Quetzalcoatlus

Quetzalcoatlus
Temporal range: Late Cretaceous, Upper Maastrichtian, 68–66 Ma
Restored skeleton in quadrupedal stance
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Reptilia
Order: Pterosauria
Suborder: Pterodactyloidea
Family: Azhdarchidae
Genus: Quetzalcoatlus
Lawson, 1975
Type species
Quetzalcoatlus northropi
Lawson, 1975
Synonyms

Hatzegopteryx thambema?
Buffetaut, Grigorescu & Csiki, 2002

Quetzalcoatlus northropi /kɛtsəlkˈætləs/ is an azhdarchid pterosaur known from the Late Cretaceous of North America (Maastrichtian stage) and one of the largest known flying animals of all time. It is a member of the family Azhdarchidae, a family of advanced toothless pterosaurs with unusually long, stiffened necks. Its name comes from the Mesoamerican feathered serpent god Quetzalcoatl.

Description

Size

See also: Pterosaur size
Size comparison of Q. northropi (green), Q. sp (blue), and a human

When it was first discovered, scientists estimated that the largest Quetzalcoatlus fossils came from an individual with a wingspan as large as 15.9 meters (52 feet), choosing the middle of three extrapolations from the proportions of other pterosaurs that gave an estimate of 11, 15.5 and 21 meters respectively (36 feet, 50.85 feet, 68.9 feet). In 1981, further study lowered these estimates to 11–12 meters (36–39 ft).[1] More recent estimates based on greater knowledge of azhdarchid proportions place its wingspan at 10–11 meters (33–36 ft).[2] Remains found in Texas in 1971 indicate that this reptile had a minimum wingspan of about 11 metres.[3]

Mass estimates for giant azhdarchids are extremely problematic because no existing species share a similar size or body plan, and in consequence published results vary widely.[4] While some studies have historically found extremely low weight estimates for Quetzalcoatlus, as low as 70 kilograms (150 lb) for a 10-meter (32-foot-10-inch) individual, a majority of estimates published since the 2000s have been higher, around 200–250 kilograms (440–550 lb).[5][6]

Skull

Skull material (from smaller specimens, possibly a related species) shows that Quetzalcoatlus had a very sharp and pointed beak. That is contrary to some earlier reconstructions that showed a blunter snout, based on the inadvertent inclusion of jaw material from another pterosaur species, possibly a tapejarid or a form related to Tupuxuara. A skull crest was also present but its exact form and size are still unknown.[7]

Discovery and species

A comparison of Quetzalcoatlus cervical vertebrae on the left with the Phosphatodraco holotype on the right

The first Quetzalcoatlus fossils were discovered in Texas, United States, from the Maastrichtian Javelina Formation at Big Bend National Park (dated to around 68 million years ago[8]) in 1971 by Douglas A. Lawson, a geology graduate student from the Jackson School of Geosciences at the University of Texas at Austin. The specimen consisted of a partial wing (in pterosaurs composed of the forearms and elongated fourth finger), from an individual later estimated at over 10 m (33 ft) in wingspan.[4] Lawson discovered a second site of the same age, about forty kilometers from the first, where between 1972 and 1974 he and Professor Wann Langston Jr. of the Texas Memorial Museum unearthed three fragmentary skeletons of much smaller individuals. Lawson in 1975 announced the find in an article in Science.[9] That same year, in a subsequent letter to the same journal, he made the original large specimen, TMM 41450-3, the holotype of a new genus and species, Quetzalcoatlus northropi. The genus name refers to the Aztec feathered serpent god Quetzalcoatl. The specific name honors John Knudsen Northrop, the founder of Northrop, who was interested in large tailless flying wing aircraft designs resembling Quetzalcoatlus.[10] At first it was assumed that the smaller specimens were juvenile or subadult forms of the larger type. Later, when more remains were found, it was realized they could have been a separate species. This possible second species from Texas was provisionally referred to as a Quetzalcoatlus sp. by Alexander Kellner and Langston in 1996, indicating that its status was too uncertain to give it a full new species name.[7] The smaller specimens are more complete than the Q. northropi holotype, and include four partial skulls, though they are much less massive, with an estimated wingspan of 5.5 meters (18 feet).[11]

Skull reconstruction of Q. sp.

The holotype specimen of Q. northropi has yet to be properly described and diagnosed, and the current status of the genus Quetzalcoatlus has been identified as problematic. Mark Witton and colleagues (2010) noted that the type species of the genus - the fragmentary wing bones comprising Q. northropi - represent elements which are typically considered undiagnostic to generic or specific level, and that this complicates interpretations of azhdarchid taxonomy. For instance, Witton et al. (2010) suggested that the Q. northropi type material is of generalised enough morphology to be near identical to that of other giant azhdarchids, such as the overlapping elements of the contemporary Romanian giant azhdarchid Hatzegopteryx. This being the case, and assuming Q. northropi can be distinguished from other pterosaurs (i.e., if it is not a nomen dubium), perhaps Hatzegopteryx should be regarded as a European occurrence of Quetzalcoatlus. However, Witton et al. also noted that the skull material of Hatzegopteryx and Q. sp. differ enough that they cannot be regarded as the same animal, but that the significance of this cannot be ascertained given uncertainty over the relationships of Quetzalcoatlus specimens.[2] These issues can only be resolved by Q. northropi being demonstrated as a valid taxon and its relationships with Q. sp. being investigated. An additional complication to these discussions are the likelihood that huge pterosaurs such as Q. northropi could have made long, transcontinental flights, suggesting that locations as disparate as North America and Europe could have shared giant azhdarchid species.[2]

An azhdarchid neck vertebra, discovered in 2002 from the Maastrichtian age Hell Creek Formation, may also belong to Quetzalcoatlus. The specimen (BMR P2002.2) was recovered accidentally when it was included in a field jacket prepared to transport part of a tyrannosaur specimen. Despite this association with the remains of a large carnivorous dinosaur, the vertebra shows no evidence that it was chewed on by the dinosaur. The bone came from an individual azhdarchid pterosaur estimated to have had a wingspan of 5–5.5 m (16–18 ft).[12]

Classification

Skeletal reconstruction of Q. sp.

Below is a cladogram showing the phylogenetic placement of Quetzalcoatlus within Neoazhdarchia from Andres and Myers (2013).[13]

 Neoazhdarchia 

 Thalassodromidae 

Thalassodromeus sethi

Tupuxuara leonardii

Tupuxuara longicristatus




 Dsungaripteridae 


Domeykodactylus ceciliae

Dsungaripterus weii

Noripterus complicidens

Noripterus parvus
 Chaoyangopteridae 

Eoazhdarcho liaoxiensis

Shenzhoupterus chaoyangensis

Chaoyangopterus zhangi

Jidapterus edentus

Radiodactylus langstoni


 Azhdarchidae 

Azhdarcho lancicollis

TMM 42489

Zhejiangopterus linhaiensis

Arambourgiania philadelphiae

Quetzalcoatlus northropi

Quetzalcoatlus sp.









Paleobiology

Quetzalcoatlus and other animals of the Hell Creek Formation

Quetzalcoatlus was abundant in Texas during the Lancian in a fauna dominated by Alamosaurus.[14] The Alamosaurus-Quetzalcoatlus association probably represents semi-arid inland plains.[14] Quetzalcoatlus had precursors in North America and its apparent rise to widespreadness may represent the expansion of its preferred habitat rather than an immigration event, as some experts have suggested.[14]

Feeding

Artist's impression of a group of Quetzalcoatlus feeding on the ground

There have been a number of different ideas proposed about the lifestyle of Quetzalcoatlus. Because the area of the fossil site was four hundred kilometers removed from the coastline and there were no indications of large rivers or deep lakes nearby at the end of the Cretaceous, Lawson in 1975 rejected a fish-eating lifestyle, instead suggesting that Quetzalcoatlus scavenged like the marabou stork, but then on the carcasses of titanosaur sauropods such as Alamosaurus. Lawson had found the remains of the giant pterosaur while searching for the bones of this dinosaur, which formed an important part of its ecosystem.

In 1996, Lehman and Langston rejected the scavenging hypothesis, pointing out that the lower jaw bent so strongly downwards that even when it closed completely a gap of over five centimeters remained between it and the upper jaw, very different from the hooked beaks of specialized scavenging birds. They suggested that with its long neck vertebrae and long toothless jaws Quetzalcoatlus fed like modern-day skimmers, catching fish during flight while cleaving the waves with its beak.[15] While this skim-feeding view became widely accepted, it was not subjected to scientific research until 2007 when a study showed that for such large pterosaurs it was not a viable method because the energy costs would be too high due to excessive drag.[16] In 2008 pterosaur workers Mark Witton and Darren Naish published an examination of possible feeding habits and ecology of azhdarchids. Witton and Naish noted that most azhdarchid remains are found in inland deposits far from seas or other large bodies of water required for skimming. Additionally, the beak, jaw, and neck anatomy are unlike those of any known skimming animal. Rather, they concluded that azhdarchids were more likely terrestrial stalkers, similar to modern storks, and probably hunted small vertebrates on land or in small streams. Though Quetzalcoatlus, like other pterosaurs, was a quadruped when on the ground, Quetzalcoatlus and other azhdarchids have fore and hind limb proportions more similar to modern running ungulate mammals than to their smaller cousins, implying that they were uniquely suited to a terrestrial lifestyle.[4]

Flight

Artist's impression of an individual in flight

The nature of flight in Quetzalcoatlus and other giant azhdarchids was poorly understood until serious biomechanical studies were conducted in the 21st century. One early (1984) experiment by Paul MacCready used practical aerodynamics to test the flight of Quetzalcoatlus. MacCready constructed a model flying machine or ornithopter with a simple computer functioning as an autopilot. The model successfully flew with a combination of soaring and wing flapping;[17] however, the model was half scale based on a then-current weight estimate of around 80 kg, far lower than more modern estimates of over 200 kg.[18] The method of flight in these pterosaurs depends largely on weight, which has been controversial, and widely differing masses have been favored by different scientists. Some researchers have suggested that these animals employed slow, soaring flight, while others have concluded that their flight was fast and dynamic.[4] In 2010, Donald Henderson argued that the mass of Q. northropi had been underestimated, even the highest estimates, and that it was too massive to have achieved powered flight. He estimated it in his 2010 paper as 540 kg. Henderson argued that it may have been flightless.[18]

Reconstructed skeleton

However, most other flight capability estimates have disagreed with Henderson's research, suggesting instead an animal superbly adapted to long-range, extended flight. In 2010, Mike Habib, a professor of biomechanics at Chatham University, and Mark Witton, a British paleontologist, undertook further investigation into the claims of flightlessness in large pterosaurs. After factoring wingspan, body weight, and aerodynamics, computer modelling led the two researchers to conclude that Q. northropi was capable of flight "up to 80 miles an hour for 7 to 10 days at altitudes of 15,000 feet". Habib further suggested a maximum flight range of 8,000 to 12,000 miles for Q. northropi.[19] Henderson's work was also further criticized by Witton and Habib in another study, who pointed out that although Henderson used excellent mass estimations, they were based on outdated pterosaur models, and that anatomical study of Q. northropi and other large pterosaur forelimbs show a higher degree of robustness than would be expected if they were purely quadrupedal.[6] This study proposed that large pterosaurs most likely utilized a short burst of powered flight in order to then transition to thermal soaring.

Cultural significance

Models in South Bank for the Royal Society's 350th anniversary exhibition

Quetzalcoatlus has been featured in documentaries, both in cinemas and on television, since the 1980s. The Smithsonian project to build a working model of Q. northropi was the subject of the 1986 IMAX documentary On the Wing, shown at the National Air and Space Museum in Washington, D.C..[17] In the BBC's 1999 documentary Walking with Dinosaurs, Quetzalcoatlus was erroneously shown as toothed piscivore with an inaccurate stub-like crest. In 2009, Dangerous Ltd.'s Clash of the Dinosaurs depicted it as having a number of fictional traits created by the producers to heighten entertainment value, including the ability to use ultraviolet vision to locate dinosaur urine when hunting in the air.[20] Quetzalcoatlus was also erroneously depicted in the 2011 documentary March of the Dinosaurs as a clawless, bipedal scavenger. Conversely, in the 2009 series Animal Armageddon and the 2010 BBC film Flying Monsters 3D, Quetzalcoatlus was accurately portrayed with pycnofibres. However, in both Flying Monsters 3D and the 2001 documentary When Dinosaurs Roamed America, Quetzalcoatlus was shown as being a vulture-like scavenger. In the "Return to Jurassic Park" bonus feature of the 2011 Blu-ray release of the Jurassic Park film series, John R. Horner describes Quetzalcoatlus as the pterosaur that most accurately represented and matched the size of the pterosaurs featured in the films.

In June 2010, several life-sized models of Q. northropi were put on display on London's South Bank as the centerpiece exhibit for the Royal Society’s 350th anniversary exhibition. The models, which included both flying and standing individuals with wingspans of 9 m (30 ft), were intended to help build public interest in science. The models were created by scientists from the University of Portsmouth, including David Martill, Bob Loveridge, and Mark Witton, and engineers Bob and Jack Rushton from Griffon Hoverwork. The display featured the most accurate pterosaur models constructed at the time; these models took into account the latest evidence based on skeletal and trace fossils from related pterosaurs.[21]

In 1985, the U.S. Defense Advanced Research Projects Agency (DARPA) and AeroVironment used Quetzalcoatlus northropi as the basis for an experimental ornithopter UAV. They produced a half-scale model weighing 18 kilograms (40 lb), with a wingspan of 5.5 metres (18 ft). Coincidentally, Douglas A. Lawson, who discovered Q. northropi in Texas in 1971, named it for John "Jack" Northrop, a developer of tailless flying wing aircraft in the 1940s.[22] The replica of Q. northropi incorporates a "flight control system/autopilot which processes pilot commands and sensor inputs, implements several feedback loops, and delivers command signals to its various servo-actuators". It is on exhibit at the National Air and Space Museum.[23]

See also

References

  1. Langston, W. (1981). "Pterosaurs", Scientific American, 244: 122-136.
  2. 1 2 3 Witton, M.P., Martill, D.M. and Loveridge, R.F. (2010). "Clipping the Wings of Giant Pterosaurs: Comments on Wingspan Estimations and Diversity." Acta Geoscientica Sinica, 31 Supp.1: 79-81
  3. Guinness World Book of Records 2014. The Jim Pattison Group. 2014. p. 27. ISBN 978-1-908843-15-9.
  4. 1 2 3 4 Witton, M.P., and Naish, D. (2008). "A Reappraisal of Azhdarchid Pterosaur Functional Morphology and Paleoecology." PLoS ONE, 3(5): e2271. doi:10.1371/journal.pone.0002271
  5. Paul, Gregory S. (2002). Dinosaurs of the Air: The Evolution and Loss of Flight in Dinosaurs and Birds. Johns Hopkins University Press. p. 472. ISBN 0-8018-6763-0.
  6. 1 2 Witton, M.P., Habib M.B. (2010). "On the Size and Flight Diversity of Giant Pterosaurs, the Use of Birds as Pterosaur Analogues and Comments on Pterosaur Flightlessness." PLoS ONE, 5(11): e13982. doi:10.1371/journal.pone.0013982
  7. 1 2 Kellner, A.W.A., and Langston, W. (1996). "Cranial remains of Quetzalcoatlus (Pterosauria, Azhdarchidae) from Late Cretaceous sediments of Big Bend National Park, Texas." Journal of Vertebrate Paleontology, 16: 222–231.
  8. Lehman, T.M., McDowell, F. and J. Connelly, J. (2006). "First isotopic (U-Pb) age for the Late Cretaceous Alamosaurus vertebrate fauna of West Texas, and its significance as a link between two faunal provinces." Journal of Vertebrate Paleontology, 26: 922–928.
  9. Lawson, D. A. (1975). "Pterosaur from the Latest Cretaceous of West Texas. Discovery of the Largest Flying Creature." Science, 187: 947-948.
  10. Lawson, D. A. (1975). "Could pterosaurs fly?", Science, 188: 676-678
  11. Buffetaut, E., Grigorescu, D., and Csiki, Z. (2002). "A new giant pterosaur with a robust skull from the latest Cretaceous of Romania." Naturwissenschaften, 89: 180–184.
  12. Henderson, M.D. and Peterson, J.E. "An azhdarchid pterosaur cervical vertebra from the Hell Creek Formation (Maastrichtian) of southeastern Montana." Journal of Vertebrate Paleontology, 26(1): 192–195.
  13. Andres, B.; Myers, T. S. (2013). "Lone Star Pterosaurs". Earth and Environmental Science Transactions of the Royal Society of Edinburgh: 1. doi:10.1017/S1755691013000303.
  14. 1 2 3 Lehman, T. M., 2001, Late Cretaceous dinosaur provinciality: In: Mesozoic Vertebrate Life, edited by Tanke, D. H., and Carpenter, K., Indiana University Press, pp. 310-328.
  15. Lehman, T. and Langston, W. Jr. (1996). "Habitat and behavior of Quetzalcoatlus: paleoenvironmental reconstruction of the Javelina Formation (Upper Cretaceous), Big Bend National Park, Texas", Journal of Vertebrate Paleontology, 18: 48A
  16. Humphries, S., Bonser, R.H.C., Witton, M.P. and Martill, D.M. (2007). "Did Pterosaurs Feed by Skimming? Physical Modelling and Anatomical Evaluation of an Unusual Feeding Method." PLoS Biol, 5(8): e204. doi:10.1371/journal.pbio.0050204
  17. 1 2 MacCready, P. (1985). "The Great Pterodactyl Project." Engineering & Science, California Institute of Technology, 49(2): 18-24.
  18. 1 2 Henderson, D.M. (2010). "Pterosaur body mass estimates from three-dimensional mathematical slicing." Journal of Vertebrate Paleontology, 30(3): 768-785. doi:10.1080/02724631003758334
  19. Frazier, Reid. "Peerless Pterosaur Could Fly Long-Distance For Days". NPR.
  20. Wedel, M. (2009). "Lies, damned lies, and Clash of the Dinosaurs." Sauropod Vertebra Picture of the Week, 15 December 2009. Accessed online 26 September 2010, http://svpow.wordpress.com/2009/12/15/lies-damned-lies-and-clash-of-the-dinosaurs/
  21. Anonymous (2010). "Engineers make dinosaurs fly." The Engineer, 22 June 2010. accessed online 26 September 2010: theengineer.co.uk
  22. Jacobsen, Annie. 2011. "When Flying Dinosaurs Were Drones". Los Angeles Times Magazine (February 27, 2011).
  23. AeroVironment. 2011. "UAS Advanced Development: Quetzalcoatlus Northropi", avinc.com, retrieved July 28, 2011.
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