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117 results on '"Rasmussen, Cornelia"'

4. Geochemistry, geochronology and petrogenesis of Maya Block granitoids and dykes from the Chicxulub Impact Crater, Gulf of México: Implications for the assembly of Pangea

Author

Zhao, Jiawei, Xiao, Long, Gulick, Sean P.S., Morgan, Joanna V., Kring, David, Fucugauchi, Jaime Urrutia, Schmieder, Martin, de Graaff, Sietze J., Wittmann, Axel, Ross, Catherine H., Claeys, Philippe, Pickersgill, Annemarie, Kaskes, Pim, Goderis, Steven, Rasmussen, Cornelia, Vajda, Vivi, Ferrière, Ludovic, Feignon, Jean–Guillaume, Chenot, Elise, Perez-Cruz, Ligia, Sato, Honami, and Yamaguchi, Kosei

Published
2020
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10. Rapid recovery of life at ground zero of the end-Cretaceous mass extinction

Author

Lowery, Christopher M., Bralower, Timothy J., Owens, Jeremy D., Rodríguez-Tovar, Francisco J., Jones, Heather, Smit, Jan, Whalen, Michael T., Claeys, Phillipe, Farley, Kenneth, Gulick, Sean P. S., Morgan, Joanna V., Green, Sophie, Chenot, Elise, Christeson, Gail L., Cockell, Charles S., Coolen, Marco J. L., Ferrière, Ludovic, Gebhardt, Catalina, Goto, Kazuhisa, Kring, David A., Lofi, Johanna, Ocampo-Torres, Rubén, Perez-Cruz, Ligia, Pickersgill, Annemarie E., Poelchau, Michael H., Rae, Auriol S. P., Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Riller, Ulrich, Sato, Honami, Tikoo, Sonia M., Tomioka, Naotaka, Urrutia-Fucugauchi, Jaime, Vellekoop, Johan, Wittmann, Axel, Xiao, Long, Yamaguchi, Kosei E., and Zylberman, William

Published
2018
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11. The formation of peak rings in large impact craters

Author

Morgan, Joanna V., Gulick, Sean P. S., Bralower, Timothy, Chenot, Elise, Christeson, Gail, Claeys, Philippe, Cockell, Charles, Collins, Gareth S., Coolen, Marco J. L., Ferrière, Ludovic, Gebhardt, Catalina, Goto, Kazuhisa, Jones, Heather, Kring, David A., Le Ber, Erwan, Lofi, Johanna, Long, Xiao, Lowery, Christopher, Mellett, Claire, Ocampo-Torres, Rubén, Osinski, Gordon R., Perez-Cruz, Ligia, Pickersgill, Annemarie, Poelchau, Michael, Rae, Auriol, Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Riller, Ulrich, Sato, Honami, Schmitt, Douglas R., Smit, Jan, Tikoo, Sonia, Tomioka, Naotaka, Urrutia-Fucugauchi, Jaime, Whalen, Michael, Wittmann, Axel, Yamaguchi, Kosei E., and Zylberman, William

Published
2016

13. CPCP

Author

Brady Shannon, Kristina, Noren, Anders, Olsen, Paul, Mundil, Roland, Kent, Dennis, Irmis, Randy, Gehrels, George, Giesler, Dominique, Lepre, Christopher, Geissman, John, Haque, Ziaul, Rasmussen, Cornelia, and Zakharova, Natalia

Abstract

Colorado Plateau Coring Project. Scientific drilling to recover core samples of complete Triassic stratigraphic sequence at Petrified Forest National Park, Arizona, USA.

Published
2022
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14. Grouping behavior in a Triassic marine apex predator

Author

Kelley, Neil P., primary, Irmis, Randall B., additional, dePolo, Paige E., additional, Noble, Paula J., additional, Montague-Judd, Danielle, additional, Little, Holly, additional, Blundell, Jon, additional, Rasmussen, Cornelia, additional, Percival, Lawrence M.E., additional, Mather, Tamsin A., additional, and Pyenson, Nicholas D., additional

Published
2022
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16. Sphene Emotional: How Titanite Was Shocked When the Dinosaurs Died

Author

Timms, Nicholas E, Pearce, Mark A, Erickson, Timmons M, Cavosie, Aaron J, Rae, Auriol, Wheeler, John, Wittmann, Axel, Ferrière, Ludovic, Poelchau, Michael H, Tomioka, Naotaka, Collins, Gareth S, Gulick, Sean P. S, Rasmussen, Cornelia, and Morgan, Joanna V

Subjects
Space Sciences (General)
Abstract

Accessory mineral geochronometers such as zircon, monazite, baddeleyite, and xenotime are increasingly being recognized for their ability to preserve diagnostic microstructural evidence of hypervelocity processes. However, little is known about the response of titanite to shock metamorphism, even though it is a widespread accessory phase and U-Pb geochronometer. Here we report two new mechanical twin modes in titanite within shocked granitoids from the Chicxulub impact structure, Mexico. Titanite grains in the newly acquired International Ocean Discovery Program Site expedition 364 M0077A core preserve multiple sets of polysynthetic twins, most commonly with composition planes (K1), = ~{1̅11}, and shear direction (η1) = <110>, and less commonly with the mode K1 = {130}, η1 = ~<522>. In some grains, {130} deformation bands have formed concurrently with shock twins, indicating dislocation glide with Burgers vector b = [341] can be active at shock conditions. Twinning of titanite in these modes, the presence of planar deformation features in shocked quartz, and lack of diagnostic shock microstructures in zircon in the same samples highlights the utility of titanite as a shock indicator for a shock pressure range between ~12 and ~17 GPa. Given the challenges of identifying ancient impact evidence on Earth and other bodies, microstructural analysis of titanite is here demonstrated to be a new avenue for recognizing impact deformation in materials where other impact evidence may be erased, altered, or did not manifest due to low shock pressure.

Published
2018

18. Shock impedance amplified impact deformation of zircon in granitic rocks from the Chicxulub impact crater

Author

Wittmann, Axel, primary, Cavosie, Aaron J., additional, Timms, Nicholas E., additional, Ferrière, Ludovic, additional, Rae, Auriol, additional, Rasmussen, Cornelia, additional, Ross, Catherine, additional, Stockli, Daniel, additional, Schmieder, Martin, additional, Kring, David A., additional, Zhao, Jiawei, additional, Xiao, Long, additional, Morgan, Joanna V., additional, and Gulick, Sean P.S., additional

Published
2021
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19. Shock-deformed zircon from the Chicxulub impact crater and implications for cratering process

Author

Zhao, Jiawei, Xiao, Long, Xiao, Zhiyong, Morgan, Joanna, Osinski, Gordon, Neal, Clive, Gulick, Sean P.S., Riller, Ulrich, Claeys, Philippe, Zhao, Shanrong, Prieur, Nils, Nemchin, Alexander, Yu, Shuoran, Chenot, Elise, Christeson, Gail l., Cockell, Charles S., Coolen, Marco J.L., Ferrière, Ludovic, Gebhardt, Catalina, Goto, Kazuhisa, Jones, Heather, Kring, David A., LOFI, Johanna, Lowery, Christopher M., OCAMPO-TORRES, Ruben, Perez-Cruz, Ligia, Pickersgill, Annemarie E., Poelchau, Michael H., Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Sato, Honami, Smit, Jan, Tikoo-Schantz, Sonia M., Tomioka, Naotaka, Urrutia Fucugauchi, Jaime, Whalen, Michael T., Wittmann, Axel, Yamaguchi, Kosei E., Institut de chimie et procédés pour l'énergie, l'environnement et la santé (ICPEES), Université de Strasbourg (UNISTRA)-Matériaux et nanosciences d'Alsace (FMNGE), Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Natural Environment Research Council (NERC), Analytical, Environmental & Geo-Chemistry, Earth System Sciences, and Chemistry

Subjects
Geochemistry & Geophysics, Reidite, 010504 meteorology & atmospheric sciences, 04 Earth Sciences, Geology, zircon, 010502 geochemistry & geophysics, 01 natural sciences, Shock (mechanics), Shock metamorphism, Impact crater, 13. Climate action, [SDU]Sciences of the Universe [physics], Scientific method, microstructures, shock metamorphism, Petrology, Cratering, 0105 earth and related environmental sciences, Zircon
Abstract

International audience; Large impact structures with peak rings are common landforms across the solar system, and their formation has implications for both the interior structure and thermal evolution of planetary bodies. Numerical modeling and structural studies have been used to simulate and ground truth peak-ring formative mechanisms, but the shock metamorphic record of minerals within these structures remains to be ascertained. We investigated impact-related microstructures and high-pressure phases in zircon from melt-bearing breccias, impact melt rock, and granitoid basement from the Chicxulub peak ring (Yucatán Peninsula, Mexico), sampled by the International Ocean Discovery Program (IODP)/International Continental Drilling Project (IODP-ICDP) Expedition 364 Hole M0077A. Zircon grains exhibit shock features such as reidite, zircon twins, and granular zircon including “former reidite in granular neoblastic” (FRIGN) zircon. These features record an initial high-pressure shock wave (>30 GPa), subsequent relaxation during the passage of the rarefaction wave, and a final heating and annealing stage. Our observed grain-scale deformation history agrees well with the stress fields predicted by the dynamic collapse model, as the central uplift collapsed downward-then-outward to form the peak ring. The occurrence of reidite in a large impact basin on Earth represents the first such discovery, preserved due to its separation from impact melt and rapid cooling by the resurging ocean. The coexistence of reidite and FRIGN zircon within the impact melt–bearing breccias indicates that cooling by seawater was heterogeneous. Our results provide valuable information on when different shock microstructures form and how they are modified according to their position in the impact structure, and this study further improves on the use of shock barometry as a diagnostic tool in understanding the cratering process.

Published
2021
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20. Magnetostratigraphy of the Triassic Moenkopi Formation From the Continuous Cores Recovered in Colorado Plateau Coring Project Phase 1 (CPCP‐1), Petrified Forest National Park, Arizona, USA: Correlation of the Early to Middle Triassic Strata and Biota in Colorado Plateau and Its Environs

Author

Haque, Ziaul, primary, Geissman, John W., additional, Irmis, Randall B., additional, Olsen, Paul E., additional, Lepre, Christopher, additional, Buhedma, Hesham, additional, Mundil, Roland, additional, Parker, William G., additional, Rasmussen, Cornelia, additional, and Gehrels, George E., additional

Published
2021
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21. Evidence of Carboniferous arc magmatism preserved in the Chicxulub impact structure

Author

Ross, Catherine H., primary, Stockli, Daniel F., additional, Rasmussen, Cornelia, additional, Gulick, Sean P.S., additional, de Graaff, Sietze J., additional, Claeys, Philippe, additional, Zhao, Jiawei, additional, Xiao, Long, additional, Pickersgill, Annemarie E., additional, Schmieder, Martin, additional, Kring, David A., additional, Wittmann, Axel, additional, and Morgan, Joanna V., additional

Published
2021
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22. Globally distributed iridium layer preserved within the Chicxulub impact structure

Author

Goderis, Steven, Sato, Honami, Ferrière, Ludovic, Schmitz, Birger, Burney, David, Kaskes, Pim, Vellekoop, Johan, Wittmann, Axel, Schulz, Toni, Chernonozhkin, Stepan, Claeys, Philippe, de Graaff, Sietze, Déhais, Thomas, de Winter, Niels, Elfman, Mikael, Feignon, Jean-Guillaume, Ishikawa, Akira, Koeberl, Christian, Kristiansson, Per, Neal, Clive, Owens, Jeremy, Schmieder, Martin, Sinnesael, Matthias, Vanhaecke, Frank, Van Malderen, Stijn, Bralower, Timothy, Gulick, Sean, Kring, David, Lowery, Christopher, Morgan, Joanna, Smit, Jan, Whalen, Michael, Chenot, Elise, Christeson, Gail l., Cockell, Charles S., Gebhardt, Catalina, Goto, Kazuhisa, Green, Sophie L., Jones, Heather, LeBer, Erwan, Lofi, Johanna, IODP-ICDP Expedition 364 scientists,, Perez-Cruz, Ligia, Pickersgill, Annemarie E., Poelchau, Michael H., Rae, Auriol S.P., Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Riller, Ulrich, Tikoo-Schantz, Sonia M., Tomioka, Naotaka, Urrutia-Fucugauchi, Jaime, Xiao, Long, Yamaguchi, Kosei E., Stratigraphy and paleontology, Stratigraphy & paleontology, Natural Environment Research Council (NERC), Earth Sciences, Chemistry, Analytical, Environmental & Geo-Chemistry, Faculty of Sciences and Bioengineering Sciences, Institut de chimie et procédés pour l'énergie, l'environnement et la santé (ICPEES), Université de Strasbourg (UNISTRA)-Matériaux et nanosciences d'Alsace (FMNGE), Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Biological Psychology, Texts and Traditions, and Sociology and Social Gerontology

Subjects
010504 meteorology & atmospheric sciences, Cretaceous–Paleogene boundary, 010502 geochemistry & geophysics, 01 natural sciences, Chicxulub crater, Sedimentary depositional environment, Paleontology, Impact crater, Iridium anomaly, SDG 14 - Life Below Water, Impact structure, ComputingMilieux_MISCELLANEOUS, Research Articles, 0105 earth and related environmental sciences, Horizon (geology), Extinction event, Multidisciplinary, SciAdv r-articles, Généralités, Geology, IODP-ICDP Expedition 364 Scientists, K-Pg boundary, Chemistry, [SDU]Sciences of the Universe [physics], Hypervelocity, mass extinction, Research Article
Abstract

The Cretaceous-Paleogene (K-Pg) mass extinction is marked globally by elevated concentrations of iridium, emplaced by a hypervelocity impact event 66 million years ago. Here, we report new data from four independent laboratories that reveal a positive iridium anomaly within the peak-ring sequence of the Chicxulub impact structure, in drill core recovered by IODP-ICDP Expedition 364. The highest concentration of ultrafine meteoritic matter occurs in the post-impact sediments that cover the crater peak ring, just below the lowermost Danian pelagic limestone. Within years to decades after the impact event, this part of the Chicxulub impact basin returned to a relatively low-energy depositional environment, recording in unprecedented detail the recovery of life during the succeeding millennia. The iridium layer provides a key temporal horizon precisely linking Chicxulub to K-Pg boundary sections worldwide., SCOPUS: ar.j, info:eu-repo/semantics/published

Published
2020
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23. Winding down the Chicxulub impact: The transition between impact and normal marine sedimentation near ground zero

Author

Whalen, Michael, Gulick, Sean P.S., Lowery, Christopher, Bralower, Timothy, Morgan, Joanna, Grice, Kliti, Schaefer, Bettina, Smit, Jan, Ormö, Jens, Wittmann, Axel, Kring, David, Lyons, Shelby, Goderis, Steven, Chenot, Elise, Christeson, Gail l., Clayes, Philippe, Cockell, Charles S., Coolen, Marco, Gebhardt, Catalina, Goto, Kazuhisa, Jones, Heather, LOFI, Johanna, IODP-ICDP Expedition 364 scientists,, Perez-Cruz, Ligia, Pickersgill, Annemarie E., Poelchau, Michael H., Rae, A.S.P., Green, Sophie L., Rasmussen, Cornelia, Sato, Honami, Tikoo, Sonia, Tomioka, Naotaka, Urrutia Fucugauchi, Jaime, Xiao, Long, Yamaguchi, Kosei E., Unidad de Excelencia Científica María de Maeztu Centro de Astrobiología del Instituto Nacional de Técnica Aeroespacial y CSIC, MDM-2017-0737, Goderis, S. [0000-0002-6666-7153], Riller, U. [0000-0002-3803-6792], Smit, J. [0000-0002-6070-4865], National Science Foundation (NSF), Australian Research Council (ARC), Belgian Science Policy Office (BELSPO), Ministerio de Economía y Competitividad (MINECO), Agencia Estatal de Investigación (AEI), Geology and Geochemistry, Natural Environment Research Council (NERC), University of Alaska [Fairbanks] (UAF), IODP Grant, G11100, National Science Foundation (NSF), OCE 14-50528 1737199 OCE 1736951 OCE 1736826 OCE 1737087 OCE 1737351, Australian Research Council Grant, DP180100982, Analytical, Environmental & Geo-Chemistry, and Chemistry

Subjects
010504 meteorology & atmospheric sciences, 04 Earth Sciences, Geochemistry, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Impact crater, Continental margin, Geochemistry and Petrology, Breccia, 14. Life underwater, SDG 14 - Life Below Water, Ejecta, Graded bedding, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, Gulf of Mexico, Tsunami, Carbon isotopes, Sediment, Seiche, Geology, International Ocean Discovery Program, Pelagic sediment, Pelagic sediments, [SDU]Sciences of the Universe [physics], 13. Climate action
Abstract

IODP-ICDP Expedition 364 Scientists complete list of expedition scientists is in Appendix A., The Chicxulub impact led to the formation of a ~ 200-km wide by ~1-km deep crater on México's Yucatán Peninsula. Over a period of hours after the impact the ocean re-entered and covered the impact basin beneath several hundred meters of water. A suite of impactites were deposited across the crater during crater formation, and by the resurge, tsunami and seiche events that followed. International Ocean Discovery Program/International Continental Scientific Drilling Program Expedition 364 drilled into the peak ring of the Chicxulub crater, and recovered ~130 m of impact deposits and a 75-cm thick, fine-grained, carbonate-rich “Transitional Unit”, above which normal marine sedimentation resumed. Here, we describe the results of analyses of the uppermost impact breccia (suevite) and the Transitional Unit, which suggests a gradual waning of energy recorded by this local K-Pg boundary sequence. The dominant depositional motif in the upper suevite and the Transitional Unit is of rapid sedimentation characterized by graded bedding, local cross bedding, and evidence of oscillatory currents. The lower Transitional Unit records the change from deposition of dominantly sand-sized to mainly silt to clay sized material with impact debris that decreases in both grain size and abundance upward. The middle part of the Transitional Unit is interrupted by a 20 cm thick soft sediment slump overlain by graded and oscillatory current cross-laminated beds. The uppermost Transitional Unit is also soft sediment deformed, contains trace fossils, and an increasing abundance of planktic foraminifer and calcareous nannoplankton survivors. The Transitional Unit, as with similar deposits in other marine target impact craters, records the final phases of impact-related sedimentation prior to resumption of normal marine conditions. Petrographic and stable isotopic analyses of carbon from organic matter provide insight into post-impact processes. δC values are between terrestrial and marine end members with fluctuations of 1–3‰. Timing of deposition of the Transitional Unit is complicated to ascertain. The repetitive normally graded laminae, both below and above the soft sediment deformed interval, record rapid deposition from currents driven by tsunami and seiches, processes that likely operated for weeks to potentially years post-impact due to subsequent continental margin collapse events. Highly siderophile element-enrichment at the top of the unit is likely from fine-grained ejecta that circulated in the atmosphere for several years prior to settling. The Transitional Unit is thus an exquisite record of the final phases of impact-related sedimentation related to one of the most consequential events in Earth history., ESP2015-65712-C5-1-R, and ESP2017-87676-C5-1-R from the Spanish Ministry of Economy and Competitiveness and Fondo Europeo de Desarrollo Regional ; With funding from the Spanish government through the "María de Maeztu Unit of Excellence" accreditation (MDM-2017-0737)

Published
2020
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24. U-Pb zircon geochronology and depositional age models for the Upper Triassic Chinle Formation (Petrified Forest National Park, Arizona, USA): implications for Late Triassic paleoecological and paleoenvironmental change

Author

Rasmussen, Cornelia, Mundil, Roland, Irmis, Randall B., Giesler, Dominique, Gehrels, George E., Olsen, Paul E., Kent, Dennis V., Lepre, Christopher J., Kinney, Sean T., Geissman, John W., and Parker, William G.

Subjects
Geology, Stratigraphic, Geological time, Zircon--Analysis, Paleoecology, Paleoclimatology
Abstract

The Upper Triassic Chinle Formation is a critical non-marine archive of low-paleolatitude biotic and environmental change in southwestern North America. The well-studied and highly fossiliferous Chinle strata at Petrified Forest National Park (PFNP), Arizona, preserve a biotic turnover event recorded by vertebrate and palynomorph fossils, which has been alternatively hypothesized to coincide with tectonically driven climate change or with the Manicouagan impact event at ca. 215.5 Ma. Previous outcrop-based geochronologic age constraints are difficult to put in an accurate stratigraphic framework because lateral facies changes and discontinuous outcrops allow for multiple interpretations. A major goal of the Colorado Plateau Coring Project (CPCP) was to retrieve a continuous record in unambiguous superposition designed to remedy this situation. We sampled the 520-m-long core 1A of the CPCP to develop an accurate age model in unquestionable superposition by combining U-Pb zircon ages and magnetostratigraphy. From 13 horizons of volcanic detritus-rich siltstone and sandstone, we screened up to ∼300 zircon crystals per sample using laser ablation−inductively coupled plasma−mass spectrometry and subsequently analyzed up to 19 crystals of the youngest age population using the chemical abrasion−isotope dilution−thermal ionization mass (CA-ID-TIMS) spectrometry method. These data provide new maximum depositional ages for the top of the Moenkopi Formation (ca. 241 Ma), the lower Blue Mesa Member (ca. 222 Ma), and the lower (ca. 218 to 217 Ma) and upper (ca. 213.5 Ma) Sonsela Member. The maximum depositional ages obtained for the upper Chinle Formation fall well within previously proposed age constraints, whereas the maximum depositional ages for the lower Chinle Formation are relatively younger than previously proposed ages from outcrop; however, core to outcrop stratigraphic correlations remain uncertain. By correlating our new ages with the magnetostratigraphy of the core, two feasible age model solutions can be proposed. Model 1 assumes that the youngest, coherent U-Pb age clusters of each sample are representative of the maximum depositional ages and are close to (227 Ma) in age, and hence the biotic turnover event cannot be correlated to the Carnian−Norian boundary but is rather a mid-Norian event. Our age models demonstrate the powers, but also the challenges, of integrating detrital CA-ID-TIMS ages with magnetostratigraphic data to properly interpret complex sedimentary sequences.

Published
2020
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25. Probing the hydrothermal system of the Chicxulub impact crater

Author

Kring, David A., Tikoo, Sonia M., Schmieder, Martin, Riller, Ulrich, Rebolledo-Vieyra, Mario, Simpson, Sarah L., Osinski, Gordon R., Gattacceca, Jérôme, Wittmann, Axel, Verhagen, Christina M., Cockell, Charles S., Coolen, Marco J. L., Longstaffe, Fred J., Gulick, Sean P. S., Morgan, Joanna V., Bralower, Timothy J., Chenot, Elise, Christeson, Gail L., Claeys, Philippe, Ferrière, Ludovic, Gebhardt, Catalina, Goto, Kazuhisa, Green, Sophie L., Jones, Heather, Lofi, Johanna, Lowery, Christopher M., Ocampo-Torres, Rubén, Perez-Cruz, Ligia, Pickersgill, Annemarie E., Poelchau, Michael H., Rae, Auriol S. P., Rasmussen, Cornelia, Sato, Honami, Smit, Jan, Tomioka, Naotaka, Urrutia-Fucugauchi, Jaime, Whalen, Michael T., Xiao, Long, Yamaguchi, Kosei E., Kring, David A., Tikoo, Sonia M., Schmieder, Martin, Riller, Ulrich, Rebolledo-Vieyra, Mario, Simpson, Sarah L., Osinski, Gordon R., Gattacceca, Jérôme, Wittmann, Axel, Verhagen, Christina M., Cockell, Charles S., Coolen, Marco J. L., Longstaffe, Fred J., Gulick, Sean P. S., Morgan, Joanna V., Bralower, Timothy J., Chenot, Elise, Christeson, Gail L., Claeys, Philippe, Ferrière, Ludovic, Gebhardt, Catalina, Goto, Kazuhisa, Green, Sophie L., Jones, Heather, Lofi, Johanna, Lowery, Christopher M., Ocampo-Torres, Rubén, Perez-Cruz, Ligia, Pickersgill, Annemarie E., Poelchau, Michael H., Rae, Auriol S. P., Rasmussen, Cornelia, Sato, Honami, Smit, Jan, Tomioka, Naotaka, Urrutia-Fucugauchi, Jaime, Whalen, Michael T., Xiao, Long, and Yamaguchi, Kosei E.

Abstract

The ~180-km-diameter Chicxulub peak-ring crater and ~240-km multiring basin, produced by the impact that terminated the Cretaceous, is the largest remaining intact impact basin on Earth. International Ocean Discovery Program (IODP) and International Continental Scientific Drilling Program (ICDP) Expedition 364 drilled to a depth of 1335 m below the sea floor into the peak ring, providing a unique opportunity to study the thermal and chemical modification of Earth’s crust caused by the impact. The recovered core shows the crater hosted a spatially extensive hydrothermal system that chemically and mineralogically modified ~1.4 × 105 km3 of Earth’s crust, a volume more than nine times that of the Yellowstone Caldera system. Initially, high temperatures of 300° to 400°C and an independent geomagnetic polarity clock indicate the hydrothermal system was long lived, in excess of 106 years.

Published
2020

27. LA-ICPMS U–Pb geochronology of detrital zircon grains from the Coconino, Moenkopi, and Chinle formations in the Petrified Forest National Park (Arizona)

Author

Gehrels, George, primary, Giesler, Dominique, additional, Olsen, Paul, additional, Kent, Dennis, additional, Marsh, Adam, additional, Parker, William, additional, Rasmussen, Cornelia, additional, Mundil, Roland, additional, Irmis, Randall, additional, Geissman, John, additional, and Lepre, Christopher, additional

Published
2020
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28. U-Pb zircon geochronology and depositional age models for the Upper Triassic Chinle Formation (Petrified Forest National Park, Arizona, USA): Implications for Late Triassic paleoecological and paleoenvironmental change

Author

Rasmussen, Cornelia, primary, Mundil, Roland, additional, Irmis, Randall B., additional, Geisler, Dominique, additional, Gehrels, George E., additional, Olsen, Paul E., additional, Kent, Dennis V., additional, Lepre, Christopher, additional, Kinney, Sean T., additional, Geissman, John W., additional, and Parker, William G., additional

Published
2020
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30. Probing the hydrothermal system of the Chicxulub impact crater

Author

Kring, David A., primary, Tikoo, Sonia M., additional, Schmieder, Martin, additional, Riller, Ulrich, additional, Rebolledo-Vieyra, Mario, additional, Simpson, Sarah L., additional, Osinski, Gordon R., additional, Gattacceca, Jérôme, additional, Wittmann, Axel, additional, Verhagen, Christina M., additional, Cockell, Charles S., additional, Coolen, Marco J. L., additional, Longstaffe, Fred J., additional, Gulick, Sean P. S., additional, Morgan, Joanna V., additional, Bralower, Timothy J., additional, Chenot, Elise, additional, Christeson, Gail L., additional, Claeys, Philippe, additional, Ferrière, Ludovic, additional, Gebhardt, Catalina, additional, Goto, Kazuhisa, additional, Green, Sophie L., additional, Jones, Heather, additional, Lofi, Johanna, additional, Lowery, Christopher M., additional, Ocampo-Torres, Rubén, additional, Perez-Cruz, Ligia, additional, Pickersgill, Annemarie E., additional, Poelchau, Michael H., additional, Rae, Auriol S. P., additional, Rasmussen, Cornelia, additional, Sato, Honami, additional, Smit, Jan, additional, Tomioka, Naotaka, additional, Urrutia-Fucugauchi, Jaime, additional, Whalen, Michael T., additional, Xiao, Long, additional, and Yamaguchi, Kosei E., additional

Published
2020
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31. The first day of the Cenozoic

Author

Gulick, Sean, Bralower, Timothy, Ormö, Jens, Hall, Brendon, Grice, Kliti, Schaefer, Bettina, Lyons, Shelby, Freeman, Katherine, Morgan, Joanna, Artemieva, Natalia, Kaskes, Pim, De Graaff, Sietze, Whalen, Michael, Collins, Gareth, Tikoo, Sonia, Verhagen, Christina, Christeson, Gail, Claeys, Philippe, Coolen, Marco, Goderis, Steven, Goto, Kazuhisa, Grieve, Richard, McCall, Naoma, Osinski, Gordon, Rae, Auriol, Riller, Ulrich, Smit, Jan, Vajda, Vivi, Wittmann, Axel, Chenot, Elise, Cockell, Charles S., Ferrière, Ludovic, Gebhardt, Catalina, Green, Sophie L., Jones, Heather, Kring, David A., LeBer, Erwan, LOFI, Johanna, Lowery, Christopher M., OCAMPO-TORRES, Ruben, Perez-Cruz, Ligia, Pickersgill, Annemarie E., Poelchau, Michael H., Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Schmitt, D, Tomioka, Naotaka, Urrutia-Fucugauchi, Jaimie, Long, Xiao, Yamaguchi, Kosei E., Geology and Geochemistry, Institut de chimie et procédés pour l'énergie, l'environnement et la santé (ICPEES), Université de Strasbourg (UNISTRA)-Matériaux et nanosciences d'Alsace (FMNGE), Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), University of Texas at Austin [Austin], Department of Geosciences, Pennsylvania State University (Penn State), Penn State System-Penn State System, Centro de Astrobiologia [Madrid] (CAB), Instituto Nacional de Técnica Aeroespacial (INTA)-Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), Imperial College London, Analytical, Environmental and Geo- Chemistry, Vrije Universiteit Brussel (VUB), University of Alaska [Fairbanks] (UAF), Department of Earth Science and Engineering [Imperial College London], Department of Earth and Planetary Sciences [Piscataway], Rutgers, The State University of New Jersey [New Brunswick] (RU), Rutgers University System (Rutgers)-Rutgers University System (Rutgers), Institute of Geophysics [Austin] (IG), International Research Institute of Disaster Science, Tohoku University [Sendai], Centre for Planetary Science and Exploration [London, ON] (CPSX), University of Western Ontario (UWO), Department of Earth Science and Technology [Imperial College London], Universität Hamburg (UHH), Faculty of Earth and Life Sciences [Amsterdam] (FALW), Vrije Universiteit Amsterdam [Amsterdam] (VU), Department of Earth and Ecosystem Sciences [Lund], Lund University [Lund], Arizona State University [Tempe] (ASU), Chemistry, Analytical, Environmental & Geo-Chemistry, Faculty of Sciences and Bioengineering Sciences, Earth System Sciences, and Natural Environment Research Council (NERC)

Subjects
ONAPING FORMATION, Cretaceous-Paleogene, 010504 meteorology & atmospheric sciences, GULF-OF-MEXICO, Annan geovetenskap och miljövetenskap, Cretaceous–Paleogene boundary, Window (geology), ASTEROID IMPACT, 010502 geochemistry & geophysics, 01 natural sciences, POLYCYCLIC AROMATIC-HYDROCARBONS, Paleontology, suevite, SUEVITE REVISITED-OBSERVATIONS, CRETACEOUS-PALEOGENE BOUNDARY, [CHIM]Chemical Sciences, 14. Life underwater, SDG 14 - Life Below Water, RIES CRATER, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, Science & Technology, Multidisciplinary, Expedition 364 Scientists, Tsunami, TERTIARY BOUNDARY, Scientific drilling, CHICXULUB IMPACT EVENT, International Ocean Discovery Program, peak ring, Multidisciplinary Sciences, Peak ring, EXTINCTION, PNAS Plus, 13. Climate action, Cretaceous–Paleogene, [SDU]Sciences of the Universe [physics], [SDE]Environmental Sciences, Chicxulub impact crater, Science & Technology - Other Topics, tsunami, Suevite, Cenozoic, Geology, Other Earth and Related Environmental Sciences
Abstract

Highly expanded Cretaceous–Paleogene (K-Pg) boundary section from the Chicxulub peak ring, recovered by International Ocean Discovery Program (IODP) –International Continental Scientific Drilling Program (ICDP) Expedition 364, provides an unprecedented window into the immediate aftermath of the impact. Site M0077 includes ∼130 m of impact melt rock and suevite deposited the first day of the Cenozoic covered by Additional funding from:The European Consortium for Ocean Research Drilling (ECORD) implemented Expedition 364 with funding from the IODP and the ICDP. US participants were supported by the US Science Support Program and National Science Foundation Grants OCE 1737351, OCE 1736826, OCE 1737087, OCE 1737037, OCE 1736951, and OCE 1737199. J.O. was partially supported by Grants ESP2015-65712-C5-1-R and ESP2017-87676-C5-1-R from the Spanish Ministry of Economy and Competitiveness and Fondo Europeo de Desarrollo Regional. B.S. thanks Curtin University for an Australian Postgraduate Award. J.V.M. was funded by Natural Environment Research Council Grant NE/P005217/1. K. Grice thanks Australia Research Council for Grant DP180100982 and Australia New Zealand IODP Consortium for funding. The Vrije Universiteit Brussel group is supported by Research Foundation Flanders (FWO) and BELSPO; P.K. is an FWO PhD fellow.

Published
2019
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32. Impact-induced porosity and micro-fracturing at the Chicxulub impact structure

Author

Rae, Auriol, Collins, Gareth, Morgan, Joanna, Salge, Tobias, Christeson, Gail, Leung, Jody, Lofi, Johanna, Gulick, Sean, Poelchau, Michael, Riller, Ulrich, Gebhardt, Catalina, Grieve, Richard, Osinski, Gordon, Chenot, Elise, Claeys, Philippe, Cockell, Charles S., Coolen, Marco J.L., Ferrière, Ludovic, Goto, Kazuhisa, Green, Sophie, Jones, Heather, Kring, David A., Lowery, Christopher, IODP-ICDP Expedition 364 scientists,, Perez-Cruz, Ligia, Pickersgill, Annemarie E., Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Sato, Honami, Smit, Jan, Tikoo-Schantz, Sonia M., Tomioka, Naotaka, Urrutia-Fucugauchi, Jaime, Whalen, Michael T., Wittmann, Axel, Xiao, Long, Yamaguchi, Kosei E., Science and Technology Facilities Council (STFC), Natural Environment Research Council (NERC), Department of Earth Science and Engineering [Imperial College London], Imperial College London, The Natural History Museum [London] (NHM), University of Texas at Austin [Austin], Géosciences Montpellier, Institut national des sciences de l'Univers (INSU - CNRS)-Université de Montpellier (UM)-Université des Antilles (UA)-Centre National de la Recherche Scientifique (CNRS), Albert-Ludwigs-Universität Freiburg, Universität Hamburg (UHH), Alfred-Wegener-Institut, Helmholtz-Zentrum für Polar- und Meeresforschung (AWI), University of Western Ontario (UWO), Mémoires - Université de Montpellier - Faculté des sciences (UM FS), and Université de Montpellier (UM)

Subjects
Geochemistry & Geophysics, porosity, 010504 meteorology & atmospheric sciences, [SDU.STU.GP]Sciences of the Universe [physics]/Earth Sciences/Geophysics [physics.geo-ph], 01 natural sciences, Gravity anomaly, Seismic wave, Impact crater, GRAVITY, Geochemistry and Petrology, DEFORMATION, CRATER, Earth and Planetary Sciences (miscellaneous), Impact structure, Petrology, Magnetic anomaly, CRUSTAL STRUCTURE, ComputingMilieux_MISCELLANEOUS, 0105 earth and related environmental sciences, Science & Technology, ORIGIN, Scientific drilling, Petrophysics, cratering, YUCATAN, International Ocean Discovery Program, fractures, Geophysics, Chicxulub, SIZE, PEAK-RING FORMATION, [SDU]Sciences of the Universe [physics], 13. Climate action, Space and Planetary Science, Physical Sciences, ASYMMETRY, Geology, HYDROCODE SIMULATIONS
Abstract

International audience; Porosity and its distribution in impact craters has an important effect on the petrophysical properties of impactites: seismic wave speeds and reflectivity, rock permeability, strength, and density. These properties are important for the identification of potential craters and the understanding of the process and consequences of cratering. The Chicxulub impact structure, recently drilled by the joint International Ocean Discovery Program and International Continental scientific Drilling Program Expedition 364, provides a unique opportunity to compare direct observations of impactites with geophysical observations and models. Here, we combine small-scale petrographic and petrophysical measurements with larger-scale geophysical measurements and numerical simulations of the Chicxulub impact structure. Our aim is to assess the cause of unusually high porosities within the Chicxulub peak ring and the capability of numerical impact simulations to predict the gravity signature and the distribution and texture of porosity within craters. We show that high porosities within the Chicxulub peak ring are primarily caused by shock-induced microfracturing. These fractures have preferred orientations, which can be predicted by considering the orientations of principal stresses during shock, and subsequent deformation during peak ring formation. Our results demonstrate that numerical impact simulations, implementing the Dynamic Collapse Model of peak ring formation, can accurately predict the distribution and orientation of impact-induced microfractures in large craters, which plays an important role in the geophysical signature of impact structures. Plain Language Summary The Chicxulub crater, Mexico, is widely known for its association with the extinction of the nonavian dinosaurs at the end of the Cretaceous period. The crater was first identified due to its gravitational and magnetic anomalies. Potential impact structures are often identified, in part, on the basis of geophysical anomalies, most commonly including a circular gravity low. Gravity is slightly weaker at craters because the impact cratering process removes mass from the impact site. In this study, we examine the cause of the Chicxulub gravity anomaly by combining observations from recent drilling of the crater, geophysical data measured across the crater, and numerical impact simulations. We demonstrate that porosity in rocks beneath the crater floor is primarily accommodated by fracturing during the impact cratering process, that the orientation of those fractures are consistent with predictions from numerical impact simulations, and that impact-induced porosity is one of the primary causes of gravity anomalies in large impact craters.

Published
2019
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33. Magnetochronology of the Entire Chinle Formation (Norian Age) in a Scientific Drill Core From Petrified Forest National Park (Arizona, USA) and Implications for Regional and Global Correlations in the Late Triassic

Author

Kent, Dennis V., Olsen, Paul E., Lepre, Christopher J., Rasmussen, Cornelia, Mundil, Roland, Gehrels, George E., Giesler, Dominique, Irmis, Randall B., Geissman, John W., and Parker, William G.

Subjects
Paleomagnetism, Geophysics, Geology, Stratigraphic, Geological time, FOS: Earth and related environmental sciences
Abstract

Building on an earlier study that confirmed the stability of the 405‐kyr eccentricity climate cycle and the timing of the Newark‐Hartford astrochronostratigraphic polarity time scale back to 215 Ma, we extend the magnetochronology of the Late Triassic Chinle Formation to its basal unconformity in scientific drill core PFNP‐1A from Petrified Forest National Park (Arizona, USA). The 335‐m‐thick Chinle section is imprinted with paleomagnetic polarity zones PF1r to PF10n, which we correlate to chrons E17r to E9n (~209 to 224 Ma) of the Newark‐Hartford astrochronostratigraphic polarity time scale. A sediment accumulation rate of ~34 m/Myr can be extended down to ~270 m, close to the base of the Sonsela Member and the base of magnetozone PF5n, which we correlate to chron E14n that onsets at 216.16 Ma. Magnetozones PF5r to PF10n in the underlying 65‐m‐thick section of the mudstone‐dominated Blue Mesa and Mesa Redondo members plausibly correlate to chrons E13r to E9n, indicating a sediment accumulation rate of only ~10 m/Myr. Published high‐precision U‐Pb detrital zircon dates from the lower Chinle tend to be several million years older than the magnetochronological age model. The source of this discrepancy is unclear but may be due to sporadic introduction of juvenile zircons that get recycled. The new magnetochronological constraint on the base of the Sonsela Member brings the apparent timing of the included Adamanian‐ Revueltian land vertebrate faunal zone boundary and the Zone II to Zone III palynofloral transition closer to the temporal range of the ~215 Ma Manicouagan impact structure in Canada.

Published
2019
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34. Ocean Drilling Perspectives on Meteorite Impacts

Author

Lowery, Chistopher, Morgan, Joanna, Gulick, Sean, Bralower, Timothy, Christeson, Gail, Chenot, Elise, Claeys, P., Cockell, C., Coolen, Marco J L, Ferrière, Ludovic, Gebhardt, Catalina, Goto, K., Green, Sophie, Jones, Heather, Kring, D. A., Lofi, Johanna, Mellett, C., Ocampo-Torres, Ruben, Perez-Cruz, Ligia, Pickersgill, Annemarie E, Poelchau, Michael, Rae, Auriol S P, Rasmussen, Cornelia, Rebolledo-Vieyra, M., Riller, U., Sato, H., Smith, J., Tikoo, S., Tomioka, Naotaka, Urrutia-Fucugauchi, J., Whalen, M.T., Wittmann, Axel, Xiao, L., Yamaguchi, Kosei E, Lowery, Chistopher, Morgan, Joanna, Gulick, Sean, Bralower, Timothy, Christeson, Gail, Chenot, Elise, Claeys, P., Cockell, C., Coolen, Marco J L, Ferrière, Ludovic, Gebhardt, Catalina, Goto, K., Green, Sophie, Jones, Heather, Kring, D. A., Lofi, Johanna, Mellett, C., Ocampo-Torres, Ruben, Perez-Cruz, Ligia, Pickersgill, Annemarie E, Poelchau, Michael, Rae, Auriol S P, Rasmussen, Cornelia, Rebolledo-Vieyra, M., Riller, U., Sato, H., Smith, J., Tikoo, S., Tomioka, Naotaka, Urrutia-Fucugauchi, J., Whalen, M.T., Wittmann, Axel, Xiao, L., and Yamaguchi, Kosei E

Abstract

Extraterrestrial impacts that reshape the surfaces of rocky bodies are ubiquitous in the solar system. On early Earth, impact structures may have nurtured the evolution of life. More recently, a large meteorite impact off the Yucatán Peninsula in Mexico at the end of the Cretaceous caused the disappearance of 75% of species known from the fossil record, including non-avian dinosaurs, and cleared the way for the dominance of mammals and the eventual evolution of humans. Understanding the fundamental processes associated with impact events is critical to understanding the history of life on Earth, and the potential for life in our solar system and beyond. Scientific ocean drilling has generated a large amount of unique data on impact pro- cesses. In particular, the Yucatán Chicxulub impact is the single largest and most sig- nificant impact event that can be studied by sampling in modern ocean basins, and marine sediment cores have been instrumental in quantifying its environmental, cli- matological, and biological effects. Drilling in the Chicxulub crater has significantly advanced our understanding of fundamental impact processes, notably the formation of peak rings in large impact craters, but these data have also raised new questions to be addressed with future drilling. Within the Chicxulub crater, the nature and thickness of the melt sheet in the central basin is unknown, and an expanded Paleocene hemipelagic section would provide insights to both the recovery of life and the climatic changes that followed the impact. Globally, new cores collected from today’s central Pacific could directly sample the downrange ejecta of this northeast-southwest trending impact. Extraterrestrial impacts have been controversially suggested as primary drivers for many important paleoclimatic and environmental events throughout Earth history. However, marine sediment archives collected via scientific ocean drilling and geo- chemical proxies (e.g., osmium isotopes) provide a long-te

Published
2019

35. Rock fluidization during peak-ring formation of large impact structures

Author

Riller, Ulrich, Poelchau, Michael H., Rae, Auriol S. P., Schulte, Felix M., Collins, Gareth S., Melosh, H. Jay, Grieve, Richard A. F., Morgan, Joanna V., Gulick, Sean P. S., Lofi, Johanna, Diaw, Abdoulaye, McCall, Naoma, Kring, David A., Green, Sophie L., Chenot, Elise, Christeson, Gail L., Claeys, Philippe, Cockell, Charles S., Coolen, Marco J. L., Ferrière, Ludovic, Gebhardt, Catalina, Goto, Kazuhisa, Jones, Heather, Long, Xiao, Lowery, Christopher M., Ocampo-Torres, Rubén, Pérez-Cruz, Ligia, Pickersgill, Annemarie E., Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Sato, Honami, Smit, Jan, Tikoo-Schantz, Sonia M., Tomioka, Naotaka, Whalen, Michael T., Wittmann, Axel, Yamaguchi, Kosei E., Fucugauchi, Jaime Urrutia, Bralower, Timothy J., IODP–ICDP Expedition 364 Science Party, Institut für Geologie, Universität Hamburg (UHH), Department of Geology, University of Freiburg [Freiburg], Department of Earth Science and Engineering [Imperial College London], Imperial College London, Department of Earth, Atmospheric, and Planetary Sciences [West Lafayette] (EAPS), Purdue University [West Lafayette], Centre for Planetary Science and Exploration [London, ON] (CPSX), University of Western Ontario (UWO), Institute of Geophysics [Austin] (IG), University of Texas at Austin [Austin], Department of Geological Sciences [Austin], Jackson School of Geosciences (JSG), University of Texas at Austin [Austin]-University of Texas at Austin [Austin], Géosciences Montpellier, Institut national des sciences de l'Univers (INSU - CNRS)-Université de Montpellier (UM)-Université des Antilles (UA)-Centre National de la Recherche Scientifique (CNRS), Universities Space Research Association (USRA), British Geological Survey [Edinburgh], British Geological Survey (BGS), Biogéosciences [UMR 6282] [Dijon] (BGS), Université de Bourgogne (UB)-AgroSup Dijon - Institut National Supérieur des Sciences Agronomiques, de l'Alimentation et de l'Environnement-Centre National de la Recherche Scientifique (CNRS), Analytical, Environmental and Geo- Chemistry, Vrije Universiteit Brussel (VUB), SUPA School of Physics and Astronomy [Edinburgh], University of Edinburgh, WA-Organic and Isotope Geochemistry Centre (WA-OIGC), The Institute for Geoscience Research [Perth] (TIGeR), School of Earth and Planetary Science [Perth - Curtin university], Curtin University [Perth], Planning and Transport Research Centre (PATREC)-Planning and Transport Research Centre (PATREC)-Curtin University [Perth], Planning and Transport Research Centre (PATREC)-Planning and Transport Research Centre (PATREC)-School of Earth and Planetary Science [Perth - Curtin university], Planning and Transport Research Centre (PATREC)-Planning and Transport Research Centre (PATREC), Natural History Museum [Vienna] (NHM), Alfred-Wegener-Institut, Helmholtz-Zentrum für Polar- und Meeresforschung (AWI), International Research Institute of Disaster Science, Tohoku University [Sendai], Pennsylvania State University (Penn State), Penn State System, China University of Geosciences [Beijing], Institut de chimie et procédés pour l'énergie, l'environnement et la santé (ICPEES), Université de Strasbourg (UNISTRA)-Matériaux et nanosciences d'Alsace (FMNGE), Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC)-Université de Strasbourg (UNISTRA)-Université de Haute-Alsace (UHA) Mulhouse - Colmar (Université de Haute-Alsace (UHA))-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Instituto de Geofisica [Mexico], Universidad Nacional Autónoma de México (UNAM), School of Geographical and Earth Sciences, University of Glasgow, NERC Argon Isotope Facility [Glasgow], Scottish Universities Environmental Research Centre (SUERC), University of Glasgow-University of Edinburgh-University of Glasgow-University of Edinburgh-Natural Environment Research Council (NERC), Unidad de Ciencias del Agua, Japan Agency for Marine-Earth Science and Technology (JAMSTEC), Faculty of Earth and Life Sciences [Amsterdam] (FALW), Vrije Universiteit Amsterdam [Amsterdam] (VU), Department of Earth and Planetary Sciences [Piscataway], Rutgers, The State University of New Jersey [New Brunswick] (RU), Rutgers University System (Rutgers)-Rutgers University System (Rutgers), Kochi Institute for Core Sample Research, Department of Geosciences, University of Alaska [Fairbanks] (UAF), Eyring Materials Center, Arizona State University [Tempe] (ASU), Department of Chemistry, Toho University, NASA Astrobiology Institute (NAI), Work supported by the Priority Programs 527 and 1006 of the German Science Foundation (grants Ri 916/16-1 and PO 1815/2-1), National Science Foundation grants (OCE-1737351, OCE-1450528 and OCE-1736826), and Natural Environment Research Council (grants NE/P011195/1 and NE/P005217/1), by the European Consortium for Ocean Research Drilling (ECORD) and the IODP as Expedition 364 with co-funding from the ICDP., Science and Technology Facilities Council (STFC), Natural Environment Research Council (NERC), Analytical, Environmental & Geo-Chemistry, Earth System Sciences, and Chemistry

Subjects
Solar System, 010504 meteorology & atmospheric sciences, ACOUSTIC FLUIDIZATION, General Science & Technology, Flow (psychology), [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, Deformation (meteorology), 010502 geochemistry & geophysics, 01 natural sciences, Brittleness, DEFORMATION, Fluidization, Impact structure, Petrology, COLLAPSE, IODP–ICDP Expedition 364 Science Party, 0105 earth and related environmental sciences, Multidisciplinary, Science & Technology, EXAMPLE, Drilling, SIMULATIONS, CHICXULUB CRATER, Multidisciplinary Sciences, TARGET, Meteorite, SUDBURY, general, ASYMMETRY, Science & Technology - Other Topics, VREDEFORT, Geology
Abstract

8 pages; International audience; Large meteorite impact structures on the terrestrial bodies of the Solar System contain pronounced topographic rings, which emerged from uplifted target (crustal) rocks within minutes of impact. To flow rapidly over large distances, these target rocks must have weakened drastically, but they subsequently regained sufficient strength to build and sustain topographic rings. The mechanisms of rock deformation that accomplish such extreme change in mechanical behaviour during cratering are largely unknown and have been debated for decades. Recent drilling of the approximately 200-km-diameter Chicxulub impact structure in Mexico has produced a record of brittle and viscous deformation within its peak-ring rocks. Here we show how catastrophic rock weakening upon impact is followed by an increase in rock strength that culminated in the formation of the peak ring during cratering. The observations point to quasi-continuous rock flow and hence acoustic fluidization as the dominant physical process controlling initial cratering, followed by increasingly localized faulting.

Published
2018
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36. Ocean Drilling Perspectives on Meteorite Impacts

Author

Lowery, Chistopher, Morgan, Joanna, Gulick, Sean, Bralower, Timothy, Christeson, Gail, Chenot, Elise, Claeys, P., Cockell, C., Coolen, Marco J L, Ferrière, Ludovic, Gebhardt, Catalina, Goto, K., Green, Sophie, Jones, Heather, Kring, D. A., Lofi, Johanna, Mellett, C., Ocampo-Torres, Ruben, Perez-Cruz, Ligia, Pickersgill, Annemarie E, Poelchau, Michael, Rae, Auriol S P, Rasmussen, Cornelia, Rebolledo-Vieyra, M., Riller, U., Sato, H., Smith, J., Tikoo, S., Tomioka, Naotaka, Urrutia-Fucugauchi, J., Whalen, M.T., Wittmann, Axel, Xiao, L., Yamaguchi, Kosei E, Analytical, Environmental & Geo-Chemistry, Earth System Sciences, and Chemistry

Subjects
bepress|Physical Sciences and Mathematics|Earth Sciences|Paleontology, bepress|Physical Sciences and Mathematics, EarthArXiv|Physical Sciences and Mathematics|Oceanography and Atmospheric Sciences and Meteorology, 010504 meteorology & atmospheric sciences, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Paleobiology, Earth science, bepress|Physical Sciences and Mathematics|Earth Sciences, EarthArXiv|Physical Sciences and Mathematics|Planetary Sciences|Planetary Geophysics and Seismology, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Stratigraphy, Structural basin, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences, 01 natural sciences, Impact crater, bepress|Physical Sciences and Mathematics|Earth Sciences|Geophysics and Seismology, bepress|Physical Sciences and Mathematics|Oceanography and Atmospheric Sciences and Meteorology, 14. Life underwater, oceanography, Ejecta, 0105 earth and related environmental sciences, EarthArXiv|Physical Sciences and Mathematics|Planetary Sciences|Planetary Geomorphology, Extinction event, geography, geography.geographical_feature_category, 010505 oceanography, 15. Life on land, Early Earth, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Paleontology, bepress|Physical Sciences and Mathematics|Earth Sciences|Stratigraphy, EarthArXiv|Physical Sciences and Mathematics, bepress|Physical Sciences and Mathematics|Earth Sciences|Paleobiology, Meteorite, EarthArXiv|Physical Sciences and Mathematics|Planetary Sciences, 13. Climate action, Extraterrestrial life, EarthArXiv|Physical Sciences and Mathematics|Earth Sciences|Geophysics and Seismology, Oceanic basin, Geology
Abstract

Extraterrestrial impacts that reshape the surfaces of rocky bodies are ubiquitous in the solar system. On early Earth, impact structures may have nurtured the evolution of life. More recently, a large meteorite impact off the Yucatán Peninsula in Mexico at the end of the Cretaceous caused the disappearance of 75% of species known from the fossil record, including non-avian dinosaurs, and cleared the way for the dominance of mammals and the eventual evolution of humans. Understanding the fundamental processes associated with impact events is critical to understanding the history of life on Earth, and the potential for life in our solar system and beyond.\ud \ud Scientific ocean drilling has generated a large amount of unique data on impact processes. In particular, the Yucatán Chicxulub impact is the single largest and most significant impact event that can be studied by sampling in modern ocean basins, and marine sediment cores have been instrumental in quantifying its environmental, climatological, and biological effects. Drilling in the Chicxulub crater has significantly advanced our understanding of fundamental impact processes, notably the formation of peak rings in large impact craters, but these data have also raised new questions to be addressed with future drilling. Within the Chicxulub crater, the nature and thickness of the melt sheet in the central basin is unknown, and an expanded Paleocene hemipelagic section would provide insights to both the recovery of life and the climatic changes that followed the impact. Globally, new cores collected from today’s central Pacific could directly sample the downrange ejecta of this northeast-southwest trending impact.\ud \ud Extraterrestrial impacts have been controversially suggested as primary drivers for many important paleoclimatic and environmental events throughout Earth history. However, marine sediment archives collected via scientific ocean drilling and geochemical proxies (e.g., osmium isotopes) provide a long-term archive of major impact events in recent Earth history and show that, other than the end-Cretaceous, impacts do not appear to drive significant environmental changes.

Published
2018

38. Magnetochronology of the Entire Chinle Formation (Norian Age) in a Scientific Drill Core From Petrified Forest National Park (Arizona, USA) and Implications for Regional and Global Correlations in the Late Triassic

Author

Kent, Dennis V., primary, Olsen, Paul E., additional, Lepre, Christopher, additional, Rasmussen, Cornelia, additional, Mundil, Roland, additional, Gehrels, George E., additional, Giesler, Dominique, additional, Irmis, Randall B., additional, Geissman, John W., additional, and Parker, William G., additional

Published
2019
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39. LA-ICPMS U-Pb geochronology of detrital zircon grains from the Coconino, Moenkopi, and Chinle Formations in the Petrified Forest National Park (Arizona)

Author

Gehrels, George, primary, Giesler, Dominique, additional, Olsen, Paul, additional, Kent, Dennis, additional, Marsh, Adam, additional, Parker, William, additional, Rasmussen, Cornelia, additional, Mundil, Roland, additional, Irmis, Randy, additional, Geissman, John, additional, and Lepre, Christopher, additional

Published
2019
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40. Supplementary material to &quot;LA-ICPMS U-Pb geochronology of detrital zircon grains from the Coconino, Moenkopi, and Chinle Formations in the Petrified Forest National Park (Arizona)&quot;

Author

Gehrels, George, primary, Giesler, Dominique, additional, Olsen, Paul, additional, Kent, Dennis, additional, Marsh, Adam, additional, Parker, William, additional, Rasmussen, Cornelia, additional, Mundil, Roland, additional, Irmis, Randy, additional, Geissman, John, additional, and Lepre, Christopher, additional

Published
2019
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41. Empirical evidence for a stable 405 kiloyear Jupiter-Venus eccentricity climate cycle as a framework for an accurate chronostratigraphy for the Mesozoic and Cenozoic

Author

Kent, Dennis, primary, Olsen, Paul, additional, Rasmussen, Cornelia, additional, Lepre, Christopher, additional, Mundil, Roland, additional, Irmis, Randall, additional, Gehrels, George, additional, Giesler, Dominique, additional, Geissman, John, additional, and Parker, William, additional

Published
2019
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42. Rapid recovery of life at ground zero of the end-Cretaceous mass extinction

Author

Lowery, Christopher M, Bralower, Timothy J, Owens, Jeremy D, Rodriguez-Tovar, Francisco J, Jones, Heather, Smit, Jan, Whalen, Michael T, Claeys, Phillipe, Farley, Kenneth, Gulick, Sean P S, Morgan, Joanna V, Green, Sophie, Chenot, Elise, Christeson, Gail L, Cockell, Charles S, Coolen, Marco J L, Ferrière, Ludovic, Gebhardt, Catalina, Goto, Kazuhisha, Kring, David A, Lofi, Johanna, Ocampo-Torres, Ruben, Perez-Cruz, Ligia, Pickersgill, Annemarie E, Poelchau, Michael H, Rae, Auriol S P, Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Riller, Ulrich, Sato, Honami, Tikoo, Sonia M, Tomioka, Naotaka, Urrutia-Fucugauchi, Jaime, Vellekoop, Johan, Wittmann, Axel, Xiao, Long, Yamaguchi, Kosei E, Zylberman, William, Lowery, Christopher M, Bralower, Timothy J, Owens, Jeremy D, Rodriguez-Tovar, Francisco J, Jones, Heather, Smit, Jan, Whalen, Michael T, Claeys, Phillipe, Farley, Kenneth, Gulick, Sean P S, Morgan, Joanna V, Green, Sophie, Chenot, Elise, Christeson, Gail L, Cockell, Charles S, Coolen, Marco J L, Ferrière, Ludovic, Gebhardt, Catalina, Goto, Kazuhisha, Kring, David A, Lofi, Johanna, Ocampo-Torres, Ruben, Perez-Cruz, Ligia, Pickersgill, Annemarie E, Poelchau, Michael H, Rae, Auriol S P, Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Riller, Ulrich, Sato, Honami, Tikoo, Sonia M, Tomioka, Naotaka, Urrutia-Fucugauchi, Jaime, Vellekoop, Johan, Wittmann, Axel, Xiao, Long, Yamaguchi, Kosei E, and Zylberman, William

Abstract

The Cretaceous/Palaeogene mass extinction eradicated 76% of species on Earth. It was caused by the impact of an asteroid on the Yucatán carbonate platform in the southern Gulf of Mexico 66 million years ago, forming the Chicxulub impact crater. After the mass extinction, the recovery of the global marine ecosystem—measured as primary productivity—was geographically heterogeneous; export production in the Gulf of Mexico and North Atlantic–western Tethys was slower than in most other regions, taking 300 thousand years (kyr) to return to levels similar to those of the Late Cretaceous period. Delayed recovery of marine productivity closer to the crater implies an impact-related environmental control, such as toxic metal poisoning, on recovery times. If no such geographic pattern exists, the best explanation for the observed heterogeneity is a combination of ecological factors—trophic interactions, species incumbency and competitive exclusion by opportunists—and ‘chance’. The question of whether the post-impact recovery of marine productivity was delayed closer to the crater has a bearing on the predictability of future patterns of recovery in anthropogenically perturbed ecosystems. If there is a relationship between the distance from the impact and the recovery of marine productivity, we would expect recovery rates to be slowest in the crater itself. Here we present a record of foraminifera, calcareous nannoplankton, trace fossils and elemental abundance data from within the Chicxulub crater, dated to approximately the first 200 kyr of the Palaeocene. We show that life reappeared in the basin just years after the impact and a high-productivity ecosystem was established within 30 kyr, which indicates that proximity to the impact did not delay recovery and that there was therefore no impact-related environmental control on recovery. Ecological processes probably controlled the recovery of productivity after the Cretaceous/Palaeogene mass extinction and are therefore likel

Published
2018

43. U-Pb zircon geochronology and depositional age models for the Upper Triassic Chinle Formation (Petrified Forest National Park, Arizona, USA): Implications for Late Triassic paleoecological and paleoenvironmental change.

Author

Rasmussen, Cornelia, Mundil, Roland, Irmis, Randall B., Geisler, Dominique, Gehrels, George E., Olsen, Paul E., Kent, Dennis V., Lepre, Christopher, Kinney, Sean T., Geissman, John W., and Parker, William G.

Subjects
*LASER ablation inductively coupled plasma mass spectrometry, *FOREST reserves, *NATIONAL parks & reserves
Abstract

The Upper Triassic Chinle Formation is a critical non-marine archive of low-paleolatitude biotic and environmental change in southwestern North America. The well-studied and highly fossiliferous Chinle strata at Petrified Forest National Park (PFNP), Arizona, preserve a biotic turnover event recorded by vertebrate and palynomorph fossils, which has been alternatively hypothesized to coincide with tectonically driven climate change or with the Manicouagan impact event at ca. 215.5 Ma. Previous outcrop-based geochronologic age constraints are difficult to put in an accurate stratigraphic framework because lateral facies changes and discontinuous outcrops allow for multiple interpretations. A major goal of the Colorado Plateau Coring Project (CPCP) was to retrieve a continuous record in unambiguous superposition designed to remedy this situation. We sampled the 520-m-long core 1A of the CPCP to develop an accurate age model in unquestionable superposition by combining U-Pb zircon ages and magnetostratigraphy. From 13 horizons of volcanic detritus-rich siltstone and sandstone, we screened up to ~300 zircon crystals per sample using laser ablation-inductively coupled plasma-mass spectrometry and subsequently analyzed up to 19 crystals of the youngest age population using the chemical abrasion-isotope dilution-thermal ionization mass (CA-ID-TIMS) spectrometry method. These data provide new maximum depositional ages for the top of the Moenkopi Formation (ca. 241 Ma), the lower Blue Mesa Member (ca. 222 Ma), and the lower (ca. 218 to 217 Ma) and upper (ca. 213.5 Ma) Sonsela Member. The maximum depositional ages obtained for the upper Chinle Formation fall well within previously proposed age constraints, whereas the maximum depositional ages for the lower Chinle Formation are relatively younger than previously proposed ages from outcrop; however, core to outcrop stratigraphic correlations remain uncertain. By correlating our new ages with the magnetostratigraphy of the core, two feasible age model solutions can be proposed. Model 1 assumes that the youngest, coherent U-Pb age clusters of each sample are representative of the maximum depositional ages and are close to (<1 Ma difference) the true time of deposition throughout the Sonsela Member. This model suggests a significant decrease in average sediment accumulation rate in the mid-Sonsela Member. Hence, the biotic turnover preserved in the mid-Sonsela Member at PFNP is also middle Norian in age, but may, at least partially, be an artifact of a condensed section. Model 2 following the magnetostratigraphic-based age model for the CPCP core 1A suggests instead that the ages from the lower and middle Sonsela Member are inherited populations of zircon crystals that are 1-3 Ma older than the true depositional age of the strata. This results in a model in which no sudden decrease in sediment accumulation rate is necessary and implies that the base of the Sonsela Member is no older than ca. 216 Ma. Independent of these alternatives, both age models agree that none of the preserved Chinle Formation in PFNP is Carnian (>227 Ma) in age, and hence the biotic turnover event cannot be correlated to the Carnian-Norian boundary but is rather a mid-Norian event. Our age models demonstrate the powers, but also the challenges, of integrating detrital CA-ID-TIMS ages with magnetostratigraphic data to properly interpret complex sedimentary sequences. [ABSTRACT FROM AUTHOR]

Published
2021
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44. Chicxulub and the Exploration of Large Peak-Ring Impact Craters through Scientific Drilling

Author

Kring, David A., Claeys, Philippe, Gulick, Sean P.S., Morgan, Joanna V., Collins, Gareth S., Bralower, Timothy, Chenot, Elise, Christeson, Gail, Cockell, C., Coolen, Marco J L, Ferrière, Ludovic, Gebhardt, Catalina, Goto, K., Jones, Heather, Lofi, Johanna, Lowery, Christopher M, Mellett, C., Ocampo-Torres, Ruben, Perez-Cruz, Ligia, Pickersgill, Annemarie E, Poelchau, Michael, Rae, Auriol, Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Riller, Ulrich, Sato, H., Smit, Jan, Tikoo, Sonia M, Tomioka, Naotaka, Urrutia-Fucugauchi, Jaime, Whalen, Michael T, Wittmann, Axel, Xiao, L., Yamaguchi, K. E., Zylberman, William, Kring, David A., Claeys, Philippe, Gulick, Sean P.S., Morgan, Joanna V., Collins, Gareth S., Bralower, Timothy, Chenot, Elise, Christeson, Gail, Cockell, C., Coolen, Marco J L, Ferrière, Ludovic, Gebhardt, Catalina, Goto, K., Jones, Heather, Lofi, Johanna, Lowery, Christopher M, Mellett, C., Ocampo-Torres, Ruben, Perez-Cruz, Ligia, Pickersgill, Annemarie E, Poelchau, Michael, Rae, Auriol, Rasmussen, Cornelia, Rebolledo-Vieyra, Mario, Riller, Ulrich, Sato, H., Smit, Jan, Tikoo, Sonia M, Tomioka, Naotaka, Urrutia-Fucugauchi, Jaime, Whalen, Michael T, Wittmann, Axel, Xiao, L., Yamaguchi, K. E., and Zylberman, William

Abstract

The Chicxulub crater is the only well-preserved peak-ring crater on Earth and linked, famously, to the K-T or K-Pg mass extinction event. For the first time, geologists have drilled into the peak ring of that crater in the International Ocean Discovery Program and International Continental Scientific Drilling Program (IODP-ICDP) Expedition 364. The Chicxulub impact event, the environmental calamity it produced, and the paleobiological consequences are among the most captivating topics being discussed in the geologic community. Here we focus attention on the geological processes that shaped the ~200-km-wide impact crater responsible for that discussion and the expedition’s first year results.

Published
2017

45. Colorado Plateau Coring Project, Phase I (CPCP-I): a continuously cored, globally exportable chronology of Triassic continental environmental change from western North America.

Author

Olsen, Paul E., Geissman, John W., Kent, Dennis V., Gehrels, George E., Mundil, Roland, Irmis, Randall B., Lepre, Christopher, Rasmussen, Cornelia, Giesler, Dominique, Parker, William G., Zakharova, Natalia, Kürschner, Wolfram M., Miller, Charlotte, Baranyi, Viktoria, Schaller, Morgan F., Whiteside, Jessica H., Schnurrenberger, Douglas, Noren, Anders, Brady Shannon, Kristina, and O'Grady, Ryan

Subjects
CORE drilling, STRATIGRAPHIC geology
Abstract

Phase 1 of the Colorado Plateau Coring Project (CPCP-I) recovered a total of over 850 m of stratigraphically overlapping core from three coreholes at two sites in the Early to Middle and Late Triassic age largely fluvial Moenkopi and Chinle formations in Petrified Forest National Park (PFNP), northeastern Arizona, USA. Coring took place during November and December of 2013 and the project is now in its post-drilling science phase. The CPCP cores have abundant detrital zircon-producing layers (with survey LA-ICP-MS dates selectively resampled for CA-ID-TIMS U-Pb ages ranging in age from at least 210 to 241 Ma), which together with their magnetic polarity stratigraphy demonstrate that a globally exportable timescale can be produced from these continental sequences and in the process show that a prominent gap in the calibrated Phanerozoic record can be filled. The portion of core CPCP-PFNP13-1A for which the polarity stratigraphy has been completed thus far spans ∼215 to 209 Ma of the Late Triassic age, and strongly validates the longer Newark-Hartford Astrochronostratigraphic-calibrated magnetic Polarity Time-Scale (APTS) based on cores recovered in the 1990s during the Newark Basin Coring Project (NBCP). Core recovery was ∼100 % in all holes (Table 1). The coreholes were inclined ∼60 –75 ∘ approximately to the south to ensure azimuthal orientation in the nearly flat-lying bedding, critical to the interpretation of paleomagentic polarity stratigraphy. The two longest of the cores (CPCP-PFNP13-1A and 2B) were CT-scanned in their entirety at the University of Texas High Resolution X-ray CT Facility in Austin, TX, and subsequently along with 2A, all cores were split and processed at the CSDCO/LacCore Facility, in Minneapolis, MN, where they were scanned for physical property logs and imaging. While remaining the property of the Federal Government, the archive half of each core is curated at the NSF-sponsored LacCore Core Repository and the working half is stored at the Rutgers University Core Repository in Piscataway, NJ, where the initial sampling party was held in 2015 with several additional sampling events following. Additional planned study will recover the rest of the polarity stratigraphy of the cores as additional zircon ages, sedimentary structure and paleosol facies analysis, stable isotope geochemistry, and calibrated XRF core scanning are accomplished. Together with strategic outcrop studies in Petrified Forest National Park and environs, these cores will allow the vast amount of surface paleontological and paleoenvironmental information recorded in the continental Triassic of western North America to be confidently placed in a secure context along with important events such as the giant Manicouagan impact at ∼215.5 Ma (Ramezani et al., 2005) and long wavelength astronomical cycles pacing global environmental change and trends in atmospheric gas composition during the dawn of the dinosaurs. [ABSTRACT FROM AUTHOR]

Published
2018
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47. Middle–late Miocene palaeoenvironments, palynological data and a fossil fish Lagerstätte from the Central Kenya Rift (East Africa).

Author

RASMUSSEN, CORNELIA, REICHENBACHER, BETTINA, LENZ, OLAF, ALTNER, MELANIE, PENK, STEFANIE B. R., PRIETO, JEROME, and BRÜSCH, DENNIS

Subjects
*FOSSIL fishes, *MIOCENE Epoch, *GEOLOGICAL formations
Abstract

The Miocene epoch was a time of major change in the East African Rift System (EARS) as forest habitats were transformed into grasslands and hominids appeared in the landscape. Here we provide new sedimentological and palynological data on the middle–upper Miocene Ngorora Formation (Tugen Hills, Central Kenya Rift, EARS), together with clay mineral characterizations, mammal finds and a description of the Ngorora fish Lagerstätte. Furthermore, we introduce a revised age of c. 13.3 Ma for the onset of the Ngorora Formation. The older part of the Ngorora Formation (c. 13.3–12 Ma) records low-energy settings of lakes, floodplains and palaeosols, and evidence of analcime indicates that lakes were alkaline. The palynomorph spectrum consists of tree pollen (Juniperus, Podocarpus), Euphorbiaceae pollen (Acalypha, Croton) and herbaceous pollen of Poaceae and Asteraceae, suggestive of wooded grasslands or grassy woodlands. Alkaline lakes, floodplains and palaeosols continue upsection (c. 12–9 Ma), but environmental fluctuations become more dynamic. Paucity of palynomorphs and the presence of an equid may point to progressively drier conditions. A total of about 500 articulated fish fossils were recovered from distinctive layers of almost all sections studied and represent different lineages of the Haplotilapiines (Pseudocrenilabrinae, Cichlidae). Some of the fish kills may be attributable to rapid water acidification and/or asphyxiation by episodic ash falls. Repeated instances of abrupt change in water depth in many sections are more likely to be due to synsedimentary tectonic activity of the Central Kenya Rift than to climatic variation. Overall, the preservation of the Ngorora fish Lagerstätte resulted from the interplay of tectonics, formation of alkaline lakes and explosive volcanism. As records of grasslands that pre-date late Miocene time are rare, our finding of middle Miocene (12–13 Ma) grassy savannah in the Central Kenya Rift is also relevant to models of human evolution in East Africa. [ABSTRACT FROM PUBLISHER]

Published
2017
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48. Evidence of Carboniferous arc magmatism preserved in the Chicxulub impact structure.

Author

Ross, Catherine H., Stockli, Daniel F., Rasmussen, Cornelia, Gulick, Sean P. S., de Graaff, Sietze J., Claeys, Philippe, Jiawei Zhao, Long Xiao, Pickersgill, Annemarie E., Schmieder, Martin, Kring, David A., Wittmann, Axel, and Morgan, Joanna V.

Subjects
*LASER ablation inductively coupled plasma mass spectrometry, *RARE earth metals, GONDWANA (Continent)
Abstract

Determining the nature and age of the 200-km-wide Chicxulub impact target rock is an essential step in advancing our understanding of the Maya Block basement. Few age constraints exist for the northern Maya Block crust, specifically the basement underlying the 66 Ma, 200 km-wide Chicxulub impact structure. The International Ocean Discovery Program-International Continental Scientific Drilling Program Expedition 364 core recovered a continuous section of basement rocks from the Chicxulub target rocks, which provides a unique opportunity to illuminate the pre-impact tectonic evolution of a terrane key to the development of the Gulf of Mexico. Sparse published ages for the Maya Block point to Mesoproterozoic, Ediacaran, Ordovician to Devonian crust are consistent with plate reconstruction models. In contrast, granitic basement recovered from the Chicxulub peak ring during Expedition 364 yielded new zircon U-Pb laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) concordant dates clustering around 334 ± 2.3 Ma. Zircon rare earth element (REE) chemistry is consistent with the granitoids having formed in a continental arc setting. Inherited zircon grains fall into three groups: 400-435 Ma, 500-635 Ma, and 940-1400 Ma, which are consistent with the incorporation of Peri-Gondwanan, Pan-African, and Grenvillian crust, respectively. Carboniferous U-Pb ages, trace element compositions, and inherited zircon grains indicate a pre-collisional continental volcanic arc located along the Maya Block's northern margin before NW Gondwana collided with Laurentia. The existence of a continental arc along NW Gondwana suggests southward-directed subduction of Rheic oceanic crust beneath the Maya Block and is similar to evidence for a continental arc along the northern margin of Gondwana that is documented in the Suwannee terrane, Florida, USA, and Coahuila Block of NE México [ABSTRACT FROM AUTHOR]

Published
2022
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49. New shock microstructures in titanite (CaTiSiO5) from the peak ring of the Chicxulub impact structure, Mexico.

Author

Timms, Nicholas E., Pearce, Mark A., Erickson, Timmons M., Cavosie, Aaron J., Rae, Auriol S. P., Wheeler, John, Wittmann, Axel, Ferrière, Ludovic, Poelchau, Michael H., Tomioka, Naotaka, Collins, Gareth S., Gulick, Sean P. S., Rasmussen, Cornelia, and Morgan, Joanna V.

Subjects
IMPACT craters, DISLOCATIONS in crystals, ROCK deformation, SPHENE, MECHANICAL shock measurement, MICROSTRUCTURE
Abstract

Accessory mineral geochronometers such as apatite, baddeleyite, monazite, xenotime and zircon are increasingly being recognized for their ability to preserve diagnostic microstructural evidence of hypervelocity-impact processes. To date, little is known about the response of titanite to shock metamorphism, even though it is a widespread accessory phase and a U–Pb geochronometer. Here we report two new mechanical twin modes in titanite within shocked granitoid from the Chicxulub impact structure, Mexico. Titanite grains in the newly acquired core from the International Ocean Discovery Program Hole M0077A preserve multiple sets of polysynthetic twins, most commonly with composition planes (K1) = ~ { 1 ¯ 11 } , and shear direction (η1) = < 110 > , and less commonly with the mode K1 = {130}, η1 = ~ <522 >. In some grains, {130} deformation bands have formed concurrently with the deformation twins, indicating dislocation slip with Burgers vector b = < 341 > can be active during impact metamorphism. Titanite twins in the modes described here have not been reported from endogenically deformed rocks; we, therefore, propose this newly identified twin form as a result of shock deformation. Formation conditions of the twins have not been experimentally calibrated, and are here empirically constrained by the presence of planar deformation features in quartz (12 ± 5 and ~ 17 ± 5 GPa) and the absence of shock twins in zircon (< 20 GPa). While the lower threshold of titanite twin formation remains poorly constrained, identification of these twins highlight the utility of titanite as a shock indicator over the pressure range between 12 and 17 GPa. Given the challenges to find diagnostic indicators of shock metamorphism to identify both ancient and recent impact evidence on Earth, microstructural analysis of titanite is here demonstrated to provide a new tool for recognizing impact deformation in rocks where other impact evidence may be erased, altered, or did not manifest due to generally low (< 20 GPa) shock pressure. [ABSTRACT FROM AUTHOR]

Published
2019
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50. Calibration of sedimentary sequences using combined methods: Examples from the Triassic Period.

Author

Mundil, Roland, Rasmussen, Cornelia, Olsen, Paul E., Kent, Dennis V., Irmis, Randall B., Lepre, Christopher, Giesler, Dominique M., Gehrels, George E., Geissman, John W., Keller, Brenhin, and Parker, William G.

Subjects
*TRIASSIC Period, *CALIBRATION, *ALLUVIUM, *DRILL cores, *FOREST reserves, *IGNEOUS intrusions
Abstract

The chronostratigraphic calibration of sedimentary sequences is, in most cases, done directly by using either radio-isotopic or astronomical clocks, or indirectly by correlating calibrated successions by means of bio-, magneto-, and/or chemostratigraphy. Age-equivalent sedimentary sections where a combination of these methods can be mutually tested and calibrated are rare but do exist. One such example are the Late Triassic fluvial deposits of the Colorado Plateau and the contemporaneous lacustrine strata of the Newark Basin. We present a suite of U-Pb zircon ages from core CPCP-PFNP13-1A of the Colorado Plateau Coring Project (CPCP) through Late Triassic non-marine deposits of Petrified Forest National Park that span a time interval from ca. 222 to 210 Ma (Norian). The zircon populations from individual layers are complex as they are redeposited, but juvenile volcanic zircon crystals, the ages of which closely approximate the depositional age, are in most cases ubiquitous. In order to extract the fraction containing abundant juvenile zircon, U-Pb LA-ICPMS analyses where employed on 80-300 crystals per sample and the youngest crystals were subsequently extracted and subjected to high-resolution U-Pb CA-TIMS analyses. The U-Pb ages in combination with the unambiguous superposition in the drill core result in a robust and exportable age model. Complementary rock magnetic analyses throughout the core reveal a U-Pb age-calibrated magnetic reversal pattern that can be correlated with the astronomically-calibrated Late Triassic sequence of the Newark Basin, allowing a calibration of the predominantly long eccentricity cycles recorded in the latter. Our results suggest that the periodicity of the long eccentricity cycle in Late Triassic times is very close to the calculated periodicity in the Cenozoic (Kent et al., 2018). Attempts to universally use this periodicity throughout Earth's history, however, should be cautioned until further studies of this kind have been completed. This caution particularly applies to sedimentary sequences that are solely calibrated by cyclostratigraphy. Similarly, reliance on one calibration method alone can be equally fragile making a combination of techniques desirable where it is applicable. Focused field or coring experiments in areas with exportable complimentary properties to the areas with robust cyclostratigraphy, or vice versa, can circumvent the limitations of the geological peculiarities of any one area, as we have done here with the CPCP. [ABSTRACT FROM AUTHOR]

Published
2019

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