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Silesaurus

Silesaurus is a genus of small silesaurid dinosauriform that lived during the Late Triassic epoch, approximately 230 million years ago, in what is now southern Poland.^[1] The type species, S. opolensis, was lightly built and measured about 2 meters (6.6 feet) in total length, with a slender body, long gracile limbs adapted for both bipedal and quadrupedal locomotion, and a skull featuring a beak-like lower jaw and low-crowned, leaf-shaped teeth.^[1] Initially interpreted as herbivorous based on its dental morphology, subsequent analyses of coprolites containing beetle remains indicate an omnivorous diet that included plants and insects.^[1]^[2] Known from over 20 partial to complete skeletons discovered at the Krasiejów clay pit, Silesaurus is one of the best-represented early dinosauriforms, offering critical insights into the anatomy and lifestyle of archosaurs just prior to the dinosaur radiation.^[1] Phylogenetically, silesaurids like Silesaurus are positioned as the sister group to Dinosauria within Dinosauriformes, though some analyses suggest they may form a paraphyletic grade leading to ornithischian dinosaurs; this debate highlights their role in understanding the evolutionary transition from nondinosaurian archosaurs to true dinosaurs.^[3] The species' fossils date to the late Carnian stage, placing it among the earliest known members of its clade, which dispersed across Pangaea during the Triassic.^[1]

Discovery

Fossil discoveries

The Krasiejów clay pit was identified as a significant fossil locality in the early 1990s, with scientific excavations beginning in 1993 under paleontologist Jerzy Dzik, in collaboration with the Institute of Paleobiology of the Polish Academy of Sciences.^[4] The first Silesaurus fossils were discovered during systematic excavations intensified from 2000 to 2003, resulting in the recovery of over 20 specimens. These included partial skeletons, skulls, and numerous isolated bones from a concentrated bonebed lens approximately 1 meter thick and 15 meters wide in the northeastern section of the quarry.^[4] The holotype specimen, cataloged as ZPAL Ab III/361, consists of a nearly complete skeleton with partial skull, discovered in 2001, and represents an adult individual preserving much of the axial and appendicular skeleton in articulation.^[4] Paratype specimens encompass a range of juvenile and adult individuals, providing an ontogenetic series that documents growth stages through variations in bone size and proportions across the assemblage.^[4] Following the 2003 field season, no additional major fossil finds of Silesaurus have been reported from Krasiejów, though ongoing analyses of the collected material continue to yield insights into the biota's diversity.^[4] The Krasiejów site holds particular importance as a key locality for Late Triassic archosauromorphs, preserving a diverse assemblage alongside Silesaurus.^[4]

Naming and validity

The genus Silesaurus and its type species S. opolensis were formally named and described by paleontologist Jerzy Dzik in 2003, based on multiple partial skeletons recovered from the Krasiejów clay-pit in southern Poland. The generic name Silesaurus derives from "Silesia," the historical region encompassing the discovery site, combined with the Greek sauros meaning "lizard" or "reptile"; the specific epithet opolensis honors the nearby city of Opole. The type locality lies within the upper fossiliferous horizon of the Krasiejów Formation, dated to the late Carnian stage of the Late Triassic, approximately 230 million years ago. In its original description, Dzik characterized Silesaurus opolensis as a beaked, herbivorous archosaur exhibiting close affinities to early dinosaurs, particularly through ornithischian-like features such as a predentary beak and leaf-shaped teeth suggestive of a basal position within Ornithischia. Subsequent phylogenetic analyses reclassified Silesaurus outside Dinosauria as the namesake genus of the clade Silesauridae, a group of basal dinosauriforms representing the immediate sister taxon to dinosaurs. The taxonomic validity of S. opolensis has been upheld by its distinct autapomorphies, including a beak-like structure on the dentaries, a reduced dentition of 11–12 teeth per dentary and maxilla, and specific dentary tooth morphology with prominent cingula, which differentiate it from other silesaurids despite early noted similarities in postcranial elements. Suggestions of potential synonymy with contemporaneous silesaurids, such as Sacisaurus, have been dismissed based on these cranial autapomorphies, confirming its monotypic status within the genus.

Description

General morphology

Silesaurus opolensis exhibited a slender, agile body plan typical of early dinosauriforms, with an estimated total length ranging from 2 to 3 meters and a body mass of 15 to 20 kilograms derived from skeletal scaling of multiple specimens.^[5] This lightweight construction, combined with proportionally elongated limbs, points to a cursorial lifestyle suited for rapid terrestrial locomotion in its Late Triassic habitat.^[6] The overall posture of Silesaurus allowed for both bipedal and quadrupedal gaits, supported by a relatively long neck that enhanced reach and a narrow snout adapted for precise foraging.^[6] Large orbital openings suggest keen visual acuity, potentially aiding in detecting small prey or environmental cues. No skin impressions are preserved among known fossils, leading to inferences of a lightweight integument similar to that observed in contemporaneous early archosaurs, though direct evidence is lacking. Evidence for sexual dimorphism remains undetermined, as the available material consists of fewer than 30 partial skeletons, limiting assessments of intraspecific variation.^[5]

Cranial features

The skull of Silesaurus opolensis measures approximately 17 cm in length and features an elongated rostrum that constitutes a significant portion of its overall proportions, ending in an edentulous beak-like tip on the dentaries separated by a vascularized ramp.^[1] A prominent antorbital fenestra is present, bordered ventrally by a ridge on the maxilla that defines the antorbital fossa.^[1] The dentition consists of leaf-shaped teeth with mesiodistally expanded crowns and coarse serrations along the mesial and distal edges, primarily on the premaxilla and maxilla; these teeth exhibit thin enamel, longitudinal ridges or grooves, and extensive wear facets.^[8] Up to 15–16 teeth are present per jaw quadrant, with 4 in the premaxilla, 11–12 in the maxilla, and 11–12 in the dentary, arranged irregularly and oriented laterally.^[1]^[8] The orbits are large, with a concave margin formed by the frontals and a raised dorsal rim, encircled by a sclerotic ring comprising about 12 elements, adaptations consistent with acute visual capabilities.^[1]^[9] The temporal fenestrae are well-developed, providing broad attachment surfaces for jaw adductor musculature.^[1] The braincase exhibits notable variation across specimens, including a large incision on the supraoccipital possibly for a dorsal head vein and an expanded floccular lobe of the cerebellum that accommodated agile head and neck movements.^[1]^[10] Unlike some later ornithischians, the skull lacks horns, crests, or other ornamental structures.^[1]

Postcranial skeleton

The postcranial skeleton of Silesaurus opolensis is characterized by an axial column adapted for flexibility and support, with approximately 7 cervical vertebrae that are elongated and amphicoelous, featuring ventral keels on the anterior ones and prominent laminae that delimit conical cavities, enabling enhanced neck flexibility.^[11]^[1] The dorsal vertebrae, numbering around 16, exhibit a gradual transition from the cervical series, with parapophyses migrating to the neural arch by the 6th or 7th vertebra, hourglass-shaped centra, and plate-shaped neural spines that narrow in the mid-region to allow some upward bending.^[11] The sacral region consists of 3–4 fused vertebrae, with robust ribs firmly connecting to the ilia via wing-like apophyses, providing structural support for an upright posture and bipedal capabilities.^[11]^[1] The tail comprises approximately 33–40 caudal vertebrae, with the proximal ones featuring high neural spines, wing-like transverse processes, and spool-shaped amphicoelous centra that taper distally, serving primarily for balance during locomotion.^[11] The forelimbs are shorter overall than the hindlimbs, with a humerus measuring about 136 mm, radius around 146.5 mm, and ulna approximately 151.8 mm, resulting in a gracile structure suited for support rather than propulsion.^[12] The manus, though incompletely preserved, includes five digits with a phalangeal formula of roughly 2-3-4-5-3, where digit I is the shortest and digit V is reduced, allowing for grasping functionality with the primary four digits.^[12] In contrast, the hindlimbs display greater elongation, with a femur of about 200 mm that is slender and slightly sigmoid, and a tibia measuring roughly 160 mm that is straight and robust, featuring a prominent cnemial crest.^[12]^[1] The ankle exhibits a mesotarsal joint, with the astragalus and calcaneum fused to form a crurotarsal articulation that connects the epipodials to the pes, resembling a bird-like configuration for efficient weight transmission.^[12] The pes includes five metatarsals, with digit I reduced to a vestigial element and digits II–IV bearing phalanges, while digit V consists only of a metatarsal.^[1] The pelvis is narrow and features a saurischian-like acetabulum that is large, closed, and ventrally oriented with a prominent supraacetabular crest, but the pubis shows an ornithischian-like orientation, being long (about 157 mm), curved, and directed more caudoventrally with a medial blade.^[12]^[1] These elements collectively indicate cursorial adaptations in the overall build, facilitating agile movement.^[12]

Classification

Placement in Archosauria

Silesaurus opolensis is a member of Silesauridae, a clade of basal dinosauriforms positioned within Avemetatarsalia, the avian lineage of archosaurs that also includes pterosaurs and dinosaurs. Silesauridae is widely regarded as the sister group to Dinosauria, rendering Silesaurus a non-dinosaurian archosaur that shares a close evolutionary relationship with the origins of dinosaurs.^[13]^[14] This placement highlights Silesaurus as a key taxon in understanding the early diversification of avemetatarsalian archosaurs during the Triassic period.^[15] Diagnostic synapomorphies of Silesauridae include asymmetrical, leaf-shaped teeth bearing subequal mesial and distal serrations, and a reduced fourth trochanter on the femur, features that distinguish the clade from more basal dinosauromorphs and early dinosaurs.^[16]^[17] These traits reflect adaptations potentially linked to herbivory and quadrupedal locomotion, bridging the morphological gap between earlier archosauromorphs and the fully bipedal stance of primitive dinosaurs.^[15] Silesaurus dates to the Late Carnian stage of the Late Triassic, around 230 million years ago, with the broader Silesauridae extending back into the Middle Triassic and thus predating the earliest unequivocal dinosaurs by approximately 10 million years.^[13]^[18] Compared to other silesaurids, Silesaurus from Poland represents a later, more derived form, while Asilisaurus from Tanzania (Middle Triassic, ~245 Ma) exemplifies the group's early origins, and Sacisaurus from Brazil (Late Triassic) shares similar cranial and femoral features indicative of a shared herbivorous niche across Pangea.^[19]^[17]

Phylogenetic debates

When Silesaurus opolensis was first described in 2003, it was classified as a basal ornithischian dinosaur or a close relative linking ornithischians and prosauropods, based on features such as a beak-like lower jaw and dentition suggestive of herbivory. Subsequent analyses, however, reclassified it as a non-dinosaurian dinosauriform, emphasizing its position outside Dinosauria due to the absence of key dinosaurian synapomorphies like an enlarged deltopectoral crest on the humerus and a perforated acetabulum.^[20] This shift highlighted ongoing uncertainties in its exact affinities within Archosauria. A 2022 phylogenetic study challenged traditional views by analyzing the hip morphology of silesaurs, including Silesaurus, and found saurischian-like arrangements in the pelvis, such as a propubic orientation and lack of an opposed pubis. This configuration suggests that early ornithischian ancestors retained saurischian hip traits, implying Silesaurus occupied a position near the base of sauropodomorphs or as a transitional form, thereby questioning Ornithischia as the basal dinosaur clade and proposing that bird-hipped features evolved secondarily from saurischian stock.^[21] Between 2011 and 2020, multiple cladistic analyses consistently positioned Silesauridae as stem-dinosaurs within Dinosauriformes, supported by shared derived traits like elongate hindlimbs and asymmetrical teeth, though a minority view advocated for a pseudosuchian offshoot based on limited cranial data.^[14]^[13] Recent 2025 research from the Natural History Museum examined a large silesaur specimen from Zambia, estimating body lengths exceeding 2 meters and suggesting silesaurs served as larger precursors to early dinosaurs, influencing size evolution patterns in the Late Triassic.^[22] This work reinforces silesaurs' role in dinosaur origins by indicating they may have been ecologically dominant herbivores before dinosaurs diversified. Additional 2025 studies have further informed the debate; for instance, analysis of silesaurid remains from the Otis Chalk locality in Texas recovered them as part of a paraphyletic grade at the base of Ornithischia, closely related to Silesaurus opolensis.^[23] Likewise, the description of the new silesaurid Itaguyra occulta from Brazil highlights the continuous presence of dinosauromorphs in South America during the Carnian, supporting hypotheses of silesaurids as early-branching ornithischians or stem-dinosaurs.^[24] Phylogenetic matrices in these studies, often comprising over 100 morphological characters such as pelvic girdle proportions and femoral curvature, consistently recover Silesaurus within Dinosauriformes under standard clade definitions (e.g., Dinosauriformes as the least inclusive clade containing Dinosauria and Lagerpeton chanarensis).^[23]^[3]

Palaeobiology

Locomotion

Silesaurus opolensis exhibited a primarily quadrupedal locomotion, functioning as an obligate quadruped capable of facultative bipedality for rapid maneuvers, as inferred from reconstructions of its locomotor musculature and skeletal posture in a detailed anatomical analysis.^[6] This versatility is supported by pillar-erected hindlimbs that provided efficient propulsion and fully erect forelimbs adapted primarily for body support rather than locomotion, contrasting with the more specialized bipedal gait of early theropods like Coelophysis, which relied less on forelimb stability.^[6] Limb proportions further emphasize this quadrupedal emphasis, with a hindlimb-to-forelimb length ratio of approximately 1.05, promoting an upright posture while necessitating forelimb reliance for balance during movement.^[6] The hindlimb-to-trunk ratio of 0.79 aligns with those of known obligate quadrupeds, indicating a body plan optimized for stability over speed in sustained travel.^[6] The foot morphology of Silesaurus was digitigrade, facilitating elevated limb posture and efficient weight distribution during quadrupedal progression.^[6] Phalanges terminated in prominent, claw-like unguals, particularly on digits II and III, which likely enhanced traction on varied terrains by providing grip during acceleration or turning.

Diet

The diet of Silesaurus opolensis has been inferred from multiple lines of evidence, including coprolites and dental features, suggesting an omnivorous feeding strategy rather than strict herbivory or carnivory. Analysis of coprolites attributed to S. opolensis from the Late Triassic of Poland revealed abundant remains of beetles and other small terrestrial invertebrates, indicating targeted insectivory as a significant component of its diet.^[2] These findings challenge earlier interpretations of Silesaurus as primarily herbivorous and support a mixed diet that included insects alongside plant material.^[25] Dental morphology provides additional insights into feeding habits. The teeth of S. opolensis are small, leaf-shaped, and bear fine serrations along their mesial and distal edges, features consistent with shearing soft vegetation or capturing small prey such as invertebrates. Microwear patterns on preserved teeth show low pit-to-scratch ratios, implying consumption of soft foods like tender plants or small arthropods rather than hard or abrasive items.^[8] The absence of direct gut contents in fossils further relies on these indirect indicators, with the dentition supporting omnivory by accommodating diverse food types. Jaw mechanics reinforce this interpretation. The skull of S. opolensis exhibits a slender mandible and reduced adductor muscle attachments, resulting in a weak bite force suited to processing soft vegetation or small invertebrates rather than tougher prey or bone-crushing. Cranial dentition, including a toothless, beak-like tip of the lower jaw, likely aided in cropping low-lying plants or nipping insects from the ground.^[8] In the evolutionary context of early dinosauriforms, the inferred omnivorous diet of Silesaurus represents a transitional stage between the carnivorous habits of basal archosaurs and the more specialized herbivory seen in later ornithischians, highlighting dietary flexibility during the radiation of Avemetatarsalia.^[14]

Palaeoenvironment

Geological setting

The fossils of Silesaurus opolensis were discovered in the Krasiejów clay pit near Opole, southwestern Poland, within the upper portion of the Late Triassic Keuper succession, specifically the Grabowa Formation (Patoka Member).^[26] This unit is correlated with the upper part of the Weser Formation in the Germanic Basin and dated to the Late Carnian stage (though some correlations suggest a possible Norian age), close to the Carnian-Norian boundary, approximately 230.91 ± 0.33 Ma based on high-precision U-Pb zircon dating from contemporaneous Italian strata.^[4] The lithology of the Krasiejów Formation consists primarily of marly mudstones, claystones, and siltstones, interbedded with thin calcareous grainstone lenses, reflecting a fluvial-lacustrine depositional environment characterized by meandering rivers, periodic flooding on subtropical floodplains, and alkaline lake basins influenced by fluvial input.^[4]^[27] Taphonomic evidence shows that Silesaurus fossils, including articulated skeletons and disarticulated elements, were preserved in a 1.0–1.5 m thick lacustrine horizon with minimal compaction (about one-third of original volume), suggesting rapid burial in anoxic, mudflat-like conditions that protected bones from decay. Sedimentological features, such as red palaeosols (vertisols) and alternations between dry and wet periods, point to a warm subtropical climate with strong seasonal variability, including heavy seasonal rainfalls and monsoonal influences on floodplain dynamics.^[4]^[28]

Associated biota

The Krasiejów site, where Silesaurus opolensis is found, preserves a diverse Late Triassic flora dominated by non-angiosperm vascular plants adapted to a fluvial and lacustrine environment. Terrestrial vegetation included ferns such as Sphenopteris sp., horsetails (sphenopsids) like Neocalamites merianii, and early conifers represented by genera such as Pseudohirmerella and Pachylepis.^[29]^[4] These plants formed wetland understories and drier upland associations, with hydrophilic elements like horsetails and ferns indicating riparian zones near seasonal water bodies, while conifers occupied better-drained areas.^[29] Aquatic flora featured characean algae, including Stellatochara germanica and three other species, contributing to the lacustrine biocoenosis.^[4] The associated fauna encompasses a range of invertebrates, fishes, amphibians, and reptiles, reflecting a complex riparian ecosystem. Invertebrates include mollusks and arthropods in lacustrine deposits, while fishes comprise ganoid species and dipnoans such as Ceratodus silesiacus.^[4] Amphibians are represented by temnospondyls like Metoposaurus krasiejowensis and Cyclotosaurus intermedius, which inhabited aquatic habitats.^[4] Reptilian taxa include pseudosuchians such as the aetosaur Stagonolepis olenkae, the phytosaur Paleorhinus cf. arenaceus, and rauisuchians like the large predator previously referred to Teratosaurus, alongside rare theropod dinosaurs and sphenodonts.^[4] Microvertebrate remains indicate additional diversity, including cynodonts and possible early crocodylomorph elements, though these are sparse.^[30] The Krasiejów assemblage documents approximately 50 taxa, underscoring its status as a biodiversity hotspot for Late Triassic archosauromorphs and other vertebrates in the Germanic Basin.^[4] This richness highlights a thriving ecosystem with distinct aquatic and terrestrial components, where Silesaurus coexisted with larger herbivores like the aetosaur Stagonolepis in riparian areas.^[4]

References

[1]
None
### Summary of Silesaurus opolensis from Dzik (2003)
[2]
Beetle-bearing coprolites possibly reveal the diet of a Late Triassic ...
Mar 13, 2019 · Silesaurus opolensis possesses characteristic cranial adaptations that were probably connected to diet [37]. Some of these adaptations are ...
[3]
A new large 'silesaur' specimen from the ?Late Triassic of Zambia
Jul 16, 2025 · 'Silesaurs' are bird-line archosaurs that either represent the sister clade to dinosaurs or a paraphyletic grade of early ornithischians.
[4]
[PDF] A Review of the Early Late Triassic Krasiejów Biota from Silesia ...
The Krasiejów lacustrine biota included algae, molluscs, arthropods, fish, Paleorhinus, and Metoposaurus. Inland had Stagonolepis, Silesaurus, and Teratosaurus.
[5]
https://doi.org/10.1080/02724634.2014.873045
[6]
https://doi.org/10.1111/joa.13155
[7]
https://doi.org/10.1671/0272-4634(2003)023%5B0556:ABHAWD%5D2.0.CO;2
[8]
[PDF] Dental microwear of a Late Triassic dinosauriform, Silesaurus ...
Jun 5, 2013 · Non-facet microwear of teeth from the left lower jaw (ZPAL Ab III 361/27) of Silesaurus opolensis Dzik, 2003 from the Upper Triassic; Krasiejów,.
[9]
New data on skull anatomy of Silesaurus opolensis - ResearchGate
Jul 8, 2015 · The skull was shorter and more robust and with probably highly reduced maxillary fenestra. The jugal is strong and high and in broad contact ...
[10]
Unexpected bird-like features and high intraspecific variation in the ...
Dec 13, 2017 · Unexpected bird-like features and high intraspecific variation in the braincase of the. Triassic relative of dinosaurs. Rafał Piechowskia,b ...
[11]
None
Below is a merged summary of the vertebral counts and features for *Silesaurus opolensis*, combining all information from the provided segments into a single, comprehensive response. To maximize detail and clarity, I will use a table in CSV format for the vertebral counts and morphological features, followed by additional notes and useful URLs. This ensures all data is retained and presented efficiently.
[12]
The locomotor musculature and posture of the early dinosauriform ...
The best known silesaurid is Silesaurus opolensis from the late Carnian of Poland (Dzik, 2003; Figure 1). The most unusual aspect of its anatomy, apart from its ...<|control11|><|separator|>
[13]
A new silesaurid from Carnian beds of Brazil fills a gap in ... - Nature
Apr 11, 2023 · Silesaurs—independent of their phylogenetic position—persisted during most of the Triassic Period, with its plesiomorphic body size advancing ...
[14]
A paraphyletic 'Silesauridae' as an alternative hypothesis for the ...
Aug 26, 2020 · We present an alternative evolutionary hypothesis that suggests consideration of traditional 'silesaurids' as a group of low-diversity clades.
[15]
Full article: Untangling the tree or unravelling the consensus ...
This clade was initially identified as the sister group to Dinosauria and described on the basis of five taxa: Silesaurus opolensis (Dzik, Citation2003), ...
[16]
A beaked herbivorous archosaur with dinosaur affinities from the ...
Aug 10, 2025 · Journal of Vertebrate Paleontology. September 2003; 23(3):556-574 ... Silesaurus opolensis (Dzik 2003; Dzik & Sulej, 2007). In addition ...
[17]
(PDF) The Late Triassic dinosauromorph Sacisaurus agudoensis ...
Aug 5, 2025 · Silesauridae is an exclusively Triassic group of dinosauromorphs ... reduced fourth trochanter. This cor-. responds to a symmetrical ...
[18]
The precise temporal calibration of dinosaur origins - PNAS
This new temporal framework assigns the Chañares dinosauromorph assemblage to the Late Triassic, specifically the early Carnian (236–234 Ma), because available ...Abstract · Sign Up For Pnas Alerts · DiscussionMissing: Silesaurus | Show results with:Silesaurus<|control11|><|separator|>
[19]
(PDF) A new silesaurid from the upper Ntawere Formation of Zambia ...
Aug 6, 2025 · Silesauridae, the sister group to Dinosauria, contains at least seven species. Here we describe Lutungutali sitwensis, gen. et sp. nov., the ...
[20]
Bone histology of Silesaurus opolensisDzik, 2003 from the Late ...
May 4, 2010 · Silesaurus possesses some features characteristic of ornithischian dinosaurs, such as the presence of a beak at the front of the lower jaw, yet ...
[21]
Shaking the dinosaur family tree: how did 'bird-hipped' dinosaurs ...
Sep 21, 2022 · The researchers conducted an extensive analysis of early dinosaurs as well as silesaurs, a group named after Silesaurus, first described in 2003 ...<|control11|><|separator|>
[22]
The first dinosaurs might have been bigger than expected
Jul 16, 2025 · Silesaurs are a group of dinosaur-like reptiles that lived during the Triassic between 240 to 200 million years ago. Despite the ancient age ...
[23]
Silesaurid (Archosauria: Dinosauriformes) remains from the base of ...
May 7, 2025 · Silesaurids are small-to-medium sized dinosauriform archosaurs, with a mostly herbivorous diet, and their fossil record spans much of Pangea ...
[24]
Digestive contents and food webs record the advent of dinosaur ...
Nov 27, 2024 · The early radiation of dinosaurs remains a complex and poorly understood evolutionary event. Here we use hundreds of fossils with direct ...<|separator|>
[25]
[PDF] The late Triassic development of playa, gilgai floodplain, and fluvial ...
Nov 10, 2018 · Nonetheless, Krasiejów represents only a small part of the entire flood- plain system and therefore should not be considered alone, as these.
[26]
Unraveling the origin of the Late Triassic multitaxic bone ...
The infills in the aquatic animal bones (sediment, pyrite and calcite) show deposition in a freshwater environment, while those in the terrestrial Stagonolepis ...
[27]
(PDF) Sphenopsid and fern remains from the Upper Triassic of ...
Aug 7, 2025 · Pacyna (2019) documented rare hydrophilic elements, sphenopsids, and ferns, from the flora of Krasiejów. A sphenopsid species, Neocalamites ...
[28]
[PDF] PRELIMINARY REPORT ON THE MICROVERTEBRATE FAUNAL ...
Fossil vertebrate remains of the Keuper unit from the vicinity of the village of Krasiejów located in SW Poland, have been analyzed for almost two decades.<|separator|>