Appalachia (landmass) explained

During most of the Late Cretaceous (100.5 to 66 million years ago) the eastern half of North America formed Appalachia (named for the Appalachian Mountains), an island land mass separated from Laramidia to the west by the Western Interior Seaway. This seaway had split North America into two massive landmasses due to a multitude of factors such as tectonism and sea-level fluctuations for nearly 40 million years.[1] [2] The seaway eventually expanded, divided across the Dakotas, and by the end of the Cretaceous,[3] it retreated towards the Gulf of Mexico and the Hudson Bay. This left the island masses joined in the continent of North America as the Rocky Mountains rose.[4] From the Cenomanian to the end of the Campanian ages of the Late Cretaceous, Appalachia was separated from the rest of North America. As the Western Interior Seaway retreated in the Maastrichtian, Laramidia and Appalachia eventually connected.[5] Because of this, its fauna was isolated, and developed very differently from the tyrannosaur, ceratopsian, hadrosaurid, pachycephalosaur and ankylosaurid dominated fauna of the western part of North America, known as "Laramidia".[6]

Due to high sea levels, subsequent erosion,[7] and the lack of orogenic input of sediment into the Western Interior Seaway unlike the east coast of Laramidia, no terrestrially formed deposits have survived, with most dinosaur remains originating from seaborne carcasses that were transported into marine environments. This same lack of terrestrial sediments is also present on the western coast of Laramidia. Some sediments in the northern part of the range have been removed by glacial erosion of the Laurentide Ice Sheet during Quaternary glaciations,[8] but it is difficult to ascertain how much sediment has been removed, or whether these sediments would have been any more productive than those that remain. Thus relatively little is known about Appalachia in comparison to Laramidia, with the exception of plant life, marine life and the insects trapped in amber from New Jersey. In addition, due to a lack of interest in Appalachia, many fossils that have been found in Appalachia lie unstudied and remain in the inaccurate genera to which they were assigned in the days of E. D. Cope and O. C. Marsh. Only a few fossils of the terrestrial creatures that were found in this region have given us a brief glimpse into what life was like here during the Cretaceous period. However, the area has seen a bit of a resurgence of interest due to several discoveries made in the past few years.[9] [10] [11] [12] [13] As mentioned earlier, not much is known about Appalachia, but some fossil sites, such as the Woodbine Formation, Navesink Formation,[14] Ellisdale Fossil Site,[15] Mooreville Chalk Formation, Demopolis Chalk Formation, Black Creek Group and the Niobrara Formation,[16] together with ongoing research in the area,[17] have given us a better look into this forgotten world of paleontology.

Geography

Appalachia stretched from Quebec and Newfoundland and Labrador all the way down to the Eastern United States and west to the Midwestern United States. Fossils found in these regions indicate that the area was covered in coastal plains and coastal lowlands during the Cretaceous period.[18] Some scientists have proposed the idea that an archipelago of islands had formed during the time that the Western Interior Seaway had divided Laramidia and Appalachia apart until the near end of the Cretaceous. This would allow dinosaurs to migrate into the Gulf Coast and why it would possibly explain why there are some noticeable distinctions with the fauna in the two assemblages of Appalachia. For instance, the southeastern assemblage (which consists of the Carolinas and the Gulf Coast sites) has some tyrannosauroids such as Appalachiosaurus, some hadrosauroids such as Eotrachodon and Lophorhothon, nodosaurs, dromaeosaurs, and new leptoceratopsian while the northern assemblage (which consists of New Jersey, Delaware, and Maryland) has some tyrannosauroids such as Dryptosaurus, hadrosauroids such as Hadrosaurus, smaller theropods, and a possible lambeosaur in the area.[19]

Range

Vertebrate fossils have been found along the Atlantic Seaboard as well as other states like Alabama, Georgia, North Carolina, South Carolina, Mississippi, Missouri, Kentucky, Tennessee, Kansas, Nebraska, Iowa, and Minnesota. Parts of Canada that were a part of Appalachia during the Cretaceous include, Manitoba, Ontario, Quebec, Nunavut, New Brunswick, Newfoundland and Labrador, and Nova Scotia.[20] [21] [22]

Fauna

Dinosaurs

See main article: articles and List of Appalachian dinosaurs. From the Cenomanian to the Maastrichtian, Appalachia was inhabited by various groups of dinosaurs including, hadrosauroids, hadrosaurs, nodosaurs, leptoceratopsians, indeterminate ornithopods, tyrannosauroids, dromaeosaurs, ornithomimids, and indeterminate maniraptors lived in the area. There is also fossil evidence of possible chasmosaurs, lambeosaurs, sauropods, carcharodontosaurs, caenagnathids, troodontids, and coelurosaurs that might have inhabited the area.[23] [24] [6] [25] [26] In 2022, fossils unearthed from the Woodbine Formation in Texas confirmed that carcharodontosaurs, troodontids, and coelurosaurs did indeed inhabit Appalachia.[27]

Tyrannosaurs

In Late Cretaceous North America, the dominant predators were the Tyrannosauroidea, huge predatory theropods built for ripping flesh from their prey. In Appalachia, dryptosaurs were the top predators in this clade. Rather than developing the huge heads and massive bodies of their western relatives such as Gorgosaurus, Albertosaurus and Lythronax,[28] dryptosaurs had more in common with the basal tyrannosaurs like Dilong and Eotyrannus. Dryptosaurs were characterized by long arms with three fingers;[29] while they were not as large as the largest tyrannosaurids, fossils from the Potomac Formation in New Jersey show that some of them did evolve some of the large-bodied features that can be found on other tyrannosaurs.[30] Three genera of valid Appalachian tyrannosaurs are known, Dryptosaurus, Appalachiosaurus, and the recently discovered Teihivenator while other indeterminate fossils lie scattered throughout most of the southern United States like Georgia, North Carolina, and South Carolina. Fossil foot bones from Appalachian deposits indicate another, unnamed tyrannosauroid measuring 9m (30feet), indicating that diversity in these basal tyrannosauroids remained high during the Late Cretaceous. These fossilized teeth possibly belong to a species of Appalachiosaurus or an undescribed species of a new tyrannosaur.[31] [32] There is also the possibility of a fourth tyrannosaur known from Applachia known as Diplotomodon, but the genus is considered dubious. Fossils from New Jersey and Delaware, most notably in the Mt. Laurel Formation and Merchantville Formations, have revealed that the primitive tyrannosauroids were much more diverse than expected, and some of them grew to lengths of 8 to 9 meters long, making them around the same size as some of the more advanced tyrannosaurs found in Laramidia.[33] [34] Fossils in Cenomanian deposits further indicate tyrannosauroids had been a constant presence in Appalachia since the Middle Cretaceous.[35]

Dromaeosaurs

The dryptosaurs were not the only predatory dinosaurs in Appalachia. Indeterminate dromaeosaur fossils, possibly belonging to Velociraptorinae and Saurornitholestinae, and teeth, most closely matching those of Saurornitholestes,[36] have also been unearthed in Appalachia as well; mostly in the southern states like Missouri, North Carolina, South Carolina, Alabama, Mississippi and Georgia.[37] Finds from the Campanian Tar Heel Formation in North Carolina indicate that there may have been dromaeosaurids of considerable size; intermediate between genera such as Saurornitholestes and Dakotaraptor. Though known only from teeth, the discovery indicates large dromaeosaurids were part of Appalachia's fauna.[38] Along with the dromaeosaurid remains, tyrannosauroid and possible ornithomimid remains have been unearthed in Missouri as well.[39] It should also be noted that dromaeosaur remains are more commonly found in the southern region of Appalachia when compared to the northern region, with their sizes ranging from smaller forms to gigantic forms.[40] Recent fossils unearthed in New Jersey show that maniraptorans were present in Appalachia as well.[41]

Ornithomimids

Various ornithomimid bones, such as Coelosaurus, have also been reported from Appalachia from Missouri, Mississippi, Alabama, Georgia and as far north in states like Maryland, New Jersey, and Delaware, but it is now believed that some of these are the bones of juvenile dryptosaurs while others belong to various undescribed species of ornithomimids. As of 2019, no distinct species of ornithomimosaurs have been identified yet, mostly due to the fact that no complete skeleton has been unearthed yet. However, it can be assumed that most of them were around the same size of their Laramidian relatives, though there is one specimen that could have reached a large size similar to Gallimimus or Beishanlong.[42] [43] [39] [44] In 2022, fossils from the Eutaw Formation from Mississippi revealed that large ornithomimids did indeed roam Appalachia.[45]

Other theropods

Fossils from the Woodbine Formation in Texas, one of the few fossil sites that is one of Appalachia's more well preserved fossils, reveal that other theropods might have roamed Appalachia around the time when the Western Interior Seaway first formed, they include possible specimens of allosauroids, troodontids, caenagnathids, dromaeosaurs, and tyrannosaurs.[23] [24] The most of these being the carcharodontosaurid Acrocanthosaurus.[46] [47]

Hadrosaurs

Another common group, arguably the most widespread species in the area,[48] of Appalachian dinosaurs were the hadrosaurs which were represented by three groups including Hadrosauromorpha, Hadrosauroidea, and the Hadrosauridae[49] which is now considered to be their "ancestral homeland"; eventually making their way to Laramidia, Asia,[50] [51] [52] [53] [54] Europe,[55] [56] South America[57] and Antarctica[58] where they diversified into the lambeosaurine and saurolophine dinosaurs, though some of the primitive hadrosaurs[59] were still present until the end of the Mesozoic.[60] [61] [62] [63] While the fossil record shows a staggering variety of hadrosaur forms in Laramidia, hadrosaur remains for Appalachia show less diversity due to the relative uncommon number of fossil beds. However, a decent number of hadrosaurs are known from Appalachia with Protohadros, Claosaurus, and Lophorhothon representing Hadrosauromorpha, Hypsibema crassicauda and Hypsibema missouriensis representing Hadrosauroidea, and Hadrosaurus and Eotrachodon representing Hadrosauridae. These hadrosaurs from Appalachia seem to be closely related to the crestless hadrosaurs of Laramidia like Gryposaurus and Edmontosaurus, despite the fact that they are not considered to be saurolophines. Claosaurus is known from a specimen which floated into the Interior Seaway and was found in Kansas, might also be from Appalachia, since it was found closer to the Appalachia side of the seaway and is unknown from Western North America. Hadrosaur remains have even been found in Iowa, though in fragmentary remains,[64] Tennessee, most notably from the Coon Creek Formation.[65] [66]

Hypsibema crassicauda,[67] over fifty feet long, was one of the largest eastern hadrosaurs, outgrowing some of more derived western hadrosaurs like Lambeosaurus and Saurolophus. The genus likely took up the environmental niche occupied by large sauropods in other areas, possibly grown to colossal sizes to that of Magnapaulia[68] and Shantungosaurus.[69] Hypsibema missouriensis, was another large species of hadrosaur, but it grew up to 45 to 49 feet, which wasn't as large as Hypsibema crassicauda. When it was first discovered in 1945, it was mistaken for a species of sauropod.[70] Hypsibema missouriensis, possibly even all of the other hadrosaurs living on Appalachia, had serrated teeth for chewing the vegetation in the area.[71] Hadrosaur fossils from the Kanguk Formation in Axel Heiberg Island in Nunavut, Canada show that hadrosaurs were rather widespread throughout Appalachia. The fossils found in the Kanguk Formation also revealed the dietary preferences of hadrosaurs, which revealed that they had a diet of conifers, stems, twigs, and various deciduous plants.[72]

In 2020, the remains of one small-bodied hadrosaur and two small-bodied hadrosauromorphs were unearthed in the New Egypt Formation in New Jersey. The fossils were dated to the Maastrichtian, which was the last stage of the Cretaceous period that ended with the extinction the dinosaurs. This information would imply that Appalachia probably had a rich diversity of life, but research will be need in order to get a better picture of this lost world.[73] In 2021, new remains of Hypsibema missouriensis, also known as Parrosaurus missouriensis, were unearthed in Missouri.[74] [75] [76]

Lambeosaurs

Indeterminate lambeosaurinae remains, mostly similar to Corythosaurus, have been reported from New Jersey's Navesink Formation, Bylot Island and Nova Scotia, Canada. It cannot yet be explained how lambeosaurines might have reached Appalachia though some have theorized that a land bridge must have formed sometime during the Campanian.[77] In 2020, a forelimb belonging to a lambeosaur was unearthed in the New Egypt Formation from New Jersey with evidence of sharks scavenging on its remains.[78]

Ornithopods

While ornithopod fossils have been unearthed in the eastern United States in the past, including footprints in Virginia,[79] they primarily belonged to scrappy remains and couldn't be described as distinct species, with the exception being Tenontosaurus.[80] [81] [82] However, this all changed with the descriptions of Convolosaurus and Ampelognathus from early Cretaceous and late Cretaceous Texas, respectively.[83] [84]

Nodosaurs

The nodosaurids, a group of large, herbivorous armored dinosaurs resembling armadillos, are another testament to Appalachia's difference from Laramidia. During the early Cretaceous, the nodosaurids prospered and were one of the most widespread dinosaurs throughout North America. However, by the latest Cretaceous, nodosaurids were scarce in western North America,[85] limited to forms like Edmontonia, Denversaurus and Panoplosaurus; perhaps due to competition from the ankylosauridae; though they did thrive in isolation, most notably in Appalachia, as mentioned earlier and in the case of Struthiosaurus,[86] Europe as well. Nodosaurid scutes have been commonly found in eastern North America, while fossil specimens are very rare. Often the findings are not diagnostic enough to identify the species, but the remains attest to a greater number of these armored dinosaurs in Appalachia. Multiple specimens have been unearthed in Kansas[87] in the Niobrara Formation, Alabama in Ripley Formation,[88] Mississippi, Delaware, Maryland and New Jersey, possibly belonging to a multitude of different species.[89] Five possible and best-known examples of Appalachian nodosaurids, from both the early and late Cretaceous period, include Priconodon, Propanoplosaurus, Niobrarasaurus,[90] [91] Silvisaurus[92] and possibly Hierosaurus,[93] though its validity is disputed. Just like the Claosaurus specimen, it is possible that the specimens of Niobrarasaurus, Silvisaurus and Hierosaurus floated into the Interior Seaway from the east, since these two species of nodosaurids were discovered in the famous chalk formations[94] of Kansas and are not known from any location from Western North America. Kansas was also a part of Appalachia when the other parts were covered by oceans, which were a part of the Western Interior Seaway.

Leptoceratopsians

While remains of the advanced ceratopsians, most notably the centrosaurines and chasmosaurines[95] which were very common in Laramidia during this time period, were not found in Appalachia, the leptoceratopsids somehow managed to inhabit that location.[96] A Campanian-era leptoceratopsid ceratopsian has been found in the Tar Heel Formation, marking the first discovery of a ceratopsian dinosaur in the Appalachian zone. This specimen bears a uniquely long, slender and downcurved upper jaw, suggesting that it was an animal with a specialized feeding strategy, yet another example of speciation on an island environment.[97] Recently, a ceratopsian tooth was unearthed in Mississippi's Owl Creek Formation,[98] which has been dated to be 67 million years old.[99] The owner of this one particular tooth was probably a chasmosaurine since by the end of the Cretaceous, the centrosaurines had completely vanished from most of North America, though they were thriving in Asia as in the case of Sinoceratops. While leptoceratopsid remains, the few that have been discovered in recent years, have been unearthed in the southern part of Appalachia, they appear to be completely absent from the northern part of Appalachia, states like New Jersey, Delaware, and Maryland. Suggesting the idea, proposed by paleontologist David R. Schwimmer, that there was a possible providence during the Late Cretaceous.[100] (although it may be a case of preservation bias) It is not completely understood how the leptoceratopsians were able to reach Appalachia, however, the most commonly accepted theory was that they island hopped during the time that the Western Interior Seaway split the North American continent into two different land masses in a way that some species of leptoceratopsids, most notably Ajkaceratops, were able to reach Europe.[101] [102] It should also be noted that there is a distinct difference with how the leptoceratopsians evolved in Appalachia and Laramida. The Appalachian leptoceratopsian that was unearthed in the Tar Heel Formation, which grew to the size of a large dog, had a more slender jaw that teeth that curved downward and outward in its beak. This would imply a specialized feeding strategy for feeding on the foliage that was native to Appalachia during the Campanian.[103]

Birds

Several bird remains are known from Appalachian sites, most of them sea birds like hesperornithes like Hesperornis, Canadaga, Baptornis, Fumicollis, Parahesperornis, and Ichthyornis, enantiornithes like Halimornis and ornithurans like Apatornis and Iaceornis, possibly indicating that Appalachia may have possessed a diverse variety of birds that were endemic to the region. Of particular interest are possible lithornithid remains in New Jersey, arguably one of the best records[104] for Cretaceous birds[105] as some specimens were preserved in the greensands[106] in the area,[107] [108] which would represent a clear example of palaeognath Neornithes in the Late Cretaceous. However, this issue is still under debate. Examples of birds that were endemic to Appalachia include a few groups such as the charadriiformes, which consisted of Graculavus and Telmatornis, anseriformes as represented by Anatalavis, procellariiformes with Tytthostonyx being a representative of the group, and Palaeotringa and Laornis belonging to a currently unknown group of birds.[104] Hesperornithid fossils have also been unearthed in Arkansas.[109] Some birds found in Canada such as Tingmiatornis and Canadaga were found in areas that were a part of Appalachia.[110] [111] Enantiornithine birds are also known from Appalachia, as is the case of Flexomornis from the Woodbine Formation from Texas.[112]

Non-dinosaur herpetofauna

Amphibians

Through the Ellisdale Fossil Site, a good picture of Appalachia's amphibian fauna is present. Amidst lissamphibians, there is evidence for sirenids (including the large Habrosaurus), the batrachosauroidid salamander Parrisia, hylids, and possible representatives of Eopelobates and Discoglossus. These show close similarities to European faunas, but aside from Habrosaurus (which is also found on Laramidia) there is a high degree of endemism, suggesting no interchanges with other landmasses throughout the Late Cretaceous.[113]

Lizards

There is also a high degree of endemism in regards to its reptilian fauna: among squamates, the teiid Prototeius is exclusive to the landmass, and native representatives of iguanids, helodermatids, and necrosaurids are also known.

No fossilized remains of snakes have been discovered in Appalachia during the Cretaceous period, only being found in Laramidia.[114]

Turtles

Amidst turtles, which are rather common finds in Appalachia, Adocus, Apalone, and Bothremys are well represented, the latter in particular more common in Appalachian sites than Laramidian ones. Pleurochayah, a bothremyid, is known from Texas.[115] In Santonian Alabama occurred the giant endemic Appalachemys.[116]

Crocodiles

Crocodiles were rather abundant in Appalachia with nine local crocodilian genera belonging to several confirmed families, with the possibility of much more undiscovered crocodiles waiting to be unearthed. Goniopholididae is represented by Dakotasuchus [117] and Woodbinesuchus,[118] Alligatoridae is represented by Bottosaurus,[119] Neosuchia is represented by Scolomastax[120] and Deltasuchus,[121] Alligatoroidea are presented Deinosuchus and Leidyosuchus, Gavialoidea are represented by Thoracosaurus,[122] Eothoracosaurus,[123] and Crocodilia is presented by Borealosuchus,[124] are well established in Laramidia as well, probably indicative of their ocean crossing capacities. Deinosuchus,[125] being one of the largest crocodilians of the fossil record,[126] was an apex predator that did prey on the dinosaurs[127] [128] [129] in the area, the same case applies for Laramidia as well,[130] [131] despite the fact that the majority of its diet consisted of turtles[132] and sea turtles.[133] [134] However, crocodiles still preyed on the endemic dinosaurs whenever they got the chance to do so; there is evidence of crocodile bite marks on the femur of large ornithomimosaur that indicates the predatory behavior of native crocodiles.[135] Fossils unearthed in South Carolina and New Jersey shows that some of the crocodilians endemic to Appalachia survived the extinction of the dinosaurs and even persisted into the Cenozoic.[136] [137]

Dyrosauridae

Dyrosauridae, most notably Dyrosaurus and Hyposaurus fossils, are also known form Appalachia, particularly in New Jersey, Alabama, and South Carolina.[138]

Pholidosauridae

Only one species of pholidosaurid is known to have lived in Appalachia; Terminonaris whose remains have been unearthed in Texas and Kansas.[139] [140]

Pterosaurs

Pterosaur fossils, mostly similar to Pteranodon and Nyctosaurus, have been unearthed in Georgia,[141] Alabama[142] and Delaware.[143] On a similar note, azhdarchid remains, which belong to Arambourgiania,[144] have been unearthed in Tennessee.[145] There have been a number of specimens of pterosaurs unearthed in areas that were a part of Appalachia during the time that the Western Interior Seaway had divided North America into two landmasses. Fossils of Appalachian pterosaurs have also been unearthed in Kansas and Texas.[146] [147] [148] [149] Pteranodontidae seems to be the most common group of pterosaurs in Appalachia and is represented by five species: Pteranodon, Nyctosaurus, Geosternbergia, Dawndraco, and Alamodactylus.[150] Members of the Ornithocheiridae and Anhangueridae are represented by Aetodactylus and Cimoliopterus respectively.[151]

Choristodera

The remains of indeterminate choristoderans have turned up in the Navesink Formation; the only known genus of choristodere during the Late Cretaceous was Champsosaurus.[152] As a whole Appalachian choristodere fossils are very rare, speculated to the result of the lack of a suitable cold freshwater environment as seen in Laramidia at similar latitudes; the animals are speculated to have been more common at higher latitudes and altitudes.[152]

Mammals

Several types of mammals[153] are also present in Ellisdale and in both of the Carolinas.[154] The most common are ptilodontoidean multituberculates, such as Mesodma, Cimolodon and a massively-sized species. The sheer diversity of species on the landmass, as well as the earlier appearance compared to other Late Cretaceous locales, suggests that ptilodontoideans evolved in Appalachia.[155] [156] Metatherians are also known, including an alphadontid,[156] a stagodontid,[157] and a herpetotheriid.[158] Unlike ptilodontoideans, metatherians show a lesser degree of endemism, implying a degree of interchange with Laramidia and Europe. Research in this area has revealed that the Taeniolabidoidea mammals can trace their origins here and that there were several species of multituberculates endemic to Appalachia.[159] Eutheria fossils, most notably molars, have also been unearthed in Mississippi. It is possible that they belong to a creature rather reminiscent to Protungulatum.[160] The genus Alphadon as well as other members of the Allotheria family have had their remains unearthed in New Jersey.[161]

Marine life

While not much was known about Appalachia's land-based fauna until recently, the marine life that in the area, as well as the life that lived in the nearby Western Interior Seaway, has been well studied by paleontologists for years. Such examples of fossil sites that have preserved the remains of marine life from that period include the Niobrara Formation, the Demopolis Chalk Formation, and the Mooreville Chalk Formation are just a few examples of the fossil sites that have successfully preserved the skeletal remains of various marine creatures from the Cretaceous.[162] [163] [164] [165] [166] [167] [168] [169] Examples of the marine fauna that lived near Appalachia include chondrichthyes, osteichthyes, chelonioids, plesiosaurs, and mosasaurs, which were the apex predators of their environment at the time.[170] [171]

Plesiosaur fossils, belonging to the genus Cimoliasaurus, have been unearthed in New Jersey.[172] Mosasaur remains have also been unearthed in Missouri.[173]

Fish fossils are rather common throughout Appalachia, especially in locations abundant in marl, shale, and limestone.[174] [175] Fish fossils, as well as a lot of Cretaceous era marine fauna, are rather abundant in regions like the Niobrara Formation in Kansas, which is made up of shale, sandstone and limestone, as well as the Woodbury Formation in New Jersey.[176] [177]

Arthropods

Many species of arthropods are known from the Turonian aged New Jersey amber, situated on the Atlantic coast of Appalachia. Arthropods are also known from the Cenomanian aged Redmond Formation of Labrador, Canada.

Flora

While the fossil sites from the southern part in Appalachia, places like Alabama and the Carolinas, have a very scant amount of Cretaceous plant fossils with the exception of Georgia, the northern parts of Appalachia, such as New Jersey, Maryland, and Delaware have a much better record in terms of plant species being unearthed there, especially with fossils sites like the Ellisdale Fossil Site, and have given us a better glimpse into a forgotten world. In the Ellisdae Fossil Site, excavations have revealed that plants like Picea, Metasequoia, Liriodendron, and possibly Rhizophora inhabited the region during the late Cretaceous period, implying that the environment during that time period was a coastal forest with a few types of marine environments as well including estuarine, lagoonal, marine, and terrestrial. Plant fossils found in neighboring states such as Delaware and Maryland have revealed that ferns, gymnosperms, and angiosperms did indeed inhabit the area.[178] Angiosperm fossils were unearthed in the Dakota Formation in Nebraska.[179] As mentioned earlier, Georgia has a rich fossil record of plant life dating back to the Cretaceous. Some of the examples of flora that was present in that area include Salicaceae, Lauraceae, Sequoioideae, Moraceae, Pinophyta, Malpighiales, Monocotyledon, Ericaceae, Cinnamomum, Ranunculales, Salicaceae, Torreya, Cupressaceae, Magnoliaceae and Rhamnaceae.[180] Plant fossils of Minnesota have revealed that cycads, evergreens, Equisetum, laurels, ferns, willows, redwoods, poplars, tulip trees, and pomegranates were present in the area during the Cretaceous.[181] There is also a huge concentration of Normapolles unearthed in the southeastern United States, suggesting that there was a distinct phytogeography through the area during the Cretaceous.[182]

Fossils unearthed near from the Redmond Formation in Labrador have revealed that many of the modern-day angiosperms first appeared in Appalachia.[183] Plant fossils found in Crawford County, Georgia show a wide variety of plant diversity such as sporophytes, gametophytes, Detrusandra, Hamamelidaceae, Actinidiaceae, and a multitude of 63 species of plants have been unearthed in this region.[184] Angiosperm plants have been found in the Woodbine Formation.[185] Pinaceae and Lauraceae fossils have been unearthed in Mississippi and North Carolina respectively.[186] [187]

Plant fossils found in Massachusetts and Rhode Island indicate that the climate here was sub-humid and paratropical too, indicating that some of Appalachia's habitats largely consisted of coastal plains and deciduous forests.[188] Plants of Pinaceae, Taxodioideae, Araucariaceae, Taxaceae, Cycas and Thallophyte have been found in Georgia and South Carolina.[189]

Notes and References

  1. Nielsen . Karsten Schjødt . Schröder-Adams . Claudia J. . Leckie . Dale A. . Haggart . James W. . Elberdak . Khalifa . Turonian to Santonian paleoenvironmental changes in the Cretaceous Western Interior Sea: The Carlile and Niobrara formations in southern Alberta and southwestern Saskatchewan, Canada . Palaeogeography, Palaeoclimatology, Palaeoecology . December 2008 . 270 . 1–2 . 64–91 . 10.1016/j.palaeo.2008.08.018 . 2008PPP...270...64N .
  2. Bertog . Janet . Stratigraphy of the Lower Pierre Shale (Campanian): Implications for the Tectonic and Eustatic Controls on Facies Distributions . Journal of Geological Research . 2010 . 2010 . 1–15 . 10.1155/2010/910243 . free .
  3. Erickson . J. Mark . The Dakota Isthmus – Closing the Late Cretaceous Western Interior Seaway . North Dakota Academy of Science Proceedings . December 1999. 53 . 124–129 . 15 June 2019.
  4. Book: Weishampel. David B.. Young. Luther. Dinosaurs of the East Coast. registration. 1996. Johns Hopkins University Press. Baltimore, MD.. 9780801852169.
  5. Book: Stanley . Steven M. . Earth System History . New York . W.H. Freeman and Company . 1999 . 978-0-7167-2882-5 . 487–489.
  6. Brownstein . Chase D. . The biogeography and ecology of the Cretaceous non-avian dinosaurs of Appalachia . Palaeontologia Electronica. February 2018 . 21 . 1.5A . 1–56 . 10.26879/801 . free .
  7. Liu. Lijun. 15 June 2014. Rejuvenation of Appalachian topography caused by subsidence-induced differential erosion. Nature Geoscience. 7. 7. 518–523. 10.1038/ngeo2187. 2014NatGe...7..518L. 1752-0894.
  8. Braun. Duane D.. September 1989. Glacial and periglacial erosion of the Appalachians. Geomorphology. en. 2. 1–3. 233–256. 10.1016/0169-555X(89)90014-7. 1989Geomo...2..233B.
  9. News: Uren. Adam. Dinosaurs in Minnesota: Fossil claw found in Iron Range has scientists excited. Bring Me the News . 10 October 2015.
  10. News: Sawyer. Liz. Fossil adds to evidence of dinosaurs in Minnesota. Star Tribune. 8 October 2015.
  11. Web site: Fossil finds behind N.J. strip mall causing excitement. CBS Evening News. 16 November 2014 . 16 November 2014.
  12. Web site: Anonymous. Rare fossil of a horned dinosaur found from 'lost continent'. University of Bath News. University of Bath. 30 November 2015.
  13. Web site: Anderson. Natali. Eotrachodon orientalis: New Duck-Billed Dinosaur Species Discovered. Science News.com. 26 January 2016 . Science News. 26 January 2016.
  14. Kennedy. William J.. Landman. Neil H.. Cobban. William Aubrey. Johnson. R.O.. Additions to the ammonite fauna of the Upper Cretaceous Navesink Formation of New Jersey. American Museum Novitates. 13 December 2000. 31. 2246/2008. free.
  15. Book: Gallagher. W.B.. When Dinosaurs Roamed New Jersey. registration. 1997. Rutgers University Press. New Brunswick, NJ. 9780813523484.
  16. Web site: Oceans of Kansas.
  17. Brownstein. Chase. The biogeography and ecology of the Cretaceous non-avian dinosaurs of Appalachia. Palaeontologia Electronica. 17 January 2018. 21. 1.5a. 1–56. 10.26879/801. free.
  18. Brownstein . Chase D. . The biogeography and ecology of the Cretaceous non-avian dinosaurs of Appalachia . Palaeontologia Electronica. 21 . 1 . 1–56 . February 2018 . 10.26879/801 . free .
  19. Schwimmer . David R. . Was There a Southeastern Dinosaur Province in the Late Cretaceous? . Geological Society of America Abstracts with Programs . 1 April 2016 . 48 . 3 . 22–3 . 10.1130/abs/2016SE-271634 .
  20. Web site: King . David T. Jr. . Late Cretaceous Dinosaurs of the Southeastern United States . auburn.edu . Auburn University . 9 January 2019.
  21. Web site: Figure 1 .
  22. Web site: Figure 2.
  23. Adams . Thomas . New Data on Mid- Cretaceous Ecosystems and Faunal Diversity in Appalachia: Insights from the Woodbine Formation (Cenomanian) of North Texas . Geological Society of America Abstracts with Programs . 13 March 2017 . 49 . 1 . 10.1130/abs/2017SC-289203 .
  24. Drumheller . Stephanie K. . Fleshing Out a Lost World: Mid-Cretaceous Diversity in Appalachia with Insights from the Arlington Archosaur Site . Geological Society of America Abstracts with Programs . 13 April 2018 . 50 . 3 . 10.1130/abs/2018SE-312397 .
  25. Brownstein . Chase D. . A Tyrannosauroid Metatarsus from the Merchantville Formation of New Jersey increases the diversity of nonTyrannosaurid Tyrannosauroids on Appalachia . PeerJ . November 2017 . 5 . e4123 . e4123 . 10.7717/peerj.4123 . 29204326 . 5712462 . free .
  26. King . James L. . DINOSAURIAN FAUNA OF THE SOUTHEASTERN UNITED STATES . Geological Society of America Abstracts with Programs . 18 October 2009 . 41 . 7 . 106 . 16 June 2019 . https://web.archive.org/web/20200423132038/https://gsa.confex.com/gsa/2009AM/finalprogram/abstract_164563.htm . 23 April 2020 . dead .
  27. Noto. Christopher R.. D’Amore. Domenic C.. Drumheller. Stephanie K.. Adams. Thomas L.. 2022-01-25. A newly recognized theropod assemblage from the Lewisville Formation (Woodbine Group; Cenomanian) and its implications for understanding Late Cretaceous Appalachian terrestrial ecosystems. PeerJ. 10. e12782. 10.7717/peerj.12782. 35127286 . 8796713 . 2167-8359 . free .
  28. Loewen. Mark A.. Irmis. Randall B.. Setrich. Joseph J. W.. J. Currie. Philip. D. Sampson. Scott. Tyrant Dinosaur Evolution Tracks the Rise and Fall of Late Cretaceous Oceans. PLOS ONE. 6 November 2013. 8. 11. 14. 10.1371/journal.pone.0079420. 24223179. 3819173. 2013PLoSO...879420L. free.
  29. Switek. Brian. Dryptosaurus' Surprising Hands. American Museum Novitates. 3717. 1–53. 11 July 2011. 10.1206/3717.2. 2011. 53318615. 20.500.11820/6aec2625-02e3-4c0f-bb39-6159c51f97b6. free.
  30. Brownstein . Chase D. . A Tyrannosauroid from the Lower Cenomanian of New Jersey and Its Evolutionary and Biogeographic Implications . Bulletin of the Peabody Museum of Natural History . 17 April 2018 . 59 . 1 . 95–106 . 10.3374/014.058.0210 . 90633156 .
  31. Yun . Chan-gyu . 2017 . Teihivenator gen. nov., a new generic name for the Tyrannosauroid Dinosaur "Laelaps" macropus (Cope, 1868; preoccupied by Koch, 1836) . Journal of Zoological and Bioscience Research . 4 . 23 July 2017 . https://web.archive.org/web/20170729051845/https://www.journalzbr.com/index.php/jzbr/article/view/71/0 . 29 July 2017 . dead .
  32. 10.1671/0272-4634(2005)025[0119:ANGASO]2.0.CO;2 . 2005 . 25 . 119–43 . A new genus and species of tyrannosauroid from the Late Cretaceous (Middle Campanian) Demopolis Formation of Alabama . Journal of Vertebrate Paleontology . Carr . Thomas D . Williamson . Thomas E . Schwimmer . David R . 86243316 .
  33. Brownstein . Chase . LARGE BASAL TYRANNOSAUROIDS FROM THE MAASTRICHTIAN AND TERRESTRIAL VERTEBRATE DIVERSITY IN THE SHADOW OF THE K-PG EXTINCTION . The Mosasaur . December 2018 . X . 105–110 . 7 January 2019.
  34. Brownstein . Chase . A tyrannosauroid metatarsus from the Merchantville Formation of Delaware increases the diversity of non-tyrannosaurid tyrannosauroids on Appalachia . PeerJ . 30 November 2017 . 5 . e4123 . e4123 . 10.7717/peerj.4123 . 29204326 . 5712462 . free .
  35. 10.3374/014.058.0210. A Tyrannosauroid from the Lower Cenomanian of New Jersey and Its Evolutionary and Biogeographic Implications. Bulletin of the Peabody Museum of Natural History. 59. 95–105. 2018. Brownstein. Chase Doran. 90633156.
  36. Kiernan. Caitlin R.. Schwimmeri. David R.. First Record of a Velociraptorine Theropod (Tetanurae, Dromaeosauridae) from the Eastern Gulf Coastal United States. 89–93. The Mosasaur. 7. 7 May 2004. January 2004.
  37. Web site: Westfall. Aundrea. Dromaeosaurs. Encyclopedia of Alabama. 18 May 2016.
  38. 10.1016/j.cretres.2018.07.006 . A giant dromaeosaurid from North Carolina . Cretaceous Research . 92 . 1–7 . 2018 . Brownstein . Chase . 135459468 .
  39. Web site: Fix. Michael F.. Dinosauria and Associated Vertebrate Fauna of the Late Cretaceous Chronister Site of Southeast Missouri. Geological Society of America. 1 April 2004.
  40. Brownstein . Chase D. . Diversity of raptor dinosaurs in southeastern North America revealed by the first definite record from North Carolina . PeerJ Preprints . 5 April 2018 . 1–19 . 10.7287/peerj.preprints.26829v1 . 14 June 2019. free .
  41. Brownstein . Chase Doran . New records of theropods from the latest Cretaceous of New Jersey and the Maastrichtian Appalachian fauna . Royal Society Open Science . 1 November 2019 . 6 . 11 . 191206 . 10.1098/rsos.191206 . 31827856 . 6894593 . 2019RSOS....691206B .
  42. Baird . D. . Horner . J. . 1979 . Cretaceous dinosaurs of North Carolina . Brimleyana . 2 . 1–28 .
  43. Brownstein . C.D. . Theropod specimens from the Navesink Formation and their implications for the Diversity and Biogeography of Ornithomimosaurs and Tyrannosauroids on Appalachia . PeerJ Preprints . 5 . e3105v1 . 10.7287/peerj.preprints.3105v1 . 24 July 2017 . free .
  44. Brownstein . Chase Doran . Theropod specimens from the Navesink Formation and their implications for the Diversity and Biogeography of Ornithomimosaurs and Tyrannosauroids on Appalachia . PeerJ Preprints . 24 July 2017 . e3105v1 . 23 December 2019.
  45. Chinzorig . Tsogtbaatar . Cullen . Thomas . Phillips . George . Rolke . Richard . Zanno . Lindsay E. . 2022-10-19 . Large-bodied ornithomimosaurs inhabited Appalachia during the Late Cretaceous of North America . PLOS ONE . 17 . 10 . e0266648 . 10.1371/journal.pone.0266648 . 36260601 . 9581415 . 2022PLoSO..1766648T . free .
  46. News: Carballo . Rebecca . 2023-07-15 . Rare Dinosaur 'Bonebed' Is Discovered in a Maryland Park . en-US . The New York Times . 2023-10-15 . 0362-4331.
  47. Brownstein . Chase . 2018 . The biogeography and ecology of the Cretaceous non-avian dinosaurs of Appalachia . Palaeontologia Electronica . 1–56 . 10.26879/801 . 1935-3952. free .
  48. Web site: King. David T. Jr.. Late Cretaceous Dinosaurs of the Southeastern United States. aubrun.edu. Auburn University Press. 14 September 2016.
  49. Colbert. Edwin H.. A Hadrosaurian Dinosaur from New Jersey. Proceedings of the Academy of Natural Sciences of Philadelphia. 1948. 100. 23–37. 4064414.
  50. Godefroit . P. . Bolotsky . Y. L. . Lauters . P. . Joger . Ulrich . A New Saurolophine Dinosaur from the Latest Cretaceous of Far Eastern Russia . 10.1371/journal.pone.0036849 . PLOS ONE . 7 . 5 . e36849 . 2012 . 22666331. 3364265. 2012PLoSO...736849G . free .
  51. Godefroit . Pascal . Bolotsky, Yuri . Alifanov, Vladimir . 2003 . A remarkable hollow-crested hadrosaur from Russia: an Asian origin for lambeosaurines . Comptes Rendus Palevol . 2 . 143–151 . 10.1016/S1631-0683(03)00017-4 . 2. 2003CRPal...2..143G .
  52. Godefroit . Pascal . Shuqin Zan . Liyong Jin . 2000 . Charonosaurus jiayinensis n. g., n. sp., a lambeosaurine dinosaur from the Late Maastrichtian of northeastern China . Comptes Rendus de l'Académie des Sciences, Série IIA . 330 . 12 . 875–882 . 10.1016/S1251-8050(00)00214-7. 2000CRASE.330..875G .
  53. Bolotsky, Y.L. & Kurzanov, S.K. 1991. [The hadrosaurs of the Amur Region.] In: [''Geology of the Pacific Ocean Border'']. Blagoveschensk: Amur KNII. 94-103. [In Russian]
  54. Godefroit. P.. Bolotsky. Y. L.. Van Itterbeeck. J. . 2004. The lambeosaurine dinosaur Amurosaurus riabinini, from the Maastrichtian of Far Eastern Russia. Acta Palaeontologica Polonica. 49 . 4. 585–618.
  55. Casanovas . M.L . Pereda-Suberbiola . X. . Santafé . J.V. . Weishampel . D.B. . 1999 . First lambeosaurine hadrosaurid from Europe: palaeobiogeographical implications . Geological Magazine . 136 . 2. 205–211 . 10.1017/s0016756899002319. 1999GeoM..136..205C . 128603347 .
  56. Pereda-Suberbiola . Xabier . José Ignacio Canudo. Penélope Cruzado-Caballero. José Luis Barco. Nieves López-Martínez. Oriol Oms. José Ignacio Ruiz-Omeñaca . 2009 . The last hadrosaurid dinosaurs of Europe: A new lambeosaurine from the Uppermost Cretaceous of Aren (Huesca, Spain) . Comptes Rendus Palevol . 8 . 6 . 559–572 . 10.1016/j.crpv.2009.05.002. 2009CRPal...8..559P .
  57. Rubén D. Juárez Valieri . José A. Haro . Lucas E. Fiorelli . Jorge O. Calvo . 2010 . A new hadrosauroid (Dinosauria: Ornithopoda) from the Allen Formation (Late Cretaceous) of Patagonia, Argentina . Revista del Museo Argentino de Ciencias Naturales . New Series . 11 . 2 . 217–231 . 13 September 2016 . https://web.archive.org/web/20110903014352/http://www.macn.secyt.gov.ar/investigacion/descargas/publicaciones/revista/12/rns_vol12-2_217-231.pdf . 3 September 2011 . dead .
  58. Case. Judd A.. Martin. James E.. Chaney. Dan S.. Regurero. Marcelo. Marenssi. Sergio A.. Santillana. Sergio M.. Woodburne. Michael O.. The First Duck-Billed Dinosaur (Family Hadrosauridae) from Antarctica. Journal of Vertebrate Paleontology. 25 September 2000 . 20 . 3 . 612–614. 4524132. 10.1671/0272-4634(2000)020[0612:tfdbdf]2.0.co;2. 11336/105444 . 131243139 . free.
  59. Dalla Vecchia . F. M. . 2009 . Tethyshadros insularis, a new hadrosauroid dinosaur (Ornithischia) from the Upper Cretaceous of Italy . Journal of Vertebrate Paleontology . 29 . 4 . 1100–1116 . 10.1671/039.029.0428. 2009JVPal..29.1100D . 198128196 .
  60. Lund. Eric K.. Gates. Terry A.. A Historical and Biogeographical Examination of Hadrosaurian Dinosaurs. January 2006. New Mexico Museum of Natural History and Science Bulletin . 35 . 263.
  61. Kaye. John M.. Russell. Dale.. The oldest record of hadrosaurian dinosaurs in North America. Journal of Paleontology. 1973. 47 . 1 . 91–93. 1302869.
  62. Research team identifies rare dinosaur from Appalachia. 21 January 2016 . 11 September 2016.
  63. Book: Lull. Richard S.. Wright. Nelda E. . Hadrosaurian dinosaurs of North America . Geological Society of America . 1942 . Geological Society of America Special Papers . 40 . 1–272 . 10.1130/SPE40-p1 . 9780813720401.
  64. Web site: Witzke. Brian J.. Dinosaurs in Iowa. Iowa Geological Society. Iowa Department of Natural Resources, University of Iowa. 12 August 2014. 12 August 2014. 27 October 2014. https://web.archive.org/web/20141027155557/http://www.iihr.uiowa.edu/igs/dinosaurs-in-iowa/. dead.
  65. Byran. Jonathan R. . Frederick . Daniel L.. Schwimmer. David R.. Siesser. William G.. First dinosaur record from Tennessee: a Campanian hadrosaur. Journal of Paleontology. July 1991 . 65 . 4 . 696–697. 11 September 2016. 10.1017/S0022336000030808. 1991JPal...65..696B . 131235991 .
  66. Markin. Walter L. . Gibson . Michael A. . Discovery of a Second Hadrosaur From the Late Cretaceous Coon Creek Formation, West Tennessee. Geological Society of America Abstracts with Programs. 3 November 2010 . 42 . 5. 631.
  67. Cope . E.D. . 1869 . Remarks on Eschrichtius polyporus, Hypsibema crassicauda, Hadrosaurus tripos, and Polydectes biturgidus . Proceedings of the Academy of Natural Sciences of Philadelphia . 21 . 191–192 .
  68. Albert. Prieto-Marquez. Luis. M. Chiappe. Shantanu. H. Joshi. The Lambeosaurine Dinosaur Magnapaulia laticaudus from the Late Cretaceous of Baja California, Northwestern Mexico. PLOS ONE. 12 June 2012. 7. 6. 29. 10.1371/journal.pone.0038207. 22719869. 3373519. 2012PLoSO...738207P. free.
  69. Web site: Chase. Antediluvian Beasts of the East: Hypsibema crassicauda. thetetanuraeguy.wordpress.com. 22 June 2015. 22 June 2015.
  70. Gilmore. Charles W.. Stewart. Dan R.. A New Sauropod Dinosaur from the Upper Cretaceous of Missouri. Journal of Paleontology. January 1945. 19. 1. 23–29. 1299165.
  71. Web site: Welcome to the Fossil Prep Lab!. Bollinger County Museum of Natural History. 13 September 2016. https://web.archive.org/web/20160623232751/http://www.bcmnh.org/fossilprep.html. 23 June 2016. dead.
  72. VAVREK . MATTHEW J. . HILLS . LEN V. . CURRIE . PHILIP J. . 55810951 . A Hadrosaurid (Dinosauria: Ornithischia) from the Late Cretaceous (Campanian) Kanguk Formation of Axel Heiberg Island, Nunavut, Canada, and Its Ecological and Geographical Implications . Arctic . 2014 . 67 . 1 . 1–9 . 24363716 . 10.14430/arctic4362 . free .
  73. Brownstein . Chase D. . Osteology and phylogeny of small-bodied hadrosauromorphs from an end-Cretaceous marine assemblage . Zoological Journal of the Linnean Society . 1 January 2021 . 191 . 1 . 180–200 . 10.1093/zoolinnean/zlaa085 . 7 April 2021.
  74. Web site: Snider. Mike. Show-Me-a-saurus! Skeleton of a new type of dinosaur unearthed in Missouri. 2021-12-01. USA TODAY. en-US.
  75. Web site: Sherry Liang. Missouri dig site is home to at least 4 rare dinosaurs, and there could be more. 2021-12-01. CNN. 25 November 2021 .
  76. Web site: Remains of 30ft duck-billed dinosaur unearthed in Missouri. 2021-12-01. news.yahoo.com. 24 November 2021 . en-US.
  77. Web site: Chase. A response to The Tetrapod Zoology Podcast #45: Why Lambeosaurines did, in fact, persist into the Maastrichtian. An Odyssey of Time. Anonymous. 30 July 2015. 30 July 2015.
  78. Brownstein . Chase D. . Bissell . Immanuel . An elongate hadrosaurid forelimb with biological traces informs the biogeography of the Lambeosaurinae . Journal of Paleontology . 2020 . 95 . 2 . 367–375 . 10.1017/jpa.2020.83 . 5 April 2021. free .
  79. Weems . Robert E. . Bachman . Jon M. . 2015-10-02 . The Lower Cretaceous Patuxent Formation Ichnofauna of Virginia . Ichnos . en . 22 . 3–4 . 208–219 . 10.1080/10420940.2015.1063493 . 2015Ichno..22..208W . 128941109 . 1042-0940.
  80. Main . Derek Jason . 2013-07-22 . Appalachian Delta Plain Paleoecology Of The Cretaceous Woodbine Formation At The Arlington Archosaur Site, North Texas . en.
  81. Brownstein . Chase D. . 2018-02-08 . The biogeography and ecology of the Cretaceous non-avian dinosaurs of Appalachia . Palaeontologia Electronica . English . 21 . 1 . 1–56 . 10.26879/801 . 1094-8074. free .
  82. Book: Weishampel, David . Dinosaurs of the East Coast . 1998 . Johns Hopkins University Press . 10.56021/9780801852169 . 978-0-8018-5216-9.
  83. Andrzejewski . Kate A. . Winkler . Dale A. . Jacobs . Louis L. . 2019-03-12 . A new basal ornithopod (Dinosauria: Ornithischia) from the Early Cretaceous of Texas . PLOS ONE . 14 . 3 . e0207935 . 10.1371/journal.pone.0207935 . 1932-6203 . 6413910 . 30860999 . 2019PLoSO..1407935A . free .
  84. Tykoski . Ronald S. . Contreras . Dori L. . Noto . Christopher . 2023-10-13 . The first small-bodied ornithopod dinosaur from the Lewisville Formation (middle Cenomanian) of TexasCitation for this article: Tykoski, R. S., Contreras, D. L., & Noto, C. (2023) The first small-bodied ornithopod dinosaur from the Lewisville Formation (middle Cenomanian) of Texas. Journal of Vertebrate Paleontology. Journal of Vertebrate Paleontology . en . 10.1080/02724634.2023.2257238 . 0272-4634. free .
  85. Bakker. Robert T.. Review of the Late Cretaceous nodosauroid Dinosauria: Denversaurus schlessmani, a new armor-plated dinosaur from the Latest Cretaceous of South Dakota, the last survivor of the nodosaurians, with comments on Stegosaur-Nodosaur relationships. Hunteria. 1988. 1. 3. 1–23.
  86. Garcia . G. . Pereda-Suberbiola . X. . 2003 . A new species of Struthiosaurus (Dinosauria: Ankylosauria) from the Upper Cretaceous of Villeveyrac (southern France) . Journal of Vertebrate Paleontology . 23 . 1. 156–165 . 10.1671/0272-4634(2003)23[156:ansosd]2.0.co;2. 140174401 .
  87. Web site: Approximate location of Smoky Hill Chalk nodosaur remains.. 13 September 2016.
  88. Web site: Bruns. Michael E.. New Appalachian Armored Dinosaur Material (Nodosauridae, Ankylosauria) From the Maastrichtian Ripley Formation of Alabama. The Geological Society of America. 1 April 2016.
  89. Web site: Ebersole. Jun. Nodosaur. Encyclopedia of Alabama. 18 May 2016.
  90. Everhart. Michael J.. Hamm. Shawn A.. A new nodosaur specimen (Dinosauria: Nodosauridae) from the Smoky Hill Chalk (Upper Cretaceous) of western Kansas. Transactions of the Kansas Academy of Science. January 2005. 108. 1&2. 15–21. 10.1660/0022-8443(2005)108[0015:ANNSDN]2.0.CO;2. 86252250 .
  91. Carpenter. Kenneth. Everhart. Michael J.. Skull of the ankylosaur Niobrarasaurus coleu (Ankylosauria: Nodosauridae) from the Smoky Hill Chalk (Coniacian) of western Kansas. Transactions of the Kansas Academy of Science. April 2007. 110. 1 & 2. 1–9 . 10.1660/0022-8443(2007)110[1:SOTANC]2.0.CO;2. 86282946 .
  92. Eaton . T. H. Jr. . 1960 . A new armored dinosaur from the Cretaceous of Kansas . The University of Kansas Paleontological Contributions: Vertebrata . 8 . 1–24 . 1808/3799 .
  93. 10.2475/ajs.s4-27.159.250 . A new armored saurian from the Niobrara . American Journal of Science . 27 . 159 . 250–2 . 1909 . Wieland . G. R . 1909AmJS...27..250W .
  94. Carpenter. Kenneth. Dilkes. David. Weishampel. Dave. The Dinosaurs of the Niobrara Chalk Formation (Upper Cretaceous, Kansas). Journal of Vertebrate Paleontology. June 1995. 15. 2. 275–297 . 10.1080/02724634.1995.10011230 . 1995JVPal..15..275C .
  95. Web site: Amazing horned dinosaurs unearthed on 'lost continent'; New discoveries include bizarre beast with 15 horns. ScienceDaily. University of Utah. 22 September 2010.
  96. Web site: Anonymous. A new Leptoceratopsid Ceratopsian From Campanian Cretaceous Appalachia. The Dragon's Tales. 14 September 2015. 14 September 2015.
  97. Longrich . Nicholas R. . 2016. A ceratopsian dinosaur from the Late Cretaceous of eastern North America, and implications for dinosaur biogeography . Cretaceous Research . 57 . 199–207 . 10.1016/j.cretres.2015.08.004. 2016CrRes..57..199L .
  98. Web site: Brantley. Mary Grace. Paleontologists make big dinosaur discovery in Mississippi. MSNewsNow. 14 September 2016. https://web.archive.org/web/20160831111745/http://www.msnewsnow.com/story/32562654/paleontologists-make-big-dinosaur-discovery-in-mississippi. 31 August 2016. dead.
  99. Web site: Fleet. Micah. Rare dinosaur tooth found in Mississippi. wapt.com. 16 WAPT News. 14 September 2016. 29 July 2016.
  100. Web site: David R.. Schwimmer. Was There a Southeastern Dinosaur Province in the Late Cretaceous?. 1 April 2016. Geological Society of America. 12 September 2016.
  101. Osi . Attila . Butler . Richard J. . Weishampel . David B. . A Late Cretaceous ceratopsian dinosaur from Europe with Asian affinities . Nature . 27 May 2010 . 465 . 7297 . 466–468 . 10.1038/nature09019 . 20505726 . 2010Natur.465..466O . 205220451 .
  102. LINDGREN . JOHAN . The First Neoceratopsian Dinosaur Remains from Europe . CURRIE . PHILIP J. . SIVERSON . MIKAEL . REESS . JAN . LINDGREN . FILIP . Palaeontology . 2007 . 50 . 4 . 929–937 . 10.1111/j.1475-4983.2007.00690.x . 2007Palgy..50..929L . 129733977 .
  103. Longrich . Nicholas . A ceratopsian dinosaur from the Late Cretaceous of eastern North America, and implications for dinosaur biogeography . Cretaceous Research . January 2016 . 57 . 199–207 . 10.1016/j.cretres.2015.08.004 . 2016CrRes..57..199L .
  104. Olson. Storrs L.. Parris. David C.. The Cretaceous Birds of New Jersey. Smithsonian Contributions to Paleobiology. 1987. 63. 63. 1–25. 10.5479/si.00810266.63.1.
  105. Wetmore. Alexander. 87807904. The Age of the Supposed Cretaceous Birds from New Jersey. The Auk. April 1930. 47. 2. 186–188. 4075921. 10.2307/4075921. free.
  106. Baird. Donald. Age of Fossil Birds from the Greensands of New Jersey. The Auk. April 1967. 84. 2. 260–262. 4083191. 10.2307/4083191. free.
  107. https://books.google.com/books?id=P_TB72RBLLMC&dq=lithornithid+new+jersey&pg=PA27 Palaeogene Fossil Birds
  108. http://escholarship.org/uc/item/6cm4v7h4 A lithornithid (Aves: Palaeognathae) from the Paleocene (Tiffanian) of southern California
  109. Bell . Alyssa . Irwin . Kelly J. . Davis . Leo Carson . Hesperornithiform Birds from the Late Cretaceous (Campanian) of Arkansas, USA . Transactions of the Kansas Academy of Science . September 2015 . 118 . 3 & 4 . 219–229 . 10.1660/062.118.0305 . 83921936 . 13 June 2019.
  110. Bono . R.K. . Clarke . J. . Tarduno . J.A. . Brinkman . Donald . A Large Ornithurine Bird (Tingmiatornis arctica) from the Turonian High Arctic: Climatic and Evolutionary Implications . Scientific Reports . 6 . 38876 . 10.1038/srep38876 . 27991515 . 2016 . 5171645 . 2016NatSR...638876B .
  111. Hou . 1999 . New hesperornithid (Aves) from the Canadian Arctic . Vertebrata PalAsiatica . 37 . 7. 228–233 .
  112. TYKOSKI . RONALD S. . FIORILLO . ANTHONY R. . An enantiornithine bird from the lower middle Cenomanian of Texas . Journal of Vertebrate Paleontology. January 2010 . 30. 1 . 288–292 . 10.1080/02724630903416068 . 2010JVPal..30..288T . 84037461 . free .
  113. Le Loeuff . J . 1991 . The Campano-Maastrichtian vertebrate faunas of southern Europe and their relationship with other faunas in the world; paleobiogeographic implications . Cretaceous Res. . 12 . 2. 93–114 . 10.1016/s0195-6671(05)80019-9 .
  114. Book: Holman. J. Alan. Fossil Snakes of North America: Origin, Evolution, Distribution, Paleoecology. 22 May 2000. Indiana University Press. Bloomington, Indiana. 376.
  115. Adrian . Brent . Smith . Heather F. . Noto . Christopher R. . Grossman . Aryeh . 2021-05-20 . An early bothremydid from the Arlington Archosaur Site of Texas . Scientific Reports . en . 11 . 1 . 9555 . 10.1038/s41598-021-88905-1 . 34017016 . 8137945 . 2021NatSR..11.9555A . 2045-2322.
  116. Gentry . A. D. . Kiernan . C. R. . Parham . J. F. . 2022 . A large non-marine turtle from the Upper Cretaceous of Alabama and a review of North American "Macrobaenids" . The Anatomical Record . 306 . 6 . 1411–1430 . 10.1002/ar.25054. 37158131 . 251698645 .
  117. Vaughn. Peter Paul. 1956. A Second Specimen of the Cretaceous Crocodile Dakotasuchus from Kansas. Transactions of the Kansas Academy of Science. 59. 3. 379–381. 10.2307/3626613. 3626613 . 0022-8443.
  118. Lee . Yuong–Nam . 1997 . The Archosauria from the Woodbine Formation (Cenomanian) in Texas . Journal of Paleontology . 71 . 6 . 1147–1156. 10.1017/S0022336000036088 . 1997JPal...71.1147L . 131923994 .
  119. 10.1080/02724634.2018.1486321. A new specimen of the alligatoroid Bottosaurus harlani and the early history of character evolution in alligatorids. 2018. Cossette. Adam P.. Brochu. Christopher A.. Journal of Vertebrate Paleontology. 38. 4. (1)-(22). 92801257.
  120. Adams. Thomas L.. Noto. Christopher R.. Drumheller. Stephanie K. 2018-09-25. A large neosuchian crocodyliform from the Upper Cretaceous (Cenomanian) Woodbine Formation of North Texas. Journal of Vertebrate Paleontology . 2021-11-22. 10.31233/osf.io/2ck7v . 240215516 .
  121. Adams. T.L. . Noto. C.R.. Drumheller. S. . 2017. A large neosuchian crocodyliform from the Upper Cretaceous (Cenomanian) Woodbine Formation of North Texas. Journal of Vertebrate Paleontology. 37 . 4 . e1349776. 10.1080/02724634.2017.1349776. 2017JVPal..37E9776A . 133647239 .
  122. Troxell. Edward L.. Thoracosaurus, A Cretaceous Crocodile. American Journal of Science. September 1925. 5. 10. 219–233. 1925AmJS...10..219T. 10.2475/ajs.s5-10.57.219.
  123. Brochu. Christopher A.. A new Late Cretaceous gavialoid crocodylian from eastern North America and the phylogenetic relationships of thoracosaurs. Journal of Vertebrate Paleontology. 5 January 2004. 24. 3. 610–633 . 10.1671/0272-4634(2004)024[0610:ANLCGC]2.0.CO;2. 131176447 .
  124. Brochu. Christopher A.. Parris. David C.. Grandstaff. Barbara Smith. Denton Jr.. Robert K.. Gallagher. William B.. A new species of Borealosuchus (Crocodyliformes, Eusuchia) from the Late Cretaceous–early Paleogene of New Jersey. Journal of Vertebrate Paleontology. 12 January 2012. 32. 1. 105–116 . 10.1080/02724634.2012.633585. 2012JVPal..32..105B . 83931184.
  125. Book: Schwimmer. David R.. King of the Crocodylians: The Paleobiology of Deinosuchus. 12 June 2002. Indiana University Press. Bloomington, IN. 240.
  126. Erickson. Gregory M.. Brochu. Christopher A.. How the 'terror crocodile' grew so big. Nature. 18 June 1999. 398. 6724. 205–206. 10.1038/18343. 1999Natur.398..205E. 4402210.
  127. Web site: Handwerk. Brian. Feces, Bite Marks Flesh Out Giant Dino-Eating Crocs. https://web.archive.org/web/20100327072948/http://news.nationalgeographic.com/news/2010/03/100323-giant-croc-crocodile-dinosaurs-deinosuchus-feces-poop. dead. 27 March 2010. National Geographic News. 25 March 2010. 25 March 2010.
  128. Cossette. A. Brochu. C. 2020-11-04. A systematic review of the giant alligatoroid Deinosuchus from the Campanian of North America and its implications for the relationships at the root of Crocodylia (project). 2021-11-22. MorphoBank datasets. 10.7934/p3782. 225240071.
  129. Brownstein. Chase Doran. 2019-04-01. First Record of a Small Juvenile Giant Crocodyliform and its Ontogenetic and Biogeographic Implications. Bulletin of the Peabody Museum of Natural History. 60. 1. 81. 10.3374/014.060.0104. 133563223 . 0079-032X.
  130. RIVERA-SYLVA. Héctor E.. FREY. Eberhard. GUZMÁN-GUTIÉRREZ. José Rubén. Evidence of predation on the vertebra of a hadrosaurid dinosaur from the Upper Cretaceous (Campanian) of Coahuila, Mexico. Carnets de Géologie. 2009. 1–7. 12 September 2016. 28 September 2016. https://web.archive.org/web/20160928015010/http://paleopolis.rediris.es/cg/CG2009_L02/. dead.
  131. Rivera-Sylva. Hector E.. W.E. Hone. David. Dodson. Peter. Bite marks of a large theropod on an hadrosaur limb bone from Coahuila, Mexico . Boletín de la Sociedad Geológica Mexicana . 2012. 64. 1. 157–161.
  132. Milan. J. Lucas. Spencer G.. Lockley. M G. Schwimmer. David R.. Bite Marks of the Giant Crocodylian Deinosuchus on Late Cretaceous (Campanian) Bones. New Mexico Museum of Natural History and Science Bulletin. 51. 183–190. January 2010.
  133. Harrell. Samantha D.. Schwimmer. David R.. Coprolites of Deinosuchus and other crocodylians from the Upper Cretaceous of western Georgia, USA. 2010. 1–7. New Mexico Museum of Natural History and Science Bulletin. 51.
  134. Book: R., Schwimmer, David. King of the crocodylians : the paleobiology of Deinosuchus. 2002. Indiana University Press. 0-253-34087-X. 488797149.
  135. Brownstein . Chase D. . Trace fossils on dinosaur bones reveal ecosystem dynamics along the coast of eastern North America during the latest Cretaceous . PeerJ . 6 . 11 June 2018 . 23 . 10.7717/peerj.4973 . 29910985 . 6001717 . free .
  136. Erickson . Bruce . Crocodilians of the Black Mingo Group (Paleocene) of the South Carolina Coastal Plain . Transactions of the American Philosophical Society . 1998 . 88 . 4 . 196–214 . 10.2307/1006674 . 1006674 .
  137. Cossette . Adam . Christopher . Christopher . A new specimen of the alligatoroid Bottosaurus harlani and the early history of character evolution in alligatorids . Journal of Vertebrate Paleontology . 3 April 2019 . 38 . 4 . (1)-(22) . 10.1080/02724634.2018.1486321 . 92801257 .
  138. Callahan . Wayne . A Nearly Complete Specimen of Hyposaurus Rogersii (Crocodylomorpha, Dyrosauridae) from the Late Cretaceous-Early Paleogene of New Jersey . Pellegrini . Rodrigo . Schein . Jason . Parris . David C. . Society of Vertebrate Paleontology . January 2015 . 10.13140/RG.2.1.2253.2724 . 4 January 2019.
  139. Adams . Thomas L. . Polcyn . Michael J. . Mateus . Octavio . Winkler . Dale A. . Jacobs . Louis L. . First occurrence of the long-snouted crocodyliform Terminonaris (Pholidosauridae) from the Woodbine Formation (Cenomanian) of Texas . Journal of Vertebrate Paleontology . May 2011 . 31 . 3 . 712–716 . 10.1080/02724634.2011.572938 . 2011JVPal..31..712A . 86061260 .
  140. Shimada . Kenshu . Parris . David C. . A Long-Snouted Late Cretaceous Crocodyliform, Terminonaris cf. T. browni, from the Carlile Shale (Turonian) of Kansas . Transactions of the Kansas Academy of Science . Spring 2007 . 110 . 1/2 . 107–115 . 20476300 . 10.1660/0022-8443(2007)110[107:ALLCCT]2.0.CO;2 . 86273062 .
  141. Schwimmer. David R.. Padian. Kevin. Woodhead. Alfred B.. First Pterosaur Records from Georgia: Open Marine Facies, Eutaw Formation (Santonian). Journal of Paleontology. 1304987. 59. 3. 674–676. 1985.
  142. Web site: Westfall. Aundrea. Pterosaurs. Encyclopedia of Alabama. 26 August 2016.
  143. Bairid. Donald. Galton. Peter M.. Pterosaur Bones from the Upper Cretaceous of Delaware. Journal of Vertebrate Paleontology. 4522837. 1. 1. 67–71. 1981. 10.1080/02724634.1981.10011880. 1981JVPal...1...67B .
  144. Harrell . T. Lynn Jr. . Gibson . Michael A. . Langston . Wann Jr. . A cervical vertebra of Arambourgiania philadelphiae (Pterosauria, Azhdarchidae) from the late Campanian micaceous facies of the Coon Creek Formation in McNairy County, Tennessee, USA . Bull. Alabama Mus. Nat. Hist. . 1 December 2016 . 33 . 94–103 .
  145. Web site: Gibson. Michael A.. Review of Vertebrate Diversity n the Coon Creek Formation Lagerstätte (Late Cretaceous) of Western Tennessee. Geological Society of America. 31 March 2008.
  146. S. Bennett . Christopher . Sexual dimorphism of Pteranodon and other pterosaurs, with comments on cranial crests . Journal of Vertebrate Paleontology . February 1992 . 12 . 4 . 422–434 . 10.1080/02724634.1992.10011472 . 1992JVPal..12..422B .
  147. Book: 10.1007/978-1-4020-9053-0_11 . Vertebrate Biostratigraphy of the Smoky Hill Chalk (Niobrara Formation) and the Sharon Springs Member (Pierre Shale) . High-Resolution Approaches in Stratigraphic Paleontology . 21 . 421–437 . Topics in Geobiology . 2008 . Carpenter . Kenneth . 978-1-4020-1443-7 .
  148. Andres . Brian . Myers . Timothy S. . Lone Star Pterosaurs . Earth and Environmental Science Transactions of the Royal Society of Edinburgh . 23 September 2013 . 103 . 3–4 . 383–398 . 10.1017/S1755691013000303 . 84617119 .
  149. S. Meyers . Timothy . Earliest occurrence of the Pteranodontidae (Archosauria: Pterosauria) in North America: new material from the Austin Group of Texas . Journal of Paleontology . November 2010 . 84 . 6 . 1071–1081 . 10.1666/09-082.1 . 2010JPal...84.1071M . 129049242 .
  150. Myers . T.S. . 2010 . Earliest occurrence of the Pteranodontidae (Archosauria: Pterosauria) in North America: New material from the Austin Group of Texas . Journal of Paleontology . 84 . 6. 1071–1081 . 10.1666/09-082.1 . 2010JPal...84.1071M . 129049242 .
  151. Myers . Timothy S. . 2010 . A new ornithocheirid pterosaur from the Upper Cretaceous (Cenomanian–Turonian) Eagle Ford Group of Texas . Journal of Vertebrate Paleontology . 30 . 1 . 280–287 . 10.1080/02724630903413099 . 2010JVPal..30..280M . 130367018 .
  152. An Appalachian population of neochoristoderes (Diapsida, Choristodera) elucidated using fossil evidence and ecological niche modelling. 10.1111/pala.12545. 2021. Dudgeon. Thomas W.. Landry. Zoe. Callahan. Wayne R.. Mehling. Carl M.. Ballwanz. Steven. Palaeontology. 64. 5. 629–643. 2021Palgy..64..629D . 237761128 .
  153. Baird. D.. Krause. D.W.. Late Cretaceous mammals east of the North American Western Interior Seaway. Journal of Paleontology. 1 May 1979. 53. 3. 13 September 2016.
  154. Web site: Denton. Robert K. Jr.. Late Cretaceous Mammals of the Carolinas. gsa.confex.com. The Geological Society of America. 1 April 2016.
  155. https://gsa.confex.com/gsa/2014SE/webprogram/Paper235341.html Late Cretaceous Multituberculates of the Carolinas: My...What Big Teeth You Have!
  156. Grandstaff . B. S. . Parris . D. C. . Denton . R. K. Jr. . Gallagher . W. B. . 1992 . Alphadon (Marsupialia) and Multituberculata (Allotheria) in the Cretaceous of eastern North America . Journal of Vertebrate Paleontology . 12 . 2. 217–222 . 10.1080/02724634.1992.10011450. 1992JVPal..12..217G .
  157. Denton, R. K. Jr., & O’Neill, R. C., 2010, A New Stagodontid Metatherian from the Campanian of New Jersey and its implications for a lack of east-west dispersal routes in the Late Cretaceous of North America. Jour. Vert. Paleo. 30(3) supp.
  158. Martin . JE . Case . JA . Jagt . JWM . Schulp . AS . Mulder . EWA . 2005 . A New European Marsupial Indicates a Late Cretaceous High-Latitude Transatlantic Dispersal Route. Journal of Mammalian Evolution. 12 . 3–4. 495–511 . 10.1007/s10914-005-7330-x. 39202343 .
  159. Krause . David W. . Baird . Donald . Late Cretaceous Mammals East of the North American Western Interior Seaway . Journal of Paleontology . May 1979 . 53 . 3 . 562–565 . 1303997.
  160. Emry . Robert J. . Archibald . J. David . Smith . Charles C. . A Mammalian Molar from the Late Cretaceous of Northern Mississippi . Journal of Paleontology . September 1982 . 55 . 5 . 953–956 . 1304518.
  161. Grandstaff . Barbara S. . Parris . David C. . Denton . Robert K. Jr. . Gallagher . William B. . Alphadon (Marsupialia) and Multituberculata (Allotheria) in the Cretaceous of Eastern North America . Journal of Vertebrate Paleontology . 10 June 1992 . 12 . 2 . 217–222 . 4523441 . 10.1080/02724634.1992.10011450 . 1992JVPal..12..217G .
  162. Web site: OCEANS OF KANSAS PALEONTOLOGY Fossils from the Late Cretaceous Western Interior Sea . 12 June 2019.
  163. Web site: Everhart . Mike . A Field Guide to Fossils of the Smoky Hill Chalk Part 2: Sharks and Bony Fish . Oceans of Kansas . 12 June 2019.
  164. Web site: Everhart . Mike . A Field Guide to the Smoky Hill Chalk Part 1: Invertebrates . Oceans of Kansas . 12 June 2019.
  165. Web site: Everhart . Mike . A Field Guide to Fossils of the Smoky Hill Chalk Part 3: Marine Reptiles . Oceans of Kansas . 12 June 2019.
  166. Web site: Everhart . Mike . A Field Guide to Fossils of the Smoky Hill Chalk Part 4: Pteranodons, Birds, and Dinosaurs . Oceans of Kansas . 12 June 2019.
  167. Web site: Everhart . Mike . A Field Guide to Fossils of the Smoky Hill Chalk Part 5: Coprolites, pearls, fossilized wood and other remains. . Oceans of Kansas . 12 June 2019.
  168. Web site: Everhart . Mike . M. J. EVERHART'S MARINE REPTILE REFERENCES: MOSASAURS, PLESIOSAURS, TURTLES AND OTHER VERTEBRATE FAUNA . Oceans of Kansas . 12 June 2019.
  169. Web site: Everhart . Mike . Other references about fossils from the Late Cretaceous Western Interior Sea, including: Invertebrates, sharks and fish . Oceans of Kansas . 12 June 2019.
  170. Kiernan . Caitlin R. Kiernan . Stratigraphic distribution and habitat segregation of mosasaurs in the Upper Cretaceous of western and central Alabama, with an historical review of alabama mosasaur discoveries . Journal of Vertebrate Paleontology. 2002 . 22 . 1 . 91–103 . 10.1671/0272-4634(2002)022[0091:SDAHSO]2.0.CO;2 . 130280406 . 0272-4634 .
  171. KIERNAN . CAITLIN R. . Stratigraphic distribution and habitat segregation of mosasaurs in the Upper Cretaceous of western and central Alabama, with an historical review of alabama mosasaur discoveries . Journal of Vertebrate Paleontology . 2002 . 22 . 1 . 91–103 . 10.1671/0272-4634(2002)022[0091:SDAHSO]2.0.CO;2 . 130280406 .
  172. Parris . David C. . 1974 . Additional Records of Plesiosaurs from the Cretaceous of New Jersey . Journal of Paleontology . 48 . 1 . 32–35 . 1303102 . 0022-3360.
  173. Gallagher . William B. . Campbell . Carl E. . Jagt . John W. M. . Mulder . Eric W. A. . Mosasaur (Reptilia, Squamata) Material from the Cretaceous-Tertiary Boundary Interval in Missouri . Journal of Vertebrate Paleontology . 2005 . 25 . 2 . 473–475 . 4524462 . 10.1671/0272-4634(2005)025[0473:MRSMFT]2.0.CO;2 . 130130952 .
  174. Rapp . William F. . Check List of the Fossil Fishes of New Jersey . Journal of Paleontology . 1946 . 20 . 5 . 510–513 . 1299280 .
  175. Case . Gerald R. . Schwimmer . David R. . 131268461 . Late Cretaceous fish from the Blufftown Formation (Campanian) in western Georgia . Journal of Paleontology . March 1988 . 62 . 2 . 290–301 . 10.1017/S0022336000029942 . 1988JPal...62..290C .
  176. Cockerell . T. D. A. . Stanton . T. W. . SOME AMERICAN CRETACEOUS FISH SCALES, WITH NOTES ON THE CLASSIFICATION AND DISTRIBUTION OF -CRETACEOUS FISHES . United States Geological Survey Bulletin . 1915 . 603 . 34–57 . 20 December 2019.
  177. Stringer . Gary L. . Oman . Luke D. . Badger . Robert F. . Woodbury Formation (Campanian) in New Jersey yields largest known Cretaceous otolith assemblage of teleostean fishes in North America . Proceedings of the Academy of Natural Sciences of Philadelphia . 28 November 2016 . 165 . 1 . 15–36 . 10.1635/053.165.0101 . 132425261 .
  178. Lauginiger . Edward M. . Cretaceous Fossils from the Chesapeake and Delaware Canal . Delaware Geological Survey . September 1988 . 61 .
  179. Lidgard . Scott . Crane . Peter R. . Angiosperm Diversification and Cretaceous Floristic Trends: A Comparison of Palynofloras and Leaf Macrofloras . Paleobiology . Winter 1990 . 16 . 1 . 77–93 . 2400934 . 10.1017/S009483730000974X . 1990Pbio...16...77L . 88231136 .
  180. Web site: 22A; Veatch & Stephenson 1911 Cretaceous Material . Georgias Fossils . 11 June 2019.
  181. Book: Murray . Minnesota . 1974 . 162–163.
  182. Sims . Hallie J. . Herendeen . Patrick S. . Lupia . Richard . Christopher . Raymond A. . Crane . Peter R. . Fossil flowers with Normapolles pollen from the Upper Cretaceous of southeastern North America . Review of Palaeobotany and Palynology . August 1999 . 106 . 3–4 . 131–151 . 10.1016/s0034-6667(99)00008-1 . 1999RPaPa.106..131S .
  183. V. Demers-Potvin . Alexandre . C. E. Larsson . Hans . Palaeoclimatic reconstruction for a Cenomanian-aged angiosperm flora near Schefferville, Labrador . Palaeontology . 62 . 6 . 1027–1048 . 2 August 2019 . 10.1111/pala.12444 . 2019Palgy..62.1027D . 240760598 .
  184. Herendeen . Patrick S. . Magallon-Puebla . Susana . Lupia . Richard . R. Crane . Peter . Kobylinska . Jolanta . A Preliminary Conspectus of the Allon Flora from the Late Cretaceous (Late Santonian) of Central Georgia, U.S.A. . Annals of the Missouri Botanical Garden . 1999 . 86 . 2 . 407–471 . 10.2307/2666182 . 2666182 .
  185. Crane . Peter R. . Dilcher . David L. . Lesqueria: An Early Angiosperm Fruiting Axis From the Mid-Cretaceous . Annals of the Missouri Botanical Garden . 1984 . 71 . 2 . 384–402 . 10.2307/2399031 . 2399031 .
  186. Blackwell . W. H. . Fossil Ponderosa-like Pine Wood from the Upper Cretaceous of North-east Mississippi . Annals of Botany . January 1984 . 53 . 1 . 133–136 . 42756870 . 10.1093/oxfordjournals.aob.a086664 .
  187. Mickell . James E. . Grexlupus carolinensis, A NEW PROBABLE LAURACEOUS FRUIT FROM THE LATE CRETACEOUS OF NORTH CAROLINA . Journal of the Elisha Mitchell Scientific Society . Spring 1996 . 112 . 1 . 1–6 . 24335383 .
  188. Frederiksen . Norman O. . Late Cretaceous and Tertiary Floras, Vegetation, and Paleoclimates of New England . Rhodora . January 1989 . 91 . 865 . 25–48 . 23312460 .
  189. Berry . Edward Wilbur . The Upper Cretaceous and Eocene floras of South Carolina and Georgia . US Government Printing Office . 1914 . 84 .