Biology:Dinosaur behavior

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Dinosaur behavior is difficult for paleontologists to study since much of paleontology is dependent solely on the physical remains of ancient life. However, trace fossils and paleopathology can give insight into dinosaur behavior. Interpretations of dinosaur behavior are generally based on the pose of body fossils and their habitat, computer simulations of their biomechanics, and comparisons with modern animals in similar ecological niches. As such, the current understanding of dinosaur behavior relies on speculation, and will likely remain controversial for the foreseeable future. However, there is general agreement that some behaviors which are common in crocodiles and birds, dinosaurs' closest living relatives, were also common among dinosaurs. Gregarious behavior was common in many dinosaur species. Dinosaurs may have congregated in herds for defense, for migratory purposes, or to provide protection for their young. There is evidence that many types of dinosaurs, including various theropods, sauropods, ankylosaurians, ornithopods, and ceratopsians, formed aggregations of immature individuals. Nests and eggs have been found for most major groups of dinosaurs, and it appears likely that dinosaurs communicated with their young, in a manner similar to modern birds and crocodiles. The crests and frills of some dinosaurs, like the marginocephalians, theropods and lambeosaurines, may have been too fragile to be used for active defense, and so they were likely used for sexual or aggressive displays, though little is known about dinosaur mating and territorialism. Most dinosaurs seem to have relied on land-based locomotion. A good understanding of how dinosaurs moved on the ground is key to models of dinosaur behavior; the science of biomechanics, in particular, has provided significant insight in this area. For example, studies of the forces exerted by muscles and gravity on dinosaurs' skeletal structure have investigated how fast dinosaurs could run,[1] whether diplodocids could create sonic booms via whip-like tail snapping,[2] and whether sauropods could float.[3]

Ceratopsian behavior

Centrosaurine ceratopsids did not fully develop their cranial ornamentation until fully grown. Scott Sampson argues that comparing ceratopsids to modern mammals with a similar lifecycle can yield insight into the socioecology of the ancient horned dinosaurs.

Parental care is implied by the fossilized remains of a grouping of Psittacosaurus consisting of one adult and 34 juveniles. In this case, the large number of juveniles may be due to communal nesting.[4]

Fossil deposits dominated large numbers of ceratopsids from individual species suggest that these animals were at least somewhat social.[5] However, the exact nature of ceratopsid social behavior has historically been controversial.[6] In 1997, Lehman argued that the aggregations of many individuals preserved in bonebeds originated as local "infestations" and compared them to similar modern occurrences in crocodiles and tortoises.[6] Other authors, such as Scott D. Sampson, interpret these deposits as the remains of large "socially complex" herds.[6]

Modern animals with mating signals as prominent as the horns and frills of ceratopsians tend to form these kinds of large, intricate associations.[7] Sampson found in previous work that the centrosaurine ceratopsids did not achieve fully developed mating signals until nearly fully grown.[8] He finds commonality between the slow growth of mating signals in centrosaurines and the extended adolescence of animals whose social structures are ranked hierarchies founded on age-related differences.[8] In these sorts of groups young males are typically sexually mature for several years before actually beginning to breed, when their mating signals are most fully developed.[9] Females, by contrast do not have such an extended adolescence.[9]

Other researchers who support the idea of ceratopsid herding have speculated that these associations were seasonal.[10] This hypothesis portrays ceratopsids as living in small groups near the coasts during the rainy season and inland with the onset of the dry season.[10] Support for the idea that ceratopsids formed herds inland comes from the greater abundance of bonebeds in inland deposits than coastal ones. The migration of ceratopsids away from the coasts may have represented a move to their nesting grounds.[10] Many African herding animals engage in this kind of seasonal herding today.[10] Herds would also have afforded some level of protection from the chief predators of ceratopsids, tyrannosaurids.[11]

Ornithopod and Parksosaur behavior

Trackways have also confirmed parental behavior among ornithopods from the Isle of Skye in northwestern Scotland.[12]

Oryctodromeus

Based on current fossil evidence from dinosaurs such as Oryctodromeus, some herbivorous species seem to have led a partially fossorial (burrowing) lifestyle.[13]

Iguanodon

The first potential evidence of herding behavior was the 1878 discovery of 31 Iguanodon dinosaurs which were then thought to have perished together in Bernissart, Belgium, after they fell into a deep, flooded sinkhole and drowned.[14]

Hadrosauridae

Trackways of hundreds or even thousands of herbivores indicate that duck-bills (hadrosaurids) may have moved in great herds, like the American Bison or the African Springbok. Jack Horner's 1978 discovery of a Maiasaura ("good mother dinosaur") nesting ground in Montana demonstrated that parental care continued long after birth among the ornithopods.[15]

Sauropodomorph behavior

Sauropod tracks document that these animals traveled in groups composed of several different species, at least in Oxfordshire, England,[16] although there is not evidence for specific herd structures.[17] There is evidence that Patagonian titanosaurian sauropods (1997 discovery) nested in large groups.[18] A dinosaur embryo (pertaining to the prosauropod Massospondylus) was found without teeth, indicating that some parental care was required to feed the young dinosaur.[19]

Theropod behavior

The interpretation of dinosaurs as gregarious has also extended to depicting carnivorous theropods as pack hunters working together to bring down large prey.[20][21] However, this lifestyle is uncommon among the modern relatives of dinosaurs (crocodiles and other reptiles, and birds – Harris's Hawk is a well-documented exception), and the taphonomic evidence suggesting pack hunting in such theropods as Deinonychus and Allosaurus can also be interpreted as the results of fatal disputes between feeding animals, as is seen in many modern diapsid predators.[22] Head wounds from bites suggest that theropods, at least, engaged in active aggressive confrontations.[23]

In 2001, Bruce Rothschild and others published a study examining evidence for stress fractures in theropod dinosaurs and the implications for their behavior.[24] Since stress fractures are caused by repeated trauma they are more likely to be a result of the animal's behavior than fractures obtained during a single injurious event.[25] The distribution of stress fractures also has behavioral significance.[26] Stress fractures to the hand are more likely to result from predatory behavior since injuries to the feet could be obtained while running or migrating.[26] In order to identify stress fractures occurring in the feet specifically due to predatory behavior, the researchers checked to see if the toes which bore the greatest portion of the animals weight while in motion also had the greatest percentage of stress fractures.[27] Since the lower end of the third metatarsal would contact the ground first while a theropod was running it would have borne the most stress and should be most predisposed to suffer stress factors more frequently.[27] The lack of such a bias in the examined fossils indicates an origin for the stress fractures from a source other than running, like interaction with prey.[27] They suggested that such injuries could occur as a result of the theropod trying to hold struggling prey with its feet.[27] Contact with struggling prey is also the likely cause of tendon avulsions found in the forelimbs of Allosaurus and Tyrannosaurus.[27] The authors concluded that the presence of stress fractures provide evidence for "very active" predation-based diets rather than obligate scavenging.[24]

Research based on energetic modelling has also backed up the role of active predatory behaviors in theropods and has effectively ruled out obligate scavenging as a likely strategy.[28] However scavenging was still likely to have been an important resource for many theropod with body size playing a key role in its importance. In general, the researchers found that small species, such as coelurosaurs, and species larger than 1000 kg, such as an adult Tyrannosaurs rex, would have been poor scavengers. In contrast intermediate sized species, such as Dilophosaurus, were found to have been capable of gaining significant energy though scavenging.[28]

Majungasaurus

Cannibalism amongst some species of dinosaurs was confirmed by tooth marks found in Madagascar in 2003, involving the theropod Majungasaurus.[29]

Ornithomimid behavior

Sinornithomimus

One example of immature dinosaurs forming social groups comes from a site in Inner Mongolia that has yielded the remains of over twenty Sinornithomimus, from one to seven years old. This assemblage is interpreted as a social group that was trapped in mud.[30]

Tyrannosauridae

Tooth wear patterns hint that complex head shaking behaviors may have been involved in tyrannosaur feeding.[31] The partially healed tail of an Edmontosaurus is damaged in such a way that shows the animal was bitten by a tyrannosaur but survived.[32]

Oviraptoridae

The Mongolian oviraptorid Citipati was discovered in a chicken-like brooding position in 1993, which may mean it was covered with an insulating layer of feathers that kept the eggs warm.[33]

Troodontidae

A recently discovered troodont fossil demonstrates that some dinosaurs slept with their heads tucked under their arms.[34] This behavior, which may have helped to keep the head warm, is also characteristic of modern birds.

Dromaeosauridae

Primitive dromaeosaurids such as Microraptor may have been arboreal (tree-climbing).[35]

Velociraptor

2003 restoration by Raúl Martín showing a featherless Velociraptor battling Protoceratops. (It is now known that Velociraptor had feathers.)

From a behavioral standpoint, one of the most valuable dinosaur fossils was discovered in the Gobi Desert in 1971. It included a Velociraptor attacking a Protoceratops,[36] providing evidence that dinosaurs did indeed attack each other.[32]

Scansoriopterygidae

The enigmatic scansoriopterygids may have been arboreal (tree-climbing).[37]

See also

  • Dinosaur brains and intelligence
  • Dinosaur senses

Footnotes

  1. Alexander RM (2006). "Dinosaur biomechanics". Proceedings of the Royal Society B 273 (1596): 1849–1855. doi:10.1098/rspb.2006.3532. PMID 16822743. 
  2. "Shape of a cracking whip". Physical Review Letters 88 (24): 244301. 2002. doi:10.1103/PhysRevLett.88.244301. PMID 12059302. Bibcode2002PhRvL..88x4301G. 
  3. Henderson, D.M. (2003). "Effects of stomach stones on the buoyancy and equilibrium of a floating crocodilian: A computational analysis". Canadian Journal of Zoology 81 (8): 1346–1357. doi:10.1139/z03-122. 
  4. Meng Qingjin; Liu Jinyuan; Varricchio, David J.; Huang, Timothy; Gao Chunling (2004). "Parental care in an ornithischian dinosaur". Nature 431 (7005): 145–146. doi:10.1038/431145a. PMID 15356619. Bibcode2004Natur.431..145M. 
  5. "Abstract," Sampson (2001); page 263.
  6. 6.0 6.1 6.2 "Introduction," Sampson (2001); page 264.
  7. "Ceratopsid Socioecology," Sampson (2001); pages 267-268.
  8. 8.0 8.1 "Retarded Growth of Mating Signals," Sampson (2001); page 270.
  9. 9.0 9.1 "Sociological Correlates in Extant Vertebrates," Sampson (2001); page 265.
  10. 10.0 10.1 10.2 10.3 "Resource Exploitation and Habitat," Sampson (2001); page 269.
  11. "Predation Pressure," Sampson (2001); page 272.
  12. Dinosaur family tracks Footprints show maternal instinct after leaving the nest.
  13. Varricchio DJ; Martin AJ; Katsura, Y (2007). "First trace and body fossil evidence of a burrowing, denning dinosaur". Proceedings of the Royal Society B 274 (1616): 1361–1368. doi:10.1098/rspb.2006.0443. PMID 17374596. 
  14. Yans J; Dejax J; Pons D; Dupuis C; Taquet P (2005). "Implications paléontologiques et géodynamiques de la datation palynologique des sédiments à faciès wealdien de Bernissart (bassin de Mons, Belgique)" (in French). Comptes Rendus Palevol 4 (1–2): 135–150. doi:10.1016/j.crpv.2004.12.003. 
  15. Horner, J.R.; Makela, Robert (1979). "Nest of juveniles provides evidence of family structure among dinosaurs". Nature 282 (5736): 296–298. doi:10.1038/282296a0. Bibcode1979Natur.282..296H. 
  16. Day, J.J.; Upchurch, P; Norman, DB; Gale, AS; Powell, HP (2002). "Sauropod trackways, evolution, and behavior". Science 296 (5573): 1659. doi:10.1126/science.1070167. PMID 12040187. 
  17. Wright, Joanna L. (2005). "Steps in understanding sauropod biology". in Curry Rogers, Kristina A.. The Sauropods: Evolution and Paleobiology. Berkeley: University of California Press. pp. 252–284. ISBN 0-520-24623-3. https://archive.org/details/sauropodsevoluti00roge. 
  18. Chiappe, Luis M.; Jackson, Frankie; Coria, Rodolfo A.; Dingus, Lowell (2005). "Nesting titanosaurs from Auca Mahuevo and adjacent sites". in Curry Rogers, Kristina A.. The Sauropods: Evolution and Paleobiology. Berkeley: University of California Press. pp. 285–302. ISBN 0-520-24623-3. https://archive.org/details/sauropodsevoluti00roge. 
  19. Reisz RR, Scott, D Sues, H-D, Evans, DC & Raath, MA (2005). "Embryos of an Early Jurassic prosauropod dinosaur and their evolutionary significance". Science 309 (5735): 761–764. doi:10.1126/science.1114942. PMID 16051793. Bibcode2005Sci...309..761R. 
  20. Lessem, Don; Glut, Donald F. (1993). "Allosaurus". The Dinosaur Society's Dinosaur Encyclopedia. Random House. pp. 19–20. ISBN 0-679-41770-2. https://archive.org/details/dinosaursocietys00less. 
  21. Maxwell, W. D.; Ostrom, John (1995). "Taphonomy and paleobiological implications of Tenontosaurus-Deinonychus associations". Journal of Vertebrate Paleontology 15 (4): 707–712. doi:10.1080/02724634.1995.10011256. (abstract )
  22. Roach, Brian T.; Brinkman, Daniel L. (2007). "A reevaluation of cooperative pack hunting and gregariousness in Deinonychus antirrhopus and other nonavian theropod dinosaurs". Bulletin of the Peabody Museum of Natural History 48 (1): 103–138. doi:10.3374/0079-032X(2007)48[103:AROCPH2.0.CO;2]. 
  23. Tanke, Darren H. (1998). "Head-biting behavior in theropod dinosaurs: paleopathological evidence". Gaia (15): 167–184. ISSN 0871-5424. Archived from the original on 2008-02-27. https://web.archive.org/web/20080227134632/http://www.mnhn.ul.pt/geologia/gaia/12.pdf. 
  24. 24.0 24.1 "Abstract," Rothschild, et al., et al. (2001); page 331.
  25. "Introduction," in Rothschild, et al. (2001); pages 331-332.
  26. 26.0 26.1 "Introduction," Rothschild, et al. (2001); page 332.
  27. 27.0 27.1 27.2 27.3 27.4 "Discussion," Rothschild, et al. (2001); page 334.
  28. 28.0 28.1 Kane, A.; Healy, K; Ruxton, GD; Jackson, AL (2016). "Body Size as a Driver of Scavenging in Theropod Dinosaurs". The American Naturalist 187 (6): 706–716. doi:10.1086/686094. PMID 27172591. 
  29. Rogers, Raymond R.; Krause, DW; Curry Rogers, K (2003). "Cannibalism in the Madagascan dinosaur Majungatholus atopus". Nature 422 (6931): 515–518. doi:10.1038/nature01532. PMID 12673249. Bibcode2003Natur.422..515R. 
  30. Varricchio, D.J.; Sereno, Paul C.; Xijin, Zhao; Lin, Tan; Wilson, Jeffery A.; Lyon, Gabrielle H. (2008). "Mud-trapped herd captures evidence of distinctive dinosaur sociality". Acta Palaeontologica Polonica 53 (4): 567–578. doi:10.4202/app.2008.0402. 
  31. "Introduction," Abler (2001); page 84.
  32. 32.0 32.1 Carpenter, K. (1998). "Evidence of predatory behavior by theropod dinosaurs". Gaia 15: 135–144. Archived from the original on 2007-11-17. https://web.archive.org/web/20071117132451/http://vertpaleo.org/publications/jvp/15-576-591.cfm. Retrieved 2007-12-05. 
  33. Oviraptor nesting Oviraptor nests or Protoceratops?
  34. Xu, X.; Norell, M.A. (2004). "A new troodontid dinosaur from China with avian-like sleeping posture". Nature 431 (7010): 838–841. doi:10.1038/nature02898. PMID 15483610. Bibcode2004Natur.431..838X. 
  35. Chatterjee, S.; Templin, R. J. (2007). "Biplane wing planform and flight performance of the feathered dinosaur Microraptor gui". Proceedings of the National Academy of Sciences 104 (5): 1576–1580. doi:10.1073/pnas.0609975104. PMID 17242354. PMC 1780066. Bibcode2007PNAS..104.1576C. http://www.pnas.org/cgi/reprint/0609975104v1.pdf. 
  36. "The Fighting Dinosaurs". American Museum of Natural History. Archived from the original on March 9, 2012. https://web.archive.org/web/20120309154910/http://www.amnh.org/exhibitions/fightingdinos/ex-fd.html. Retrieved 2007-12-05. 
  37. Zhang, F.; Zhou, Z.; Xu, X.; Wang, X. (2002). "A juvenile coelurosaurian theropod from China indicates arboreal habits". Naturwissenschaften 89 (9): 394–398. doi:10.1007/s00114-002-0353-8. PMID 12435090. Bibcode2002NW.....89..394Z. 

References

  • Abler, W.L. 2001. A kerf-and-drill model of tyrannosaur tooth serrations. p. 84-89. In: Mesozoic Vertebrate Life. Ed.s Tanke, D. H., Carpenter, K., Skrepnick, M. W. Indiana University Press.
  • Rothschild, B., Tanke, D. H., and Ford, T. L., 2001, Theropod stress fractures and tendon avulsions as a clue to activity: In: Mesozoic Vertebrate Life, edited by Tanke, D. H., and Carpenter, K., Indiana University Press, p. 331-336.
  • Sampson, S. D., 2001, Speculations on the socioecology of Ceratopsid dinosaurs (Orinthischia: Neoceratopsia): In: Mesozoic Vertebrate Life, edited by Tanke, D. H., and Carpenter, K., Indiana University Press, pp. 263–276.