Fact-checked by Grok 2 weeks ago

Rajasaurus

Rajasaurus narmadensis is a of carnivorous abelisaurid theropod dinosaur that lived during the period, approximately 70 to 66 million years ago, in what is now . Known from associated cranial and postcranial fossils discovered in the , it represents one of the most complete theropod specimens from the . The genus name Rajasaurus, meaning " " from the word raja ( or king) and saurus (), reflects its regal appearance and status as a dominant predator in its ecosystem; the specific name narmadensis refers to the Narmada Valley. This medium-sized bipedal dinosaur measured an estimated 6.6 meters (22 feet) in length and stood about 2 meters (6.5 feet) tall at the hip, with a robust build suited for hunting large prey. Notable anatomical features include a distinctive single short horn or median nasofrontal protuberance on the snout, possibly used for display or intraspecific combat, as well as elongated supratemporal fenestrae in the skull and short, stubby forelimbs typical of abelisaurids. As a member of the Abelisauridae family within Ceratosauria, Rajasaurus shares close affinities with relatives like Majungasaurus from Madagascar and Carnotaurus from South America, highlighting biogeographical connections across the ancient Gondwanan landmasses before the end-Cretaceous extinction. The holotype specimen was unearthed in the early 1980s near Rahioli in by Indian paleontologists Srivastava and Ashok Sahni, with subsequent analysis and naming by an international team including Jeffrey A. Wilson and Paul C. Sereno in 2003. Fossils include elements of the braincase, vertebrae, pelvic girdle, and hind limbs, providing insights into its predatory lifestyle in a environment shared with titanosaurian sauropods, which likely served as its primary prey. Rajasaurus underscores the diversity of abelisaurid theropods in isolated Gondwanan faunas and contributes to understanding the final chapter of non-avian dinosaur evolution in .

Discovery and naming

Discovery history

The fossils of Rajasaurus narmadensis were first unearthed during surveys conducted by the (GSI) in the early 1980s along the valley in central and , within the . In 1982, Suresh Srivastava of the GSI discovered the primary material at Temple Hill near Rahioli village in (23° 3' 26.2" N, 73° 20' 30.8" E), during excavations of connected quarries in infratrappean sediments below an egg-bearing limestone layer. Between 1982 and 1984, this effort yielded the specimen (GSI Type No. 21141, comprising 33 elements), a partial skeleton including the braincase, a centrum, partial vertebrae, the , caudal vertebrae, a partial , ilia, pubis, , , , and metatarsals, all associated from a single individual. Ashok Sahni joined Srivastava for a major 1983 expedition that collected hundreds of additional bones from the Narmada region, though much of the theropod material remained fragmentary and initially classified as indeterminate theropod due to incomplete preparation and association uncertainties. Fieldwork faced significant challenges, including the erosion-prone nature of riverbank exposures in the , which both revealed fossils through seasonal flooding and monsoon rains but also led to their rapid destruction or scattering. Limited funding and resources for paleontological research in during this period further hampered systematic excavations, with GSI teams often relying on small-scale operations amid competing geological priorities. Additional fragments attributable to Rajasaurus, such as a piece of upper jaw, were later noted near in the northern of , suggesting a broader along the Narmada valley. The key specimens underwent detailed preparation and analysis during a 2001 joint Indo-American project led by Jeffrey A. Wilson, Paul C. Sereno, Suresh Srivastava, and Ashok Sahni, culminating in the formal description of Rajasaurus narmadensis in 2003 and resolving its abelisaurid identity from the earlier indeterminate status. This collaboration addressed prior limitations in Indian paleontology by integrating international expertise with local collections housed at the GSI in .

Etymology and taxonomy

Rajasaurus narmadensis was formally named and described in 2003 by Jeffrey A. Wilson, Paul C. Sereno, Suresh Srivastava, Devendra K. Bhatt, Ashu Khosla, and Ashok Sahni in a paper published in the Contributions from the Museum of Paleontology of the (volume 31, number 1, pages 1–42). This description established Rajasaurus as a new and of abelisaurid theropod based on a partial that includes both cranial and postcranial elements, marking it as the first such associated theropod remains from . The generic name Rajasaurus derives from the word raja, meaning "prince" or "princely," combined with the Greek sauros, meaning "" or "," thus translating to "princely ." The specific epithet narmadensis refers to the valley in , where the fossils were discovered, highlighting the dinosaur's geographic association with this region. The holotype specimen, designated GSI Type No. 21141/1–33, consists of a partial including the braincase, a centrum, vertebrae, the , caudal vertebrae, a partial , ilia, pubis, , , , and metatarsals; it is housed in the collections of the . Taxonomically, Rajasaurus narmadensis is recognized as a valid and distinct within , with no synonyms proposed since its naming. Early comparisons noted similarities to the Indian theropod , but Rajasaurus was differentiated by unique features such as elongated supratemporal fenestrae and a median nasofrontal protuberance on the skull. Rajasaurus narmadensis remains the only valid assigned to the , and the 2003 publication was well-received for resolving long-standing uncertainties in associating isolated theropod bones from the , indicating the presence of at least three large-bodied theropod taxa in the assemblage.

Description

Overall size and build

Rajasaurus narmadensis was a large bipedal theropod dinosaur, estimated to have measured 8–9 meters (26–30 feet) in length and weighed between 1 and 2 metric tons, based on measurements of its partial holotype skeleton and allometric scaling from the more completely known abelisaurid Majungasaurus crenatissimus. Recent estimates vary, with some scaling methods suggesting a length of 6.6-7 m. These dimensions place it among the larger members of Abelisauridae, comparable in scale to other Late Cretaceous abelisaurids from Gondwana. The overall build of Rajasaurus was robust and stocky, characterized by a deep ribcage forming a barrel-shaped torso, a relatively short tail, and powerfully constructed hindlimbs that supported its bipedal locomotion as a carnivorous predator potentially capable of short bursts of speed. Its general body plan followed the typical abelisauroid pattern, featuring reduced forelimbs with limited functionality and a large skull approximately 71 cm (28 inches) in length. The scaling of body size was derived primarily from preserved elements such as the femur, tibia, and vertebrae, extrapolated using proportional relationships observed in Majungasaurus, where hindlimb robusticity and axial proportions provide key metrics for reconstruction. Unique to Rajasaurus among theropods were its cranial proportions, with a shorter relative to overall length, which emphasized robust bony ornamentation such as a midline nasal-frontal boss rather than elongation for piercing prey. This contributed to a more compact, heavily built anterior region, aligning with the stocky postcranial framework that distinguished it from slenderer coelurosaurs.

Skull and

The skull of Rajasaurus narmadensis exhibits a robust construction with thickened cranial elements, including frontals up to 4 cm thick above the and fused parietals nearly 2 cm thick, contributing to its overall sturdiness typical of abelisaurids. The reconstructed skull is approximately 71 cm (28 inches) in length, based on the assembled elements and comparisons to related abelisaurids like and . A key diagnostic feature is the distinctive midline nasal boss, a low horn primarily formed by the fused nasals with the frontals contributing to the posterior rim, rising about 10 cm high and positioned centrally on the snout—unique among abelisaurids in its size and placement. This structure likely supported a keratinous covering, potentially employed for display or intraspecific combat, analogous to the rugose nasal ornamentation in . The is short and , with the premaxillary row terminating anterior to the external naris and the maxillary row ending anterior to the ventral ramus of the lacrimal, reflecting reduced anterior common in abelisaurids. comprises around 20-25 conical per side, equipped with serrations suited for tearing flesh; crowns are low-crowned, measuring 10-15% of height at midlength, and the rows display marked transverse curvature, with the third dentary enlarged relative to the second. The braincase preserves several abelisaurid-affirming traits, including anteroposteriorly elongate supratemporal fenestrae (length approximately 150% of transverse frontal breadth, which measures 105 mm) bordered medially by the fused parietals, a prominent , and a nuchal wedge; the has a transverse width of 19 mm. The small brain cavity indicates limited encephalization, consistent with the inferred of abelisaurids.

Postcranial skeleton

The postcranial skeleton of Rajasaurus narmadensis is known primarily from the specimen (GSI 21141), a partial skeleton that includes elements of the vertebral column, pelvis, and hind limbs, but lacks detailed forelimb and rib material. These remains indicate a robust build typical of abelisaurids, with features supporting stability and powerful locomotion. The comprises one mid-cervical , several partial vertebrae, six sacral centra, and seven anterior caudal vertebrae. The preserved mid-cervical centrum is spool-shaped and amphicoelous, measuring 87 mm in length; it is broader than tall, with a deeply posterior face, a gently anterior face, a low ventral median keel, and a large parapophysis bearing an oval fossa and two pneumatic openings. This centrum is shorter anteroposteriorly than those of Ceratosaurus or other abelisaurids such as Majungasaurus and Carnotaurus. The vertebrae feature spool-shaped centra that are gently amphicoelous, with lengths of approximately 87 mm, and highly pneumatized neural arches exhibiting deep lateral fossae and prominent laminae; the neural arches lack pneumatic foramina in the centra but show extensive internal pneumatization. The sacral vertebrae consist of six elongate centra that taper in width toward the middle of the series, with the central four (–S5) coossified and the first and last remaining free; the total sacral length measures 566 mm, with minimal ventral arching, contributing to a stiffened presacral for enhanced axial . The anterior caudal vertebrae are amphicoelous and transversely compressed, each bearing a prominent ventral but lacking visible chevron facets; these elements taper posteriorly, consistent with a tapering tail structure. The appendicular skeleton is dominated by hind limb elements, with the forelimb represented only by a partial left scapula, underscoring the extreme reduction of the forelimbs seen across Abelisauridae, where the manus is typically shorter than the humerus. The preserved distal portions of the femora (both sides) exhibit anteroposteriorly compressed shafts that widen toward the broad distal condyles, separated by a shallow intercondylar groove; the tibial condyle is roughly half the mediolateral breadth of the fibular condyle, with a total distal breadth of 150 mm. The right distal tibia is broad and flattened along its shaft, with an asymmetrical distal end featuring a larger fibular malleolus; its distal breadth measures 193 mm. The right proximal fibula is laterally compressed with a concave medial surface and a fibular fossa, attaining a proximal breadth of 100 mm. Metatarsals II (right and left) and IV (right) are robust, with metatarsal II measuring 276 mm in length, indicating strong weight-bearing capacity and a three-toed pes configuration typical of theropods. The pelvic girdle includes partial ilia from both sides and the proximal portion of the left pubis, but no . Each ilium is robust, measuring 360 mm from the pubic to the ischial ; it has a short, wide pubic angled approximately 50° from the , a narrow ischial with peg-like processes, and a broad separated from the by a prominent transverse . The pubis features a broad, rugose iliac with a conical pit for attachment. These pelvic features, combined with the robust , suggest a deep thoracic region and powerful hind limb anchorage for . No are preserved in the .

Classification

Phylogenetic analyses

Rajasaurus narmadensis was initially classified within Abelisauridae in its original description, based on a maximum parsimony analysis that evaluated its position among basal neotheropods using a dataset of 169 morphological characters scored across 21 ingroup taxa, with outgroups including Eoraptor and Herrerasauridae. This placement was supported by key cranial features such as a prominent nasal boss and a reduced antorbital fenestra, which aligned Rajasaurus with other abelisaurids like Majungatholus (now Majungasaurus) and Carnotaurus within the subfamily Carnotaurinae. Subsequent phylogenetic studies have consistently nested Rajasaurus within , the derived subclade of , often as the sister taxon to . For instance, a analysis using methods in PAUP* 4.0b10 on a of 151 characters and 18 ingroup ceratosaur taxa (outgroups: , Syntarsus, ) recovered Rajasaurus in a with and the Indian abelisaurid , though with weak nodal support (decay index of 1). This positioning was reinforced by shared character states including a short , fused nasals forming a midline boss, and reduced elements, which were scored alongside cranial and postcranial traits diagnostic of abelisaurids. Modern phylogenies, incorporating broader theropod datasets, have integrated Rajasaurus into expanded Gondwanan-focused trees without altering its core placement. A 2024 study employed analysis in 1.6 on a comprehensive matrix of 245 characters across 47 taxa, alongside Bayesian tip-dating in RevBayes 1.2, placing Rajasaurus firmly within (synonymous with in this context) alongside and other Indo-Madagascan forms, with overall low resolution for intergeneric relationships (average bootstrap support of 17.3%). These analyses, which include over 100 taxa in some extended theropod matrices, highlight consistent support for (bootstrap values exceeding 70% in family-level nodes) via synapomorphies such as robust hindlimbs and texturized roofing bones. Post-2003 updates reflect no major shifts in Rajasaurus's position, emphasizing its role in illuminating Gondwanan ceratosaur diversification.

Relationships within Abelisauridae

Within Abelisauridae, Rajasaurus narmadensis occupies a derived position in the subclade , forming a close phylogenetic relationship with crenatissimus from , based on shared synapomorphies such as the positioning of the nasal posterior process dorsal to the and the presence of nasal ornamentation. This grouping reflects a Gondwanan distribution pattern, with Rajasaurus clustering alongside other Indo-Madagascan forms like in recent analyses. A key diagnostic trait of Rajasaurus is its single midline nasofrontal horn, formed primarily by the nasals with a posterior rim contributed by the frontals, which distinguishes it from relatives exhibiting paired crests—as seen in —or multiple bosses and excrescences in genera like . This ornamentation likely served a display or agonistic function, consistent with trends in carnotaurine abelisaurids. Additionally, Rajasaurus shares highly reduced forelimbs with Ilokelesia aureocollaris, both featuring diminutive humeri less than 10% of length, underscoring the extreme limb reduction characteristic of the . In contrast, its skull exhibits greater depth relative to the shallower proportions inferred for Pycnonemosaurus nevesi, based on postcranial scaling and comparative metrics from other abelisaurids. Biogeographically, Rajasaurus represents the Indo-Madagascan radiation of abelisaurids, which diverged from South American lineages approximately 20 million years earlier during the mid-Cretaceous, following the isolation of Indo-Madagascar around 100 million years ago but with abelisauroid dispersal predating full vicariance. This separation highlights a distinct evolutionary trajectory for eastern Gondwanan forms, isolated from the more diverse South American abelisaurine clades by tectonic events. Recent phylogenetic studies, including a 2024 incorporating expanded character matrices, reaffirm Rajasaurus as a derived abelisaurine rather than a basal member, resolving it firmly within and excluding earlier basal placements proposed in limited datasets.

Locomotion and

Rajasaurus exhibited a bipedal typical of theropod dinosaurs, with facilitated by robust hindlimbs featuring a relatively short and that supported powerful thigh muscles for bursts of speed during predation. Limb proportions in abelisaurids, including Rajasaurus, suggest estimated top speeds of 20–30 km/h, derived from relative stride length and hip height using for theropod cursoriality. The forelimbs of Rajasaurus were highly reduced and likely served limited functions beyond , with vestigial elements adapted for weak grasping via retained flexor muscles on digits II and III, though lacking fine control. In related abelisaurids like , these limbs retained a wide at the and , supporting possible roles in intraspecific or behaviors rather than weight-bearing or predatory assistance. Sensory physiology in Rajasaurus is inferred from its braincase, which preserves the for cranial nerve II and a trough for the , but detailed inferences on visual or olfactory capabilities are limited due to incomplete preservation. Bone in abelisaurids reveals moderate to rapid early rates with fibrolamellar , supporting inferences of elevated metabolic rates akin to endothermy in other large theropods, though specific data for Rajasaurus remain unavailable. The robusticity of its , with elongated centra and interlocking ribs, points to a predominantly horizontal neck posture for efficient head movement during or predation.

Diet and predatory behavior

Rajasaurus was a carnivorous theropod that functioned as the in its Late Indian ecosystem, primarily preying on large herbivorous dinosaurs such as the titanosaur sauropods colberti and septentrionalis. evidence from contemporaneous formations indicates that abelisaurids, including relatives of Rajasaurus, interacted trophically with titanosaurs through predation or scavenging, as demonstrated by shed abelisaurid teeth found in association with titanosaur skeletons. In the , where Rajasaurus fossils occur, these sauropods dominated the herbivore niche, providing the bulk of available large prey for such predators. The robust cranial architecture of Rajasaurus, inferred from its braincase and partial skull elements, supported powerful jaw mechanics suited for subduing sizable prey. Estimated bite forces for closely related abelisaurids like crenatissimus are approximately 12,000 Newtons posteriorly; Rajasaurus likely possessed comparable strength given its similar size and build. Although no teeth are preserved in Rajasaurus specimens, abelisaurid generally features thick, recurved blades with coarse serrations and a D- or J-shaped cross-section, adapted for slashing and maintaining a grip during struggles rather than deep puncturing like in tyrannosaurids. This configuration aligns with a bite-and-hold feeding , where the predator would clamp onto prey and use body weight and neck musculature to restrain it. Rajasaurus likely employed an ambush-oriented predatory style, relying on bursts of speed from its robust hindlimbs to close distances on unsuspecting herbivores in forested or riverine habitats, rather than prolonged pursuits. Its short, vestigial forelimbs limited capabilities, emphasizing the head as the primary weapon, potentially augmented by with the prominent midline nasal for display, intra-specific combat, or stunning prey. Agent-based modeling of predator-prey interactions in the indicates high predation success for Rajasaurus under scenarios of solitary or small-group , with efficient kill rates against juvenile or subadult titanosaurs. Direct evidence of feeding traces for Rajasaurus is absent, but analogies from —such as bite-marked conspecific bones and coprolites containing theropod remains—suggest possible opportunistic intra-specific predation or scavenging during times of resource scarcity. As the dominant large carnivore in isolated , Rajasaurus occupied an ecological role comparable to Tyrannosaurus rex in , controlling herbivore populations and shaping community dynamics through top-down predation pressure.

Paleoecology

Geological context

The fossils of Rajasaurus narmadensis were recovered from the infratrappean beds of the in , specifically near Rahioli in along the valley. This formation consists of sedimentary rocks underlying the basal flows of the , a massive volcanic province, and represents intertrappean deposits formed during pauses in volcanic activity. The is dated to the stage of the , approximately 70 to 66 million years ago, based on from associated microvertebrates and microfossils, as well as the stratigraphic position below Deccan Trap basalts radiometrically dated to around 65.5 Ma using ⁴⁰Ar/³⁹Ar methods. The depositional environment of the is interpreted as fluvio-lacustrine, characterized by alluvial floodplains, meandering rivers, and seasonal water bodies, with lithologies including red mudstones, calcareous sandstones, and conglomerates that indicate in river channels. These features suggest a dominated by low-gradient rivers depositing sediments in channel and overbank settings under a subtropical . Recent geochemical analyses of palaeosols in the formation's Mottled Nodular Bed, including chemical index of alteration values, reveal evidence of intense chemical and mean annual estimates of 779 to 1150 mm/year, pointing to warmer and wetter tropical humid conditions rather than the previously inferred semi-arid regime. Radiometric dating of the Deccan Traps places the main eruptive phase at approximately 66 Ma, overlapping with the upper Lameta Formation and coinciding temporally with the end-Cretaceous (K-Pg) mass extinction event, suggesting potential environmental stresses from volcanism on the contemporaneous biota including Rajasaurus. The taphonomy of Rajasaurus fossils reflects preservation in fluvial channel lag deposits, where disarticulated bones were scattered over an area of about 7 meters and mixed with remains of multiple sauropod individuals, indicating moderate transport, sorting by currents, and rapid burial in river systems that limited further weathering or scavenging.

Contemporaneous biota

The ecosystem of the in supported a dominated by large herbivorous dinosaurs that formed the primary prey base for apex predators like Rajasaurus narmadensis. Titanosaurian sauropods, including Isisaurus colberti (reaching lengths of up to 15 meters) and Jainosaurus septentrionalis, were the most prominent herbivores, browsing on vegetation in humid alluvial floodplains and contributing significantly to the trophic structure through their abundance and size. Ornithischians represented a minor component of the herbivore guild based on fragmentary and indeterminate remains. Among carnivores, smaller theropods like Indosuchus raptorius (estimated at 6–7 meters long) co-occurred with Rajasaurus, scavenging or hunting mid-sized prey without challenging the larger abelisaurid's dominance as the apex predator. This partitioning reduced direct competition, allowing Rajasaurus to focus on high-value targets in the upper trophic levels. The broader vertebrate assemblage included indeterminate crocodylomorphs, turtles such as Sankuchemys sethnai from associated intertrappean beds, and assorted fish in riverine and lacustrine habitats, filling aquatic and semi-aquatic roles but contributing minimally to terrestrial dynamics. Overall faunal diversity remained low, reflecting India's isolation as an island-like fragment of Gondwana, which restricted faunal exchange and fostered endemism among dinosaurs while limiting total species richness. In this , Rajasaurus occupied the top predatory role, preying on vulnerable herbivores such as juvenile titanosaurs amid a marked by nesting colonies. Bone beds and extensive nesting sites preserve of predation on hatchlings, underscoring how Rajasaurus exploited seasonal abundances of young sauropods to sustain its position. Recent paleontological work from 2023 has revealed 92 titanosaur nesting sites with 256 eggs in the , integrating new insights into theropod-prey interactions and highlighting Lameta theropod diversity. These findings emphasize the precarious balance of the , where reproductive vulnerabilities amplified the impact of top predators like Rajasaurus.

Cultural significance

Representations in media

Rajasaurus has gained some visibility in popular media since its discovery and naming in 2003, though its depictions remain relatively sparse compared to more iconic North American theropods like Tyrannosaurus rex. Initial press coverage highlighted the find as India's first major carnivorous dinosaur skull, sparking interest in the country's prehistoric heritage. In documentary television, Rajasaurus features prominently in the second season of the BBC Studios and Apple TV+ series Prehistoric Planet (2023), specifically in the episode "Badlands," where it is portrayed as a solitary ambush predator stalking vulnerable hatchling Isisaurus amid volcanic hazards in Late Cretaceous India. The reconstruction emphasizes its robust build, short forelimbs, and distinctive nasal boss, with a reddish coloration for visual impact, aligning closely with scientific consensus on abelisaurid anatomy. An Indian short film, Rajasaur (2022), directed by Sreejith Nair, centers on the dinosaur as a menacing antagonist; the plot follows a prehistoric father and daughter duo tasked with returning a lost Rajasaurus egg, blending adventure with educational elements about the species' role as an apex predator. In video games, Rajasaurus appears as an unlockable super-rare carnivore in Jurassic World: The Game (developed by Ludia), where players can acquire its DNA through events and evolve it for park management and combat scenarios, often depicted with enhanced aggression to fit gameplay mechanics. It also features in Jurassic World Alive, another Ludia title in the franchise, as part of hybrid pursuit events that allow collection of its genetic material in augmented reality hunts. Merchandise representations include the Jurassic World Dominion Roar Strikers toy figure (2022), a posable model with integrated roaring sounds and a chomping action, portraying the with exaggerated size and ferocity for interactive play, though not appearing in itself. Artistic reconstructions of Rajasaurus in frequently highlight its single midline , sometimes speculated to have been sheathed in colorful for display or intraspecific combat, as seen in illustrations accompanying paleontological exhibits and digital models. Early depictions occasionally erred by assigning abelisaurids an overly upright, tyrannosaurid-like posture, but modern renderings correct this to a more crouched, horizontal stance reflective of updated skeletal analyses.

Role in paleontological research and education

The discovery of Rajasaurus narmadensis has provided critical evidence for the isolation of Gondwanan dinosaur faunas during the Late Cretaceous, demonstrating how India's separation from other landmasses led to unique evolutionary trajectories among theropod dinosaurs. As an abelisaurid theropod, it shares close phylogenetic affinities with taxa like Majungasaurus from Madagascar and Carnotaurus from South America, underscoring biogeographic connections between India and these regions prior to the final breakup of Gondwana. This has advanced understanding of abelisaurid diversification, revealing how endemic forms adapted to insular conditions on the Indian subcontinent. The 2003 description of Rajasaurus, based on the first associated cranial and postcranial remains of an theropod, marked a turning point for in , spurring increased fieldwork and funding for excavations in the and beyond. International collaborations, particularly between the , the , and U.S. institutions like the and , facilitated the assembly of the skull and subsequent analyses, enhancing global comparative studies. These efforts, supported by grants from the American Institute for Indian Studies and , resolved long-standing uncertainties about fragmentary theropod fossils from and identified multiple coexisting abelisaurid . In , Rajasaurus serves as a cornerstone for teaching in , featured prominently in school curricula to illustrate national prehistoric diversity and featured in exhibits at institutions like the in . Casts of its remains are housed at the Museum of Paleontology for study, while replicas appear in public displays at sites like the Gwalior Museum and Dinosaur Fossil Park, fostering hands-on learning about ecosystems. As a of India's rich heritage, Rajasaurus has elevated public awareness of the subcontinent's biota, challenging long-dominant Eurocentric narratives in by emphasizing the role of Gondwanan endemics in global evolutionary history.

References

  1. [1]
    [PDF] contributions from the museum of paleontology - Cloudfront.net
    Aug 17, 2006 · Their brief description noted several salient features, such as the lack of pleurocoels in presacral vertebrae, the short forelimb length ...<|control11|><|separator|>
  2. [2]
    Rajasaurus - Paul Sereno - The University of Chicago
    Rajasaurus was a stocky, carnivorous dinosaur with a head crest that lived at the end of the dinosaur era on India. The 30-foot-long predator would have pursued ...
  3. [3]
    Rajasaurus | Natural History Museum
    Rajasaurus was a large meat-eating dinosaur that lived towards the end of the Cretaceous Period in what is now India. It was a kind of abelisaur, a group that ...
  4. [4]
    Lameta Formation - Wikipedia
    History. The first fossils found in the Lameta Formation were discovered between 1917 and 1919. The Lameta Formation was first identified in 1981 by geologists ...
  5. [5]
    U-M researcher co-discovers horned dinosaur in India
    Aug 13, 2003 · A team that includes a University of Michigan paleontologist has identified from bones collected in India a stocky, carnivorous dinosaur with an unusual head ...
  6. [6]
    Why India's fossil wealth has remained hidden - BBC
    Jan 16, 2022 · ... Rajasaurus narmadensis, which is thought to have been 30ft (9.14m) long. But it's Sahni's less glamorous, lesser-known discoveries that have ...<|control11|><|separator|>
  7. [7]
    (PDF) A New Abelisaurid (Dinosauria, Theropoda) from the Lameta ...
    It has well developed amphicoelous concave articular surfaces ( Figure 25) while the Rajasaurus [132] and Rahiolisaurus [131] Its bones seem to be enveloped by ...<|control11|><|separator|>
  8. [8]
    Rajasaurus | Paul Sereno - Paleontologist - The University of Chicago
    Rajasaurus narmadensis. Type: theropod. Age: 65 million years old. Height at hip: 8 ft (2.44 m) Length: 30 ft (9.14 m) Discovery site: Niger, Africa.
  9. [9]
    [PDF] craniofacial anatomy of majungasaurus crenatissimus (theropoda ...
    Majungasaurus also possesses a derived suite of skull morphologies, including: a rostrocaudally abbreviated, dorsoventrally deep, and transversely broad skull; ...
  10. [10]
    (PDF) Review of the Cretaceous dinosaurs from India and their ...
    The Maastrichtian Lameta Formation has yielded at least 5 valid sauropod taxa and indeterminate titanosaurid remains, and at least 11 named (but likely ...
  11. [11]
    The postcranial axial skeleton of Majungasaurus crenatissimus ...
    Aug 10, 2025 · Majungasaurus (and abelisaurids generally) exhibit a robust cervical skeleton that features tightly interlocking cervical ribs, ...
  12. [12]
    [PDF] The Phylogeny of Ceratosauria (Dinosauria: Theropoda)
    Rajasaurus narmadensis Wilson et al., 2003. 197. Rugops primus Sereno et al., 2004. 197. Spinostropheus gautieri (Lapparent, 1960) Sereno et al., 2004. 197.
  13. [13]
    A new abelisaurid dinosaur from the end Cretaceous of Patagonia ...
    May 21, 2024 · and Shani, A., 2003. A new abelisaurid (Dinosauria, Theropoda) from the Lameta Formation (Cretaceous, Maastrichtian) of India. Contrib. Mus ...
  14. [14]
    An Abelisauroid Theropod Dinosaur from the Turonian of Madagascar
    Apr 18, 2013 · Geophysical evidence strongly supports the complete isolation of India and Madagascar (Indo-Madagascar) by ∼100 million years ago, ...Missing: Madagascan | Show results with:Madagascan
  15. [15]
    [PDF] Estimates of speeds of dinosaurs - Semantic Scholar
    This work has obtained a relationship between speed, stride length and body size from observations of living animals and applied this to dinosaurs to ...
  16. [16]
    An approach to scoring cursorial limb proportions in carnivorous ...
    Jan 27, 2016 · In this paper, we do not estimate absolute or relative maximum running speeds, but rather quantify and compare theropod limb proportions to ...
  17. [17]
    Myology of the forelimb of Majungasaurus crenatissimus ...
    Possible functions for this limb include intraspecific display, partner stimulation or clasping during mating. The unusual morphology of the abelisaurid ...
  18. [18]
    Osteohistological analyses reveal diverse strategies of theropod ...
    Small to medium abelisaurid taxa have been found to display a range of moderate to relatively slow growth rates [39], and although complicated by a lack of ...
  19. [19]
    The Cervical Vertebrae of the Late Cretaceous Abelisaurid Dinosaur ...
    Jun 27, 2012 · The distribution of vertebral centra with offset articular surfaces largely determines the sigmoid arching or curvature of the neck.Missing: posture carriage
  20. [20]
    None
    Nothing is retrieved...<|control11|><|separator|>
  21. [21]
    [PDF] Isolated theropod teeth associated with a sauropod skeleton from ...
    Jun 7, 2021 · the fact that Abelisauridae were feeding on titanosaurs. (Rogers et al. 2003, 2007; Sampson and Witmer 2007). Some abelisaurids were also ...
  22. [22]
    Preliminary investigations into the predator prey dynamics of Indian ...
    Aug 18, 2025 · Two dinosaur species, Rajasaurus narmadensis(Wilson), and Isisaurus colberti (Jain & Bandyopadhyay) dominated the late Maastrichtian stage of ...
  23. [23]
    Estimating bite force in extinct dinosaurs using phylogenetically predicted physiological cross-sectional areas of jaw adductor muscles
    ### Summary of Bite Force Estimates and Comments on Abelisaurids
  24. [24]
    Cannibalism in the Madagascan dinosaur Majungatholus atopus
    Aug 9, 2025 · Majungatholus clearly fed upon the remains of not only sauropods, but also conspecifics, and thus was a cannibal.
  25. [25]
    Vertebrate fauna from the Deccan volcanic province
    However, since 1980, several dinosaur fossils, including a few bones and teeth, and many eggshell fragments, have been documented from phase II ...
  26. [26]
    their palaeoecological and palaeoenvironmental significance
    The Lameta Formation (Upper Cretaceous) is exposed in parts of central and western India as detached outcrops and covers an area of nearly 5000 km2.
  27. [27]
    (PDF) Palaeoenvironments of the Lameta beds (late Cretaceous) at ...
    Aug 10, 2025 · The Maastrichtian age dinosaur-bearing Lameta Formation in Central India is a pedogenically modified sedimentary succession. This succession ...
  28. [28]
    https://pmc.ncbi.nlm.nih.gov/articles/PMC9848018/
  29. [29]
    New Late Cretaceous titanosaur sauropod dinosaur egg clutches ...
    Jan 18, 2023 · From the Lameta Formation, dinosaur clutches, isolated eggs and eggshell fragments have been reported from the Lameta Ghat (type section), Bara ...
  30. [30]
    (PDF) Indosuchus and Indosaurus, Cretaceous carnosaurs from India
    Aug 6, 2025 · Rajasaurus narmadensis has no preserved teeth or cranial elements ... The metatarsal measures 190 mm in length, suggesting a small animal, ~2.6 m ...Missing: weight | Show results with:weight
  31. [31]
    (PDF) First evidence of ankylosaurian dinosaurs (Ornithischia ...
    Jun 7, 2013 · The material, which comprises isolated teeth, is the youngest evidence of ankylosaurs in Australia. Although the Winton teeth exhibit a suite of ...
  32. [32]
    Island life in the Cretaceous - faunal composition, biogeography ...
    Jan 8, 2015 · These faunas lived on an island archipelago, and we describe how this insular setting led to ecological peculiarities such as low diversity, a ...
  33. [33]
    Predation upon Hatchling Dinosaurs by a New Snake from the Late ...
    New fossils from western India provide direct evidence of feeding ecology in a Mesozoic snake and demonstrate predation risks for hatchling sauropod dinosaurs.
  34. [34]
    Researchers uncover 92 fossil nests belonging to India's largest ...
    Jan 21, 2023 · Recent work in the area uncovered 92 nesting sites containing a total of 256 fossil eggs belonging to titanosaurs, which were among the largest dinosaurs ever ...
  35. [35]
    New Dinosaur Species Unearthed - CBS News
    Aug 14, 2003 · The dinosaur bones were discovered over the past 18 years by Indian scientists Suresh Srivastava of the Geological Survey of India and Ashok ...Missing: history SL Jain
  36. [36]
    Rajasaur (Short 2022) - IMDb
    A father and daughter living in prehistoric India, must embark on a dangerous mission to return the lost egg of a Rajasaurus, India's most dangerous dinosaur.Missing: documentary | Show results with:documentary
  37. [37]
    RAJASAURUS | Creatures | Jurassic World: The Game - Paleo.GG
    The Rajasaurus gets its name from a combination of Sanskrit and Greek, meaning 'king of lizards'. The Rajasaurus was a rare fossil find.Basic Stats · Facts · Evolutions
  38. [38]
    Jurassic World Roar Strikers™ Rajasaurus - Service.Mattel.com
    6-day delivery 30-day returnsJurassic World Roar Strikers™ Rajasaurus. Product#: HDX35 Released: 2022. Battery Info: 3 AG13 (LR44) button cell batteries required. Ages: 4 years and up.
  39. [39]
    Ashok Sahni: The man who placed India on the fossil map of the world
    Jul 17, 2007 · “The useful thing that came out of the Rajasaurus episode was speedy grants for future digs,” said Sahni. According to him, India is a hotbed of ...
  40. [40]
    Amber Analysis and Palaeoentomology Laboratory
    Prof. Sahni is a pioneer in the field of Indian Palaeontology who discovered the first Indian dinosaur fossil Rajasaurus along the Narmada River. It was his ...
  41. [41]
    Fossils of Rajasaurus, Narmada man find home at Gwalior museum
    Dec 16, 2024 · Its fossils were discovered in the Narmada river valley in Gujarat by paleontologist Suresh Srivastava of the GSI between 1982 and 1984.<|control11|><|separator|>
  42. [42]
    How Deccan volcanism, climate shifts, and continental drift shaped ...
    Jan 21, 2025 · Profound environmental changes and ecosystem reorganization were observed closer to the K-Pg boundary from sediments scoured by Samant and ...