Biogeography

@misc{dansereau1957biogeography2,
    author = "Dansereau, P",
    title = "Biogeography",
    year = "1957",
    howpublished = "An Ecological Perspective: New York, Ronald, 394 p",
    note = "talkorigins\_source = {true}; raw\_reference = {Dansereau, P., 1957, Biogeography: An Ecological Perspective: New York, Ronald, 394 p.}"
}

@book{darlington1957zoogeography3,
    author = "Darlington, P. J",
    title = "Zoogeography",
    year = "1957",
    publisher = "The Geographical Distribution of Animals: New York, Wiley, 675 p",
    note = "talkorigins\_source = {true}; raw\_reference = {Darlington, P. J., 1957, Zoogeography: The Geographical Distribution of Animals: New York, Wiley, 675 p.}"
}

@article{darlington1959area,
    author = "Darlington, Philip J.",
    title = "AREA, CLIMATE, AND EVOLUTION",
    year = "1959",
    journal = "Evolution",
    url = "https://doi.org/10.1111/j.1558-5646.1959.tb03038.x",
    doi = "10.1111/j.1558-5646.1959.tb03038.x",
    number = "4",
    openalex = "W2326053869",
    pages = "488-510",
    volume = "13",
    references = "doi101038175234a0, doi101086396077, doi101111j109583121954tb00708x, doi101111j155856461947tb01340x, doi101525aa195052402a00270, doi1023071375443, doi105281zenodo18028696, doi105962bhltitle27468, openalexw2395298606, openalexw650249977"
}

@misc{darlington1959area4,
    author = "Darlington, P. J",
    title = "Area, climate, and evolution",
    year = "1959",
    howpublished = "Evolution, v. 13, p. 488-510",
    note = "talkorigins\_source = {true}; raw\_reference = {Darlington, P. J., 1959, Area, climate, and evolution: Evolution, v. 13, p. 488-510.}"
}

@book{darlington1965biogeography5,
    author = "Darlington, P. J",
    title = "Biogeography of the Southern End of the World",
    year = "1965",
    publisher = "Cambridge, Harvard University Press, 236 p",
    note = "talkorigins\_source = {true}; raw\_reference = {Darlington, P. J., 1965, Biogeography of the Southern End of the World: Cambridge, Harvard University Press, 236 p.}"
}

@article{doi101130001676061970813513ioptft20co2,
    author = "Atwater, Tanya",
    title = "Implications of Plate Tectonics for the Cenozoic Tectonic Evolution of Western North America",
    year = "1970",
    journal = "Geological Society of America Bulletin",
    url = "https://doi.org/10.1130/0016-7606(1970)81[3513:ioptft]2.0.co;2",
    doi = "10.1130/0016-7606(1970)81[3513:ioptft]2.0.co;2",
    openalex = "W2024953052"
}

@misc{brown1971mammals1,
    author = "Brown, J. H",
    title = "Mammals on mountaintops",
    year = "1971",
    howpublished = "nonequilibrium insular biogeography: American Naturalist, v. 105, p. 467-478",
    note = "talkorigins\_source = {true}; raw\_reference = {Brown, J. H., 1971, Mammals on mountaintops: nonequilibrium insular biogeography: American Naturalist, v. 105, p. 467-478.}"
}

A theory is presented that cranial crests of hadrosaurs were visual and acoustical display organs. Facial morphology and phylogeny of the Hadrosauridae and earlier theories of crest function are reviewed. The following hypothesis is presented: cranial crests, whether hollow or solid, served as visual signal structures, and hollow lambeosaur crests were also vocal resonators; all crests promoted successful matings within species, i.e., they served as premating genetic isolating mechanisms. The following predictions are tested and found to support the hypothesis: (1) hadrosaurs had well-developed eyes and ears; (2) external features of crests varied independently of internal structure; (3) crest variations were species-specific and sexually-dimorphic; (4) crest distinctiveness correlates with species diversity; (5) crest size tended to increase through time. The circumnarial depression on the side of the face in hadrosaurines housed an inflatable diverticulum of the nasal passage which served as a visual display organ. Primitive hadrosaurs (kritosaurs) possessed a small nasal horn used as a butting weapon in intraspecific combat. Because the weapon was also used in intimidative displays, narial diverticula evolved to draw attention to it. In the kritosaur Brachylophosaurus fighting was modified to ritualized head-pushing using the flat nasal “shield”. Saurolophines expanded the diverticula on to the elongated nasal horn, converting the weapon to a dominance rank symbol. In non-crested edmontosaurs, enlarged diverticula assumed a vocalization function. Lambeosaurs created resonators by enclosing the diverticula in bone; they further enhanced the resonator function of the nose by forming elongated “organ pipes” in the premaxillae. This “pushed” the olfactory region above the eyes as a conspicuous dome which then was modified to form species-specific visual display organs.

@article{doi101017s0094837300002165,
    author = "Hopson, James A.",
    title = "The evolution of cranial display structures in hadrosaurian dinosaurs",
    year = "1975",
    journal = "Paleobiology",
    abstract = "A theory is presented that cranial crests of hadrosaurs were visual and acoustical display organs. Facial morphology and phylogeny of the Hadrosauridae and earlier theories of crest function are reviewed. The following hypothesis is presented: cranial crests, whether hollow or solid, served as visual signal structures, and hollow lambeosaur crests were also vocal resonators; all crests promoted successful matings within species, i.e., they served as premating genetic isolating mechanisms. The following predictions are tested and found to support the hypothesis: (1) hadrosaurs had well-developed eyes and ears; (2) external features of crests varied independently of internal structure; (3) crest variations were species-specific and sexually-dimorphic; (4) crest distinctiveness correlates with species diversity; (5) crest size tended to increase through time. The circumnarial depression on the side of the face in hadrosaurines housed an inflatable diverticulum of the nasal passage which served as a visual display organ. Primitive hadrosaurs (kritosaurs) possessed a small nasal horn used as a butting weapon in intraspecific combat. Because the weapon was also used in intimidative displays, narial diverticula evolved to draw attention to it. In the kritosaur Brachylophosaurus fighting was modified to ritualized head-pushing using the flat nasal “shield”. Saurolophines expanded the diverticula on to the elongated nasal horn, converting the weapon to a dominance rank symbol. In non-crested edmontosaurs, enlarged diverticula assumed a vocalization function. Lambeosaurs created resonators by enclosing the diverticula in bone; they further enhanced the resonator function of the nose by forming elongated “organ pipes” in the premaxillae. This “pushed” the olfactory region above the eyes as a conspicuous dome which then was modified to form species-specific visual display organs.",
    url = "https://doi.org/10.1017/s0094837300002165",
    doi = "10.1017/s0094837300002165",
    openalex = "W2406812419",
    references = "doi105281zenodo16298542"
}

Development of Mesozoic and Cenozoic sedimentary basins in western North America was linked to the overall geodynamics of an active continental margin. The Cordilleran margin, now largely of Californian-type with a bounding transform, was Atlantic-type from late Precambrian to early Paleozoic, Japanese-type from late Paleozoic to early Mesozoic, and Andean-type from late Mesozoic to early Tertiary, when a continental-margin arc–trench system included the following tectonic elements from west to east: (a) the subduction complex at the main subduction zone; (b) forearc basins within the arc–trench gap; (c) the magmatic arc of generally andesitic volcanics and subjacent granitic plutons; (d) a backarc fold-thrust belt, commonly with an associated metamorphic infrastructure; and (e) the retroarc foreland basin adjacent to the craton. Progressive broadening of this tectonic system was achieved by tectonic accretion of oceanic elements to the edge of the continental block and by peeling of cover off rigid basement underthrust behind the arc along the edge of a zone of ductile lithosphere formed thermally beneath the arc. An initial Jurassic island arc evolved through the Cretaceous into a terrestrial Tertiary arc as subsiding forearc and retroarc basins were filled with sediment.

@article{doi101139e76129,
    author = "Dickinson, William R.",
    title = "Sedimentary basins developed during evolution of Mesozoic–Cenozoic arc–trench system in western North America",
    year = "1976",
    journal = "Canadian Journal of Earth Sciences",
    abstract = "Development of Mesozoic and Cenozoic sedimentary basins in western North America was linked to the overall geodynamics of an active continental margin. The Cordilleran margin, now largely of Californian-type with a bounding transform, was Atlantic-type from late Precambrian to early Paleozoic, Japanese-type from late Paleozoic to early Mesozoic, and Andean-type from late Mesozoic to early Tertiary, when a continental-margin arc–trench system included the following tectonic elements from west to east: (a) the subduction complex at the main subduction zone; (b) forearc basins within the arc–trench gap; (c) the magmatic arc of generally andesitic volcanics and subjacent granitic plutons; (d) a backarc fold-thrust belt, commonly with an associated metamorphic infrastructure; and (e) the retroarc foreland basin adjacent to the craton. Progressive broadening of this tectonic system was achieved by tectonic accretion of oceanic elements to the edge of the continental block and by peeling of cover off rigid basement underthrust behind the arc along the edge of a zone of ductile lithosphere formed thermally beneath the arc. An initial Jurassic island arc evolved through the Cretaceous into a terrestrial Tertiary arc as subsiding forearc and retroarc basins were filled with sediment.",
    url = "https://doi.org/10.1139/e76-129",
    doi = "10.1139/e76-129",
    openalex = "W2046368242",
    references = "doi101029jb077i023p04432, doi101029rg008i004p00813, doi10113000167606196879429sobina20co2, doi101130001676061969802409mcatuo20co2, doi101130001676061970813513ioptft20co2, doi101130001676061971822979lceotg20co2, doi101130001676061973842583arbgca20co2, doi10113000167606197586377saait20co2, doi101139e67013, doi102475ajs272297, openalexw106656250"
}

@book{pielou1979biogeography7,
    author = "Pielou, E. C",
    title = "Biogeography",
    year = "1979",
    publisher = "New York, Wiley",
    note = "talkorigins\_source = {true}; raw\_reference = {Pielou, E. C., 1979, Biogeography: New York, Wiley.}"
}

@article{doi10113000167606198394941teomaa20co2,
    author = "Anderson, Thomas H. and Schmidt, Victor A.",
    title = "The evolution of Middle America and the Gulf of Mexico–Caribbean Sea region during Mesozoic time",
    year = "1983",
    journal = "Geological Society of America Bulletin",
    url = "https://doi.org/10.1130/0016-7606(1983)94<941:teomaa>2.0.co;2",
    doi = "10.1130/0016-7606(1983)94<941:teomaa>2.0.co;2",
    openalex = "W2094938772"
}

Large‐volume ash flow eruptions and associated caldera collapses provide a direct link with subvolcanic granitic plutons of batholithic dimensions. The eruptive history, structural features, and petrologic evolution of ash flow calderas provide data on early stages of the evolution of an associated subvolcanic magmatic system. Broadly cogenetic, erosionally unroofed granitic plutons provide a record mainly of the late stages of emplacement and crystallization of silicic magmas. This review summarizes features of well‐studied calderas and ash flow volcanic fields in western North America, exposed at advantageous levels where both remnants of a Volcanic sequence and upper parts of the cogenetic intrusion are preserved, in comparison with similar rocks elsewhere in the worjd. Primary examples include San Juan, Mogollon‐Datil, Marysvale, Latir‐Questa, Chiricahua‐Turkey Creek, Challis, and Boulder Batholith‐Elkhorn Mountains. Most ash flows have erupted from sites of preceding volcanism that records shallow accumulation of caldera‐related magma. Structural boundaries of calderas are single ring faults or composite ring fault zones that dip vertically to steeply inward; outward dipping boundary faults favored by some models have not been identified in North American calderas. The area and volume of caldera collapse are roughly proportional to the amount of erupted material. Pyroclastic eruptions of relatively small volume (less than 50–100 km 3) may cause incomplete hinged caldera subsidences or structural sags; larger systems are bounded by complete ring faults. Few ash flow vent structures have been related to major calderas; vent geometry, as determined by size analyses of pyroclastic materials, may shift complexly during caldera collapse. Scalloped topographic walls beyond the structural boundaries of most calderas are due to secondary gravitational slumping during subsidence. Most exposed floors are a structurally coherent plate or cylinder bounded by a ring fault or dike, indicating pistonlike caldera collapse; chaotically brecciated floors predicted by models of piecemeal collapse have not been identified. Deviations from circular shape commonly reflect influence of regional structures; some calderas in extensional terranes are elongate in the direction of extension. Large calderas (greater than 100 km 3 of erupted material) collapse concurrently with eruption, as indicated by thick intracaldera ash flow fill and interleaved collapse slide breccias. Volumes of intracaldera and outflow tuff tend to be subequal; correlation between them is commonly complicated by contrasts in abundance and size of phenocrysts and lithic fragments, degree of welding, devitrification, alteration, and even chemical composition of magmatie material. Postcollapse volcanism may occur from varied vent geometries within ash flow calderas; ring vent eruptions are most common in resurgent calderas, reflecting renewed magmatic pressure. Large intrusions related to resurgence are exposed centrally within some calderas; ring dikes and other intrusions along bounding ring fractures are especially common in alkalic igneous systems in extensional environments. Subvolcanic magma chambers of calc‐alkaline affinities associated with plate‐convergent tectonic settings may rise to such high levels that deep cauldron subsidence structures are obliterated. Resurgence within calderas may result in a symmetrical dome or more geometrically complex forms; resurgence is most common in large calderas (greater than 10‐km diameter) in cratonic crust and is associated with large silicic intrusions. In addition to resurgence within single calderas, broader magmatic uplift occurs widely within silicic volcanic fields, reflecting isostatic adjustment to emplacement of associated subvolcanic batholiths. Much additional space for shallow batholith emplacement is probably accommodated by gravitationally driven down warping of wall rocks at lower structural levels. Hydrothermal activity and mineralization accompany all stages of ash flow magmatism, becoming dominant late during caldera evolution. Much rich mineralization is millions of years later than caldera collapse, where the caldera served primarily as a structural control for genetically unrelated intrusions and associated hydrothermal systems.

@article{doi101029jb089ib10p08801,
    author = "Lipman, Peter W.",
    title = "The roots of ash flow calderas in western North America: Windows into the tops of granitic batholiths",
    year = "1984",
    journal = "Journal of Geophysical Research Atmospheres",
    abstract = "Large‐volume ash flow eruptions and associated caldera collapses provide a direct link with subvolcanic granitic plutons of batholithic dimensions. The eruptive history, structural features, and petrologic evolution of ash flow calderas provide data on early stages of the evolution of an associated subvolcanic magmatic system. Broadly cogenetic, erosionally unroofed granitic plutons provide a record mainly of the late stages of emplacement and crystallization of silicic magmas. This review summarizes features of well‐studied calderas and ash flow volcanic fields in western North America, exposed at advantageous levels where both remnants of a Volcanic sequence and upper parts of the cogenetic intrusion are preserved, in comparison with similar rocks elsewhere in the worjd. Primary examples include San Juan, Mogollon‐Datil, Marysvale, Latir‐Questa, Chiricahua‐Turkey Creek, Challis, and Boulder Batholith‐Elkhorn Mountains. Most ash flows have erupted from sites of preceding volcanism that records shallow accumulation of caldera‐related magma. Structural boundaries of calderas are single ring faults or composite ring fault zones that dip vertically to steeply inward; outward dipping boundary faults favored by some models have not been identified in North American calderas. The area and volume of caldera collapse are roughly proportional to the amount of erupted material. Pyroclastic eruptions of relatively small volume (less than 50–100 km 3) may cause incomplete hinged caldera subsidences or structural sags; larger systems are bounded by complete ring faults. Few ash flow vent structures have been related to major calderas; vent geometry, as determined by size analyses of pyroclastic materials, may shift complexly during caldera collapse. Scalloped topographic walls beyond the structural boundaries of most calderas are due to secondary gravitational slumping during subsidence. Most exposed floors are a structurally coherent plate or cylinder bounded by a ring fault or dike, indicating pistonlike caldera collapse; chaotically brecciated floors predicted by models of piecemeal collapse have not been identified. Deviations from circular shape commonly reflect influence of regional structures; some calderas in extensional terranes are elongate in the direction of extension. Large calderas (greater than 100 km 3 of erupted material) collapse concurrently with eruption, as indicated by thick intracaldera ash flow fill and interleaved collapse slide breccias. Volumes of intracaldera and outflow tuff tend to be subequal; correlation between them is commonly complicated by contrasts in abundance and size of phenocrysts and lithic fragments, degree of welding, devitrification, alteration, and even chemical composition of magmatie material. Postcollapse volcanism may occur from varied vent geometries within ash flow calderas; ring vent eruptions are most common in resurgent calderas, reflecting renewed magmatic pressure. Large intrusions related to resurgence are exposed centrally within some calderas; ring dikes and other intrusions along bounding ring fractures are especially common in alkalic igneous systems in extensional environments. Subvolcanic magma chambers of calc‐alkaline affinities associated with plate‐convergent tectonic settings may rise to such high levels that deep cauldron subsidence structures are obliterated. Resurgence within calderas may result in a symmetrical dome or more geometrically complex forms; resurgence is most common in large calderas (greater than 10‐km diameter) in cratonic crust and is associated with large silicic intrusions. In addition to resurgence within single calderas, broader magmatic uplift occurs widely within silicic volcanic fields, reflecting isostatic adjustment to emplacement of associated subvolcanic batholiths. Much additional space for shallow batholith emplacement is probably accommodated by gravitationally driven down warping of wall rocks at lower structural levels. Hydrothermal activity and mineralization accompany all stages of ash flow magmatism, becoming dominant late during caldera evolution. Much rich mineralization is millions of years later than caldera collapse, where the caldera served primarily as a structural control for genetically unrelated intrusions and associated hydrothermal systems.",
    url = "https://doi.org/10.1029/jb089ib10p08801",
    doi = "10.1029/jb089ib10p08801",
    openalex = "W2104144529",
    references = "openalexw2000029815"
}

@article{lehman1987late,
    author = "Lehman, Thomas M.",
    title = "Late Maastrichtian paleoenvironments and dinosaur biogeography in the western interior of North America",
    year = "1987",
    journal = "Palaeogeography, Palaeoclimatology, Palaeoecology",
    url = "https://doi.org/10.1016/0031-0182(87)90032-0",
    doi = "10.1016/0031-0182(87)90032-0",
    openalex = "W1967510231",
    pages = "189-217",
    volume = "60",
    references = "doi101038288329a0, doi1010970001069419510500000019, doi10113000167606198394941teomaa20co2, doi1011300091761319821070taatoo20co2, doi101139e76129, doi10120197802037498838, doi1031582rmagmg63119, doi105281zenodo16298542, lozinsky1984late, openalexw2000029815, openalexw2246336267, openalexw337536883, openalexw610180004"
}

@misc{lehman1987late6,
    author = "Lehman, T. M",
    title = "Late Maastrichtian paleoenvironments and dinosaur biogeography in the western interior of North America",
    year = "1987",
    howpublished = "Palaeogeography, Palaeoclimatology, Palaeoecology, v. 60, p. 189-217",
    note = "talkorigins\_source = {true}; raw\_reference = {Lehman, T. M., 1987, Late Maastrichtian paleoenvironments and dinosaur biogeography in the western interior of North America: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 60, p. 189-217.}"
}

@incollection{crossref1995biogeography,
    title = "Biogeography",
    year = "1995",
    booktitle = "Carcasson's African Butterflies",
    url = "https://doi.org/10.1071/9780643100787.ch04",
    doi = "10.1071/9780643100787.ch04",
    pages = "17-47"
}

Quantification in historical biogeography has usually been based on the search for a single branching relationship among areas of endemism. Unlike organisms, however, areas rarely have a unique hierarchical history. Dispersal barriers appear and disappear and may have different effects on different species. As a result, the biota of an area may consist of several components with separate histories, each of which may be reticulate rather than branching. In an attempt to address these problems, I present a new biogeographic method, dispersal–vicariance analysis, which reconstructs the ancestral distributions in a given phylogeny without any prior assumptions about the form of area relationships. A three-dimensional step matrix based on a simple biogeographic model is used in the reconstruction. Speciation is assumed to subdivide the ranges of widespread species into vicariant components; the optimal ancestral distributions are those that minimize the number of implied dispersal and extinction events. Exact algorithms that find the optimal reconstruction(s) are described. In addition to their use in taxon biogeography, the inferred distribution histories of individual groups serve as a basis for the study of general patterns in historical biogeography, particularly if the relative age of the nodes in the source cladograms is known.

@article{doi101093sysbio461195,
    author = "Ronquist, Fredrik",
    title = "Dispersal-Vicariance Analysis: A New Approach to the Quantification of Historical Biogeography",
    year = "1997",
    journal = "Systematic Biology",
    abstract = "Quantification in historical biogeography has usually been based on the search for a single branching relationship among areas of endemism. Unlike organisms, however, areas rarely have a unique hierarchical history. Dispersal barriers appear and disappear and may have different effects on different species. As a result, the biota of an area may consist of several components with separate histories, each of which may be reticulate rather than branching. In an attempt to address these problems, I present a new biogeographic method, dispersal–vicariance analysis, which reconstructs the ancestral distributions in a given phylogeny without any prior assumptions about the form of area relationships. A three-dimensional step matrix based on a simple biogeographic model is used in the reconstruction. Speciation is assumed to subdivide the ranges of widespread species into vicariant components; the optimal ancestral distributions are those that minimize the number of implied dispersal and extinction events. Exact algorithms that find the optimal reconstruction(s) are described. In addition to their use in taxon biogeography, the inferred distribution histories of individual groups serve as a basis for the study of general patterns in historical biogeography, particularly if the relative age of the nodes in the source cladograms is known.",
    url = "https://doi.org/10.1093/sysbio/46.1.195",
    doi = "10.1093/sysbio/46.1.195",
    openalex = "W2098673312",
    references = "doi101006clad19941010, doi101093sysbio293254, doi101093sysbio414436, doi101093sysbio43158, doi101111j109600311990tb00532x, doi101111j155856461994tb01326x, doi101111j155856461996tb04494x, doi1023072992205, doi104159harvard9780674865327, doi105860choice392183"
}

ABSTRACT Although sauropods played a major role in terrestrial ecosystems during much of the Mesozoic Era, little effort has been directed toward diagnosing Sauropoda and establishing higher-level interrelationships among sauropods. As a consequence, the origin and evolution of major skeletal adaptations in sauropods has remained largely speculative. The cladistic analysis presented here focuses on higher-level relationships among sauropods. Based on 109 characters (32 cranial, 24 axial, 53 appendicular) for 10 sauropod taxa, the most parsimonious arrangement places four genera (Vulcanodon, Shunosaurus, Barapasaurus, and Omeisaurus) as a sequence of sister-taxa to a group of advanced sauropods, defined here as Neosauropoda. Neosauropoda, in turn, is composed of the sister-clades Diplodocoidea and Macronaria; the latter is a new taxon that includes Haplocanthosaurus, Camarasaurus, and Titanosauriformes. Titanosauriformes includes Brachiosauridae and Somphospondyli, a new taxon uniting Euhelopus and Titanosauria. Among macronarians, the position of Haplocanthosaurus is the least stable as a result of the absence of cranial remains. The basic structure of the phylogeny is resilient to various tests and establishes the evolutionary sequence of many functionally significant sauropod adaptations, such as the digitigrade posture of the manus in neosauropods. Other characteristic sauropod adaptations, such as narrow tooth crowns, increases in length and number of cervical vertebrae, and bifid neural spines, are shown to have evolved more than once. As these results underscore, the higher-level phylogeny of sauropods must be based on a broad sampling of character data. The fossil record of sauropods, although relatively limited during the early phase of the radiation (Late Triassic through Early Jurassic), nonetheless indicates that all major clades were established prior to the Late Jurassic, when substantial faunal interchange among major continental regions was still possible. The functional, temporal, and biogeographic implications of the higher-level phylogeny of sauropods are explored.

@article{doi10108002724634199810011115,
    author = "Wilson, Jeffrey A. and Sereno, Paul C.",
    title = "Early Evolution and Higher-Level Phylogeny of Sauropod Dinosaurs",
    year = "1998",
    journal = "Journal of Vertebrate Paleontology",
    abstract = "ABSTRACT Although sauropods played a major role in terrestrial ecosystems during much of the Mesozoic Era, little effort has been directed toward diagnosing Sauropoda and establishing higher-level interrelationships among sauropods. As a consequence, the origin and evolution of major skeletal adaptations in sauropods has remained largely speculative. The cladistic analysis presented here focuses on higher-level relationships among sauropods. Based on 109 characters (32 cranial, 24 axial, 53 appendicular) for 10 sauropod taxa, the most parsimonious arrangement places four genera (Vulcanodon, Shunosaurus, Barapasaurus, and Omeisaurus) as a sequence of sister-taxa to a group of advanced sauropods, defined here as Neosauropoda. Neosauropoda, in turn, is composed of the sister-clades Diplodocoidea and Macronaria; the latter is a new taxon that includes Haplocanthosaurus, Camarasaurus, and Titanosauriformes. Titanosauriformes includes Brachiosauridae and Somphospondyli, a new taxon uniting Euhelopus and Titanosauria. Among macronarians, the position of Haplocanthosaurus is the least stable as a result of the absence of cranial remains. The basic structure of the phylogeny is resilient to various tests and establishes the evolutionary sequence of many functionally significant sauropod adaptations, such as the digitigrade posture of the manus in neosauropods. Other characteristic sauropod adaptations, such as narrow tooth crowns, increases in length and number of cervical vertebrae, and bifid neural spines, are shown to have evolved more than once. As these results underscore, the higher-level phylogeny of sauropods must be based on a broad sampling of character data. The fossil record of sauropods, although relatively limited during the early phase of the radiation (Late Triassic through Early Jurassic), nonetheless indicates that all major clades were established prior to the Late Jurassic, when substantial faunal interchange among major continental regions was still possible. The functional, temporal, and biogeographic implications of the higher-level phylogeny of sauropods are explored.",
    url = "https://doi.org/10.1080/02724634.1998.10011115",
    doi = "10.1080/02724634.1998.10011115",
    openalex = "W1981694118",
    references = "crossref1976allosaurus, doi1010079789400904095, doi101038063003a0, doi101038114085a0, doi10108002724634199110011386, doi10108002724634199410011523, doi10108002724634199410011524, doi10108002724634199710011027, doi101093oxfordjournalsafrafa100309, doi101098rstb19950125, doi101111j109583121965tb00944x, doi101111j109636421985tb00871x, doi101111j150239311985tb00690x, doi101126science2562999, doi101126science2665183267, doi101127njgpa210199841, doi1023071292217, doi1023073514751, doi1023073514816, doi102307jctv143mdjg, doi102475ajss31695411, doi102475ajss319111253, doi102475ajss321125417, doi102475ajss32313381, doi105281zenodo16171435, doi105860choice331556, openalexw1025856234, openalexw2173200745, openalexw2472827083, openalexw616953834, openalexw653009579"
}

Thematic Table of Contents. Contributors. A Guide to Using the Encyclopedia. Michael Crichton, Foreword. Preface. Dedication. F.E. Novas, Abelisauridae. L.L. Jacobs, African Dinosaurs. G. Erickson, Age Determination. A. Chinsamy, Albany K. Padian and J.R. Hutchinson, Allosauroidea. P. Dodson, American Dinosaurs. L. Dingus, American Museum of Natural History. K. Carpenter, Ankylosauria. J.M. Parrish, Archosauria. J.R. Hutchinson and K. Padain, Arctometatarsalia. R.E. Molnar, Australasian Dinosaurs. L.M. Chiappe, Aves. The Editors, Avetheropoda. K. Padian, Avialae. H. Osmolska, Barun Goyot Formation. J.L. Sanz, Bastus Nesting Site. The Editors, Bavarian State Collection for Paleontology and Historical Geology. P. Currie, Bayan Mandahu. H. Osmolska, Bayn Dzak. J.R. Horner, Behavior. A. Chinsamy, Bernard Price Institute for Paleontological Research. J. Le Loeuff, Biogeography. R.M. Alexander, Biomechanics. R. Chapman, Biometrics. C. Trueman, Biomineralization. S.G. Lucas, Biostratigraphy. K. Padian, Bipedality. K. Padian, Bird Origins. B. Breithaupt, Bone Cabin Quarry. P. Currie, Braincase Anatomy. K. Padain and J.R. Hutchinson, Bullatosauria. M. Lockley, Cabo Espichel. J.S. Moratalla and J.L. Sanz, Cameros Basin Megatracksite. C. Coy, Canadian Dinosaurs. K. Carpenter, Canon City. M. Lockley, Carenque. J.S. McIntosh, Carnegie Museum of Natural History. J.R. Hutchinson and K. Padian, Carnosauria. J. Kirkland, Cedar Mountain Formation. M. Norell, Central Asiatic Expeditions. The Editors, Cerapoda. P. Dodson, Ceratopsia. T. Rowe, R. Tykoski, and J.R. Hutchinson, Ceratosauria. H. Bocherens, Chemical Composition of Dinosaur Fossils. D. Zhiming, Chinese Dinosaurs. J.M. Parrish, Chinle Formation. J.B. Smith, Cleveland-Lloyd Dinosaur Quarry. D. Maxwell, Cloverly Formation. J.R. Hutchinson and K. Padian, Coelurosauria. M.J. Ryan and A.P. Russell, Color. B. Breithaupt, Como Bluff. R.E. Chapman and D.B. Weishampel, Computers and Related Technology. J. Wright, Connecticut River Valley. D.B. Weishampel, Constructional Morphology. K. Chin, Coprolites. L.M. Witmer, Craniofacial Air Sinus Systems. E-B. Koppelhus, Cretaceous Period. J.M. Clark, Crocodylia. W.A.S. Sarjeant, Crystal Palace Dinosaurs. B. Britt and K.L. Stadtman, Dalton Wells Quarry. A. Sahni, Deccan Basalt. The Editors, Deinonychosauria. K. Carpenter, Denver Museum of Natural History. C. Coy, Devil's Coulee Dinosaur Egg Historic Site. M.J. Ryan and M.K. Vickaryous, Diet. K. Padian, Dinosauria: Definition. D. Chure, Dinosaur National Monument. A.B. Arcucci, Dinosauromorpha. C. Coy, Dinosaur Provincial Park. M. Lockley, Dinosaur Ridge. Don Lesson, Dinosaur Society. M. Lockley, Dinosaur Valley. M. Lockley, Dinoturbation. P. Dodson, Distribution and Diversity. T. Jerzykiewicz, Djadokhta Formation. P.A. Murry and R.A. Long, Dockum Group. P. Currie, Dromaeosaridae. B. Britt and B.I. Curtice, Dry Mesa Quarry. M.J. Ryan, Dryosauridae. D.A. Eberth, Edmonton Group. J.R. Horner, Egg Mountain. K.E. Mikhailov, Eggs, Eggshells, and Nests. P. Currie, Elmisauridae. The Editors, Enantiornithes. P. Currie, Erenhot Dinosaur The Editors, Euornithopoda. E. Buffetaut, European Dinosaurs. J.D. Archibald, Evolution. J.D. Archibald, Extinction, Cretaceous. M.J. Benton, Extinction, Triassic. P. Guangzhao, Fabrosauridae. M. Lockley, Fatima. P. Currie, Feathered Dinosaurs. M. Lockley, Footprints and Trackways. Per Christiansen, Forelimbs and Hands. J.I. Kirkland, Fruita Paleontological Area. M.J. Ryan, Fruitland Formation. X-C. Wu, Functional Morphology. L. Claessens, Gastralia. D.D. Gillette, Gastroliths. The Editors, Genasauria. J.M. Parrish, Genetics. C.C. Swisher, Geologic Time. C. Coy, Ghost Ranch. K. Padian, Glen Canyon Group. D.A. Winkler, Glen Rose, Texas. P. Currie, Graduate Studies. D.J. Varricchio, Growth and Embryology. K. Padian, Growth Lines. C.A. Forster, Hadrosauridae. K.R. Johnson, Hell Creek Flora. D.F. Lofgren, Hell Creek Formation. F.E. Novas, Herrerasauridae. J.A. Long and K.J. McNamara, Heterochrony. J.B. Smith, Heterodontosauridae. Per Christiansen, Hind Limbs and Feet. R.E.H. Reid, Histology of Bones and Teeth. W.A.S. Sarjeant, History of Dinosaur Discoveries: Early Discoveries. B. Breithaupt, History of Dinosaur Discoveries: First Golden Period. E. Buffetaut, History of Dinosaur Discoveries: Quiet Times. L. Psihoyos, History of Dinosaur Discoveries: Research Today. B. Breithaupt, Howe Quarry. H-D. Sues, Hypsilophodontidae. C.A. Forster, Iguanodontidae. A. Sahni, Indian Dinosaurs. The Editors, Institute de Paleontologie, Museum National d'Histoire Naturelle, Paris, France. D. Zhiming, Institute of Vertebrate Paleontology and Paleoanthropology, Beijing, China. D.A. Russell, Intelligence. R.R. Rogers, Ischigualasto Formation. Y. Azuma and Y. Tamida, Japanese Dinosaurs. D.A. Eberth, Judith River Wedge. D. Lessem and M. Schweitzer, Jurassic Park. P. Dodson, Jurassic Period. H. Haubold, Keuper Formation. M. Lockley, Khodja-Pil-Ata. M.J. Ryan, Kirtland Formation. A. Sahni, Lameta Formation. B. Breithaupt, Lance Formation. S.G. Lucas, Land-Mammal Ages. B.P. Perez-Moreno and J.L. Sanz, Las Hoyas. V.L. Santucci, Legislation Protecting Dinosaur Fossils. D.B. Weishampel, Life History. M. Lockley, Lommiswil. E. Frey and J. Martin, Long Necks of Sauropods. D. Zhiming, Lufeng. K. Padian, Maniraptora. K. Padian, Maniraptoriformes. The Editors, Marginocephalia. K. Padian, Megalosaurus. M. Lockley, Megatracksites. K. Padian, Mesozoic Era. H-D. Sues, Mesozoic Faunas. J. Basinger, Mesozoic Floras. R. Hernandez-Rivera, Mexican Dinosaurs. J.A. Schiebout, Microvertebrate Sites. M.J. Ryan, Middle Asian Dinosaurs. G.S. Paul, Migration. R. Barsbold, Mongolian Dinosaurs. K. Carpenter, Morrison Formation. J.M. Parrish, Musculature. J. Le Loeuff, Musee des Dinosaures, Esperaza, Aude, France. The Editors, Museum of Comparative Zoology, Harvard University. D.K. Smith, Museum of Earth Science, Brigham Young University. M. Schweitzer, Museum of the Rockies. D. Chure, Museums and Displays. A. Chinsamy, National Museum, Bloemfontein, South Africa. P. Davis, Natual History Museum, London. H. Osmolska, Nemegt Formation. P. Dodson, Neoceratopsia. The Editors, Neotetanurae. H-D. Sues, Newark Supergroup. K. Padian, Origin of Dinosaurs. L.B. Tatarinov, Orlov Museum of Paleontology. M.K. Vickaryous and M.J. Ryan, Ornamentation. K. Padian, Ornithischia. K. Padian, Ornithodira. H. Osmolska, Ornithomimosauria. The Editors, Ornithopoda. K. Padian, Ornithosuchia. R. Barsbold, Oviraptorosauria. J.B. Smith, Oxford Clay. H-D. Sues, Pachycephalosauria. H. Haubold, Paleoclimatology. P. Dodson, Paleoecology. J.F. Lerbekmo, Paleomagnetic Correlation. E.A. Buchholtz, Paleoneurology. P.J. Currie, Paleontogical Museum, Ulaan Baatar. P. Davis, Paleontology. D.H. Tanke and B.M. Rothschild, Paleopathology. K. Padian, Pectoral Girdle. D. Rasskin-Gutman, Pelvis, Comparative Anatomy. C. Trueman, Permineralization. J.M. Parrish, Petrified Forest. K. Padian, Phylogenetic System. K. Padian, Phylogeny of Dinosaurs. K. Padian, Physiology. B. Tiffney, Plants and Dinosaurs. E. Hoch, Plate Tectonics. T.H. Rich, R.A. Gangloff, and W.R. Hammer, Polar Dinosaurs. H. Osmolska, Polish-Mongolian Paleontological Expeditions. D.F. Glut, Popular Culture, Literature. P. Makovicky, Postcranial Axial Skeleton. B. Britt, Postcranial Pneumaticity. R.E. Molnar, Problems with the Fossil Record. P. Upchurch, Prosauropoda. P. Davis, Pseudofossils. K. Padian, Pseudosuchia. P. Sereno, Psittacosauridae. K. Padian, Pterosauria. K. Padian, Pterosauromopha. M. Lockney, Purgatoire. K. Padian, Quadrupedality. D.A. Eberth, Radiometric Dating. P. Currie, Raptors. S.J. Czerkas, Reconstruction and Restoration. G.S. Paul, Reproductive Behavior and Rates. M.J. Benton, Reptiles. J. Wright, Rocky Hill Dinosaur Park. H-D. Sues, Royal Ontario B.G. Naylor, Royal Tyrrell Museum of Palaeontology. M. Lockley, Samcheonpo. K. Padian, Saurischia. J.S. McIntosh, Sauropoda. P. Upchurch, Sauropodomorpha. P. Currie, Sino-Canadian Dinosaur Project. P. Currie, Sino-Soviet Expeditions. N.J. Mateer, Sino-Swedish Expeditions. E.H. Colbert, Size. R.M. Alexander, Size and Scaling. K. Padian, Skeletal Structures. S.A. Czerkas, Skin. The Editors, Skull, Comparative Anatomy. M.K. Brett-Surman, Smithsonian Institution. H. Haubold, Solnhofen Formation. A. Chinsamy, South African F.E. Novas, South American Dinosaurs. E. Buffetaut, Southeast Asian Dinosaurs. C. Coy, Soviet-Mongolian Paleontological Expeditions. J.D. Archibald, Speciation. J.D. Archibald, Species. A. Milner, Spinosauridae and Baryonychidae. The Editors, State Museum for Natural History, Stuttgart, Germany. K. Padian, Staurikosauridae. P. Galton, Stegosauria. X-C. Wu and A.P. Russell, Systematics. A.R. Fiorillo, Taphonomy. P.M. Sander, Teeth and Jaws. G. Maier, Tendaguru. J.R. Hutchinson and K. Padian, Tetanurae. K. Padian, Thecodontia. D.A. Russell, Therizinosauria. P.J. Currie, Theropoda. K. Carpenter, Thyreophora. A.R. Jacobsen, Tooth Marks. G.M. Erickson, Tooth Replacement Patterns. W.L. Abler, Tooth Serrations in Carnivorous Dinosaurs. A.R. Fiorillo and D.B. Weishampel, Tooth Wear. K. Padian, Trace Fossils. J.M. Parrish, Triassic Period. D.J. Varricchio, Troodontidae. J.O. Farlow, Trophic Groups. D.B. Weishampel, Trossingen. R.R. Rogers, Two Medicine Formation. K. Carpenter, Tyrannosauridae. M. Norell, Ukhaa Tolgod. The Editors, University of California Museum of Paleontology. S.D. Sampson and M.J. Ryan, Variation. M.J. Benton, Vertebrata. P. Davis, Vertebrate Paleontology. G.M. Erickson, Von Ebner Incremental Growth Lines. D. Norman, Wealden Group. J.R. Horner, Willow Creek Anticline. M.A. Turner, Yale Peabody D. Zhiming, Zigong Museum. Resources. Index.

@article{doi105860choice353642,
    title = "Encyclopedia of dinosaurs",
    year = "1998",
    journal = "Choice Reviews Online",
    abstract = "Thematic Table of Contents. Contributors. A Guide to Using the Encyclopedia. Michael Crichton, Foreword. Preface. Dedication. F.E. Novas, Abelisauridae. L.L. Jacobs, African Dinosaurs. G. Erickson, Age Determination. A. Chinsamy, Albany K. Padian and J.R. Hutchinson, Allosauroidea. P. Dodson, American Dinosaurs. L. Dingus, American Museum of Natural History. K. Carpenter, Ankylosauria. J.M. Parrish, Archosauria. J.R. Hutchinson and K. Padain, Arctometatarsalia. R.E. Molnar, Australasian Dinosaurs. L.M. Chiappe, Aves. The Editors, Avetheropoda. K. Padian, Avialae. H. Osmolska, Barun Goyot Formation. J.L. Sanz, Bastus Nesting Site. The Editors, Bavarian State Collection for Paleontology and Historical Geology. P. Currie, Bayan Mandahu. H. Osmolska, Bayn Dzak. J.R. Horner, Behavior. A. Chinsamy, Bernard Price Institute for Paleontological Research. J. Le Loeuff, Biogeography. R.M. Alexander, Biomechanics. R. Chapman, Biometrics. C. Trueman, Biomineralization. S.G. Lucas, Biostratigraphy. K. Padian, Bipedality. K. Padian, Bird Origins. B. Breithaupt, Bone Cabin Quarry. P. Currie, Braincase Anatomy. K. Padain and J.R. Hutchinson, Bullatosauria. M. Lockley, Cabo Espichel. J.S. Moratalla and J.L. Sanz, Cameros Basin Megatracksite. C. Coy, Canadian Dinosaurs. K. Carpenter, Canon City. M. Lockley, Carenque. J.S. McIntosh, Carnegie Museum of Natural History. J.R. Hutchinson and K. Padian, Carnosauria. J. Kirkland, Cedar Mountain Formation. M. Norell, Central Asiatic Expeditions. The Editors, Cerapoda. P. Dodson, Ceratopsia. T. Rowe, R. Tykoski, and J.R. Hutchinson, Ceratosauria. H. Bocherens, Chemical Composition of Dinosaur Fossils. D. Zhiming, Chinese Dinosaurs. J.M. Parrish, Chinle Formation. J.B. Smith, Cleveland-Lloyd Dinosaur Quarry. D. Maxwell, Cloverly Formation. J.R. Hutchinson and K. Padian, Coelurosauria. M.J. Ryan and A.P. Russell, Color. B. Breithaupt, Como Bluff. R.E. Chapman and D.B. Weishampel, Computers and Related Technology. J. Wright, Connecticut River Valley. D.B. Weishampel, Constructional Morphology. K. Chin, Coprolites. L.M. Witmer, Craniofacial Air Sinus Systems. E-B. Koppelhus, Cretaceous Period. J.M. Clark, Crocodylia. W.A.S. Sarjeant, Crystal Palace Dinosaurs. B. Britt and K.L. Stadtman, Dalton Wells Quarry. A. Sahni, Deccan Basalt. The Editors, Deinonychosauria. K. Carpenter, Denver Museum of Natural History. C. Coy, Devil's Coulee Dinosaur Egg Historic Site. M.J. Ryan and M.K. Vickaryous, Diet. K. Padian, Dinosauria: Definition. D. Chure, Dinosaur National Monument. A.B. Arcucci, Dinosauromorpha. C. Coy, Dinosaur Provincial Park. M. Lockley, Dinosaur Ridge. Don Lesson, Dinosaur Society. M. Lockley, Dinosaur Valley. M. Lockley, Dinoturbation. P. Dodson, Distribution and Diversity. T. Jerzykiewicz, Djadokhta Formation. P.A. Murry and R.A. Long, Dockum Group. P. Currie, Dromaeosaridae. B. Britt and B.I. Curtice, Dry Mesa Quarry. M.J. Ryan, Dryosauridae. D.A. Eberth, Edmonton Group. J.R. Horner, Egg Mountain. K.E. Mikhailov, Eggs, Eggshells, and Nests. P. Currie, Elmisauridae. The Editors, Enantiornithes. P. Currie, Erenhot Dinosaur The Editors, Euornithopoda. E. Buffetaut, European Dinosaurs. J.D. Archibald, Evolution. J.D. Archibald, Extinction, Cretaceous. M.J. Benton, Extinction, Triassic. P. Guangzhao, Fabrosauridae. M. Lockley, Fatima. P. Currie, Feathered Dinosaurs. M. Lockley, Footprints and Trackways. Per Christiansen, Forelimbs and Hands. J.I. Kirkland, Fruita Paleontological Area. M.J. Ryan, Fruitland Formation. X-C. Wu, Functional Morphology. L. Claessens, Gastralia. D.D. Gillette, Gastroliths. The Editors, Genasauria. J.M. Parrish, Genetics. C.C. Swisher, Geologic Time. C. Coy, Ghost Ranch. K. Padian, Glen Canyon Group. D.A. Winkler, Glen Rose, Texas. P. Currie, Graduate Studies. D.J. Varricchio, Growth and Embryology. K. Padian, Growth Lines. C.A. Forster, Hadrosauridae. K.R. Johnson, Hell Creek Flora. D.F. Lofgren, Hell Creek Formation. F.E. Novas, Herrerasauridae. J.A. Long and K.J. McNamara, Heterochrony. J.B. Smith, Heterodontosauridae. Per Christiansen, Hind Limbs and Feet. R.E.H. Reid, Histology of Bones and Teeth. W.A.S. Sarjeant, History of Dinosaur Discoveries: Early Discoveries. B. Breithaupt, History of Dinosaur Discoveries: First Golden Period. E. Buffetaut, History of Dinosaur Discoveries: Quiet Times. L. Psihoyos, History of Dinosaur Discoveries: Research Today. B. Breithaupt, Howe Quarry. H-D. Sues, Hypsilophodontidae. C.A. Forster, Iguanodontidae. A. Sahni, Indian Dinosaurs. The Editors, Institute de Paleontologie, Museum National d'Histoire Naturelle, Paris, France. D. Zhiming, Institute of Vertebrate Paleontology and Paleoanthropology, Beijing, China. D.A. Russell, Intelligence. R.R. Rogers, Ischigualasto Formation. Y. Azuma and Y. Tamida, Japanese Dinosaurs. D.A. Eberth, Judith River Wedge. D. Lessem and M. Schweitzer, Jurassic Park. P. Dodson, Jurassic Period. H. Haubold, Keuper Formation. M. Lockley, Khodja-Pil-Ata. M.J. Ryan, Kirtland Formation. A. Sahni, Lameta Formation. B. Breithaupt, Lance Formation. S.G. Lucas, Land-Mammal Ages. B.P. Perez-Moreno and J.L. Sanz, Las Hoyas. V.L. Santucci, Legislation Protecting Dinosaur Fossils. D.B. Weishampel, Life History. M. Lockley, Lommiswil. E. Frey and J. Martin, Long Necks of Sauropods. D. Zhiming, Lufeng. K. Padian, Maniraptora. K. Padian, Maniraptoriformes. The Editors, Marginocephalia. K. Padian, Megalosaurus. M. Lockley, Megatracksites. K. Padian, Mesozoic Era. H-D. Sues, Mesozoic Faunas. J. Basinger, Mesozoic Floras. R. Hernandez-Rivera, Mexican Dinosaurs. J.A. Schiebout, Microvertebrate Sites. M.J. Ryan, Middle Asian Dinosaurs. G.S. Paul, Migration. R. Barsbold, Mongolian Dinosaurs. K. Carpenter, Morrison Formation. J.M. Parrish, Musculature. J. Le Loeuff, Musee des Dinosaures, Esperaza, Aude, France. The Editors, Museum of Comparative Zoology, Harvard University. D.K. Smith, Museum of Earth Science, Brigham Young University. M. Schweitzer, Museum of the Rockies. D. Chure, Museums and Displays. A. Chinsamy, National Museum, Bloemfontein, South Africa. P. Davis, Natual History Museum, London. H. Osmolska, Nemegt Formation. P. Dodson, Neoceratopsia. The Editors, Neotetanurae. H-D. Sues, Newark Supergroup. K. Padian, Origin of Dinosaurs. L.B. Tatarinov, Orlov Museum of Paleontology. M.K. Vickaryous and M.J. Ryan, Ornamentation. K. Padian, Ornithischia. K. Padian, Ornithodira. H. Osmolska, Ornithomimosauria. The Editors, Ornithopoda. K. Padian, Ornithosuchia. R. Barsbold, Oviraptorosauria. J.B. Smith, Oxford Clay. H-D. Sues, Pachycephalosauria. H. Haubold, Paleoclimatology. P. Dodson, Paleoecology. J.F. Lerbekmo, Paleomagnetic Correlation. E.A. Buchholtz, Paleoneurology. P.J. Currie, Paleontogical Museum, Ulaan Baatar. P. Davis, Paleontology. D.H. Tanke and B.M. Rothschild, Paleopathology. K. Padian, Pectoral Girdle. D. Rasskin-Gutman, Pelvis, Comparative Anatomy. C. Trueman, Permineralization. J.M. Parrish, Petrified Forest. K. Padian, Phylogenetic System. K. Padian, Phylogeny of Dinosaurs. K. Padian, Physiology. B. Tiffney, Plants and Dinosaurs. E. Hoch, Plate Tectonics. T.H. Rich, R.A. Gangloff, and W.R. Hammer, Polar Dinosaurs. H. Osmolska, Polish-Mongolian Paleontological Expeditions. D.F. Glut, Popular Culture, Literature. P. Makovicky, Postcranial Axial Skeleton. B. Britt, Postcranial Pneumaticity. R.E. Molnar, Problems with the Fossil Record. P. Upchurch, Prosauropoda. P. Davis, Pseudofossils. K. Padian, Pseudosuchia. P. Sereno, Psittacosauridae. K. Padian, Pterosauria. K. Padian, Pterosauromopha. M. Lockney, Purgatoire. K. Padian, Quadrupedality. D.A. Eberth, Radiometric Dating. P. Currie, Raptors. S.J. Czerkas, Reconstruction and Restoration. G.S. Paul, Reproductive Behavior and Rates. M.J. Benton, Reptiles. J. Wright, Rocky Hill Dinosaur Park. H-D. Sues, Royal Ontario B.G. Naylor, Royal Tyrrell Museum of Palaeontology. M. Lockley, Samcheonpo. K. Padian, Saurischia. J.S. McIntosh, Sauropoda. P. Upchurch, Sauropodomorpha. P. Currie, Sino-Canadian Dinosaur Project. P. Currie, Sino-Soviet Expeditions. N.J. Mateer, Sino-Swedish Expeditions. E.H. Colbert, Size. R.M. Alexander, Size and Scaling. K. Padian, Skeletal Structures. S.A. Czerkas, Skin. The Editors, Skull, Comparative Anatomy. M.K. Brett-Surman, Smithsonian Institution. H. Haubold, Solnhofen Formation. A. Chinsamy, South African F.E. Novas, South American Dinosaurs. E. Buffetaut, Southeast Asian Dinosaurs. C. Coy, Soviet-Mongolian Paleontological Expeditions. J.D. Archibald, Speciation. J.D. Archibald, Species. A. Milner, Spinosauridae and Baryonychidae. The Editors, State Museum for Natural History, Stuttgart, Germany. K. Padian, Staurikosauridae. P. Galton, Stegosauria. X-C. Wu and A.P. Russell, Systematics. A.R. Fiorillo, Taphonomy. P.M. Sander, Teeth and Jaws. G. Maier, Tendaguru. J.R. Hutchinson and K. Padian, Tetanurae. K. Padian, Thecodontia. D.A. Russell, Therizinosauria. P.J. Currie, Theropoda. K. Carpenter, Thyreophora. A.R. Jacobsen, Tooth Marks. G.M. Erickson, Tooth Replacement Patterns. W.L. Abler, Tooth Serrations in Carnivorous Dinosaurs. A.R. Fiorillo and D.B. Weishampel, Tooth Wear. K. Padian, Trace Fossils. J.M. Parrish, Triassic Period. D.J. Varricchio, Troodontidae. J.O. Farlow, Trophic Groups. D.B. Weishampel, Trossingen. R.R. Rogers, Two Medicine Formation. K. Carpenter, Tyrannosauridae. M. Norell, Ukhaa Tolgod. The Editors, University of California Museum of Paleontology. S.D. Sampson and M.J. Ryan, Variation. M.J. Benton, Vertebrata. P. Davis, Vertebrate Paleontology. G.M. Erickson, Von Ebner Incremental Growth Lines. D. Norman, Wealden Group. J.R. Horner, Willow Creek Anticline. M.A. Turner, Yale Peabody D. Zhiming, Zigong Museum. Resources. Index.",
    url = "https://doi.org/10.5860/choice.35-3642",
    doi = "10.5860/choice.35-3642",
    openalex = "W647458292"
}

This interdisciplinary book interprets early human evolution in the context of the local ecology and specific habitats. It assesses carefully the possible role of climate change in driving early human evolution. Bringing an ecological and biogeographic perspective to recent fossil finds, the book provides a new synthesis of ideas on hominid evolution. It will be a valuable resource for researchers in physical, biological, or paleoanthropology, evolutionary biology or biogeography.

@book{crossref1999african,
    title = "African Biogeography, Climate Change, \& Human Evolution",
    year = "1999",
    abstract = "This interdisciplinary book interprets early human evolution in the context of the local ecology and specific habitats. It assesses carefully the possible role of climate change in driving early human evolution. Bringing an ecological and biogeographic perspective to recent fossil finds, the book provides a new synthesis of ideas on hominid evolution. It will be a valuable resource for researchers in physical, biological, or paleoanthropology, evolutionary biology or biogeography.",
    url = "https://doi.org/10.1093/oso/9780195114379.001.0001",
    doi = "10.1093/oso/9780195114379.001.0001",
    openalex = "W4388335255"
}

Since the publication of Darwin (1859), the biological meaning of the Cambrian radiation has been debated. Most commentators agree, however, that the Cambrian radiation is fundamentally a time of major metazoan cladogenesis. In and of itself this does not necessarily mean that unique evolutionary processes operated during the Cambrian radiation. Phylogenetic analysis has been used to study the tempo of speciation during the radiation, and thus far there is no need to invoke special rules relating to the tempo of evolution. Instead, what seems unique about the Cambrian radiation is its place as an important episode in the history of life—that is, as the first major radiation of the Metazoa. Although the tempo of evolution during the Cambrian radiation may not have been uniquely high, there were largely unique tectonic events that transpired during the late Neoproterozoic and Early Cambrian, such as extensive cratonic fragmentation. Biogeographic analysis of Early Cambrian olenelloid trilobites reveals that these tectonic events powerfully influenced evolutionary and distributional patterns in this diverse and abundant trilobite group. This emphasizes the importance of physical earth history in generating evolutionary patterns. In the general study of macroevolutionary patterns and processes, earth history phenomena emerge as powerful forces influencing the history of life and provide insights into evolution that can best be inferred by paleontological data.

@article{doi101017s0022336000027700,
    author = "Lieberman, B.",
    title = "Testing the Darwinian legacy of the Cambrian radiation using trilobite phylogeny and biogeography",
    year = "1999",
    journal = "Journal of Paleontology",
    abstract = "Since the publication of Darwin (1859), the biological meaning of the Cambrian radiation has been debated. Most commentators agree, however, that the Cambrian radiation is fundamentally a time of major metazoan cladogenesis. In and of itself this does not necessarily mean that unique evolutionary processes operated during the Cambrian radiation. Phylogenetic analysis has been used to study the tempo of speciation during the radiation, and thus far there is no need to invoke special rules relating to the tempo of evolution. Instead, what seems unique about the Cambrian radiation is its place as an important episode in the history of life—that is, as the first major radiation of the Metazoa. Although the tempo of evolution during the Cambrian radiation may not have been uniquely high, there were largely unique tectonic events that transpired during the late Neoproterozoic and Early Cambrian, such as extensive cratonic fragmentation. Biogeographic analysis of Early Cambrian olenelloid trilobites reveals that these tectonic events powerfully influenced evolutionary and distributional patterns in this diverse and abundant trilobite group. This emphasizes the importance of physical earth history in generating evolutionary patterns. In the general study of macroevolutionary patterns and processes, earth history phenomena emerge as powerful forces influencing the history of life and provide insights into evolution that can best be inferred by paleontological data.",
    url = "https://www.semanticscholar.org/paper/8ceb1444407c52f3fcf4391995c4e95012cd7bdd",
    doi = "10.1017/S0022336000027700",
    is_oa = "true",
    number = "2",
    pages = "176-181",
    semanticscholar_citation_count = "32",
    semanticscholar_id = "8ceb1444407c52f3fcf4391995c4e95012cd7bdd",
    volume = "73"
}

@article{doi101038sjhdy6885841,
    author = "Gillespie, Rosemary G.",
    title = "Island Biogeography — Ecology, Evolution and Conservation",
    year = "1999",
    journal = "Heredity",
    url = "https://doi.org/10.1038/sj.hdy.6885841",
    doi = "10.1038/sj.hdy.6885841",
    openalex = "W1503840956",
    references = "doi1023072419593"
}

PART I. THEORY PART II. GEOLOGY, ECOLOGY, AND BIOGEOGRAPHY PART III. FOSSIL FAUNAS PART IV. HOMINID EVOLUTION

@book{openalexw655043828,
    author = "Bromage, Timothy G. and Schrenk, Friedemann",
    title = "African biogeography, climate change, \& human evolution",
    year = "1999",
    booktitle = "Oxford University Press eBooks",
    abstract = "PART I. THEORY PART II. GEOLOGY, ECOLOGY, AND BIOGEOGRAPHY PART III. FOSSIL FAUNAS PART IV. HOMINID EVOLUTION",
    openalex = "W655043828"
}

@article{doi101006icar20006570,
    author = "Bullock, M. A.",
    title = "The Recent Evolution of Climate on Venus",
    year = "2001",
    journal = "Icarus",
    url = "https://doi.org/10.1006/icar.2000.6570",
    doi = "10.1006/icar.2000.6570",
    openalex = "W2119946162"
}

Climate‐interior coupled evolution is investigated for Venus by merging a partial‐melting/parameterized mantle convection model with a gray radiative‐convective atmospheric model. A positive feedback process can operate by the release of water to the atmosphere via mantle melting, leading to an increase in atmospheric opacity and the radiative temperature gradient. The resulting amplification of the greenhouse surface temperature raises the mantle temperature leading to an increase in the partial‐melting rate. Using thin‐lid convection, a coupled model for Venus running over an interval of 3 to 1 Ga shows a significant increase in surface temperature, partial‐melting extent, and extrusive magma flux compared to a model where there is no communication between greenhouse‐modulated surface temperature and partial‐melting in the interior. Coupled and uncoupled models that transition (with variable timing) to stagnant‐lid convection either shut down partial melting via lithospheric thickening, or evolve to large amounts of melt due to increased interior temperatures.

@article{phillips2001climate,
    author = "Phillips, Roger J. and Bullock, Mark A. and Hauck, Steven A.",
    title = "Climate and interior coupled evolution on Venus",
    year = "2001",
    journal = "Geophysical Research Letters",
    abstract = "Climate‐interior coupled evolution is investigated for Venus by merging a partial‐melting/parameterized mantle convection model with a gray radiative‐convective atmospheric model. A positive feedback process can operate by the release of water to the atmosphere via mantle melting, leading to an increase in atmospheric opacity and the radiative temperature gradient. The resulting amplification of the greenhouse surface temperature raises the mantle temperature leading to an increase in the partial‐melting rate. Using thin‐lid convection, a coupled model for Venus running over an interval of 3 to 1 Ga shows a significant increase in surface temperature, partial‐melting extent, and extrusive magma flux compared to a model where there is no communication between greenhouse‐modulated surface temperature and partial‐melting in the interior. Coupled and uncoupled models that transition (with variable timing) to stagnant‐lid convection either shut down partial melting via lithospheric thickening, or evolve to large amounts of melt due to increased interior temperatures.",
    url = "https://doi.org/10.1029/2000gl011821",
    doi = "10.1029/2000gl011821",
    number = "9",
    openalex = "W1972170877",
    pages = "1779-1782",
    volume = "28",
    references = "doi101006icar19931055, doi101006icar20006570, doi1010160019103583902415, doi1010160377027384900398, doi10102995je03361, doi10102995je03567, doi101029ja085ia13p07891, doi1010631868465, doi101093petrology253713, doi101093petrology293625"
}

Wilson, Jeffrey A. (2002): Sauropod dinosaur phylogeny: critique and cladistic analysis. Zoological Journal of the Linnean Society 136 (2): 217-276, DOI: 10.1046/j.1096-3642.2002.00029.x, URL: https://academic.oup.com/zoolinnean/article-lookup/doi/10.1046/j.1096-3642.2002.00029.x

@article{doi101046j10963642200200029x,
    author = "Wilson, Jeffrey A.",
    title = "Sauropod dinosaur phylogeny: critique and cladistic analysis",
    year = "2002",
    journal = "Zoological Journal of the Linnean Society",
    abstract = "Wilson, Jeffrey A. (2002): Sauropod dinosaur phylogeny: critique and cladistic analysis. Zoological Journal of the Linnean Society 136 (2): 217-276, DOI: 10.1046/j.1096-3642.2002.00029.x, URL: https://academic.oup.com/zoolinnean/article-lookup/doi/10.1046/j.1096-3642.2002.00029.x",
    url = "https://doi.org/10.1046/j.1096-3642.2002.00029.x",
    doi = "10.1046/j.1096-3642.2002.00029.x",
    openalex = "W2018305891",
    references = "doi101002mmng19994860020102, doi101007978140206754912413, doi101017s0094837300026543, doi10108002724634199410011523, doi10108002724634199410011524, doi10108002724634199510011575, doi10108002724634199810011115, doi101098rstb19950125, doi101111j109636421998tb00569x, doi101111j155856461983tb05533x, doi101126science28053661048, doi101126science28454232137, doi101242dev1212333, doi1023071292217, doi1023072408332, doi1023072992353, doi102475ajss319111253, doi102475ajss321125417, doi102475ajss32313381, doi105281zenodo16171435, doi107312crac92306005, openalexw1025856234, openalexw3114518543, ostrom2019osteology"
}

The family Scaridae comprises about 90 species of herbivorous coral reef, rock reef, and seagrass fishes. Parrotfishes are important agents of marine bioerosion who rework the substrate with their beaklike oral jaws. Many scarid populations are characterized by complex social systems including highly differentiated sexual stages, territoriality, and the defense of harems. Here, we test a hypothesis of relationships among parrotfish genera derived from nearly 2 kb of nuclear and mitochondrial DNA sequence. The DNA tree is different than a phylogeny based on comparative morphology and leads to important reinterpretations of scarid evolution. The molecular data suggest a split among seagrass and coral reef associated genera with nearly 80% of all species in the coral reef clade. Our phylogenetic results imply an East Tethyan origin of the family and the recurrent evolution of excavating and scraping feeding modes. It is likely that ecomorphological differences played a significant role in the initial divergence of major scarid lineages, but that variation in color and breeding behavior has triggered subsequent diversification. We present a two-phase model of parrotfish evolution to explain patterns of comparative diversity. Finally, we discuss the application of this model to other adaptively radiating clades.

@article{doi101111j001438202002tb01408x,
    author = "Streelman, J. Todd and Alfaro, Michael E. and Westneat, Mark W. and Bellwood, David R. and Karl, Stephen A.",
    title = "EVOLUTIONARY HISTORY OF THE PARROTFISHES: BIOGEOGRAPHY, ECOMORPHOLOGY, AND COMPARATIVE DIVERSITY",
    year = "2002",
    journal = "Evolution",
    abstract = "The family Scaridae comprises about 90 species of herbivorous coral reef, rock reef, and seagrass fishes. Parrotfishes are important agents of marine bioerosion who rework the substrate with their beaklike oral jaws. Many scarid populations are characterized by complex social systems including highly differentiated sexual stages, territoriality, and the defense of harems. Here, we test a hypothesis of relationships among parrotfish genera derived from nearly 2 kb of nuclear and mitochondrial DNA sequence. The DNA tree is different than a phylogeny based on comparative morphology and leads to important reinterpretations of scarid evolution. The molecular data suggest a split among seagrass and coral reef associated genera with nearly 80\% of all species in the coral reef clade. Our phylogenetic results imply an East Tethyan origin of the family and the recurrent evolution of excavating and scraping feeding modes. It is likely that ecomorphological differences played a significant role in the initial divergence of major scarid lineages, but that variation in color and breeding behavior has triggered subsequent diversification. We present a two-phase model of parrotfish evolution to explain patterns of comparative diversity. Finally, we discuss the application of this model to other adaptively radiating clades.",
    url = "https://doi.org/10.1111/j.0014-3820.2002.tb01408.x",
    doi = "10.1111/j.0014-3820.2002.tb01408.x",
    openalex = "W2108491494",
    references = "doi101111j155856461999tb03769x"
}

As stated by the island rule, small mammals evolve toward gigantism on islands. In addition they are known to evolve faster than their mainland counterparts. Body size in island mammals may also be influenced by geographical climatic gradients or climatic change through time. We tested the relative effects of climate change and isolation on the size of the Japanese rodent Apodemus speciosus and calculated evolutionary rates of body size change since the last glacial maximum (LGM). Currently A. speciosus populations conform both to Bergmann's rule, with an increase in body size with latitude, and to the island rule, with larger body sizes on small islands. We also found that fossil representatives of A. speciosus are larger than their extant relatives. Our estimated evolutionary rates since the LGM show that body size evolution on the smaller islands has been less than half as rapid as on Honshu, the mainland-type large island of Japan. We conclude that island populations exhibit larger body sizes today not because they have evolved toward gigantism, but because their evolution toward a smaller size, due to climate warming since the LGM, has been decelerated by the island effect. These combined results suggest that evolution in Quaternary island small mammals may not have been as fast as expected by the island effect because of the counteracting effect of climate change during this period.

@article{doi101111j001438202004tb01713x,
    author = "Millien, Virginie and Damuth, John",
    title = "CLIMATE CHANGE AND SIZE EVOLUTION IN AN ISLAND RODENT SPECIES: NEW PERSPECTIVES ON THE ISLAND RULE",
    year = "2004",
    journal = "Evolution",
    abstract = "As stated by the island rule, small mammals evolve toward gigantism on islands. In addition they are known to evolve faster than their mainland counterparts. Body size in island mammals may also be influenced by geographical climatic gradients or climatic change through time. We tested the relative effects of climate change and isolation on the size of the Japanese rodent Apodemus speciosus and calculated evolutionary rates of body size change since the last glacial maximum (LGM). Currently A. speciosus populations conform both to Bergmann's rule, with an increase in body size with latitude, and to the island rule, with larger body sizes on small islands. We also found that fossil representatives of A. speciosus are larger than their extant relatives. Our estimated evolutionary rates since the LGM show that body size evolution on the smaller islands has been less than half as rapid as on Honshu, the mainland-type large island of Japan. We conclude that island populations exhibit larger body sizes today not because they have evolved toward gigantism, but because their evolution toward a smaller size, due to climate warming since the LGM, has been decelerated by the island effect. These combined results suggest that evolution in Quaternary island small mammals may not have been as fast as expected by the island effect because of the counteracting effect of climate change during this period.",
    url = "https://doi.org/10.1111/j.0014-3820.2004.tb01713.x",
    doi = "10.1111/j.0014-3820.2004.tb01713.x",
    openalex = "W2179816938",
    references = "doi101038202234a0, doi101038365748a0"
}

Family level molecular phylogenetic analyses of cichlid fishes have generally suffered from a limited number of characters and/or poor taxonomic sampling across one or more major geographic assemblage, and therefore have not provided a robust test of early intrafamilial diversification. Herein we use both nuclear and mitochondrial nucleotide characters and direct optimization to reconstruct a phylogeny for cichlid fishes. Representatives of major cichlid lineages across all geographic assemblages are included, as well as nearly twice the number of characters as any prior family-level study. In a strict consensus of 81 equally most-parsimonious hypotheses, based on the simultaneous analysis of 2222 aligned nucleotide characters from two mitochondrial and two nuclear genes, four major subfamilial lineages are recovered with strong support. Etroplinae, endemic to Madagascar (Paretroplus) and southern Asia (Etroplus), is recovered as the sister taxon to the remainder of Cichlidae. Although the South Asian cichlids are monophyletic, the Malagasy plus South Asian lineages are not. The remaining Malagasy lineage, Ptychochrominae, is monophyletic and is recovered as the sister group to a clade comprising the African and Neotropical cichlids. The African (Pseudocrenilabrinae) and Neotropical (Cichlinae) lineages are each monophyletic in this reconstruction. The use of multiple molecular markers, from both mitochondrial and nuclear genes, results in a phylogeny that in general exhibits strong support, notably for early diversification events within Cichlidae. Results further indicate that Labroidei is not monophyletic, and that the sister group to Cichlidae may comprise a large and diverse assemblage of percomorph lineages. This hypothesis may at least partly explain why morphological studies that have attempted to place Cichlidae within Percomorpha, or that have tested cichlid monophyly using only "labroid" lineages, have met with only limited success.

@article{doi101111j10960031200400038x,
    author = "Sparks, John S. and Smith, W. Leo",
    title = "Phylogeny and biogeography of cichlid fishes (Teleostei: Perciformes: Cichlidae)",
    year = "2004",
    journal = "Cladistics",
    abstract = {Family level molecular phylogenetic analyses of cichlid fishes have generally suffered from a limited number of characters and/or poor taxonomic sampling across one or more major geographic assemblage, and therefore have not provided a robust test of early intrafamilial diversification. Herein we use both nuclear and mitochondrial nucleotide characters and direct optimization to reconstruct a phylogeny for cichlid fishes. Representatives of major cichlid lineages across all geographic assemblages are included, as well as nearly twice the number of characters as any prior family-level study. In a strict consensus of 81 equally most-parsimonious hypotheses, based on the simultaneous analysis of 2222 aligned nucleotide characters from two mitochondrial and two nuclear genes, four major subfamilial lineages are recovered with strong support. Etroplinae, endemic to Madagascar (Paretroplus) and southern Asia (Etroplus), is recovered as the sister taxon to the remainder of Cichlidae. Although the South Asian cichlids are monophyletic, the Malagasy plus South Asian lineages are not. The remaining Malagasy lineage, Ptychochrominae, is monophyletic and is recovered as the sister group to a clade comprising the African and Neotropical cichlids. The African (Pseudocrenilabrinae) and Neotropical (Cichlinae) lineages are each monophyletic in this reconstruction. The use of multiple molecular markers, from both mitochondrial and nuclear genes, results in a phylogeny that in general exhibits strong support, notably for early diversification events within Cichlidae. Results further indicate that Labroidei is not monophyletic, and that the sister group to Cichlidae may comprise a large and diverse assemblage of percomorph lineages. This hypothesis may at least partly explain why morphological studies that have attempted to place Cichlidae within Percomorpha, or that have tested cichlid monophyly using only "labroid" lineages, have met with only limited success.},
    url = "https://doi.org/10.1111/j.1096-0031.2004.00038.x",
    doi = "10.1111/j.1096-0031.2004.00038.x",
    openalex = "W2052307054",
    references = "doi101071bt00025"
}

Taxa have been dated using three methods: equating their age with the age of the oldest known fossil, with the age of strata the taxa are endemic to, and with the age of paleogeographic events. All three methods have been adopted as methods of dating nodes in molecular phylogenies. The first method has been the most popular, but both this and the second method involve serious difficulties. Studies often, correctly, introduce oldest known fossils as providing minimum ages for divergences. However, in the actual analyses these ages, and ages derived from them, are often treated as absolute ages and earlier geological events are deemed irrelevant to the phylogeny. In fact, only younger geological events can be irrelevant. Studies correlating the age of nodes with age of volcanic islands often overlook the fact that these islands have been produced at subduction zones or hot spots where small, individually ephemeral islands are constantly being produced and disappearing, and a metapopulation can survive indefinitely. Correlating the age of taxa with that of associated paleogeographic events is probably the most promising method but has often been used in a simplistic way, for example in assuming that all divergence across the Isthmus of Panama dates to its final rise. Most workers now agree that a global molecular clock does not exist, and that rates can change between lineages and within a lineage over time. New methods of estimating branch lengths do not assume a strict clock, but the number of models for molecular evolution is then effectively infinite. Problems with calibrating the nodes, as well as with substitution models, mean that phylogeography's claim to be able to test between vicariance and dispersal is not justified.

@article{doi101111j10960031200500052x,
    author = "Heads, Michael",
    title = "Dating nodes on molecular phylogenies: a critique of molecular biogeography",
    year = "2005",
    journal = "Cladistics",
    abstract = "Taxa have been dated using three methods: equating their age with the age of the oldest known fossil, with the age of strata the taxa are endemic to, and with the age of paleogeographic events. All three methods have been adopted as methods of dating nodes in molecular phylogenies. The first method has been the most popular, but both this and the second method involve serious difficulties. Studies often, correctly, introduce oldest known fossils as providing minimum ages for divergences. However, in the actual analyses these ages, and ages derived from them, are often treated as absolute ages and earlier geological events are deemed irrelevant to the phylogeny. In fact, only younger geological events can be irrelevant. Studies correlating the age of nodes with age of volcanic islands often overlook the fact that these islands have been produced at subduction zones or hot spots where small, individually ephemeral islands are constantly being produced and disappearing, and a metapopulation can survive indefinitely. Correlating the age of taxa with that of associated paleogeographic events is probably the most promising method but has often been used in a simplistic way, for example in assuming that all divergence across the Isthmus of Panama dates to its final rise. Most workers now agree that a global molecular clock does not exist, and that rates can change between lineages and within a lineage over time. New methods of estimating branch lengths do not assume a strict clock, but the number of models for molecular evolution is then effectively infinite. Problems with calibrating the nodes, as well as with substitution models, mean that phylogeography's claim to be able to test between vicariance and dispersal is not justified.",
    url = "https://doi.org/10.1111/j.1096-0031.2005.00052.x",
    doi = "10.1111/j.1096-0031.2005.00052.x",
    openalex = "W2124060421",
    references = "doi101071bt00025, doi1023072412140"
}

Abstract Aim Phylogenies are increasingly being used to attempt to answer biogeographical questions. However, a reliance on tree topology alone has emerged without consideration of earth processes or the biology of the organisms in question. Most ancestral‐state optimization methods have inherent problems, including failure to take account of asymmetry, such as unequal probabilities of losses and gains, and the lack of use of independent cost estimates. Here we discuss what we perceive as shortcomings in most current tree‐based biogeography interpretation methods and show that consideration of processes and their likelihoods can turn the conventional biogeographical interpretation on its head. Location Southern hemisphere focus but applicable world‐wide. Methods The logic of existing methods is reviewed with respect to their adequacy in modelling processes such as geographical mode of speciation and likelihood of dispersal, including directional bias. Published reconstructions of dispersal of three plant taxa between Australia and New Zealand were re‐analysed using standard parsimony and maximum likelihood (ML) methods with rate matrices to model expected asymmetry of dispersal. Results Few studies to date incorporate asymmetric dispersal rate matrices or question the simplistic assumption of equal costs. Even when they do, cost matrices typically are not derived independently of tree topology. Asymmetrical dispersal between Australia and New Zealand could be reconstructed using parsimony but not with ML. Main conclusions The inadequacy of current models has important consequences for our interpretation of southern hemisphere biogeography, particularly in relation to dispersal. For example, if repeated directional dispersals and colonization in the direction of prevailing winds have occurred, with intervening periods of speciation, then there is no need to infer dispersals against those winds. Failure to take account of directionality and other biases in reconstruction methods has implications beyond the simple misinterpretation of the biogeography of a taxonomic group, such as calibration of molecular clocks, the dating of vicariance events, and the prioritization of areas for conservation.

@article{doi101111j13652699200501261x,
    author = "Cook, Lyn G. and Crisp, Michael D.",
    title = "Directional asymmetry of long‐distance dispersal and colonization could mislead reconstructions of biogeography",
    year = "2005",
    journal = "Journal of Biogeography",
    abstract = "Abstract Aim Phylogenies are increasingly being used to attempt to answer biogeographical questions. However, a reliance on tree topology alone has emerged without consideration of earth processes or the biology of the organisms in question. Most ancestral‐state optimization methods have inherent problems, including failure to take account of asymmetry, such as unequal probabilities of losses and gains, and the lack of use of independent cost estimates. Here we discuss what we perceive as shortcomings in most current tree‐based biogeography interpretation methods and show that consideration of processes and their likelihoods can turn the conventional biogeographical interpretation on its head. Location Southern hemisphere focus but applicable world‐wide. Methods The logic of existing methods is reviewed with respect to their adequacy in modelling processes such as geographical mode of speciation and likelihood of dispersal, including directional bias. Published reconstructions of dispersal of three plant taxa between Australia and New Zealand were re‐analysed using standard parsimony and maximum likelihood (ML) methods with rate matrices to model expected asymmetry of dispersal. Results Few studies to date incorporate asymmetric dispersal rate matrices or question the simplistic assumption of equal costs. Even when they do, cost matrices typically are not derived independently of tree topology. Asymmetrical dispersal between Australia and New Zealand could be reconstructed using parsimony but not with ML. Main conclusions The inadequacy of current models has important consequences for our interpretation of southern hemisphere biogeography, particularly in relation to dispersal. For example, if repeated directional dispersals and colonization in the direction of prevailing winds have occurred, with intervening periods of speciation, then there is no need to infer dispersals against those winds. Failure to take account of directionality and other biases in reconstruction methods has implications beyond the simple misinterpretation of the biogeography of a taxonomic group, such as calibration of molecular clocks, the dating of vicariance events, and the prioritization of areas for conservation.",
    url = "https://doi.org/10.1111/j.1365-2699.2005.01261.x",
    doi = "10.1111/j.1365-2699.2005.01261.x",
    openalex = "W2149566376",
    references = "doi101071bt00025"
}

Silicified plant tissues (phytoliths) preserved in Late Cretaceous coprolites from India show that at least five taxa from extant grass (Poaceae) subclades were present on the Indian subcontinent during the latest Cretaceous. This taxonomic diversity suggests that crown-group Poaceae had diversified and spread in Gondwana before India became geographically isolated. Other phytoliths extracted from the coprolites (from dicotyledons, conifers, and palms) suggest that the suspected dung producers (titanosaur sauropods) fed indiscriminately on a wide range of plants. These data also make plausible the hypothesis that gondwanatherian mammals with hypsodont cheek teeth were grazers.

@article{doi101126science1118806,
    author = "Prasad, Vandana and Strömberg, Caroline A. E. and Alimohammadian, Habib and Sahni, Ashok",
    title = "Dinosaur Coprolites and the Early Evolution of Grasses and Grazers",
    year = "2005",
    journal = "Science",
    abstract = "Silicified plant tissues (phytoliths) preserved in Late Cretaceous coprolites from India show that at least five taxa from extant grass (Poaceae) subclades were present on the Indian subcontinent during the latest Cretaceous. This taxonomic diversity suggests that crown-group Poaceae had diversified and spread in Gondwana before India became geographically isolated. Other phytoliths extracted from the coprolites (from dicotyledons, conifers, and palms) suggest that the suspected dung producers (titanosaur sauropods) fed indiscriminately on a wide range of plants. These data also make plausible the hypothesis that gondwanatherian mammals with hypsodont cheek teeth were grazers.",
    url = "https://doi.org/10.1126/science.1118806",
    doi = "10.1126/science.1118806",
    openalex = "W2157319590",
    references = "doi101016jpalaeo200309028, doi101017s1464793101005735, doi101038333843a0, doi101071bt00023, doi101073pnas0505700102, doi101111j10958339200400345x, doi101130spe332, doi1023072398811, doi1023072666186, doi1023073298585, doi1023073889325"
}

Abstract Vicariance biogeography emerged several decades ago from the fusion of cladistics and plate tectonics, and quickly came to dominate historical biogeography. The field has since been largely constrained by the notion that only processes of vicariance and not dispersal offer testable patterns and refutable hypotheses, dispersal being a random process essentially adding only noise to a vicariant system. A consequence of this thinking seems to have been a focus on the biogeography of continents and continental islands, considering the biogeography of oceanic islands less worthy of scientific attention because, being dependent on stochastic dispersal, it was uninteresting. However, the importance of dispersal is increasingly being recognized, and here we stress its fundamental role in the generation of biodiversity on oceanic islands that have been created in situ, never connected to larger land masses. Historical dispersal patterns resulting in modern distributions, once considered unknowable, are now being revealed in many plant and animal taxa, in large part through the analysis of polymorphic molecular markers. We emphasize the profound evolutionary insights that oceanic island biodiversity has provided, and the fact that, although small in area, oceanic islands harbour disproportionately high biodiversity and numbers of endemic taxa. We further stress the importance of continuing research on mechanisms generating oceanic island biodiversity, especially detection of general, non‐random patterns of dispersal, and hence the need to acknowledge oceanic dispersal as significant and worthy of research.

@article{doi101111j13652699200501383x,
    author = "Cowie, Robert H. and Holland, Brenden S.",
    title = "Dispersal is fundamental to biogeography and the evolution of biodiversity on oceanic islands",
    year = "2006",
    journal = "Journal of Biogeography",
    abstract = "Abstract Vicariance biogeography emerged several decades ago from the fusion of cladistics and plate tectonics, and quickly came to dominate historical biogeography. The field has since been largely constrained by the notion that only processes of vicariance and not dispersal offer testable patterns and refutable hypotheses, dispersal being a random process essentially adding only noise to a vicariant system. A consequence of this thinking seems to have been a focus on the biogeography of continents and continental islands, considering the biogeography of oceanic islands less worthy of scientific attention because, being dependent on stochastic dispersal, it was uninteresting. However, the importance of dispersal is increasingly being recognized, and here we stress its fundamental role in the generation of biodiversity on oceanic islands that have been created in situ, never connected to larger land masses. Historical dispersal patterns resulting in modern distributions, once considered unknowable, are now being revealed in many plant and animal taxa, in large part through the analysis of polymorphic molecular markers. We emphasize the profound evolutionary insights that oceanic island biodiversity has provided, and the fact that, although small in area, oceanic islands harbour disproportionately high biodiversity and numbers of endemic taxa. We further stress the importance of continuing research on mechanisms generating oceanic island biodiversity, especially detection of general, non‐random patterns of dispersal, and hence the need to acknowledge oceanic dispersal as significant and worthy of research.",
    url = "https://doi.org/10.1111/j.1365-2699.2005.01383.x",
    doi = "10.1111/j.1365-2699.2005.01383.x",
    openalex = "W2013813449",
    references = "doi101093sysbio244431, doi101111j155856461999tb03769x"
}

@article{doi101016jjhevol200706005,
    author = "Maslin, Mark and Christensen, Beth A.",
    title = "Tectonics, orbital forcing, global climate change, and human evolution in Africa: introduction to the African paleoclimate special volume",
    year = "2007",
    journal = "Journal of Human Evolution",
    url = "https://doi.org/10.1016/j.jhevol.2007.06.005",
    doi = "10.1016/j.jhevol.2007.06.005",
    openalex = "W2025924576",
    references = "doi101017cbo9780511542343018, doi101144gslsp20052470102"
}

Synopsis Ornithischia is a familiar and diverse clade of dinosaurs whose global phylogeny has remained largely unaltered since early cladistic analyses in the mid 1980s. Current understanding of ornithischian evolution is hampered by a paucity of explicitly numerical phylogenetic analyses that consider the entire clade. As a result, it is difficult to assess the robustness of current phylogenetic hypotheses for Ornithischia and the effect that the addition of new taxa or characters is likely to have on the overall topology of the clade. The new phylogenetic analysis presented here incorporates a range of new basal taxa and characters in an attempt to rigorously test global ornithischian phylogeny. Parsimony analysis is carried out with 46 taxa and 221 characters. Although the strict component consensus tree shows poor resolution in a number of areas, application of reduced consensus methods provides a well‐resolved picture of ornithischian interrelationships. Surprisingly, Heterodontosauridae is placed as the most basal group of all well‐known ornithischians, phylogenetically distant from a stem‐defined Ornithopoda, creating a topology that is more congruent with the known ornithischian stratigraphical record. There is no evidence for a monophyletic ‘Fabrosauridae’, and Lesothosaurus (the best‐known ‘fabrosaur') occupies an unusual position as the most basal member of Thyreophora. Other relationships within Thyreophora remain largely stable. The primitive thyreophoran Scelidosaurus is the sister taxon of Eurypoda (stegosaurs and ankylosaurs), rather than a basal ankylosaur as implied by some previous studies. The taxonomic content of Ornithopoda differs significantly from previous analyses and basal relationships within the clade are weakly supported, requiring further investigation. ‘Hypsilopho‐dontidae’ is paraphyletic, with some taxa (Agilisaurus, Hexinlusaurus, Othnielia) placed outside of Ornithopoda as non‐cerapodans. Ceratopsia and Pachycephalosauria are monophyletic and are united as Marginocephalia; however, the stability of these clades is reduced by a number of poorly preserved basal taxa. This analysis reaffirms much of the currently accepted ornithischian topology. Nevertheless, instability in the position and content of several clades (notably Heterodontosauridae and Ornithopoda) indicates that considerable future work on ornithischian phylogeny is required and causes problems for several current phylogenetic definitions.

@article{doi101017s1477201907002271,
    author = "Butler, Richard J. and Upchurch, Paul and Norman, David",
    title = "The phylogeny of the ornithischian dinosaurs",
    year = "2007",
    journal = "Journal of Systematic Palaeontology",
    abstract = "Synopsis Ornithischia is a familiar and diverse clade of dinosaurs whose global phylogeny has remained largely unaltered since early cladistic analyses in the mid 1980s. Current understanding of ornithischian evolution is hampered by a paucity of explicitly numerical phylogenetic analyses that consider the entire clade. As a result, it is difficult to assess the robustness of current phylogenetic hypotheses for Ornithischia and the effect that the addition of new taxa or characters is likely to have on the overall topology of the clade. The new phylogenetic analysis presented here incorporates a range of new basal taxa and characters in an attempt to rigorously test global ornithischian phylogeny. Parsimony analysis is carried out with 46 taxa and 221 characters. Although the strict component consensus tree shows poor resolution in a number of areas, application of reduced consensus methods provides a well‐resolved picture of ornithischian interrelationships. Surprisingly, Heterodontosauridae is placed as the most basal group of all well‐known ornithischians, phylogenetically distant from a stem‐defined Ornithopoda, creating a topology that is more congruent with the known ornithischian stratigraphical record. There is no evidence for a monophyletic ‘Fabrosauridae’, and Lesothosaurus (the best‐known ‘fabrosaur') occupies an unusual position as the most basal member of Thyreophora. Other relationships within Thyreophora remain largely stable. The primitive thyreophoran Scelidosaurus is the sister taxon of Eurypoda (stegosaurs and ankylosaurs), rather than a basal ankylosaur as implied by some previous studies. The taxonomic content of Ornithopoda differs significantly from previous analyses and basal relationships within the clade are weakly supported, requiring further investigation. ‘Hypsilopho‐dontidae’ is paraphyletic, with some taxa (Agilisaurus, Hexinlusaurus, Othnielia) placed outside of Ornithopoda as non‐cerapodans. Ceratopsia and Pachycephalosauria are monophyletic and are united as Marginocephalia; however, the stability of these clades is reduced by a number of poorly preserved basal taxa. This analysis reaffirms much of the currently accepted ornithischian topology. Nevertheless, instability in the position and content of several clades (notably Heterodontosauridae and Ornithopoda) indicates that considerable future work on ornithischian phylogeny is required and causes problems for several current phylogenetic definitions.",
    url = "https://doi.org/10.1017/s1477201907002271",
    doi = "10.1017/s1477201907002271",
    openalex = "W2107074601",
    references = "doi101007bf00377897, doi101007bf02988144, doi101017s1477201906001970, doi101038248168a0, doi10108002724634198310011956, doi10108002724634198510011859, doi10108002724634199010011815, doi10108002724634199110011386, doi10108002724634199110011426, doi10108002724634199410011523, doi10108002724634199410011524, doi10108002724634199410011538, doi10108008912960600719988, doi101086273307, doi101093oxfordjournalsafrafa100309, doi101098rspb20043047, doi101098rspl18870117, doi101098rstb19650003, doi101111j109636421998tb02533x, doi101111j155856461988tb02497x, doi101111j174966321940tb57047x, doi101111j216409471940tb00068x, doi101126science2562999, doi101127njgpa210199841, doi10120600030082200635301ydanpc20co2, doi1015259780520941434, doi1015468gbdyof, doi101671a1097, doi1023071292217, doi1023072408870, doi102475ajss319111253, doi105281zenodo16171435, doi105281zenodo16673433, doi105479si00963801361666197, doi105860choice325663, doi105860choice393984, openalexw1535663436, openalexw1574544995, openalexw225597919, openalexw2310875238, openalexw2603335639, openalexw2894525608, openalexw3215057009, openalexw616953834, owen2015monograph, padian1989presence"
}

A latitudinal gradient in biodiversity has existed since before the time of the dinosaurs, yet how and why this gradient arose remains unresolved. Here we review two major hypotheses for the origin of the latitudinal diversity gradient. The time and area hypothesis holds that tropical climates are older and historically larger, allowing more opportunity for diversification. This hypothesis is supported by observations that temperate taxa are often younger than, and nested within, tropical taxa, and that diversity is positively correlated with the age and area of geographical regions. The diversification rate hypothesis holds that tropical regions diversify faster due to higher rates of speciation (caused by increased opportunities for the evolution of reproductive isolation, or faster molecular evolution, or the increased importance of biotic interactions), or due to lower extinction rates. There is phylogenetic evidence for higher rates of diversification in tropical clades, and palaeontological data demonstrate higher rates of origination for tropical taxa, but mixed evidence for latitudinal differences in extinction rates. Studies of latitudinal variation in incipient speciation also suggest faster speciation in the tropics. Distinguishing the roles of history, speciation and extinction in the origin of the latitudinal gradient represents a major challenge to future research.

@article{doi101111j14610248200701020x,
    author = "Mittelbach, Gary G. and Schemske, Douglas W. and Cornell, Howard V. and Allen, Andrew P. and Brown, J. Mark and Bush, Mark B. and Harrison, Susan and Hurlbert, Allen H. and Knowlton­, Nancy­ and Lessios, H. A. and McCain, Christy M. and McCune, Amy R. and McDade, Lucinda A. and McPeek, Mark A. and Near, Thomas J. and Price, Trevor D. and Ricklefs, Robert E. and Roy, Kaustuv and Sax, Dov F. and Schluter, Dolph and Sobel, James M. and Turelli, Michael",
    title = "Evolution and the latitudinal diversity gradient: speciation, extinction and biogeography",
    year = "2007",
    journal = "Ecology Letters",
    abstract = "A latitudinal gradient in biodiversity has existed since before the time of the dinosaurs, yet how and why this gradient arose remains unresolved. Here we review two major hypotheses for the origin of the latitudinal diversity gradient. The time and area hypothesis holds that tropical climates are older and historically larger, allowing more opportunity for diversification. This hypothesis is supported by observations that temperate taxa are often younger than, and nested within, tropical taxa, and that diversity is positively correlated with the age and area of geographical regions. The diversification rate hypothesis holds that tropical regions diversify faster due to higher rates of speciation (caused by increased opportunities for the evolution of reproductive isolation, or faster molecular evolution, or the increased importance of biotic interactions), or due to lower extinction rates. There is phylogenetic evidence for higher rates of diversification in tropical clades, and palaeontological data demonstrate higher rates of origination for tropical taxa, but mixed evidence for latitudinal differences in extinction rates. Studies of latitudinal variation in incipient speciation also suggest faster speciation in the tropics. Distinguishing the roles of history, speciation and extinction in the origin of the latitudinal gradient represents a major challenge to future research.",
    url = "https://doi.org/10.1111/j.1461-0248.2007.01020.x",
    doi = "10.1111/j.1461-0248.2007.01020.x",
    openalex = "W2142834673",
    references = "doi101038217624a0, doi101086381004, doi101093aibsbulletin2214b, doi101093oso97801985052350010001, doi101098rstb20031393, doi101111j001438202006tb01143x, doi101111j155856461960tb03057x, doi101111j20060906759004272x, doi101126science1059412, doi101126science1130880, doi101126science2354785167, doi101146annurevecolsys34012103144032, doi101722611310, doi1023071435536, doi1023072485224, doi105860choice332720, doi105860choice435875, doi105962bhltitle46292, doi105962bhltitle59991, openalexw1840956397, openalexw2145250129, openalexw2989964553"
}

@incollection{crossref2008biogeography,
    title = "Biogeography",
    year = "2008",
    booktitle = "Saudi Arabia",
    url = "https://doi.org/10.1201/9780203030882.ch7",
    doi = "10.1201/9780203030882.ch7",
    pages = "163-187"
}

Abstract Aim This paper reviews the biogeography of the Australian monsoon tropical biome to highlight general patterns in the distribution of a range of organisms and their environmental correlates and evolutionary history, as well as to identify knowledge gaps. Location Northern Australia, Australian Monsoon Tropics (AMT). The AMT is defined by areas that receive more than 85% of rainfall between November and April. Methods Literature is summarized, including the origin of the monsoon climate, present‐day environment, biota and habitat types, and phylogenetic and geographical relationships of selected organisms. Results Some species are widespread throughout the AMT while others are narrow‐range endemics. Such contrasting distributions correspond to present‐day climates, hydrologies (particularly floodplains), geological features (such as sandstone plateaux), fire regimes, and vegetation types (ranging from rain forest to savanna). Biogeographical and phylogenetic studies of terrestrial plants (e.g. eucalypts) and animals (vertebrates and invertebrates) suggest that distinct bioregions within the AMT reflect the aggregated effects of landscape and environmental history, although more research is required to determine and refine the boundaries of biogeographical zones within the AMT. Phylogenetic analyses of aquatic organisms (fishes and prawns) suggest histories of associations with drainage systems, dispersal barriers, links to New Guinea, and the existence of Lake Carpentaria, now submerged by the Gulf of Carpentaria. Complex adaptations to the landscape and climate in the AMT are illustrated by a number of species. Main conclusions The Australian monsoon is a component of a single global climate system, characterized by a dominant equator‐spanning Hadley cell. Evidence of hot, seasonally moist climates dates back to the Late Eocene, implying that certain endemic elements of the AMT biota have a long history. Vicariant differentiation is inferred to have separated the Kimberley and Arnhem Land bioregions from Cape York Peninsula/northern Queensland. Such older patterns are overlaid by younger events, including dispersal from Southeast Asia, and range expansions and contractions. Future palaeoecological and phylogenetic investigations will illuminate the evolution of the AMT biome. Understanding the biogeography of the AMT is essential to provide a framework for ecological studies and the sustainable development of the region.

@article{doi101111j13652699200902210x,
    author = "Bowman, David M. J. S. and Brown, Gillian K. and Braby, Michael F. and Brown, Josephine R. and Cook, Lyn G. and Crisp, Michael D. and Ford, F. and Haberle, Simon and Hughes, Jane and Isagi, Yuji and Joseph, Leo and McBride, John L. and Nelson, Gareth and Ladiges, Pauline Y.",
    title = "Biogeography of the Australian monsoon tropics",
    year = "2009",
    journal = "Journal of Biogeography",
    abstract = "Abstract Aim This paper reviews the biogeography of the Australian monsoon tropical biome to highlight general patterns in the distribution of a range of organisms and their environmental correlates and evolutionary history, as well as to identify knowledge gaps. Location Northern Australia, Australian Monsoon Tropics (AMT). The AMT is defined by areas that receive more than 85\% of rainfall between November and April. Methods Literature is summarized, including the origin of the monsoon climate, present‐day environment, biota and habitat types, and phylogenetic and geographical relationships of selected organisms. Results Some species are widespread throughout the AMT while others are narrow‐range endemics. Such contrasting distributions correspond to present‐day climates, hydrologies (particularly floodplains), geological features (such as sandstone plateaux), fire regimes, and vegetation types (ranging from rain forest to savanna). Biogeographical and phylogenetic studies of terrestrial plants (e.g. eucalypts) and animals (vertebrates and invertebrates) suggest that distinct bioregions within the AMT reflect the aggregated effects of landscape and environmental history, although more research is required to determine and refine the boundaries of biogeographical zones within the AMT. Phylogenetic analyses of aquatic organisms (fishes and prawns) suggest histories of associations with drainage systems, dispersal barriers, links to New Guinea, and the existence of Lake Carpentaria, now submerged by the Gulf of Carpentaria. Complex adaptations to the landscape and climate in the AMT are illustrated by a number of species. Main conclusions The Australian monsoon is a component of a single global climate system, characterized by a dominant equator‐spanning Hadley cell. Evidence of hot, seasonally moist climates dates back to the Late Eocene, implying that certain endemic elements of the AMT biota have a long history. Vicariant differentiation is inferred to have separated the Kimberley and Arnhem Land bioregions from Cape York Peninsula/northern Queensland. Such older patterns are overlaid by younger events, including dispersal from Southeast Asia, and range expansions and contractions. Future palaeoecological and phylogenetic investigations will illuminate the evolution of the AMT biome. Understanding the biogeography of the AMT is essential to provide a framework for ecological studies and the sustainable development of the region.",
    url = "https://doi.org/10.1111/j.1365-2699.2009.02210.x",
    doi = "10.1111/j.1365-2699.2009.02210.x",
    openalex = "W1983173239",
    references = "doi101071bt00025, doi101111j14000952200401078x"
}

The oldest unequivocal records of Dinosauria were unearthed from Late Triassic rocks (approximately 230 Ma) accumulated over extensional rift basins in southwestern Pangea. The better known of these are Herrerasaurus ischigualastensis, Pisanosaurus mertii, Eoraptor lunensis, and Panphagia protos from the Ischigualasto Formation, Argentina, and Staurikosaurus pricei and Saturnalia tupiniquim from the Santa Maria Formation, Brazil. No uncontroversial dinosaur body fossils are known from older strata, but the Middle Triassic origin of the lineage may be inferred from both the footprint record and its sister-group relation to Ladinian basal dinosauromorphs. These include the typical Marasuchus lilloensis, more basal forms such as Lagerpeton and Dromomeron, as well as silesaurids: a possibly monophyletic group composed of Mid-Late Triassic forms that may represent immediate sister taxa to dinosaurs. The first phylogenetic definition to fit the current understanding of Dinosauria as a node-based taxon solely composed of mutually exclusive Saurischia and Ornithischia was given as "all descendants of the most recent common ancestor of birds and Triceratops". Recent cladistic analyses of early dinosaurs agree that Pisanosaurus mertii is a basal ornithischian; that Herrerasaurus ischigualastensis and Staurikosaurus pricei belong in a monophyletic Herrerasauridae; that herrerasaurids, Eoraptor lunensis, and Guaibasaurus candelariensis are saurischians; that Saurischia includes two main groups, Sauropodomorpha and Theropoda; and that Saturnalia tupiniquim is a basal member of the sauropodomorph lineage. On the contrary, several aspects of basal dinosaur phylogeny remain controversial, including the position of herrerasaurids, E. lunensis, and G. candelariensis as basal theropods or basal saurischians, and the affinity and/or validity of more fragmentary taxa such as Agnosphitys cromhallensis, Alwalkeria maleriensis, Chindesaurus bryansmalli, Saltopus elginensis, and Spondylosoma absconditum. The identification of dinosaur apomorphies is jeopardized by the incompleteness of skeletal remains attributed to most basal dinosauromorphs, the skulls and forelimbs of which are particularly poorly known. Nonetheless, Dinosauria can be diagnosed by a suite of derived traits, most of which are related to the anatomy of the pelvic girdle and limb. Some of these are connected to the acquisition of a fully erect bipedal gait, which has been traditionally suggested to represent a key adaptation that allowed, or even promoted, dinosaur radiation during Late Triassic times. Yet, contrary to the classical "competitive" models, dinosaurs did not gradually replace other terrestrial tetrapods over the Late Triassic. In fact, the radiation of the group comprises at least three landmark moments, separated by controversial (Carnian-Norian, Triassic-Jurassic) extinction events. These are mainly characterized by early diversification in Carnian times, a Norian increase in diversity and (especially) abundance, and the occupation of new niches from the Early Jurassic onwards. Dinosaurs arose from fully bipedal ancestors, the diet of which may have been carnivorous or omnivorous. Whereas the oldest dinosaurs were geographically restricted to south Pangea, including rare ornithischians and more abundant basal members of the saurischian lineage, the group achieved a nearly global distribution by the latest Triassic, especially with the radiation of saurischian groups such as "prosauropods" and coelophysoids.

@article{doi101111j1469185x200900094x,
    author = "Langer, Max C. and Ezcurra, Martín D. and Bittencourt, Jonathas S. and Novas, Fernando E.",
    title = "The origin and early evolution of dinosaurs",
    year = "2009",
    journal = "Biological reviews/Biological reviews of the Cambridge Philosophical Society",
    abstract = {The oldest unequivocal records of Dinosauria were unearthed from Late Triassic rocks (approximately 230 Ma) accumulated over extensional rift basins in southwestern Pangea. The better known of these are Herrerasaurus ischigualastensis, Pisanosaurus mertii, Eoraptor lunensis, and Panphagia protos from the Ischigualasto Formation, Argentina, and Staurikosaurus pricei and Saturnalia tupiniquim from the Santa Maria Formation, Brazil. No uncontroversial dinosaur body fossils are known from older strata, but the Middle Triassic origin of the lineage may be inferred from both the footprint record and its sister-group relation to Ladinian basal dinosauromorphs. These include the typical Marasuchus lilloensis, more basal forms such as Lagerpeton and Dromomeron, as well as silesaurids: a possibly monophyletic group composed of Mid-Late Triassic forms that may represent immediate sister taxa to dinosaurs. The first phylogenetic definition to fit the current understanding of Dinosauria as a node-based taxon solely composed of mutually exclusive Saurischia and Ornithischia was given as "all descendants of the most recent common ancestor of birds and Triceratops". Recent cladistic analyses of early dinosaurs agree that Pisanosaurus mertii is a basal ornithischian; that Herrerasaurus ischigualastensis and Staurikosaurus pricei belong in a monophyletic Herrerasauridae; that herrerasaurids, Eoraptor lunensis, and Guaibasaurus candelariensis are saurischians; that Saurischia includes two main groups, Sauropodomorpha and Theropoda; and that Saturnalia tupiniquim is a basal member of the sauropodomorph lineage. On the contrary, several aspects of basal dinosaur phylogeny remain controversial, including the position of herrerasaurids, E. lunensis, and G. candelariensis as basal theropods or basal saurischians, and the affinity and/or validity of more fragmentary taxa such as Agnosphitys cromhallensis, Alwalkeria maleriensis, Chindesaurus bryansmalli, Saltopus elginensis, and Spondylosoma absconditum. The identification of dinosaur apomorphies is jeopardized by the incompleteness of skeletal remains attributed to most basal dinosauromorphs, the skulls and forelimbs of which are particularly poorly known. Nonetheless, Dinosauria can be diagnosed by a suite of derived traits, most of which are related to the anatomy of the pelvic girdle and limb. Some of these are connected to the acquisition of a fully erect bipedal gait, which has been traditionally suggested to represent a key adaptation that allowed, or even promoted, dinosaur radiation during Late Triassic times. Yet, contrary to the classical "competitive" models, dinosaurs did not gradually replace other terrestrial tetrapods over the Late Triassic. In fact, the radiation of the group comprises at least three landmark moments, separated by controversial (Carnian-Norian, Triassic-Jurassic) extinction events. These are mainly characterized by early diversification in Carnian times, a Norian increase in diversity and (especially) abundance, and the occupation of new niches from the Early Jurassic onwards. Dinosaurs arose from fully bipedal ancestors, the diet of which may have been carnivorous or omnivorous. Whereas the oldest dinosaurs were geographically restricted to south Pangea, including rare ornithischians and more abundant basal members of the saurischian lineage, the group achieved a nearly global distribution by the latest Triassic, especially with the radiation of saurischian groups such as "prosauropods" and coelophysoids.},
    url = "https://doi.org/10.1111/j.1469-185x.2009.00094.x",
    doi = "10.1111/j.1469-185x.2009.00094.x",
    openalex = "W2121596487",
    references = "chatterjee2013a, crossref1998encyclopedia, currie2009stratigraphy, doi1010160031018281900924, doi1010160031018295000178, doi101016c20090644421, doi101016jjsames200504002, doi101016jpalaeo200606041, doi101016s0012825203000825, doi101016s0016699580800386, doi101016s0016699583800205, doi101016s0031018298001175, doi101017cbo9780511628948, doi101017s0094837300010575, doi101017s1477201906001970, doi101017s1477201907002040, doi101017s1477201907002246, doi101017s1477201907002271, doi101017s247526300000091x, doi10103820167, doi10106313060577, doi101073pnas0606028103, doi10108002724634199410011538, doi10108002724634199510011271, doi10108002724634199810011115, doi10108002724634199910011124, doi101098rspb20042692, doi101098rspb20080715, doi101098rspl18870117, doi101098rstb19990489, doi101111j109636421985tb01796x, doi101111j10963642200400130x, doi101126science1143325, doi101126science21545391501, doi101126science2645160828, doi101126science2845414616, doi101126science3616622, doi101127njgpa210199841, doi101144gsjgs14720321, doi1012060003009020073021taoeoa20co2, doi101525california97805202420980010001, doi1015468gbdyof, doi1016710272463420020220510toomka20co2, doi1016710272463420072773tclagn20co2, doi101671a1097, doi1023071292217, doi1023071441916, doi1023073889325, doi102475ajss319111253, doi102475ajss32313381, doi104202app20080415, doi10432497802030907329, doi105281zenodo16120887, doi105281zenodo16171435, doi105281zenodo16246150, doi105860choice325663, doi105860choice393984, doi105860choice465038, doi107146moggeosciv32i140904, doi10718895fylantbak30809522, openalexw114509570, openalexw1496509561, openalexw1535663436, openalexw205674743, openalexw2242116350, openalexw2788234611, openalexw2991310333, openalexw3208547338, openalexw3215057009, padian1989presence, rowe1989a, walker1964triassic"
}

@article{doi101016jgloplacha201001015,
    author = "Bonnefille, Raymonde",
    title = "Cenozoic vegetation, climate changes and hominid evolution in tropical Africa",
    year = "2010",
    journal = "Global and Planetary Change",
    url = "https://doi.org/10.1016/j.gloplacha.2010.01.015",
    doi = "10.1016/j.gloplacha.2010.01.015",
    openalex = "W2075192171",
    references = "doi101016s0031018203004838, doi101126science1175802, doi102973odpprocsr1381321995"
}

The herbivorous sauropod dinosaurs of the Jurassic and Cretaceous periods were the largest terrestrial animals ever, surpassing the largest herbivorous mammals by an order of magnitude in body mass. Several evolutionary lineages among Sauropoda produced giants with body masses in excess of 50 metric tonnes by conservative estimates. With body mass increase driven by the selective advantages of large body size, animal lineages will increase in body size until they reach the limit determined by the interplay of bauplan, biology, and resource availability. There is no evidence, however, that resource availability and global physicochemical parameters were different enough in the Mesozoic to have led to sauropod gigantism.

@article{doi101111j1469185x201000137x,
    author = "Sander, P. Martin and Christian, Andreas and Clauß, Marcus and Fechner, Regina and Gee, Carole T. and Griebeler, Eva-Maria and Gunga, Hanns‐Christian and Hummel, Jürgen and Mallison, Heinrich and Perry, Steven F. and Preuschoft, Holger and Rauhut, Oliver W. M. and Remes, Kristian and Tütken, Thomas and Wings, Oliver and Witzel, U.",
    title = "Biology of the sauropod dinosaurs: the evolution of gigantism",
    year = "2010",
    journal = "Biological reviews/Biological reviews of the Cambridge Philosophical Society",
    abstract = "The herbivorous sauropod dinosaurs of the Jurassic and Cretaceous periods were the largest terrestrial animals ever, surpassing the largest herbivorous mammals by an order of magnitude in body mass. Several evolutionary lineages among Sauropoda produced giants with body masses in excess of 50 metric tonnes by conservative estimates. With body mass increase driven by the selective advantages of large body size, animal lineages will increase in body size until they reach the limit determined by the interplay of bauplan, biology, and resource availability. There is no evidence, however, that resource availability and global physicochemical parameters were different enough in the Mesozoic to have led to sauropod gigantism.",
    url = "https://doi.org/10.1111/j.1469-185x.2010.00137.x",
    doi = "10.1111/j.1469-185x.2010.00137.x",
    openalex = "W2090710319",
    references = "amiot2006oxygen, christiansen2004mass, crossref1998encyclopedia, doi101002jez513, doi1010079789400904095, doi101016jpalaeo200901002, doi101016jtree200508012, doi101017cbo9780511565441, doi101017cbo9780511608551, doi101017cbo9781139167826, doi101017s0094837300009866, doi101017s0094837300021321, doi101017s1464793101005735, doi101021j150446a008, doi101038262207a0, doi101038344858a0, doi10103835086558, doi101046j10963642200200029x, doi101073pnas0708903105, doi101073pnas251548698, doi10108002724634199410011538, doi10108002724634199510011575, doi10108002724634199810011115, doi10108002724634199910011178, doi101098rsbl20070254, doi101098rspb20080715, doi101098rstb19950125, doi101111j109636421985tb00871x, doi101111j109636421998tb00569x, doi101111j146979981985tb04915x, doi101126science1118806, doi101139e93176, doi101146annurevecolsys36102003152631, doi101146annureves26110195002305, doi101242jeb029009, doi101371journalpone0001230, doi101371journalpone0006924, doi1015159781400881376, doi101525california97805202420980030015, doi101525california97805202420980030031, doi101525california97805202462320010001, doi1016660094837320000260466lhotts20co2, doi1016660094837320030290105dbttoo20co2, doi1016660094837320080340247ositlb20co2, doi1016710272463420000200115lbhoth20co2, doi1022179revmacn7344, doi1023072407154, doi1023073889325, doi102475ajss319111253, doi10560219780801881206, doi105860choice271523, doi105860choice304997, doi105860choice326223, doi105860choice353642, doi105860choice490282, martinsander2006bone, openalexw1025856234, openalexw114509570, openalexw1504554173, openalexw1534857865, openalexw1558456135, openalexw1585246501, openalexw1607828269, openalexw2318111898, openalexw2618301958, openalexw2983381470, openalexw3015256845, openalexw575222456, seymour1976dinosaurs"
}

BACKGROUND: During much of the Late Cretaceous, a shallow, epeiric sea divided North America into eastern and western landmasses. The western landmass, known as Laramidia, although diminutive in size, witnessed a major evolutionary radiation of dinosaurs. Other than hadrosaurs (duck-billed dinosaurs), the most common dinosaurs were ceratopsids (large-bodied horned dinosaurs), currently known only from Laramidia and Asia. Remarkably, previous studies have postulated the occurrence of latitudinally arrayed dinosaur "provinces," or "biomes," on Laramidia. Yet this hypothesis has been challenged on multiple fronts and has remained poorly tested. METHODOLOGY/PRINCIPAL FINDINGS: Here we describe two new, co-occurring ceratopsids from the Upper Cretaceous Kaiparowits Formation of Utah that provide the strongest support to date for the dinosaur provincialism hypothesis. Both pertain to the clade of ceratopsids known as Chasmosaurinae, dramatically increasing representation of this group from the southern portion of the Western Interior Basin of North America. Utahceratops gettyi gen. et sp. nov.-characterized by short, rounded, laterally projecting supraorbital horncores and an elongate frill with a deep median embayment-is recovered as the sister taxon to Pentaceratops sternbergii from the late Campanian of New Mexico. Kosmoceratops richardsoni gen. et sp. nov.-characterized by elongate, laterally projecting supraorbital horncores and a short, broad frill adorned with ten well developed hooks-has the most ornate skull of any known dinosaur and is closely allied to Chasmosaurus irvinensis from the late Campanian of Alberta. CONCLUSIONS/SIGNIFICANCE: Considered in unison, the phylogenetic, stratigraphic, and biogeographic evidence documents distinct, co-occurring chasmosaurine taxa north and south on the diminutive landmass of Laramidia. The famous Triceratops and all other, more nested chasmosaurines are postulated as descendants of forms previously restricted to the southern portion of Laramidia. Results further suggest the presence of latitudinally arrayed evolutionary centers of endemism within chasmosaurine ceratopsids during the late Campanian, the first documented occurrence of intracontinental endemism within dinosaurs.

@article{doi101371journalpone0012292,
    author = "Sampson, Scott D. and Loewen, Mark A. and Farke, Andrew A. and Roberts, Eric M. and Forster, Catherine A. and Smith, Joshua A. and Titus, Alan L.",
    title = "New Horned Dinosaurs from Utah Provide Evidence for Intracontinental Dinosaur Endemism",
    year = "2010",
    journal = "PLoS ONE",
    abstract = {BACKGROUND: During much of the Late Cretaceous, a shallow, epeiric sea divided North America into eastern and western landmasses. The western landmass, known as Laramidia, although diminutive in size, witnessed a major evolutionary radiation of dinosaurs. Other than hadrosaurs (duck-billed dinosaurs), the most common dinosaurs were ceratopsids (large-bodied horned dinosaurs), currently known only from Laramidia and Asia. Remarkably, previous studies have postulated the occurrence of latitudinally arrayed dinosaur "provinces," or "biomes," on Laramidia. Yet this hypothesis has been challenged on multiple fronts and has remained poorly tested. METHODOLOGY/PRINCIPAL FINDINGS: Here we describe two new, co-occurring ceratopsids from the Upper Cretaceous Kaiparowits Formation of Utah that provide the strongest support to date for the dinosaur provincialism hypothesis. Both pertain to the clade of ceratopsids known as Chasmosaurinae, dramatically increasing representation of this group from the southern portion of the Western Interior Basin of North America. Utahceratops gettyi gen. et sp. nov.-characterized by short, rounded, laterally projecting supraorbital horncores and an elongate frill with a deep median embayment-is recovered as the sister taxon to Pentaceratops sternbergii from the late Campanian of New Mexico. Kosmoceratops richardsoni gen. et sp. nov.-characterized by elongate, laterally projecting supraorbital horncores and a short, broad frill adorned with ten well developed hooks-has the most ornate skull of any known dinosaur and is closely allied to Chasmosaurus irvinensis from the late Campanian of Alberta. CONCLUSIONS/SIGNIFICANCE: Considered in unison, the phylogenetic, stratigraphic, and biogeographic evidence documents distinct, co-occurring chasmosaurine taxa north and south on the diminutive landmass of Laramidia. The famous Triceratops and all other, more nested chasmosaurines are postulated as descendants of forms previously restricted to the southern portion of Laramidia. Results further suggest the presence of latitudinally arrayed evolutionary centers of endemism within chasmosaurine ceratopsids during the late Campanian, the first documented occurrence of intracontinental endemism within dinosaurs.},
    url = "https://doi.org/10.1371/journal.pone.0012292",
    doi = "10.1371/journal.pone.0012292",
    openalex = "W2027103072",
    references = "crossref1998encyclopedia, doi101007978140206754912413, doi101016jcretres200501002, doi101016jsedgeo200610001, doi101038358059a0, doi101086285558, doi101098rspl18870117, doi101111j10960031200800217x, doi101126science13234331023, doi101126science24348951145, doi101139e93016, doi105860choice353642, doi105860choice435902, lehman1987late, openalexw2611511275, openalexw3206657856, openalexw3215057009"
}

Climate change and its effects on African ecosystems may have played a key role in human evolution.

@article{doi101126science1190683,
    author = "deMenocal, Peter B",
    title = "Climate and Human Evolution",
    year = "2011",
    journal = "Science",
    abstract = "Climate change and its effects on African ecosystems may have played a key role in human evolution.",
    url = "https://doi.org/10.1126/science.1190683",
    doi = "10.1126/science.1190683",
    openalex = "W2053190053",
    references = "doi101002ajpa20733, doi101038nature05163, doi101146annurevearth031208100055"
}

BACKGROUND: Troodontids are a predominantly small-bodied group of feathered theropod dinosaurs notable for their close evolutionary relationship with Avialae. Despite a diverse Asian representation with remarkable growth in recent years, the North American record of the clade remains poor, with only one controversial species--Troodon formosus--presently known from substantial skeletal remains. METHODOLOGY/PRINCIPAL FINDINGS: Here we report a gracile new troodontid theropod--Talos sampsoni gen. et sp. nov.--from the Upper Cretaceous Kaiparowits Formation, Utah, USA, representing one of the most complete troodontid skeletons described from North America to date. Histological assessment of the holotype specimen indicates that the adult body size of Talos was notably smaller than that of the contemporary genus Troodon. Phylogenetic analysis recovers Talos as a member of a derived, latest Cretaceous subclade, minimally containing Troodon, Saurornithoides, and Zanabazar. MicroCT scans reveal extreme pathological remodeling on pedal phalanx II-1 of the holotype specimen likely resulting from physical trauma and subsequent infectious processes. CONCLUSION/SIGNIFICANCE: Talos sampsoni adds to the singularity of the Kaiparowits Formation dinosaur fauna, which is represented by at least 10 previously unrecognized species including the recently named ceratopsids Utahceratops and Kosmoceratops, the hadrosaurine Gryposaurus monumentensis, the tyrannosaurid Teratophoneus, and the oviraptorosaurian Hagryphus. The presence of a distinct troodontid taxon in the Kaiparowits Formation supports the hypothesis that late Campanian dinosaurs of the Western Interior Basin exhibited restricted geographic ranges and suggests that the taxonomic diversity of Late Cretaceous troodontids from North America is currently underestimated. An apparent traumatic injury to the foot of Talos with evidence of subsequent healing sheds new light on the paleobiology of deinonychosaurians by bolstering functional interpretations of prey grappling and/or intraspecific combat for the second pedal digit, and supporting trackway evidence indicating a minimal role in weight bearing.

@article{doi101371journalpone0024487,
    author = "Zanno, Lindsay E. and Varricchio, David J. and O’Connor, Patrick M. and Titus, Alan L. and Knell, Michael J.",
    title = "A New Troodontid Theropod, Talos sampsoni gen. et sp. nov., from the Upper Cretaceous Western Interior Basin of North America",
    year = "2011",
    journal = "PLoS ONE",
    abstract = "BACKGROUND: Troodontids are a predominantly small-bodied group of feathered theropod dinosaurs notable for their close evolutionary relationship with Avialae. Despite a diverse Asian representation with remarkable growth in recent years, the North American record of the clade remains poor, with only one controversial species--Troodon formosus--presently known from substantial skeletal remains. METHODOLOGY/PRINCIPAL FINDINGS: Here we report a gracile new troodontid theropod--Talos sampsoni gen. et sp. nov.--from the Upper Cretaceous Kaiparowits Formation, Utah, USA, representing one of the most complete troodontid skeletons described from North America to date. Histological assessment of the holotype specimen indicates that the adult body size of Talos was notably smaller than that of the contemporary genus Troodon. Phylogenetic analysis recovers Talos as a member of a derived, latest Cretaceous subclade, minimally containing Troodon, Saurornithoides, and Zanabazar. MicroCT scans reveal extreme pathological remodeling on pedal phalanx II-1 of the holotype specimen likely resulting from physical trauma and subsequent infectious processes. CONCLUSION/SIGNIFICANCE: Talos sampsoni adds to the singularity of the Kaiparowits Formation dinosaur fauna, which is represented by at least 10 previously unrecognized species including the recently named ceratopsids Utahceratops and Kosmoceratops, the hadrosaurine Gryposaurus monumentensis, the tyrannosaurid Teratophoneus, and the oviraptorosaurian Hagryphus. The presence of a distinct troodontid taxon in the Kaiparowits Formation supports the hypothesis that late Campanian dinosaurs of the Western Interior Basin exhibited restricted geographic ranges and suggests that the taxonomic diversity of Late Cretaceous troodontids from North America is currently underestimated. An apparent traumatic injury to the foot of Talos with evidence of subsequent healing sheds new light on the paleobiology of deinonychosaurians by bolstering functional interpretations of prey grappling and/or intraspecific combat for the second pedal digit, and supporting trackway evidence indicating a minimal role in weight bearing.",
    url = "https://doi.org/10.1371/journal.pone.0024487",
    doi = "10.1371/journal.pone.0024487",
    openalex = "W2075731101",
    references = "doi101002ar20986, doi101002sici109686441999081094563aidajpa1130co2x, doi101016jsedgeo200610001, doi101016s0006320796900622, doi101016s0748300703000604, doi101111j155856461985tb00420x, doi1012066481, doi101371journalpone0012292, doi101371journalpone0014329, doi1015468gcrned, doi1016710272463420050250897anotmf20co2, doi1023072408678, doi102307jctvqc6gzx, doi102475ajss319111253, doi105860choice362492, doi105962bhltitle115853, doi105962p339375, openalexw2611511275, openalexw3206657856, openalexw3215057009, wilson1985stenonychosaurus"
}

Although an African origin of the modern human species is generally accepted, the evolutionary processes involved in the speciation, geographical spread, and eventual extinction of archaic humans outside of Africa are much debated. An additional complexity has been the recent evidence of limited interbreeding between modern humans and the Neandertals and Denisovans. Modern human migrations and interactions began during the buildup to the Last Glacial Maximum, starting about 100,000 years ago. By examining the history of other organisms through glacial cycles, valuable models for evolutionary biogeography can be formulated. According to one such model, the adoption of a new refugium by a subgroup of a species may lead to important evolutionary changes.

@article{doi101126science1215627,
    author = "Stewart, John R. and Stringer, Chris",
    title = "Human Evolution Out of Africa: The Role of Refugia and Climate Change",
    year = "2012",
    journal = "Science",
    abstract = "Although an African origin of the modern human species is generally accepted, the evolutionary processes involved in the speciation, geographical spread, and eventual extinction of archaic humans outside of Africa are much debated. An additional complexity has been the recent evidence of limited interbreeding between modern humans and the Neandertals and Denisovans. Modern human migrations and interactions began during the buildup to the Last Glacial Maximum, starting about 100,000 years ago. By examining the history of other organisms through glacial cycles, valuable models for evolutionary biogeography can be formulated. According to one such model, the adoption of a new refugium by a subgroup of a species may lead to important evolutionary changes.",
    url = "https://doi.org/10.1126/science.1215627",
    doi = "10.1126/science.1215627",
    openalex = "W2036024839",
    references = "doi101002ajpa10021"
}

Phylogenetic relationships, divergence times, and patterns of biogeographic descent among primate species are both complex and contentious. Here, we generate a robust molecular phylogeny for 70 primate genera and 367 primate species based on a concatenation of 69 nuclear gene segments and ten mitochondrial gene sequences, most of which were extracted from GenBank. Relaxed clock analyses of divergence times with 14 fossil-calibrated nodes suggest that living Primates last shared a common ancestor 71-63 Ma, and that divergences within both Strepsirrhini and Haplorhini are entirely post-Cretaceous. These results are consistent with the hypothesis that the Cretaceous-Paleogene mass extinction of non-avian dinosaurs played an important role in the diversification of placental mammals. Previous queries into primate historical biogeography have suggested Africa, Asia, Europe, or North America as the ancestral area of crown primates, but were based on methods that were coopted from phylogeny reconstruction. By contrast, we analyzed our molecular phylogeny with two methods that were developed explicitly for ancestral area reconstruction, and find support for the hypothesis that the most recent common ancestor of living Primates resided in Asia. Analyses of primate macroevolutionary dynamics provide support for a diversification rate increase in the late Miocene, possibly in response to elevated global mean temperatures, and are consistent with the fossil record. By contrast, diversification analyses failed to detect evidence for rate-shift changes near the Eocene-Oligocene boundary even though the fossil record provides clear evidence for a major turnover event ("Grande Coupure") at this time. Our results highlight the power and limitations of inferring diversification dynamics from molecular phylogenies, as well as the sensitivity of diversification analyses to different species concepts.

@article{doi101371journalpone0049521,
    author = "Springer, Mark S. and Meredith, Robert W. and Gatesy, John and Emerling, Christopher A. and Park, Jong Seok and Rabosky, Daniel L. and Stadler, Tanja and Steiner, Cynthia and Ryder, Oliver A. and Janečka, Jan E. and Fisher, Colleen A. and Murphy, William J.",
    title = "Macroevolutionary Dynamics and Historical Biogeography of Primate Diversification Inferred from a Species Supermatrix",
    year = "2012",
    journal = "PLoS ONE",
    abstract = {Phylogenetic relationships, divergence times, and patterns of biogeographic descent among primate species are both complex and contentious. Here, we generate a robust molecular phylogeny for 70 primate genera and 367 primate species based on a concatenation of 69 nuclear gene segments and ten mitochondrial gene sequences, most of which were extracted from GenBank. Relaxed clock analyses of divergence times with 14 fossil-calibrated nodes suggest that living Primates last shared a common ancestor 71-63 Ma, and that divergences within both Strepsirrhini and Haplorhini are entirely post-Cretaceous. These results are consistent with the hypothesis that the Cretaceous-Paleogene mass extinction of non-avian dinosaurs played an important role in the diversification of placental mammals. Previous queries into primate historical biogeography have suggested Africa, Asia, Europe, or North America as the ancestral area of crown primates, but were based on methods that were coopted from phylogeny reconstruction. By contrast, we analyzed our molecular phylogeny with two methods that were developed explicitly for ancestral area reconstruction, and find support for the hypothesis that the most recent common ancestor of living Primates resided in Asia. Analyses of primate macroevolutionary dynamics provide support for a diversification rate increase in the late Miocene, possibly in response to elevated global mean temperatures, and are consistent with the fossil record. By contrast, diversification analyses failed to detect evidence for rate-shift changes near the Eocene-Oligocene boundary even though the fossil record provides clear evidence for a major turnover event ("Grande Coupure") at this time. Our results highlight the power and limitations of inferring diversification dynamics from molecular phylogenies, as well as the sensitivity of diversification analyses to different species concepts.},
    url = "https://doi.org/10.1371/journal.pone.0049521",
    doi = "10.1371/journal.pone.0049521",
    openalex = "W1989350663",
    references = "doi101017s0094837300004929, doi101073pnas0900319106, doi10108010635150701883881, steiper2006primate"
}

PREFACE: James O. Farlow and M. K. Brett-Surman PART ONE: THE DISCOVERY OF DINOSAURS The Earliest Discoveries: William A. S. Sarjeant European Dinosaur Hunters: Hans-Dieter Sues North American Dinosaur Hunters: Edwin H. Colbert Asian Dinosaur Hunters: John R. Lavas Dinosaur Hunters of the Southern Continents: Thomas R. Holtz, Jr. PART TWO: THE STUDY OF DINOSAURS Hunting for Dinosaur Bones: David D. Gillette The Osteology of the Dinosaurs: Thomas R. Holtz, Jr. and M. K.Brett-Surman The Taxonomy and Systematics of the Dinosaurs: Thomas R. Holtz, Jr. and M. K. Brett-Surman Dinosaurs and Geologic Time: James O. Farlow The Scientific Study of Dinosaurs: Ralph E. Chapman Molecular Paleontology: Rationale and Techniques for the Study of Ancient Biomolecules: Mary Higby Schweitzer Dinosaurs as Museum Exhibits: Kenneth Carpenter Restoring Dinosaurs as Living Animals: Douglas Henderson PART THREE: THE GROUPS OF DINOSAURS Introduction: James O. Farlow and M. K. Brett-Surman Politics and Paleontology: Richard Owen and the Invention of Dinosaurs: Hugh Torrens Evolution of the Archosaurs: J. Michael Parrish Origin and Early Evolution of Dinosaurs: Michael J. Benton Theropods: Philip J. Currie Segnosaurs (Therezinosaurs): Teresa Maryanska Prosauropods: Jacques VanHeerden Sauropods: John S. McIntosh, M. K. Brett-Surman, and James O. Farlow Stegosaurs: Peter M. Galton Ankylosaurs: Kenneth Carpenter Marginocephalians: Catherine A. Forster and Paul C. Sereno Ornithopods: M. K. Brett-Surman PART FOUR: BIOLOGY OF THE DINOSAURS Land Plants as Food and Habitat in the Age of Dinosaurs: Bruce H. Tiffney What Did Dinosaurs Eat? Coprolites and Other Direct Evidence of Dinosaur Diets: Karen Chin Dinosaur Combat and Courtship: Scott Sampson Dinosaur Eggs: Karl F. Hirsch and Darla K. Zelenitsky How Dinosaurs Grew: R. E. H. Reid Engineering a Dinosaur: R. McN. Alexander Dinosaurian Paleopathology: Bruce M. Rothschild Dinosaurian Physiology: the Case for Intermediate Dinosaurs: R. E. H. Reid Oxygen Isotopes in Dinosaur Bone: Reese E. Barrick, Michael K. Stoskopf, and William J. Showers A Blueprint for Giants: Do Living Reptiles, Birds or Mammals Provide the Best Model for the Physiology of Large Dinosaurs? Frank V. Paladino, James R. Spotila, and Peter Dodson New Insights into the Metabolic Physiology of Dinosaurs: John Ruben, Andrew Leitch, Willem Hillenius, Nicholas Geist, and Terry Jones The Scientific Study of Dinosaur Footprints: James O. Farlow and Ralph E. Chapman The Paleoecological and Paleoenvironmental Utility of Dinosaur Tracks: Martin G. Lockley PART FIVE: DINOSAUR EVOLUTION IN THE CHANGING WORLD OF THE MESOZOIC ERA Biogeography for Dinosaurs: Ralph E. Molnar Major Groups of Non-Dinosaurian Vertebrates of the Mesozoic Era: Michael Morales Continental Tetrapods of the Early Mesozoic: Faunas and Faunal Changes: Hans-Dieter Sues Dinosaurian Faunas of the Later Mesozoic: Dale A. Russell and Jose F. Bonaparte The Extinction of the Dinosaurs: A Dialogue Between a Catastrophist and a Gradualist: Dale A. Russell and Peter Dodson PART SIX: DINOSAURS AND THE MEDIA Dinosaurs and the Media: Donald F. Glut and M. K. Brett-Surman APPENDIX: A CHRONOLOGICAL HISTORY OF DINOSAUR PALEONTOLOGY: M. K. Brett-Surman GLOSSARY CONTRIBUTORS INDEX

@book{openalexw1585246501,
    author = "Farlow, James O. and Brett-Surman, Michael K.",
    title = "The Complete Dinosaur",
    year = "2012",
    booktitle = "Opus: Research \& Creativity (Indiana University – Purdue University Fort Wayne)",
    abstract = "PREFACE: James O. Farlow and M. K. Brett-Surman PART ONE: THE DISCOVERY OF DINOSAURS The Earliest Discoveries: William A. S. Sarjeant European Dinosaur Hunters: Hans-Dieter Sues North American Dinosaur Hunters: Edwin H. Colbert Asian Dinosaur Hunters: John R. Lavas Dinosaur Hunters of the Southern Continents: Thomas R. Holtz, Jr. PART TWO: THE STUDY OF DINOSAURS Hunting for Dinosaur Bones: David D. Gillette The Osteology of the Dinosaurs: Thomas R. Holtz, Jr. and M. K.Brett-Surman The Taxonomy and Systematics of the Dinosaurs: Thomas R. Holtz, Jr. and M. K. Brett-Surman Dinosaurs and Geologic Time: James O. Farlow The Scientific Study of Dinosaurs: Ralph E. Chapman Molecular Paleontology: Rationale and Techniques for the Study of Ancient Biomolecules: Mary Higby Schweitzer Dinosaurs as Museum Exhibits: Kenneth Carpenter Restoring Dinosaurs as Living Animals: Douglas Henderson PART THREE: THE GROUPS OF DINOSAURS Introduction: James O. Farlow and M. K. Brett-Surman Politics and Paleontology: Richard Owen and the Invention of Dinosaurs: Hugh Torrens Evolution of the Archosaurs: J. Michael Parrish Origin and Early Evolution of Dinosaurs: Michael J. Benton Theropods: Philip J. Currie Segnosaurs (Therezinosaurs): Teresa Maryanska Prosauropods: Jacques VanHeerden Sauropods: John S. McIntosh, M. K. Brett-Surman, and James O. Farlow Stegosaurs: Peter M. Galton Ankylosaurs: Kenneth Carpenter Marginocephalians: Catherine A. Forster and Paul C. Sereno Ornithopods: M. K. Brett-Surman PART FOUR: BIOLOGY OF THE DINOSAURS Land Plants as Food and Habitat in the Age of Dinosaurs: Bruce H. Tiffney What Did Dinosaurs Eat? Coprolites and Other Direct Evidence of Dinosaur Diets: Karen Chin Dinosaur Combat and Courtship: Scott Sampson Dinosaur Eggs: Karl F. Hirsch and Darla K. Zelenitsky How Dinosaurs Grew: R. E. H. Reid Engineering a Dinosaur: R. McN. Alexander Dinosaurian Paleopathology: Bruce M. Rothschild Dinosaurian Physiology: the Case for Intermediate Dinosaurs: R. E. H. Reid Oxygen Isotopes in Dinosaur Bone: Reese E. Barrick, Michael K. Stoskopf, and William J. Showers A Blueprint for Giants: Do Living Reptiles, Birds or Mammals Provide the Best Model for the Physiology of Large Dinosaurs? Frank V. Paladino, James R. Spotila, and Peter Dodson New Insights into the Metabolic Physiology of Dinosaurs: John Ruben, Andrew Leitch, Willem Hillenius, Nicholas Geist, and Terry Jones The Scientific Study of Dinosaur Footprints: James O. Farlow and Ralph E. Chapman The Paleoecological and Paleoenvironmental Utility of Dinosaur Tracks: Martin G. Lockley PART FIVE: DINOSAUR EVOLUTION IN THE CHANGING WORLD OF THE MESOZOIC ERA Biogeography for Dinosaurs: Ralph E. Molnar Major Groups of Non-Dinosaurian Vertebrates of the Mesozoic Era: Michael Morales Continental Tetrapods of the Early Mesozoic: Faunas and Faunal Changes: Hans-Dieter Sues Dinosaurian Faunas of the Later Mesozoic: Dale A. Russell and Jose F. Bonaparte The Extinction of the Dinosaurs: A Dialogue Between a Catastrophist and a Gradualist: Dale A. Russell and Peter Dodson PART SIX: DINOSAURS AND THE MEDIA Dinosaurs and the Media: Donald F. Glut and M. K. Brett-Surman APPENDIX: A CHRONOLOGICAL HISTORY OF DINOSAUR PALEONTOLOGY: M. K. Brett-Surman GLOSSARY CONTRIBUTORS INDEX",
    openalex = "W1585246501",
    references = "chatterjee2013a, chinsamy1998polar, deklerk2000a, doi101002ar20982, doi101002ara10097, doi101002jmor10406, doi101007s0011400804883, doi1010160031018291900605, doi1010160034666781900695, doi101016jannpal200803002, doi101016jepsl200801015, doi101016jpalaeo201002025, doi101017cbo9780511608551, doi101017s0022336000018862, doi101017s0094837300007557, doi101017s0094837300016900, doi101017s0094837300021321, doi101038262207a0, doi101038307360a0, doi10103832884, doi101038359117a0, doi101038362709a0, doi101038368196a0, doi101038nature03635, doi101038nature10906, doi101046j14401738200300386x, doi10108002724634199810011086, doi10108002724634199910011125, doi10108008912960903503345, doi10108010420940802471027, doi101086284406, doi101086422766, doi101098rspb20060443, doi101111j10963642200600245x, doi101111j10963642200900631x, doi101111j1469185x200900107x, doi101111j150239311985tb00690x, doi101111j15023931200900187x, doi101126science1157704, doi101126science1180219, doi101126science172397867, doi101126science24248841403, doi101126science27352791204, doi101127njgpm19831983141, doi1011300091761319930210503pioatv23co2, doi101130g23452a1, doi101130spe40p1, doi101144001676492006032, doi101144gslsp20042280106, doi101146annurevearth040610133502, doi101146annurevearth28119, doi101146annurevgenet37110801143214, doi10120600030082200635301ydanpc20co2, doi1012066391, doi101353book59141, doi101371journalpone0012292, doi1016660094837320000260450fpindi20co2, doi1016660094837320050310291teafot20co2, doi1016690883135120030180286rpoumt20co2, doi1016710272463420020220593cvancf20co2, doi1016710272463420020220766tehits20co2, doi101671a11168, doi102110palo2007p07070r, doi1023071445147, doi1023073514548, doi102475ajss425149387, doi104202app20080049, doi105281zenodo13315375, doi105281zenodo16692311, doi105281zenodo3739898, doi105962p339375, fiorillo2004the, jacobsen1998feeding, lehman1987late, nelson1980counts, openalexw1550095290, openalexw1558456135, openalexw2163397885, openalexw2242116350, openalexw2506868775, pontzer2009biomechanics, russell2002synopsis, seymour1976dinosaurs, sloan1986gradual, stevens2006binocular, witmer1991biomechanics, woodward1910on"
}

@article{doi101007s1169201392507,
    author = "Ge, Deyan and Liu, Xueqin and Lv, XF and Zhang, ZQ and Xia, Lin and Yang, QS",
    title = "Historical Biogeography and Body Form Evolution of Ground Squirrels (Sciuridae: Xerinae)",
    year = "2013",
    journal = "Evolutionary Biology",
    url = "https://doi.org/10.1007/s11692-013-9250-7",
    doi = "10.1007/s11692-013-9250-7",
    openalex = "W2046083434",
    references = "doi101111j155856461947tb01340x"
}

Historical biogeography is increasingly studied from an explicitly statistical perspective, using stochastic models to describe the evolution of species range as a continuous-time Markov process of dispersal between and extinction within a set of discrete geographic areas. The main constraint of these methods is the computational limit on the number of areas that can be specified. We propose a Bayesian approach for inferring biogeographic history that extends the application of biogeographic models to the analysis of more realistic problems that involve a large number of areas. Our solution is based on a "data-augmentation" approach, in which we first populate the tree with a history of biogeographic events that is consistent with the observed species ranges at the tips of the tree. We then calculate the likelihood of a given history by adopting a mechanistic interpretation of the instantaneous-rate matrix, which specifies both the exponential waiting times between biogeographic events and the relative probabilities of each biogeographic change. We develop this approach in a Bayesian framework, marginalizing over all possible biogeographic histories using Markov chain Monte Carlo (MCMC). Besides dramatically increasing the number of areas that can be accommodated in a biogeographic analysis, our method allows the parameters of a given biogeographic model to be estimated and different biogeographic models to be objectively compared. Our approach is implemented in the program, BayArea.

@article{doi101093sysbiosyt040,
    author = "Landis, Michael J. and Matzke, Nicholas J. and Moore, Brian R. and Huelsenbeck, John P.",
    title = "Bayesian Analysis of Biogeography when the Number of Areas is Large",
    year = "2013",
    journal = "Systematic Biology",
    abstract = {Historical biogeography is increasingly studied from an explicitly statistical perspective, using stochastic models to describe the evolution of species range as a continuous-time Markov process of dispersal between and extinction within a set of discrete geographic areas. The main constraint of these methods is the computational limit on the number of areas that can be specified. We propose a Bayesian approach for inferring biogeographic history that extends the application of biogeographic models to the analysis of more realistic problems that involve a large number of areas. Our solution is based on a "data-augmentation" approach, in which we first populate the tree with a history of biogeographic events that is consistent with the observed species ranges at the tips of the tree. We then calculate the likelihood of a given history by adopting a mechanistic interpretation of the instantaneous-rate matrix, which specifies both the exponential waiting times between biogeographic events and the relative probabilities of each biogeographic change. We develop this approach in a Bayesian framework, marginalizing over all possible biogeographic histories using Markov chain Monte Carlo (MCMC). Besides dramatically increasing the number of areas that can be accommodated in a biogeographic analysis, our method allows the parameters of a given biogeographic model to be estimated and different biogeographic models to be objectively compared. Our approach is implemented in the program, BayArea.},
    url = "https://doi.org/10.1093/sysbio/syt040",
    doi = "10.1093/sysbio/syt040",
    openalex = "W2119783895",
    references = "doi101007bf01734359, doi101016b9781483232119500097, doi101038109132a0, doi10106311699114, doi10108010635150701883881, doi101093biomet57197, doi101093sysbio461195, doi101109tit19621057683, doi101214ss1177011136, doi1015159781400881376, doi10560219781421407944"
}

The Late Cretaceous (∼95-66 million years ago) western North American landmass of Laramidia displayed heightened non-marine vertebrate diversity and intracontinental regionalism relative to other latest Cretaceous Laurasian ecosystems. Processes generating these patterns during this interval remain poorly understood despite their presumed role in the diversification of many clades. Tyrannosauridae, a clade of large-bodied theropod dinosaurs restricted to the Late Cretaceous of Laramidia and Asia, represents an ideal group for investigating Laramidian patterns of evolution. We use new tyrannosaurid discoveries from Utah--including a new taxon which represents the geologically oldest member of the clade--to investigate the evolution and biogeography of Tyrannosauridae. These data suggest a Laramidian origin for Tyrannosauridae, and implicate sea-level related controls in the isolation, diversification, and dispersal of this and many other Late Cretaceous vertebrate clades.

@article{doi101371journalpone0079420,
    author = "Loewen, Mark A. and Irmis, Randall B. and Sertich, Joseph J. W. and Currie, Philip J. and Sampson, Scott D.",
    title = "Tyrant Dinosaur Evolution Tracks the Rise and Fall of Late Cretaceous Oceans",
    year = "2013",
    journal = "PLoS ONE",
    abstract = "The Late Cretaceous (∼95-66 million years ago) western North American landmass of Laramidia displayed heightened non-marine vertebrate diversity and intracontinental regionalism relative to other latest Cretaceous Laurasian ecosystems. Processes generating these patterns during this interval remain poorly understood despite their presumed role in the diversification of many clades. Tyrannosauridae, a clade of large-bodied theropod dinosaurs restricted to the Late Cretaceous of Laramidia and Asia, represents an ideal group for investigating Laramidian patterns of evolution. We use new tyrannosaurid discoveries from Utah--including a new taxon which represents the geologically oldest member of the clade--to investigate the evolution and biogeography of Tyrannosauridae. These data suggest a Laramidian origin for Tyrannosauridae, and implicate sea-level related controls in the isolation, diversification, and dispersal of this and many other Late Cretaceous vertebrate clades.",
    url = "https://doi.org/10.1371/journal.pone.0079420",
    doi = "10.1371/journal.pone.0079420",
    openalex = "W2091933212",
    references = "doi101080027246342011557116, doi10108010635150701883881, doi101111j10960031200800217x, doi101111j10963642200900591x, doi101111j155856461985tb00420x, doi101126science1116412, doi101126science23547931156, doi101214aos1176344552, doi101371journalpone0021376, doi1015259780520941434, doi1023072408678, doi102475ajss321125417, doi105281zenodo16171435, nesbitt2009a, openalexw2611511275, openalexw3215057009"
}

@incollection{corlett2014biogeography,
    author = "Corlett, Richard T.",
    title = "Biogeography",
    year = "2014",
    booktitle = "The Ecology of Tropical East Asia",
    url = "https://doi.org/10.1093/acprof:oso/9780199681341.003.0003",
    doi = "10.1093/acprof:oso/9780199681341.003.0003",
    pages = "62-85"
}

Current evidence suggests that all of the major events in hominin evolution have occurred in East Africa. Over the last two decades, there has been intensive work undertaken to understand African palaeoclimate and tectonics in order to put together a coherent picture of how the environment of East Africa has varied in the past. The landscape of East Africa has altered dramatically over the last 10 million years. It has changed from a relatively flat, homogenous region covered with mixed tropical forest, to a varied and heterogeneous environment, with mountains over 4 km high and vegetation ranging from desert to cloud forest. The progressive rifting of East Africa has also generated numerous lake basins, which are highly sensitive to changes in the local precipitation-evaporation regime. There is now evidence that the presence of precession-driven, ephemeral deep-water lakes in East Africa were concurrent with major events in hominin evolution. It seems the unusual geology and climate of East Africa created periods of highly variable local climate, which, it has been suggested could have driven hominin speciation, encephalisation and dispersal out of Africa. One example is the significant hominin speciation and brain expansion event at ∼1.8 Ma that seems to have been coeval with the occurrence of highly variable, extensive, deep-water lakes. This complex, climatically very variable setting inspired first the variability selection hypothesis, which was then the basis for the pulsed climate variability hypothesis. The newer of the two suggests that the long-term drying trend in East Africa was punctuated by episodes of short, alternating periods of extreme humidity and aridity. Both hypotheses, together with other key theories of climate-evolution linkages, are discussed in this paper. Though useful the actual evolution mechanisms, which led to early hominins are still unclear and continue to be debated. However, it is clear that an understanding of East African lakes and their palaeoclimate history is required to understand the context within which humans evolved and eventually left East Africa.

@article{doi101016jquascirev201406012,
    author = "Maslin, Mark and Brierley, Chris and Milner, Alice M. and Shultz, Susanne and Trauth, Martin H. and Wilson, Katy E.",
    title = "East African climate pulses and early human evolution",
    year = "2014",
    journal = "Quaternary Science Reviews",
    abstract = "Current evidence suggests that all of the major events in hominin evolution have occurred in East Africa. Over the last two decades, there has been intensive work undertaken to understand African palaeoclimate and tectonics in order to put together a coherent picture of how the environment of East Africa has varied in the past. The landscape of East Africa has altered dramatically over the last 10 million years. It has changed from a relatively flat, homogenous region covered with mixed tropical forest, to a varied and heterogeneous environment, with mountains over 4 km high and vegetation ranging from desert to cloud forest. The progressive rifting of East Africa has also generated numerous lake basins, which are highly sensitive to changes in the local precipitation-evaporation regime. There is now evidence that the presence of precession-driven, ephemeral deep-water lakes in East Africa were concurrent with major events in hominin evolution. It seems the unusual geology and climate of East Africa created periods of highly variable local climate, which, it has been suggested could have driven hominin speciation, encephalisation and dispersal out of Africa. One example is the significant hominin speciation and brain expansion event at ∼1.8 Ma that seems to have been coeval with the occurrence of highly variable, extensive, deep-water lakes. This complex, climatically very variable setting inspired first the variability selection hypothesis, which was then the basis for the pulsed climate variability hypothesis. The newer of the two suggests that the long-term drying trend in East Africa was punctuated by episodes of short, alternating periods of extreme humidity and aridity. Both hypotheses, together with other key theories of climate-evolution linkages, are discussed in this paper. Though useful the actual evolution mechanisms, which led to early hominins are still unclear and continue to be debated. However, it is clear that an understanding of East African lakes and their palaeoclimate history is required to understand the context within which humans evolved and eventually left East Africa.",
    url = "https://doi.org/10.1016/j.quascirev.2014.06.012",
    doi = "10.1016/j.quascirev.2014.06.012",
    openalex = "W2002631603",
    references = "doi101002ajpa20733, doi101016027737919190033q, doi101016b9780444594259000299, doi101016jquageo201001002, doi101016s0012821x04000032, doi101016s027737919900061x, doi101017cbo9780511542343018, doi1010292004pa001071, doi10103843854, doi101038nature03052, doi101126science1175802, doi101126science1177216, doi101126science270523353, doi101144gslsp20052470102, doi1016710272463420010210172dteotr20co2, doi1058769781607322252c04"
}

Large-scale adaptive radiations might explain the runaway success of a minority of extant vertebrate clades. This hypothesis predicts, among other things, rapid rates of morphological evolution during the early history of major groups, as lineages invade disparate ecological niches. However, few studies of adaptive radiation have included deep time data, so the links between extant diversity and major extinct radiations are unclear. The intensively studied Mesozoic dinosaur record provides a model system for such investigation, representing an ecologically diverse group that dominated terrestrial ecosystems for 170 million years. Furthermore, with 10,000 species, extant dinosaurs (birds) are the most speciose living tetrapod clade. We assembled composite trees of 614-622 Mesozoic dinosaurs/birds, and a comprehensive body mass dataset using the scaling relationship of limb bone robustness. Maximum-likelihood modelling and the node height test reveal rapid evolutionary rates and a predominance of rapid shifts among size classes in early (Triassic) dinosaurs. This indicates an early burst niche-filling pattern and contrasts with previous studies that favoured gradualistic rates. Subsequently, rates declined in most lineages, which rarely exploited new ecological niches. However, feathered maniraptoran dinosaurs (including Mesozoic birds) sustained rapid evolution from at least the Middle Jurassic, suggesting that these taxa evaded the effects of niche saturation. This indicates that a long evolutionary history of continuing ecological innovation paved the way for a second great radiation of dinosaurs, in birds. We therefore demonstrate links between the predominantly extinct deep time adaptive radiation of non-avian dinosaurs and the phenomenal diversification of birds, via continuing rapid rates of evolution along the phylogenetic stem lineage. This raises the possibility that the uneven distribution of biodiversity results not just from large-scale extrapolation of the process of adaptive radiation in a few extant clades, but also from the maintenance of evolvability on vast time scales across the history of life, in key lineages.

@article{doi101371journalpbio1001853,
    author = "Benson, Roger and Campione, Nicolás E. and Carrano, Matthew T. and Mannion, Philip D. and Sullivan, Corwin and Upchurch, Paul and Evans, David C.",
    title = "Rates of Dinosaur Body Mass Evolution Indicate 170 Million Years of Sustained Ecological Innovation on the Avian Stem Lineage",
    year = "2014",
    journal = "PLoS Biology",
    abstract = "Large-scale adaptive radiations might explain the runaway success of a minority of extant vertebrate clades. This hypothesis predicts, among other things, rapid rates of morphological evolution during the early history of major groups, as lineages invade disparate ecological niches. However, few studies of adaptive radiation have included deep time data, so the links between extant diversity and major extinct radiations are unclear. The intensively studied Mesozoic dinosaur record provides a model system for such investigation, representing an ecologically diverse group that dominated terrestrial ecosystems for 170 million years. Furthermore, with 10,000 species, extant dinosaurs (birds) are the most speciose living tetrapod clade. We assembled composite trees of 614-622 Mesozoic dinosaurs/birds, and a comprehensive body mass dataset using the scaling relationship of limb bone robustness. Maximum-likelihood modelling and the node height test reveal rapid evolutionary rates and a predominance of rapid shifts among size classes in early (Triassic) dinosaurs. This indicates an early burst niche-filling pattern and contrasts with previous studies that favoured gradualistic rates. Subsequently, rates declined in most lineages, which rarely exploited new ecological niches. However, feathered maniraptoran dinosaurs (including Mesozoic birds) sustained rapid evolution from at least the Middle Jurassic, suggesting that these taxa evaded the effects of niche saturation. This indicates that a long evolutionary history of continuing ecological innovation paved the way for a second great radiation of dinosaurs, in birds. We therefore demonstrate links between the predominantly extinct deep time adaptive radiation of non-avian dinosaurs and the phenomenal diversification of birds, via continuing rapid rates of evolution along the phylogenetic stem lineage. This raises the possibility that the uneven distribution of biodiversity results not just from large-scale extrapolation of the process of adaptive radiation in a few extant clades, but also from the maintenance of evolvability on vast time scales across the history of life, in key lineages.",
    url = "https://doi.org/10.1371/journal.pbio.1001853",
    doi = "10.1371/journal.pbio.1001853",
    openalex = "W2155522161",
    references = "doi101007b97636, doi101017s009483730001263x, doi101017s009483730001280x, doi10103835086500, doi10103844766, doi101038nature11631, doi10108010635150490445706, doi101086284325, doi101093bioinformaticsbtm538, doi101093oso97801985052350010001, doi101093oso97801985404720010001, doi101098rspb20122526, doi101111j001438202003tb00285x, doi101111j1469185x201000137x, doi101111j15585646201201723x, doi101126science1144066, doi101126science1161833, doi101146annurevecolsys39110707173447, doi101159000452856, doi101186174170071060, doi101198tech2003s146, doi101371journalpbio1001853, doi101371journalpone0007390, doi101371journalpone0044318, doi10166612041, martinsander2006bone, openalexw2145250129"
}

@article{doi101016jjhevol201506014,
    author = "Potts, Richard and Faith, J. Tyler",
    title = "Alternating high and low climate variability: The context of natural selection and speciation in Plio-Pleistocene hominin evolution",
    year = "2015",
    journal = "Journal of Human Evolution",
    url = "https://doi.org/10.1016/j.jhevol.2015.06.014",
    doi = "10.1016/j.jhevol.2015.06.014",
    openalex = "W1147853437",
    references = "doi101002ajpa20733, doi101038nature05163, doi1058769781607322252c04"
}

@article{doi101016jympev201503008,
    author = "Yu, Yan and Harris, AJ and Blair, Christopher and He, Xing‐Jin",
    title = "RASP (Reconstruct Ancestral State in Phylogenies): A tool for historical biogeography",
    year = "2015",
    journal = "Molecular Phylogenetics and Evolution",
    url = "https://doi.org/10.1016/j.ympev.2015.03.008",
    doi = "10.1016/j.ympev.2015.03.008",
    openalex = "W1970390075",
    references = "doi10108010635150701883881, doi101093sysbio461195, doi101093sysbiosyt040, doi101093sysbiosyt050, doi101093sysbiosyu056"
}

The Ankylosauria is a group of herbivorous, quadrupedal, armoured dinosaurs subdivided into at least two major clades, the Ankylosauridae and the Nodosauridae. The most derived members of Ankylosauridae had a unique tail club formed from modified, tightly interlocking distal caudal vertebrae and enlarged osteoderms that envelop the terminus of the tail. We review all known ankylosaurid species, as well as ankylosaurs of uncertain affinities, in order to conduct a revised phylogenetic analysis of the clade. The revised phylogenetic analysis resulted in a monophyletic Ankylosauridae consisting of Ahshislepelta, Aletopelta, Gastonia, Gobisaurus, Liaoningosaurus, Shamosaurus and a suite of derived ankylosaurids (Ankylosaurinae). There is convincing evidence for the presence of nodosaurids in Asia during the Early Cretaceous. In the mid Cretaceous, Asian nodosaurids were replaced by ankylosaurine ankylosaurids. Ankylosaurines migrated into North America from Asia between the Albian and Campanian, where they diversified into a clade of ankylosaurines, here named Ankylosaurini, characterized by arched snouts and numerous flat cranial caputegulae. There is no evidence for any ankylosaurids in Gondwana; Ankylosauridae appears to be completely restricted to Asia and North America. The genus Crichtonpelta gen. nov. is created, type species Crichtonsaurus benxiensis Lü et al.http://zoobank.org/urn:lsid:zoobank.org:pub:EE5B88A3-3353-4FB6-B9A2-FCF0F99770EB

@article{doi1010801477201920151059985,
    author = "Arbour, Victoria M. and Currie, Philip J.",
    title = "Systematics, phylogeny and palaeobiogeography of the ankylosaurid dinosaurs",
    year = "2015",
    journal = "Journal of Systematic Palaeontology",
    abstract = "The Ankylosauria is a group of herbivorous, quadrupedal, armoured dinosaurs subdivided into at least two major clades, the Ankylosauridae and the Nodosauridae. The most derived members of Ankylosauridae had a unique tail club formed from modified, tightly interlocking distal caudal vertebrae and enlarged osteoderms that envelop the terminus of the tail. We review all known ankylosaurid species, as well as ankylosaurs of uncertain affinities, in order to conduct a revised phylogenetic analysis of the clade. The revised phylogenetic analysis resulted in a monophyletic Ankylosauridae consisting of Ahshislepelta, Aletopelta, Gastonia, Gobisaurus, Liaoningosaurus, Shamosaurus and a suite of derived ankylosaurids (Ankylosaurinae). There is convincing evidence for the presence of nodosaurids in Asia during the Early Cretaceous. In the mid Cretaceous, Asian nodosaurids were replaced by ankylosaurine ankylosaurids. Ankylosaurines migrated into North America from Asia between the Albian and Campanian, where they diversified into a clade of ankylosaurines, here named Ankylosaurini, characterized by arched snouts and numerous flat cranial caputegulae. There is no evidence for any ankylosaurids in Gondwana; Ankylosauridae appears to be completely restricted to Asia and North America. The genus Crichtonpelta gen. nov. is created, type species Crichtonsaurus benxiensis Lü et al.http://zoobank.org/urn:lsid:zoobank.org:pub:EE5B88A3-3353-4FB6-B9A2-FCF0F99770EB",
    url = "https://doi.org/10.1080/14772019.2015.1059985",
    doi = "10.1080/14772019.2015.1059985",
    openalex = "W4232331209",
    references = "doi101002ar20794, doi101016002532279290061l, doi101016jympev201004011, doi10108002724634199510011230, doi101098rspl18870117, doi101111j109636422001tb01314x, doi101126science2562999, doi101126science9231776, doi101371journalpone0012292, doi101371journalpone0108804, doi105860choice393984, openalexw1535663436, openalexw2173200745, openalexw2912219260"
}

Evaluating the relationships between climate, the environment, and human traits is a key part of human origins research because changes in Earth's atmosphere, oceans, landscapes, and ecosystems over the past 10 Myr shaped the selection pressures experienced by early humans. In Africa, these relationships have been influenced by a combination of high-latitude ice distributions, sea surface temperatures, and low-latitude orbital forcing that resulted in large oscillations in vegetation and moisture availability that were modulated by local basin dynamics. The importance of both climate and tectonics in shaping African landscapes means that integrated views of the ecological, environmental, and tectonic histories of a region are necessary in order to understand the relationships between climate and human evolution.

@article{doi101146annurevearth060614105310,
    author = "Levin, Naomi E.",
    title = "Environment and Climate of Early Human Evolution",
    year = "2015",
    journal = "Annual Review of Earth and Planetary Sciences",
    abstract = "Evaluating the relationships between climate, the environment, and human traits is a key part of human origins research because changes in Earth's atmosphere, oceans, landscapes, and ecosystems over the past 10 Myr shaped the selection pressures experienced by early humans. In Africa, these relationships have been influenced by a combination of high-latitude ice distributions, sea surface temperatures, and low-latitude orbital forcing that resulted in large oscillations in vegetation and moisture availability that were modulated by local basin dynamics. The importance of both climate and tectonics in shaping African landscapes means that integrated views of the ecological, environmental, and tectonic histories of a region are necessary in order to understand the relationships between climate and human evolution.",
    url = "https://doi.org/10.1146/annurev-earth-060614-105310",
    doi = "10.1146/annurev-earth-060614-105310",
    openalex = "W2146867942",
    references = "doi101002ajpa20733, doi101016jquascirev201406012"
}

The Late Cretaceous was a time of tremendous global change, as the final stages of the Age of Dinosaurs were shaped by climate and sea level fluctuations and witness to marked paleogeographic and faunal changes, before the end-Cretaceous bolide impact. The terrestrial fossil record of Late Cretaceous Europe is becoming increasingly better understood, based largely on intensive fieldwork over the past two decades, promising new insights into latest Cretaceous faunal evolution. We review the terrestrial Late Cretaceous record from Europe and discuss its importance for understanding the paleogeography, ecology, evolution, and extinction of land-dwelling vertebrates. We review the major Late Cretaceous faunas from Austria, Hungary, France, Spain, Portugal, and Romania, as well as more fragmentary records from elsewhere in Europe. We discuss the paleogeographic background and history of assembly of these faunas, and argue that they are comprised of an endemic 'core' supplemented with various immigration waves. These faunas lived on an island archipelago, and we describe how this insular setting led to ecological peculiarities such as low diversity, a preponderance of primitive taxa, and marked changes in morphology (particularly body size dwarfing). We conclude by discussing the importance of the European record in understanding the end-Cretaceous extinction and show that there is no clear evidence that dinosaurs or other groups were undergoing long-term declines in Europe prior to the bolide impact.

@article{doi103897zookeys4698439,
    author = "Csiki‐Sava, Zoltán and Buffetaut, Éric and Ősi, Attila and Suberbiola, Xabier Pereda and Brusatte, Stephen L.",
    title = "Island life in the Cretaceous - faunal composition, biogeography, evolution, and extinction of land-living vertebrates on the Late Cretaceous European archipelago",
    year = "2015",
    journal = "ZooKeys",
    abstract = "The Late Cretaceous was a time of tremendous global change, as the final stages of the Age of Dinosaurs were shaped by climate and sea level fluctuations and witness to marked paleogeographic and faunal changes, before the end-Cretaceous bolide impact. The terrestrial fossil record of Late Cretaceous Europe is becoming increasingly better understood, based largely on intensive fieldwork over the past two decades, promising new insights into latest Cretaceous faunal evolution. We review the terrestrial Late Cretaceous record from Europe and discuss its importance for understanding the paleogeography, ecology, evolution, and extinction of land-dwelling vertebrates. We review the major Late Cretaceous faunas from Austria, Hungary, France, Spain, Portugal, and Romania, as well as more fragmentary records from elsewhere in Europe. We discuss the paleogeographic background and history of assembly of these faunas, and argue that they are comprised of an endemic 'core' supplemented with various immigration waves. These faunas lived on an island archipelago, and we describe how this insular setting led to ecological peculiarities such as low diversity, a preponderance of primitive taxa, and marked changes in morphology (particularly body size dwarfing). We conclude by discussing the importance of the European record in understanding the end-Cretaceous extinction and show that there is no clear evidence that dinosaurs or other groups were undergoing long-term declines in Europe prior to the bolide impact.",
    url = "https://doi.org/10.3897/zookeys.469.8439",
    doi = "10.3897/zookeys.469.8439",
    openalex = "W2133891947",
    references = "apesteguía2011tunasniyoj, doi101002mmng20010040112, doi101006cres20000236, doi101007s0001500812473, doi101007s0011401209171, doi101016004019518690199x, doi101016jcretres200802004, doi101016jearscirev201009005, doi101016jearscirev201203002, doi101016jgloplacha201312007, doi101016jpalaeo200412005, doi101016jpalaeo200909018, doi101016jpalaeo201206008, doi101016s0012825202000752, doi101016s1631068303000022, doi101017cbo9780511608377011, doi101017s0016756800012413, doi101017s1477201907002246, doi101038nature04633, doi101038ncomms1815, doi101038sjhdy6885841, doi101073pnas1006970107, doi101073pnas1211526110, doi101080089129632012763034, doi101080089129632013777533, doi10108010420940601006859, doi101080147720192011630927, doi101098rspb20090229, doi101111brv12128, doi101111j10963642200900617x, doi101111j10963642201000642x, doi101111j13652699200501314x, doi101111j136531211990tb00103x, doi101126science23547931156, doi1011302014250315, doi101139e72031, doi101139e93176, doi101144gsljgs1934090010405, doi101146annurevearth31100901141308, doi1012067481, doi101371journalpbio0040321, doi101371journalpone0012292, doi101371journalpone0020011, doi101371journalpone0044318, doi101371journalpone0054991, doi101371journalpone0072579, doi101371journalpone0080405, doi101525california97805202420980030015, doi10166612041, doi10167102724634200727931dtftco20co2, doi1016710390290428, doi103090610262296200073181198, doi104202app20120121, doi105860choice435902, doi105860choice514447, doi105962bhltitle59991, doi105962bhltitle68064, garilli2009first, lehman1987late, leloeuff1994the, martinsander2006bone, openalexw3015256845, openalexw51761775"
}

Tyrannosauroids--the group of carnivores including Tyrannosaurs rex--are some of the most familiar dinosaurs of all. A surge of recent discoveries has helped clarify some aspects of their evolution, but competing phylogenetic hypotheses raise questions about their relationships, biogeography, and fossil record quality. We present a new phylogenetic dataset, which merges published datasets and incorporates recently discovered taxa. We analyze it with parsimony and, for the first time for a tyrannosauroid dataset, Bayesian techniques. The parsimony and Bayesian results are highly congruent, and provide a framework for interpreting the biogeography and evolutionary history of tyrannosauroids. Our phylogenies illustrate that the body plan of the colossal species evolved piecemeal, imply no clear division between northern and southern species in western North America as had been argued, and suggest that T. rex may have been an Asian migrant to North America. Over-reliance on cranial shape characters may explain why published parsimony studies have diverged and filling three major gaps in the fossil record holds the most promise for future work.

@article{doi101038srep20252,
    author = "Brusatte, Stephen L. and Carr, Thomas D.",
    title = "The phylogeny and evolutionary history of tyrannosauroid dinosaurs",
    year = "2016",
    journal = "Scientific Reports",
    abstract = "Tyrannosauroids--the group of carnivores including Tyrannosaurs rex--are some of the most familiar dinosaurs of all. A surge of recent discoveries has helped clarify some aspects of their evolution, but competing phylogenetic hypotheses raise questions about their relationships, biogeography, and fossil record quality. We present a new phylogenetic dataset, which merges published datasets and incorporates recently discovered taxa. We analyze it with parsimony and, for the first time for a tyrannosauroid dataset, Bayesian techniques. The parsimony and Bayesian results are highly congruent, and provide a framework for interpreting the biogeography and evolutionary history of tyrannosauroids. Our phylogenies illustrate that the body plan of the colossal species evolved piecemeal, imply no clear division between northern and southern species in western North America as had been argued, and suggest that T. rex may have been an Asian migrant to North America. Over-reliance on cranial shape characters may explain why published parsimony studies have diverged and filling three major gaps in the fossil record holds the most promise for future work.",
    url = "https://doi.org/10.1038/srep20252",
    doi = "10.1038/srep20252",
    openalex = "W2327114096",
    references = "doi101007bf01734359, doi101007s001140090614x, doi101016b9781483232102500066, doi101016b9781483232119500097, doi101016jcretres201103005, doi101016jcretres201304001, doi101016jcub201408034, doi101038nature04511, doi101038nature10906, doi101038ncomms4788, doi10108001621459199510476572, doi101080106351501753462876, doi10108010635150490264699, doi10108010635150600755396, doi101080147720192011630927, doi101093sysbiosys029, doi101111j10960031200800217x, doi101111j10963642200400130x, doi101111j10963642200900591x, doi101111j10963642200900617x, doi101126science1193304, doi10120637172, doi101371journalpbio1001853, doi101371journalpone0021376, doi101371journalpone0079420, doi105860choice393984"
}

Identification of the ontogenetic status of an extinct organism is complex, and yet this underpins major areas of research, from taxonomy and systematics to ecology and evolution. In the case of the non-avialan dinosaurs, at least some were reproductively mature before they were skeletally mature, and a lack of consensus on how to define an 'adult' animal causes problems for even basic scientific investigations. Here we review the current methods available to determine the age of non-avialan dinosaurs, discuss the definitions of different ontogenetic stages, and summarize the implications of these disparate definitions for dinosaur palaeontology. Most critically, a growing body of evidence suggests that many dinosaurs that would be considered 'adults' in a modern-day field study are considered 'juveniles' or 'subadults' in palaeontological contexts.

@article{doi101098rsbl20150947,
    author = "Hone, David W. E. and Farke, Andrew A. and Wedel, Matt",
    title = "Ontogeny and the fossil record: what, if anything, is an adult dinosaur?",
    year = "2016",
    journal = "Biology Letters",
    abstract = "Identification of the ontogenetic status of an extinct organism is complex, and yet this underpins major areas of research, from taxonomy and systematics to ecology and evolution. In the case of the non-avialan dinosaurs, at least some were reproductively mature before they were skeletally mature, and a lack of consensus on how to define an 'adult' animal causes problems for even basic scientific investigations. Here we review the current methods available to determine the age of non-avialan dinosaurs, discuss the definitions of different ontogenetic stages, and summarize the implications of these disparate definitions for dinosaur palaeontology. Most critically, a growing body of evidence suggests that many dinosaurs that would be considered 'adults' in a modern-day field study are considered 'juveniles' or 'subadults' in palaeontological contexts.",
    url = "https://doi.org/10.1098/rsbl.2015.0947",
    doi = "10.1098/rsbl.2015.0947",
    openalex = "W2279103404",
    references = "carr1999craniofacial, doi101007s0001501000242, doi101017pab201519, doi10103835086558, doi101038nature04633, doi101073pnas0708903105, doi101073pnas1313334111, doi10108002724634199610011283, doi10108002724634199910011161, doi101080027246342010483632, doi101093sysbio24137, doi101098rsbl20070254, doi101111j109636421997tb00340x, doi101111j15023931201100300x, doi101146annurevearth060313054858, doi101371journalpone0021376, doi1016660094837320010270039coosea20co2, doi1016660094837320040300253chopom20co2, doi1016660094837320080340247ositlb20co2, doi1016690883135120010160482ttoaco20co2, doi1016710272463420000200115lbhoth20co2, doi10167102724634200727350asoitp20co2, doi1016710390290119, doi1023071564148, erickson2014on, martinsander2006bone"
}

@article{longrich2016a,
    author = "Longrich, Nicholas R.",
    title = "A ceratopsian dinosaur from the Late Cretaceous of eastern North America, and implications for dinosaur biogeography",
    year = "2016",
    journal = "Cretaceous Research",
    url = "https://doi.org/10.1016/j.cretres.2015.08.004",
    doi = "10.1016/j.cretres.2015.08.004",
    openalex = "W1812778731",
    pages = "199-207",
    volume = "57",
    references = "doi10103826886, doi101073pnas1211526110, doi10108010635150500481390, doi101093nqs5vi146318i, doi101098rspb20063566, doi101111j174966321940tb57047x, doi101119112007, doi101139e72031, doi107312kiel11918, openalexw597685939"
}

@article{doi101038nature21700,
    author = "Baron, Matthew G. and Norman, David and Barrett, Paul M.",
    title = "A new hypothesis of dinosaur relationships and early dinosaur evolution",
    year = "2017",
    journal = "Nature",
    url = "https://doi.org/10.1038/nature21700",
    doi = "10.1038/nature21700",
    openalex = "W2601753892",
    references = "doi101016jearscirev201004001, doi101017s1477201906001970, doi101017s1477201907002271, doi101017s1755691013000431, doi101017s247526300000091x, doi101080027246342013820113, doi101080147720192010484650, doi101098rspb20110410, doi101098rspl18870117, doi101111j109583121965tb00944x, doi101111j10960031200800217x, doi101111j10963642200900569x, doi1012063521, doi101525california97805202420980010001, doi1023071292217, doi102475ajss319111253, doi105281zenodo16120887, doi105281zenodo16171435, nesbitt2009a, openalexw3215057009"
}

During their long evolutionary history, neornithischian dinosaurs diverged into several clades with distinctive adaptations. However, the early evolution within Neornithischia and the resolution of the phylogenetic relationships of taxa situated near the base of the clade remain problematic. This is especially true for those taxa traditionally placed at the base of Ornithopoda, either as ‘hypsilophodontids’ or at the base of the diverse clade Iguanodontia. Recent studies are improving our understanding of the anatomy and relationships of these taxa, with discoveries of several new non-ankylopollexian ornithopods from South America and Europe providing key insights into early ornithopod evolution and palaeobiogeography. Here, we describe a new basal ornithopod, Burianosaurus augustai gen. et sp. nov., based on a well-preserved femur from the upper Cenomanian strata (Korycany Beds of the Peruc-Korycany Formation) of the Czech Republic. The new taxon is diagnosed by a unique suite of characters and represents the only occurrence of a Cenomanian non-avian dinosaur in Central Europe north of the Alpine Tethyan areas. Histological examination of the type specimen reveals the presence of a loosely packed Haversian system which suggests relatively mature bone from a possible young adult. Phylogenetic analyses of two different data sets, selected to test the placement of B. augustai in various parts of the neornithischian tree, reconstruct B. augustai as a basal ornithopod, firmly nested outside Ankylopollexia. These results also support a diverse Elasmaria as a basal clade within Ornithopoda and reconstruct Hypsilophodon outside Ornithopoda as the sister taxon to Cerapoda. However, the relationships of ‘hypsilophodontids’ within Neornithischia remain contentious.http://zoobank.org/urn:lsid:zoobank.org:pub:D28A9FB8-A253-4032-8710-4F51668A1E4F

@article{doi1010801477201920171371258,
    author = "Madzia, Daniel and Boyd, Clint and Mazuch, Martin",
    title = "A basal ornithopod dinosaur from the Cenomanian of the Czech Republic",
    year = "2017",
    journal = "Journal of Systematic Palaeontology",
    abstract = "During their long evolutionary history, neornithischian dinosaurs diverged into several clades with distinctive adaptations. However, the early evolution within Neornithischia and the resolution of the phylogenetic relationships of taxa situated near the base of the clade remain problematic. This is especially true for those taxa traditionally placed at the base of Ornithopoda, either as ‘hypsilophodontids’ or at the base of the diverse clade Iguanodontia. Recent studies are improving our understanding of the anatomy and relationships of these taxa, with discoveries of several new non-ankylopollexian ornithopods from South America and Europe providing key insights into early ornithopod evolution and palaeobiogeography. Here, we describe a new basal ornithopod, Burianosaurus augustai gen. et sp. nov., based on a well-preserved femur from the upper Cenomanian strata (Korycany Beds of the Peruc-Korycany Formation) of the Czech Republic. The new taxon is diagnosed by a unique suite of characters and represents the only occurrence of a Cenomanian non-avian dinosaur in Central Europe north of the Alpine Tethyan areas. Histological examination of the type specimen reveals the presence of a loosely packed Haversian system which suggests relatively mature bone from a possible young adult. Phylogenetic analyses of two different data sets, selected to test the placement of B. augustai in various parts of the neornithischian tree, reconstruct B. augustai as a basal ornithopod, firmly nested outside Ankylopollexia. These results also support a diverse Elasmaria as a basal clade within Ornithopoda and reconstruct Hypsilophodon outside Ornithopoda as the sister taxon to Cerapoda. However, the relationships of ‘hypsilophodontids’ within Neornithischia remain contentious.http://zoobank.org/urn:lsid:zoobank.org:pub:D28A9FB8-A253-4032-8710-4F51668A1E4F",
    url = "https://doi.org/10.1080/14772019.2017.1371258",
    doi = "10.1080/14772019.2017.1371258",
    openalex = "W2760542243",
    references = "doi101017s1477201903001032, doi101017s1477201907002271, doi101080027246342013746229, doi101098rspl18870117, doi101111j10963642200900617x, doi101111zoj12193, doi101126science1253351, doi101126science28454232137, doi101127njgpa210199841, doi101371journalpone0014075, doi102307jctt1zxz1md6, doi103897zookeys4698439, doi105962p313819, doi107717peerj1523, openalexw2173200745, openalexw225597919"
}

Interbasinal stratigraphic correlation provides the foundation for all consequent continental-scale geological and paleontological analyses. Correlation requires synthesis of lithostratigraphic, biostratigraphic and geochronologic data, and must be periodically updated to accord with advances in dating techniques, changing standards for radiometric dates, new stratigraphic concepts, hypotheses, fossil specimens, and field data. Outdated or incorrect correlation exposes geological and paleontological analyses to potential error. The current work presents a high-resolution stratigraphic chart for terrestrial Late Cretaceous units of North America, combining published chronostratigraphic, lithostratigraphic, and biostratigraphic data. 40Ar / 39Ar radiometric dates are newly recalibrated to both current standard and decay constant pairings. Revisions to the stratigraphic placement of most units are slight, but important changes are made to the proposed correlations of the Aguja and Javelina formations, Texas, and recalibration corrections in particular affect the relative age positions of the Belly River Group, Alberta; Judith River Formation, Montana; Kaiparowits Formation, Utah; and Fruitland and Kirtland formations, New Mexico. The stratigraphic ranges of selected clades of dinosaur species are plotted on the chronostratigraphic framework, with some clades comprising short-duration species that do not overlap stratigraphically with preceding or succeeding forms. This is the expected pattern that is produced by an anagenetic mode of evolution, suggesting that true branching (speciation) events were rare and may have geographic significance. The recent hypothesis of intracontinental latitudinal provinciality of dinosaurs is shown to be affected by previous stratigraphic miscorrelation. Rapid stepwise acquisition of display characters in many dinosaur clades, in particular chasmosaurine ceratopsids, suggests that they may be useful for high resolution biostratigraphy.

@article{doi101371journalpone0188426,
    author = "Fowler, Denver Warwick",
    title = "Revised geochronology, correlation, and dinosaur stratigraphic ranges of the Santonian-Maastrichtian (Late Cretaceous) formations of the Western Interior of North America.",
    year = "2017",
    journal = "PloS one",
    abstract = "Interbasinal stratigraphic correlation provides the foundation for all consequent continental-scale geological and paleontological analyses. Correlation requires synthesis of lithostratigraphic, biostratigraphic and geochronologic data, and must be periodically updated to accord with advances in dating techniques, changing standards for radiometric dates, new stratigraphic concepts, hypotheses, fossil specimens, and field data. Outdated or incorrect correlation exposes geological and paleontological analyses to potential error. The current work presents a high-resolution stratigraphic chart for terrestrial Late Cretaceous units of North America, combining published chronostratigraphic, lithostratigraphic, and biostratigraphic data. 40Ar / 39Ar radiometric dates are newly recalibrated to both current standard and decay constant pairings. Revisions to the stratigraphic placement of most units are slight, but important changes are made to the proposed correlations of the Aguja and Javelina formations, Texas, and recalibration corrections in particular affect the relative age positions of the Belly River Group, Alberta; Judith River Formation, Montana; Kaiparowits Formation, Utah; and Fruitland and Kirtland formations, New Mexico. The stratigraphic ranges of selected clades of dinosaur species are plotted on the chronostratigraphic framework, with some clades comprising short-duration species that do not overlap stratigraphically with preceding or succeeding forms. This is the expected pattern that is produced by an anagenetic mode of evolution, suggesting that true branching (speciation) events were rare and may have geographic significance. The recent hypothesis of intracontinental latitudinal provinciality of dinosaurs is shown to be affected by previous stratigraphic miscorrelation. Rapid stepwise acquisition of display characters in many dinosaur clades, in particular chasmosaurine ceratopsids, suggests that they may be useful for high resolution biostratigraphy.",
    url = "https://pmc.ncbi.nlm.nih.gov/articles/PMC5699823/",
    doi = "10.1371/journal.pone.0188426",
    openalex = "W2544476050",
    pmcid = "PMC5699823",
    pmid = "29166406",
    references = "doi1010160012821x77900607, doi101016016896228790025x, doi101016037594749090598g, doi101016jgca201006017, doi101016jgca201106021, doi101016jsedgeo200610001, doi101016s0009254197001599, doi101016s0016703799002045, doi101016s0375947497006131, doi101126science1154339, doi101130001676061952631011cotcfo20co2, doi101130b310761, doi101139e93016, doi101371journalpone0012292, doi101371journalpone0024487, doi101371journalpone0025186, doi101371journalpone0141304, doi10167102724634200727373aarolm20co2, doi105860choice514447, lehman1987late, openalexw2025327988"
}

@article{doi101038s4155901704546,
    author = "O’Donovan, Ciara and Meade, Andrew and Venditti, Chris",
    title = "Dinosaurs reveal the geographical signature of an evolutionary radiation",
    year = "2018",
    journal = "Nature Ecology \& Evolution",
    url = "https://doi.org/10.1038/s41559-017-0454-6",
    doi = "10.1038/s41559-017-0454-6",
    openalex = "W2785844442",
    references = "doi101371journalpone0012553, longrich2016a"
}

The Late Jurassic Tendaguru Formation of Tanzania, southeastern Africa, records a diverse and abundant sauropod fauna, including the flagellicaudatan diplodocoids Dicraeosaurus and Tornieria, and the brachiosaurid titanosauriform Giraffatitan. However, the taxonomic affinities of other sympatric sauropod taxa and remains are poorly understood. Here, we critically reassess and redescribe these problematic taxa, and present the largest phylogenetic analysis for sauropods (117 taxa scored for 542 characters) to explore their placement within Eusauropoda. A full re-description of the holotype of Janenschia, and all referable remains, supports its validity and placement as a nonneosauropod eusauropod. New information on the internal pneumatic tissue structure of the anterior dorsal vertebrae of the enigmatic Tendaguria tanzaniensis, coupled with a full re-description, results in its novel placement as a turiasaur. A previously referred caudal sequence cannot be assigned to Janenschia and displays several features that indicate a close relationship with Middle–Late Jurassic East Asian mamenchisaurids. It can be diagnosed by six autapomorphies, and we erect the new taxon Wamweracaudia keranjei n. gen. n. sp. The Tendaguru Formation shares representatives of nearly all sauropod lineages with Middle Jurassic–earliest Cretaceous global faunas, but displays a greater range of diversity than any of those faunas considered individually.

@article{doi101093zoolinneanzly068,
    author = "Mannion, Philip D. and Upchurch, Paul and Schwarz, Daniela and Wings, Oliver",
    title = "Taxonomic affinities of the putative titanosaurs from the Late Jurassic Tendaguru Formation of Tanzania: phylogenetic and biogeographic implications for eusauropod dinosaur evolution",
    year = "2018",
    journal = "Zoological Journal of the Linnean Society",
    abstract = "The Late Jurassic Tendaguru Formation of Tanzania, southeastern Africa, records a diverse and abundant sauropod fauna, including the flagellicaudatan diplodocoids Dicraeosaurus and Tornieria, and the brachiosaurid titanosauriform Giraffatitan. However, the taxonomic affinities of other sympatric sauropod taxa and remains are poorly understood. Here, we critically reassess and redescribe these problematic taxa, and present the largest phylogenetic analysis for sauropods (117 taxa scored for 542 characters) to explore their placement within Eusauropoda. A full re-description of the holotype of Janenschia, and all referable remains, supports its validity and placement as a nonneosauropod eusauropod. New information on the internal pneumatic tissue structure of the anterior dorsal vertebrae of the enigmatic Tendaguria tanzaniensis, coupled with a full re-description, results in its novel placement as a turiasaur. A previously referred caudal sequence cannot be assigned to Janenschia and displays several features that indicate a close relationship with Middle–Late Jurassic East Asian mamenchisaurids. It can be diagnosed by six autapomorphies, and we erect the new taxon Wamweracaudia keranjei n. gen. n. sp. The Tendaguru Formation shares representatives of nearly all sauropod lineages with Middle Jurassic–earliest Cretaceous global faunas, but displays a greater range of diversity than any of those faunas considered individually.",
    url = "https://doi.org/10.1093/zoolinnean/zly068",
    doi = "10.1093/zoolinnean/zly068",
    openalex = "W2911482806",
    references = "doi101002mmng19994860020102, doi101002mmng19994860020109, doi101002mmng200900004, doi101016jcretres201603008, doi101016jearscirev201203002, doi101016jgr201403014, doi101017s0016756804000330, doi101038ncomms3929, doi101038s41467018051281, doi101038srep19165, doi101038srep34467, doi101080027246342011557116, doi101080027246342012671204, doi101080027246342013776562, doi101093sysbiosyu056, doi101093zoolinneanzlx103, doi101098rspb20120660, doi101098rspb20171219, doi101111cla12160, doi101111j10960031200800217x, doi101111j10963642201000620x, doi101111pala12142, doi101111zoj12029, doi101111zoj12425, doi101144001676492006032, doi101371journalpone0006924, doi101371journalpone0017114, doi101371journalpone0037122, doi101371journalpone0079420, doi101371journalpone0125819, doi1018814epiiugs2013v36i3002, doi1021425f55419694, doi1022179revmacn7344, doi1023073802723, doi1026879529, doi10274700206814489791, doi105281zenodo16171435, doi105710amegh261210131889, doi105860choice331556, doi107717peerj857, heinrich1998late, openalexw1545181283"
}

@incollection{dupuisdésormeaux2018biogeography,
    author = "Dupuis-Désormeaux, Marc",
    title = "Biogeography",
    year = "2018",
    booktitle = "Encyclopedia of Animal Cognition and Behavior",
    url = "https://doi.org/10.1007/978-3-319-47829-6\_397-1",
    doi = "10.1007/978-3-319-47829-6\_397-1",
    pages = "1-3"
}

@article{doi101016jcub201905076,
    author = "Melstrom, Keegan M. and Irmis, Randall B.",
    title = "Repeated Evolution of Herbivorous Crocodyliforms during the Age of Dinosaurs",
    year = "2019",
    journal = "Current Biology",
    url = "https://doi.org/10.1016/j.cub.2019.05.076",
    doi = "10.1016/j.cub.2019.05.076",
    openalex = "W2955898298",
    references = "doi101080089129632013777533, doi101371journalpone0093105, doi103897zookeys4698439"
}

@article{doi101016jcub201910050,
    author = "Button, David J. and Zanno, Lindsay E.",
    title = "Repeated Evolution of Divergent Modes of Herbivory in Non-avian Dinosaurs",
    year = "2019",
    journal = "Current Biology",
    url = "https://doi.org/10.1016/j.cub.2019.10.050",
    doi = "10.1016/j.cub.2019.10.050",
    openalex = "W2993362957",
    references = "doi101002ar23306, doi101002ar23988, doi10100797836426953391, doi101007s0011401411439, doi101007s0042701605392, doi101016jcub201609040, doi101016jcub201610043, doi101016jpalaeo201803006, doi101038nature24679, doi101038ncomms3827, doi101038srep19165, doi101038srep44942, doi101073pnas1310711110, doi101073pnas1319091111, doi10108002724631003763516, doi101080147720192010488045, doi1010801477201920151059985, doi101086414425, doi101093bioinformatics176520, doi101093bioinformaticsbtg180, doi101093bioinformaticsbtm069, doi101098rsos161086, doi101098rspb20110410, doi101098rspb20122526, doi101098rspb20171219, doi101111j2041210x201100169x, doi101371journalpone0078573, doi101371journalpone0079420, doi101371journalpone0092022, doi101371journalpone0098605, doi101371journalpone0112055, doi1017161paleo180818764, doi102307jctvjsf433, doi105281zenodo13315375, doi105860choice396411, doi107717peerj1032, doi107717peerj1523, openalexw2282537990"
}

Titanosaurs were a globally distributed clade of Cretaceous sauropods. Historically regarded as a primarily Gondwanan radiation, there is a growing number of Eurasian taxa, with several putative titanosaurs contemporaneous with, or even pre-dating, the oldest known Southern Hemisphere remains. The early Late Cretaceous Jinhua Formation, in Zhejiang Province, China, has yielded two putative titanosaurs, Jiangshanosaurus lixianensis and Dongyangosaurus sinensis. Here, we provide a detailed re-description and diagnosis of Jiangshanosaurus, as well as new anatomical information on Dongyangosaurus. Previously, a 'derived' titanosaurian placement for Jiangshanosaurus was primarily based on the presence of procoelous anterior caudal centra. We show that this taxon had amphicoelous anterior-middle caudal centra. Its only titanosaurian synapomorphy is that the dorsal margins of the scapula and coracoid are approximately level with one another. Dongyangosaurus can clearly be differentiated from Jiangshanosaurus, and displays features that indicate a closer relationship to the titanosaur radiation. Revised scores for both taxa are incorporated into an expanded phylogenetic data matrix, comprising 124 taxa scored for 548 characters. Under equal weights parsimony, Jiangshanosaurus is recovered as a member of the non-titanosaurian East Asian somphospondylan clade Euhelopodidae, and Dongyangosaurus lies just outside of Titanosauria. However, when extended implied weighting is applied, both taxa are placed within Titanosauria. Most other 'middle' Cretaceous East Asian sauropods are probably non-titanosaurian somphospondylans, but at least Xianshanosaurus appears to belong to the titanosaur radiation. Our analyses also recover the Early Cretaceous European sauropod Normanniasaurus genceyi as a 'derived' titanosaur, clustering with Gondwanan taxa. These results provide further support for a widespread diversification of titanosaurs by at least the Early Cretaceous.

@article{doi101098rsos191057,
    author = "Mannion, Philip D. and Upchurch, Paul and Jin, Xingsheng and Zheng, Wenjie",
    title = "New information on the Cretaceous sauropod dinosaurs of Zhejiang Province, China: impact on Laurasian titanosauriform phylogeny and biogeography",
    year = "2019",
    journal = "Royal Society Open Science",
    abstract = "Titanosaurs were a globally distributed clade of Cretaceous sauropods. Historically regarded as a primarily Gondwanan radiation, there is a growing number of Eurasian taxa, with several putative titanosaurs contemporaneous with, or even pre-dating, the oldest known Southern Hemisphere remains. The early Late Cretaceous Jinhua Formation, in Zhejiang Province, China, has yielded two putative titanosaurs, Jiangshanosaurus lixianensis and Dongyangosaurus sinensis. Here, we provide a detailed re-description and diagnosis of Jiangshanosaurus, as well as new anatomical information on Dongyangosaurus. Previously, a 'derived' titanosaurian placement for Jiangshanosaurus was primarily based on the presence of procoelous anterior caudal centra. We show that this taxon had amphicoelous anterior-middle caudal centra. Its only titanosaurian synapomorphy is that the dorsal margins of the scapula and coracoid are approximately level with one another. Dongyangosaurus can clearly be differentiated from Jiangshanosaurus, and displays features that indicate a closer relationship to the titanosaur radiation. Revised scores for both taxa are incorporated into an expanded phylogenetic data matrix, comprising 124 taxa scored for 548 characters. Under equal weights parsimony, Jiangshanosaurus is recovered as a member of the non-titanosaurian East Asian somphospondylan clade Euhelopodidae, and Dongyangosaurus lies just outside of Titanosauria. However, when extended implied weighting is applied, both taxa are placed within Titanosauria. Most other 'middle' Cretaceous East Asian sauropods are probably non-titanosaurian somphospondylans, but at least Xianshanosaurus appears to belong to the titanosaur radiation. Our analyses also recover the Early Cretaceous European sauropod Normanniasaurus genceyi as a 'derived' titanosaur, clustering with Gondwanan taxa. These results provide further support for a widespread diversification of titanosaurs by at least the Early Cretaceous.",
    url = "https://doi.org/10.1098/rsos.191057",
    doi = "10.1098/rsos.191057",
    openalex = "W2970495169",
    references = "doi101016jcretres201603008, doi101016jgr201403014, doi101016jjsames201411008, doi101016jpalaeo201206008, doi101038srep34467, doi101080027246342012671204, doi101093zoolinneanzlx103, doi101093zoolinneanzly068, doi101098rspb20171219, doi101111brv12255, doi1011646zootaxa384811, doi101371journalpone0125819, doi103897zookeys4698439"
}

The non-marine Horseshoe Canyon Formation (HCFm, southern Alberta) yields taxonomically diverse, late Campanian to middle Maastrichtian dinosaur assemblages that play a central role in documenting dinosaur evolution, paleoecology, and paleobiogeography leading up to the end-Cretaceous extinction. Here, we present high-precision U–Pb CA–ID–TIMS ages and the first calibrated chronostratigraphy for the HCFm using zircon grains from (1) four HCFm bentonites distributed through 129 m of section, (2) one bentonite from the underlying Bearpaw Formation, and (3) a bentonite from the overlying Battle Formation that we dated previously. In its type area, the HCFm ranges in age from 73.1–68.0 Ma. Significant paleoenvironmental and climatic changes are recorded in the formation, including (1) a transition from a warm-and-wet deltaic setting to a cooler, seasonally wet-dry coastal plain at 71.5 Ma, (2) maximum transgression of the Drumheller Marine Tongue at 70.896 ± 0.048 Ma, and (3) transition to a warm-wet alluvial plain at 69.6 Ma. The HCFm’s three mega-herbivore dinosaur assemblage zones track these changes and are calibrated as follows: Edmontosaurus regalis – Pachyrhinosaurus canadensis zone, 73.1–71.5 Ma; Hypacrosaurus altispinus – Saurolophus osborni zone, 71.5–69.6 Ma; and Eotriceratops xerinsularis zone, 69.6–68.2 Ma. The Albertosaurus Bonebed — a monodominant assemblage of tyrannosaurids in the Tolman Member — is assessed an age of 70.1 Ma. The unusual triceratopsin, Eotriceratops xerinsularis, from the Carbon Member, is assessed an age of 68.8 Ma. This chronostratigraphy is useful for refining correlations with dinosaur-bearing upper Campanian–middle Maastrichtian units in Alberta and elsewhere in North America.

@article{doi101139cjes20190019,
    author = "Eberth, David A. and Kamo, Sandra L.",
    title = "High-precision U–Pb CA–ID–TIMS dating and chronostratigraphy of the dinosaur-rich Horseshoe Canyon Formation (Upper Cretaceous, Campanian–Maastrichtian), Red Deer River valley, Alberta, Canada",
    year = "2019",
    journal = "Canadian Journal of Earth Sciences",
    abstract = "The non-marine Horseshoe Canyon Formation (HCFm, southern Alberta) yields taxonomically diverse, late Campanian to middle Maastrichtian dinosaur assemblages that play a central role in documenting dinosaur evolution, paleoecology, and paleobiogeography leading up to the end-Cretaceous extinction. Here, we present high-precision U–Pb CA–ID–TIMS ages and the first calibrated chronostratigraphy for the HCFm using zircon grains from (1) four HCFm bentonites distributed through 129 m of section, (2) one bentonite from the underlying Bearpaw Formation, and (3) a bentonite from the overlying Battle Formation that we dated previously. In its type area, the HCFm ranges in age from 73.1–68.0 Ma. Significant paleoenvironmental and climatic changes are recorded in the formation, including (1) a transition from a warm-and-wet deltaic setting to a cooler, seasonally wet-dry coastal plain at 71.5 Ma, (2) maximum transgression of the Drumheller Marine Tongue at 70.896 ± 0.048 Ma, and (3) transition to a warm-wet alluvial plain at 69.6 Ma. The HCFm’s three mega-herbivore dinosaur assemblage zones track these changes and are calibrated as follows: Edmontosaurus regalis – Pachyrhinosaurus canadensis zone, 73.1–71.5 Ma; Hypacrosaurus altispinus – Saurolophus osborni zone, 71.5–69.6 Ma; and Eotriceratops xerinsularis zone, 69.6–68.2 Ma. The Albertosaurus Bonebed — a monodominant assemblage of tyrannosaurids in the Tolman Member — is assessed an age of 70.1 Ma. The unusual triceratopsin, Eotriceratops xerinsularis, from the Carbon Member, is assessed an age of 68.8 Ma. This chronostratigraphy is useful for refining correlations with dinosaur-bearing upper Campanian–middle Maastrichtian units in Alberta and elsewhere in North America.",
    url = "https://doi.org/10.1139/cjes-2019-0019",
    doi = "10.1139/cjes-2019-0019",
    openalex = "W2979872101",
    references = "andeberth2016new, doi101007springerreference4923, doi1010160016703773902135, doi101016jchemgeo200503011, doi101016jgca200509007, doi101016jgca201006017, doi101016s0009254196000332, doi101016s0195667105800308, doi101073pnas1313334111, doi101103physrevc41889, doi101126science1154339, doi101126science1230492, doi101139cjes20120185, doi101371journalpone0188426, doi104202app20110033, doi105860choice435902, openalexw2989049194"
}

This work attempts at providing a revised framework for ornithischian phylogeny, based on an exhaustive data compilation of already published analyses, a critical re-evaluation of osteological characters and an in-depth checking of characters scoring to fix mistakes that have accumulated in previous analyses; we have also included recently described basal ornithischians, marginocephalians and ornithopods. ‘Heterodontosaurids’ are recovered as a paraphyletic group of basal Marginocephalia that progressively lead to the dome-headed ‘true’ pachycephalosaurs. ‘Heterodontosaurids’ consequently fall within Pachycephalosauria sensu Sereno, 1998. The reconfiguration of basal cerapodan relationships pulls the origins of ornithopods to the earliest stages of the Jurassic. Based on the present analysis, we also discuss ornithopod relationships, with a particular focus on basal Iguanodontia. Tenontosaurus is found as the basalmost iguanodontian. The monophyly of Rhabdodontomorpha in a position more derived than Tenontosaurus is supported by the present analysis.

@article{doi1010800891296320201793979,
    author = "Dieudonné, Paul-Émile and Cruzado‐Caballero, Penélope and Godefroit, Pascal and Tortosa, Thierry",
    title = "A new phylogeny of cerapodan dinosaurs",
    year = "2020",
    journal = "Historical Biology",
    abstract = "This work attempts at providing a revised framework for ornithischian phylogeny, based on an exhaustive data compilation of already published analyses, a critical re-evaluation of osteological characters and an in-depth checking of characters scoring to fix mistakes that have accumulated in previous analyses; we have also included recently described basal ornithischians, marginocephalians and ornithopods. ‘Heterodontosaurids’ are recovered as a paraphyletic group of basal Marginocephalia that progressively lead to the dome-headed ‘true’ pachycephalosaurs. ‘Heterodontosaurids’ consequently fall within Pachycephalosauria sensu Sereno, 1998. The reconfiguration of basal cerapodan relationships pulls the origins of ornithopods to the earliest stages of the Jurassic. Based on the present analysis, we also discuss ornithopod relationships, with a particular focus on basal Iguanodontia. Tenontosaurus is found as the basalmost iguanodontian. The monophyly of Rhabdodontomorpha in a position more derived than Tenontosaurus is supported by the present analysis.",
    url = "https://doi.org/10.1080/08912963.2020.1793979",
    doi = "10.1080/08912963.2020.1793979",
    openalex = "W3044772036",
    references = "doi101007bf02988144, doi101016jcub201910050, doi101017s1755691013000431, doi101038nature21700, doi101080027246342011606857, doi101080027246342012694385, doi101080027246342013746229, doi1010801477201920171371258, doi101086383584, doi101093sysbio274401, doi101111cla12160, doi101111j10960031200800217x, doi101111j10963642200900631x, doi101111j155856461983tb05533x, doi101139e11017, doi101144sp37916, doi101371journalpone0014075, doi101371journalpone0044318, doi1018814epiiugs2013v36i3002, doi1023072408332, doi1023072412923, doi105281zenodo16171435, doi107717peerj1523, openalexw1535663436, openalexw597685939"
}

The independent evolution of gigantism among dinosaurs has been a topic of long-standing interest, but it remains unclear if gigantic theropods, the largest bipeds in the fossil record, all achieved massive sizes in the same manner, or through different strategies. We perform multi-element histological analyses on a phylogenetically broad dataset sampled from eight theropod families, with a focus on gigantic tyrannosaurids and carcharodontosaurids, to reconstruct the growth strategies of these lineages and test if particular bones consistently preserve the most complete growth record. We find that in skeletally mature gigantic theropods, weight-bearing bones consistently preserve extensive growth records, whereas non-weight-bearing bones are remodelled and less useful for growth reconstruction, contrary to the pattern observed in smaller theropods and some other dinosaur clades. We find a heterochronic pattern of growth fitting an acceleration model in tyrannosaurids, with allosauroid carcharodontosaurids better fitting a model of hypermorphosis. These divergent growth patterns appear phylogenetically constrained, representing extreme versions of the growth patterns present in smaller coelurosaurs and allosauroids, respectively. This provides the first evidence of a lack of strong mechanistic or physiological constraints on size evolution in the largest bipeds in the fossil record and evidence of one of the longest-living individual dinosaurs ever documented.

@article{doi101098rspb20202258,
    author = "Cullen, Thomas M. and Canale, Juan I. and Apesteguı́a, Sebastián and Smith, Nathan D. and Hu, Dongyu and Makovicky, Peter J.",
    title = "Osteohistological analyses reveal diverse strategies of theropod dinosaur body-size evolution",
    year = "2020",
    journal = "Proceedings of the Royal Society B Biological Sciences",
    abstract = "The independent evolution of gigantism among dinosaurs has been a topic of long-standing interest, but it remains unclear if gigantic theropods, the largest bipeds in the fossil record, all achieved massive sizes in the same manner, or through different strategies. We perform multi-element histological analyses on a phylogenetically broad dataset sampled from eight theropod families, with a focus on gigantic tyrannosaurids and carcharodontosaurids, to reconstruct the growth strategies of these lineages and test if particular bones consistently preserve the most complete growth record. We find that in skeletally mature gigantic theropods, weight-bearing bones consistently preserve extensive growth records, whereas non-weight-bearing bones are remodelled and less useful for growth reconstruction, contrary to the pattern observed in smaller theropods and some other dinosaur clades. We find a heterochronic pattern of growth fitting an acceleration model in tyrannosaurids, with allosauroid carcharodontosaurids better fitting a model of hypermorphosis. These divergent growth patterns appear phylogenetically constrained, representing extreme versions of the growth patterns present in smaller coelurosaurs and allosauroids, respectively. This provides the first evidence of a lack of strong mechanistic or physiological constraints on size evolution in the largest bipeds in the fossil record and evidence of one of the longest-living individual dinosaurs ever documented.",
    url = "https://doi.org/10.1098/rspb.2020.2258",
    doi = "10.1098/rspb.2020.2258",
    openalex = "W3110230871",
    references = "doi101016jcub201408034, doi101017s0094837300006588, doi101017s0094837300021308, doi101029sc005p0175, doi101038nature02699, doi101038ncomms3827, doi101073pnas0708903105, doi101098rspb20122526, doi101126sciadvaax6250, doi101126science1225376, doi101126science1258750, doi101146annurevearth060313054858, doi101186174170071060, doi101186s1289801601068, doi101371journalpone0033539, doi1016710272463420000200115lbhoth20co2, doi10560219780801881206, doi105860choice490282, erickson2014on"
}

@incollection{crossref2021biogeography,
    title = "Biogeography",
    year = "2021",
    booktitle = "Operation Valhalla",
    url = "https://doi.org/10.2307/j.ctv1h7zn5g.21",
    doi = "10.2307/j.ctv1h7zn5g.21",
    pages = "227-232"
}

The question why non-avian dinosaurs went extinct 66 million years ago (Ma) remains unresolved because of the coarseness of the fossil record. A sudden extinction caused by an asteroid is the most accepted hypothesis but it is debated whether dinosaurs were in decline or not before the impact. We analyse the speciation-extinction dynamics for six key dinosaur families, and find a decline across dinosaurs, where diversification shifted to a declining-diversity pattern ~76 Ma. We investigate the influence of ecological and physical factors, and find that the decline of dinosaurs was likely driven by global climate cooling and herbivorous diversity drop. The latter is likely due to hadrosaurs outcompeting other herbivores. We also estimate that extinction risk is related to species age during the decline, suggesting a lack of evolutionary novelty or adaptation to changing environments. These results support an environmentally driven decline of non-avian dinosaurs well before the asteroid impact.

@article{doi101038s41467021237540,
    author = "Condamine, Fabien L. and Guinot, Guillaume and Benton, Michael J. and Currie, Philip J.",
    title = "Dinosaur biodiversity declined well before the asteroid impact, influenced by ecological and environmental pressures",
    year = "2021",
    journal = "Nature Communications",
    abstract = "The question why non-avian dinosaurs went extinct 66 million years ago (Ma) remains unresolved because of the coarseness of the fossil record. A sudden extinction caused by an asteroid is the most accepted hypothesis but it is debated whether dinosaurs were in decline or not before the impact. We analyse the speciation-extinction dynamics for six key dinosaur families, and find a decline across dinosaurs, where diversification shifted to a declining-diversity pattern \textasciitilde 76 Ma. We investigate the influence of ecological and physical factors, and find that the decline of dinosaurs was likely driven by global climate cooling and herbivorous diversity drop. The latter is likely due to hadrosaurs outcompeting other herbivores. We also estimate that extinction risk is related to species age during the decline, suggesting a lack of evolutionary novelty or adaptation to changing environments. These results support an environmentally driven decline of non-avian dinosaurs well before the asteroid impact.",
    url = "https://doi.org/10.1038/s41467-021-23754-0",
    doi = "10.1038/s41467-021-23754-0",
    openalex = "W3160661672",
    references = "alvarez1980extraterrestrial, close2020the, doi101016jcub202006105, doi101016jgloplacha201804004, doi101016jpalaeo201602033, doi101016jtree202009001, doi101038307360a0, doi101038nature06588, doi101038nature24679, doi101038ncomms9296, doi101038s41467019089972, doi101038s41598019517095, doi101046j14610248200200354x, doi101073pnas1521478113, doi101073pnas1902693116, doi101073pnas2006087117, doi1010801477201920151059985, doi101093sysbiosyy032, doi101098rsos161086, doi101111nph13264, doi101126sciadvaaw4486, doi101126science1059412, doi101126science1116412, doi101126science1177265, doi101126science1211028, doi101126scienceabd9220, doi101139cjes20170031, doi10120639651, doi101371journalpone0028964, doi101371journalpone0032623, doi101371journalpone0067182, doi101371journalpone0108804, doi103389feart201800252, doi107717peerj1032, doi107717peerj5749, doi107717peerj7247, doi107717peerj8672, openalexw2145250129"
}

The spectacular fossil fauna and flora preserved in the Upper Cretaceous terrestrial strata of North America's Western Interior Basin record an exceptional peak in the diversification of fossil vertebrates in the Campanian, which has been termed the 'zenith of dinosaur diversity'. The wide latitudinal distribution of rocks and fossils that represent this episode, spanning from northern Mexico to the northern slopes of Alaska, provides a unique opportunity to gain insights into dinosaur paleoecology and to address outstanding questions regarding faunal provinciality in connection to paleogeography and climate. Whereas reliable basin-wide correlations are fundamental to investigations of this sort, three decades of radioisotope geochronology of various vintages and limited compatibility has complicated correlation of distant fossil-bearing successions and given rise to contradictory paleobiogeographic and evolutionary hypotheses. Here we present new U-Pb geochronology by the CA-ID-TIMS method for 16 stratigraphically well constrained bentonite beds, ranging in age from 82.419 ± 0.074 Ma to 73.496 ± 0.039 Ma (2σ internal uncertainties), and the resulting Bayesian age models for six key fossil-bearing formations over a 1600 km latitudinal distance from northwest New Mexico, USA to southern Alberta, Canada. Our high-resolution chronostratigraphic framework for the upper Campanian of the Western Interior Basin reveals that despite their contrasting depositional settings and basin evolution histories, significant age overlap exists between the main fossil-bearing intervals of the Kaiparowits Formation (southern Utah), Judith River Formation (central Montana), Two Medicine Formation (western Montana) and Dinosaur Park Formation (southern Alberta). Pending more extensive paleontologic collecting that would allow more rigorous faunal analyses, our results support a first-order connection between paleoecologic and fossil diversities and help overcome the chronostratigraphic ambiguities that have impeded the testing of proposed models of latitudinal provinciality of dinosaur taxa during the Campanian.

@article{doi101038s4159802219896w,
    author = "Ramezani, Jahandar and Beveridge, Tegan L and Rogers, Raymond R and Eberth, David A and Roberts, Eric M",
    title = "Calibrating the zenith of dinosaur diversity in the Campanian of the Western Interior Basin by CA-ID-TIMS U-Pb geochronology.",
    year = "2022",
    journal = "Scientific reports",
    abstract = "The spectacular fossil fauna and flora preserved in the Upper Cretaceous terrestrial strata of North America's Western Interior Basin record an exceptional peak in the diversification of fossil vertebrates in the Campanian, which has been termed the 'zenith of dinosaur diversity'. The wide latitudinal distribution of rocks and fossils that represent this episode, spanning from northern Mexico to the northern slopes of Alaska, provides a unique opportunity to gain insights into dinosaur paleoecology and to address outstanding questions regarding faunal provinciality in connection to paleogeography and climate. Whereas reliable basin-wide correlations are fundamental to investigations of this sort, three decades of radioisotope geochronology of various vintages and limited compatibility has complicated correlation of distant fossil-bearing successions and given rise to contradictory paleobiogeographic and evolutionary hypotheses. Here we present new U-Pb geochronology by the CA-ID-TIMS method for 16 stratigraphically well constrained bentonite beds, ranging in age from 82.419 ± 0.074 Ma to 73.496 ± 0.039 Ma (2σ internal uncertainties), and the resulting Bayesian age models for six key fossil-bearing formations over a 1600 km latitudinal distance from northwest New Mexico, USA to southern Alberta, Canada. Our high-resolution chronostratigraphic framework for the upper Campanian of the Western Interior Basin reveals that despite their contrasting depositional settings and basin evolution histories, significant age overlap exists between the main fossil-bearing intervals of the Kaiparowits Formation (southern Utah), Judith River Formation (central Montana), Two Medicine Formation (western Montana) and Dinosaur Park Formation (southern Alberta). Pending more extensive paleontologic collecting that would allow more rigorous faunal analyses, our results support a first-order connection between paleoecologic and fossil diversities and help overcome the chronostratigraphic ambiguities that have impeded the testing of proposed models of latitudinal provinciality of dinosaur taxa during the Campanian.",
    url = "https://pmc.ncbi.nlm.nih.gov/articles/PMC9512893/",
    doi = "10.1038/s41598-022-19896-w",
    pmcid = "PMC9512893",
    pmid = "36163377"
}

Modern birds are typified by the presence of feathers, complex evolutionary innovations that were already widespread in the group of theropod dinosaurs (Maniraptoriformes) that include crown Aves. Squamous or scaly reptilian-like skin is, however, considered the plesiomorphic condition for theropods and dinosaurs more broadly. Here, we review the morphology and distribution of non-feathered integumentary structures in non-avialan theropods, covering squamous skin and naked skin as well as dermal ossifications. The integumentary record of non-averostran theropods is limited to tracks, which ubiquitously show a covering of tiny reticulate scales on the plantar surface of the pes. This is consistent also with younger averostran body fossils, which confirm an arthral arrangement of the digital pads. Among averostrans, squamous skin is confirmed in Ceratosauria (Carnotaurus), Allosauroidea (Allosaurus, Concavenator, Lourinhanosaurus), Compsognathidae (Juravenator), and Tyrannosauroidea (Santanaraptor, Albertosaurus, Daspletosaurus, Gorgosaurus, Tarbosaurus, Tyrannosaurus), whereas dermal ossifications consisting of sagittate and mosaic osteoderms are restricted to Ceratosaurus. Naked, non-scale bearing skin is found in the contentious tetanuran Sciurumimus, ornithomimosaurians (Ornithomimus) and possibly tyrannosauroids (Santanaraptor), and also on the patagia of scansoriopterygids (Ambopteryx, Yi). Scales are surprisingly conservative among non-avialan theropods compared to some dinosaurian groups (e.g. hadrosaurids); however, the limited preservation of tegument on most specimens hinders further interrogation. Scale patterns vary among and/or within body regions in Carnotaurus, Concavenator and Juravenator, and include polarised, snake-like ventral scales on the tail of the latter two genera. Unusual but more uniformly distributed patterning also occurs in Tyrannosaurus, whereas feature scales are present only in Albertosaurus and Carnotaurus. Few theropods currently show compelling evidence for the co-occurrence of scales and feathers (e.g. Juravenator, Sinornithosaurus), although reticulate scales were probably retained on the mani and pedes of many theropods with a heavy plumage. Feathers and filamentous structures appear to have replaced widespread scaly integuments in maniraptorans. Theropod skin, and that of dinosaurs more broadly, remains a virtually untapped area of study and the appropriation of commonly used techniques in other palaeontological fields to the study of skin holds great promise for future insights into the biology, taphonomy and relationships of these extinct animals.

@article{doi101111brv12829,
    author = "Hendrickx, Christophe and Bell, Phil R. and Pittman, Michael and Milner, Andrew R. and Cuesta, Elena and O’Connor, Jingmai K. and Loewen, Mark A. and Currie, Philip J. and Mateus, Octávio and Kaye, Thomas G. and Delcourt, Rafael",
    title = "Morphology and distribution of scales, dermal ossifications, and other non‐feather integumentary structures in non‐avialan theropod dinosaurs",
    year = "2022",
    journal = "Biological reviews/Biological reviews of the Cambridge Philosophical Society",
    abstract = "Modern birds are typified by the presence of feathers, complex evolutionary innovations that were already widespread in the group of theropod dinosaurs (Maniraptoriformes) that include crown Aves. Squamous or scaly reptilian-like skin is, however, considered the plesiomorphic condition for theropods and dinosaurs more broadly. Here, we review the morphology and distribution of non-feathered integumentary structures in non-avialan theropods, covering squamous skin and naked skin as well as dermal ossifications. The integumentary record of non-averostran theropods is limited to tracks, which ubiquitously show a covering of tiny reticulate scales on the plantar surface of the pes. This is consistent also with younger averostran body fossils, which confirm an arthral arrangement of the digital pads. Among averostrans, squamous skin is confirmed in Ceratosauria (Carnotaurus), Allosauroidea (Allosaurus, Concavenator, Lourinhanosaurus), Compsognathidae (Juravenator), and Tyrannosauroidea (Santanaraptor, Albertosaurus, Daspletosaurus, Gorgosaurus, Tarbosaurus, Tyrannosaurus), whereas dermal ossifications consisting of sagittate and mosaic osteoderms are restricted to Ceratosaurus. Naked, non-scale bearing skin is found in the contentious tetanuran Sciurumimus, ornithomimosaurians (Ornithomimus) and possibly tyrannosauroids (Santanaraptor), and also on the patagia of scansoriopterygids (Ambopteryx, Yi). Scales are surprisingly conservative among non-avialan theropods compared to some dinosaurian groups (e.g. hadrosaurids); however, the limited preservation of tegument on most specimens hinders further interrogation. Scale patterns vary among and/or within body regions in Carnotaurus, Concavenator and Juravenator, and include polarised, snake-like ventral scales on the tail of the latter two genera. Unusual but more uniformly distributed patterning also occurs in Tyrannosaurus, whereas feature scales are present only in Albertosaurus and Carnotaurus. Few theropods currently show compelling evidence for the co-occurrence of scales and feathers (e.g. Juravenator, Sinornithosaurus), although reticulate scales were probably retained on the mani and pedes of many theropods with a heavy plumage. Feathers and filamentous structures appear to have replaced widespread scaly integuments in maniraptorans. Theropod skin, and that of dinosaurs more broadly, remains a virtually untapped area of study and the appropriation of commonly used techniques in other palaeontological fields to the study of skin holds great promise for future insights into the biology, taphonomy and relationships of these extinct animals.",
    url = "https://doi.org/10.1111/brv.12829",
    doi = "10.1111/brv.12829",
    openalex = "W4206485050",
    references = "crossref1998encyclopedia, doi101002jmor10382, doi101016jcub201706071, doi101016jcub202006105, doi101016jgca201006017, doi101016s001678780180047x, doi101017jpa202014, doi10103831635, doi10103834356, doi10103835047056, doi101038ncomms14972, doi101038s41598018371862, doi101038srep44942, doi1010800272463420211897604, doi101080147720192013781067, doi101093biolinneanblaa105, doi101093zoolinneanzly009, doi101111brv12829, doi101111cla12160, doi101126science28454232137, doi1011270077774920100125, doi101146annurevearth060313054858, doi1012063521, doi101371journalpone0044012, doi101371journalpone0125819, doi1017161paleo180818764, doi1017161pc180818764, doi10230725058147, doi105962bhltitle5716, doi107717peerj4066, doi107717peerj7247, doi107717peerj7963, doi107717peerj9192, erickson2014on, openalexw1915591379, openalexw2619609965"
}

@inproceedings{andjasinski2023recent,
    author = "Jasinski, Steven and Dalman, Sebastian G.",
    title = "RECENT DINOSAUR DISCOVERIES IN THE WESTERN INTERIOR BASIN AND THEIR IMPLICATIONS FOR LATE CRETACEOUS BIOGEOGRAPHY AND DINOSAURIAN EVOLUTION",
    year = "2023",
    booktitle = "Geological Society of America Abstracts with Programs",
    url = "https://doi.org/10.1130/abs/2023am-393523",
    doi = "10.1130/abs/2023am-393523",
    openalex = "W4389327509"
}

@incollection{crossref2023biogeography,
    title = "Biogeography",
    year = "2023",
    booktitle = "Birds of Belize",
    url = "https://doi.org/10.1515/9780691220734-003",
    doi = "10.1515/9780691220734-003",
    pages = "14-23"
}

Titanosaurian sauropod dinosaurs were diverse and abundant throughout the Cretaceous, with a global distribution. However, few titanosaurian taxa are represented by multiple skeletons, let alone skulls. Diamantinasaurus matildae, from the lower Upper Cretaceous Winton Formation of Queensland, Australia, was heretofore represented by three specimens, including one that preserves a braincase and several other cranial elements. Herein, we describe a fourth specimen of Diamantinasaurus matildae that preserves a more complete skull-including numerous cranial elements not previously known for this taxon-as well as a partial postcranial skeleton. The skull of Diamantinasaurus matildae shows many similarities to that of the coeval Sarmientosaurus musacchioi from Argentina (e.g. quadratojugal with posterior tongue-like process; braincase with more than one ossified exit for cranial nerve V; compressed-cone-chisel-like teeth), providing further support for the inclusion of both taxa within the clade Diamantinasauria. The replacement teeth within the premaxilla of the new specimen are morphologically congruent with teeth previously attributed to Diamantinasaurus matildae, and Diamantinasauria more broadly, corroborating those referrals. Plesiomorphic characters of the new specimen include a sacrum comprising five vertebrae (also newly demonstrated in the holotype of Diamantinasaurus matildae), rather than the six or more that typify other titanosaurs. However, we demonstrate that there have been a number of independent acquisitions of a six-vertebrae sacrum among Somphospondyli and/or that there have been numerous reversals to a five-vertebrae sacrum, suggesting that sacral count is relatively plastic. Other newly identified plesiomorphic features include: the overall skull shape, which is more similar to brachiosaurids than 'derived' titanosaurs; anterior caudal centra that are amphicoelous, rather than procoelous; and a pedal phalangeal formula estimated as 2-2-3-2-0. These features are consistent with either an early-branching position within Titanosauria, or a position just outside the titanosaurian radiation, for Diamantinasauria, as indicated by alternative character weighting approaches applied in our phylogenetic analyses, and help to shed light on the early assembly of titanosaurian anatomy that has until now been obscured by a poor fossil record.

@article{doi101098rsos221618,
    author = "Poropat, Stephen F. and Mannion, Philip D. and Rigby, Samantha L. and Duncan, Ruairidh J. and Pentland, Adele H. and Bevitt, Joseph J. and Sloan, Trish and Elliott, David A.",
    title = "A nearly complete skull of the sauropod dinosaur Diamantinasaurus matildae from the Upper Cretaceous Winton Formation of Australia and implications for the early evolution of titanosaurs",
    year = "2023",
    journal = "Royal Society Open Science",
    abstract = "Titanosaurian sauropod dinosaurs were diverse and abundant throughout the Cretaceous, with a global distribution. However, few titanosaurian taxa are represented by multiple skeletons, let alone skulls. Diamantinasaurus matildae, from the lower Upper Cretaceous Winton Formation of Queensland, Australia, was heretofore represented by three specimens, including one that preserves a braincase and several other cranial elements. Herein, we describe a fourth specimen of Diamantinasaurus matildae that preserves a more complete skull-including numerous cranial elements not previously known for this taxon-as well as a partial postcranial skeleton. The skull of Diamantinasaurus matildae shows many similarities to that of the coeval Sarmientosaurus musacchioi from Argentina (e.g. quadratojugal with posterior tongue-like process; braincase with more than one ossified exit for cranial nerve V; compressed-cone-chisel-like teeth), providing further support for the inclusion of both taxa within the clade Diamantinasauria. The replacement teeth within the premaxilla of the new specimen are morphologically congruent with teeth previously attributed to Diamantinasaurus matildae, and Diamantinasauria more broadly, corroborating those referrals. Plesiomorphic characters of the new specimen include a sacrum comprising five vertebrae (also newly demonstrated in the holotype of Diamantinasaurus matildae), rather than the six or more that typify other titanosaurs. However, we demonstrate that there have been a number of independent acquisitions of a six-vertebrae sacrum among Somphospondyli and/or that there have been numerous reversals to a five-vertebrae sacrum, suggesting that sacral count is relatively plastic. Other newly identified plesiomorphic features include: the overall skull shape, which is more similar to brachiosaurids than 'derived' titanosaurs; anterior caudal centra that are amphicoelous, rather than procoelous; and a pedal phalangeal formula estimated as 2-2-3-2-0. These features are consistent with either an early-branching position within Titanosauria, or a position just outside the titanosaurian radiation, for Diamantinasauria, as indicated by alternative character weighting approaches applied in our phylogenetic analyses, and help to shed light on the early assembly of titanosaurian anatomy that has until now been obscured by a poor fossil record.",
    url = "https://doi.org/10.1098/rsos.221618",
    doi = "10.1098/rsos.221618",
    openalex = "W4365147243",
    references = "doi101038srep19165, doi101093zoolinneanzlx103, doi101093zoolinneanzly068, doi101111cla12524, doi1011646zootaxa370131, doi1011646zootaxa384811, doi101371journalpone0151661"
}

In the dusk of the Mesozoic, advanced duck-billed dinosaurs (Hadrosauridae) were so successful that they likely outcompeted other herbivores, contributing to declines in dinosaur diversity. From Laurasia, hadrosaurids dispersed widely, colonizing Africa, South America, and, allegedly, Antarctica. Here, we present the first species of a duck-billed dinosaur from a subantarctic region, Gonkoken nanoi, of early Maastrichtian age in Magallanes, Chile. Unlike duckbills further north in Patagonia, Gonkoken descends from North American forms diverging shortly before the origin of Hadrosauridae. However, at the time, non-hadrosaurids in North America had become replaced by hadrosaurids. We propose that the ancestors of Gonkoken arrived earlier in South America and reached further south, into regions where hadrosaurids never arrived: All alleged subantarctic and Antarctic remains of hadrosaurids could belong to non-hadrosaurid duckbills like Gonkoken. Dinosaur faunas of the world underwent qualitatively different changes before the Cretaceous-Paleogene asteroid impact, which should be considered when discussing their possible vulnerability.

@article{doi101126sciadvadg2456,
    author = "Alarcón-Muñoz, Jhonatan and Vargas, Alexander O. and Püschel, Hans P. and Soto‐Acuña, Sergio and Manríquez, Leslie M.E. and Leppe, Marcelo and Kaluza, Jonatan and Milla, Verónica and Gutstein, Carolina S. and Palma-Liberona, José and Stinnesbeck, Wolfgang and Frey, Eberhard and Pino, Juan Pablo and Bajor, Dániel and Núñez, Elaine and Ortíz, Héctor and Rubilar-Rogers, David and Cruzado‐Caballero, Penélope",
    title = "Relict duck-billed dinosaurs survived into the last age of the dinosaurs in subantarctic Chile",
    year = "2023",
    journal = "Science Advances",
    abstract = "In the dusk of the Mesozoic, advanced duck-billed dinosaurs (Hadrosauridae) were so successful that they likely outcompeted other herbivores, contributing to declines in dinosaur diversity. From Laurasia, hadrosaurids dispersed widely, colonizing Africa, South America, and, allegedly, Antarctica. Here, we present the first species of a duck-billed dinosaur from a subantarctic region, Gonkoken nanoi, of early Maastrichtian age in Magallanes, Chile. Unlike duckbills further north in Patagonia, Gonkoken descends from North American forms diverging shortly before the origin of Hadrosauridae. However, at the time, non-hadrosaurids in North America had become replaced by hadrosaurids. We propose that the ancestors of Gonkoken arrived earlier in South America and reached further south, into regions where hadrosaurids never arrived: All alleged subantarctic and Antarctic remains of hadrosaurids could belong to non-hadrosaurid duckbills like Gonkoken. Dinosaur faunas of the world underwent qualitatively different changes before the Cretaceous-Paleogene asteroid impact, which should be considered when discussing their possible vulnerability.",
    url = "https://doi.org/10.1126/sciadv.adg2456",
    doi = "10.1126/sciadv.adg2456",
    openalex = "W4380989179",
    references = "doi101016jjsames2021103369, doi101038s41559021016515, doi101111cla12524, doi101371journalpone0045712, doi1016711110, doi104202app20110051, doi107717peerj11290, doi107717peerj12362, longrich2016a, tsogtbaatar2019a"
}

Tyrannosaurid dinosaurs dominated as predators in the Late Cretaceous of Laurasia, culminating in the evolution of the giant Tyrannosaurus rex, both the last and largest tyrannosaurid. Where and when Tyrannosaurini (T. rex and kin) originated remains unclear. Competing hypotheses place tyrannosaurin origins in Asia, or western North America (Laramidia). We report a new tyrannosaurin, Tyrannosaurus mcraeensis, from the Campanian-Maastrichtian Hall Lake Formation of New Mexico, based on a fossil previously referred to T. rex. T. mcraeensis predates T. rex by ~ 6-7 million years, yet rivaled it in size. Phylogenetic analysis recovers T. mcraeensis as sister to T. rex and suggests Tyrannosaurini originated in southern Laramidia. Evolution of giant tyrannosaurs in southern North America, alongside giant ceratopsians, hadrosaurs, and titanosaurs suggests large-bodied dinosaurs evolved at low latitudes in North America.

@article{doi101038s41598023470110,
    author = "Dalman, Sebastian G. and Loewen, Mark A. and Pyron, R. Alexander and Jasinski, Steven E. and Malinzak, Dale Edward and Lucas, Spencer G. and Fiorillo, Anthony R. and Currie, Philip J. and Longrich, Nicholas R.",
    title = "A giant tyrannosaur from the Campanian–Maastrichtian of southern North America and the evolution of tyrannosaurid gigantism",
    year = "2024",
    journal = "Scientific Reports",
    abstract = "Tyrannosaurid dinosaurs dominated as predators in the Late Cretaceous of Laurasia, culminating in the evolution of the giant Tyrannosaurus rex, both the last and largest tyrannosaurid. Where and when Tyrannosaurini (T. rex and kin) originated remains unclear. Competing hypotheses place tyrannosaurin origins in Asia, or western North America (Laramidia). We report a new tyrannosaurin, Tyrannosaurus mcraeensis, from the Campanian-Maastrichtian Hall Lake Formation of New Mexico, based on a fossil previously referred to T. rex. T. mcraeensis predates T. rex by \textasciitilde\ 6-7 million years, yet rivaled it in size. Phylogenetic analysis recovers T. mcraeensis as sister to T. rex and suggests Tyrannosaurini originated in southern Laramidia. Evolution of giant tyrannosaurs in southern North America, alongside giant ceratopsians, hadrosaurs, and titanosaurs suggests large-bodied dinosaurs evolved at low latitudes in North America.",
    url = "https://doi.org/10.1038/s41598-023-47011-0",
    doi = "10.1038/s41598-023-47011-0",
    openalex = "W4390753961",
    references = "doi101016jcretres2021105034, doi101038s4155901908880, doi101038s4159802219896w, doi101139cjes20190019"
}

Gondwanan dinosaur faunae during the 20 Myr preceding the Cretaceous-Palaeogene (K/Pg) extinction included several lineages that were absent or poorly represented in Laurasian landmasses. Among these, the South American fossil record contains diverse abelisaurids, arguably the most successful groups of carnivorous dinosaurs from Gondwana in the Cretaceous, reaching their highest diversity towards the end of this period. Here we describe Koleken inakayali gen. et sp. n., a new abelisaurid from the La Colonia Formation (Maastrichtian, Upper Cretaceous) of Patagonia. Koleken inakayali is known from several skull bones, an almost complete dorsal series, complete sacrum, several caudal vertebrae, pelvic girdle and almost complete hind limbs. The new abelisaurid shows a unique set of features in the skull and several anatomical differences from Carnotaurus sastrei (the only other abelisaurid known from the La Colonia Formation). Koleken inakayali is retrieved as a brachyrostran abelisaurid, clustered with other South American abelisaurids from the latest Cretaceous (Campanian-Maastrichtian), such as Aucasaurus, Niebla and Carnotaurus. Leveraging our phylogeny estimates, we explore rates of morphological evolution across ceratosaurian lineages, finding them to be particularly high for elaphrosaurine noasaurids and around the base of Abelisauridae, before the Early Cretaceous radiation of the latter clade. The Noasauridae and their sister clade show contrasting patterns of morphological evolution, with noasaurids undergoing an early phase of accelerated evolution of the axial and hind limb skeleton in the Jurassic, and the abelisaurids exhibiting sustained high rates of cranial evolution during the Early Cretaceous. These results provide much needed context for the evolutionary dynamics of ceratosaurian theropods, contributing to broader understanding of macroevolutionary patterns across dinosaurs.

@article{doi101111cla12583,
    author = "Pol, Diego and Baiano, Mattia A. and Černý, David and Novas, Fernando E. and Cerda, Ignacio A. and Pittman, Michael",
    title = "A new abelisaurid dinosaur from the end Cretaceous of Patagonia and evolutionary rates among the Ceratosauria",
    year = "2024",
    journal = "Cladistics",
    abstract = "Gondwanan dinosaur faunae during the 20 Myr preceding the Cretaceous-Palaeogene (K/Pg) extinction included several lineages that were absent or poorly represented in Laurasian landmasses. Among these, the South American fossil record contains diverse abelisaurids, arguably the most successful groups of carnivorous dinosaurs from Gondwana in the Cretaceous, reaching their highest diversity towards the end of this period. Here we describe Koleken inakayali gen. et sp. n., a new abelisaurid from the La Colonia Formation (Maastrichtian, Upper Cretaceous) of Patagonia. Koleken inakayali is known from several skull bones, an almost complete dorsal series, complete sacrum, several caudal vertebrae, pelvic girdle and almost complete hind limbs. The new abelisaurid shows a unique set of features in the skull and several anatomical differences from Carnotaurus sastrei (the only other abelisaurid known from the La Colonia Formation). Koleken inakayali is retrieved as a brachyrostran abelisaurid, clustered with other South American abelisaurids from the latest Cretaceous (Campanian-Maastrichtian), such as Aucasaurus, Niebla and Carnotaurus. Leveraging our phylogeny estimates, we explore rates of morphological evolution across ceratosaurian lineages, finding them to be particularly high for elaphrosaurine noasaurids and around the base of Abelisauridae, before the Early Cretaceous radiation of the latter clade. The Noasauridae and their sister clade show contrasting patterns of morphological evolution, with noasaurids undergoing an early phase of accelerated evolution of the axial and hind limb skeleton in the Jurassic, and the abelisaurids exhibiting sustained high rates of cranial evolution during the Early Cretaceous. These results provide much needed context for the evolutionary dynamics of ceratosaurian theropods, contributing to broader understanding of macroevolutionary patterns across dinosaurs.",
    url = "https://doi.org/10.1111/cla.12583",
    doi = "10.1111/cla.12583",
    openalex = "W4398169218",
    references = "doi101002spp21375, doi101016jcretres2019104312, doi101016jcretres2020104408, doi101016jcretres2021104829, doi101038s41598019453069, doi101038s41598022155356, doi101038srep44942, doi101080027246342013776562, doi1010800272463420201877151, doi1010801477201920222093661, doi101111brv12666, doi101111cla12524, doi101111zoj12425, doi1011646zootaxa375911, doi101371journalpone0062047, doi101371journalpone0088905, doi105852crpalevol2020v19a6, doi107717peerj5976"
}

Dinosaurs were dominant members of terrestrial ecosystems throughout the Mesozoic, yet only recently are studies beginning to illuminate the key role of global climate variation in controlling dinosaur biodiversity, global distribution, and macroevolution. Our work uses statistical, biogeographic, and phylogenetic comparative approaches with comprehensive fossil occurrence data and paleoclimate data from general circulation models to quantitatively examine key hypotheses connecting patterns of dinosaur diversity and evolution with climatic conditions. We examined the impact of climate change in driving early dinosaur evolution across the end-Triassic mass extinction (ETME). Our results demonstrate that the geographic distribution of early sauropodomorphs was constrained by climate and following the ETME, the expansion of climate zones facilitated the geographic expansion of sauropodomorphs and other dinosaurs. Evolutionary model-fitting analyses provide evidence for an important evolutionary shift from cooler to warmer climatic niches during the origin of Sauropoda. This same approach is also revealing the relationship between climatic conditions and dinosaur diversity in the Jurassic to Cretaceous, with implications for our understanding of the origins of sauropod gigantism and the evolution of herbivory. Our results suggest that primary productivity was a key climatic factor in driving sauropod evolution and promoting the evolution of larger body sizes, supporting the hypothesis that gigantism was facilitated by the increasing availability of high quality vegetation. Analyses of dinosaur paleoclimatic niche space show evidence of niche partitioning between herbivorous theropods and ‘traditional’ herbivorous dinosaurs (e.g. sauropods), indicating that climatic changes may have influenced evolutionary innovations related to dinosaur diet. Further work examining the relationship between dinosaur diversity and changes in vegetation using state-of-the-art vegetation models will illuminate the key role played by environmental change in controlling dinosaur diversity and evolution throughout the Mesozoic.

@misc{dunne2025climatic,
    author = "Dunne, Emma and Schnetz, Lisa and Farnsworth, Alexander and Lautenschlager, Stephan and Godoy, Pedro and Tasimov, Eren and Butler, Richard and Greene, Sarah",
    title = "Climatic controls on dinosaur evolution, diversity and biogeography",
    year = "2025",
    abstract = "Dinosaurs were dominant members of terrestrial ecosystems throughout the Mesozoic, yet only recently are studies beginning to illuminate the key role of global climate variation in controlling dinosaur biodiversity, global distribution, and macroevolution. Our work uses statistical, biogeographic, and phylogenetic comparative approaches with comprehensive fossil occurrence data and paleoclimate data from general circulation models to quantitatively examine key hypotheses connecting patterns of dinosaur diversity and evolution with climatic conditions. We examined the impact of climate change in driving early dinosaur evolution across the end-Triassic mass extinction (ETME). Our results demonstrate that the geographic distribution of early sauropodomorphs was constrained by climate and following the ETME, the expansion of climate zones facilitated the geographic expansion of sauropodomorphs and other dinosaurs. Evolutionary model-fitting analyses provide evidence for an important evolutionary shift from cooler to warmer climatic niches during the origin of Sauropoda. This same approach is also revealing the relationship between climatic conditions and dinosaur diversity in the Jurassic to Cretaceous, with implications for our understanding of the origins of sauropod gigantism and the evolution of herbivory. Our results suggest that primary productivity was a key climatic factor in driving sauropod evolution and promoting the evolution of larger body sizes, supporting the hypothesis that gigantism was facilitated by the increasing availability of high quality vegetation. Analyses of dinosaur paleoclimatic niche space show evidence of niche partitioning between herbivorous theropods and \&\#8216;traditional\&\#8217; herbivorous dinosaurs (e.g. sauropods), indicating that climatic changes may have influenced evolutionary innovations related to dinosaur diet. Further work examining the relationship between dinosaur diversity and changes in vegetation using state-of-the-art vegetation models will illuminate the key role played by environmental change in controlling dinosaur diversity and evolution throughout the Mesozoic.",
    url = "https://doi.org/10.5194/egusphere-egu24-15098",
    doi = "10.5194/egusphere-egu24-15098",
    openalex = "W4392758148"
}