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Podokesaurus

January 01, 1970

Podokesaurus is a genus of coelophysoid dinosaur that lived in what is now the eastern United States during the Early Jurassic Period. The first fossil was discovered by the geologist Mignon Talbot near Mount Holyoke, Massachusetts, in 1910. The specimen was fragmentary, preserving much of the body, limbs, and tail. In 1911, Talbot described and named the new genus and species Podokesaurus holyokensis based on it. The full name can be translated as "swift-footed lizard of Holyoke". This discovery made Talbot the first woman to find and describe a non-bird dinosaur. The holotype fossil was recognized as significant and was studied by other researchers, but was lost when the building it was kept in burned down in 1917; no unequivocal Podokesaurus specimens have since been discovered. It was made state dinosaur of Massachusetts in 2022.

Podokesaurus
Temporal range: Early Jurassic, 190 Ma
Holotype specimen, with tail and uncertain bones at left, and body at right
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Clade: Dinosauria
Clade: Saurischia
Clade: Theropoda
Superfamily: Coelophysoidea
Genus: Podokesaurus
Talbot, 1911
Species:
P. holyokensis
Binomial name
Podokesaurus holyokensis
Talbot, 1911
Synonyms
  • Coelophysis holyokensis (Talbot, 1911) Colbert, 1964

Estimated to have been about 1 m (3 ft) in length and 1–40 kg (2–90 lb) in weight, Podokesaurus was lightly constructed with hollow bones, and would have been similar to Coelophysis, being slender, long-necked, and with sharp, recurved teeth. The vertebrae were very light and hollow, and some were slightly concave at each end. The cervical (neck) vertebrae were relatively large in length and diameter compared to the dorsal (back) vertebrae, and the caudal (tail) vertebrae were long and slender. The humerus (upper-arm bone) was small and delicate, less than half the length of the femur (thigh-bone). The pubis (pubic bone) was very long, expanding both at the front and hind ends. The femur was slender, nearly straight, had thin walls, and was expanded at the back side of its lower end. The three metatarsals of the lower leg were closely appressed together forming a compact structure.

Since it was one of the few small theropods known at the time it was described, the affinities of Podokesaurus were long unclear. It was placed in the family Podokesauridae along with other small theropods, and was speculated to have been similar to a proto-bird. It was suggested it was a synonym of Coelophysis and a natural cast specimen was assigned to it, but these ideas are not currently accepted. The family Podokesauridae is not in use anymore, having been replaced by Coelophysidae, and Podokesaurus is thought to have been a coelophysoid. As such, Podokesaurus would have been a fleet-footed predator, with powerful forelimbs and grasping hands. It is estimated it could have run at 15–20 km/h (9–12 mph). Podokesaurus is thought to have been collected from the Portland Formation, the age of which has long been unclear, but is currently believed to date to the HettangianSinemurian stages of the Early Jurassic, between 201 and 190 million years ago.

Discovery and history edit

 
 
Geological maps of the Connecticut Valley from 1915; 22 is where Podokesaurus was found, 12 is Mount Holyoke (some areas marked as Triassic are now thought to be Early Jurassic in age)

In 1910, the American geologist Mignon Talbot was walking with her sister Ellen to Holyoke, Massachusetts, in the eastern US, when they passed a farm and noticed a small hill nearby. It had a gravel pit at one side, and was formed by an accumulation of sand, gravel, and boulders left by a receding glacier. Talbot noticed a white streak on a sandstone boulder at the bottom of the gravel pit, and upon discovering these were bones, she told her sister she had found a "real live fossil". This was because many fossil tracks had previously been discovered in the Connecticut Valley (that she had often taken her students to see), but few actual dinosaur skeletons, and none at Mount Holyoke. She was granted permission by the land owner to collect the specimen for Mount Holyoke College (an all-women's college a few miles from there), where she was head of the geology department.[1][2][3][4]

The next day she brought a group of workmen to collect the specimen, and found another piece of sandstone that contained the rest of the fossil as well as impressions of those in the first slab. The specimen appeared to have been exposed for years with no one noticing it, the boulder having been broken open by people or frost. The fossil was brought to the laboratory where it was prepared and photographed.[1] The incomplete specimen preserved 5 cervical (neck), 11 dorsal (back) and 24 caudal (tail) vertebrae, a fragment of the left scapula (shoulder blade) and right coracoid (part of the pectoral girdle), a partial left humerus (upper arm bone), phalanx bones of 3 fingers, including 2 unguals (claw bones), ribs, the pubis and ischium (bones forming the lower front and lower back of the pelvis, respectively), the femora (thigh bones), the left tibia (lower leg bone), a fragment of the right astragalus (a bone in the ankle), articulated metatarsals (foot bones) of the left foot, followed by 3 pedal phalanges (toe bones), partial metatarsals and possible phalanges of the right foot, and fragments of uncertain identity.[5][6] The light and delicate bones were in their natural position or nearly so within the rock, except for the tail and uncertain fragments, which were a few centimeters away from the skeleton, following a long gap in the skeleton behind the pelvis. The front half of the neck was missing.[1][7]

 
1915 skeletal reconstruction by Richard Swann Lull; shaded areas were known from the fossil, missing parts were reconstructed after Compsognathus
 
Model by Lull at Peabody Museum of Natural History

The significance of the fossil was confirmed at an intercollegiate meeting of geology departments, and when the American paleontologist Richard Swann Lull subsequently encouraged Talbot to describe the specimen, she replied she did not know anything about dinosaurs, but Lull suggested she should study them and then describe it. In December 1910, Talbot read a preliminary description of the fossil at the Paleontological Society meeting at Pittsburgh, and in June 1911 she published a short scientific description, in which she made the specimen the holotype of the new genus and species Podokesaurus holyokensis.[1][8] The generic name is derived from the Ancient Greek words podōkēs (ποδώκης), which means "swift (or fleet)-footed", an epithet commonly used in reference to the Greek hero Achilles, and saura (σαύρα) meaning "lizard", while the specific name refers to Holyoke. In full, the name can be translated as "swift-footed lizard of Holyoke".[8][2] The discovery and naming of Podokesaurus made Talbot the first woman to find and describe a non-bird dinosaur.[9] The American paleontologist Robert T. Bakker stated in 2014 that while old professors grumbled that women were unfit for working with fossils during his time at university, Talbot's discovery of Podokesaurus was a counterargument to that.[10]

By the time the description was published, Talbot had sent the fossil to the Peabody Museum of Natural History at Yale University for further preparation and study, where cast replicas were also made of the bones as they lay in the rock. There, Lull drew a reconstruction of the skeleton, basing the parts missing from the fossil on the equivalents in Compsognathus, and created a model of the animal in life, which Talbot later described as having a "sardonic smile". Lull expanded on Talbot's article in a 1915 publication, wherein he also proposed other identities for some of the bones than what she had originally suggested, including a partial coracoid instead of a scapula and part of the tibia instead of the ilium (part of the hips). Lull suggested that the boulder containing the fossil must have come from a ledge which lay on the south side of the Holyoke Range, about two or three miles north of where it was found, and specified that it was from the Longmeadow Sandstone.[6][2][11][7]

 
Mignon Talbot (second from left) and students searching the rubble of the burned down Williston Hall in 1917

Lull had sent his manuscript to the Danish ornithologist Gerhard Heilmann for criticism prior to publication. Heilmann published his response in a 1913 article in which he included previously unpublished photos of the fossil received from Talbot, as well as his own restorations. He disagreed with some of Lull's anatomical interpretations, and had corresponded regarding the fossil with the American zoologist Robert Wilson Shufeldt about his contentions. Heilmann's article was one in a series about the origin of birds, wherein he examined the skeletons of prehistoric reptiles to find traits that may have been ancestral to birds.[12] In a 1916 Washington Academy of Sciences meeting, Shufeldt gave an account of his correspondence with Lull, Talbot, and Heilmann, and agreed with the latter in some of his criticisms of Lull's restoration of Podokesaurus.[13]

Talbot wanted the fossil to stay at Yale or Washington on permanent exhibit, where it could "be with its kind", but it was kept at Mount Holyoke in the old science building, Williston Hall, as a local specimen, where it became a "pet curiosity" for the students. During the Christmas break of 1917, Williston Hall burned down, and no remains of the Podokesaurus fossil were found in the rubble. The American writer Christopher Benfey pointed out in 2002 that Podokesaurus therefore had the peculiar distinction of being the dinosaur that vanished twice.[2][1] The German paleontologist Friedrich von Huene was the last to study and describe the holotype specimen, in a 1914 publication before it was destroyed (he had studied it at Yale before Talbot's description was published).[7][14] While the college's fossil collections were almost entirely destroyed by the fire, its facilities and collections continued to grow and improve afterwards due to Talbot's efforts.[15]

No other unequivocal Podokesaurus specimens have since been found, but cast replicas of the type specimen remain at the Peabody Museum of Natural History and the American Museum of Natural History in New York. Podokesaurus received little further attention until new and abundant fossils of Coelophysis were discovered in the late 1940s, and the anatomy of small theropod dinosaurs became clearer; the American paleontologists Edwin Harris Colbert and Donald Baird compared Podokesaurus with Coelophysis in 1958, using the casts of the former. Along with the sauropodomorph Anchisaurus, Podokesaurus was among the first substantial collections of dinosaur skeletal material known from the East Coast of North America. Apart from a tooth (assigned to Coelophysis in 1976), all other Early Jurassic theropod records on the East Coast are footprints.[16][17][18]

In 2021, Podokesaurus and Anchisaurus were proposed as contenders for state dinosaur of Massachusetts by Representative Jack Patrick Lewis, with Podokesaurus winning the online poll.[19][20][21] On May 2, 2022, Governor Charlie Baker signed a law making it the official state dinosaur.[22]

Description edit

 
Size of Podokesaurus compared to a human and a cat

The preserved body of the only known Podokesaurus fossil was 18 cm (7 in) long.[8] Lull estimated the complete length of Podokesaurus to have been 1,150 mm (3.77 ft), the neck accounting for 130 mm (5.1 in), the back for 170 mm (6.7 in), the sacrum (the vertebrae of the pelvic region) for 45 mm (1.8 in), and the tail for 730 mm (2.40 ft).[6] Von Huene estimated the animal to have been 1,100 mm (3.6 ft) long, with the tail accounting for about 70 cm (2.3 ft), more than 1.5 times the rest of the skeleton together.[7] Colbert estimated the animal's length at about 1 m (3.3 ft).[17] In 1995, the writer Jan Peczkis estimated Podokesaurus to have weighed 10–40 kg (22–88 lb), through pelvic height determination (based on von Huene's measurements).[23] The paleontologist Gregory S. Paul estimated it to have weighed 1 kg (2 lb) in 2016 (based on a 1 m length estimate).[24] Talbot stated in 1937 that those scientists who had seen the specimen did not think it was a young individual as there were no indications of cartilage that would turn to bone with age,[1] while Paul thought it was possibly juvenile.[24] In general, the animal was lightly constructed, with hollow bones.[8] As a coelophysoid, it would likely have been similar in build to for example Coelophysis, being slender, long-necked, and with sharp, recurved teeth.[16]

Since few other small theropods were known at the time Podokesaurus was described, it was mainly compared to the later genera Compsognathus, Ornitholestes, and Ornithomimus, which were thought related. Due to the fragmentary nature of the Podokesaurus specimen and the fact that it is lost, the identity and shape of some of its bones are today unclear. As only casts of the specimen now remain, it is only possible to get a general impression of the preserved skeleton and its proportions. Talbot identified bone fragments next to the tail as skull bones because two of them were bilaterally symmetric, and one was broadly convex with a sulcus (or furrow) at the midline, and according to Lull, was possibly placed at the upper wall of the skull, not far from the frontal bones. Lull thought other of these elements may have been part of the nasal bones.[6][17] Von Huene instead interpreted these bones as caudals from the middle of the tail.[7]

Postcranial skeleton edit

 
 
 
 
 
Photo and interpretative drawing of the front part of the specimen from 1911 (above), photo of uncertain bone fragments that may belong to either the skull or tail (bottom left), drawing of the tail and uncertain bone fragments (lower middle), and cross-section of a vertebra (lower right)

The vertebrae were very light and hollow, and some were slightly concave at each end. The cervical vertebrae were relatively large in length and diameter compared to the dorsals, and had styliform (resembling a pen or bristle in shape) cervical ribs which were long, straight, and narrow, as in Anchisaurus. The front dorsals were much shorter than the cervicals, then again increased in size towards the pelvis. They measured 12–13 mm (0.47–0.51 in) in length. The neural spines of the dorsals were narrow, high, and curved backwards, but not as expanded from front to back as in Compsognathus. The dorsal ribs were strongly curved and very slender and hollow, reminiscent of those in Saltopus and Hallopus, the largest being 52 mm (2.0 in) long and 2 mm (0.1 in) wide. The transverse processes (that connected with the ribs on each side of a vertebra) formed a circular arc downward from each side of a dorsal, extending about as far from the centrum (the "body" of a vertebra) as the spinous process was high. The zygapophyses (processes that connected adjacent vertebrae) were well-developed. The centra were relatively longer than those of Ornithomimus, while those of Compsognathus resembled those of Podokesaurus more, but were shorter.[8][6][7]

While the hind part of the tail was located some distance away from the rest of the skeleton, Lull believed it was in its natural position and that it would have been very long, the intermediate vertebrae having been swept away. The caudal vertebrae were very long and slender, and along with their chevrons (bones on the undersides of the caudals), resembled those of Ornitholestes. A typical caudal was 17 mm (0.67 in) long and 4 mm (0.16 in) in diameter. The caudals were very similar in length and did not decrease in length until the last few in the succession. Just in front of the pubis there was a cluster of slender gastralia (abdominal ribs), the longest of which was 18 mm (0.71 in) long. The frontmost gastralia had broadened ends, which is often the condition in sternal ribs.[8][6][7]

The humerus was small and very delicate, 42 mm (1.7 in) long, less than half the length of the femur. It had a strong processus lateralis (a process directed to the side) 30 mm (1.2 in) above its lower end. Lull found it similar to that of Ornitholestes, apart from the radial crest (that connected with the radius bone of the lower arm) not being as high, showing little muscular power. Von Huene estimated the radius to have been 30 mm (1.2 in) long. Lull found the hand more similar to that of Compsognathus than of Ornitholestes.[8][6][7] Only slender phalanx bones of the three fingers were preserved, including sharp, curved claws.[7]

 
Hypothetical life restoration

The pubis was very long, expanding both at the front and hind ends. It was 6 mm (0.24 in) wide and 95 mm (3.7 in) long, and its lower expansion was 10 mm (0.39 in) in diameter. Talbot found the pubis similar to that of the then undescribed Procompsognathus. Lull argued that the pubis lay approximately in position in the fossil, pointing forwards.[8][6] Heilmann instead believed the bone had been moved out of position before burial, and would have been directed backwards.[12] Colbert and Baird suggested the pubis was directed forwards, but that it curved slightly upwards instead of downwards due to natural warping and cracking of the bone. The ischium was 55 mm (2.2 in) long, 15.5 mm (0.61 in) wide at the end closest to the body, and its slender shaft was 4 mm (0.16 in) in diameter, and somewhat thickened at its lower end. Lull found it similar to those of Compsognathus and Ornitholestes. Below the acetabulum (where the femur connects with the pelvis) there was a broad lamella running towards the pubis.[6][7]

The femur was slender, nearly straight, had thin walls, and was expanded at the back side of its lower end. It was 86 mm (3.4 in) long and 6.5 mm (0.26 in) in diameter just below the fourth trochanter (a flange placed mid-length at the back of the femur). The fourth trochanter was strong, 18 mm (0.71 in) long and about 2 mm (0.079 in) high, and was situated past the middle of the shaft, towards the lower end. The condyles (round prominences) of the femur's lower end protruded strongly hindwards. The tibia was a thin, narrow shaft, 104 mm (4.1 in) in length, and about 7 mm (0.28 in) in diameter. Talbot stated the very thin fibula lay close to the tibia and was of almost equal length, while von Huene thought this was instead part of the crushed tibia. The three metatarsals of the lower leg were closely appressed together forming a compact structure, similar to what was seen in Ornithomimus, but not fused into a tarsometatarsus, as seen in birds. The length of the metatarsals was 75 mm (3.0 in), while their width was 9 mm (0.35 in). The most complete pedal phalanx was very slender and 12 mm (0.47 in) long.[6][8][7]

Classification edit

Early interpretations edit

 
Lull's 1915 illustration of the pelvic region, showing the forwards directed pubis (Pu) as preserved

When reading her preliminary description in 1910, Talbot suggested Podokesaurus to have been an "herbivorous dinosaur", but further work at Yale University showed that some bones had been incorrectly identified, and the ischium of the pelvis with a well-developed ridge was found to resemble that of Compsognathus. She refrained from making a definite classification of the specimen in her 1911 description due to the lack of jaw and foot-bones which could have aided in this, but concluded it would have belonged to a "carnivorous dinosaur" based on the shape and position of the pubis, as well as the absence of a postpubis. She considered the fossil to be Triassic in age (the first of the three Mesozoic periods).[8] In 1914, von Huene named the new family Podokesauridae, wherein he, in addition to Podokesaurus, included Saltopus, Procompsognathus, Coelophysis, and Tanystropheus. He placed this group under Coelurosauria, which at the time was used to include small theropods in general.[25][7][26]

Heilmann considered Podokesaurus very similar to the early bird Archaeopteryx in 1913, and wondered why Talbot had not made any comparisons to it. He particularly found the legs and the pelvis, when the pubis was interpreted as pointing backwards (as in birds), similar to what it might look like in a bird ancestor, while considering Lull's reconstruction of a forward-directed pubis unlikely. He also found parts of the shoulder blade, forelimbs, and even tail bones similar to those of birds. He furthermore pointed to the presence of abdominal ribs and that the bones were hollow, and concluded that nothing precluded Podokesaurus from being a very primitive proto-bird, with not yet fused middle-foot bones. The only feature he found inconsistent with this interpretation was the short finger with a claw, if it was not instead part of a toe. He suggested that the issue could be determined if the skull, sternum, and clavicle were found in the rock, bones that would be important clues for classification.[12]

 
 
Gerhard Heilmann's 1913 comparison between the legs and pelvis of Podokesaurus (left: 1, with backwards directed pubis, 2, with forwards directed pubis) and Archaeopteryx (3), and his redrawing of Lull's skeletal reconstruction (right) compared with other dinosaurs

Heilmann wished for a clearer explanation of the placement of the middle-foot bones in relation to each other, and found it surprising that Lull's reconstruction of Podokesaurus showed an even more appressed middle-foot than was present in the later supposed descendant Ornithomimus, which he thought would have developed a completely bird-like middle-foot by that time. Heilmann found Podokesaurus very unusual for a dinosaur from the Triassic, and thought it was one of the earliest bipedal vertebrates. He suggested that since it was so different from Thecodontosaurus and Plateosaurus, those may not have been dinosaurs, or Podokesaurus could instead have been related to Saltopus or parasuchians, but found its fossils too insufficient to say anything definite about the issue.[12]

Shufeldt elaborated on his and Heilmann's interpretation of the pubis in 1915, and stated the bone had probably been displaced during fossilization. He pointed out that if it had faced forward, it would have been in forcible contact with the abdominal ribs that would have been dangerous for internal organs during movement.[11] Lull found Heilmann and Shufeldt's criticisms of his pelvis reconstruction probable in 1915. He listed Podokesauridae under the superfamily Compsognatha, and suggested Podokesaurus was perhaps ancestral to the later North American genera Ornitholestes and Ornithimimus.[6] In 1916, Heilmann pointed out that early dinosaurs, parasuchians, and pterosaurs all had similarities to birds, as well as to each other, and that Triassic reptiles like Scleromochlus, Saltopus, and Podokesaurus, were difficult to separate. He proposed that Podokesaurus and other bipedal reptiles from the Triassic were descended from pseudosuchians (which many types of archosaurs were classified as at the time) that may have evolved bipedality by the Permian. He concluded that birds were descended from ornithosuchian pseudosuchians rather than from dinosaurs, due to their bipedality and bird-like legs.[27]

The paleontologist Henry Fairfield Osborn used Podokesaurus as an example of a "carnivorous dinosaur of the bird-like type" in 1917, while stating that similarities between birds and dinosaurs were due to parallel evolution.[28] The paleontologist Franz Nopcsa von Felső-Szilvás created the subfamily Podokesaurinae in 1928, within which he included Podokesaurus, Procerosaurus, Saltopus, and Tanystropheus.[29] Von Huene grouped Podokesaurus, Coelophysis, Spinosuchus, Halticosaurus, Saltopus, Avipes, and Velocipes in Podokesauridae in 1932.[30]

Relation to Coelophysis edit

 
Replica of a natural cast of bones assigned to C. holyokensis in 1964 (when Podokesaurus was suggested to be a synonym of Coelophysis)

In 1958, Colbert and Baird described a theropod specimen consisting of natural casts of bones in sandstone (probably formed when the bones were dissolved by acidic water, leaving molds of the bones), including a pubis, tibia, and some ribs. They found the specimen similar to Coelophysis and Podokesaurus, referring to it as C. sp. (of unknown species). They considered the natural cast and Podokesaurus to be from the Portland Arkose of the Newark Group in the Connecticut valley. Though Podokesaurus was smaller than the others (being comparable in size to the smallest-known Coelophysis specimens), these researchers suggested that because it was so similar to them, this raised questions as to its validity.[31][32] In 1964, Colbert synomymized Podokesaurus with Coelophysis, (since the latter name was older), coining the new combination C. holyokensis. He also suggested that the natural cast belonged to C. holyokensis. Colbert stated that Podokesaurus could only be distinguished from Coelophysis by the neural spines of its vertebrae not being as long from front to back, and because the ischium differed in shape. He found these differences to be similar to those seen between modern reptile species within the same genus, and that they represented eastern (C. holyokensis) and western (C. bauri) species of the same genus. While he admitted that these conclusions were not ironclad, and that Podokesaurus may indeed have been distinct, he said the burden of proof should be on the proponents of such a view.[17]

In 1977, the paleontologists Paul E. Olsen and Peter Galton redated the Newark Supergroup (which the Portland Formation belongs to) to the Early Jurassic instead of the preceding Triassic as was previously thought. This was part of a study in which Olsen compared the fauna of various formations and concluded there had not been a sudden, widespread extinction event at the Triassic-Jurassic border, but that it had instead been gradual.[33] Olsen stated in 1980 that while the exact provenance and systematic position of Podokesaurus will probably remain uncertain, the Portland Formation it was thought to be from was probably Early Jurassic in age, and therefore 15 million years younger than Coelophysis from the Triassic. Since features shared between Podokesaurus and Coelophysis are also known in other small theropods, such as Syntarsus, Olsen suggested that Podokesaurus should be retained as a separate genus of indeterminate theropods, to avoid overextending the temporal range of Coelophysis. He also applied this argument to the natural cast, regarding it as incertae sedis (with uncertain relationships) among theropods rather than as Podokesaurus or Coelophysis.[34]

The paleontologist Samuel P. Welles stated in 1984 that the family Podokesauridae had become a "catch-all" for most Triassic theropods. While he found Coelophysis the most similar to Podokesaurus among theropods, he thought the two differed greatly in that the fourth trochanter of the latter was below midheight on the femur (unlike the higher position in most other theropods), and its metatarsals were of equal length.[14] The paleontologist Kevin Padian stated in 1986 that while Colbert's suggestion of synonymy was possible, the discernible similarities between Podokesaurus and Coelophysis were primitive theropod features, and the two were not as close in time as once thought.[35] Paul said in 1988 that while the family Podokesauridae was still used for Coelophysis and kin, Podokesaurus was not based on good remains to begin with, and with only bad cast replicas remaining, he thought there would always be disagreement about the taxon. He found this to be too much ambiguity to put up with, and proposed the name Coelophysidae should be used instead (Halticosauridae, another contender, was also based on too fragmentary remains).[36] In 1989, Colbert also doubted the synonymy of Podokesaurus with Coelophysis, and that the natural casts belonged to the latter, due to their revised Early Jurassic ages, and he made no attempt to resolve the status of Podokesaurus due to the only specimen being lost. He retained the name Podokesauridae for the family.[37]

 
Mounted skeleton of Coelophysis, which is thought to have been similar to Podokesaurus

In 1990, the paleontologists Timothy Rowe and Jacques Gauthier considered Podokesauridae a taxonomic waste-basket, wherein taxa had been grouped based on phenetic resemblance and stratigraphic division, and therefore under continuous revision and instability. They considered it possible that Podokesaurus and the natural cast specimen were Coelophysis, but found that their similarities were not shared exclusively by them, but were ancestral features among theropods. They therefore agreed that the name Podokesaurus should be restricted to the holotype, and that it and the natural cast should be considered Theropoda incertae sedis.[38] In the same volume, the paleontologist David B. Norman agreed with this assessment, and stated the features used to unite Podokesaurus with Coelophysis merely confirm that they were dinosaurs rather than establish a specific relation between them.[5] The paleontologist Thomas R. Holtz agreed in 1994 that the family name Podokesauridae should be replaced by Coelophysidae. By this time, the idea that small theropods should be grouped in Coelurosauria and large theropods in Carnosauria was falling out of favor, and Coelophysoidea was considered a separate group of gracile, early theropods.[39] The paleontologists David B. Weishampel and Luther Young suggested ceratosaurian affinities for Podokesaurus in 1996.[40]

The paleontologist Ronald S. Tykoski and Rowe noted in 2004 that while Podokesaurus had coelophysoid features (such as a small, knob-like expansion on the lower part of the pubis), it did not have any derived traits that would unite it with Coelophysis. They agreed with earlier researchers that the name Podokesaurus should be restricted to the holotype, and concluded that the natural cast may be a coelophysoid, but could not be identified beyond being a theropod.[41] In 2004, the paleontologists Matthew T. Carrano and Scott D. Sampson stated that Podokesaurus was almost certainly a coelophysoid similar to Coelophysis. It had coelophysoid features such as a long, downward curved pubis, that was longer than the ischium, and an additional foramen (opening) on the pubis, below the oburator foramen, but little more could be said about its affinities.[42] Carrano and colleagues stated in 2004 that Segisaurus and Podokesaurus were among the latest-surviving coelophysoids, and that the evolutionary radiation of this group may have ended by the latest part of the Early Jurassic.[43] Also in 2004, the paleontologists Anthea Bristowe and Michael A. Raath listed Podokesaurus as a synonym of Coelophysis without elaboration.[44] Tykoski rejected synonymy between the two in his 2005 dissertation, but left Podokesaurus out of his analysis.[45] Paul suggested in 2016 that Podokesaurus may have formed the family Coelophysidae with Coelophysis, Panguraptor, and Procompsognathus.[24]

Paleobiology edit

 
Heilmann's outdated 1913 restoration of Podokesaurus running near a lake and other dinosaurs

Talbot suggested that the short, slender humerus, long, straight hindlimb bones, and the well-developed fourth trochanter of the femur indicated that Podokesaurus was bipedal. She found the fact that the tibia was much longer than the femur, that the metatarsals were very long, over half the length of the tibia, and the skeleton's light construction, were indicative of rapid locomotion. Talbot stated that Lull thought this was an adaptation to climatic conditions, as the animal must have been able to travel fast and far for water in its semi-arid region. Talbot also reported a small piece of smooth, polished quartz among the ribs, and suggested it could have been a gastrolith (stomach stone), and so the first time these were found in association with a carnivorous dinosaur.[8] Von Huene agreed the stone was a gastrolith, distinct from the surrounding sandstone, and added it was 11 mm (0.43 in) long.[7]

Lull found the animal to have been essentially a slender, cursorial (adapted for running) animal, with carnivorous habits, but that the slenderness that made it swift also confined it to small prey.[6] In 1932, von Huene proposed that small coelurosaurs had a jumping gait, due to their lower legs being longer than their upper legs, contrasting with the alternating steps of carnosaurs. With its large fourth trocanther, he thought Podokesaurus had probably abandoned this jumping gait, instead moving with rapid, alternating steps similar to ratite birds.[30]

 
Grallator cursorius footprint, which Lull correlated with Podokesaurus

In 1982, the paleontologist Richard A. Thulborn estimated the speed of various dinosaurs, based on the relationships between speed, gait, and body size of modern animals (mainly mammals). By extrapolating the stride length and cadence of Podokesaurus, he estimated it could have run at about 15–20 km/h (9–12 mph). He concluded that if a dinosaur could match a mammal in speed, it must have had similar levels of efficiency in locomotor ability and physiology. He cautioned that comparison was difficult because dinosaur anatomy differed significantly from that of mammals and birds. Differences included the massive tails of dinosaurs, and hindlimb retractor muscles that originated behind the femur, while these muscles originate more forward in mammals and extant birds.[46] Weishampel stated in 2006 that as a coelophysoid, Podokesaurus would have been a fleet-footed predator, with powerful forelimbs and grasping hands.[16]

Lull found that fossil footprints named Grallator cursorius agreed with the foot and stride of Podokesaurus. These were abundant at a quarry in South Hadley (where they were found alongside large Otozoum moodii tracks), which he thought supported this identity.[6] In 1926, Heilmann suggested that the foot of Procompsognathus was a better match for the G. cursorius tracks, due to the proportions of its toe bones.[47] The paleontologist Wilhelm Bock stated in 1952 that while very similar Grallator tracks had been attributed to various small dinosaurs (such as Podokesaurus), he considered such correlations too specific, and that the best that could be said was such tracks represented small coelurosaurians.[48] The writer Donald F. Glut suggested in 1997 that a slab with tracks from the Brunswick Formation of New York previously attributed to Coelophysis may instead have been produced by Podokesaurus, based on its Jurassic age.[49] This formation is now known as the Passaic Formation, and instead thought to be Late Triassic in age.[50]

Paleoenvironment edit

 
1917 restorations of animals from the Connecticut Valley then thought to have lived during the Triassic. The Portland Formation, which Podokesaurus is from, was redated to the Early Jurassic in 1977

The only known specimen of Podokesaurus is thought to have been collected from the Portland Formation (earlier known as the Portland Arkose) in the Hartford Basin of Massachusetts. The age of this formation has long been unclear (it was thought to be Triassic until 1977), but it is currently thought to date to the HettangianSinemurian stages of the Early Jurassic, between 201 and 190 million years ago (earlier thought to be the PliensbachianToarcian stages).[51][16][34] In 2016, the paleontologist Robert E. Weems and colleagues suggested the Portland Formation should be elevated to a geological group within the Newark Supergroup (as the Portland Group), and thereby replacing the former name "Agawam Group". They also reinstated the Longmeadow Sandstone, where Podokesaurus was found, as a formation (within the uppermost Portland Group); it had earlier been considered identical to the Portland Formation.[51][6]

The Portland Group represents the uppermost part of the Newark Supergroup, and was deposited after the Central Atlantic magmatic province was formed during the end of the Triassic and the beginning of the Jurassic. The Longmeadow Sandstone consists of fluvial (deposited by rivers and streams) red mudstones, sandstones, conglomerates, minor red eolian (deposited by wind) sandstones and siltstones.[51] Other animals known from the formation include the sauropodomorph dinosaur Anchisaurus, the crocodylomorph Stegomosuchus, and fish such as Acentrophorus and Semionotus.[34] Dinosaur tracks include the ichnogenera Anchisauripus, Anomoepus, Eubrontes, and Grallator.[52]

See also edit

References edit

  1. ^ a b c d e f Warner, F. L. (1937). "XII. Lost dinosaur". On a New England Campus. Cambridge: Houghton Mifflin Company. p. 279. ASIN B00085TO0O.
  2. ^ a b c d Benfey, C. (2002). "Foreword: "A route of evanescence"". Changing Prospects: The View from Mount Holyoke. Ithaca: Cornell University Press. p. 9. ISBN 978-0801441196.
  3. ^ "Daring to Dig: Mignon Talbot (1869–1950)". museumoftheearth.org. from the original on February 11, 2021. Retrieved August 14, 2020.
  4. ^ Rossiter, M. W. (1981). "Geology in nineteenth-century women's education in the United States". Journal of Geological Education. 29 (5): 228–232. Bibcode:1981JGeoE..29..228R. doi:10.5408/0022-1368-29.5.228.
  5. ^ a b Norman, D. B. (1990). "Problematic Theropoda". In Weishampel, D. B.; Osmolska, H.; Dodson, P. (eds.). The Dinosauria (1 ed.). Berkeley: University of California Press. p. 298. ISBN 978-0-520-06727-1.
  6. ^ a b c d e f g h i j k l m n Lull, R. S. (1915). "Triassic life of the Connecticut valley". State Geological and Natural History Survey of Connecticut. 24: 155–169. doi:10.5962/bhl.title.70405. ISBN 978-1167291937. from the original on October 6, 2020. Retrieved August 21, 2020.
  7. ^ a b c d e f g h i j k l m von Huene, F. (1914). "Beiträge zur Geschichte der Archosaurier". Geologische und Paläontologische Abhandlungen (in German). 13: 1–53. from the original on October 9, 2020. Retrieved October 7, 2020.
  8. ^ a b c d e f g h i j k Talbot, M. (1911). "Podokesaurus holyokensis, a new dinosaur from the Triassic of the Connecticut Valley". American Journal of Science. s4-31 (186): 469–479. Bibcode:1911AmJS...31..469T. doi:10.2475/ajs.s4-31.186.469. from the original on August 18, 2020. Retrieved August 16, 2020.
  9. ^ Turner, S.; Burek, C. V.; Moody, R. T. J. (2010). "Forgotten women in an extinct saurian (man's) world". Geological Society, London, Special Publications. 343 (1): 111–153. Bibcode:2010GSLSP.343..111T. doi:10.1144/SP343.7. S2CID 130338204.
  10. ^ Bakker, R. T. (2014). "A Tale of Two Compys: What Jurassic Park got right — and wrong — about dino anatomy". The Houston Museum of Natural Science. from the original on September 21, 2020. Retrieved August 18, 2020.
  11. ^ a b Moodie, R. L. (1913). "Some recent advances in vertebrate paleontology. II". The American Naturalist. 47 (556): 248–256. doi:10.1086/279347. ISSN 0003-0147. JSTOR 2455799.
  12. ^ a b c d Heilmann, G. (1913–1914). "Vor nuværende viden om fuglenes afstamning. Andet afsnit: Fugleligheder blandt fortidsøgler". Dansk Ornithologisk Forenings Tidsskrift (in Danish). 8: 56–65.
  13. ^ Wegemann, C. H.; Lyon, M. W. (1916). "Proceedings of the Academy and Affiliated Societies". Journal of the Washington Academy of Sciences. 6 (9): 251–259. ISSN 0043-0439. JSTOR 24521263.
  14. ^ a b Welles, S. P. (1984). "Dilophosaurus wetherilli (Dinosauria, Theropoda), osteology and comparisons". Palaeontographica Abteilung A. 185: 172.
  15. ^ Elder, E. S. (1982). "Women in early geology". Journal of Geological Education. 30 (5): 287–293. Bibcode:1982JGeoE..30..287E. doi:10.5408/0022-1368-30.5.287.
  16. ^ a b c d Weishampel, D. B. (2006). Another look at the dinosaurs of the East Coast of North America. III Jornadas Internacionales sobre Paleontología de Dinosaurios y su Entorno, Salas de los Infantes, Burgos, Spain. Colectivo Arqueológico-Paleontológico Salense Actas. pp. 129–168.
  17. ^ a b c d Colbert, E. H. (1964). "The Triassic dinosaur genera Podokesaurus and Coelophysis". American Museum Novitates (2168): 1–12. hdl:2246/3350.
  18. ^ Galton, P. M. (1976). "Prosauropod dinosaurs (Reptilia, Saurischia) of North America". Postilla, Peabody Museum Yale University (169): 6.
  19. ^ Morrison, H. (February 4, 2021). "Massachusetts State Dinosaur: Podokesaurus holyokensis wins fan vote, lawmaker files legislation to officially declare state dinosaur". Masslive. from the original on March 21, 2021.
  20. ^ Kent, L. (2021). "Massachusetts will soon propose an official state dinosaur". CNN. from the original on January 18, 2021. Retrieved January 18, 2021.
  21. ^ Chianca, P. (2021). "Boston.com readers want this as official Mass. dinosaur". www.boston.com. from the original on January 17, 2021. Retrieved January 18, 2021.
  22. ^ Morrisson, H. (May 3, 2022). "Massachusetts officially has a state dinosaur". MassLive. Retrieved May 4, 2022.
  23. ^ Peczkis, J. (1995). "Implications of body-mass estimates for dinosaurs". Journal of Vertebrate Paleontology. 14 (4): 530–531. doi:10.1080/02724634.1995.10011575. ISSN 0272-4634.
  24. ^ a b c Paul, G. S. (2016). "Theropods". The Princeton Field Guide to Dinosaurs (2 ed.). Princeton: Princeton University Press. pp. 76, 78. ISBN 978-0691167664.
  25. ^ von Huene, F. (1914). "Das natürliche System der Saurischia". Centralblatt für Mineralogie, Geologie und Paläontologie (in German). 5: 154–158. from the original on October 27, 2020. Retrieved October 24, 2020.
  26. ^ Padian, K. (2012). "The problem of dinosaur origins: integrating three approaches to the rise of Dinosauria". Earth and Environmental Science Transactions of the Royal Society of Edinburgh. 103 (3–4): 423–442. doi:10.1017/S1755691013000431. S2CID 128420276.
  27. ^ Heilmann, G. (1916). "Vor nuværende viden om fuglenes afstamning. Femte afsnit: Førfuglen Proavis". Dansk Ornithologisk Forenings Tidsskrift (in Danish). 11: 90, 113, 137.
  28. ^ Osborn, H. F. (1917). The Origin and Evolution of Life, on the Theory of Action, Reaction and Interaction of Energy. New York: C. Scribner's Sons. pp. 210–215. doi:10.5962/bhl.title.7397. from the original on June 16, 2021. Retrieved September 21, 2020.
  29. ^ Nopcsa, F. (1928). "The genera of reptiles". Palaeobiologica (1): 163–188.
  30. ^ a b von Huene, F. (1932). "Die fossile Reptil-Ordnung Saurischia, ihre Entwicklung und Geschichte" (PDF). Monographien zur Geologie und Paläontologie (in German). 4 (1): 24, 35, 332. (PDF) from the original on February 25, 2021. Retrieved December 20, 2020.
  31. ^ Colbert, E. H.; Baird, D. (1958). "Coelurosaur bone casts from the Connecticut Valley Triassic". American Museum Novitates (1901): 1–11. hdl:2246/2486. from the original on November 14, 2020. Retrieved November 14, 2020.
  32. ^ Getty, P. R.; Bush, A. M. (2011). "Sand pseudomorphs of dinosaur bones: Implications for (non-) preservation of tetrapod skeletal material in the Hartford Basin, USA". Palaeogeography, Palaeoclimatology, Palaeoecology. 302 (3–4): 407. Bibcode:2011PPP...302..407G. doi:10.1016/j.palaeo.2011.01.029.
  33. ^ Olsen, P. E.; Galton, P. M. (1977). "Triassic-Jurassic tetrapod extinctions: Are they real?". Science. 197 (4307): 983–986. Bibcode:1977Sci...197..983O. doi:10.1126/science.197.4307.983. PMID 17784133. S2CID 44654197.
  34. ^ a b c Olsen, P. E. (1980). "A comparison of the vertebrate assemblages from the Newark and Hartford basins (Early Mesozoic, Newark Supergroup) of Eastern North America" (PDF). In Jacobs, L. L. (ed.). Aspects of Vertebrate History: Essays in Honor of Edwin Harris Colbert. Flagstaff: Museum of Northern Arizona Press. pp. 35–53. ISBN 978-0897340526. (PDF) from the original on June 16, 2021. Retrieved November 16, 2020.
  35. ^ Padian, K. (1986). "On the type material of Coelophysis Cope (Saurischia: Theropoda) and a new specimen from the Petrified Forest of Arizona (Late Triassic: Chinle Formation)". In Padian, K. (ed.). The beginning of the age of dinosaurs: Faunal change across the Triassic-Jurassic boundary. Cambridge: Cambridge University Press. pp. 57–60. ISBN 978-0521367790.
  36. ^ Paul, G. S. (1988). Predatory Dinosaurs of the World. New York: Simon & Schuster. pp. 258–259. ISBN 978-0-671-61946-6.
  37. ^ Colbert, E. H. (1989). "The Triassic dinosaur Coelophysis". Museum of Northern Arizona Bulletin. 57: 24, 28–29. ISBN 978-0897340977.
  38. ^ Rowe, T.; Gauthier, J. (1990). "Ceratosauria". In Weishampel, D. B.; Osmolska, H.; Dodson, P. (eds.). The Dinosauria (1 ed.). Berkeley: University of California Press. pp. 153, 166. ISBN 978-0-520-06727-1.
  39. ^ Holtz, T. R. (1994). "The phylogenetic position of the Tyrannosauridae: Implications for theropod systematics". Journal of Paleontology. 68 (5): 1100–1117. doi:10.1017/S0022336000026706. ISSN 0022-3360. JSTOR 1306180. from the original on October 3, 2020. Retrieved October 3, 2020.
  40. ^ Weishampel, D. B.; Young, L. (1996). Dinosaurs of the East Coast. Baltimore: Johns Hopkins University Press. p. 275. ISBN 978-0801852176.
  41. ^ Tykoski, R. S.; Rowe, T. (2004). "Ceratosauria". In Weishampel, D. B.; Dodson, P.; Osmolska, H. (eds.). The Dinosauria (2 ed.). Berkeley: University of California Press. p. 68. ISBN 978-0-520-24209-8.
  42. ^ Carrano, M. T.; Sampson, Scott D. (2004). "A review of coelophysoids (Dinosauria: Theropoda) from the Early Jurassic of Europe, with comments on the late history of the Coelophysoidea". Neues Jahrbuch für Geologie und Paläontologie - Monatshefte. 2004 (9): 537–558. doi:10.1127/njgpm/2004/2004/537.
  43. ^ Carrano, M. T.; Hutchinson, J. R.; Sampson, S. D. (2005). "New information on Segisaurus halli, a small theropod dinosaur from the Early Jurassic of Arizona". Journal of Vertebrate Paleontology. 25 (4): 835–849. doi:10.1671/0272-4634(2005)025[0835:NIOSHA]2.0.CO;2.
  44. ^ Bristowe, A.; Raath, M. A. (2004). "A juvenile coelophysoid skull from the Early Jurassic of Zimbabwe, and the synonymy of Coelophysis and Syntarsus". Palaeontologia Africana. ISSN 0078-8554. from the original on August 9, 2020. Retrieved October 20, 2020.
  45. ^ Tykoski, R. S. (2005). Anatomy, ontogeny, and phylogeny of coelophysoid theropods. The University of Texas at Austin (Thesis). p. 69. from the original on July 29, 2020. Retrieved October 20, 2020.
  46. ^ Thulborn, R. A. (1982). "Speeds and gaits of dinosaurs". Palaeogeography, Palaeoclimatology, Palaeoecology. 38 (3–4): 227–256. Bibcode:1982PPP....38..227T. doi:10.1016/0031-0182(82)90005-0.
  47. ^ Heilmann, G. (1926). The Origin of Birds. New York: Dover Publications. p. 181. ISBN 0-486-22784-7.
  48. ^ Bock, W. (1952). "Triassic reptilian tracks and trends of locomotive evolution: With remarks on correlation". Journal of Paleontology. 26 (3): 395–433. ISSN 0022-3360. JSTOR 1299951. from the original on June 16, 2021. Retrieved September 30, 2020.
  49. ^ Glut, D. F. (1997). Dinosaurs: The Encyclopedia. Jefferson: McFarland & Company, Inc. pp. 718–719. ISBN 978-0786472222.
  50. ^ Metz, R. (2000). "Triassic trace fossils from lacustrine shoreline deposits of the Passaic formation, douglassville, pennsylvania". Ichnos. 7 (4): 253–266. doi:10.1080/10420940009380165. S2CID 128688223.
  51. ^ a b c Weems, R. E.; Tanner, L. H.; Lucas, S. G. (2016). "Synthesis and revision of the lithostratigraphic groups and formations in the Upper Permian?–Lower Jurassic Newark Supergroup of eastern North America". Stratigraphy. 13 (2): 111–153. from the original on August 5, 2020. Retrieved October 20, 2020.
  52. ^ Collette, J. H.; Getty, P. R.; Hagadorn, J. W. (2011). "Insights into an Early Jurassic dinosaur habitat: ichnofacies and enigmatic structures from the Portland Formation, Hoover Quarry, Massachusetts, U.S.A." Atlantic Geology. 47: 81–98. doi:10.4138/atlgeol.2011.003.

External links edit

 
Wikimedia Commons has media related to Podokesaurus.
 
Wikispecies has information related to Podokesaurus.
  • Museum of Science, Boston – "Celebrate Podokesaurus holyokensis as the Massachusetts State Dinosaur" 24 minute video
  • Museum of Science, Boston – "Choosing the Massachusetts State Dinosaur" 49 minute video

January 01, 1970
podokesaurus, genus, coelophysoid, dinosaur, that, lived, what, eastern, united, states, during, early, jurassic, period, first, fossil, discovered, geologist, mignon, talbot, near, mount, holyoke, massachusetts, 1910, specimen, fragmentary, preserving, much, . Podokesaurus is a genus of coelophysoid dinosaur that lived in what is now the eastern United States during the Early Jurassic Period The first fossil was discovered by the geologist Mignon Talbot near Mount Holyoke Massachusetts in 1910 The specimen was fragmentary preserving much of the body limbs and tail In 1911 Talbot described and named the new genus and species Podokesaurus holyokensis based on it The full name can be translated as swift footed lizard of Holyoke This discovery made Talbot the first woman to find and describe a non bird dinosaur The holotype fossil was recognized as significant and was studied by other researchers but was lost when the building it was kept in burned down in 1917 no unequivocal Podokesaurus specimens have since been discovered It was made state dinosaur of Massachusetts in 2022 PodokesaurusTemporal range Early Jurassic 190 Ma PreꞒ Ꞓ O S D C P T J K Pg N Holotype specimen with tail and uncertain bones at left and body at right Scientific classification Domain Eukaryota Kingdom Animalia Phylum Chordata Clade Dinosauria Clade Saurischia Clade Theropoda Superfamily Coelophysoidea Genus PodokesaurusTalbot 1911 Species P holyokensis Binomial name Podokesaurus holyokensisTalbot 1911 Synonyms Coelophysis holyokensis Talbot 1911 Colbert 1964 Estimated to have been about 1 m 3 ft in length and 1 40 kg 2 90 lb in weight Podokesaurus was lightly constructed with hollow bones and would have been similar to Coelophysis being slender long necked and with sharp recurved teeth The vertebrae were very light and hollow and some were slightly concave at each end The cervical neck vertebrae were relatively large in length and diameter compared to the dorsal back vertebrae and the caudal tail vertebrae were long and slender The humerus upper arm bone was small and delicate less than half the length of the femur thigh bone The pubis pubic bone was very long expanding both at the front and hind ends The femur was slender nearly straight had thin walls and was expanded at the back side of its lower end The three metatarsals of the lower leg were closely appressed together forming a compact structure Since it was one of the few small theropods known at the time it was described the affinities of Podokesaurus were long unclear It was placed in the family Podokesauridae along with other small theropods and was speculated to have been similar to a proto bird It was suggested it was a synonym of Coelophysis and a natural cast specimen was assigned to it but these ideas are not currently accepted The family Podokesauridae is not in use anymore having been replaced by Coelophysidae and Podokesaurus is thought to have been a coelophysoid As such Podokesaurus would have been a fleet footed predator with powerful forelimbs and grasping hands It is estimated it could have run at 15 20 km h 9 12 mph Podokesaurus is thought to have been collected from the Portland Formation the age of which has long been unclear but is currently believed to date to the Hettangian Sinemurian stages of the Early Jurassic between 201 and 190 million years ago Contents 1 Discovery and history 2 Description 2 1 Postcranial skeleton 3 Classification 3 1 Early interpretations 3 2 Relation to Coelophysis 4 Paleobiology 5 Paleoenvironment 6 See also 7 References 8 External linksDiscovery and history edit nbsp nbsp Geological maps of the Connecticut Valley from 1915 22 is where Podokesaurus was found 12 is Mount Holyoke some areas marked as Triassic are now thought to be Early Jurassic in age In 1910 the American geologist Mignon Talbot was walking with her sister Ellen to Holyoke Massachusetts in the eastern US when they passed a farm and noticed a small hill nearby It had a gravel pit at one side and was formed by an accumulation of sand gravel and boulders left by a receding glacier Talbot noticed a white streak on a sandstone boulder at the bottom of the gravel pit and upon discovering these were bones she told her sister she had found a real live fossil This was because many fossil tracks had previously been discovered in the Connecticut Valley that she had often taken her students to see but few actual dinosaur skeletons and none at Mount Holyoke She was granted permission by the land owner to collect the specimen for Mount Holyoke College an all women s college a few miles from there where she was head of the geology department 1 2 3 4 The next day she brought a group of workmen to collect the specimen and found another piece of sandstone that contained the rest of the fossil as well as impressions of those in the first slab The specimen appeared to have been exposed for years with no one noticing it the boulder having been broken open by people or frost The fossil was brought to the laboratory where it was prepared and photographed 1 The incomplete specimen preserved 5 cervical neck 11 dorsal back and 24 caudal tail vertebrae a fragment of the left scapula shoulder blade and right coracoid part of the pectoral girdle a partial left humerus upper arm bone phalanx bones of 3 fingers including 2 unguals claw bones ribs the pubis and ischium bones forming the lower front and lower back of the pelvis respectively the femora thigh bones the left tibia lower leg bone a fragment of the right astragalus a bone in the ankle articulated metatarsals foot bones of the left foot followed by 3 pedal phalanges toe bones partial metatarsals and possible phalanges of the right foot and fragments of uncertain identity 5 6 The light and delicate bones were in their natural position or nearly so within the rock except for the tail and uncertain fragments which were a few centimeters away from the skeleton following a long gap in the skeleton behind the pelvis The front half of the neck was missing 1 7 nbsp 1915 skeletal reconstruction by Richard Swann Lull shaded areas were known from the fossil missing parts were reconstructed after Compsognathus nbsp Model by Lull at Peabody Museum of Natural History The significance of the fossil was confirmed at an intercollegiate meeting of geology departments and when the American paleontologist Richard Swann Lull subsequently encouraged Talbot to describe the specimen she replied she did not know anything about dinosaurs but Lull suggested she should study them and then describe it In December 1910 Talbot read a preliminary description of the fossil at the Paleontological Society meeting at Pittsburgh and in June 1911 she published a short scientific description in which she made the specimen the holotype of the new genus and species Podokesaurus holyokensis 1 8 The generic name is derived from the Ancient Greek words podōkes podwkhs which means swift or fleet footed an epithet commonly used in reference to the Greek hero Achilles and saura sayra meaning lizard while the specific name refers to Holyoke In full the name can be translated as swift footed lizard of Holyoke 8 2 The discovery and naming of Podokesaurus made Talbot the first woman to find and describe a non bird dinosaur 9 The American paleontologist Robert T Bakker stated in 2014 that while old professors grumbled that women were unfit for working with fossils during his time at university Talbot s discovery of Podokesaurus was a counterargument to that 10 By the time the description was published Talbot had sent the fossil to the Peabody Museum of Natural History at Yale University for further preparation and study where cast replicas were also made of the bones as they lay in the rock There Lull drew a reconstruction of the skeleton basing the parts missing from the fossil on the equivalents in Compsognathus and created a model of the animal in life which Talbot later described as having a sardonic smile Lull expanded on Talbot s article in a 1915 publication wherein he also proposed other identities for some of the bones than what she had originally suggested including a partial coracoid instead of a scapula and part of the tibia instead of the ilium part of the hips Lull suggested that the boulder containing the fossil must have come from a ledge which lay on the south side of the Holyoke Range about two or three miles north of where it was found and specified that it was from the Longmeadow Sandstone 6 2 11 7 nbsp Mignon Talbot second from left and students searching the rubble of the burned down Williston Hall in 1917 Lull had sent his manuscript to the Danish ornithologist Gerhard Heilmann for criticism prior to publication Heilmann published his response in a 1913 article in which he included previously unpublished photos of the fossil received from Talbot as well as his own restorations He disagreed with some of Lull s anatomical interpretations and had corresponded regarding the fossil with the American zoologist Robert Wilson Shufeldt about his contentions Heilmann s article was one in a series about the origin of birds wherein he examined the skeletons of prehistoric reptiles to find traits that may have been ancestral to birds 12 In a 1916 Washington Academy of Sciences meeting Shufeldt gave an account of his correspondence with Lull Talbot and Heilmann and agreed with the latter in some of his criticisms of Lull s restoration of Podokesaurus 13 Talbot wanted the fossil to stay at Yale or Washington on permanent exhibit where it could be with its kind but it was kept at Mount Holyoke in the old science building Williston Hall as a local specimen where it became a pet curiosity for the students During the Christmas break of 1917 Williston Hall burned down and no remains of the Podokesaurus fossil were found in the rubble The American writer Christopher Benfey pointed out in 2002 that Podokesaurus therefore had the peculiar distinction of being the dinosaur that vanished twice 2 1 The German paleontologist Friedrich von Huene was the last to study and describe the holotype specimen in a 1914 publication before it was destroyed he had studied it at Yale before Talbot s description was published 7 14 While the college s fossil collections were almost entirely destroyed by the fire its facilities and collections continued to grow and improve afterwards due to Talbot s efforts 15 No other unequivocal Podokesaurus specimens have since been found but cast replicas of the type specimen remain at the Peabody Museum of Natural History and the American Museum of Natural History in New York Podokesaurus received little further attention until new and abundant fossils of Coelophysis were discovered in the late 1940s and the anatomy of small theropod dinosaurs became clearer the American paleontologists Edwin Harris Colbert and Donald Baird compared Podokesaurus with Coelophysis in 1958 using the casts of the former Along with the sauropodomorph Anchisaurus Podokesaurus was among the first substantial collections of dinosaur skeletal material known from the East Coast of North America Apart from a tooth assigned to Coelophysis in 1976 all other Early Jurassic theropod records on the East Coast are footprints 16 17 18 In 2021 Podokesaurus and Anchisaurus were proposed as contenders for state dinosaur of Massachusetts by Representative Jack Patrick Lewis with Podokesaurus winning the online poll 19 20 21 On May 2 2022 Governor Charlie Baker signed a law making it the official state dinosaur 22 Description edit nbsp Size of Podokesaurus compared to a human and a cat The preserved body of the only known Podokesaurus fossil was 18 cm 7 in long 8 Lull estimated the complete length of Podokesaurus to have been 1 150 mm 3 77 ft the neck accounting for 130 mm 5 1 in the back for 170 mm 6 7 in the sacrum the vertebrae of the pelvic region for 45 mm 1 8 in and the tail for 730 mm 2 40 ft 6 Von Huene estimated the animal to have been 1 100 mm 3 6 ft long with the tail accounting for about 70 cm 2 3 ft more than 1 5 times the rest of the skeleton together 7 Colbert estimated the animal s length at about 1 m 3 3 ft 17 In 1995 the writer Jan Peczkis estimated Podokesaurus to have weighed 10 40 kg 22 88 lb through pelvic height determination based on von Huene s measurements 23 The paleontologist Gregory S Paul estimated it to have weighed 1 kg 2 lb in 2016 based on a 1 m length estimate 24 Talbot stated in 1937 that those scientists who had seen the specimen did not think it was a young individual as there were no indications of cartilage that would turn to bone with age 1 while Paul thought it was possibly juvenile 24 In general the animal was lightly constructed with hollow bones 8 As a coelophysoid it would likely have been similar in build to for example Coelophysis being slender long necked and with sharp recurved teeth 16 Since few other small theropods were known at the time Podokesaurus was described it was mainly compared to the later genera Compsognathus Ornitholestes and Ornithomimus which were thought related Due to the fragmentary nature of the Podokesaurus specimen and the fact that it is lost the identity and shape of some of its bones are today unclear As only casts of the specimen now remain it is only possible to get a general impression of the preserved skeleton and its proportions Talbot identified bone fragments next to the tail as skull bones because two of them were bilaterally symmetric and one was broadly convex with a sulcus or furrow at the midline and according to Lull was possibly placed at the upper wall of the skull not far from the frontal bones Lull thought other of these elements may have been part of the nasal bones 6 17 Von Huene instead interpreted these bones as caudals from the middle of the tail 7 Postcranial skeleton edit nbsp nbsp nbsp nbsp nbsp Photo and interpretative drawing of the front part of the specimen from 1911 above photo of uncertain bone fragments that may belong to either the skull or tail bottom left drawing of the tail and uncertain bone fragments lower middle and cross section of a vertebra lower right The vertebrae were very light and hollow and some were slightly concave at each end The cervical vertebrae were relatively large in length and diameter compared to the dorsals and had styliform resembling a pen or bristle in shape cervical ribs which were long straight and narrow as in Anchisaurus The front dorsals were much shorter than the cervicals then again increased in size towards the pelvis They measured 12 13 mm 0 47 0 51 in in length The neural spines of the dorsals were narrow high and curved backwards but not as expanded from front to back as in Compsognathus The dorsal ribs were strongly curved and very slender and hollow reminiscent of those in Saltopus and Hallopus the largest being 52 mm 2 0 in long and 2 mm 0 1 in wide The transverse processes that connected with the ribs on each side of a vertebra formed a circular arc downward from each side of a dorsal extending about as far from the centrum the body of a vertebra as the spinous process was high The zygapophyses processes that connected adjacent vertebrae were well developed The centra were relatively longer than those of Ornithomimus while those of Compsognathus resembled those of Podokesaurus more but were shorter 8 6 7 While the hind part of the tail was located some distance away from the rest of the skeleton Lull believed it was in its natural position and that it would have been very long the intermediate vertebrae having been swept away The caudal vertebrae were very long and slender and along with their chevrons bones on the undersides of the caudals resembled those of Ornitholestes A typical caudal was 17 mm 0 67 in long and 4 mm 0 16 in in diameter The caudals were very similar in length and did not decrease in length until the last few in the succession Just in front of the pubis there was a cluster of slender gastralia abdominal ribs the longest of which was 18 mm 0 71 in long The frontmost gastralia had broadened ends which is often the condition in sternal ribs 8 6 7 The humerus was small and very delicate 42 mm 1 7 in long less than half the length of the femur It had a strong processus lateralis a process directed to the side 30 mm 1 2 in above its lower end Lull found it similar to that of Ornitholestes apart from the radial crest that connected with the radius bone of the lower arm not being as high showing little muscular power Von Huene estimated the radius to have been 30 mm 1 2 in long Lull found the hand more similar to that of Compsognathus than of Ornitholestes 8 6 7 Only slender phalanx bones of the three fingers were preserved including sharp curved claws 7 nbsp Hypothetical life restoration The pubis was very long expanding both at the front and hind ends It was 6 mm 0 24 in wide and 95 mm 3 7 in long and its lower expansion was 10 mm 0 39 in in diameter Talbot found the pubis similar to that of the then undescribed Procompsognathus Lull argued that the pubis lay approximately in position in the fossil pointing forwards 8 6 Heilmann instead believed the bone had been moved out of position before burial and would have been directed backwards 12 Colbert and Baird suggested the pubis was directed forwards but that it curved slightly upwards instead of downwards due to natural warping and cracking of the bone The ischium was 55 mm 2 2 in long 15 5 mm 0 61 in wide at the end closest to the body and its slender shaft was 4 mm 0 16 in in diameter and somewhat thickened at its lower end Lull found it similar to those of Compsognathus and Ornitholestes Below the acetabulum where the femur connects with the pelvis there was a broad lamella running towards the pubis 6 7 The femur was slender nearly straight had thin walls and was expanded at the back side of its lower end It was 86 mm 3 4 in long and 6 5 mm 0 26 in in diameter just below the fourth trochanter a flange placed mid length at the back of the femur The fourth trochanter was strong 18 mm 0 71 in long and about 2 mm 0 079 in high and was situated past the middle of the shaft towards the lower end The condyles round prominences of the femur s lower end protruded strongly hindwards The tibia was a thin narrow shaft 104 mm 4 1 in in length and about 7 mm 0 28 in in diameter Talbot stated the very thin fibula lay close to the tibia and was of almost equal length while von Huene thought this was instead part of the crushed tibia The three metatarsals of the lower leg were closely appressed together forming a compact structure similar to what was seen in Ornithomimus but not fused into a tarsometatarsus as seen in birds The length of the metatarsals was 75 mm 3 0 in while their width was 9 mm 0 35 in The most complete pedal phalanx was very slender and 12 mm 0 47 in long 6 8 7 Classification editEarly interpretations edit nbsp Lull s 1915 illustration of the pelvic region showing the forwards directed pubis Pu as preserved When reading her preliminary description in 1910 Talbot suggested Podokesaurus to have been an herbivorous dinosaur but further work at Yale University showed that some bones had been incorrectly identified and the ischium of the pelvis with a well developed ridge was found to resemble that of Compsognathus She refrained from making a definite classification of the specimen in her 1911 description due to the lack of jaw and foot bones which could have aided in this but concluded it would have belonged to a carnivorous dinosaur based on the shape and position of the pubis as well as the absence of a postpubis She considered the fossil to be Triassic in age the first of the three Mesozoic periods 8 In 1914 von Huene named the new family Podokesauridae wherein he in addition to Podokesaurus included Saltopus Procompsognathus Coelophysis and Tanystropheus He placed this group under Coelurosauria which at the time was used to include small theropods in general 25 7 26 Heilmann considered Podokesaurus very similar to the early bird Archaeopteryx in 1913 and wondered why Talbot had not made any comparisons to it He particularly found the legs and the pelvis when the pubis was interpreted as pointing backwards as in birds similar to what it might look like in a bird ancestor while considering Lull s reconstruction of a forward directed pubis unlikely He also found parts of the shoulder blade forelimbs and even tail bones similar to those of birds He furthermore pointed to the presence of abdominal ribs and that the bones were hollow and concluded that nothing precluded Podokesaurus from being a very primitive proto bird with not yet fused middle foot bones The only feature he found inconsistent with this interpretation was the short finger with a claw if it was not instead part of a toe He suggested that the issue could be determined if the skull sternum and clavicle were found in the rock bones that would be important clues for classification 12 nbsp nbsp Gerhard Heilmann s 1913 comparison between the legs and pelvis of Podokesaurus left 1 with backwards directed pubis 2 with forwards directed pubis and Archaeopteryx 3 and his redrawing of Lull s skeletal reconstruction right compared with other dinosaurs Heilmann wished for a clearer explanation of the placement of the middle foot bones in relation to each other and found it surprising that Lull s reconstruction of Podokesaurus showed an even more appressed middle foot than was present in the later supposed descendant Ornithomimus which he thought would have developed a completely bird like middle foot by that time Heilmann found Podokesaurus very unusual for a dinosaur from the Triassic and thought it was one of the earliest bipedal vertebrates He suggested that since it was so different from Thecodontosaurus and Plateosaurus those may not have been dinosaurs or Podokesaurus could instead have been related to Saltopus or parasuchians but found its fossils too insufficient to say anything definite about the issue 12 Shufeldt elaborated on his and Heilmann s interpretation of the pubis in 1915 and stated the bone had probably been displaced during fossilization He pointed out that if it had faced forward it would have been in forcible contact with the abdominal ribs that would have been dangerous for internal organs during movement 11 Lull found Heilmann and Shufeldt s criticisms of his pelvis reconstruction probable in 1915 He listed Podokesauridae under the superfamily Compsognatha and suggested Podokesaurus was perhaps ancestral to the later North American genera Ornitholestes and Ornithimimus 6 In 1916 Heilmann pointed out that early dinosaurs parasuchians and pterosaurs all had similarities to birds as well as to each other and that Triassic reptiles like Scleromochlus Saltopus and Podokesaurus were difficult to separate He proposed that Podokesaurus and other bipedal reptiles from the Triassic were descended from pseudosuchians which many types of archosaurs were classified as at the time that may have evolved bipedality by the Permian He concluded that birds were descended from ornithosuchian pseudosuchians rather than from dinosaurs due to their bipedality and bird like legs 27 The paleontologist Henry Fairfield Osborn used Podokesaurus as an example of a carnivorous dinosaur of the bird like type in 1917 while stating that similarities between birds and dinosaurs were due to parallel evolution 28 The paleontologist Franz Nopcsa von Felso Szilvas created the subfamily Podokesaurinae in 1928 within which he included Podokesaurus Procerosaurus Saltopus and Tanystropheus 29 Von Huene grouped Podokesaurus Coelophysis Spinosuchus Halticosaurus Saltopus Avipes and Velocipes in Podokesauridae in 1932 30 Relation to Coelophysis edit nbsp Replica of a natural cast of bones assigned to C holyokensis in 1964 when Podokesaurus was suggested to be a synonym of Coelophysis In 1958 Colbert and Baird described a theropod specimen consisting of natural casts of bones in sandstone probably formed when the bones were dissolved by acidic water leaving molds of the bones including a pubis tibia and some ribs They found the specimen similar to Coelophysis and Podokesaurus referring to it as C sp of unknown species They considered the natural cast and Podokesaurus to be from the Portland Arkose of the Newark Group in the Connecticut valley Though Podokesaurus was smaller than the others being comparable in size to the smallest known Coelophysis specimens these researchers suggested that because it was so similar to them this raised questions as to its validity 31 32 In 1964 Colbert synomymized Podokesaurus with Coelophysis since the latter name was older coining the new combination C holyokensis He also suggested that the natural cast belonged to C holyokensis Colbert stated that Podokesaurus could only be distinguished from Coelophysis by the neural spines of its vertebrae not being as long from front to back and because the ischium differed in shape He found these differences to be similar to those seen between modern reptile species within the same genus and that they represented eastern C holyokensis and western C bauri species of the same genus While he admitted that these conclusions were not ironclad and that Podokesaurus may indeed have been distinct he said the burden of proof should be on the proponents of such a view 17 In 1977 the paleontologists Paul E Olsen and Peter Galton redated the Newark Supergroup which the Portland Formation belongs to to the Early Jurassic instead of the preceding Triassic as was previously thought This was part of a study in which Olsen compared the fauna of various formations and concluded there had not been a sudden widespread extinction event at the Triassic Jurassic border but that it had instead been gradual 33 Olsen stated in 1980 that while the exact provenance and systematic position of Podokesaurus will probably remain uncertain the Portland Formation it was thought to be from was probably Early Jurassic in age and therefore 15 million years younger than Coelophysis from the Triassic Since features shared between Podokesaurus and Coelophysis are also known in other small theropods such as Syntarsus Olsen suggested that Podokesaurus should be retained as a separate genus of indeterminate theropods to avoid overextending the temporal range of Coelophysis He also applied this argument to the natural cast regarding it as incertae sedis with uncertain relationships among theropods rather than as Podokesaurus or Coelophysis 34 The paleontologist Samuel P Welles stated in 1984 that the family Podokesauridae had become a catch all for most Triassic theropods While he found Coelophysis the most similar to Podokesaurus among theropods he thought the two differed greatly in that the fourth trochanter of the latter was below midheight on the femur unlike the higher position in most other theropods and its metatarsals were of equal length 14 The paleontologist Kevin Padian stated in 1986 that while Colbert s suggestion of synonymy was possible the discernible similarities between Podokesaurus and Coelophysis were primitive theropod features and the two were not as close in time as once thought 35 Paul said in 1988 that while the family Podokesauridae was still used for Coelophysis and kin Podokesaurus was not based on good remains to begin with and with only bad cast replicas remaining he thought there would always be disagreement about the taxon He found this to be too much ambiguity to put up with and proposed the name Coelophysidae should be used instead Halticosauridae another contender was also based on too fragmentary remains 36 In 1989 Colbert also doubted the synonymy of Podokesaurus with Coelophysis and that the natural casts belonged to the latter due to their revised Early Jurassic ages and he made no attempt to resolve the status of Podokesaurus due to the only specimen being lost He retained the name Podokesauridae for the family 37 nbsp Mounted skeleton of Coelophysis which is thought to have been similar to Podokesaurus In 1990 the paleontologists Timothy Rowe and Jacques Gauthier considered Podokesauridae a taxonomic waste basket wherein taxa had been grouped based on phenetic resemblance and stratigraphic division and therefore under continuous revision and instability They considered it possible that Podokesaurus and the natural cast specimen were Coelophysis but found that their similarities were not shared exclusively by them but were ancestral features among theropods They therefore agreed that the name Podokesaurus should be restricted to the holotype and that it and the natural cast should be considered Theropoda incertae sedis 38 In the same volume the paleontologist David B Norman agreed with this assessment and stated the features used to unite Podokesaurus with Coelophysis merely confirm that they were dinosaurs rather than establish a specific relation between them 5 The paleontologist Thomas R Holtz agreed in 1994 that the family name Podokesauridae should be replaced by Coelophysidae By this time the idea that small theropods should be grouped in Coelurosauria and large theropods in Carnosauria was falling out of favor and Coelophysoidea was considered a separate group of gracile early theropods 39 The paleontologists David B Weishampel and Luther Young suggested ceratosaurian affinities for Podokesaurus in 1996 40 The paleontologist Ronald S Tykoski and Rowe noted in 2004 that while Podokesaurus had coelophysoid features such as a small knob like expansion on the lower part of the pubis it did not have any derived traits that would unite it with Coelophysis They agreed with earlier researchers that the name Podokesaurus should be restricted to the holotype and concluded that the natural cast may be a coelophysoid but could not be identified beyond being a theropod 41 In 2004 the paleontologists Matthew T Carrano and Scott D Sampson stated that Podokesaurus was almost certainly a coelophysoid similar to Coelophysis It had coelophysoid features such as a long downward curved pubis that was longer than the ischium and an additional foramen opening on the pubis below the oburator foramen but little more could be said about its affinities 42 Carrano and colleagues stated in 2004 that Segisaurus and Podokesaurus were among the latest surviving coelophysoids and that the evolutionary radiation of this group may have ended by the latest part of the Early Jurassic 43 Also in 2004 the paleontologists Anthea Bristowe and Michael A Raath listed Podokesaurus as a synonym of Coelophysis without elaboration 44 Tykoski rejected synonymy between the two in his 2005 dissertation but left Podokesaurus out of his analysis 45 Paul suggested in 2016 that Podokesaurus may have formed the family Coelophysidae with Coelophysis Panguraptor and Procompsognathus 24 Paleobiology edit nbsp Heilmann s outdated 1913 restoration of Podokesaurus running near a lake and other dinosaurs Talbot suggested that the short slender humerus long straight hindlimb bones and the well developed fourth trochanter of the femur indicated that Podokesaurus was bipedal She found the fact that the tibia was much longer than the femur that the metatarsals were very long over half the length of the tibia and the skeleton s light construction were indicative of rapid locomotion Talbot stated that Lull thought this was an adaptation to climatic conditions as the animal must have been able to travel fast and far for water in its semi arid region Talbot also reported a small piece of smooth polished quartz among the ribs and suggested it could have been a gastrolith stomach stone and so the first time these were found in association with a carnivorous dinosaur 8 Von Huene agreed the stone was a gastrolith distinct from the surrounding sandstone and added it was 11 mm 0 43 in long 7 Lull found the animal to have been essentially a slender cursorial adapted for running animal with carnivorous habits but that the slenderness that made it swift also confined it to small prey 6 In 1932 von Huene proposed that small coelurosaurs had a jumping gait due to their lower legs being longer than their upper legs contrasting with the alternating steps of carnosaurs With its large fourth trocanther he thought Podokesaurus had probably abandoned this jumping gait instead moving with rapid alternating steps similar to ratite birds 30 nbsp Grallator cursorius footprint which Lull correlated with Podokesaurus In 1982 the paleontologist Richard A Thulborn estimated the speed of various dinosaurs based on the relationships between speed gait and body size of modern animals mainly mammals By extrapolating the stride length and cadence of Podokesaurus he estimated it could have run at about 15 20 km h 9 12 mph He concluded that if a dinosaur could match a mammal in speed it must have had similar levels of efficiency in locomotor ability and physiology He cautioned that comparison was difficult because dinosaur anatomy differed significantly from that of mammals and birds Differences included the massive tails of dinosaurs and hindlimb retractor muscles that originated behind the femur while these muscles originate more forward in mammals and extant birds 46 Weishampel stated in 2006 that as a coelophysoid Podokesaurus would have been a fleet footed predator with powerful forelimbs and grasping hands 16 Lull found that fossil footprints named Grallator cursorius agreed with the foot and stride of Podokesaurus These were abundant at a quarry in South Hadley where they were found alongside large Otozoum moodii tracks which he thought supported this identity 6 In 1926 Heilmann suggested that the foot of Procompsognathus was a better match for the G cursorius tracks due to the proportions of its toe bones 47 The paleontologist Wilhelm Bock stated in 1952 that while very similar Grallator tracks had been attributed to various small dinosaurs such as Podokesaurus he considered such correlations too specific and that the best that could be said was such tracks represented small coelurosaurians 48 The writer Donald F Glut suggested in 1997 that a slab with tracks from the Brunswick Formation of New York previously attributed to Coelophysis may instead have been produced by Podokesaurus based on its Jurassic age 49 This formation is now known as the Passaic Formation and instead thought to be Late Triassic in age 50 Paleoenvironment edit nbsp 1917 restorations of animals from the Connecticut Valley then thought to have lived during the Triassic The Portland Formation which Podokesaurus is from was redated to the Early Jurassic in 1977 The only known specimen of Podokesaurus is thought to have been collected from the Portland Formation earlier known as the Portland Arkose in the Hartford Basin of Massachusetts The age of this formation has long been unclear it was thought to be Triassic until 1977 but it is currently thought to date to the Hettangian Sinemurian stages of the Early Jurassic between 201 and 190 million years ago earlier thought to be the Pliensbachian Toarcian stages 51 16 34 In 2016 the paleontologist Robert E Weems and colleagues suggested the Portland Formation should be elevated to a geological group within the Newark Supergroup as the Portland Group and thereby replacing the former name Agawam Group They also reinstated the Longmeadow Sandstone where Podokesaurus was found as a formation within the uppermost Portland Group it had earlier been considered identical to the Portland Formation 51 6 The Portland Group represents the uppermost part of the Newark Supergroup and was deposited after the Central Atlantic magmatic province was formed during the end of the Triassic and the beginning of the Jurassic The Longmeadow Sandstone consists of fluvial deposited by rivers and streams red mudstones sandstones conglomerates minor red eolian deposited by wind sandstones and siltstones 51 Other animals known from the formation include the sauropodomorph dinosaur Anchisaurus the crocodylomorph Stegomosuchus and fish such as Acentrophorus and Semionotus 34 Dinosaur tracks include the ichnogenera Anchisauripus Anomoepus Eubrontes and Grallator 52 See also editTimeline of coelophysoid researchReferences edit a b c d e f Warner F L 1937 XII Lost dinosaur On a New England Campus Cambridge Houghton Mifflin Company p 279 ASIN B00085TO0O a b c d Benfey C 2002 Foreword A route of evanescence Changing Prospects The View from Mount Holyoke Ithaca Cornell University Press p 9 ISBN 978 0801441196 Daring to Dig Mignon Talbot 1869 1950 museumoftheearth org Archived from the original on February 11 2021 Retrieved August 14 2020 Rossiter M W 1981 Geology in nineteenth century women s education in the United States Journal of Geological Education 29 5 228 232 Bibcode 1981JGeoE 29 228R doi 10 5408 0022 1368 29 5 228 a b Norman D B 1990 Problematic Theropoda In Weishampel D B Osmolska H Dodson P eds The Dinosauria 1 ed Berkeley University of California Press p 298 ISBN 978 0 520 06727 1 a b c d e f g h i j k l m n Lull R S 1915 Triassic life of the Connecticut valley State Geological and Natural History Survey of Connecticut 24 155 169 doi 10 5962 bhl title 70405 ISBN 978 1167291937 Archived from the original on October 6 2020 Retrieved August 21 2020 a b c d e f g h i j k l m von Huene F 1914 Beitrage zur Geschichte der Archosaurier Geologische und Palaontologische Abhandlungen in German 13 1 53 Archived from the original on October 9 2020 Retrieved October 7 2020 a b c d e f g h i j k Talbot M 1911 Podokesaurus holyokensis a new dinosaur from the Triassic of the Connecticut Valley American Journal of Science s4 31 186 469 479 Bibcode 1911AmJS 31 469T doi 10 2475 ajs s4 31 186 469 Archived from the original on August 18 2020 Retrieved August 16 2020 Turner S Burek C V Moody R T J 2010 Forgotten women in an extinct saurian man s world Geological Society London Special Publications 343 1 111 153 Bibcode 2010GSLSP 343 111T doi 10 1144 SP343 7 S2CID 130338204 Bakker R T 2014 A Tale of Two Compys What Jurassic Park got right and wrong about dino anatomy The Houston Museum of Natural Science Archived from the original on September 21 2020 Retrieved August 18 2020 a b Moodie R L 1913 Some recent advances in vertebrate paleontology II The American Naturalist 47 556 248 256 doi 10 1086 279347 ISSN 0003 0147 JSTOR 2455799 a b c d Heilmann G 1913 1914 Vor nuvaerende viden om fuglenes afstamning Andet afsnit Fugleligheder blandt fortidsogler Dansk Ornithologisk Forenings Tidsskrift in Danish 8 56 65 Wegemann C H Lyon M W 1916 Proceedings of the Academy and Affiliated Societies Journal of the Washington Academy of Sciences 6 9 251 259 ISSN 0043 0439 JSTOR 24521263 a b Welles S P 1984 Dilophosaurus wetherilli Dinosauria Theropoda osteology and comparisons Palaeontographica Abteilung A 185 172 Elder E S 1982 Women in early geology Journal of Geological Education 30 5 287 293 Bibcode 1982JGeoE 30 287E doi 10 5408 0022 1368 30 5 287 a b c d Weishampel D B 2006 Another look at the dinosaurs of the East Coast of North America III Jornadas Internacionales sobre Paleontologia de Dinosaurios y su Entorno Salas de los Infantes Burgos Spain Colectivo Arqueologico Paleontologico Salense Actas pp 129 168 a b c d Colbert E H 1964 The Triassic dinosaur genera Podokesaurus and Coelophysis American Museum Novitates 2168 1 12 hdl 2246 3350 Galton P M 1976 Prosauropod dinosaurs Reptilia Saurischia of North America Postilla Peabody Museum Yale University 169 6 Morrison H February 4 2021 Massachusetts State Dinosaur Podokesaurus holyokensis wins fan vote lawmaker files legislation to officially declare state dinosaur Masslive Archived from the original on March 21 2021 Kent L 2021 Massachusetts will soon propose an official state dinosaur CNN Archived from the original on January 18 2021 Retrieved January 18 2021 Chianca P 2021 Boston com readers want this as official Mass dinosaur www boston com Archived from the original on January 17 2021 Retrieved January 18 2021 Morrisson H May 3 2022 Massachusetts officially has a state dinosaur MassLive Retrieved May 4 2022 Peczkis J 1995 Implications of body mass estimates for dinosaurs Journal of Vertebrate Paleontology 14 4 530 531 doi 10 1080 02724634 1995 10011575 ISSN 0272 4634 a b c Paul G S 2016 Theropods The Princeton Field Guide to Dinosaurs 2 ed Princeton Princeton University Press pp 76 78 ISBN 978 0691167664 von Huene F 1914 Das naturliche System der Saurischia Centralblatt fur Mineralogie Geologie und Palaontologie in German 5 154 158 Archived from the original on October 27 2020 Retrieved October 24 2020 Padian K 2012 The problem of dinosaur origins integrating three approaches to the rise of Dinosauria Earth and Environmental Science Transactions of the Royal Society of Edinburgh 103 3 4 423 442 doi 10 1017 S1755691013000431 S2CID 128420276 Heilmann G 1916 Vor nuvaerende viden om fuglenes afstamning Femte afsnit Forfuglen Proavis Dansk Ornithologisk Forenings Tidsskrift in Danish 11 90 113 137 Osborn H F 1917 The Origin and Evolution of Life on the Theory of Action Reaction and Interaction of Energy New York C Scribner s Sons pp 210 215 doi 10 5962 bhl title 7397 Archived from the original on June 16 2021 Retrieved September 21 2020 Nopcsa F 1928 The genera of reptiles Palaeobiologica 1 163 188 a b von Huene F 1932 Die fossile Reptil Ordnung Saurischia ihre Entwicklung und Geschichte PDF Monographien zur Geologie und Palaontologie in German 4 1 24 35 332 Archived PDF from the original on February 25 2021 Retrieved December 20 2020 Colbert E H Baird D 1958 Coelurosaur bone casts from the Connecticut Valley Triassic American Museum Novitates 1901 1 11 hdl 2246 2486 Archived from the original on November 14 2020 Retrieved November 14 2020 Getty P R Bush A M 2011 Sand pseudomorphs of dinosaur bones Implications for non preservation of tetrapod skeletal material in the Hartford Basin USA Palaeogeography Palaeoclimatology Palaeoecology 302 3 4 407 Bibcode 2011PPP 302 407G doi 10 1016 j palaeo 2011 01 029 Olsen P E Galton P M 1977 Triassic Jurassic tetrapod extinctions Are they real Science 197 4307 983 986 Bibcode 1977Sci 197 983O doi 10 1126 science 197 4307 983 PMID 17784133 S2CID 44654197 a b c Olsen P E 1980 A comparison of the vertebrate assemblages from the Newark and Hartford basins Early Mesozoic Newark Supergroup of Eastern North America PDF In Jacobs L L ed Aspects of Vertebrate History Essays in Honor of Edwin Harris Colbert Flagstaff Museum of Northern Arizona Press pp 35 53 ISBN 978 0897340526 Archived PDF from the original on June 16 2021 Retrieved November 16 2020 Padian K 1986 On the type material of Coelophysis Cope Saurischia Theropoda and a new specimen from the Petrified Forest of Arizona Late Triassic Chinle Formation In Padian K ed The beginning of the age of dinosaurs Faunal change across the Triassic Jurassic boundary Cambridge Cambridge University Press pp 57 60 ISBN 978 0521367790 Paul G S 1988 Predatory Dinosaurs of the World New York Simon amp Schuster pp 258 259 ISBN 978 0 671 61946 6 Colbert E H 1989 The Triassic dinosaur Coelophysis Museum of Northern Arizona Bulletin 57 24 28 29 ISBN 978 0897340977 Rowe T Gauthier J 1990 Ceratosauria In Weishampel D B Osmolska H Dodson P eds The Dinosauria 1 ed Berkeley University of California Press pp 153 166 ISBN 978 0 520 06727 1 Holtz T R 1994 The phylogenetic position of the Tyrannosauridae Implications for theropod systematics Journal of Paleontology 68 5 1100 1117 doi 10 1017 S0022336000026706 ISSN 0022 3360 JSTOR 1306180 Archived from the original on October 3 2020 Retrieved October 3 2020 Weishampel D B Young L 1996 Dinosaurs of the East Coast Baltimore Johns Hopkins University Press p 275 ISBN 978 0801852176 Tykoski R S Rowe T 2004 Ceratosauria In Weishampel D B Dodson P Osmolska H eds The Dinosauria 2 ed Berkeley University of California Press p 68 ISBN 978 0 520 24209 8 Carrano M T Sampson Scott D 2004 A review of coelophysoids Dinosauria Theropoda from the Early Jurassic of Europe with comments on the late history of the Coelophysoidea Neues Jahrbuch fur Geologie und Palaontologie Monatshefte 2004 9 537 558 doi 10 1127 njgpm 2004 2004 537 Carrano M T Hutchinson J R Sampson S D 2005 New information on Segisaurus halli a small theropod dinosaur from the Early Jurassic of Arizona Journal of Vertebrate Paleontology 25 4 835 849 doi 10 1671 0272 4634 2005 025 0835 NIOSHA 2 0 CO 2 Bristowe A Raath M A 2004 A juvenile coelophysoid skull from the Early Jurassic of Zimbabwe and the synonymy of Coelophysis and Syntarsus Palaeontologia Africana ISSN 0078 8554 Archived from the original on August 9 2020 Retrieved October 20 2020 Tykoski R S 2005 Anatomy ontogeny and phylogeny of coelophysoid theropods The University of Texas at Austin Thesis p 69 Archived from the original on July 29 2020 Retrieved October 20 2020 Thulborn R A 1982 Speeds and gaits of dinosaurs Palaeogeography Palaeoclimatology Palaeoecology 38 3 4 227 256 Bibcode 1982PPP 38 227T doi 10 1016 0031 0182 82 90005 0 Heilmann G 1926 The Origin of Birds New York Dover Publications p 181 ISBN 0 486 22784 7 Bock W 1952 Triassic reptilian tracks and trends of locomotive evolution With remarks on correlation Journal of Paleontology 26 3 395 433 ISSN 0022 3360 JSTOR 1299951 Archived from the original on June 16 2021 Retrieved September 30 2020 Glut D F 1997 Dinosaurs The Encyclopedia Jefferson McFarland amp Company Inc pp 718 719 ISBN 978 0786472222 Metz R 2000 Triassic trace fossils from lacustrine shoreline deposits of the Passaic formation douglassville pennsylvania Ichnos 7 4 253 266 doi 10 1080 10420940009380165 S2CID 128688223 a b c Weems R E Tanner L H Lucas S G 2016 Synthesis and revision of the lithostratigraphic groups and formations in the Upper Permian Lower Jurassic Newark Supergroup of eastern North America Stratigraphy 13 2 111 153 Archived from the original on August 5 2020 Retrieved October 20 2020 Collette J H Getty P R Hagadorn J W 2011 Insights into an Early Jurassic dinosaur habitat ichnofacies and enigmatic structures from the Portland Formation Hoover Quarry Massachusetts U S A Atlantic Geology 47 81 98 doi 10 4138 atlgeol 2011 003 External links edit nbsp Wikimedia Commons has media related to Podokesaurus nbsp Wikispecies has information related to Podokesaurus Museum of Science Boston Celebrate Podokesaurus holyokensis as the Massachusetts State Dinosaur 24 minute video Museum of Science Boston Choosing the Massachusetts State Dinosaur 49 minute video Portals nbsp Dinosaurs nbsp United States Retrieved from https en wikipedia org w index php title Podokesaurus amp oldid 1206932511, wikipedia, wiki, book, books, library,

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