Dilophosaurus: Difference between revisions
m er... |
|||
Line 43: | Line 43: | ||
==Classification== |
==Classification== |
||
[[File:Dilophosaurus wetherilli.PNG|thumb|Restoration]] |
[[File:Dilophosaurus wetherilli.PNG|thumb|Restoration with hypothetical filaments.]] |
||
''Dilophosaurus'' has been examined several times over the years and has been assigned to no less than nine different [[theropod]] groups. Welles (1954) and the majority of subsequent phylogenetic analyses during the 1980s and 1990s have classified this genus as a large coelophysoid within the taxon [[Coelophysoidea]].<ref name="welles_s_1954"/><ref>M. T. Carrano, R. B. J. Benson, and S. D. Sampson. 2012. The phylogeny of Tetanurae (Dinosauria: Theropoda). Journal of Systematic Palaeontology 10(2):211–300 [M. Carrano/M. Carrano]</ref> However, most 21st century studies to date have found that ''Dilophosaurus'' and various other "dilophosaurids" were more closely related to [[Tetanurae|tetanuran]] theropods than to true coelophysoids.<ref name=yates2005>Yates, 2005. A new theropod dinosaur from the Early Jurassic of South Africa and its implications for the early evolution of theropods. Palaeontologia Africana. 41, 105–122.</ref><ref name=smithetal2007a>Smith, Makovicky, Hammer and Currie, 2007. Osteology of ''Cryolophosaurus ellioti'' (Dinosauria: Theropoda) from the Early Jurassic of Antarctica and implications for early theropod evolution. Zoological Journal of the Linnean Society. 151, 377–421.</ref> |
''Dilophosaurus'' has been examined several times over the years and has been assigned to no less than nine different [[theropod]] groups. Welles (1954) and the majority of subsequent phylogenetic analyses during the 1980s and 1990s have classified this genus as a large coelophysoid within the taxon [[Coelophysoidea]].<ref name="welles_s_1954"/><ref>M. T. Carrano, R. B. J. Benson, and S. D. Sampson. 2012. The phylogeny of Tetanurae (Dinosauria: Theropoda). Journal of Systematic Palaeontology 10(2):211–300 [M. Carrano/M. Carrano]</ref> However, most 21st century studies to date have found that ''Dilophosaurus'' and various other "dilophosaurids" were more closely related to [[Tetanurae|tetanuran]] theropods than to true coelophysoids.<ref name=yates2005>Yates, 2005. A new theropod dinosaur from the Early Jurassic of South Africa and its implications for the early evolution of theropods. Palaeontologia Africana. 41, 105–122.</ref><ref name=smithetal2007a>Smith, Makovicky, Hammer and Currie, 2007. Osteology of ''Cryolophosaurus ellioti'' (Dinosauria: Theropoda) from the Early Jurassic of Antarctica and implications for early theropod evolution. Zoological Journal of the Linnean Society. 151, 377–421.</ref> |
||
Revision as of 16:48, 20 March 2017
Dilophosaurus Temporal range: Early Jurassic,
| |
---|---|
Cast of the holotype with skull restored after the second specimen, Royal Ontario Museum | |
Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Animalia |
Phylum: | Chordata |
Clade: | Dinosauria |
Clade: | Saurischia |
Clade: | Theropoda |
Genus: | †Dilophosaurus Welles, 1970 |
Species: | †D. wetherilli
|
Binomial name | |
†Dilophosaurus wetherilli Welles, 1954
| |
Synonyms | |
Dilophosaurus breedorum |
Dilophosaurus (/daɪˌloʊfəˈsɔːrəs, -foʊ-/[1] dy-LOAF-o-SAWR-əs) is a genus of theropod dinosaur. It contains a single known species, Dilophosaurus wetherilli, known from fossil remains found in the Kayenta Formation of Arizona. This rock formation has been dated to the early Jurassic Period (Sinemurian age), about 193 million years ago. Dilophosaurus was among the largest carnivores of its time (about 7 meters long) and had a pair of rounded crests on its skull.
Description
Dilophosaurus measured about 7 metres (23 ft) long and weighed about 400 kilograms (880 lb).[2]
The teeth of Dilophosaurus are long, but have a fairly small base and expand basally.[3] Dilophosaurus had 12 maxillary teeth and as many as 18 dentary teeth; the teeth were smaller in the tip of the upper jaw. The second and third front teeth feature serrations, which are absent in the fourth.[4] Another skull feature was a notch behind the first row of teeth, giving Dilophosaurus an almost crocodile-like appearance, similar to the putatively piscivorous spinosaurid dinosaurs. This "notch" existed by virtue of a weak connection between the premaxillary and maxillary bones of the skull.[5] The braincase is well known in Dilophosaurus, and is significant in that it bears a feature of the top side wall that is absent in ceratosaurians.[4] Compared with ceratosaurians, the distal scapular expansion in D. wetherilli is uniquely rectangular.[4] The upper leg bone (femur) is longer than the lower leg (tibia).[4]
A study by Robert J. Gay (2005) comparing various specimens found no indication that sexual dimorphism was present in Dilophosaurus, so males and females would have been largely the same in terms of skeletal anatomy.[6]
According to Rauhut (2000), Dilophosaurus can be distinguished based on the following features: a lacrimal bone with a thickened dorso-posterior rim; cervical vertebrae that have neural spines with a distinct central "cap" and an anterior and posterior "shoulder"; a scapular blade with a squared distal expansion; the presence of thin, paired nasolacrimal crests extending vertically from skull roof, each with a fingerlike posterior projection (according to Carrano, 2012)[7][4][8]
Cranial ornamentation
The most distinctive characteristic of Dilophosaurus is the pair of rounded crests on its skull, made up of extensions of the nasal and lacrimal bones. These are considered to be too delicate for anything but display purposes.[4][9] Dodson (1997) noted that cranial crests first appeared in Dilophosaurus and were later retained, in one form or another, by other theropods.[10]
The function of the crests on the skull of Dilophosaurus have been the subject of speculation among scientists ever since they were discovered. Traditionally, these bizarre cranial structures (and similar structures and post-cranial armor in other dinosaurs) were thought to be variously for attracting mates, intimidating/fighting rivals in the group, and intimidating potential predators of other species. However, Padian, Horner and Dhaliwal (2004) argued that phylogenetic, histological, and functional evidence indicates that these bizarre structures were most likely used for intra-species recognition.[11][12]
Discovery and species
The first Dilophosaurus specimens were uncovered by Sam Welles in the summer of 1942 in the Kayenta Formation in Arizona.[13] The site had been found by a Navajo, Jesse Williams, in 1940. Three individuals were present but one of these was too weathered to make an excavation worthwhile. Two specimens were brought back to Berkeley for cleaning and mounting by the team of Wann Langston, the holotype UCMP 37302 (specimen on which a name is based), and a second skeleton, the paratype UCMP 37303. They were given the name Megalosaurus wetherilli in 1954 by Welles.[14] The specific name honoured John Wetherill who had explored the area of the find.[15]
Returning to the same formation in 1964 to determine from which time period the bones dated, Welles found a new specimen, UCMP 77270, not far from the location of the previous discovery. Based on the unique double crests preserved for the first time in the new skeleton, Welles realized that the species was significantly different from Megalosaurus. In 1970, he re-classified it in a new genus, which he named Dilophosaurus,[3][14] from the Greek words di (δι) meaning "two", lophos (λόφος) meaning "crest", and sauros (σαυρος) meaning "lizard"; thus, "two-crested lizard".[15] The available evidence strongly suggests that both the holotype of D. wetherilli and the second skeleton are juveniles.[4]
In 2001, Robert Gay reported the discovery of two, or possibly three, new specimens of Dilophosaurus wetherilli in the collections of the Museum of Northern Arizona. The specimens were found in 1978 in the Kayenta Formation, in the Rock Head Quadrangle. Gay found the specimens to compare favorably with the holotype (UCMP 37302). Gay noted that this material is significant in that it includes parts of the pelvis not preserved in either the holotype or in the "D. breedorum" specimen UCMP 77270.[3]
Gay reported that some elements in the MNA collection were representative of an infant specimen (MNA P1.3181). This included a partial humerus, a partial fibula, and a tooth fragment. The infant specimen is significant for several reasons; first, it lends insight into the growth rates of early dinosaurs, and second, it provides researchers with an opportunity to compare the growth rate of Dilophosaurus wetherilli with that of a related species like Coelophysis bauri which could provide insights into early theropod growth rates. This specimen is also the first known infant of the genus.[3]
Hu Shaojin (1993) assigned specimen KMV 8701 to a second species, Dilophosaurus sinensis.[16] This species was recovered from the Yunnan Province of China in 1987, with the prosauropod Yunnanosaurus.[17] Compared to D. wetherilli, this species was larger and more robust. Lamanna et al. (1998b) examined the material ascribed to D. sinensis and found it to be synonymous with Sinosaurus triassicus.[18] This finding was confirmed in 2013.[19]
A proposed third species, D. breedorum, was coined by Samuel Welles through Welles and Pickering (1999) for the specimen UCMP 77270 collected in 1964. Tykoski (2005) performed an ontogenetic analysis in his thesis and concluded that D. breedorum is an adult Dilophosaurus wetherilli.[20] This was the first specimen of the genus to preserve a nearly complete cranial crest.[21] Welles concluded that differences between the original specimens and UCMP 77270 justified the naming of separate species.[4] He was unable to complete a manuscript describing this during his lifetime, and the name eventually came out in a private publication distributed by Pickering.[22] This species has not been accepted as valid in other reviews of the genus, which see it as a nomen nudum and/or a junior subjective synonym.[3][23]
Classification
Dilophosaurus has been examined several times over the years and has been assigned to no less than nine different theropod groups. Welles (1954) and the majority of subsequent phylogenetic analyses during the 1980s and 1990s have classified this genus as a large coelophysoid within the taxon Coelophysoidea.[9][24] However, most 21st century studies to date have found that Dilophosaurus and various other "dilophosaurids" were more closely related to tetanuran theropods than to true coelophysoids.[25][26]
The following family tree illustrates a synthesis of the relationships of the early theropod groups compiled by Hendrickx et al. in 2015, and illustrates the current consensus relationships of Dilophosaurus.[27]
Paleobiology
Dilophosaurus is considered to have been an obligate biped based on the presence of long hindlimbs oriented vertically under the pelvis, and short forelimbs that did not support quadrupedal locomotion. The hindlimbs suggest a fast and agile runner, as would be expected in a carnivorous theropod.[4]
Welles (1984) proposed that Dilophosaurus traveled in small groups, based on the fact that several individuals were found together.[4] Gay (2001b) noted that there was no direct evidence for this and noted that "flash floods would pick up scattered and isolated material from different individuals and deposit them together in the same area".[3] Cranial display features make sense in social, gregarious animals, where other members of the species are available to observe and interpret messages of sexual status.[10]
Feeding
The presence and distribution of non-interdigitating sutures in the skull of some reptilian groups, including Dilophosaurus, has been interpreted as indicating the presence of a system of levers, driven by jaw muscles, as an aid to predation.[28] Welles (1984) rejected this hypothesis and interpreted the potential mobility in the skull of Dilophosaurus as a sign of weakness, and argued that the loose connection of the premaxilla precluded the capture and subduing of prey.[4] This led to the early hypothesis that Dilophosaurus scavenged off carrion, because its teeth were too weak to bring down large prey.[5] Recently, some researchers have argued that Dilophosaurus may have been piscivorous, due to the presence of Eubrontes-sized swim tracks at some localities, as well as anatomical similarities with spinosaurids.[29]
Growth
Tkach (1996) conducted a study of the bone structure of the type species and concluded that Dilophosaurus wetherilli could have attained growth rates of nearly 35 kilograms (77 lb) in early life,[clarification needed] which reflects a rapid growth rate.[30]
Paleopathology
One Dilophosaurus wetherilli specimen shows potential damage "due to injury or crushing" to a vertebra, and a potential abscess on a humerus. A Dilophosaurus wetherilli is also known with an unusually small left humerus compared to a very robust right arm, a possible example of "fluctuating asymmetry". Fluctuating asymmetry results from developmental disturbances and is more common in populations under stress and can therefore be informative about the quality of conditions a dinosaur lived under.[31] A specimen of Dilophosaurus from the University of California Museum of Paleontology labelled as UCMP 37302 displays eight different pathologies to its pectoral girdle and forelimb bones, including three bone tumors, broken and re-healed bones on both arms, deformed digits and an inability to utilize one forelimb. Though it is not certain, it is believed that most or all of the injuries on this specimen were acquired in a fight or an accident and that the theropod would have been in severe pain as it healed. The pathologies of this specimen were documented in the journal PLOS One.[32]
In a 2001 study conducted by Bruce Rothschild and other paleontologists, 60 foot bones referred to Dilophosaurus were examined for signs of stress fracture, but none were found.[33]
Paleoecology
The remains of the type specimen of Dilophosaurus wetherilli UCMP 37302 and partial skeleton UCMP 37303 were recovered in the Silty Facies Member of the Kayenta Formation, in northeastern Arizona. The remains were discovered in 1942 and 1964 in blue shale and brown/gray siltstone that was deposited during the Sinemurian-Pliensbachian stages of the Early Jurassic, approximately 196-183 million years ago. Two other specimens assigned to this genus were discovered in the same formation; one in 1982 (UCMP 130053) in channel sandstone and the other, a scapula in terrestrial sandstone.[34]
The Kayenta Formation is part of the Glen Canyon Group that includes formations not only in northern Arizona but also parts of southeastern Utah, western Colorado, and northwestern New Mexico. It is composed mostly of two facies, one dominated by silty deposition and the other dominated by sandstone. The siltstone facies is found in much of Arizona, while the sandstone facies is present in areas of northern Arizona, southern Utah, western Colorado, and northwestern New Mexico. The formation was primarily deposited by rivers, with the silty facies as the slower, more sluggish part of the river system. Kayenta Formation deposition was ended by the encroaching dune field that would become the Navajo Sandstone.[35] A definitive radiometric dating of this formation has not yet been made, and the available stratigraphic correlation has been based on a combination of radiometric dates from vertebrate fossils, magnetostratigraphy and pollen evidence.[34] It has been surmised that the Kayenta Formation was deposited during the Sinemurian and Pliensbachian stages of the Early Jurassic Period or approximately 196 to 183 million years ago.[36]
The Kayenta Formation has yielded a small but growing assemblage of organisms. Most fossils are from the silty facies.[37] Most organisms known so far are vertebrates. Non-vertebrates include microbial or "algal" limestone,[38] petrified wood,[39] plant impressions,[40] freshwater bivalves and snails,[35] ostracods,[41] and invertebrate trace fossils.[38]
Vertebrates are known from both body fossils and trace fossils. Vertebrates known from body fossils include (the following after Lucas et al. [2005],[37] except where noted): hybodont sharks, indeterminate bony fish, lungfish,[39] salamanders,[42] the frog Prosalirus, the caecilian Eocaecilia, the turtle Kayentachelys, a sphenodontian reptile, lizards,[43] several early crocodylomorphs including Calsoyasuchus, Eopneumatosuchus, Kayentasuchus, and Protosuchus), the pterosaur Rhamphinion, several theropods including Dilophosaurus, Kayentavenator[44] Coelophysis kayentakatae, and the "Shake N Bake" theropod, the basal sauropodomorph Sarahsaurus,[45] a heterodontosaurid, armored dinosaurs Scelidosaurus and Scutellosaurus, the tritylodontids synapsids Dinnebiton, Kayentatherium, and Oligokyphus, morganucodontids,[43] possible early true mammal Dinnetherium, and a haramyid mammal. The majority of these finds come from the vicinity of Gold Spring, Arizona.[37] Vertebrate trace fossils include coprolites[38] and the tracks of therapsids, lizard-like animals, and several types of dinosaur.[46]
Explorations in the 1970s and 1980s by James M. Clark, Farish Jenkins and David E. Fastovsky and collection and analysis by William R. Downs have produced several vertebrate specimens. The Kayenta Formation has produced several mass burial sites, and the remains of three coelophysoid taxa of different body size, which represents the most diverse ceratosaur fauna yet known.[47]
Remains assigned to Dilophosaurus were recovered in the Upper Member of the Dharmaram Formation, in Andhra Pradesh, India. The remains were discovered in mudstone that was deposited during the Sinemurian stage of the Early Jurassic, approximately 196-189 million years ago. The same sediments also contained the fossils of a crocodilian, a sauropodomorph and the sauropod Lamplughsaura dharmaramensis.[48]
Ichnology
In the Kayenta Formation in Arizona, the same formation that yielded the original specimens for this genus, the trackways known as Kayentapus hopii and Dilophosauripus williamsi were attributed to Dilophosaurus by Welles (1971). These ichnotaxa feature a series of three-toed footprints that are consistent with the expected size and shape of the feet of Dilophosaurus.[49] In 1991, trackway specialist Gerard Gierlinski re-examined tracks from the Holy Cross Mountains in Poland and renamed them Kayentapus soltykovensis, concluding that the "dilophosaur" form was the most appropriate candidate for making these ichnotaxa.[50]
Fossilized footprints, discovered in 200-million-year-old sedimentary rock, which were assigned to Dilophosaurus were discovered in the Höganäs Formation in Vallåkra, Sweden, during the 1970s. The footprints appears to show that these dinosaurs lived in herds.[51] Fossilized footprints assigned to Dilophosaurus have also been discovered in Sala, Sweden. Other tracks discovered in the Höganäs Formation have been assigned to the ichnogenus Grallator (Eubrontes) cf. giganteus, which were discovered in Rhaetian strata, and Grallator (Eubrontes) soltykovensis, which were discovered in Hettangian strata.[52] A few of the tracks were taken to museums, but most of them disappeared in natural floodings.[53] In 1994, Gierlinski and Ahlberg assigned these tracks from the Hoganas Formation of Sweden to Dilophosaurus as well.[54]
Gierlinski (1996) observed unusual traces associated with a track specimen in the collection at the Pratt Museum in Amherst, Massachusetts. Specimen AC 1/7 is a "dinosaur sitting imprint", made when a dinosaur is resting its body on the ground, leaving an impression of its belly between a pair of footprints. Traces associated with AC 1/7 were interpreted by Gierlinski as the imprints of feathers, suggesting that Dilophosaurus was a feathered dinosaur.[54] Further analysis proved, however, that the lines that seemed to be feathers were in reality just cracks in the mud where the animal sat. While this does not rule out the possibility of feathery covering on this species, there is no evidence for it and it currently remains as speculation.[55]
Tracks of Eubrontes and Gigandipus of the Connecticut River Valley, which have been found in both Connecticut and in Massachusetts, have often been attributed to Dilophosaurus,[56][57] however no fossil remains of Dilophosaurus have been directly attributed to either one of the footprint types. The size and shape suggested they were made by a theropod around 20 feet long similar to that of Dilophosaurus, suggesting they were either made by Dilophosaurus or a very close relative. Two similar footprints, Anchisauripus and Grallator, also found in the valley, have often been attributed to Dilophosaur's smaller relatives, Podokesaurus and Coelophysis, and occasionally attributed to Dilophosaurus itself.[56]
In popular culture
Dilophosaurus is featured in both Michael Crichton's 1990 novel Jurassic Park and its 1993 movie adaptation. It is depicted as venomous, being able to spit venom, aiming for the eyes to blind and paralyze its prey (much like a spitting cobra); in the film, it also has a retractable neck frill around its neck (much like a frill-necked lizard). There is no evidence to support either the frill or the venom spitting,[58] which was acknowledged by Crichton as creative license.[59] In the film, Steven Spielberg also reduced the size of Dilophosaurus to 3 feet (0.91 m) tall and 5 feet (1.5 m) long in order to avoid confusion with Velociraptor.[60]
See also
References
- ^ "Dilophosaurus". Oxford Dictionaries UK English Dictionary. Oxford University Press. n.d. Retrieved 2016-01-21.
- ^ Paul, G.S., 2010, The Princeton Field Guide to Dinosaurs, Princeton University Press p. 75
- ^ a b c d e f Gay, Robert (2001). "New specimens of Dilophosaurus wetherilli (Dinosauria: Theropoda) from the early Jurassic Kayenta Formation of northern Arizona". Western Association of Vertebrate Paleontologists annual meeting volume Mesa, Arizona. 1: 1.
- ^ a b c d e f g h i j k Welles, S. P. (1984). "Dilophosaurus wetherilli (Dinosauria, Theropoda), osteology and comparisons". Palaeontogr. Abt. A. 185: 85–180.
- ^ a b Norman, David (1985). The Illustrated Encyclopedia of Dinosaurs. New York: Crescent Books. pp. 62–67. ISBN 0-517-46890-5.
- ^ Gay, Robert (2005). "Evidence for sexual dimorphism in the Early Jurassic theropod dinosaur, Dilophosaurus and a comparison with other related forms In: Carpenter, Ken, ed. The Carnivorous Dinosaurs". The Carnivorous Dinosaurs. Indiana University Press. pp. 277–283. ISBN 0-253-34539-1.
- ^ Carrano, Benson and Sampson, 2012. The phylogeny of Tetanurae (Dinosauria: Theropoda). Journal of Systematic Palaeontology. 10(2), 211–300.
- ^ Rauhut, 2000. The interrelationships and evolution of basal theropods (Dinosauria, Saurischia). Ph.D. dissertation, Univ. Bristol [U.K.]. 440 pp.
- ^ a b Welles, S. P. (1954). "New Jurassic dinosaur from the Kayenta formation of Arizona". Bulletin of the Geological Society of America. 65 (6): 591–598. doi:10.1130/0016-7606(1954)65[591:NJDFTK]2.0.CO;2.
- ^ a b Dodson, P. (1997) Paleoecology In: Encyclopedia of Dinosaurs, edited by Currie, P.J., and Padian, K., Academic Press.
- ^ Glut, D. F., 2006, Dinosaurs, the Encyclopedia, Supplement 4: McFarland & Company, Inc, 749pp.
- ^ Padian, K., Horner, J. R., and Dhaliwal, J. 2004. Species recognition as the principal cause of bizarre structures in dinosaurs. Journal of Vertebrate Paleontology 23(3):100A.
- ^ Welles, Sam (2007). "Dilophosaurus Discovered". ucmp.berkeley.edu. University of California, Berkeley. Retrieved 2007-11-17.
- ^ a b Welles, Sam (2007). "Dilophosaurus Details". ucmp.berkeley.edu. University of California, Berkeley. Retrieved 2007-11-17.
- ^ a b Benton, Michael J. (2012). Prehistoric Life. Edinburgh, Scotland: Dorling Kindersley. p. 258. ISBN 978-0-7566-9910-9.
- ^ Irmis, Randall (2004-12-22). "First Report of Megapnosaurus from China" (PDF). PaleoBios. 24 (3): 11–18.
- ^ Hu, Shaojin (1993). "A Short Report on the Occurrence of Dilophosaurus from Jinning County, Yunnan Province". Vertebrata PalAsiatica. 31: 65–69.
- ^ Lamanna, M. C., Holtz, T. R. Jr, and Dodson, P., 1998, A reassessment of the Chinese Theropod Dinosaur Dilophosaurus sinensis: Journal of Vertebrate Paleontology, Volume 18, Supplement to Number 3. Abstracts of papers. Fifty-eighth annual meeting, Society of Vertebrate Paleontology, Snowbird Ski and Summer Resort, Snowbird, Utah, September 30 – October 3, 1998, p. 57a.
- ^ Xing, L.; Bell, P. R.; Rothschild, B. M.; Ran, H.; Zhang, J.; Dong, Z.; Zhang, W.; Currie, P. J. (2013). "Tooth loss and alveolar remodeling in Sinosaurus triassicus (Dinosauria: Theropoda) from the Lower Jurassic strata of the Lufeng Basin, China". Chinese Science Bulletin. doi:10.1007/s11434-013-5765-7.
- ^ Tykoski, 2005. Anatomy, ontogeny and phylogeny of coelophysoid theropods. PhD Dissertation. University of Texas at Austin. 553 pp.
- ^ Mortimer, Mickey (2012). "Coelophysoidea".
- ^ Olshevsky, George (1999-12-05). "Dinosaur Genera List corrections #126". Dinosaur Mailing List Archives. Cleveland Museum of Natural History. Retrieved 2008-06-25.
- ^ Tykoski, R.S. & Rowe, T. (2004). "Ceratosauria". In: Weishampel, D.B., Dodson, P., & Osmolska, H. (Eds.) The Dinosauria (2nd edition). Berkeley: University of California Press. Pp. 47–70 ISBN 0-520-24209-2
- ^ M. T. Carrano, R. B. J. Benson, and S. D. Sampson. 2012. The phylogeny of Tetanurae (Dinosauria: Theropoda). Journal of Systematic Palaeontology 10(2):211–300 [M. Carrano/M. Carrano]
- ^ Yates, 2005. A new theropod dinosaur from the Early Jurassic of South Africa and its implications for the early evolution of theropods. Palaeontologia Africana. 41, 105–122.
- ^ Smith, Makovicky, Hammer and Currie, 2007. Osteology of Cryolophosaurus ellioti (Dinosauria: Theropoda) from the Early Jurassic of Antarctica and implications for early theropod evolution. Zoological Journal of the Linnean Society. 151, 377–421.
- ^ Hendrickx, C., Hartman, S.A., & Mateus, O. (2015). An Overview of Non- Avian Theropod Discoveries and Classification. PalArch’s Journal of Vertebrate Palaeontology, 12(1): 1-73.
- ^ Bradley, O. C. 1903. The muscles of mastication and movements of the skull in Lacertilia. Zoologische Jahrbiicher, Anatomie 18: 475–486.
- ^ Milner, A.; Kirkland, J. (2007). "The case for fishing dinosaurs at the St. George Dinosaur Discovery Site at Johnson Farm" (PDF). Survey Notes of the Utah Geological Survey. 39: 1–3.
- ^ Tkach, J. S., 1996, Multi-element osteohistological analysis of Dilphosaurus wetherilli: Journal of Vertebrate Paleontology, v. 16, supplement to n. 3, Abstracts of Papers, Fifty-sixth Annual Meeting, Society of Vertebrate Paleontology, American Museum of Natural History, New York, New York, October 16–19.
- ^ Molnar, R. E., 2001, Theropod paleopathology: a literature survey: In: Mesozoic Vertebrate Life, edited by Tanke, D. H., and Carpenter, K., Indiana University Press, p. 337-363.
- ^ http://journals.plos.org/plosone/article?id=10.1371%2Fjournal.pone.0149140
- ^ 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.
- ^ a b J. M. Clark and D. E. Fastovsky. 1986. Vertebrate biostratigraphy of the Glen Canyon Group in northern Arizona. The Beginning of the Age of the Dinosaurs: Faunal change across the Triassic-Jurassic boundary, N. C. Fraser and H.-D. Sues (eds.), Cambridge University Press 285–301
- ^ a b Harshbarger, J. W.; Repenning, C. A.; Irwin, J. H. (1957). Stratigraphy of the uppermost Triassic and the Jurassic rocks of the Navajo country. Professional Paper. Vol. 291. Washington, D.C.: U.S. Geological Survey.
- ^ Padian, K (1997) Glen Canyon Group In: Encyclopedia of Dinosaurs, edited by Currie, P. J., and Padian, K., Academic Press.
- ^ a b c Lucas, S. G.; Heckert, A. B.; Tanner, L. H. (2005). "Arizona's Jurassic fossil vertebrates and the age of the Glen Canyon Group". In Heckert, A. B.; Lucas, S. G. (eds.). Vertebrate paleontology in Arizona. Bulletin. Vol. 29. Albuquerque, NM: New Mexico Museum of Natural History and Science. pp. 95–104.
- ^ a b c Luttrell, P. R., and Morales, M. 1993. Bridging the gap across Moenkopi Wash: a lithostratigraphic correlation. Aspects of Mesozoic geology and paleontology of the Colorado Plateau. Pages 111–127 in Morales, M., editor. Museum of Northern Arizona, Flagstaff, AZ. Bulletin 59.
- ^ a b Jenkins, F. A., Jr. and Shubin, N. H. 1998. Prosalirus bitis and the anuran caudopelvic mechanism. Journal of Vertebrate Paleontology 18(3):495–510.
- ^ Rigby, J. K., Hamblin, W. K., Matheny, R., and Welsh, S. L. 1971. Guidebook to the Colorado river: part 3, Moab to Hite, Utah through Canyonlands National Park. Brigham Young University Research Studies, Geology Series 18(2).
- ^ Lucas, S. G., and Tanner L. H. 2007. Tetrapod biostratigraphy and biochronology of the Triassic-Jurassic transition on the southern Colorado Plateau, USA. Palaeogeography, Palaeoclimatology, Palaeoecology 244(1–4):242–256.
- ^ Curtis, K., and Padian, K. 1999. An Early Jurassic microvertebrate fauna from the Kayenta Formation of northeastern Arizona: microfaunal change across the Triassic-Jurassic boundary. PaleoBios 19(2):19–37.
- ^ a b Jenkins, F. A., Jr., Crompton, A. W., and Downs, W. R. 1983. Mesozoic mammals from Arizona: new evidence in mammalian evolution. Science 222(4629):1233–1235.
- ^ Gay, R. 2010. Kayentavenator elysiae, a new tetanuran from the early Jurassic of Arizona. Pages 27–43 in Gay, R. Notes on early Mesozoic theropods. Lulu Press (on-demand online press).
- ^ Rowe, T. B., Sues, H.-D., and Reisz, R. R. 2011. Dispersal and diversity in the earliest North American sauropodomorph dinosaurs, with a description of a new taxon. Proceedings of the Royal Society B: Biological Sciences 278(1708):1044–1053.
- ^ Hamblin, A. H., and Foster, J. R. 2000. Ancient animal footprints and traces in the Grand Staircase-Escalante National Monument, south-central Utah. Pages 557–568 in Sprinkel, D. A., Chidsey, T. C., Jr., and Anderson, P. B. editors. Geology of Utah's parks and monuments. Utah Geological Association, Salt Lake City, UT. Publication 28.
- ^ Tykoski, R. S., 1998, The Osteology of Syntarsus kayentakatae and its Implications for Ceratosaurid Phylogeny: Theses, The University of Texas, December 1998.
- ^ Kutty, T. S.; Chatterjee, S.; Galton, P. M.; Upchurch, P. (2007). "Basal Sauropodomorphs (Dinosauria: Saurischia) from the Lower Jurassic of India: Their Anatomy and Relationships". Journal of Paleontology. 81 (6): 1218. doi:10.1666/04-074.1.
- ^ Welles, S.P. (1971). Dinosaur footprints from the Kayenta Formation of northern Arizona: Plateau, v. 44, pp. 27–38.
- ^ Gierlinski, G.(1991) New dinosaur ichnotaxa from the Early Jurassic of the Holy Cross Mountains, Poland. Palaeogeogr., Palaeoclimat.,Palaeoecol.,85(1–2): 137–148
- ^ http://www.exempelbanken.se/system/documents/980191441/original/3228_vallakra.pdf
- ^ Gierliński, G.; Ahlberg, A. (1994). "Late triassic and early jurassic dinosaur footprints in the höganäs formation of southern Sweden". Ichnos. 3 (2): 99. doi:10.1080/10420949409386377.
- ^ Kent Lungren. "Tankar i tiden: Kontakt med Trias och Jura". Kentlundgren.blogspot.se. Retrieved 2013-10-23.
- ^ a b Glut, D. F. (1999). Dinosaurs, the Encyclopedia, Supplement 1: McFarland & Company, Inc., 442pp.
- ^ Martin, A. J. & Rainforth, E. C. 2004. A theropod resting trace that is also a locomotion trace: case study of Hitchcock’s specimen AC 1/7. Geological Society of America, Abstracts with Programs 36 (2), 96.
- ^ a b "Dinosaur footprints of the Connecticut River Valley". Nash Dinosaur Track Site and Rock Shop.
- ^ "10 Crested Facts About Dilophosaurus". Mental Floss.
- ^ Bennington, J Bret (1996). "Errors in the Movie "Jurassic Park"". American Paleontologist. 4 (2): 4–7.
- ^ Crichton, Michael (1990). Jurassic Park. Alfred A. Knopf. ISBN 0-394-58816-9.
- ^ The Making of Jurassic Park by Don Shay & Jody Duncan, Boxtree Ltd; 1st Edition. edition (30 Jun 1993), ISBN 1-85283-774-8