Biology:Diplodocus

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Short description: Genus of diplodocid sauropod dinosaurs (fossil)

Diplodocus
Temporal range: Late Jurassic (Kimmeridgian), 154–152 Ma
CM Diplodocus.jpg
Scientific classification e
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Clade: Dinosauria
Clade: Saurischia
Clade: Sauropodomorpha
Clade: Sauropoda
Superfamily: Diplodocoidea
Family: Diplodocidae
Subfamily: Diplodocinae
Genus: Diplodocus
Marsh, 1878
Type species
Diplodocus longus
(nomen dubium)
Marsh, 1878
Other species
  • D. carnegii
    Hatcher, 1901
  • D. hallorum
    (Gillette, 1991) (originally Seismosaurus)
Synonyms
  • Seismosaurus
    Gillette, 1991

Diplodocus (/dɪˈplɒdəkəs/,[1][2] /dˈplɒdəkəs/,[2] or /ˌdɪplˈdkəs/[1]) was a genus of diplodocid sauropod dinosaurs, whose fossils were first discovered in 1877 by S. W. Williston. The generic name, coined by Othniel Charles Marsh in 1878, is a Neo-Latin term derived from Greek διπλός (diplos) "double" and δοκός (dokos) "beam",[1][3] in reference to the double-beamed chevron bones located in the underside of the tail, which were then considered unique.

The genus of dinosaurs lived in what is now mid-western North America, at the end of the Jurassic period. It is one of the more common dinosaur fossils found in the middle to upper Morrison Formation, between about 154 and 152 million years ago, during the late Kimmeridgian Age.[4] The Morrison Formation records an environment and time dominated by gigantic sauropod dinosaurs, such as Apatosaurus, Barosaurus, Brachiosaurus, Brontosaurus, and Camarasaurus.[5] Its great size may have been a deterrent to the predators Allosaurus and Ceratosaurus: their remains have been found in the same strata, which suggests that they coexisted with Diplodocus.

Diplodocus is among the most easily identifiable dinosaurs, with its typical sauropod shape, long neck and tail, and four sturdy legs. For many years, it was the longest dinosaur known.

Description

Sizes of Diplodocus carnegii (orange) and D. hallorum (green) compared with a human.

Among the best-known sauropods, Diplodocus were very large, long-necked, quadrupedal animals, with long, whip-like tails. Their forelimbs were slightly shorter than their hind limbs, resulting in a largely horizontal posture. The skeletal structure of these long-necked, long-tailed animals supported by four sturdy legs have been compared with suspension bridges.[6] In fact, D. carnegii is currently one of the longest dinosaurs known from a complete skeleton,[6] with a total length of 24–26 meters (79–85 ft).[7][8] Modern mass estimates for D. carnegii have tended to be in the 12–14.8-metric-ton (13.2–16.3-short-ton) range.[7][9][8]

D. hallorum, known from partial remains, was even larger, and is estimated to have been the size of four elephants.[10] When first described in 1991, discoverer David Gillette calculated it to be 33 m (110 ft) long based on isometric scaling with D. carnegii. However, he later stated that this was unlikely and estimated it to be 39 – 45 meters (130 – 150 ft) long, suggesting that some individuals may have been up to 52 m (171 ft) long and weighed 80 to 100 metric tons,[11] making it the longest known dinosaur (excluding those known from exceedingly poor remains, such as Amphicoelias or Maraapunisaurus). The estimated length was later revised downward to 30.5–35 m (100–115 ft) and later on to 29–33.5 m (95–110 ft)[12][13][14][8][7] based on findings that show that Gillette had originally misplaced vertebrae 12–19 as vertebrae 20–27. Weight estimates based on the revised length are as high as 38 metric tons (42 short tons)[12] although more recently, and according to Gregory S. Paul, a 29 m (95 ft) long D. hallorum was estimated to weigh 23 metric tons (25 short tons) in body mass.[7] The nearly complete D. carnegii skeleton at the Carnegie Museum of Natural History in Pittsburgh, Pennsylvania, on which size estimates of D. hallorum are mainly based, also was found to have had its 13th tail vertebra come from another dinosaur, throwing off size estimates for D. hallorum even further. While dinosaurs such as Supersaurus were probably longer, fossil remains of these animals are only fragmentary and D. hallorum still remains among the longest known dinosaurs.[12][15]

Caudal vertebrae of D. carnegii showing the double-beamed chevron bones to which the genus name refers, Natural History Museum, London

Diplodocus had an extremely long tail, composed of about 80 caudal vertebrae,[16] which are almost double the number some of the earlier sauropods had in their tails (such as Shunosaurus with 43), and far more than contemporaneous macronarians had (such as Camarasaurus with 53). Some speculation exists as to whether it may have had a defensive[17] or noisemaking (by cracking it like a coachwhip)[18] or, as more recently suggested, tactile function.[19] The tail may have served as a counterbalance for the neck. The middle part of the tail had "double beams" (oddly shaped chevron bones on the underside, which gave Diplodocus its name). They may have provided support for the vertebrae, or perhaps prevented the blood vessels from being crushed if the animal's heavy tail pressed against the ground. These "double beams" are also seen in some related dinosaurs. Chevron bones of this particular form were initially believed to be unique to Diplodocus; since then they have been discovered in other members of the diplodocid family as well as in non-diplodocid sauropods, such as Mamenchisaurus.[20]

Reconstruction of D. carnegii with horizontal neck, flexible whip tail, keratinous spines and nostrils low on the snout

Like other sauropods, the manus (front "feet") of Diplodocus were highly modified, with the finger and hand bones arranged into a vertical column, horseshoe-shaped in cross section. Diplodocus lacked claws on all but one digit of the front limb, and this claw was unusually large relative to other sauropods, flattened from side to side, and detached from the bones of the hand. The function of this unusually specialized claw is unknown.[21]

No skull has ever been found that can be confidently said to belong to Diplodocus, though skulls of other diplodocids closely related to Diplodocus (such as Galeamopus) are well known. The skulls of diplodocids were very small compared with the size of these animals. Diplodocus had small, 'peg'-like teeth that pointed forward and were only present in the anterior sections of the jaws.[22] Its braincase was small. The neck was composed of at least 15 vertebrae and may have been held parallel to the ground and unable to be elevated much past horizontal.[23]

Diplodocus sp. scale shapes. These scale shapes include (1) rectangular, (2) ovoid and dome, (3) arching scale rows, (4) globular.

Skin

The discovery of partial diplodocid skin impressions in 1990 showed that some species had narrow, pointed, keratinous spines, much like those on an iguana. The spines could be up to 18 centimeters (7.1 in) long, on the "whiplash" portion of their tails, and possibly along the back and neck as well, similarly to hadrosaurids.[24][25] The spines have been incorporated into many recent reconstructions of Diplodocus, notably Walking with Dinosaurs.[26] The original description of the spines noted that the specimens in the Howe Quarry near Shell, Wyoming were associated with skeletal remains of an undescribed diplodocid "resembling Diplodocus and Barosaurus."[24] Specimens from this quarry have since been referred to Kaatedocus siberi and Barosaurus sp., rather than Diplodocus.[4][27]

Fossilized skin of Diplodocus sp., discovered at the Mother's Day Quarry, exhibits several different types of scale shapes including rectangular, polygonal, pebble, ovoid, dome, and globular. These scales range in size and shape depending upon their location on the integument, the smallest of which reach about 1mm while the largest 10 mm. Some of these scales show orientations that may indicate where they belonged on the body. For instance, the ovoid scales are closely clustered together and look similar to scales in modern reptiles that are located dorsally. Another orientation on the fossil consists of arching rows of square scales that interrupts nearby polygonal scale patterning. It is noted that the arching scale rows look similar to the scale orientations seen around crocodilian limbs, suggesting that this area may have also originated from around a limb on the Diplodocus. The skin fossil itself is small in size, reaching less than 70 cm in length. Due to the vast amount of scale diversity seen within such a small area, as well as the scales being smaller in comparison to other diplodocid scale fossils, and the presence of small and potentially “juvenile” material at the Mother’s Day Quarry, it is hypothesized that the skin originated from a small or even “juvenile” Diplodocus.[28]

Discovery and history

Bone Wars and Diplodocus longus

The first record of Diplodocus comes from Marshall P. Felch’s quarry at Garden Park near Cañon City, Colorado, when several fossils were collected by Benjamin Mudge and Samuel Wendell Williston in 1877. The first specimen (YPM VP 1920) was very incomplete, consisting only of two complete caudal vertebrae, a chevron, and several other fragmentary caudal vertebrae. The specimen was sent to the Yale Peabody Museum and was named Diplodocus longus ('long double-beam') by paleontologist Othniel Charles Marsh in 1878.[29] Marsh named Diplodocus during the Bone Wars, his competition with Philadelphian paleontologist Edward Drinker Cope to collect and describe as many fossil taxa as possible.[30] Though several more complete specimens have been attributed to D. longus,[31][32] detailed analysis has discovered that this type specimen is actually dubious, which is not an ideal situation for the type species of a well-known genus like Diplodocus. A petition to the International Commission on Zoological Nomenclature was being considered which proposed to make D. carnegii the new type species.[4][33] This proposal was rejected by the ICZN and D. longus has been maintained as the type species.[34]

Although the type specimen was very fragmentary, several additional diplodocid fossils were collected at Felch’s quarry from 1877 to 1884 and sent to Marsh, who then referred them to D. longus. One specimen (USNM V 2672), an articulated complete skull, mandibles, and partial atlas was collected in 1883, and was the first complete Diplodocid skull to be reported.[35][36] Tschopp et al.’s analysis placed it as an indeterminate diplodocine in 2015 due to the lack of overlap with any diagnostic Diplodocus postcranial material, as was the fate with all skulls assigned to Diplodocus.[4]

Second Dinosaur Rush and Diplodocus carnegii

Barnum Brown (left) and Henry Osborn (right) excavating a femur of Diplodocus hallorum (AMNH 223), 1897.
Several elements referred to Diplodocus longus, including a type caudal at the bottom, as figured in Marsh, 1896.[37]

After the end of the Bone Wars, many major institutions in the eastern United States were inspired by the depictions and finds by Marsh and Cope to assemble their own dinosaur fossil collections.[30] The competition to mount the first sauropod skeleton specifically was the most intense, with the American Museum of Natural History, Carnegie Museum of Natural History, and Field Museum of Natural History all sending expeditions to the west to find the most complete sauropod specimen, bring it back to the home institution, and mount it in their fossil halls.[30] The American Museum of Natural History was the first to launch an expedition, finding a semi-articulated partial postcranial skeleton containing many vertebrae of Diplodocus in at Como Bluff in 1897. The skeleton (AMNH FR 223) was collected by Barnum Brown and Henry Osborn, who shipped the specimen to the AMNH and it was briefly described in 1899 by Osborn, who referred it to D. longus. It was later mounted—the first Diplodocus mount made—and was the first well preserved individual skeleton of Diplodocus discovered.[4][31] In Emmanuel Tschopp et al.'s phylogenetic analysis of Diplodocidae, AMNH FR 223 was found to be not a skeleton of D. longus, but the later named species D. hallorum.[4]

The most notable Diplodocus find also came in 1899, when crew members from the Carnegie Museum of Natural History were collecting fossils in the Morrison Formation of Sheep Creek, Wyoming, with funding from Scottish-American steel tycoon Andrew Carnegie, they discovered a massive and well preserved skeleton of Diplodocus.[38] The skeleton was collected that year by Jacob L. Wortman and several other crewmen under his direction along with several specimens of Stegosaurus, Brontosaurus parvus, and Camarasaurus preserved alongside the skeleton.[38] The skeleton (CM 84) was preserved in semi articulation and was very complete, including 41 well preserved vertebrae from the mid caudals to the anterior cervicals, 18 ribs, 2 sternal ribs, a partial pelvis, right scapulocoracoid, and right femur. In 1900, Carnegie crews returned to Sheep Creek, this expedition led by John Bell Hatcher, William Jacob Holland, and Charles Gilmore, and discovered another well preserved skeleton of Diplodocus adjacent to the specimen collected in 1899.[4][38] The second skeleton (CM 94) was from a smaller individual and had preserved fewer vertebrae, but preserved more caudal vertebrae and appendicular remains than CM 84.[38][4] Both of the skeletons were named and described in great detail by John Bell Hatcher in 1901, with Hatcher making CM 84 the type specimen of a new species of Diplodocus, Diplodocus carnegii ("Andrew Carnegie's double beam"),[4][38] with CM 94 becoming the paratype.[38]

It wasn't until 1907, that the Carnegie Museum of Natural History created a composite mount of Diplodocus carnegii that incorporated CM 84 and CM 94 along with several other specimens and even other taxa were used to complete the mount, including a skull molded based on USNM 2673, a skull assigned to Galeamopus pabsti.[39][4] The Carnegie Museum mount became very popular, being nicknamed "Dippy" by the populace, eventually being cast and sent to museums in London, Berlin, Paris, Vienna, Bologna, St. Petersburg, Buenos Aires, Madrid, and Mexico City from 1905 to 1928.[40] The London cast specifically became very popular; its casting was requested by King Edward VII and it was the first sauropod mount put on display outside of the United States.[40] The goal of Carnegie in sending these casts overseas was apparently to bring international unity and mutual interest around the discovery of the dinosaur.[41]

Dinosaur National Monument

The Carnegie Museum of Natural History made another landmark discovery in 1909 when Earl Douglass unearthed several caudal vertebrae from Apatosaurus in what is now Dinosaur National Monument on the border region between Colorado and Utah, with the sandstone dating to the Kimmeridgian of the Morrison Formation. From 1909 to 1922, with the Carnegie Museum excavating the quarry, eventually unearthing over 120 dinosaur individuals and 1,600+ bones, many of the associated skeletons being very complete and are on display in several American museums. In 1912, Douglass found a semi articulated skull of a diplodocine with mandibles (CM 11161) in the Monument. Another skull (CM 3452) was found by Carnegie crews in 1915, bearing 6 articulated cervical vertebrae and mandibles, and another skull with mandibles (CM 1155) was found in 1923. All of the skulls found at Dinosaur National Monument were shipped back to Pittsburgh and described by William Jacob Holland in detail in 1924, who referred the specimens to D. longus.[42] This assignment was also questioned by Tschopp, who stated that all of the aforementioned skulls could not be referred to any specific diplodocine. Hundreds of assorted postcranial elements were found in the Monument that have been referred to Diplodocus, but few have been properly described.[4] A nearly complete skull of a juvenile Diplodocus was collected by Douglass in 1921, and it is the first known from a Diplodocus.[43]

Another Diplodocus skeleton was collected at the Carnegie Quarry in Dinosaur National Monument, Utah, by the National Museum of Natural History in 1923. The skeleton (USNM V 10865) is one of the most complete known from Diplodocus, consisting of a semi-articulated partial postcranial skeleton, including a well preserved dorsal column. The skeleton was briefly described by Charles Gilmore in 1932, who also referred it to D. longus, and it was mounted in the fossil hall at the National Museum of Natural History the same year. In Emmanuel Tschopp et al.'s phylogenetic analysis of Diplodocidae, USNM V 10865 was also found to be an individual of D. hallorum.[4][44]

Hatcher's original composite skeletal reconstruction of Diplodocus carnegii, 1901.

The Denver Museum of Nature and Science also collected a Diplodocus specimen in Dinosaur National Monument, a partial postcranial skeleton including cervical vertebrae, that was later mounted in the museum. Although not described in detail, Tschopp and colleagues determined that this skeleton also belonged to D. hallorum.[4]

Recent discoveries and Diplodocus hallorum

Few Diplodocus finds came for many years until 1979, when three hikers came across several vertebrae stuck in elevated stone next to several petroglyphs in a canyon west of San Ysidro, New Mexico. The find was reported to the New Mexican Museum of Natural History, who dispatched an expedition led by David D. Gillette in 1985, that collected the specimen after several visits from 1985 to 1990. The specimen was preserved in semi-articulation, including 230 gastroliths, with several vertebrae, partial pelvis, and right femur and was prepared and deposited at the New Mexican Museum of Natural History under NMMNH P-3690. The specimen was not described until 1991 in the Journal of Paleontology, where Gillette named it Seismosaurus halli (Jim and Ruth Hall's seismic lizard), though in 1994, Gillette published an amendment changing the name to S. hallorum.[11][45] In 2004 and later 2006, Seismosaurus was synonymized with Diplodocus and even suggested to be synonymous with the dubious D. longus and later Tschopp et al.'s phylogenetic analysis in 2015 supported the idea that many specimens referred to D. longus actually belonged to D. hallorum.[4]

In 1994, the Museum of the Rockies discovered a very productive fossil site at Mother's Day Quarry in Carbon County, Montana from the Salt Wash member of the Morrison Formation that was later excavated by the Cincinnati Museum of Natural History and Science in 1996, and after that the Bighorn Basin Paleontological Institute in 2017. The quarry was very productive, having mostly isolated Diplodocus bones from juveniles to adults in pristine preservation. The quarry notably had a great disparity between the amount of juveniles and adults in the quarry, as well as the frequent preservation of skin impressions, pathologies, and some articulated specimens from Diplodocus.[45][28] One specimen, a nearly complete skull of a juvenile Diplodocus, was found at the quarry and is one of few known and highlighted ontogenetic dietary changes in the genus.[46]

Classification and species

Phylogeny

Diplodocus is both the type genus of, and gives its name to, the Diplodocidae, the family in which it belongs.[35] Members of this family, while still massive, have a markedly more slender build than other sauropods, such as the titanosaurs and brachiosaurs. All are characterized by long necks and tails and a horizontal posture, with forelimbs shorter than hind limbs. Diplodocids flourished in the Late Jurassic of North America and possibly Africa.[16]

A subfamily, the Diplodocinae, was erected to include Diplodocus and its closest relatives, including Barosaurus. More distantly related is the contemporaneous Apatosaurus, which is still considered a diplodocid, although not a diplodocine, as it is a member of the sister subfamily Apatosaurinae.[47][48] The Portuguese Dinheirosaurus and the African Tornieria have also been identified as close relatives of Diplodocus by some authors.[49][50] Diplodocoidea comprises the diplodocids, as well as the dicraeosaurids, rebbachisaurids, Suuwassea,[47][48] Amphicoelias[50] possibly Haplocanthosaurus,[51] and/or the nemegtosaurids.[52] The clade is the sister group to Macronaria (camarasaurids, brachiosaurids and titanosaurians).[51][52]

A Cladogram of the Diplodocidae after Tschopp, Mateus, and Benson (2015) below:[4]

Diplodocus sp. skeleton nicknamed "Misty", Zoological Museum of Copenhagen
Diplodocidae

Amphicoelias altus

Apatosaurinae

Unnamed species

Apatosaurus ajax

Apatosaurus louisae

Brontosaurus excelsus

Brontosaurus yahnahpin

Brontosaurus parvus

Diplodocinae

Unnamed species

Tornieria africana

Supersaurus lourinhanensis

Supersaurus vivianae

Leinkupal laticauda

Galeamopus hayi

Diplodocus carnegii

Diplodocus hallorum

Kaatedocus siberi

Barosaurus lentus

Valid species

  • D. carnegii (also spelled D. carnegiei), named after Andrew Carnegie, is the best known, mainly due to a near-complete skeleton known as Dippy (specimen CM 84) collected by Jacob Wortman, of the Carnegie Museum of Natural History in Pittsburgh, Pennsylvania, and described and named by John Bell Hatcher in 1901.[53] It was reconsidered as the type species for Diplodocus.[33]
  • D. hallorum, first described in 1991 by Gillette as Seismosaurus halli from a partial skeleton comprising vertebrae, pelvis and ribs (specimen NMMNH P-3690).[54] As the specific name honors two people, Jim and Ruth Hall (of Ghost Ranch[55]), George Olshevsky later suggested to emend the name as S. hallorum, using the mandatory genitive plural; Gillette then emended the name,[11] which usage has been followed by others, including Carpenter (2006).[12] In 2004, a presentation at the annual conference of the Geological Society of America made a case for Seismosaurus being a junior synonym of Diplodocus.[56] This was followed by a much more detailed publication in 2006, which not only renamed the species Diplodocus hallorum, but also speculated that it could prove to be the same as D. longus.[57] The position that D. hallorum should be regarded as a specimen of D. longus was also taken by the authors of a redescription of Supersaurus, refuting a previous hypothesis that Seismosaurus and Supersaurus were the same.[58] A 2015 analysis of diplodocid relationships noted that these opinions are based on the more complete referred specimens of D. longus. The authors of this analysis concluded that those specimens were indeed the same species as D. hallorum, but that D. longus itself was a nomen dubium.[4]
    Skeletal reconstruction of D. carnegii specimens CM 84 and CM 94, with missing portions reconstructed after other diplodocids

Nomina dubia (doubtful species)

USNM 2672, a skull formerly thought to have belonged to the holotype of D. longus
  • D. longus, the type species, is known from two complete and several fragmentary caudal vertebrae from the Morrison Formation (Felch Quarry) of Colorado. Though several more complete specimens have been attributed to D. longus,[32] detailed analysis has suggested that the original fossil lacks the necessary features to allow comparison with other specimens. For this reason, it has been considered a nomen dubium, which Tschopp et al. regarded as not an ideal situation for the type species of a well-known genus like Diplodocus. A petition to the International Commission on Zoological Nomenclature (ICZN) was being considered, which proposed to make D. carnegii the new type species.[4][33] The proposal was rejected by the ICZN and D. longus has been maintained as the type species.[34] However, in comments responding to the petition, some authors regarded D. longus as potentially valid after all.[59][60]
  • D. lacustris ("of the lake") is a nomen dubium named by Marsh in 1884 based on specimen YPM 1922 found by Arthur Lakes, consisting of the snout and upper jaw of a smaller animal from Morrison, Colorado.[35] The remains are now believed to have been from an immature animal, rather than from a separate species.[61] Mossbrucker et al., 2013 surmised that the dentary and teeth of Diplodocus lacustris was actually from Apatosaurus ajax.[62] Later in 2015, it was concluded that the snout of the specimen actually belonged to Camarasaurus.[4]

Formerly assigned species

  • Diplodocus hayi was named by William Jacob Holland in 1924 based on a braincase and partial postcranial skeleton (HMNS 175), including a nearly complete vertebral column, found in the Morrison Formation strata near Sheridan, Wyoming.[4][42] D. hayi remained a species of Diplodocus until reassessment by Emmanuel Tschopp and colleagues determined that it was its own genus, Galeamopus, in 2015. The reassessment also found that the skulls AMNH 969 and USNM 2673 were not Diplodocus either and actually referred specimens of Galeamopus.[4]

Paleobiology

Restoration of D. hallorum in environment

Due to a wealth of skeletal remains, Diplodocus is one of the best-studied dinosaurs. Many aspects of its lifestyle have been subjects of various theories over the years.[20] Comparisons between the scleral rings of diplodocines and modern birds and reptiles suggest that they may have been cathemeral, active throughout the day at short intervals.[63]

Marsh and then Hatcher[38] assumed that the animal was aquatic, because of the position of its nasal openings at the apex of the cranium. Similar aquatic behavior was commonly depicted for other large sauropods, such as Brachiosaurus and Apatosaurus. A 1951 study by Kenneth A. Kermack indicates that sauropods probably could not have breathed through their nostrils when the rest of the body was submerged, as the water pressure on the chest wall would be too great.[64] Since the 1970s, general consensus has the sauropods as firmly terrestrial animals, browsing on trees, ferns, and bushes.[65]

Scientists have debated as to how sauropods were able to breathe with their large body sizes and long necks, which would have increased the amount of dead space. They likely had an avian respiratory system, which is more efficient than a mammalian and reptilian system. Reconstructions of the neck and thorax of Diplodocus show great pneumaticity, which could have played a role in respiration as it does in birds.[66]

Posture

An outmoded depiction by Oliver P. Hay (1910), with sprawled limbs[67]

The depiction of Diplodocus posture has changed considerably over the years. For instance, a classic 1910 reconstruction by Oliver P. Hay depicts two Diplodocus with splayed lizard-like limbs on the banks of a river. Hay argued that Diplodocus had a sprawling, lizard-like gait with widely splayed legs,[68] and was supported by Gustav Tornier. This hypothesis was contested by William Jacob Holland, who demonstrated that a sprawling Diplodocus would have needed a trench through which to pull its belly.[69] Finds of sauropod footprints in the 1930s eventually put Hay's theory to rest.[65]

Upright neck pose for D. carnegii based on Taylor et al. (2009)
A reconstruction of the neck ligament structure from a Diplodocus. The depiction of the entire neck seen in C and D shows where the possible elastic and supraspinal ligaments in addition to muscle groups could have been located.[70]

Later, diplodocids were often portrayed with their necks held high up in the air, allowing them to graze from tall trees. Studies looking at the morphology of sauropod necks have concluded that the neutral posture of Diplodocus neck was close to horizontal, rather than vertical, and scientists such as Kent Stevens have used this to argue that sauropods including Diplodocus did not raise their heads much above shoulder level.[71][72] A nuchal ligament may have held the neck in this position.[71] One approach to understanding the possible ligament structure in ancient sauropods is by studying the ligaments and their attachments to bones in extant animals to see if they resemble any bony structures in sauropods or other dinosaur species like Parasaurolophus.[73] If diplodocus relied on a mammal-like nuchal ligament, it would have been for passively sustaining the weight of its head and neck. This ligament is found in many hoofed mammals, such as bison and horses. In mammals, it typically consists of a funiculus cord that runs from the external occipital crest of the skull to elongate vertebral neural spines or “withers” in the shoulder region plus sheet-like extensions called laminae run from the cord to the neural spines on some or all of the cervical vertebrae. However, most sauropods do not have withers in the shoulders, so if they possessed a similar ligament, it would differ substantially, perhaps anchoring in the hip region.[74] [75]Another hypothesized neck-supporting ligament is an avian-like elastic ligament, such as that seen in Struthio camelus.[76][77] This ligament acts similarly to the mammal-like nuchal ligament but comprises short segments of ligament that connect the bases of the neural spines, and therefore does not need a robust attachment zone like those seen in mammals. A 2009 study found that all tetrapods appear to hold the base of their necks at the maximum possible vertical extension when in a normal, alert posture, and argued that the same would hold true for sauropods barring any unknown, unique characteristics that set the soft tissue anatomy of their necks apart from other animals. The study found faults with Stevens' assumptions regarding the potential range of motion in sauropod necks, and based on comparing skeletons to living animals the study also argued that soft tissues could have increased flexibility more than the bones alone suggest. For these reasons they argued that Diplodocus would have held its neck at a more elevated angle than previous studies have concluded.[78]

As with the related genus Barosaurus, the very long neck of Diplodocus is the source of much controversy among scientists. A 1992 Columbia University study of diplodocid neck structure indicated that the longest necks would have required a 1.6-ton heart – a tenth of the animal's body weight. The study proposed that animals like these would have had rudimentary auxiliary "hearts" in their necks, whose only purpose was to pump blood up to the next "heart".[6] Some argue that the near-horizontal posture of the head and neck would have eliminated the problem of supplying blood to the brain, as it would not be elevated.[23]

Diet and feeding

Cast of a diplodocid skull that may belong to a species of Diplodocus (CM 11161)

Diplodocines have highly unusual teeth compared to other sauropods. The crowns are long and slender, and elliptical in cross-section, while the apex forms a blunt, triangular point. The most prominent wear facet is on the apex, though unlike all other wear patterns observed within sauropods, diplodocine wear patterns are on the labial (cheek) side of both the upper and lower teeth.[22] This implies that the feeding mechanism of Diplodocus and other diplodocids was radically different from that of other sauropods. Unilateral branch stripping is the most likely feeding behavior of Diplodocus,[79][80][81] as it explains the unusual wear patterns of the teeth (coming from tooth–food contact). In unilateral branch stripping, one tooth row would have been used to strip foliage from the stem, while the other would act as a guide and stabilizer. With the elongated preorbital (in front of the eyes) region of the skull, longer portions of stems could be stripped in a single action. Also, the palinal (backwards) motion of the lower jaws could have contributed two significant roles to feeding behavior: (1) an increased gape, and (2) allowed fine adjustments of the relative positions of the tooth rows, creating a smooth stripping action.[22]

Young et al. (2012) used biomechanical modeling to examine the performance of the diplodocine skull. It was concluded that the proposal that its dentition was used for bark-stripping was not supported by the data, which showed that under that scenario, the skull and teeth would undergo extreme stresses. The hypotheses of branch-stripping and/or precision biting were both shown to be biomechanically plausible feeding behaviors.[82] Diplodocine teeth were also continually replaced throughout their lives, usually in less than 35 days, as was discovered by Michael D'Emic et al. Within each tooth socket, as many as five replacement teeth were developing to replace the next one. Studies of the teeth also reveal that it preferred different vegetation from the other sauropods of the Morrison, such as Camarasaurus. This may have better allowed the various species of sauropods to exist without competition.[83]

Diplodocus (green) and various sauropods in a tripodal posture; The white dots showing the approximate center of mass, as estimated in studies.

The flexibility of Diplodocus neck is debated but it should have been able to browse from low levels to about 4 m (13 ft) when on all fours.[23][71] However, studies have shown that the center of mass of Diplodocus was very close to the hip socket;[84][85] this means that Diplodocus could rear up into a bipedal posture with relatively little effort. It also had the advantage of using its large tail as a 'prop' which would allow for a very stable tripodal posture. In a tripodal posture Diplodocus could potentially increase its feeding height up to about 11 m (36 ft).[85][86]

The neck's range of movement would have also allowed the head to graze below the level of the body, leading some scientists to speculate on whether Diplodocus grazed on submerged water plants, from riverbanks. This concept of the feeding posture is supported by the relative lengths of front and hind limbs. Furthermore, its peg-like teeth may have been used for eating soft water plants.[71] Matthew Cobley et al. (2013) disputed this, finding that large muscles and cartilage would have limited neck movements. They state that the feeding ranges for sauropods like Diplodocus were smaller than previously believed and the animals may have had to move their whole bodies around to better access areas where they could browse vegetation. As such, they might have spent more time foraging to meet their minimum energy needs.[87][88] The conclusions of Cobley et al. were disputed in 2013 and 2014 by Mike Taylor, who analyzed the amount and positioning of intervertebral cartilage to determine the flexibility of the neck of Diplodocus and Apatosaurus. Taylor found that the neck of Diplodocus was very flexible, and that Cobley et al. was incorrect, in that flexibility as implied by bones is less than in reality.[89]

In 2010, Whitlock et al. described a juvenile skull at the time referred to Diplodocus (CM 11255) that differed greatly from adult skulls of the same genus: its snout was not blunt, and the teeth were not confined to the front of the snout. These differences suggest that adults and juveniles were feeding differently. Such an ecological difference between adults and juveniles had not been previously observed in sauropodomorphs.[90]

Reproduction and growth

Restoration of a narrow snouted juvenile (based on the "Andrew" specimen CMC VP14128) feeding alongside broad snouted adults

While the long neck has traditionally been interpreted as a feeding adaptation, it was also suggested[91] that the oversized neck of Diplodocus and its relatives may have been primarily a sexual display, with any other feeding benefits coming second. A 2011 study refuted this idea in detail.[92]

While no evidence indicates Diplodocus nesting habits, other sauropods, such as the titanosaurian Saltasaurus, have been associated with nesting sites.[93][94] The titanosaurian nesting sites indicate that they may have laid their eggs communally over a large area in many shallow pits, each covered with vegetation. Diplodocus may have done the same. The documentary Walking with Dinosaurs portrayed a mother Diplodocus using an ovipositor to lay eggs, but it was pure speculation on the part of the documentary author.[26] For Diplodocus and other sauropods, the size of clutches and individual eggs were surprisingly small for such large animals. This appears to have been an adaptation to predation pressures, as large eggs would require greater incubation time and thus would be at greater risk.[95]

Based on a number of bone histology studies, Diplodocus, along with other sauropods, grew at a very fast rate, reaching sexual maturity at just over a decade, and continuing to grow throughout their lives.[96][97][98]

Paleoecology

Restoration of two D. longus

The Morrison Formation is a sequence of shallow marine and alluvial sediments which, according to radiometric dating, ranges between 156.3 million years old (Ma) at its base,[99] and 146.8 million years old at the top,[100] which places it in the late Oxfordian, Kimmeridgian, and early Tithonian stages of the Late Jurassic period. This formation is interpreted as a semi-arid environment with distinct wet and dry seasons. The Morrison Basin, where many dinosaurs lived, stretched from New Mexico to Alberta and Saskatchewan, and was formed when the precursors to the Front Range of the Rocky Mountains started pushing up to the west. The deposits from their east-facing drainage basins were carried by streams and rivers and deposited in swampy lowlands, lakes, river channels, and floodplains.[101] This formation is similar in age to the Lourinha Formation in Portugal and the Tendaguru Formation in Tanzania.[102]

Saurophaganax and D. hallorum, New Mexico Museum of Natural History and Science

The Morrison Formation records an environment and time dominated by gigantic sauropod dinosaurs.[103] Dinosaurs known from the Morrison include the theropods Ceratosaurus, Koparion, Stokesosaurus, Ornitholestes, Allosaurus and Torvosaurus, the sauropods Brontosaurus, Apatosaurus, Brachiosaurus, Camarasaurus, and the ornithischians Camptosaurus, Dryosaurus, Othnielia, Gargoyleosaurus and Stegosaurus.[104] Diplodocus is commonly found at the same sites as Apatosaurus, Allosaurus, Camarasaurus, and Stegosaurus.[105] Allosaurus accounted for 70 to 75% of theropod specimens and was at the top trophic level of the Morrison food web.[106] Many of the dinosaurs of the Morrison Formation are the same genera as those seen in Portuguese rocks of the Lourinha Formation (mainly Allosaurus, Ceratosaurus, Torvosaurus, and Stegosaurus), or have a close counterpart (Brachiosaurus and Lusotitan; Camptosaurus and Draconyx).[102] Other vertebrates that shared the same paleoenvironment included ray-finned fishes, frogs, salamanders, turtles like Dorsetochelys, sphenodonts, lizards, terrestrial and aquatic crocodylomorphs such as Hoplosuchus, and several species of pterosaur like Harpactognathus and Mesadactylus. Shells of bivalves and aquatic snails are also common. The flora of the period was green algae, fungi, mosses, horsetails, cycads, ginkgoes, and several families of conifers. Vegetation varied from river-lining forests of tree ferns and ferns (gallery forests), to fern savannas with occasional trees such as the Araucaria-like conifer Brachyphyllum.[12]

Cultural significance

"Dippy", the first replica of D. carnegii at the Natural History Museum
Holland's D. carnegii cast in the French National Museum of Natural History, in Paris, much as it was in 1908
D. carnegii cast in Berlin, Germany, unveiled in 1908

Diplodocus has been a famous and much-depicted dinosaur as it has been on display in more places than any other sauropod dinosaur.[107] Much of this has probably been due to its wealth of skeletal remains and former status as the longest dinosaur.

The donation of many mounted skeletal casts of "Dippy" by industrialist Andrew Carnegie to potentates around the world at the beginning of the 20th century[108] did much to familiarize it to people worldwide. Casts of Diplodocus skeletons are still displayed in many museums worldwide, including D. carnegii in a number of institutions.[65]

The project, along with its association with 'big science', philanthropism, and capitalism, drew much public attention in Europe. The German satirical weekly Kladderadatsch devoted a poem to the dinosaur:

Auch ein viel älterer Herr noch muß
Den Wanderburschen spielen
Er ist genannt Diplodocus
und zählt zu den Fossilen
Herr Carnegie verpackt ihn froh
In riesengroße Archen
Und schickt als Geschenk ihn so
An mehrere Monarchen[109]
But even a much older gent
Sees itself forced to wander
He goes by the name Diplodocus
And belongs among the fossils
Mr. Carnegie packs him joyfully
Into giant arks
And sends him as gift
To several monarchs

"Le diplodocus" became a generic term for sauropods in French, much as "brontosaur" is in English.[110]

D. longus is displayed the Senckenberg Museum in Frankfurt (a skeleton made up of several specimens, donated in 1907 by the American Museum of Natural History), Germany.[111][112] A mounted and more complete skeleton of D. longus is at the Smithsonian National Museum of Natural History in Washington, DC,[113] while a mounted skeleton of D. hallorum (formerly Seismosaurus), which may be the same as D. longus, can be found at the New Mexico Museum of Natural History and Science.[114]

A war machine (landship) from WW1 named Boirault machine was designed in 1915, later deemed impractical and hence given a nickname "Diplodocus militaris".[115]

References

  1. 1.0 1.1 1.2 Simpson, John, ed (1989). The Oxford English Dictionary (2nd ed.). Oxford: Oxford University Press. ISBN 978-0-19-861186-8. 
  2. 2.0 2.1 Pickett, Joseph P., ed (2000). The American Heritage Dictionary of the English Language (4th ed.). Boston: Houghton Mifflin Company. ISBN 978-0-395-82517-4. 
  3. "diplodocus". Online Etymology Dictionary. http://www.etymonline.com/index.php?term=diplodocus&allowed_in_frame=0. 
  4. 4.00 4.01 4.02 4.03 4.04 4.05 4.06 4.07 4.08 4.09 4.10 4.11 4.12 4.13 4.14 4.15 4.16 4.17 4.18 4.19 Tschopp, E.; Mateus, O. V.; Benson, R. B. J. (2015). "A specimen-level phylogenetic analysis and taxonomic revision of Diplodocidae (Dinosauria, Sauropoda)". PeerJ 3: e857. doi:10.7717/peerj.857. PMID 25870766. 
  5. Turner, C.E.; Peterson, F. (2004). "Reconstruction of the Upper Jurassic Morrison Formation extinct ecosystem—a synthesis". Sedimentary Geology 167 (3–4): 309–355. doi:10.1016/j.sedgeo.2004.01.009. Bibcode2004SedG..167..309T. http://doc.rero.ch/record/14577/files/PAL_E1793.pdf. 
  6. 6.0 6.1 6.2 Lambert D. (1993). The Ultimate Dinosaur Book. DK Publishing. ISBN 978-0-86438-417-1. 
  7. 7.0 7.1 7.2 7.3 Paul, Gregory S. (2016). Princeton Field Guide to Dinosaurs: 2nd Edition. Princeton University Press. ISBN 978-0-691-16766-4. https://archive.org/details/princetonfieldgu0000paul. 
  8. 8.0 8.1 8.2 Molina-Perez & Larramendi (2020). Dinosaur Facts and Figures: The Sauropods and Other Sauropodomorphs. New Jersey: Princeton University Press. pp. 257. Bibcode2020dffs.book.....M. 
  9. Foster, J.R. (2003). Paleoecological Analysis of the Vertebrate Fauna of the Morrison Formation (Upper Jurassic), Rocky Mountain Region, U.S.A. New Mexico Museum of Natural History and Science:Albuquerque, New Mexico. Bulletin 23.
  10. Holtz, Thomas R. Jr.; Rey, Luis V. (2011). Dinosaurs: the most complete, up-to-date encyclopedia for dinosaur lovers of all ages (Winter 2011 appendix). New York: Random House. ISBN 978-0-375-82419-7. https://archive.org/details/dinosaursmostcom00holt. 
  11. 11.0 11.1 11.2 Gillette, D.D., 1994, Seismosaurus: The Earth Shaker. New York, Columbia University Press, 205 pp
  12. 12.0 12.1 12.2 12.3 12.4 Carpenter, Kenneth (2006). "Biggest of the big: a critical re-evaluation of the mega-sauropod Amphicoelias fragillimus". in Foster, John R.. Paleontology and Geology of the Upper Jurassic Morrison Formation. New Mexico Museum of Natural History and Science Bulletin, 36. Albuquerque, New Mexico: New Mexico Museum of Natural History and Science. pp. 131–138. https://books.google.com/books?id=qKjECQAAQBAJ&pg=PA131. 
  13. Herne, Matthew C.; Lucas, Spencer G. (2006). "Seismosaurus hallorum: Osteological reconstruction from the holotype". New Mexico Museum of Natural History and Science Bulletin 36. 
  14. "The biggest of the big". Skeletaldrawing.com. June 14, 2013. http://www.skeletaldrawing.com/home/2013/06/the-biggest-of-big.html?rq=diplodocus. 
  15. Wedel, M.J. and Cifelli, R.L. Sauroposeidon: Oklahoma's Native Giant. 2005. Oklahoma Geology Notes 65:2.
  16. 16.0 16.1 Wilson JA (2005). "Overview of Sauropod Phylogeny and Evolution". The Sauropods:Evolution and Paleobiology. Indiana University Press. pp. 15–49. ISBN 978-0-520-24623-2. 
  17. Holland WJ (1915). "Heads and Tails: a few notes relating to the structure of sauropod dinosaurs". Annals of the Carnegie Museum 9 (3–4): 273–278. doi:10.5962/p.331052. 
  18. "Supersonic sauropods? Tail dynamics in the diplodocids". Paleobiology 23 (4): 393–409. 1997. doi:10.1017/s0094837300019801. Bibcode1997Pbio...23..393M. http://doc.rero.ch/record/15579/files/PAL_E1438.pdf. 
  19. Baron, Matthew G. (October 3, 2021). "Tactile tails: a new hypothesis for the function of the elongate tails of diplodocid sauropods". Historical Biology 33 (10): 2057–2066. doi:10.1080/08912963.2020.1769092. ISSN 0891-2963. Bibcode2021HBio...33.2057B. https://doi.org/10.1080/08912963.2020.1769092. 
  20. 20.0 20.1 Benton, Michael J. (2012). Prehistoric Life. Dorling Kindersley. pp. 268–269. ISBN 978-0-7566-9910-9. 
  21. Bonnan, M. F. (2003). "The evolution of manus shape in sauropod dinosaurs: implications for functional morphology, forelimb orientation, and phylogeny". Journal of Vertebrate Paleontology 23 (3): 595–613. doi:10.1671/A1108. Bibcode2003JVPal..23..595B. http://doc.rero.ch/record/15172/files/PAL_E2447.pdf. 
  22. 22.0 22.1 22.2 Upchurch, P.; Barrett, P.M. (2000). "The evolution of sauropod feeding mechanism". in Sues, Hans Dieter. Evolution of Herbivory in Terrestrial Vertebrates. Cambridge University Press. ISBN 978-0-521-59449-3. 
  23. 23.0 23.1 23.2 Stevens, K.A.; Parrish, J.M. (1999). "Neck posture and feeding habits of two Jurassic sauropod dinosaurs". Science 284 (5415): 798–800. doi:10.1126/science.284.5415.798. PMID 10221910. Bibcode1999Sci...284..798S. 
  24. 24.0 24.1 Czerkas, S. A. (1993). "Discovery of dermal spines reveals a new look for sauropod dinosaurs". Geology 20 (12): 1068–1070. doi:10.1130/0091-7613(1992)020<1068:dodsra>2.3.co;2. Bibcode1992Geo....20.1068C. 
  25. Czerkas, S. A. (1994). "The history and interpretation of sauropod skin impressions." In Aspects of Sauropod Paleobiology (M. G. Lockley, V. F. dos Santos, C. A. Meyer, and A. P. Hunt, Eds.), Gaia No. 10. (Lisbon, Portugal).
  26. 26.0 26.1 Haines, T., James, J. Time of the Titans . ABC Online.
  27. Tschopp, E.; Mateus, O. V. (2012). "The skull and neck of a new flagellicaudatan sauropod from the Morrison Formation and its implication for the evolution and ontogeny of diplodocid dinosaurs". Journal of Systematic Palaeontology 11 (7): 1. doi:10.1080/14772019.2012.746589. 
  28. 28.0 28.1 Gallagher, T; Poole, J; Schein, J (2021). "Evidence of integumentary scale diversity in the late Jurassic Sauropod Diplodocus sp. from the Mother's Day Quarry, Montana". PeerJ 9: e11202. doi:10.7717/peerj.11202. PMID 33986987. 
  29. Marsh OC (1878). "Principal characters of American Jurassic dinosaurs. Part I". American Journal of Science 3 (95): 411–416. doi:10.2475/ajs.s3-16.95.411. 
  30. 30.0 30.1 30.2 Brinkman, P. D. (2010). The second Jurassic dinosaur rush. University of Chicago Press.
  31. 31.0 31.1 Osborn, H. F. (1899). A skeleton of Diplodocus, recently mounted in the American Museum. Science, 10(259), 870-874.
  32. 32.0 32.1 "Sauropoda". The Dinosauria (2nd ed.). University of California Press. 2004. p. 305. ISBN 978-0-520-24209-8. 
  33. 33.0 33.1 33.2 Tschopp, E.; Mateus, O. (2016). "Diplodocus Marsh, 1878 (Dinosauria, Sauropoda): proposed designation of D. carnegii Hatcher, 1901 as the type species". Bulletin of Zoological Nomenclature 73 (1): 17–24. doi:10.21805/bzn.v73i1.a22. 
  34. 34.0 34.1 ICZN. (2018). "Opinion 2425 (Case 3700) – Diplodocus Marsh, 1878 (Dinosauria, Sauropoda): Diplodocus longus Marsh, 1878 maintained as the type species". Bulletin of Zoological Nomenclature 75 (1): 285–287. doi:10.21805/bzn.v75.a062. 
  35. 35.0 35.1 35.2 Marsh, O.C. (1884). "Principal characters of American Jurassic dinosaurs. Part VII. On the Diplodocidae, a new family of the Sauropoda". American Journal of Science 3 (158): 160–168. doi:10.2475/ajs.s3-27.158.161. Bibcode1884AmJS...27..161M. https://zenodo.org/record/2341943. 
  36. McIntosh, J. S., & Carpenter, K. (1998). THE HOLOTYPE OF DIPLODOCUS LONGUS, WITH COMMENTS ON OTHER SPECIMENS. Modern Geology, 23, 85-110.
  37. Marsh, O. C. (1896). The dinosaurs of North America. US Government Printing Office.
  38. 38.0 38.1 38.2 38.3 38.4 38.5 38.6 Hatcher, J. B. (1901). Diplodocus (Marsh): its osteology, taxonomy, and probable habits, with a restoration of the skeleton (Vol. 1, No. 1-4). Carnegie institute.
  39. Tschopp, Emanuel; Mateus, Octávio (May 2, 2017). "Osteology of Galeamopus pabsti sp. nov. (Sauropoda: Diplodocidae), with implications for neurocentral closure timing, and the cervico-dorsal transition in diplodocids" (in en). PeerJ 5: e3179. doi:10.7717/peerj.3179. ISSN 2167-8359. PMID 28480132. 
  40. 40.0 40.1 Otero, Alejandro; Gasparini, Zulma (2014). "The History of the Cast Skeleton of Diplodocus carnegii Hatcher, 1901, at the Museo De La Plata, Argentina" (in en). Annals of Carnegie Museum 82 (3): 291–304. doi:10.2992/007.082.0301. ISSN 0097-4463. http://www.bioone.org/doi/abs/10.2992/007.082.0301. 
  41. McCall, Chris (January 22, 2019). "Dippy, 'the UK's most famous dinosaur', arrives at Kelvingrove Museum". The Scotsman. https://www.scotsman.com/lifestyle/dippy-the-uk-s-most-famous-dinosaur-arrives-at-kelvingrove-museum-1-4860574. 
  42. 42.0 42.1 Holland WJ. (1924) The skull of Diplodocus. Memoirs of the Carnegie Museum IX; 379–403.
  43. Whitlock, John A.; Wilson, Jeffrey A.; Lamanna, Matthew C. (March 24, 2010). "Description of a nearly complete juvenile skull of Diplodocus (Sauropoda: Diplodocoidea) from the Late Jurassic of North America". Journal of Vertebrate Paleontology 30 (2): 442–457. doi:10.1080/02724631003617647. ISSN 0272-4634. Bibcode2010JVPal..30..442W. https://doc.rero.ch/record/31560/files/PAL_E598.pdf. 
  44. Gilmore, Charles W. (1932). "On a newly mounted skeleton of Diplodocus in the United States National Museum". Proceedings of the United States National Museum 81 (2941): 1–21. doi:10.5479/si.00963801.81-2941.1. ISSN 0096-3801. https://repository.si.edu/bitstream/handle/10088/16065/1/USNMP-81_2941_1932.pdf. 
  45. 45.0 45.1 Schein, J. P., Poole, J. C., Schmidt, R. W., & Rooney, L. (2019). Reopening the Mother’s Day Quarry (Jurassic Morrison Formation, Montana) is yielding new information. In Geological Society of America–Annual Meeting, Arizona (pp. 22-25).
  46. Woodruff, D. C., Carr, T. D., Storrs, G. W., Waskow, K., Scannella, J. B., Nordén, K. K., & Wilson, J. P. (2018). The smallest diplodocid skull reveals cranial ontogeny and growth-related dietary changes in the largest dinosaurs. Scientific reports, 8(1), 1-12.
  47. 47.0 47.1 Taylor, M.P.; Naish, D. (2005). "The phylogenetic taxonomy of Diplodocoidea (Dinosauria: Sauropoda)". PaleoBios 25 (2): 1–7. ISSN 0031-0298. 
  48. 48.0 48.1 Harris, J.D. (2006). "The significance of Suuwassea emiliae (Dinosauria: Sauropoda) for flagellicaudatan intrarelationships and evolution". Journal of Systematic Palaeontology 4 (2): 185–198. doi:10.1017/S1477201906001805. Bibcode2006JSPal...4..185H. 
  49. Bonaparte, J.F.; Mateus, O. (1999). "A new diplodocid, Dinheirosaurus lourinhanensis gen. et sp. nov., from the Late Jurassic beds of Portugal". Revista del Museo Argentino de Ciencias Naturales 5 (2): 13–29. http://www.lusodinos.dinodata.org/index.php?option=com_content&task=category&sectionid=8&id=20&Itemid=29. Retrieved June 13, 2013. 
  50. 50.0 50.1 Rauhut, O.W.M.; Remes, K.; Fechner, R.; Cladera, G.; Puerta, P. (2005). "Discovery of a short-necked sauropod dinosaur from the Late Jurassic period of Patagonia". Nature 435 (7042): 670–672. doi:10.1038/nature03623. PMID 15931221. Bibcode2005Natur.435..670R. 
  51. 51.0 51.1 Wilson, J. A. (2002). "Sauropod dinosaur phylogeny: critique and cladistica analysis". Zoological Journal of the Linnean Society 136 (2): 217–276. doi:10.1046/j.1096-3642.2002.00029.x. 
  52. 52.0 52.1 Upchurch P; Barrett PM; Dodson P (2004). "Sauropoda". The Dinosauria (2nd ed.). University of California Press. p. 316. ISBN 978-0-520-24209-8. 
  53. Brezinski, D. K.; Kollar, A. D. (2008). "Geology of the Carnegie Museum Dinosaur Quarry Site of Diplodocus carnegii, Sheep Creek, Wyoming". Annals of Carnegie Museum 77 (2): 243–252. doi:10.2992/0097-4463-77.2.243. 
  54. Gillette, D.D. (1991). "Seismosaurus halli, gen. et sp. nov., a new sauropod dinosaur from the Morrison Formation (Upper Jurassic/Lower Cretaceous) of New Mexico, USA". Journal of Vertebrate Paleontology 11 (4): 417–433. doi:10.1080/02724634.1991.10011413. Bibcode1991JVPal..11..417G. 
  55. "Hall, Jim & Ruth". https://sflivingtreasures.org/index.php/treasures/2-treasures/101-hall-jim-a-ruth-.html?showall=1. 
  56. Lucas S, Herne M, Heckert A, Hunt A, and Sullivan R. Reappraisal of Seismosaurus, A Late Jurassic Sauropod Dinosaur from New Mexico. The Geological Society of America, 2004 Denver Annual Meeting (November 7–10, 2004). Retrieved on May 24, 2007.
  57. Lucas, S.G.; Spielman, J.A.; Rinehart, L.A.; Heckert, A.B.; Herne, M.C.; Hunt, A.P.; Foster, J.R.; Sullivan, R.M. (2006). "Taxonomic status of Seismosaurus hallorum, a Late Jurassic sauropod dinosaur from New Mexico". in Foster, J.R.. Paleontology and Geology of the Upper Morrison Formation. Bulletin of the New Mexico Museum of Natural History and Science. New Mexico Museum of Natural History and Science (bulletin 36). pp. 149–161. https://econtent.unm.edu/digital/collection/bulletins/id/792. 
  58. Lovelace, David M.; Hartman, Scott A.; Wahl, William R. (2007). "Morphology of a specimen of Supersaurus (Dinosauria, Sauropoda) from the Morrison Formation of Wyoming, and a re-evaluation of diplodocid phylogeny". Arquivos do Museu Nacional 65 (4): 527–544. 
  59. Mortimer, Mickey (March 2017). "Comment (Case 3700) — A statement against the proposed designation of Diplodocus carnegii Hatcher, 1901 as the type species of Diplodocus Marsh, 1878 (Dinosauria, Sauropoda)". The Bulletin of Zoological Nomenclature 73 (2–4): 129–131. doi:10.21805/bzn.v73i2.a14. ISSN 0007-5167. 
  60. Carpenter, Kenneth (May 15, 2017). "Comment (Case 3700) — Opposition against the proposed designation of Diplodocus carnegii Hatcher, 1901 as the type species of Diplodocus Marsh, 1878 (Dinosauria, Sauropoda)". The Bulletin of Zoological Nomenclature 74 (1): 47–49. doi:10.21805/bzn.v74.a014. ISSN 0007-5167. 
  61. Upchurch, P.; Barrett, P.M.; Dodson, P. (2004). "Sauropoda". The Dinosauria (2nd ed.). University of California Press. pp. 259–322. ISBN 978-0-520-25408-4. 
  62. Mossbrucker, M. T., & Bakker, R. T. (October 2013). Missing muzzle found: new skull material referrable to Apatosaurus ajax (Marsh 1877) from the Morrison Formation of Morrison, Colorado. In Geological Society of America Abstracts with Programs (Vol. 45, p. 111).
  63. Schmitz, L.; Motani, R. (2011). "Nocturnality in Dinosaurs Inferred from Scleral Ring and Orbit Morphology". Science 332 (6030): 705–8. doi:10.1126/science.1200043. PMID 21493820. Bibcode2011Sci...332..705S. 
  64. Kermack, Kenneth A. (1951). "A note on the habits of sauropods". Annals and Magazine of Natural History 12 (4): 830–832. doi:10.1080/00222935108654213. 
  65. 65.0 65.1 65.2 Gangewere, J.R. (1999). "Diplodocus carnegii ". Carnegie Magazine.
  66. Pierson, D. J. (2009). "The Physiology of Dinosaurs: Circulatory and Respiratory Function in the Largest Animals Ever to Walk the Earth". Respiratory Care 54 (7): 887–911. doi:10.4187/002013209793800286. PMID 19558740. 
  67. Hay, O. P., 1910, Proceedings of the Washington Academy of Sciences, vol. 12,, pp. 1–25
  68. Hay, Dr. Oliver P., "On the Habits and Pose of the Sauropod Dinosaurs, especially of Diplodocus." The American Naturalist, Vol. XLII, October 1908
  69. Holland, Dr. W. J. (1910). "A Review of Some Recent Criticisms of the Restorations of Sauropod Dinosaurs Existing in the Museums of the United States, with Special Reference to that of Diplodocus carnegii in the Carnegie Museum". The American Naturalist 44 (521): 259–283. doi:10.1086/279138. https://zenodo.org/record/1431355. 
  70. Schwarz, Daniela; Frey, Eberhard; Meyer, Christian A. (2007). "Pneumaticity and soft−tissue reconstructions in the neck of diplodocid and dicraeosaurid sauropods". The Anatomical Record 290 (1): 32–47. doi:10.1002/ar.20405. PMID 17441196. https://www.researchgate.net/publication/234833820. 
  71. 71.0 71.1 71.2 71.3 Carpenter, Kenneth, ed (2005). "Neck Posture, Dentition and Feeding Strategies in Jurassic Sauropod Dinosaurs". Thunder Lizards: The Sauropodomorph Dinosaurs. Indiana University Press. pp. 212–232. ISBN 978-0-253-34542-4. 
  72. Upchurch, P (2000). "Neck Posture of Sauropod Dinosaurs". Science 287 (5453): 547b. doi:10.1126/science.287.5453.547b. http://www.sciencemag.org/cgi/reprint/287/5453/547b.pdf. Retrieved November 28, 2006. 
  73. Bertozzo, Filippo; Manucci, Fabio; Dempsey, Matthew; Tanke, Darren H.; Evans, David C.; Ruffell, Alastair; Murphy, Eileen (May 2021). "Description and etiology of paleopathological lesions in the type specimen of Parasaurolophus walkeri (Dinosauria: Hadrosauridae), with proposed reconstructions of the nuchal ligament". Journal of Anatomy 238 (5): 1055–1069. doi:10.1111/joa.13363. PMID 33289113. PMC 8053592. https://www.researchgate.net/publication/346603204. 
  74. Woodruff, D. Cary (2017). "Nuchal ligament reconstructions in diplodocid sauropods support horizontal neck feeding postures". Historical Biology 29 (3): 308–319. doi:10.1080/08912963.2016.1158257. Bibcode2017HBio...29..308W. https://www.tandfonline.com/doi/abs/10.1080/08912963.2016.1158257. 
  75. Dimery, Nicola J.; Alexander, R. McN.; Deyst, Katherine A. (1985). "Mechanics of the ligamentum nuchae of some artiodactyls". Journal of Zoology 206 (3): 341–351. doi:10.1111/j.1469-7998.1985.tb05663.x. https://zslpublications.onlinelibrary.wiley.com/doi/abs/10.1111/j.1469-7998.1985.tb05663.x#:~:text=The%20ligamentum%20nuchae%20lies%20near,with%20rubber%2Dlike%20elastic%20properties.. 
  76. Dzemski, Gordon; Christian, Andreas (2007). "Flexibility along the neck of the ostrich (Struthio camelus) and consequences for the reconstruction of dinosaurs with extreme neck length". Journal of Morphology 268 (8): 701–714. doi:10.1002/jmor.10542. PMID 17514722. https://onlinelibrary.wiley.com/doi/10.1002/jmor.10542. 
  77. Schwarz, Daniela; Frey, Eberhard; Meyer, Christian A. (2007). "Pneumaticity and soft tissue reconstruction in the neck of diplodocid and dicraeosaurid sauropods". The Anatomical Record 290 (1): 32–47. doi:10.1002/ar.20405. PMID 17441196. https://www.researchgate.net/publication/234833820. 
  78. Taylor, M.P.; Wedel, M.J.; Naish, D. (2009). "Head and neck posture in sauropod dinosaurs inferred from extant animals". Acta Palaeontologica Polonica 54 (2): 213–220. doi:10.4202/app.2009.0007. http://doc.rero.ch/record/209502/files/PAL_E4057.pdf. 
  79. Norman, D.B. (1985). The illustrated Encyclopedia of Dinosaurs. London: Salamander Books Ltd
  80. Dodson, P. (1990). "Sauropod paleoecology". in Weishampel, D.B.. The Dinosauria" 1st Edition. University of California Press. 
  81. Barrett, P.M.; Upchurch, P. (1994). "Feeding mechanisms of Diplodocus". Gaia 10: 195–204. 
  82. Young, Mark T.; Rayfield, Emily J.; Holliday, Casey M.; Witmer, Lawrence M.; Button, David J.; Upchurch, Paul; Barrett, Paul M. (August 2012). "Cranial biomechanics of Diplodocus (Dinosauria, Sauropoda): testing hypotheses of feeding behavior in an extinct megaherbivore". Naturwissenschaften 99 (8): 637–643. doi:10.1007/s00114-012-0944-y. ISSN 1432-1904. PMID 22790834. Bibcode2012NW.....99..637Y. 
  83. D’Emic, M. D.; Whitlock, J. A.; Smith, K. M.; Fisher, D. C.; Wilson, J. A. (2013). Evans, A. R.. ed. "Evolution of high tooth replacement rates in sauropod dinosaurs". PLOS ONE 8 (7): e69235. doi:10.1371/journal.pone.0069235. PMID 23874921. Bibcode2013PLoSO...869235D. 
  84. Henderson, Donald M. (2006). "Burly gaits: centers of mass, stability, and the trackways of sauropod dinosaurs". Journal of Vertebrate Paleontology 26 (4): 907–921. doi:10.1671/0272-4634(2006)26[907:BGCOMS2.0.CO;2]. http://doc.rero.ch/record/15149/files/PAL_E2423.pdf. 
  85. 85.0 85.1 Mallison, H. (2011). "Rearing Giants – kinetic-dynamic modeling of sauropod bipedal and tripodal poses". in Farlow, J.. Biology of the Sauropod Dinosaurs: Understanding the life of giants. Life of the Past. Indiana University Press. ISBN 978-0-253-35508-9. 
  86. Paul, Gregory S. (2017). "Restoring Maximum Vertical Browsing Reach in Sauropod Dinosaurs". The Anatomical Record 300 (10): 1802–1825. doi:10.1002/ar.23617. PMID 28556505. 
  87. Cobley, Matthew J.; Rayfield, Emily J.; Barrett, Paul M. (2013). "Inter-Vertebral Flexibility of the Ostrich Neck: Implications for Estimating Sauropod Neck Flexibility". PLOS ONE 8 (8): e72187. doi:10.1371/journal.pone.0072187. PMID 23967284. Bibcode2013PLoSO...872187C. 
  88. Ghose, Tia (August 15, 2013). "Ouch! Long-Necked Dinosaurs Had Stiff Necks". livescience.com. http://www.livescience.com/38895-sauropods-had-stiff-necks.html. 
  89. Taylor, M.P. (2014). "Quantifying the effect of intervertebral cartilage on neutral posture in the necks of sauropod dinosaurs". PeerJ 2: e712. doi:10.7717/peerj.712. PMID 25551027. 
  90. Whitlock, John A.; Wilson, Jeffrey A.; Lamanna, Matthew C. (March 2010). "Description of a Nearly Complete Juvenile Skull of Diplodocus (Sauropoda: Diplodocoidea) from the Late Jurassic of North America". Journal of Vertebrate Paleontology 30 (2): 442–457. doi:10.1080/02724631003617647. Bibcode2010JVPal..30..442W. http://www.bioone.org/doi/pdf/10.4202/app.00257.2016. 
  91. Senter, P. (2006). "Necks for Sex: Sexual Selection as an Explanation for Sauropod Neck Elongation". Journal of Zoology 271 (1): 45–53. doi:10.1111/j.1469-7998.2006.00197.x. http://doc.rero.ch/record/16143/files/PAL_E3046.pdf. 
  92. Taylor, M.P.; Hone, D.W.E.; Wedel, M.J.; Naish, D. (2011). "The long necks of sauropods did not evolve primarily through sexual selection". Journal of Zoology 285 (2): 151–160. doi:10.1111/j.1469-7998.2011.00824.x. http://www.miketaylor.org.uk/dino/pubs/taylor-et-al-2011b/TaylorEtAl2011-sauropod-necks-not-sexually-selected.pdf. 
  93. Walking on Eggs: The Astonishing Discovery of Thousands of Dinosaur Eggs in the Badlands of Patagonia, by Luis Chiappe and Lowell Dingus. June 19, 2001, Scribner
  94. Grellet-Tinner, Chiappe Coria (2004). "Eggs of titanosaurid sauropods from the Upper Cretaceous of Auca Mahuevo (Argentina)". Canadian Journal of Earth Sciences 41 (8): 949–960. doi:10.1139/e04-049. Bibcode2004CaJES..41..949G. 
  95. Ruxton, Graeme D.; Birchard, Geoffrey F.; Deeming, D Charles (2014). "Incubation time as an important influence on egg production and distribution into clutches for sauropod dinosaurs". Paleobiology 40 (3): 323–330. doi:10.1666/13028. Bibcode2014Pbio...40..323R. 
  96. Sander, P. M. (2000). "Long bone histology of the Tendaguru sauropods: Implications for growth and biology". Paleobiology 26 (3): 466–488. doi:10.1666/0094-8373(2000)026<0466:lhotts>2.0.co;2. http://doc.rero.ch/record/16668/files/PAL_E2877.pdf. 
  97. Sander, P. M.; N. Klein; E. Buffetaut; G. Cuny; V. Suteethorn; J. Le Loeuff (2004). "Adaptive radiation in sauropod dinosaurs: Bone histology indicates rapid evolution of giant body size through acceleration". Organisms, Diversity & Evolution 4 (3): 165–173. doi:10.1016/j.ode.2003.12.002. http://doc.rero.ch/record/14551/files/PAL_E1760.pdf. 
  98. Sander, P. M.; N. Klein (2005). "Developmental plasticity in the life history of a prosauropod dinosaur". Science 310 (5755): 1800–1802. doi:10.1126/science.1120125. PMID 16357257. Bibcode2005Sci...310.1800S. 
  99. Trujillo, K.C.; Chamberlain, K.R.; Strickland, A. (2006). "Oxfordian U/Pb ages from SHRIMP analysis for the Upper Jurassic Morrison Formation of southeastern Wyoming with implications for biostratigraphic correlations". Geological Society of America Abstracts with Programs 38 (6): 7. 
  100. Bilbey, S.A. (1998). "Cleveland-Lloyd Dinosaur Quarry – age, stratigraphy and depositional environments". in Carpenter, K.. The Morrison Formation: An Interdisciplinary Study. Modern Geology 22. Taylor and Francis Group. pp. 87–120. 
  101. Russell, Dale A. (1989). An Odyssey in Time: Dinosaurs of North America. Minocqua, Wisconsin: NorthWord Press. pp. 64–70. ISBN 978-1-55971-038-1. 
  102. 102.0 102.1 Mateus, Octávio (2006). "Jurassic dinosaurs from the Morrison Formation (USA), the Lourinhã and Alcobaça Formations (Portugal), and the Tendaguru Beds (Tanzania): A comparison". in Foster, John R.. Paleontology and Geology of the Upper Jurassic Morrison Formation. New Mexico Museum of Natural History and Science Bulletin, 36. Albuquerque, New Mexico: New Mexico Museum of Natural History and Science. pp. 223–231. 
  103. Foster, J. (2007). "Appendix." Jurassic West: The Dinosaurs of the Morrison Formation and Their World. Indiana University Press. pp. 327–329.
  104. Chure, Daniel J.; Litwin, Ron; Hasiotis, Stephen T.; Evanoff, Emmett; Carpenter, Kenneth (2006). "The fauna and flora of the Morrison Formation: 2006". in Foster, John R.. Paleontology and Geology of the Upper Jurassic Morrison Formation. New Mexico Museum of Natural History and Science Bulletin, 36. Albuquerque, New Mexico: New Mexico Museum of Natural History and Science. pp. 233–248. 
  105. Dodson, P.; Behrensmeyer, A.K.; Bakker, R.T.; McIntosh, J.S. (1980). "Taphonomy and paleoecology of the dinosaur beds of the Jurassic Morrison Formation". Paleobiology 6 (1): 208–232. doi:10.1017/S0094837300025768. 
  106. Foster, John R. (2003). Paleoecological Analysis of the Vertebrate Fauna of the Morrison Formation (Upper Jurassic), Rocky Mountain Region, U.S.A.. New Mexico Museum of Natural History and Science Bulletin, 23. Albuquerque, New Mexico: New Mexico Museum of Natural History and Science. p. 29. 
  107. "Diplodocus." In: Dodson, Peter & Britt, Brooks & Carpenter, Kenneth & Forster, Catherine A. & Gillette, David D. & Norell, Mark A. & Olshevsky, George & Parrish, J. Michael & Weishampel, David B. The Age of Dinosaurs. Publications International, LTD. p. 58–59. ISBN:0-7853-0443-6.
  108. Rea, Tom (2001). Bone Wars. The Excavation and Celebrity of Andrew Carnegie's Dinosaur. Pittsburgh University Press. See particularly pages 1–11 and 198–216.
  109. "Die Wanderjahre" (in de). Kladderadatsch 61: 319. May 10, 1908. https://digi.ub.uni-heidelberg.de/diglit/kla1908/0319. 
  110. Russell, Dale A. (1988). An Odyssey in Time: the Dinosaurs of North America. NorthWord Press, Minocqua, WI. p. 76.
  111. Sachs, Sven (2001). "Diplodocus – Ein Sauropode aus dem Oberen Jura (Morrison-Formation) Nordamerikas". Natur und Museum 131 (5): 133–150. 
  112. Beasley, Walter (1907). "An American Dinosaur for Germany." The World Today, August 1907: 846–849.
  113. "Dinosaur Collections". National Museum of Natural History. 2008.
  114. "Age of Giants Hall ". New Mexico Museum of Natural History and Science.
  115. Socha, Vladimír (March 23, 2020). "Diplodocus militaris" (in Czech). https://www.osel.cz/11090-diplodocus-militaris.html. 

External links

Wikidata ☰ Q14330 entry