 700.309

Rhamphorhynchus's long tail had a stiff flap of skin called a vane at the end that stabilized flight. Some scientists think this membrane faced sideways, like a fish tail, and helped prevent rocking from side to side. Others think it lay flat, like a paddle, and helped the flying pterosaur control its elevation.
© AMNH 2014
The exhibition includes a remarkable fossil of Rhamphorhynchus muensteri, discovered in Germany in 2001, which features wing tissues so well preserved that scientists have been able to see fine details in their structure. Under ultraviolet light, researchers detected layers of skin threaded with blood vessels, muscles, and long fibers that stiffened the wing. Because of the shadowy color of the wing membrane, paleontologists call this fossil Dark Wing.


Visitors with Dark Wing Fossil 700.309

The Pterosaurs exhibition includes a remarkable fossil of Rhamphorhynchus muensteri known as Dark Wing, which has allowed scientists to see fine details of pterosaur wing structure.
© AMNH/D. Finnin


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