Research related to paleontology that either does not concern any of the groups of the organisms listed above, or concerns multiple groups. • A study on the links between changes in the composition of exposed continental crust and oxygenation of the atmosphere in the
Precambrian is published by Smit & Mezger (2017). • A review of the progress in modeling the
Snowball Earth atmosphere,
cryosphere,
hydrosphere and
lithosphere, specifically as it pertains to
Cryogenian geology and
geobiology, is published by
Hoffman et al. (2017). • A revised record of fossil
eukaryotic steroids during the
Neoproterozoic is presented by Brocks
et al. (2017), who argue that
bacteria were the only notable
primary producers in the oceans before the
Cryogenian, and that rapid rise of marine
planktonic
algae to domination occurred in the narrow time interval between the
Sturtian and
Marinoan glaciations, 659–645 million years ago, likely driving the subsequent radiation of animals in the
Ediacaran period. • A study evaluating whether mass
extinction events over the last 500 million year were caused by astronomical phenomena is published by Erlykin
et al. (2017). • A study on the water column geochemistry of the Yangtze Sea during the
Ediacaran-
Cambrian transition and its implications for the relationship between ocean oxygenation and Early Cambrian animal diversification is published by Zhang
et al. (2017). • A study on the links between the expansion of
siliceous sponges and seawater oxygenation during the Ediacaran–Cambrian transition is published by Tatzel
et al. (2017). • A study on the factors influencing marine invertebrate diversity dynamics through the
Phanerozoic is published by Cermeño
et al. (2017). • Edwards
et al. (2017) identify a strong temporal link between the rising atmospheric oxygen levels and the
Great Ordovician Biodiversification Event. • A study on the impact of the drawdown of atmospheric
carbon dioxide (caused by burial of organic
carbon leading to the formation of
coal) on the climate around the
Carboniferous/
Permian boundary is published by Feulner (2017). • A comprehensive reconstruction of the
Permian (
Lopingian)
Bletterbach Biota (
Italy) and a review of other best-known Lopingian terrestrial associations containing both vertebrate and plant remains is published by Bernardi
et al. (2017). • A study on the causal connection between the
Siberian Traps large igneous province magmatism and
Permian–Triassic extinction event, identifying the initial emplacement pulse as likely to have triggered mass extinction, is published by Burgess, Muirhead & Bowring (2017). • Viglietti, Rubidge & Smith (2017) review the tectonic setting of the Late
Permian Karoo Basin (
South Africa), provide an updated basin development model, and interpret their findings as indicating that the climatic changes associated with the Permian–Triassic extinction event were occurring much lower in the
stratigraphy (and thus earlier) than previously documented. • A summary of knowledge of the impact of Permian-Triassic mass extinction on reef ecosystems, and on their recovery after this extinction, is presented by Martindale, Foster & Velledits (2017). • A study on
benthic invertebrate communities from the
Lower Triassic Werfen Formation (Italy), aiming to test whether carbon isotope perturbations during the Early Triassic were associated with biotic crises that impeded benthic recovery after the Permian–Triassic extinction event, is published by Foster
et al. (2017). • A study on the impact of the magmatic activity associated with the
Central Atlantic magmatic province on the
Triassic–Jurassic extinction event is published by Davies
et al. (2017). • A study on the volcanic activity at the end of the
Triassic as indicated by
mercury concentrations in sediments from around the world is published by Percival
et al. (2017). • A study on the oxygen levels in Earth's oceans during and after the Triassic–Jurassic extinction event as indicated by uranium isotopes in shallow-marine limestones in the Lombardy Basin (northern
Italy) is published by Jost
et al. (2017). • A high-resolution
stratigraphic chart for terrestrial Late Cretaceous units of North America and a study on the stratigraphic ranges of North American dinosaurs is published by Fowler (2017). • A study on the impact that large amounts of
soot injected into the atmosphere during the
Cretaceous–Paleogene extinction event (probably caused by global wildfires) had on the climate is published by Bardeen
et al. (2017). • A study estimating the decrease of the air temperature and the duration of the climate cooling caused by
Chicxulub impact at the end of the Cretaceous is published by Brugger, Feulner & Petri (2017). • A study on the volume of the climate-active gases released from sedimentary rocks as a result of the Chicxulub impact, as well as on their effect on the global climate, is published by Artemieva, Morgan & Expedition 364 Science Party (2017). • Kaiho & Oshima (2017) calculate the amounts of
stratospheric soot and
sulfate formed by a virtual asteroid impact at various global locations, and conclude that the Cretaceous–Paleogene extinction event was caused by the Chicxulub impact happening at the
hydrocarbon-rich, sulfate-dominated area on the Earth's surface, and that an impact at a low–medium hydrocarbon area on Earth would be unlikely to cause mass extinction. • A study on the data sets of
molluscan fossils from the Cretaceous–Paleogene of the
Seymour Island (
Antarctica) is published by Tobin (2017), who identifies possible evidence of two separate extinction events, one prior to the Cretaceous–Paleogene boundary, and one simultaneous with the bolide impact at the Cretaceous–Paleogene boundary. • A study on the behavioral and ecological diversification of animals that colonized land as indicated by
trace fossils is published by Minter
et al. (2017). • A study on the age of the Cowie Harbour Fish Bed (
Scotland,
United Kingdom), containing
fish and
arthropod fossils (including the
millipede Pneumodesmus newmani), is published by Suarez
et al. (2017). • A study on the preservation of skin and keratinous integumentary structures in
tetrapod fossils through time is published by Eliason
et al. (2017). • A study on the differences between the
tetrapod faunas at different latitudes during the early and middle
Permian, as well as their implications for establishing whether the
Olson's Extinction was a genuine event, is published by Brocklehurst
et al. (2017). • A study on the non-flying terrestrial tetrapod species richness through the Mesozoic and early Palaeogene is published by Close
et al. (2017). • A study on the evolution of the shape of brain and skull roof during the transition from early reptiles through
archosauromorphs, including nonavian dinosaurs, to birds is published by Fabbri
et al. (2017). • A study on the structure and vulnerability of the
food web in marine vertebrate assemblages prior to the
Cretaceous–Paleogene extinction event as indicated by calcium isotope data from plesiosaurs and mosasaurs is published by Martin
et al. (2017). • Qvarnström
et al. (2017) reconstruct fossil inclusions in two
coprolites (produced by an insectivorous animal and a large aquatic predator) from the
Late Triassic locality of
Krasiejów (
Poland) using propagation phase-contrast synchrotron
microtomography. • A study on the fossil inclusions in coprolite fragments (produced by medium to large-sized carnivores, possibly
therocephalian
therapsids or early
archosauriforms) recovered from the Late
Permian locality of Vyazniki (
Russia) is published by Bajdek
et al. (2017). • A new
tetrapod assemblage from the lowermost levels of the
Triassic Chañares Formation (
Argentina), dominated by fossils of
Tarjadia ruthae,
dicynodonts and
cynodonts, and also including fossils of other
pseudosuchians and
rhynchosaurs, is described by Ezcurra
et al. (2017), who also reinterpret
Tarjadia ruthae and
Archeopelta arborensis as
erpetosuchid archosaurs. • A study on the
cosmopolitanism of terrestrial
amniote faunas in the aftermath of the
Permian–Triassic extinction event and
Triassic–Jurassic extinction event is published by Button
et al. (2017). • Frese
et al. (2017) determine the mineral and elemental composition of a range of fossils from the
Talbragar fossil site (
Australia) and their rock matrices using ultraviolet light-induced fluorescence/
photoluminescence, X-ray fluorescence and X-ray diffractometry, and use those techniques to reveal anatomical details of animals and plants fossils that weren't discernible otherwise. • A study on changes of the size of fossil marine shells and predatory drill holes in those shells during the
Phanerozoic, as well as their implications for changes of predator-prey size ratio throughout the Phanerozoic, is published by Klompmaker
et al. (2017). • A study evaluating the utility of oxygen-isotope compositions of fossilised foraminifera
tests as proxies for surface- and deep-ocean paleotemperatures, and its implications for inferring Late Cretaceous and Paleogene deep-ocean and high-latitude surface-ocean temperatures, is published by Bernard
et al. (2017). • A study on the
glacial development and environmental changes in the
Aurora Subglacial Basin (
Antarctica) throughout the Cenozoic based on geophysical and geological evidence is published by Gulick
et al. (2017). • A study on the onset duration of the
Paleocene–Eocene Thermal Maximum is published by Kirtland Turner
et al. (2017). • A study on the relationship between volcanic activity in the
North Atlantic Igneous Province and the Paleocene–Eocene Thermal Maximum is published by Gutjahr
et al. (2017). • A study on the environment in the area corresponding to the present-day
Amazon basin in the
Miocene as indicated by data from the shark and ray fossils from the
Pirabas Formation (
Brazil) is published by Aguilera
et al. (2017). • A study on the impact of the
Messinian salinity crisis on Mediterranean
magmatism is published by Sternai
et al. (2017). • A study on the changes of
ice sheets volume and sea level during the late
Pliocene is published by de Boer
et al. (2017). • Pimiento
et al. (2017) identify a previously unrecognized
extinction event among marine
megafauna at the end of the
Pliocene. • A study on the aridity in eastern Africa over the past 4.4 million years as indicated by oxygen isotope ratios in fossil herbivore
tooth enamel, and on its implications for inferring the role of climate in shaping early hominin environments, is published by Blumenthal
et al. (2017). • Tierney, deMenocal & Zander (2017) reconstruct temperature and aridity in the
Horn of Africa region spanning the past 200,000 years. • A vertebrate fauna from the
Pleistocene and
Holocene of
Sumba (
Indonesia) is described by Turvey
et al. (2017). • A study on the modified mammalian bones from the Plio–Pleistocene of
Ethiopia is published by Sahle, El Zaatari & White (2017), who interpret the marks on some of these bones as more likely to be produced by crocodiles than by
hominids using
stone tools. • Hagstrum
et al. (2017) report impact-related microspherules and elevated
platinum concentrations found in fine-grained sediments retained within Late Pleistocene bison and mammoth skull fragments from
Alaska and
Yukon, and interpret the findings as evidence of repeated airbursts and ground/ice impacts associated with multiple episodes of cosmic impact. • A study on changes in landscape moisture in the
rangelands in Europe, Siberia and the Americas during the late
Pleistocene as indicated by data from the bones of
megaherbivores is published by Rabanus-Wallace
et al. (2017). ==References==