Timeline of tyrannosaur research

Skeletal mount of the Tyrannosaurus rex holotype.

This timeline of tyrannosaur research is a chronological listing of events in the history of paleontology focused on the tyrannosaurs, a group of predatory theropod dinosaurs that began as small, long-armed bird-like creatures with elaborate cranial ornamentation but achieved apex predator status during the Late Cretaceous as their arms shrank and body size expanded. Although formally trained scientists did not begin to study tyrannosaur fossils until the mid-19th century, these remains may have been discovered by Native Americans and interpreted through a mythological lens. The Montana Crow tradition about thunder birds with two claws on their feet may have been inspired by isolated tyrannosaurid forelimbs found locally.[1] Other legends possibly inspired by tyrannosaur remains include Cheyenne stories about a mythical creature called the Ahke,[2] and Delaware stories about smoking the bones of ancient monsters to have wishes granted.[3]

Tyrannosaur remains were among the first dinosaur fossils collected in the United States. The first of these was named Deinodon horridus by Joseph Leidy. However, as this species was based only on teeth the name would fall into disuse.[4] Soon after, Edward Drinker Cope described Laelaps aquilunguis from a partial skeleton in New Jersey. Its discovery heralded the realization that carnivorous dinosaurs were bipeds, unlike the lizardlike megalosaurs sculpted for the Crystal Palace.[5] Laelaps was also among the first dinosaurs to be portrayed artistically as a vigorous, active animal, presaging the Dinosaur Renaissance by decades.[6] Later in the century, Cope's hated rival Othniel Charles Marsh would discover that the name Laelaps had already been given to a parasitic mite, and would rename the dinosaur Dryptosaurus.[7]

Early in the 20th century, Tyrannosaurus itself was discovered by Barnum Brown and named by Henry Fairfield Osborn, who would recognize it as a representative of a distinct family of dinosaurs he called the Tyrannosauridae.[8] Tyrannosaur taxonomy would be controversial for many decades afterward. One controversy centered around the use of the name Tyrannosauridae for this family, as the name "Deinodontidae" had already been proposed. The name Tyrannosauridae came out victorious following arguments put forth by Dale Russell in 1970.[9] The other major controversy regarding tyrannosaur taxonomy was the family's evolutionary relationships. Early in the history of paleontology, it was assumed that the large carnivorous dinosaurs were all part of one evolutionary lineage ("carnosaurs"), while the small carnivorous dinosaurs were part of a separate lineage (coelurosaurs). Tyrannosaurid anatomy led some early researchers like Matthew, Brown, and Huene, to cast doubt on the validity of this division. However, the traditional carnosaur-coelurosaur division persisted until the early 1990s, when the application of cladistics to tyrannosaur systematics confirmed the doubts of early workers and found tyrannosaurs to be large-bodied coelurosaurs.[10]

Another debate about tyrannosaurs would not be settled until the early 21st century: their diet. Early researchers were so overwhelmed by the massive bulk of Tyrannosaurus rex that some, like Lawrence Lambe, were skeptical that it was even capable of hunting down live prey and assumed that it lived as a scavenger. This view continued to be advocated into the 1990s by Jack Horner but was shown false by Kenneth Carpenter, who reported the discovery of a partially healed tyrannosaur bite wound on an Edmontosaurus annectens tail vertebra, proving that T. rex at least sometimes pursued living victims.[11]

Prescientific

Bones of Dryptosaurus, originally known as Laelaps.

19th century

Illustration of the teeth of Deinodon.

1850s

1856

1860s

1865

1866

1868

1870s

Illustration of the type specimen (AMNH 3982) of Manospondylus gigas

1876

1877

1880s

1884

1890s

Leaping Laelaps by Charles R. Knight, 1896.

1890

1892

20th century

Skeletal reconstruction of T. rex from the original description.

1900s

1905

1910s

1914

1917

1920s

Type specimen of Gorgosaurus sternbergi, now recognized as a juvenile Gorgosaurus libratus.

1922

Despite still classifying tyrannosaurs as members of the family Deinodontidae.[9] They proposed that, contrary to researchers who regarded tyrannosaurs as carnosaurs related to other large carnivorous dinosaurs like Allosaurus and Megalosaurus, that tyrannosaurs were actually more closely related to the small carnivores known as coelurosaurs.[10]

1923

1928

1930s

1930

1932

1933

1940s

Holotype skull of "Gorgosaurus" (now Nanotyrannus) lancensis.

1946

1950s

Holotype skull of Tarbosaurus bataar PIN 551-1, Museum of Paleontology, Moscow.

1955

1956

1958

1960s

1964

1970s

Artist's restoration of Daspletosaurus torosus.

1970

1974

Skeletal mount of Alioramus remotus.

1975

1976

1977

1978

1979

1980s

A juvenile Tarbosaurus.

1980

1981

Holotype skull of Nanotyrannus lancensis.

1983

1986

1988

1990s

Tyrannosaurs had long been classified with carnosaurs like Allosaurus (pictured). In the 1990s, this consensus began to change.

1990

Paleontologists like Abler studied tyrannosaur tooth biomechanics (Tyrannosaurus teeth pictured) in the early 1990s.

1991

1992

1993

1994

Lockley and Hunt reported a possible T. rex footprint in 1994.

1995

The known skeletal elements of Bagaraatan ostromi.

1996

1997

1998

Skeletal mount of Santanaraptor placidus.

1999

21st century

2000s

Edmontosaurus annectens tail vertebrae have been preserved with partially healed T. rex bite marks.

2000

Known skeletal elements of Eotyrannus lengi.

2001

Diagaram of T. rex forelimb anatomy.

Thomas R. Holtz, Jr. published a cladistic analysis of the Tyrannosauridae.[25] Holtz defined the Tyrannosauridae in his analysis as "all descendants of the most recent common ancestor of Tyrannosaurus and Aublysodon."[10] He concluded that the Tyrannosauridae had two subfamilies, a more primitive Aublysodontinae and the tyrannosaurinae.[25] He defined the former as "Aublysodon and all taxa sharing a more recent common ancestor with it than with Tyrannosaurus."[26]

Jaws and teeth of Albertosaurus.

He observed that these dinosaurs were distinguished by their unserrated premaxillary teeth.[25] The Tyrannosaurinae he defined as "Tyrannosaurus and all taxa sharing a more recent common ancestor with it than with Aublysodon."[26]

Holtz considered these definitions only tentative due to the scant remains representing most taxa in the Aublysodontinae.[27] Holtz also noted that the lack of serrations on aublyodontines' premaxillary teeth could have been caused by tooth wear in life, postmortem abrasion, or digestion.[28] Alternatively "Aublysodontine"-type teeth could be from an ontogenetic stage or sexual morph of another kind of tyrannosaur.[28] Holtz also expressed the taxonomic opinion that Nanotyrannus lancensis was a juvenile T. rex.[10] The results of his phylogenetic analysis of the Tyrannosauridae are reproduced below:

2002

Skeletal mount of Appalachiosaurus.

2003

2004

2005

Artist's restoration of Guanlong.

2006

2009

2010s

Artist's restoration of Xiongguanlong.

2010

2011

Artist's restoration of Yutyrannus.

2012

2013

Artist's restoration of Nanuqsaurus.

2014

2015

2016

See also

Footnotes

  1. Mayor (2005); "Crow Fossil Collectors," page 276.
  2. 1 2 Mayor (2005); "Cheyenne Fossil Knowledge," pages 211–212.
  3. 1 2 Mayor (2005); "Smoking the Monster's Bone: An Ancient Delaware Fossil Legend," pages 68–69.
  4. Horner (2001); "History of Dinosaur Collecting in Montana," page 44.
  5. For the implications of Dryptosaurus for theropod gait, see Holtz (2004); "Introduction", page 111. For a characterization of the Crystal Palace theropods, see Bakker (2004); page 3.
  6. Brett-Surman (1999); "1897," page 713.
  7. Moore (2014); "1866," page 62.
  8. For the discovery of T. rex, see Horner (2001); "History of Dinosaur Collecting in Montana," page 48. For the erection of the Tyrannosauridae, see Holtz (2004); "Introduction", page 114.
  9. 1 2 3 4 5 6 7 8 9 Holtz (2004); "Introduction", page 114.
  10. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 Holtz (2004); "Systematics and Evolution", page 127.
  11. 1 2 3 4 5 6 7 8 Holtz (2004); "Paleobiology", pages 134–135.
  12. 1 2 3 4 5 6 7 8 9 10 11 12 13 Holtz (2004); "Table 5.1: Tyrannosauroidea", page 114.
  13. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Holtz (2004); "Table 5.1: Tyrannosauroidea", page 112.
  14. 1 2 Holtz (2004); "Introduction", page 111.
  15. Tanke (2010); "Background and Collection History," page 542.
  16. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Holtz (2004); "Table 5.1: Tyrannosauroidea", page 113.
  17. 1 2 3 4 5 6 7 8 9 10 11 12 13 Holtz (2004); "Paleobiology", page 134.
  18. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Holtz (2004); "Paleobiology", page 135.
  19. Chicago Field Museum - All About Sue
  20. Holtz (2004); "Paleobiology", pages 135–136.
  21. Holtz (2004); "Systematics and Evolution", page 133.
  22. Holtz (2004); "Systematics and Evolution", page 128.
  23. 1 2 Carpenter and Smith (2001); "Abstract," page 90.
  24. Carpenter and Smith (2001); "Introduction," page 91.
  25. 1 2 3 Holtz (2001); "Abstract," page 64.
  26. 1 2 Holtz (2001); "Results," page 66.
  27. Holtz (2001); "Results," page 66-67.
  28. 1 2 Holtz (2001); "Results," page. 67.
  29. 1 2 Abler (2001); "Abstract," page 84.
  30. Abler (2001); "Kerf-and-Drill Model," page 86.
  31. Abler (2001); "Kerf-and-Drill Model," pages 86–88.
  32. Abler (2001); "Introduction," page 84.
  33. Jacobsen (2001); "Abstract," page 58.
  34. Jacobsen (2001); "Introduction," page 59.
  35. Jacobsen (2001); "Discussion," page 61.
  36. Jacobsen (2001); "Discussion," page 60.
  37. Rauhut (2003); "Abstract," page 903.
  38. Xu et al. (2004); "Abstract," page 680.
  39. Carr, Williamson, and Schwimmer (2005); "Abstract," page 119.
  40. Carpenter, Miles, and Cloward (2005); "Abstract," page 23.
  41. Xu et al. (2006); "Abstract," page 715.
  42. Sereno et al. (2009); "Abstract," page 418.
  43. Ji, Ji, and Zhang (2009); "Abstract," page 1369.
  44. Carr and Williamson (2010); "Abstract," page 1.
  45. Averianov et al. (2010); "Abstract," page 42.
  46. Li et al. (2010); "Abstract," page 183.
  47. Carr et al. (2011); "Abstract," page 241.
  48. Hone et al. (2011); "Abstract," page 495.
  49. Xu et al. (2012); "Abstract," page 92.
  50. Brusatte and Benson (2013); "Abstract," page 47.
  51. Loewen et al. (2013); "Abstract," page 1.
  52. Fiorillo and Tykoski (2014); "Abstract," page 1.
  53. Lü et al. (2013); "Abstract," page 1.
  54. National Geographic’s T. rex Autopsy is a Roaring Return to the Science Special
  55. Stephen L. Brusatte, Alexander Averianov, Hans-Dieter Sues, Amy Muir and Ian B. Butler (2016). "New tyrannosaur from the mid-Cretaceous of Uzbekistan clarifies evolution of giant body sizes and advanced senses in tyrant dinosaurs". Proceedings of the National Academy of Sciences of the United States of America. in press.

References

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