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NARROW
GeoRef Subject
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all geography including DSDP/ODP Sites and Legs
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Asia
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Indian Peninsula
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India (1)
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Chicxulub Crater (1)
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Mexico (1)
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Yucatan Peninsula (1)
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elements, isotopes
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carbon (4)
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isotope ratios (1)
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isotopes
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stable isotopes
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Sr-87/Sr-86 (1)
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metals
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alkaline earth metals
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strontium
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Sr-87/Sr-86 (1)
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fossils
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Invertebrata
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Protista
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Foraminifera (1)
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microfossils (1)
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Plantae
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algae
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nannofossils (1)
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geologic age
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Cenozoic
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Tertiary
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Paleogene
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Paleocene
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lower Paleocene
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Danian (1)
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K-T boundary (1)
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Mesozoic
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Cretaceous
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Upper Cretaceous
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K-T boundary (1)
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Paleozoic
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Cambrian
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Upper Cambrian
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Furongian (1)
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Devonian (1)
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lower Paleozoic (1)
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Ordovician
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Middle Ordovician (1)
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Silurian
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Lower Silurian
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Llandovery (1)
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Precambrian
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upper Precambrian
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Proterozoic
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Neoproterozoic (1)
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igneous rocks
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igneous rocks
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volcanic rocks
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basalts
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flood basalts (2)
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minerals
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carbonates
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calcite (1)
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sulfates (1)
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Primary terms
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Asia
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Indian Peninsula
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India (1)
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carbon (4)
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Cenozoic
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Tertiary
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Paleogene
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Paleocene
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lower Paleocene
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Danian (1)
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K-T boundary (1)
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climate change (2)
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continental drift (1)
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crust (1)
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data processing (2)
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geochemistry (2)
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igneous rocks
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volcanic rocks
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basalts
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flood basalts (2)
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Invertebrata
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Protista
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Foraminifera (1)
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-
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isotopes
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stable isotopes
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Sr-87/Sr-86 (1)
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-
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Mesozoic
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Cretaceous
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Upper Cretaceous
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K-T boundary (1)
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metals
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alkaline earth metals
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strontium
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Sr-87/Sr-86 (1)
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Mexico (1)
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paleoclimatology (4)
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Paleozoic
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Cambrian
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Upper Cambrian
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Furongian (1)
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Devonian (1)
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lower Paleozoic (1)
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Ordovician
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Middle Ordovician (1)
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Silurian
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Lower Silurian
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Llandovery (1)
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Plantae
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algae
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nannofossils (1)
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Precambrian
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upper Precambrian
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Proterozoic
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Neoproterozoic (1)
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sea water (1)
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weathering (3)
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rock formations
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Deccan Traps (2)
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ABSTRACT The latest Cretaceous (Maastrichtian) through earliest Paleogene (Danian) interval was a time marked by one of the five major mass extinctions in Earth’s history. The synthesis of published data permits the temporal correlation of the Cretaceous-Paleogene boundary crisis with two major geological events: (1) the Chicxulub impact, discovered in the Yucatán Peninsula (Mexico), and (2) eruption of the Deccan Traps large igneous province, located on the west-central Indian plateau. In this study, environmental and biological consequences from the Chicxulub impact and emplacement of the Deccan continental flood basalts were explored using a climate-carbon-biodiversity coupled model called the ECO-GEOCLIM model. The novelty of this study was investigation into the ways in which abiotic factors (temperature, pH, and calcite saturation state) acted on various marine organisms to determine the primary productivity and biodiversity changes in response to a drastic environmental change. Results showed that the combination of Deccan volcanism with a 10-km-diameter impactor would lead to global warming (3.5 °C) caused by rising carbon dioxide (CO 2 ) concentration (+470 ppmv), interrupted by a succession of short-term cooling events, provided by a “shielding effect” due to the formation of sulfate aerosols. The consequences related to these climate changes were the decrease of the surface ocean pH by 0.2 (from 8.0 to 7.8), while the deep ocean pH dropped by 0.4 (from 7.8 to 7.4). Without requiring any additional perturbations, these environmental disturbances led to a drastic decrease of the biomass of calcifying species and their biodiversity by ~80%, while the biodiversity of noncalcifying species was reduced by ~60%. We also suggest that the short-lived acidification caused by the Chicxulub impact, when combined with eruption of the Deccan Traps, may explain the severity of the extinction among pelagic calcifying species.
Modeling the carbon-sulfate interplays in climate changes related to the emplacement of continental flood basalts
Climatic and environmental changes are now widely recognized as the main cause of mass extinctions. Global warming that immediately preceded the Cretaceous-Tertiary boundary is regarded as a consequence of CO 2 released during the main phase of Deccan Trap emplacement. Modeling has shown that such global warming cannot be explained by the continuous release of volcanic carbon dioxide. In the present paper, we use a biogeochemical model, coupled to a climate model, to further our understanding of climate changes caused by continental flood basalts. The response of the global climate–carbon-cycle system to sulfur dioxide (SO 2 ) and carbon dioxide (CO 2 ) emissions is investigated, assuming a degassing history consisting of a series of evenly spaced pulses. We find that CO 2 -related warming is enhanced when large-scale SO 2 injections are added. According to our model, we observe that the succession of drastic cooling events induced by sulfate aerosols decreases the efficiency of silicate weathering and destabilizes the carbon cycle during the full time span of trap emplacement. In the case of the Deccan Traps, these transient dis-equilibria lead to a 25% increase in p CO 2 and ensuing warming. The environmental consequences of emplacement of large igneous provinces appear to be even more complex: A SO 2 -related climate feedback may have enhanced the long-term warming due to CO 2 emissions.
Modeling the early Paleozoic long-term climatic trend
Modelling the Snowball Earth
Abstract We review most of the modelling studies performed to date to understand the initiation and melting of a Snowball Earth, as well as to describe the glacial environment during the glaciation itself. All the described scenarios explaining the onset of glaciation rely on a sufficient decrease in the concentrations of atmospheric greenhouse gases (GHGs), typically resulting from the equatorial palaeogeography of the late Proterozoic. It is still heavily debated whether or not the oceanic ice cover was thick during the glaciation itself. However, a consensus has arisen that the most climatically stable scenarios imply the existence of a globally frozen ocean, with a thick ice cover caused by the flowing of high-latitude sea-ice glaciers towards the equator. Depending on the characteristics of the ice, a thin ice layer may have persisted along the equator, but this numerical solution is rather fragile. During the snowball event itself, model results suggest the existence of wet-based continental glaciers. Some parts of the continents may have remained ice-free. From the modelling perspective, the most significant problem in the snowball hypothesis, particularly in its ‘hard snowball’ version (the most stable numerically), is the melting phase. With improved modelling, the CO 2 threshold required to melt the snowball is much higher than initially thought, significantly above 0.29 bar. Indeed, because of the very cold conditions prevailing at the surface of the Earth during the glacial event, the atmosphere becomes vertically isothermal, strongly limiting the efficiency of the greenhouse effect. This melting problem is further highlighted by geochemical modelling studies that show that weathering of the oceanic crust might be an active sink of CO 2 during the glacial event, limiting the rise in atmospheric CO 2 . The solution might be found by considering the input of dark dust from catastrophic volcanic eruptions that would efficiently decrease the albedo of the ice. Finally, modelling studies also explore the aftermath of the glaciation. The world might have been drier than initially anticipated, resulting in the persistence of the supergreenhouse effect for at least one million years after the melting phase.