All about dinosaurs, fossils and prehistoric animals by Everything Dinosaur team members.

Articles, features and information which have slightly more scientific content with an emphasis on palaeontology, such as updates on academic papers, published papers etc.

29 06, 2026

Scientists Formally Describe the First Dinosaur Fossil Found in Antarctica

By |2026-06-30T06:38:08+01:00June 29th, 2026|Categories: Palaeontological articles|0 Comments

Scientists have formally described the first dinosaur fossil found in Antarctica. The remarkable discovery is a single vertebra from a Late Cretaceous titanosaur. Although the fossil was collected more than forty years ago, researchers have only recently confirmed its identity.  The first dinosaur fossil found in Antarctica described in the journal Acta Palaeontologica Polonica.

The Late Cretaceous Antarctic titanosaur life reconstruction.

A life reconstruction of the titanosaur. The single caudal vertebra may have come from a dwarf titanosaur species or perhaps a titanosaur that was not fully grown. Picture credit: Andrew McAfee, Carnegie Museum of Natural History.

Picture credit: Andrew McAfee, Carnegie Museum of Natural History

The First Dinosaur Fossil Found in Antarctica Described

The fossil was discovered in 1985 by British Antarctic Survey geologist Dr Mike Thomson during an expedition Ross Island. At the time, the team focused on finding marine fossils such as ammonites. These fossils help scientists date ancient rock layers. However, one unusual bone collected during the expedition has now proved to be Antarctica’s first recognised dinosaur fossil.

The survey team's camp during the 1985 expedition to James Ross Island (Antarctica).

A photograph of the geology field camp on James Ross Island taken in 1985. Picture credit: Mike Thomson (British Antarctic Survey).

Picture credit: Mike Thomson (British Antarctic Survey)

Researchers identified the specimen as a tail vertebra from a titanosaur. Titanosaurs belonged to a diverse and geographically widespread group of sauropod dinosaurs. These plant-eating giants had long necks, long tails and pillar-like limbs. Some species ranked among the largest land animals ever to walk the Earth. The Antarctic animal, however, measured only around six to seven metres long. It was either a juvenile, or it possibly represented a relatively small species.

The Santa Marta Formation

The fossil came from the Santa Marta Formation, a sequence of Late Cretaceous rocks dating to approximately 82 million years ago (Campanian faunal stage). At that time, Antarctica looked very different. Instead of being buried beneath thick ice, much of the continent supported lush temperate forests. Dinosaurs, alongside a wide variety of other animals and plants, thrived in this much warmer environment.

Antarctic titanosaur caudal vertebra.

Eutitanosauria indet. (BAS D.8621.25) from the Upper Cretaceous (lower Campanian) Beta Member (≈ upper Lachman Crags Member) of the Santa Marta Formation of James Ross Island, Antarctica. Fossil is shown in anterior view. Picture credit: The Trustees of the Natural History Museum, London.

Picture credit: The Trustees of the Natural History Museum, London

Interestingly, the vertebra was preserved in marine sediments. Scientists think the dinosaur died on land before its body drifted out to sea. Eventually, the remains settled onto the seabed where they became buried and fossilised.

Commenting on the significance of this single fossil bone, Dr Mark Evans (British Antarctic Survey) stated:

“This fossil was found by Dr Mike Thomson, one of the true pioneers of Antarctic geology, whose work helps us date all fossil finds across the Antarctic Peninsula today. When I first spotted this bone in our collections a few years ago, I suspected it was a dinosaur. After looking at it properly, I thought it was probably a titanosaur tail vertebra. Looking back at Mike’s notebooks, he knew it was a large reptile – so it’s very special to confirm his find forty years later. We’ve also been able to compare it against dinosaur fossils that have been found since.”

Antarctica preserves very few dinosaur fossils. Today, almost the entire continent lies beneath a vast ice sheet. As a result, very little fossil-bearing rock remains exposed. Most discoveries come from isolated coastal outcrops and mountain ranges where ancient rocks reach the surface. Consequently, every new specimen provides valuable information about Antarctica’s prehistoric ecosystems.

The titanosaur caudal vertebra shown in posterior view.

First ever dinosaur remains found in Antarctica described. A photograph of the single, caudal vertebra (BAS D.8621.25) shown in posterior view. Picture credit: The Trustees of the Natural History Museum, London.

Picture credit: The Trustees of the Natural History Museum, London

By comparing the vertebra with more recently discovered sauropod fossils, researchers confirmed that the bone belonged to a titanosaur.

An Important Milestone in Antarctic Exploration

Professor Paul Barrett of the Natural History Museum explained that the fossil represents an important milestone in Antarctic exploration. Furthermore, he suggested that many more dinosaur discoveries could await scientists as additional fossil-bearing rocks become exposed.

This discovery also improves our understanding of dinosaur evolution across the southern continents. During the Late Cretaceous, Antarctica formed part of the southern supercontinent Gondwana. Land connections linked Antarctica with South America and Australasia. Therefore, fossils such as this provide important evidence for the movement and distribution of dinosaurs across these ancient landmasses.

The first dinosaur fossil found in Antarctica may consist of only a single vertebra. Nevertheless, it represents a landmark discovery. Moreover, it highlights how museum collections continue to yield important scientific discoveries decades after fossils were first collected.

Everything Dinosaur acknowledges the assistance of a media release from the London Natural History Museum in the compilation of this article.

The scientific paper: “A titanosaurian sauropod dinosaur from the Upper Cretaceous of Antarctica” by Paul M. Barrett, Philip D. Mannion, Samantha L. Beeston, Matthew C. Lamanna, Brett Clark, Alejandro Otero, José P. O’gorman and Mark Evans published in Acta Palaeontologica Polonica.

For museum quality models of titanosaurs and other sauropods: Dinosaur and Prehistoric Animal Models.

19 06, 2026

Pterosaurs May Have Possessed Iridescent Pycnofibres

By |2026-06-21T12:34:59+01:00June 19th, 2026|Categories: Palaeontological articles|0 Comments

New research suggests that colourful tapejarid pterosaurs may have been even more spectacular than previously imagined. A recently published study proposes that some of these flying reptiles possessed iridescent pycnofibres that produced shimmering colours. As a result, these structures may have played an important role in visual signalling and display.

The bodies of pterosaurs, the first vertebrates to achieve powered flight, are covered with integumentary filaments (pycnofibres). They are thought to be homologous with feathers associated with the Dinosauria.

CollectA Deluxe Caiuajara with moveable jaw.

The Age of Dinosaurs Deluxe Caiuajara pterosaur figure with a moveable jaw. Tapejarid pterosaurs like Caiuajara have been depicted with colourful crests, however, a recent study (May 2026) proposes that the pycnofibres covering their bodies may have been iridescent.

The image (above) shows the CollectA Supreme Deluxe Caiuajara figure.  It is pronounced – Kay-you-ah-jar-rah.  CollectA have introduced an extensive range of beautiful pterosaur scale models.

To view the CollectA Deluxe model range: Scale Models of Pterosaurs and Other Prehistoric Animals.

Colourful Tapejarid Pterosaurs

The Tapejaridae were a geographically widespread Early Cretaceous pterosaur family with probable Asian origins.  Tapejarid fossil material is known from the UK, Europe, Africa, South America and possibly from North America too.  All known tapejarids were edentulous (lacked teeth). These pterosaurs are famed for their large and flamboyant crests.  A recently published paper suggests that pycnofibres covering their bodies may have been capable of iridescence.  If this is the case, they would have been extremely colourful.

To read a blog post from 2020 about the discovery of a tapejarid pterosaur in the Wessex Formation (Wightia declivirostris)A Terrific Tapejarid from the Isle of Wight.

Significantly, the recently published paper reveals evidence of something remarkable.

Scientists identified a layered arrangement of melanosomes within the pycnofibres of a tapejarid specimen. The fossil material represents Sinopterus dongi from the Early Cretaceous Jehol Biota.  It had not been formally studied previously. Importantly, this internal structure of melanosomes resembles the organisation seen in the iridescent feathers of living birds. In modern species, such arrangements generate structural colours that can shift and shimmer when viewed from different angles. Consequently, the researchers propose that these pterosaurs exhibited colours ranging from green to magenta.

Did Iridescence Appear Early in the Evolution of Integumentary Filaments?

The research also has wider implications. According to the authors, this discovery indicates that the capacity for producing iridescence evolved very early in the evolution of integumentary filaments. Therefore, complex colour signalling and visual displays may have originated long before the appearance of birds.

In addition, the research provides further evidence that pycnofibres were multifunctional. Although they probably helped with insulation and thermoregulation, they also appear to have been used for communication and display. This finding supports the idea that visual signalling played a significant role in pterosaur behaviour. After all, if you are a tapejarid with a bold crest, then why not have iridescent pycnofibres too?  The Early Cretaceous skies could have been filled with colourful tapejarid pterosaurs.

Highlighting the importance of this recent research, Mike from Everything Dinosaur commented:

“Large head crests already made tapejarids some of the most distinctive pterosaurs known. Now, scientists suggest that these reptiles may have enhanced their appearance with dazzling colours. Such displays could have helped attract mates, establish dominance or identify members of the same species.”

Implications for Palaeoartists and Model Makers

Most pterosaurs very probably had excellent colour vision.  Using colour for signalling, social status and display makes sense.  This has implications for model makers and palaeoartists. As a result of this study, colourful tapejarid pterosaurs may have looked far more vibrant than traditionally portrayed. They might have rivalled many modern birds in both appearance and visual complexity.

Wild Safari Prehistoric World Tapejara model.

A model of Tapejara imperator (Safari Ltd)

The image (above) shows a model of a tapejarid pterosaur (Tapejara imperator).  Most models have bright crests, but the pycnofibres tend to be plain in comparison. The conclusions from this study suggest a re-think when it comes to pterosaur colouration.

The paper highlights how exceptionally preserved fossils continue to transform our understanding of prehistoric life. Moreover, it demonstrates that the skies of the Cretaceous Period may have been filled with flying reptiles adorned with brilliant, iridescent colours.

The scientific paper: “Iridescence in pterosaur pycnofibers and the evolution of integumentary coloration” by Zelin Wu, Liliana D’ Alba, Chang-Fu Zhou, Julia A. Clarke, Jinhua Li, Matthew D. Shawkey and Quanguo Li published in bioRxiv.

The award-winning Everything Dinosaur website: Models of Pterosaurs and Other Prehistoric Animals.

17 06, 2026

New Study Reveals Different Growth Strategies in Tiny Dimetrodon Species

By |2026-06-17T06:29:38+01:00June 17th, 2026|Categories: Palaeontological articles|0 Comments

A newly published study examining the growth rates of Dimetrodon teutonis and Dimetrodon natalis has provided a fresh perspective on a famous, primitive synapsid. Researchers have discovered that the smallest known species of Dimetrodon achieved their diminutive size in contrasting ways. The study provides fresh insights into the lives of these iconic sail-backed predators that roamed the Earth millions of years before the dinosaurs evolved.

The Dimetrodon genus comprises several species. Most of these species grew into large predators more than three metres in length.  For example, Dimetrodon grandis measured about 3.2 metres long and weighed approximately 250 kilograms. However, a few species were much smaller. An international team of researchers has now investigated how these animals evolved their reduced body size.

Dimetrodon teutonis – The Smallest Known Dimetrodon Species

The study focused on two species. One is Dimetrodon natalis from North America. The other is Dimetrodon teutonis from the Bromacker fossil site in Germany. This German species is significant because it is the only known Dimetrodon discovered outside North America.

For many years, D. natalis was regarded as the smallest species. However, D. teutonis turned out to be even smaller.

  • Dimetrodon natalis – named in 1936 by Romer from earlier work by Cope. It measures about 1.7 metres long with an estimated bodyweight of 38 kilograms*.
  • Dimetrodon teutonis – named in 2001 (Berman, Reisz, Martens and Henrici) and measuring around 70 cm in length and weighing approximately 24 kilograms*.

Limb bone midshaft circumference analysis of fossil material used in this research suggests that the individual animals representing D. teutonis had a body weight of 6.3 to 6.8 kilograms. In contrast, the same analysis method provides body weight estimates for the D. natalis individuals between 20.9 and 21.7 kilograms.

To learn more about these animals, the scientists examined the microscopic structure of fossil bones. Bone tissue preserves information about growth rates and development. Therefore, it can reveal important details about the life history of extinct species.

Bone Histology Reveals Different Life Histories

The results have been published in the academic journal “Scientific Reports”. They show that the two species followed contrasting growth strategies. Dimetrodon natalis appears to have grown quickly. However, it stopped growing at an early age. As a result, it reached adulthood while remaining small. In contrast, Dimetrodon teutonis grew much more slowly. It continued developing over a longer period. The researchers suggest that it probably reached sexual maturity later in life.

Dimetrodon teutonis and Dimetrodon natalis growth study.

Bone histology comparison between D. teutonis and D. natalis demonstrates fundamentally different bone microanatomy. The humerus cross section of D. teutonis (left) exhibits thin cortices composed of poorly vascularized parallel-fibered bone. This suggests slow growth and delayed maturity. In contrast, the bone histology of D. natalis (right) shows thick and highly vascularised woven to parallel-fibered bone cortices. Picture credit: Frederik Spindler, PALAEONAVIX.

Picture credit: Frederik Spindler, PALAEONAVIX

Dr Tom Hübner, curator and head of the Bromacker project at the Friedenstein Foundation Gotha, commented:

“This work demonstrates that bone histology can provide direct insights into the palaeobiology of long-extinct animals. Who would have thought that these two small species had such different life histories?”

Different Environments Influenced Growth

According to the research team, environmental conditions played a key role. North American Dimetrodon species lived in humid lowland habitats. These ecosystems contained abundant food resources. In addition, predators were common. Under these conditions, rapid growth would have offered advantages for survival and reproduction.

The Bromacker ecosystem in Germany presented different challenges. Seasonal droughts and limited resources shaped this environment. Fossilised burrows suggest that potential prey animals retreated underground during dry periods. Consequently, slower growth may have helped Dimetrodon teutonis cope with fluctuating food supplies.

Dr Aurore Canoville explained:

“These new findings once again highlight the uniqueness of the Bromacker locality compared with other Early Permian fossil sites. They make Dimetrodon even more fascinating. Long before dinosaurs dominated the Earth, these early synapsids were already responding in remarkably flexible ways to climate, food availability, competition and predation.”

Unique Insights from the Bromacker Fossil Site

Professor Jörg Fröbisch of the Museum für Naturkunde Berlin emphasised the importance of the discovery.

He stated:

“These fascinating results provide an increasingly complete picture of the Bromacker ecosystem and its enormous potential for many decades of future research.”

The study highlights how adaptable these early synapsids were. It also demonstrates the importance of the Bromacker fossil locality. Thanks to discoveries such as these, scientists continue to improve our understanding of life during the Early Permian.

Unique fossil provides information on Bromacker food web: Regurgitated Pellet from a Dimetrodon.

In the paper, the researchers state that the largest known species of Dimetrodon is D. angelensis.  It is stated that this species was up to 4.6 metres long and weighed 250 kilograms.

Everything Dinosaur acknowledges the assistance of a media release from the Museum für Naturkunde Berlin in the compilation of this article.

The scientific paper: “Contrasting life history in the diminutive Dimetrodon species from North America and Germany” by Aurore Canoville, Philipp L. Knaus, Lorenzo Marchetti and Jörg Fröbisch published in Scientific Reports.

The award-winning Everything Dinosaur website: Models of Palaeozoic Creatures and Other Prehistoric Animals.

15 06, 2026

Ground-breaking Study Strengthens the Case for Lips in Dinosaurs

By |2026-06-16T15:38:36+01:00June 15th, 2026|Categories: Palaeontological articles|0 Comments

The debate about lips in dinosaurs continues.  Whether dinosaurs possessed extraoral tissue remains controversial. However, a remarkable new study has added substantial support to the idea that most dinosaurs possessed extraoral tissues that covered and protected their teeth. A new study, published in the journal “Palaeontology” provides compelling evidence that lips were the ancestral condition in dinosaurs and many other reptiles.

Researchers led by Rafael Terras (Programa de Pós-Graduação em Ciências Ambientais, Universidade Comunitária da Região de Chapecó, Chapecó, Brazil), have examined Triassic archosaurs from Brazil. Their findings suggest that lips in dinosaurs were not an unusual feature. Instead, they may represent the ancestral condition for the entire Sauropsida, the group that includes reptiles and birds.

Importantly, this study does not stand alone. Rather, it builds upon previous work by researchers such as Robert Bakker, Thomas Paul, Casey Holliday, Mark Witton and Thomas Cullen. Consequently, the scientific case for lips in dinosaurs continues to grow.

A Debate That Goes Back More Than a Century

The idea of lips in dinosaurs is not new. In the 1920s, palaeontologist Charles Gilmore suggested that openings in the jaw of Ceratosaurus transmitted nerves and blood vessels to the lips. Later, Robert Bakker proposed that many dinosaurs possessed thin, immobile lips similar to those seen in living lizards. Ironically, the advent of cinema and the need to make dinosaurs scary by showing their teeth could have popularised non-lipped dinosaurs with the public.

More recently, the landmark 2023 study by Cullen and colleagues demonstrated that theropod teeth show little evidence of the wear expected if they had remained permanently exposed. Their work also highlighted similarities between theropod skull anatomy and living squamates.

To read more about the 2023 study: New Paper Suggests Dinosaurs Had Lips.

Now, this new study extends these observations far beyond the Theropoda.

Studying Triassic Archosauromorphs from Brazil

The researchers examined numerous Triassic archosaurs from southern Brazil. These included early dinosaurs and several crocodile-line relatives.

They found several features associated with covered teeth.  For example, the team examined the location of foramina (tiny openings in the skull bones which are location points for nerves).

The researchers identified the following, consistent characteristics:

  • rows of horizontally arranged facial foramina.
  • fewer than one hundred foramina per rostral bone.
  • vertically orientated teeth.
  • a lack of interlocking teeth.
  • uniform enamel thickness.
  • no evidence of exposed dentine.
  • a positive relationship between skull length and tooth crown height.

These characteristics closely resemble those seen in living lizards (lepidosaurs) rather than modern crocodilians. As a result, the authors concluded that labial scales and extensive gingiva (soft tissue that supports the teeth – gums) probably enclosed the teeth.

Foramina in selected Triassic saurischians provides further evidence for lips in dinosaurs.

Foramina in selected Triassic saurischians. A, Buriolestes (ULBRA PVT 280). B, Buriolestes (CAPPA/UFSM 0035). C, Pampadromaeus (ULBRA PVT 016). D, Gnathovorax (CAPPA/UFSM 0009). E, Unaysaurus (UFSM 11069). F, Macrocollum (CAPPA/UFSM 0001a). G, Gnathovorax (CAPPA/UFSM 0009). H, Macrocollum (CAPPA/UFSM 0001d). Abbreviations: edf, ellipsoid dentary foramen; emf, ellipsoid maxillary foramen; faaf, foramen anterior to the maxillary fenestra; fdaf, foramen dorsal to the antorbital fenestra; gif, groove-inserted foramen; odf, oval dentary foramen; omf, oval maxillary foramen; opmf, oval premaxillary foramen; sbg, subnarial gap; sf, subnarial foramen. Scale bars represent: 10 mm (A–C, E, H); 25 mm (D, F, G). Picture credit: Terras et al.

Picture credit: Terras et al

Tooth Histology Provides Important Clues for Lips in Dinosaurs

The researchers also examined thin sections of fossil teeth. They discovered that enamel thickness remained consistent around the crowns. Furthermore, the dentine showed no signs of wear. This condition contrasts strongly with crocodilians, whose exposed teeth experience significant abrasion. Therefore, the teeth of these Triassic archosaurs appear to have remained hydrated and protected.

This conclusion mirrors the findings published by Cullen and colleagues in the 2023 paper. Consequently, independent lines of evidence are converging on the same answer.

Studying the Pseudosuchian Prestosuchus

One of the most intriguing aspects of the study concerns the giant pseudosuchian Prestosuchus. This large, terrestrial predator possessed a distinctive gap between the upper and lower jaws. At first glance, this arrangement might suggest permanently exposed teeth. However, the researchers argue otherwise. They propose that a mandibular gap existed between the jaws. Soft tissues and gingiva would have occupied this space and maintained a complete oral seal. In effect, the teeth remained covered despite the unusual skull shape.

Lips in the giant pseudosuchian Prestosuchus. The research team proposes that Prestosuchus had extraoral tissue.

Prestosuchus skulls and reconstructions. A, ULBRA PVT 281 crushed skull in right lateral view. B, reconstruction of UFRGS PV 0629 T in right lateral view (mirrored) with a mandibular gap; modified from Mastrantonio et al. (2019). C–D, life reconstructions of ULBRA PVT 281: C, in right lateral view with a closed mouth displaying the oral seal; D, in frontal view with an open mouth displaying the oral rim; artwork by Matheus F. Gadelha used with permission. Scale bars represent: 300 mm (A, C, D); 100 mm (B). Picture credit: Terras et al with illustrations by Matheus F. Gadelha.

Picture credit: Terras et al with illustrations by Matheus F. Gadelha

This interpretation is significant. It demonstrates that specialised skull anatomy does not necessarily imply exposed teeth. Moreover, it suggests that lips could be retained even in large-bodied predators with unusual cranial morphology.

Prestosuchus (P. chiniquensis) is an extinct archosaur more closely related to extant crocodilians than to the Dinosauria. Size estimates vary but it could have reached a length of five metres or more. It was one of the largest Triassic pseudosuchians and an apex predator.

New for 2019 the Wild Safari Prehistoric World Prestosuchus.

The Wild Safari Prehistoric World Prestosuchus model.

The image (above) shows a model of the Triassic predator Prestosuchus.  This model was introduced in 2019.  The model has exposed teeth and no extraoral tissue.  It was made prior to the recent research suggesting the presence of lips in dinosaurs and other archosaurs.  The Prestosuchus model is from the Wild Safari Prehistoric World range of figures.

Wild Safari Prehistoric World: Prehistoric Animal Models and Figures.

Lips in Specialised Archosauromorphs

The authors also considered a number of highly specialised forms. They concluded that lips probably occurred in a wide variety of archosaurs.  For example, the researchers suggest that Triassic theropods had lips, along with sauropodomorph dinosaurs.  In addition, they propose that ornithosuchids (pseudosuchian archosaurs – crocodilian lineage) had lips.  Furthermore, the researchers propose that proterosuchids (basal archosaurs) also had extraoral tissue.  It is suggested that phytosaurs had lips too. Some archosauromorphs evolved additional keratinous coverings. These structures formed primitive beaks (rhamphothecae).

Illustration of Triassic archosauromorphs shown with an oral seal.

Triassic archosauromorphs reconstructed with labial scales and the oral seal in lateral view. A, Gnathovorax (CAPPA/UFSM 0009; Herrerasauria). B, Pampadromaeus (ULBRA PTV 016; Sauropodomorpha). C, Machaeroprosopus (NMMNH P-4983; Phytosauria). D, Riojasuchus (PVL 3827; Ornithosuchidae). E, Proterosuchus (NMQR 880; Proterosuchidae). F, Silesaurus (ZPAL Ab III/361; Silesauridae). G, Venetoraptor (CAPPA/UFSM 0356; Lagerptidae). H, ‘Hyperodapedon’ (ULBRA PVT 053; Rhynchosauria). I, Prestosuchus (ULBRA PTV 281; Loricata). Artwork by Matheus F. Gadelha used with permission. Scale bars represent: 50 mm (A, D); 20 mm (B, F); 100 mm (C, H); 30 mm (E); 10 mm (G); 300 mm (I). Picture credit: Terras et al with illustrations by Matheus F. Gadelha.

Picture credit: Terras et al with illustrations by Matheus F. Gadelha

A Complex Picture

The evolution of facial tissues in archosaurs appears to have been far more complex than previously thought.  However, extraoral soft tissues such as lips were probably the ancestral condition. According to the authors of the study, lips represent the primitive condition for the Sauropsida. Therefore, the common ancestor of reptiles and birds likely possessed covered teeth.

If correct, exposed teeth evolved later.  Extant crocodilians would represent a more derived branch of the Archosauria. Their exposed dentition and highly sensitive facial skin appear to be derived adaptations rather than the ancestral state. This finding reverses a common assumption.  However, the debate about lips in dinosaurs and their near relatives is likely to continue.

Instead of asking why dinosaurs had lips, researchers may need to explain why crocodilians lost them.

A Growing Scientific Consensus

No single paper or study can settle such a complex question. Nevertheless, the evidence continues to accumulate. Studies of facial foramina, tooth wear, enamel thickness and skull proportions increasingly point in the same direction. Taken together, they indicate that most dinosaurs probably possessed extraoral tissues covering their teeth. As a result, reconstructions showing permanently exposed teeth may eventually become less common.

This study is significant because it suggests origins for this condition originated much earlier in archosaur evolution. Consequently, it provides fresh evidence that covered teeth were widespread among early members of the Archosauria. Furthermore, it strengthens the idea that the familiar crocodilian condition evolved later.

Nile crocodile on Display

The head of a stuffed crocodile specimen (Nile crocodile) on display at the London Natural History Museum. The lack of extraoral tissue (lips) in this archosaur might be a derived condition. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Mike from Everything Dinosaur commented:

“This exciting new research adds another important piece to the puzzle. Evidence supporting lips in dinosaurs has been steadily accumulating for many years. The research team have shown that these soft tissues probably have much deeper evolutionary roots than previously thought. Their work strengthens the view that covered teeth represented the ancestral condition in dinosaurs and many of their close relatives. As a result, palaeoartists and scientists are gaining an increasingly detailed picture of how these remarkable animals actually looked.”

Everything Dinosaur acknowledges the assistance of the study’s corresponding author in the compilation of this article.

The scientific paper: “Inferred presence of extraoral tissues in Triassic archosauromorphs and the evolutionary implications for the clade Sauropsida” by Rafael Terras, Jaqueline Borger, Manuelle O. P. Almeida, Silvia Bettin, Owen A. Higgins, Giulia Marciani, Stefano Benazzi, Rodrigo T. Müller, Leonardo Kerber and Mirian Carbonera published in Palaeontology.

The Everything Dinosaur website: Museum Quality Models of Archosaurs.

14 06, 2026

Could a Cetiosaurus Have Left the Longest Sauropod Trackway?

By |2026-06-12T14:37:27+01:00June 14th, 2026|Categories: Palaeontological articles|0 Comments

Recently, we published a post highlighting the on-going research into the remarkable Oxfordshire “dinosaur highway”.  A limestone quarry preserves the remains of numerous dinosaur tracks.  The tracks are preserved in strata laid down in the Middle Jurassic.  Palaeontologists estimate that the trackways are around 166 million years old (Bathonian faunal stage).  In a recent radio interview, a researcher commented that one of the tracks could be a record breaker. At around 220 metres in length, one Oxfordshire trackway could represent the longest continuous sauropod trackway known to science. However, describing them as Cetiosaurus dinosaur tracks is somewhat controversial.

To read Everything Dinosaur’s earlier blog post: Oxfordshire Trackway Could be the Longest Sauropod Trackway Discovered to Date.

Could a Cetiosaurus Have Left the Longest Sauropod Trackway?

Whilst undoubtedly made by sauropods, it is difficult to assign with any certainty the taxon that walked across a lagoon that led to the footprints being trapped in time.  Indeed, as the tracks are different sizes, they could represent several taxa.  Alternatively, the tracks might represent a single species, but different aged individuals walking together.  However, Cetiosaurus is the sauropod most often mentioned in association with the trace fossils.  Why might that be the case?

Dewars Farm Quarry in the Middle Jurassic.

An artist’s reconstruction of the Dewars Farm Quarry site 166 million years ago. A Megalosaurus tracks an adult Cetiosaurus with a second sauropod in the background whilst pterosaurs soar overhead. Picture credit: Mark Witton.

Picture credit: Mark Witton

Cetiosaurus is regarded as being a primitive member of the Sauropoda. Nevertheless, this is an important genus. It has the distinction of being regarded as the first sauropod dinosaur to be formally described (Owen 1841). However, Owen’s scientific study was inaccurate. For example, Owen suggested that the large vertebrae with their rough texture were similar to extant whale vertebrae. As the fossils had been found in marine deposits, Owen incorrectly concluded that the fossils represented an enormous marine crocodile.

Cetiosaurus oxoniensis

Unfortunately, most Cetiosaurus fossil specimens consist of fragmentary material.  Indeed, little is known about Middle Jurassic sauropods.  Significantly, the species Cetiosaurus oxoniensis was described from fossils found in Oxfordshire.  The material comes from deposits that are approximately the same age as the trackway bedding planes at the quarry site.  So, it is possible that these extensive trace fossils do indeed represent Cetiosaurus dinosaur tracks.

The right femur of a sauropod (Cetiosaurus) on display.

The enormous and robust right femur of a Middle Jurassic sauropod. The femur has been ascribed to the taxon Cetiosaurus. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Cetiosaurus Dinosaur Tracks

Whether or not these footprints represent Cetiosaurus dinosaur tracks remains open to debate.  However, as perhaps the first sauropod formally described, this taxon is iconic.  In addition, it is pleasing symmetry if a Cetiosaurus did leave what may prove to be the world’s longest sauropod trackway. Such an accolade only enriches England’s rich fossil heritage.

Mike from Everything Dinosaur commented:

“At around 220 metres in length, one Oxfordshire trackway could represent the longest continuous sauropod trackway ever discovered. Other lengthy European sauropod trackways are known.  For example, from Portugal and France.  These fossil trackways are over 140 metres in length, so they are considerably shorter than the trackway from Oxfordshire.  Nonetheless, they are still impressive and give palaeontologists the opportunity to learn more about these enormous creatures.”

Everything Dinosaur acknowledges the assistance of a media release from the University of Birmingham supplied in January 2025 in the compilation of this article.

For sauropod models and other dinosaurs: Dinosaur Figures and Prehistoric Animal Models.

11 06, 2026

Oxfordshire Dinosaur Trackway Could Be the Longest Sauropod Trackway Known

By |2026-06-12T07:12:29+01:00June 11th, 2026|Categories: Palaeontological articles|0 Comments

Scientists studying the famous Oxfordshire “dinosaur highway” have announced that one of the giant trackways may represent the longest known sauropod trackway discovered anywhere in the world. The remarkable sequence of footprints, uncovered at Dewars Farm Quarry, could have been made by a single Cetiosaurus as it wandered across a Jurassic mudflat around 166 million years ago.

Dewars Farm Quarry excavation work.

The Dewars Farm Quarry excavation work taking place in June 2024. Picture credit: The University of Birmingham.

Picture credit: The University of Birmingham

A Giant Dinosaur Left Its Footprints

Researchers have traced the trackway for approximately two-hundred and twenty metres. This enormous trail records the movements of a huge, long-necked herbivore. Furthermore, scientists think the tracks were made by a Cetiosaurus or a sauropod similar to Cetiosaurus, the first sauropod to be scientifically described (Owen, 1841). In total, four sauropod trackways at the site have been discovered. In addition, the site has yielded several other trackways, including those of a meat-eating dinosaur.  These tracks have been tentatively assigned to Megalosaurus.

The original discovery attracted worldwide attention when details were formally announced in early 2025. The sauropod tracks represent animals of different sizes.  This suggests some intriguing possibilities.  For example, the tracks could represent a family moving together, or the trackways could represent a group of unrelated animals moving together.  In an interview with Radio Oxfordshire, co-leader of the excavation Dr Emma Nichols (Oxford University Museum of Natural History), opined that the trace fossils could represent more than one type of sauropod.

Working on the Dewars Farm Quarry dinosaur tracks.

Working on the Dewars Farm Quarry dinosaur tracks. Picture credit: Caroline Wood University of Oxford.

Picture credit: Caroline Wood University of Oxford

The Oxfordshire “Dinosaur Highway” Made by a Cetiosaurus (Possibly)

The tracks cannot be linked directly to a skeleton. However, the footprints closely resemble those expected from a large, narrow-gauge sauropod. Consequently, scientists have suggested that the trackmaker was probably Cetiosaurus.

Cetiosaurus lived during the Middle Jurassic. It reached lengths of around eighteen metres and weighed many tonnes. Moreover, the type species, Cetiosaurus oxoniensis, was named from fossils discovered in Oxfordshire. Therefore, assigning the tracks to this dinosaur makes geological sense.

Cetiosaurus fossils on display.

Fossils ascribed to the taxon Cetiosaurus on display at the Oxford University Museum of Natural History (OUMNH). Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

To read Everything Dinosaur’s article from January 2025 (formal announcement of quarry discovery): Remarkable Dinosaur Highway Uncovered in Oxfordshire.

Following in the Footsteps of Jurassic Giants

Trackways provide a different type of evidence from fossil bones. Skeletons reveal anatomy. However, footprints capture behaviour. They show how dinosaurs moved and interacted with their environment. Using modern imaging techniques, researchers have created detailed three-dimensional models of the trackway. As a result, scientists can estimate walking speed and study the animal’s gait. The Oxfordshire trackways represent one of the most important dinosaur discoveries made in Britain for decades. Furthermore, they provide a rare snapshot of life during the Middle Jurassic.

Jurassic dinosaurs. A typical sauropod dinosaur.

An illustration of a typical sauropod from the Middle Jurassic (Cetiosaurus). It is thought that the Oxfordshire “dinosaur highway” was created by Cetiosaurus or sauropods similar to Cetiosaurus. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

One of the World’s Most Important Dinosaur Sites

At the time the tracks were made, much of Britain was covered by a shallow sea. The Oxfordshire area formed part of a shallow tropical landscape. Mudflats and lagoons provided ideal conditions for preserving footprints. Consequently, the tracks survived for millions of years beneath layers of sediment.

Scientists continue to investigate the quarry. Therefore, further discoveries may yet emerge from this extraordinary site.  However, it is not the only site where long trackways of sauropod dinosaurs have been discovered.

Commenting on the on-going research, Mike from Everything Dinosaur stated:

“The Dewars Farm Quarry site is remarkable. Scientists think there are more footprints awaiting discovery. Hopefully, the site’s owners will continue to work closely with the researchers as well as Natural England to ensure that these fossils are preserved.”

Everything Dinosaur acknowledges the assistance of a media release from the University of Birmingham supplied in January 2025 in the compilation of this article.

The award-winning Everything Dinosaur website: Models of Dinosaurs.

10 06, 2026

Rare Dinosaur Fossil From the Upper Cretaceous Nanaimo Group Described

By |2026-06-11T14:24:17+01:00June 10th, 2026|Categories: Palaeontological articles|0 Comments

Researchers have described a single dinosaur caudal vertebra (tail bone) from Denman Island (British Columbia, Canada).  It has been identified as an ornithomimosaur caudal vertebra. The fossil, thought to represent a bone from the middle part of the tail, is only the second dinosaur fossil identified from the Upper Cretaceous Nanaimo Group. In addition, it is the first definitive dinosaur fossil found in Canadian outcrops. Specifically, the caudal vertebra is from marine sediments of the Campanian-aged Cedar District Formation. The fossil discovery suggests that ostrich-like dinosaurs were present on the western margins of Laramidia.

A dinosaur caudal vertebra (Late Cretaceous hadrosaur).

A single dinosaur caudal vertebra similar to the fossil discovery. A tail bone ascribed to the Ornithomimosauria clade has been found in Upper Cretaceous deposits on Denman Island (British Columbia). Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

A Dinosaur Caudal Vertebra

The discovery of the single caudal bone is only the second reported occurrence of dinosaur fossils from the Upper Cretaceous Nanaimo Group. In 2015, we reported a partial theropod femur from Sucia Island (Washington State, USA). Interestingly, this bone also derives from the Cedar District Formation, but it is geologically older than the ornithomimosaur tail bone.

  • Partial theropod femur (Washington State, USA) – 83.6 to 79.8 mya
  • Mid-caudal ornithomimosaur vertebra (Denman Island, British Columbia, Canada) – 79.8 to 75.5 mya

mya = millions of years ago.

To read our blog post from 2015 about the partial theropod femur fossil discovery: Washington State’s First Dinosaur.

The Upper Cretaceous Nanaimo Group

The deposits of the Upper Cretaceous Nanaimo Group of Vancouver Island have been studied for decades. Numerous vertebrate fossils have been collected representing a diverse marine biota. For example, fossils of fish including sharks, pterosaurs, elasmosaurids and birds have been found. However, despite intensive collecting no dinosaur fossils had been discovered.

Writing in the journal “FACETS” researchers, Victoria Arbour (Royal British Columbian Museum), Timon Bullard (École Secondaire Esquimalt High School) and David Evans (Royal Ontario Museum) describe an isolated theropod caudal vertebra. The fossil was found in marine sediments of the Campanian-aged Cedar District Formation of Denman Island. This small island is located off the eastern coast of the much larger Vancouver Island.

Contemporaneous with Judith River and Two Medicine Formation Biotas

The bone resembles the tail bones of ornithomimosaurs. However, the specimen cannot be identified at the family level. It was likely transported from the western margin of North America to the east. The Nanaimo Group was deposited at least 37o miles (600 km) south of its present position, and this ornithomimosaur likely lived at a similar palaeolatitude to contemporaneous dinosaur faunas in the Two Medicine and Judith River formations in the Western Interior.

CollectA Deluxe Gallimimus model.

Ornithomimosaurs were probably feathered.  In addition, they had long necks, small skulls and lengthy tails. Analysis of the long and graceful hindlimbs suggests that these dinosaurs were fast runners. The caudal vertebra found on Denman Island is likely to have come from the middle part of the animal’s tail.

The image (above) is that of the recently introduced CollectA Deluxe Gallimimus model.  It is a popular figure with collectors and dinosaur fans.  Furthermore, it is one of very few models representing ornithomimosaurs available.

To view the CollectA Deluxe range of prehistoric animal models: CollectA Deluxe Prehistoric Animals.

The scientific paper: “An ornithomimosaur from the Campanian Cedar District Formation (Nanaimo Group) of Denman Island, British Columbia, Canada” by Victoria M. Arbour, Timon S. Bullard and David C. Evans published in FACETS.

For models of ornithomimosaurs and other dinosaurs: Theropod Models and Dinosaur Toys.

8 06, 2026

New Four-winged Dinosaur from China Described

By |2026-06-09T13:48:30+01:00June 8th, 2026|Categories: Palaeontological articles|0 Comments

Palaeontologists have described a new species of microraptorine theropod from north-western China. Named Jian changmaensis, this small, feathered dinosaur probably glided on four wings. The fossil provides fresh insights into Early Cretaceous ecosystems and extends the known range of the Microraptorinae. The fossil material consists of an articulated partial left pectoral girdle and forelimb. It consists of a complete scapulocoracoid, humerus, radius, and ulna. The specimen number is GSGM-D050.

The fossil comes from the Lower Cretaceous Xiagou Formation of the Changma Basin (Gansu Province). These lake deposits date to the Aptian faunal stage. Researchers have collected more than one hundred bird fossils from this site. However, no non-avian dinosaur body fossils had been described until now. Jian is the first non-avian dinosaur body fossil from the Xiagou Formation of the Changma Basin.

Jian changmaensis life reconstruction.

Jian changmaensis life reconstruction. The new microraptorine theropod Jian changmaensis (left) attacks the early bird Gansus yumenensis (right) in what is now the Changma Basin of north-western China approximately 120 million years ago. Picture credit: illustration by Lewis LaRosa, colourised by Jão Canol.

Picture credit: Lewis LaRosa, colourised by Jão Canol

Jian changmaensis from the Xiagou Formation

The location is famous for the relative abundance of aquatic bird fossils. This assemblage is dominated by fossils of the pigeon-sized Gansus yumenensis. Classified as an ornithuran, G. yumenensis is thought to be a closely related to the ancestors of modern birds. Many of the specimens preserved in the fine-grained mudstones show soft tissue structures like feathers and webbing between their toes. This prehistoric bird was probably volant and capable of diving.

Scientists Suspected the Presence of a Predator

Intriguingly, palaeontologists had found examples of crushed bird bones and evidence of regurgitated remains, interpreted as undigestible pellets coughed up by a predator. Scientists speculated that a larger predatory animal must have hunted these ancient birds. However, direct fossil evidence proved elusive. Although far from complete, the limb bones preserve enough anatomical information to identify a new genus and species within the Dromaeosauridae family.  Specifically, phylogenetic analysis places Jian changmaensis within the Microraptorinae subfamily. This group contains small dromaeosaurids closely related to Microraptor. Members of this clade are famous for their feathered limbs and possible gliding abilities.

Jian changmaensis holotype material.

Holotype of Jian changmaensis, (GSGM-D050), an articulated partial left pectoral girdle (scapulocoracoid) and forelimb (humerus, radius, and ulna). Silhouette of generalised microraptorine dromaeosaurid theropod (courtesy Scott Hartman) showing skeletal elements preserved (A). Photograph of specimen as preserved, exposed primarily in dorsomedial (scapulocoracoid), caudodorsal (humerus), and dorsal (radius and ulna) views (B). Interpretive line drawing (C) of B. Photograph of scapulocoracoid and proximal end of humerus in caudodorsal view (D), showing supracoracoid fenestra and other structures. Interpretive line drawing (E) of D. Abbreviations: ac, acromion; bc, bicipital crest; C, coracoid; cr, caudal ridge; dep, dorsal epicondyle; dpc, deltopectoral crest; dr, dorsal ridge; ed, epicondylar depression; fs?, fossa for M. supinator?; H, humerus; hh, humeral head; lp, lateral process; ‘mb’, ‘medial bar’; op, olecranon process; R, radius; S, scapula; scb, scapular blade; scf, supracoracoid fenestra; sta, sternal articulation; U, ulna. Picture credit: Zhou et al.

Picture credit: Zhou et al

A Relative of Microraptor

The researchers surmise that Jian changmaensis probably possessed feathers on both its arms and legs. Therefore, it likely had four wing surfaces. This arrangement may have helped it glide through the forests of Early Cretaceous China. The discovery expands the known fossil record of the Microraptorinae into north-western China. In addition, the partial pectoral girdle indicates that J. changmaensis was much larger than Microraptor. It is one of the largest microraptorines known to science. The fossil material suggests an animal with a wingspan of around a metre to 1.2 metres. This suggests that Jian would have had a wingspan comparable in size to that of the Common Buzzard (Buteo buteo).

PNSO Gaoyuan the Microraptor.

The PNSO Microraptor figure, new for 2020 swoops into view.

The picture (above) shows a model of Microraptor.  It is the PNSO Gaoyuan model.  Microraptor had feathers on its arms and legs, and it has been speculated that it was capable of gliding.

To view the range of PNSO prehistoric animal models in stock: PNSO Age of Dinosaurs Figures.

Similarities with the Famous Jehol Biota

Scientists noted striking similarities between the Changma Basin and the famous Jehol deposits of north-eastern China. Both regions contain microraptorine dinosaurs. Furthermore, both ecosystems included early birds. The Changma deposits contain abundant remains of Gansus yumenensis. Likewise, some Jehol localities are dominated by closely related early birds.

These similarities suggest that the two regions may have shared comparable environments. Such habitats are poorly represented at many other Jehol fossil sites.

The fascinating Jehol Biota: The Jehol Biota.

To read a blog post about a new tiny dromaeosaurid dinosaur from the Jehol fossil sites: New Dromaeosaurid from Liaoning Province (Jehol Biota).

First Non-avian Dinosaur from Changma

The discovery of Jian changmaensis marks an important milestone. It represents the first non-avian dinosaur body fossil reported from the Xiagou Formation. Moreover, the fossil demonstrates that small dromaeosaurids lived alongside numerous early birds. Consequently, scientists now have a better understanding of the biodiversity preserved within the Changma Basin.

Although only part of the skeleton is known, Jian changmaensis provides valuable information. The fossil helps researchers reconstruct the distribution and evolution of microraptorines.

In addition, the discovery highlights the importance of the Changma Basin. Future finds could reveal even more dinosaurs from these remarkable deposits.

Everything Dinosaur acknowledges the assistance of a media release from the Field Museum (Chicago) in the compilation of this article.

The scientific paper: “First non-avian theropod (Dromaeosauridae, Microraptorinae) from the bird-bearing Lower Cretaceous Xiagou Formation of the Changma Basin, Gansu Province, north-western China” by Ling-Qi Zhou, Matthew C. LaManna, Ashley W. Poust, Da-Qing Li, Hai-Lu You and Jingmai K. O’Connor published in the Annals of the Carnegie Museum.

The award-winning Everything Dinosaur website: Dinosaur and Prehistoric Animal Models.

2 06, 2026

A New Unenlagiid Dinosaur from Patagonia (Argentina)

By |2026-06-05T06:02:59+01:00June 2nd, 2026|Categories: Palaeontological articles|0 Comments

A team of scientists from Argentina and Japan has described a new species of unenlagiid dinosaur from southern Patagonia. Named Kank australis, this small, theropod dinosaur lived around 70 million years ago during the Late Cretaceous.

The fossil remains were discovered in the Chorrillo Formation of Santa Cruz Province, Argentina. The discovery helps palaeontologists better understand the diversity of Southern Hemisphere dromaeosaurids and provides fresh insights into the ecosystems that existed shortly before the extinction of the non-avian dinosaurs.

Kank australis life reconstruction.

Kank australis life reconstruction. Picture credit: Gabriel Díaz Yantén.

Picture credit: Gabriel Díaz Yantén

Kank australis Expands the Known Range of Unenlagiids

The newly described Kank australis belongs to the Unenlagiidae, a group of long-snouted paravian theropods up to now represented in Gondwanan landmasses. These dinosaurs are often compared to famous Northern Hemisphere relatives such as the dromaeosaurid Velociraptor. However, unenlagiids were unique to the southern continents. Unenlagiids are particularly diverse in northern Patagonia, where at least seven species have been identified from Upper Cretaceous strata. Therefore, the discovery of Kank australis extends the known distribution of these dinosaurs much further south.

A new fish-eating unenlagiid from Brazil (Ypupiara lopai): A New Piscivorous Dinosaur is Described.

Researchers suggest that this discovery helps bridge an important geographical gap. Furthermore, it may provide clues about links between South American dinosaurs and species that may have inhabited Antarctica during the Late Cretaceous. Antarctic species such as the probable unenlagiid Imperobator antarcticus.

The fossil material consists of vertebrae, isolated pedal phalanges, and shed teeth.

Fossil material associated with the newly described dinosaur K. australis.

Fossil material associated with the newly described unenlagiid K. australis. Picture credit: Ignacio García.

Picture credit: Ignacio García

Named After an Ancient Mythological Bird

This dinosaur’s name has an interesting origin. The genus name comes from the “elder rhea” from indigenous Aonikenk (Tehuelche) mythology. According to tradition, this bird left its footprint in the sky, creating the constellation known today as the Southern Cross.

Meanwhile, the species name “australis” means southern. It refers to the location in Patagonia where the fossil material was discovered.

Fossils Recovered During Difficult Fieldwork

The remains of Kank australis were collected during several expeditions that began in 2019. One of the most significant discoveries came just before severe weather forced researchers to abandon a field season. A vertebra from the base of the neck was spotted by a technician searching for small fossil fragments. At first, the team could not identify the specimen because it remained embedded in rock. However, once the surrounding matrix was removed, the researchers realised they had found part of a “raptor” dinosaur.

Examining the fossil material.

Working on the fossil material. Picture credit: Ignacio García.

Picture credit: Ignacio García

Although fragmentary, the fossils possess distinctive anatomical features that justify the erection of a new species.  In addition, the fossils demonstrate a suite of characteristics suggesting that K. australis was probably distinct from other unenlagiids.  Therefore, it reinforces the hypothesis that the Unenlagiidae was a morphologically disparate clade.

To read an article from 2024 about a newly described unenlagiine from northern Patagonia (Diuqin lechiguanae): A New Unenlagiid from Northern Patagonia.

What Did It Look Like?

Scientists estimate that Kank australis measured approximately two metres in length. This would make it comparable in size to Velociraptor. Its anatomy suggests that it may have occupied a different ecological niche from many Northern Hemisphere dromaeosaurs. For example, its teeth possess small longitudinal ridges. These structures may have helped the animal grip slippery prey. As a result, researchers propose that fish formed an important part of its diet. Whereas, most Northern Hemisphere dromaeosaurids are thought to have been terrestrial predators.

In addition, the neck vertebrae show specialised muscle attachment sites and structures associated with blood vessel protection. Similar features are seen in modern birds that make complex neck movements, including herons.

Consequently, palaeontologists suggest that Kank australis may have been a piscivore, rather than a purely terrestrial predator.

A Rich Late Cretaceous Ecosystem

Seventy million years ago, Patagonia looked very different from today. The Andes Mountains had not yet formed. Instead, the region was dominated by rivers, lakes and lush vegetation. The Chorrillo Formation has yielded a remarkable range of fossils. These include fish, frogs, turtles, snakes, mammals and numerous dinosaurs.

Large predators also shared this environment. Fossils of the giant megaraptoran theropod Maip macrothorax have been found at the same locality. In addition, the long-necked titanosaur Nullotitan glaciaris roamed the landscape.

CollectA Deluxe 1:40 scale Maip macrothorax model.

A replica of the giant South American theropod M. macrothorax. The CollectA Deluxe Maip macrothorax model measures 26 cm in length.

The picture (above) shows the CollectA Deluxe Maip macrothorax dinosaur model.  It is a recent theropod introduction into this extensive scale model range.

To view the CollectA Deluxe models: CollectA Deluxe Prehistoric Animal Models.

Together, these discoveries are helping scientists reconstruct one of the southernmost dinosaur ecosystems known from the final stages of the Age of Dinosaurs.

A Window into the Last Days of the Dinosaurs

The discovery of Kank australis demonstrates that southern Patagonia supported a diverse dinosaur fauna shortly before the end-Cretaceous mass extinction.

Each new fossil helps researchers piece together the complex history of life in Gondwana. Furthermore, discoveries such as Kank australis highlight how much remains to be learned about dinosaur evolution in the Southern Hemisphere.

Everything Dinosaur acknowledges the assistance of a media release from the Museo Argentino de Ciencias Naturales “Bernardino Rivadavia” in the compilation of this article.

The scientific paper: “New unenlagiid from the Chorrillo Formation (Late Cretaceous, Maastrichtian), SW Patagonia, Argentina” by Matías J. Motta, Alexis M. Aranciaga Rolando, Sebastián Rozadilla, Federico L. Agnolín, Federico Brissón Egli, Gerardo P. Álvarez Herrera, Nicolás R. Chimento, Gastón Lo Coco, Takanobu Tsuihiji, Makoto Manabe, Diego Pol and Fernando E. Novas published in the Journal of Vertebrate Paleontology.

The Everything Dinosaur website: Theropod Dinosaurs and Other Models.

1 06, 2026

New English Crocodylomorph Honours Welsh Teacher

By |2026-06-02T14:09:07+01:00June 1st, 2026|Categories: Palaeontological articles|0 Comments

Scientists have identified a new species of ancient crocodylomorph from Upper Triassic rocks in southwest England. The newly named species, Galahadosuchus jonesi, lived around 215 million years ago and it represents the second species of non-crocodyliform crocodylomorph described from the Late Triassic–aged fissures of the Bristol Channel area.

Non-crocodyliform crocodylomorph fossil material is known from both sides of the Bristol Channel.  Osteoderms, teeth and bones have been found.  Most of these fossils have been assigned to the species Terrestrisuchus gracilis (Crush, 1984).  However, it is probable that T. gracilis has become a taxonomic waste basket to some extent.  Different genera of early crocodylomorphs are likely present. The discovery of Galahadosuchus jonesi, named from fossils formerly assigned to Terrestrisuchus confirms previous suggestions of under-described pseudosuchian diversity from these deposits.

The fossil specimen was discovered in 1969. However, researchers have only recently recognised that it represents a previously unknown species. The findings have been published in the academic journal “The Anatomical Record”.

A Small, Fast-moving Terrestrial Predator

Unlike modern crocodilians, Galahadosuchus was not an aquatic ambush hunter. Instead, it was a lightly built, agile, fast-running animal that spent its life on land.

Researchers describe it as resembling a reptilian greyhound. It had long, slender limbs, an upright posture and a body adapted for speed. The animal probably hunted small reptiles, amphibians and early mammals.

Galahadosuchus jonesi scale drawing.

Galahadosuchus jonesi scale drawing (based on Pseudhesperosuchus jachaleri). Note scale bar equals 10 cm. Picture credit: Everything Dinosaur.

Picture credit: Everything Dinosaur

Several anatomical features support this interpretation. These include elongated wrist bones, tightly grouped metacarpals and a distinctive ankle structure. Together, these traits indicate that Galahadosuchus was a highly cursorial predator, related to Terrestrisuchus but a distinct genus.

Fossils from an Ancient Karst Landscape

The fossil comes from the famous fissure deposits found around the Bristol Channel area. During the Late Triassic, this region consisted of limestone uplands surrounded by hot, arid lowlands. Over time, caves and fissures formed within the limestone. The remains of animals were washed into these natural traps and became buried by sediment. As a result, the fissure deposits preserve a fascinating snapshot of life, although the exact dating of the deposits has proved controversial. For example, the geological age of these deposits and their fossil content remains unknown.

Some academics suggest that the fossils represent a biota from the youngest faunal stage of the Triassic (Rhaetian).  Moreover, that the fossils date from around 206 to 201.5 million years ago. In contrast, other researchers consider these deposits to be much older and spanning a greater interval of deep geological time.  For instance, it has been postulated that these fissure fill deposits span an age range from the Carnian to the Rhaetian (around 230 to 201.5 million years ago).

These rocks have provided numerous important vertebrate fossils including early dinosaurs and ancestors of modern lizards.

To read Everything Dinosaur’s blog post from 2021 about the discovery of an early theropod dinosaur: “Chief Dragon” from a South Wales Quarry.

Evidence of modern lizards in the Late Triassic: Cryptovaranoides is Clearly a Squamate.

Identifying a New Species

The specimen was originally assigned to Terrestrisuchus. However, a detailed study revealed important anatomical differences (autapomorphies). The research team identified thirteen anatomical traits that distinguish the fossil from known Terrestrisuchus specimens. Several of these differences involve the wrist bones, which are shorter and more robust in the new species. The differences in the morphology of the limb and wrist bones might correspond to differences in locomotory function between Terrestrisuchus and Galahadosuchus. These differences could reflect varying specialisations within Late Triassic crocodylomorphs.

Phylogenetic analysis places Galahadosuchus as a sister taxon to Terrestrisuchus. Both animals belong to a family of early crocodylomorphs known as the Saltoposuchidae.

These findings demonstrate that early crocodylomorph diversity was greater than previously recognised.

Galahadosuchus jonesi Honours an Inspirational Teacher

The species name honours David Rhys Jones, a physics teacher at Ysgol Uwchradd Aberteifi in Cardigan, Wales.

Lead author of the study, Ewan Bodenham explained that Mr Jones played an important role in encouraging his interest in science. The teacher’s enthusiasm, humour and willingness to challenge students helped inspire a future palaeontologist.

Meanwhile, the genus name combines “suchus” (crocodile) with a reference to Sir Galahad from Arthurian legend, a knight renowned for his moral uprightness. Therefore, the genus name reflects the upright stance of this reptile.

A Window into Early Crocodylomorph Evolution

The discovery of Galahadosuchus jonesi adds another important species to the rich fossil record of the Bristol Channel fissure deposits. These remarkable fossils continue to improve our understanding of life during the Late Triassic. Furthermore, they provide valuable evidence about the early evolution of crocodylomorphs, a lineage that would eventually give rise to modern crocodilians.

Everything Dinosaur Comments on Galahadosuchus jonesi

Commenting on the study, Mike from Everything Dinosaur stated:

“The fissure deposits of southwest England and South Wales continue to produce extraordinary insights into Late Triassic ecosystems. The identification of Galahadosuchus jonesi highlights just how diverse the early relatives of crocodiles had become before the end-Triassic extinction event. It also demonstrates the importance of revisiting historic museum specimens, as collections can still contain species waiting to be recognised.”

Everything Dinosaur acknowledges the assistance of the media team from University College London and the London Natural History Museum in the compilation of this article.

The scientific paper: “A second species of non-crocodyliform crocodylomorph from the Late Triassic fissure deposits of southwestern UK: Implications for locomotory ecological diversity in Saltoposuchidae” by Ewan H. Bodenham, Stephan N. F. Spiekman, Susannah C. R. Maidment, Paul Upchurch and Philip D. Mannion published in The Anatomical Record.

The Everything Dinosaur website: Dinosaur Toys and Models.

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