identifier	taxonID	type	CVterm	format	language	title	description	additionalInformationURL	UsageTerms	rights	Owner	contributor	creator	bibliographicCitation
3031FBA3A09853B58B1B8BF38A1FB543.text	3031FBA3A09853B58B1B8BF38A1FB543.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Dacentrurinae Mateus, Maidment & Christiansen 2009	<div><p>Dacentrurinae Mateus, Maidment &amp; Christiansen, 2009 (nomen cladi conversum)</p><p>Registration number.</p><p>1099.</p><p>Phylogenetic definition.</p><p>The largest clade containing  Dacentrurus armatus Owen, 1875 but not  Stegosaurus stenops Marsh, 1887 . This is a maximum-clade definition.</p><p>Reference phylogeny.</p><p>Figure 5 of this paper is designated as the primary reference phylogeny. Additional reference phylogenies include figure 3.14 of Carpenter et al. (2001), figure 16.11 of Galton and Upchurch (2004), figure 8 of Maidment et al. (2006), figure 3 of Escaso et al. (2007 a), figure 11 A and 12 A of Maidment et al. (2008), figure 1 of Mateus et al. (2009), figure 1 of Maidment (2010), figure 1 and 2 of Raven and Maidment (2017), figure 6 A of Hao et al. (2018), figure 12 of Maidment et al. (2020), figure 8 of Dai et al. (2022), figure 6 of Jia et al. (2024), figure 15 of Li et al. (2024 a), figure 8 of Li et al. (2024 b), figure 7 of Li et al. (2024 c), and figure 12 of Zafaty et al. (2024).</p><p>Composition.</p><p>According to the primary reference phylogeny, the clade Dacentrurinae comprises  Al. longispinus,  K. aethiopicus, Th. atlasicus,  Ad. boulahfa, and  D. armatus .</p><p>Comments.</p><p>Dacentrurinae was first (informally) defined by Mateus et al. (2009). This is formalized using the same type of definition but replacing  S. armatus Marsh, 1877 with  S. stenops as external specifier. The species  S. armatus was originally designated as the type species of the genus  Stegosaurus, but it was later replaced by  S. stenops as the type (International Commission on Zoological Nomenclature 2013). Figure 5 of this paper has been designated as the primary reference phylogeny because it considers the latest taxonomic revisions, includes the highest number of stegosaurian OTUs, and provides a high-resolution topology.</p></div>	https://treatment.plazi.org/id/3031FBA3A09853B58B1B8BF38A1FB543	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Sánchez-Fenollosa, Sergio;Cobos, Alberto	Sánchez-Fenollosa, Sergio, Cobos, Alberto (2025): New insights into the phylogeny and skull evolution of stegosaurian dinosaurs: An extraordinary cranium from the European Late Jurassic (Dinosauria: Stegosauria). Vertebrate Zoology 75: 147-171, DOI: 10.3897/vz.75.e146618
F73F2FB4C6095069B77B62FB2EEBA30D.text	F73F2FB4C6095069B77B62FB2EEBA30D.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Dacentrurus armatus Owen 1875	<div><p>Dacentrurus armatus Owen, 1875</p><p>Synonymy.</p><p>Omosaurus armatus Owen, 1875,  Stegosaurus armatus Lydekker, 1888,  Omosaurus lennieri Nopcsa, 1911 b,  Dacentrurus lennieri Hennig, 1915 b,  Dacentrurosaurus armatus Hennig, 1925,  Miragaia longicollum Mateus, Maidment &amp; Christiansen, 2009, and  Dacentrurus longicollum Raven &amp; Maidment, 2017 .</p><p>Revised diagnosis.</p><p>D. armatus possesses the following autapomorphies (modified from Sánchez-Fenollosa et al. 2025): A premaxilla with (1) an anterior tip that drawn into a point; and (2) an anterolateral margin ventrally projected; a supraoccipital with (3) a posteroventrally orientation with an angle greater than 90 ° with the dorsal plane of the skull roof (new); a cervical series with (4) at least 17 cervical vertebrae; and (5) at least anterior and mid cervical ribs fused to the vertebrae; cervical vertebrae with (6) two spinopostzygapophyseal laminae that extend anterolaterally from the top of the postzygapophyses to both sides of the base of the neural spine and culminate on its anterior margin; mid and posterior cervical vertebrae with (7) neural spines positioned in the anterior half of the centrum; anterior caudal vertebrae with (8) short neural spines and expanded and rounded apices; an ilium with (9) a wide and short preacetabular process; and (10) a broad base of the preacetabular process and a smooth curvature between the anterior margin of the sacral yoke and the dorsal margin of the preacetabular process; and a pubis with (11) a dorsoventrally expanded anterior end of the prepubis.</p><p>Holotype.</p><p>NHMUK PV OR 46013 (Owen 1875; Galton 1985).</p><p>Type locality and horizon.</p><p>Unknown horizon. The fossils were discovered in a clay pit at the municipality of Swindon (United Kingdom). Lower part of the Kimmeridge Clay Formation, Upper Jurassic (Kimmeridgian) (Davies 1876; Galton 1985; Martill et al. 2006).</p><p>Referred material.</p><p>A partial cranium (MAP- 9029) (Figs 2, 3) and a mid cervical vertebra (MAP- 9030) (Fig. 4). Additional postcranial fossils of this specimen were recovered, but their study is beyond the scope of this research and some of them are still unprepared.</p><p>Other referred material.</p><p>MHNH A (Nopcsa 1911 b; Galton 1990), ML 433 (Fig. 6 A – G; Mateus et al. 2009), ML 433 - A (Mateus et al. 2009), MG 4863 (Costa and Mateus 2019), the Pedras Muitas specimen (Galton 1991; Escaso 2014), the Murteiras specimen (Galton 1991; Escaso 2014), the Atalaia specimen (Galton 1991; Escaso 2014), SHN. LPP 016 (Escaso et al. 2007 b), the CO specimen (Casanovas-Cladellas et al. 1995), the RD- 10 specimens (Cobos et al. 2010; Sánchez-Fenollosa et al. 2022), and the CT- 28 specimen (Sánchez-Fenollosa et al. 2025).</p><p>Locality and horizon.</p><p>Están de Colón (RD- 34) site in the municipality of Riodeva, province of Teruel, Aragón, Spain. South-Iberian Basin, Villar del Arzobispo Formation, Upper Jurassic (upper Kimmeridgian – Tithonian) (Fig. 1).</p><p>Locality and horizon of other referred material.</p><p>All specimens are known from the Upper Jurassic (Kimmeridgian – Tithonian) of western Europe (France, Portugal, and Spain) (Sánchez-Fenollosa et al. 2025 and references therein).</p><p>Systematic remarks.</p><p>This stegosaurian specimen is classified as  D. armatus because it possesses characters 5, 6, and 7 from the diagnosis. When coded as an independent OTU, it was recovered as sister to  D. armatus in the phylogenetic analyses (File S 1 [fig. S 1]).</p><p>Description.</p><p>Cranium (MAP- 9029) (Figs 2, 3). MAP- 9029 consist of the posterior half of the skull roof including a fragment of the right prefrontal, both frontals, both postorbitals, both squamosals, the parietal, the supraoccipital, and a possible fragment of the left paroccipital process (Figs 2, 3). The dorsal surface is slightly eroded and exhibits some cortical remodelling (Figs 2 A, 3 A). Perhaps for these reasons, sutures between elements are barely visible. Two small and open supratemporal fenestrae are present (Figs 2, 3 A – D). Lateral temporal fenestrae presumably are large. Ventrally it is strongly eroded including almost all the braincase (Figs 2, 3). Each element of the cranium will be described individually below. — Prefrontal. A small fragment of the right prefrontal can be observed in posteromedially contact to the frontal (Figs 2, 3 A – D). The suture with the frontal is barely visible (Figs 2, 3 B). Its surface is flat and smooth (Figs 2 A, 3 A). Presumably, the non-preserved supraorbitals would exclude the prefrontal (also the frontal) from the orbital rim similar to that in other stegosaurs (e. g., Sereno and Dong 1992; Galton and Upchurch 2004; Salgado et al. 2017; Maidment et al. 2018; pers. obs. [NHMUK PV R 36730]). — Frontal. Both frontals are present and they are longer than wide (Figs 2 A, 3 A, B) similar to that in  S. stenops (Galton and Upchurch 2004; pers. obs. [NHMUK PV R 36730]). Their surfaces are flat and the sagittal suture between them is straight and slightly convex (Figs 2 A, 3 A, B). The suture with postorbitals and parietal is barely visible in dorsal view (Figs 2 A, 3 A, B). — Postorbital. Both almost complete postorbitals are preserved and they form the anterolateral margins of the supratemporal fenestrae (Figs 2, 3 A – D). The medial process is flat, broad and sutured to the frontal and parietal (excluding the frontal from the anteromedial margin of the supratemporal fenestra) (Figs 2, 3 A – D) similar to that in  S. stenops (Galton and Upchurch 2004; pers. obs. [NHMUK PV R 36730]). The posterior process is slender and D-shaped in cross-section with a convex dorsal surface and a flattened ventral surface (Figs 2, 3 A – D). The posterior process is in contact to the squamosal (Figs 2, 3 A – D). The right postorbital preserves the most proximal part of the ventral process (Figs 2 B, 3 C) and dorsally in this area the postorbital is bulbous and exhibits a very small horn-like protuberance (Figs 2 A, 3 A). It is different from the bigger and more medially located protuberance of  H. taibaii (Sereno and Dong 1992) . — Squamosal. Both squamosals are present and triradiate (Figs 2, 3). They form the posterior margin of the supratemporal fenestrae and are in contact with the postorbital, parietal, and occiput (Figs 2, 3). The anterior process is short (Figs 2, 3 A – D) and in the left squamosal it can be seen to underlap the postorbital (Figs 2 B, C). The posterior process is well-developed and horn-like (Figs 2, 3). In dorsal and ventral views, the lateral margin between posterior processes of postorbital and squamosal is concave (Figs 2, 3 A – D). — Parietal. The parietal forms the medial margin of the supratemporal fenestrae (Figs 2, 3 A – D). It is sub-square in dorsal view and its dorsal surface is convex with a straight and pronounced sagittal crest (Figs 2 A, 3 A, B) similar to that in  T. multispinus (Dong et al. 1983) . Distinct breaks in slope separate the dorsal surface from the lateral surfaces and the occiput (Figs 2, 3 A – D). — Occiput. The upper-most part of the occiput is preserved and sutures between elements cannot be observed (Fig. 3 E, F). The surface of the supraoccipital is smooth and there is not a dorsoventral ridge (Figs 2 A, 3 E, F) similar to that in  K. aethiopicus (Galton 1988) . The supraoccipital is obliquely oriented with an angle greater than 90 ° with the dorsal plane of the skull roof (Figs 2, 3 A – D). A possible fragment of the left paroccipital process is preserved (Fig. 3 E, F).</p><p>Cervical vertebra (MAP- 9030) (Fig. 4). MAP- 9030 is an almost complete mid cervical vertebra (Fig. 4). It is distorted and the anterior-most part is missing; therefore, some features and measurements must be considered cautiously. The centrum is presumably amphicoelous (Fig. 4 C) and longer than wide and tall (File S 1 [table S 1]). The articular facets are wider than tall (File S 1 [table S 1]) and heart-shaped (Fig. 4 A, C). Smooth concentric ridges are present in the surface of the posterior articular facet (Fig. 4 C). Laterally, the parapophyses are located in the anterior margin and the upper half of the centrum (Fig. 4 A, B, E). The ventral surface is smooth and concave due to the distortion (Fig. 4 E). In general, the neural arch is anteroposteriorly elongated and dorsally short (Fig. 4 A – D). The neural canal is large and suboval (Fig. 4 A, C). Regarding the prezygapophyses, only the posterior-most region is preserved and located below the postzygapophyses (Fig. 4 A, B, D). The diapophyses arise on the neural arch ventral to the prezygapophyses (Fig. 4 A – C). Both cervical ribs are preserved and fused to the parapophyses and diapophyses of the vertebra (Fig. 4) similar to that in  D. armatus (Casanovas-Cladellas et al. 1995; Galton 1991; Mateus et al. 2009; Cobos et al. 2010; Costa and Mateus 2019; pers. obs. [ML 433 and CO specimen]), although only the left one is well-preserved (Fig. 4 B). The left cervical rib is posteriorly directed, medially curved, notably overhang the centrum and has a blunt and round tip (Fig. 4 B, D, E). The postzygapophyses are finger-like and extend beyond the posterior articular facet of the centrum (Fig. 4 B – D). This differs from the greatly elongated postzygapophyses of  S. stenops (Ostrom and McIntosh 1966; Escaso et al. 2007 a; Maidment et al. 2015). Their articular facets are lateroventrally directed and oval in outline (Fig. 4 B, C). Dorsally, two spinopostzygapophyseal laminae are well-visible, wide, and extending anterolaterally from the top of the postzygapophyses to both sides of the base of the neural spine and culminate on its anterior margin (Fig. 4 D). This condition is shared with  D. armatus (Mateus et al. 2009; Costa and Mateus 2019; pers. obs. [ML 433 and CO specimen]), but not with other stegosaurs (Ostrom and McIntosh 1966; Maidment et al. 2015; 2018; 2020; pers. obs. [NHMUK PV R 37367 and NHMUK PV R 37368]). The neural spine is located in the anterior half of the vertebra (Fig. 4 B) and it is short and slightly transversely expanded (Fig. 4 A, C) similar to that in  D. armatus (Casanovas-Cladellas et al. 1995; Mateus et al. 2009; Costa and Mateus 2019; pers. obs. [ML 433 and CO specimen]). However, it is in the posterior half of the centrum (Gilmore 1914; Hennig 1925; Ostrom and McIntosh 1966; Dong et al. 1983; Zhou 1984; Galton 1990; Carpenter et al. 2001; Escaso et al. 2007 a; Jia et al. 2007; Maidment et al. 2015; 2018) or in both halves (Maidment et al. 2020; pers. obs. [NHMUK PV R 37367 and NHMUK PV R 37368]) in other stegosaurian species.</p></div>	https://treatment.plazi.org/id/F73F2FB4C6095069B77B62FB2EEBA30D	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Sánchez-Fenollosa, Sergio;Cobos, Alberto	Sánchez-Fenollosa, Sergio, Cobos, Alberto (2025): New insights into the phylogeny and skull evolution of stegosaurian dinosaurs: An extraordinary cranium from the European Late Jurassic (Dinosauria: Stegosauria). Vertebrate Zoology 75: 147-171, DOI: 10.3897/vz.75.e146618
E7FCADDAEA1351BC8651E4F710575D6C.text	E7FCADDAEA1351BC8651E4F710575D6C.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Neostegosauria Sanchez-Fenollosa & Cobos	<div><p>Neostegosauria Sánchez-Fenollosa &amp; Cobos (nomen cladi novum)</p><p>Registration number.</p><p>1097.</p><p>Phylogenetic definition.</p><p>The smallest clade containing  Kentrosaurus aethiopicus Hennig, 1915 a,  Dacentrurus armatus Owen, 1875, and  Stegosaurus stenops Marsh, 1887 . This is a minimum-clade definition.</p><p>Etymology.</p><p>Derived from ‘ neo- ’ (Greek), meaning new. And from the clade name Stegosauria.</p><p>Reference phylogeny.</p><p>Figure 5 of this paper is designated as the primary reference phylogeny. Additional refence phylogenies include figure 3.14 of Carpenter et al. (2001), figure 8 of Maidment et al. (2006), figure 1 of Raven and Maidment (2017), figure 12 of Maidment et al. (2020), figure 8 of Dai et al. (2022), figure 6 of Jia et al. (2024), figure 15 of Li et al. (2024 a), figure 8 of Li et al. (2024 b), figure 7 of Li et al. (2024 c), and figure 12 of Zafaty et al. (2024).</p><p>Composition.</p><p>According to the primary reference phylogeny, the clade Neostegosauria comprises  Lo. priscus,  He. mjosi,  S. stenops,  J. junggarensis,  W. homheni,  Ya. ultimus,  Al. longispinus,  K. aethiopicus, Th. atlasicus,  Ad. boulahfa, and  D. armatus .</p><p>Comments.</p><p>Neostegosauria is the name established for the clade that includes the late-diverging members of  Stegosauridae (Stegosaurinae and Dacentrurinae). This clade has been recovered in the last phylogenetic analyses although with differences in composition and topology. According to the primary reference phylogeny, it is supported by six synapomorphies (File S 1 [1.6]). These synapomorphies, except the two cranial ones, are widely recognized in these taxa. Neostegosaurs are late-diverging stegosaurids of medium to large size that at least inhabited Africa and Europe during the Middle and Late Jurassic, North America during the Late Jurassic, and Asia during the Late Jurassic and Early Cretaceous. They are mainly characterized by presenting a dorsal process on the transverses processes of anterior and mid caudal vertebrae, and a solid sacral yoke with no foramina between ribs. Figure 5 of this paper has been designated as the primary reference phylogeny because it considers the latest taxonomic revisions, includes the highest number of stegosaurian OTUs, and provides a high-resolution topology.</p></div>	https://treatment.plazi.org/id/E7FCADDAEA1351BC8651E4F710575D6C	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Sánchez-Fenollosa, Sergio;Cobos, Alberto	Sánchez-Fenollosa, Sergio, Cobos, Alberto (2025): New insights into the phylogeny and skull evolution of stegosaurian dinosaurs: An extraordinary cranium from the European Late Jurassic (Dinosauria: Stegosauria). Vertebrate Zoology 75: 147-171, DOI: 10.3897/vz.75.e146618
89CE3725EF9A5371AD6CC7739D4EB480.text	89CE3725EF9A5371AD6CC7739D4EB480.taxon	http://purl.org/dc/dcmitype/Text	http://rs.tdwg.org/ontology/voc/SPMInfoItems#GeneralDescription	text/html	en	Stegosaurinae Marsh 1880	<div><p>Stegosaurinae Marsh, 1880 (nomen cladi conversum)</p><p>Registration number.</p><p>1098.</p><p>Phylogenetic definition.</p><p>The largest clade containing  Stegosaurus stenops Marsh, 1887 but not  Dacentrurus armatus Owen, 1875 . This is a maximum-clade definition.</p><p>Reference phylogeny.</p><p>Figure 5 of this paper is designated as the primary reference phylogeny. Additional refence phylogenies include figure 3.14 of Carpenter et al. (2001), figure 16.11 of Galton and Upchurch (2004), figure 8 of Maidment et al. (2006), figure 3 of Escaso et al. (2007 a), figure 11 A and 12 A of Maidment et al. (2008), figure 1 of Mateus et al. (2009), figure 1 of Maidment (2010), figure 1 and 2 of Raven and Maidment (2017), figure 6 A of Hao et al. (2018), figure 12 of Maidment et al. (2020), figure 8 of Dai et al. (2022), figure 6 of Jia et al. (2024), figure 15 of Li et al. (2024 a), figure 8 of Li et al. (2024 b), figure 7 of Li et al. (2024 c), and figure 12 of Zafaty et al. (2024).</p><p>Composition.</p><p>According to the primary reference phylogeny, the clade Stegosaurinae comprises  Lo. priscus,  He. mjosi,  S. stenops,  J. junggarensis,  W. homheni, and  Ya. ultimus .</p><p>Comments.</p><p>Stegosaurinae was first (informally) defined by Sereno (1998). Sereno (2005) defined Stegosaurinae applying the maximum-clade definition and using  S. stenops as the internal specifier and  D. armatus as the external specifier. This definition is formalized using the same type of definition and specifiers. Note that Raven et al. (2023) re-defined (informally) Stegosaurinae using  Stegosaurus and  Hesperosaurus Carpenter, Miles, and Cloward, 2001 as internal specifiers and a minimum-clade definition. There is no reason for its redefinition and makes it is less suitable. In fact, some authors have proposed the genus  Hesperosaurus as a subjective junior synonym of  Stegosaurus . Therefore, the ‘ traditional concept’ of Stegosaurinae is retained. Figure 5 of this paper has been designated as the primary reference phylogeny because it considers the latest taxonomic revisions, includes the highest number of stegosaurian OTUs, and provides a high-resolution topology.</p></div>	https://treatment.plazi.org/id/89CE3725EF9A5371AD6CC7739D4EB480	Public Domain	No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.		Pensoft via Plazi	Sánchez-Fenollosa, Sergio;Cobos, Alberto	Sánchez-Fenollosa, Sergio, Cobos, Alberto (2025): New insights into the phylogeny and skull evolution of stegosaurian dinosaurs: An extraordinary cranium from the European Late Jurassic (Dinosauria: Stegosauria). Vertebrate Zoology 75: 147-171, DOI: 10.3897/vz.75.e146618
