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2. Double-beta decay Q values of 130Te, 128Te, and 120Te

Author

Scielzo, N. D., Caldwell, S., Savard, G., Clark, J. A., Deibel, C. M., Fallis, J., Gulick, S., Lascar, D., Levand, A. F., Li, G., Mintz, J., Norman, E. B., Sharma, K. S., Sternberg, M., Sun, T., and Van Schelt, J.

Subjects
Nuclear Experiment
Abstract

The double-beta decay Q values of 130Te, 128Te, and 120Te have been determined from parent-daughter mass differences measured with the Canadian Penning Trap mass spectrometer. The 132Xe-129Xe mass difference, which is precisely known, was also determined to confirm the accuracy of these results. The 130Te Q value was found to be 2527.01(32) keV which is 3.3 keV lower than the 2003 Atomic Mass Evaluation recommended value, but in agreement with the most precise previous measurement. The uncertainty has been reduced by a factor of 6 and is now significantly smaller than the resolution achieved or foreseen in experimental searches for neutrinoless double-beta decay. The 128Te and 120Te Q values were found to be 865.87(131) keV and 1714.81(125) keV, respectively. For 120Te, this reduction in uncertainty of nearly a factor of 8 opens up the possibility of using this isotope for sensitive searches for neutrinoless double-electron capture and electron capture with positron emission., Comment: 5 pages, 2 figures, submitted to Physical Review Letters

Published
2009
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4. An Ion Guide for the Production of a Low Energy Ion Beam of Daughter Products of $\alpha$-Emitters

Author

Tordoff, B., Eronen, T., Elomaa, V. V., Gulick, S., Hager, U., Karvonen, P., Kessler, T., Lee, J., Moore, I., Popov, A., Rahaman, S., Rinta-Antila, S., Sonoda, T., and Aysto, J.

Subjects
Nuclear Experiment
Abstract

A new ion guide has been modeled and tested for the production of a low energy ($\approx$ 40 kV) ion beam of daughter products of alpha-emitting isotopes. The guide is designed to evacuate daughter recoils originating from the $\alpha$-decay of a $^{233}$U source. The source is electroplated onto stainless steel strips and mounted along the inner walls of an ion guide chamber. A combination of electric fields and helium gas flow transport the ions through an exit hole for injection into a mass separator. Ion guide efficiencies for the extraction of $^{229}$Th$^{+}$ (0.06%), $^{221}$Fr$^{+}$ (6%), and $^{217}$At$^{+}$ (6%) beams have been measured. A detailed study of the electric field and gas flow influence on the ion guide efficiency is described for two differing electric field configurations., Comment: 13 pages, 11 figures, 4 tables. Submitted to Nucl. Instr. Meth. B

Published
2006
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7. Site M0077: Upper Peak Ring

Author

Gulick, S., primary, Morgan, J., additional, Mellett, C.L., additional, Green, S.L., additional, Bralower, T., additional, Chenot, E., additional, Christeson, G., additional, Claeys, P., additional, Cockell, C., additional, Coolen, M.J.L., additional, Ferrière, L., additional, Gebhardt, C., additional, Goto, K., additional, Jones, H., additional, Kring, D., additional, Lofi, J., additional, Lowery, C., additional, Ocampo-Torres, R., additional, Perez-Cruz, L., additional, Pickersgill, A.E., additional, Poelchau, M., additional, Rae, A., additional, Rasmussen, C., additional, Rebolledo-Vieyra, M., additional, Riller, U., additional, Sato, H., additional, Smit, J., additional, Tikoo, S., additional, Tomioka, N., additional, Urrutia-Fucugauchi, J., additional, Whalen, M., additional, Wittmann, A., additional, Yamaguchi, K., additional, Xiao, L., additional, and Zylberman, W., additional

Published
2017
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8. Site M0077: Post-Impact Sedimentary Rocks

Author

Gulick, S., primary, Morgan, J., additional, Mellett, C.L., additional, Green, S.L., additional, Bralower, T., additional, Chenot, E., additional, Christeson, G., additional, Claeys, P., additional, Cockell, C., additional, Coolen, M.J.L., additional, Ferrière, L., additional, Gebhardt, C., additional, Goto, K., additional, Jones, H., additional, Kring, D., additional, Lofi, J., additional, Lowery, C., additional, Ocampo-Torres, R., additional, Perez-Cruz, L., additional, Pickersgill, A.E., additional, Poelchau, M., additional, Rae, A., additional, Rasmussen, C., additional, Rebolledo-Vieyra, M., additional, Riller, U., additional, Sato, H., additional, Smit, J., additional, Tikoo, S., additional, Tomioka, N., additional, Urrutia-Fucugauchi, J., additional, Whalen, M., additional, Wittmann, A., additional, Yamaguchi, K., additional, Xiao, L., additional, and Zylberman, W., additional

Published
2017
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9. Expedition 364 summary

Author

Gulick, S., primary, Morgan, J., additional, Mellett, C.L., additional, Green, S.L., additional, Bralower, T., additional, Chenot, E., additional, Christeson, G., additional, Claeys, P., additional, Cockell, C., additional, Coolen, M.J.L., additional, Ferrière, L., additional, Gebhardt, C., additional, Goto, K., additional, Jones, H., additional, Kring, D., additional, Lofi, J., additional, Lowery, C., additional, Ocampo-Torres, R., additional, Perez-Cruz, L., additional, Pickersgill, A.E., additional, Poelchau, M., additional, Rae, A., additional, Rasmussen, C., additional, Rebolledo-Vieyra, M., additional, Riller, U., additional, Sato, H., additional, Smit, J., additional, Tikoo, S., additional, Tomioka, N., additional, Urrutia-Fucugauchi, J., additional, Whalen, M., additional, Wittmann, A., additional, Yamaguchi, K., additional, Xiao, L., additional, and Zylberman, W., additional

Published
2017
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10. Site M0077: microbiology

Author

Gulick, S., primary, Morgan, J., additional, Mellett, C.L., additional, Green, S.L., additional, Bralower, T., additional, Chenot, E., additional, Christeson, G., additional, Claeys, P., additional, Cockell, C., additional, Coolen, M.J.L., additional, Ferrière, L., additional, Gebhardt, C., additional, Goto, K., additional, Jones, H., additional, Kring, D., additional, Lofi, J., additional, Lowery, C., additional, Ocampo-Torres, R., additional, Perez-Cruz, L., additional, Pickersgill, A.E., additional, Poelchau, M., additional, Rae, A., additional, Rasmussen, C., additional, Rebolledo-Vieyra, M., additional, Riller, U., additional, Sato, H., additional, Smit, J., additional, Tikoo, S., additional, Tomioka, N., additional, Urrutia-Fucugauchi, J., additional, Whalen, M., additional, Wittmann, A., additional, Yamaguchi, K., additional, Xiao, L., additional, and Zylberman, W., additional

Published
2017
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11. Site M0077: Open Hole

Author

Gulick, S., primary, Morgan, J., additional, Mellett, C.L., additional, Green, S.L., additional, Bralower, T., additional, Chenot, E., additional, Christeson, G., additional, Claeys, P., additional, Cockell, C., additional, Coolen, M.J.L., additional, Ferrière, L., additional, Gebhardt, C., additional, Goto, K., additional, Jones, H., additional, Kring, D., additional, Lofi, J., additional, Lowery, C., additional, Ocampo-Torres, R., additional, Perez-Cruz, L., additional, Pickersgill, A.E., additional, Poelchau, M., additional, Rae, A., additional, Rasmussen, C., additional, Rebolledo-Vieyra, M., additional, Riller, U., additional, Sato, H., additional, Smit, J., additional, Tikoo, S., additional, Tomioka, N., additional, Urrutia-Fucugauchi, J., additional, Whalen, M., additional, Wittmann, A., additional, Yamaguchi, K., additional, Xiao, L., additional, and Zylberman, W., additional

Published
2017
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12. Site M0077: Lower Peak Ring

Author

Gulick, S., primary, Morgan, J., additional, Mellett, C.L., additional, Green, S.L., additional, Bralower, T., additional, Chenot, E., additional, Christeson, G., additional, Claeys, P., additional, Cockell, C., additional, Coolen, M.J.L., additional, Ferrière, L., additional, Gebhardt, C., additional, Goto, K., additional, Jones, H., additional, Kring, D., additional, Lofi, J., additional, Lowery, C., additional, Ocampo-Torres, R., additional, Perez-Cruz, L., additional, Pickersgill, A.E., additional, Poelchau, M., additional, Rae, A., additional, Rasmussen, C., additional, Rebolledo-Vieyra, M., additional, Riller, U., additional, Sato, H., additional, Smit, J., additional, Tikoo, S., additional, Tomioka, N., additional, Urrutia-Fucugauchi, J., additional, Whalen, M., additional, Wittmann, A., additional, Yamaguchi, K., additional, Xiao, L., additional, and Zylberman, W., additional

Published
2017
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13. Site M0077: introduction

Author

Gulick, S., primary, Morgan, J., additional, Mellett, C.L., additional, Green, S.L., additional, Bralower, T., additional, Chenot, E., additional, Christeson, G., additional, Claeys, P., additional, Cockell, C., additional, Coolen, M.J.L., additional, Ferrière, L., additional, Gebhardt, C., additional, Goto, K., additional, Jones, H., additional, Kring, D., additional, Lofi, J., additional, Lowery, C., additional, Ocampo-Torres, R., additional, Perez-Cruz, L., additional, Pickersgill, A.E., additional, Poelchau, M., additional, Rae, A., additional, Rasmussen, C., additional, Rebolledo-Vieyra, M., additional, Riller, U., additional, Sato, H., additional, Smit, J., additional, Tikoo, S., additional, Tomioka, N., additional, Urrutia-Fucugauchi, J., additional, Whalen, M., additional, Wittmann, A., additional, Yamaguchi, K., additional, Xiao, L., additional, and Zylberman, W., additional

Published
2017
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15. Investigating the rp-process with the Canadian Penning trap mass spectrometer

Author

Clark, J. A., Barber, R. C., Blank, B., Boudreau, C., Buchinger, F., Crawford, J. E., Greene, J. P., Gulick, S., Hardy, J. C., Hecht, A. A., Heinz, A., Lee, J. K. P., Levand, A. F., Lundgren, B. F., Moore, R. B., Savard, G., Scielzo, N. D., Seweryniak, D., Sharma, K. S., Sprouse, G. D., Trimble, W., Vaz, J., Wang, J. C., Wang, Y., Zabransky, B. J., Zhou, Z., Gross, Carl J., editor, Nazarewicz, Witold, editor, and Rykaczewski, Krzysztof P., editor

Published
2005
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17. The Canadian Penning Trap Spectrometer at Argonne

Author

Savard, G., Barber, R. C., Boudreau, C., Buchinger, F., Caggiano, J., Clark, J., Crawford, J. E., Fukutani, H., Gulick, S., Hardy, J. C., Heinz, A., Lee, J. K. P., Moore, R. B., Sharma, K. S., Schwartz, J., Seweryniak, D., Sprouse, G. D., Vaz, J., Lunney, David, editor, Audi, Georges, editor, and Kluge, H.-Jürgen, editor

Published
2001
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19. Mass measurements of proton-rich nuclides using the Canadian Penning trap mass spectrometer

Author

Clark, J. A., Barber, R. C., Boudreau, C., Buchinger, F., Caggiano, J. A., Crawford, J. E., Fukutani, H., Gulick, S., Hardy, J. C., Heinz, A., Lee, J. K. P., Maier, M., Moore, R. B., Savard, G., Schwartz, J., Seweryniak, D., Sharma, K. S., Sprouse, G., Vaz, J., Wang, J. C., Äystö, Juha, editor, Dendooven, Peter, editor, Jokinen, Ari, editor, and Leino, Matti, editor

Published
2003
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24. A steeply-inclined trajectory for the Chicxulub impact

Author

Collins, G. S., Patel, N., Davison, T. M., Rae, A. S. P., Morgan, J. V., Gulick, S. P. S., Christeson, G. L., Chenot, E., Claeys, P., Cockell, C. S., Coolen, M. J. L., Ferrière, L., Gebhardt, C., Goto, K., Jones, H., Kring, D. A., Lofi, J., Lowery, C. M., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A. E., Poelchau, M. H., Rasmussen, C., Rebolledo-Vieyra, M., Riller, U., Sato, H., Smit, J., Tikoo, S. M., Tomioka, N., Urrutia-Fucugauchi, J., Whalen, M. T., Wittmann, A., Xiao, L., Yamaguchi, K. E., Artemieva, N., Bralower, T. J., Geology and Geochemistry, Department of Earth Science and Engineering [Imperial College London], Imperial College London, 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), Science and Technology Facilities Council (STFC), and Natural Environment Research Council (NERC)

Subjects
010504 meteorology & atmospheric sciences, Science, Impact angle, General Physics and Astronomy, 010502 geochemistry & geophysics, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Impact crater, EMPLACEMENT, DEFORMATION, CRATER, 10. No inequality, lcsh:Science, 0105 earth and related environmental sciences, Multidisciplinary, Science & Technology, Plane (geometry), ORIGIN, METEORITE, General Chemistry, ANGLE, Multidisciplinary Sciences, BOUNDARY, SIZE, Meteorite, PEAK-RING FORMATION, 13. Climate action, Asteroid, [SDU]Sciences of the Universe [physics], ASYMMETRY, Trajectory, Science & Technology - Other Topics, lcsh:Q, Third-Party Scientists, IODP-ICDP Expedition 364 Science Party, Asteroids, comets and Kuiper belt, Seismology, Geology
Abstract

The environmental severity of large impacts on Earth is influenced by their impact trajectory. Impact direction and angle to the target plane affect the volume and depth of origin of vaporized target, as well as the trajectories of ejected material. The asteroid impact that formed the 66 Ma Chicxulub crater had a profound and catastrophic effect on Earth’s environment, but the impact trajectory is debated. Here we show that impact angle and direction can be diagnosed by asymmetries in the subsurface structure of the Chicxulub crater. Comparison of 3D numerical simulations of Chicxulub-scale impacts with geophysical observations suggests that the Chicxulub crater was formed by a steeply-inclined (45–60° to horizontal) impact from the northeast; several lines of evidence rule out a low angle (, The authors here present a 3D model that simulates the formation of the Chicxulub impact crater. Based on asymmetries in the subsurface structure of the Chicxulub crater, the authors diagnose impact angle and direction and suggest a steeply inclined (60° to horizontal) impact from the northeast.

Published
2020

27. The Habitat of the Nascent Chicxulub Crater

Author

Bralower, T. J., primary, Cosmidis, J., additional, Fantle, M. S., additional, Lowery, C. M., additional, Passey, B. H., additional, Gulick, S. P. S., additional, Morgan, J. V., additional, Vajda, V., additional, Whalen, M. T., additional, Wittmann, A., additional, Artemieva, N., additional, Farley, K., additional, Goderis, S., additional, Hajek, E., additional, Heaney, P. J., additional, Kring, D. A., additional, Lyons, S. L., additional, Rasmussen, C., additional, Sibert, E., additional, Rodríguez Tovar, F. J., additional, Turner‐Walker, G., additional, Zachos, J. C., additional, Carte, J., additional, Chen, S. A., additional, Cockell, C., additional, Coolen, M., additional, Freeman, K. H., additional, Garber, J., additional, Gonzalez, M., additional, Gray, J. L., additional, Grice, K., additional, Jones, H. L., additional, Schaefer, B., additional, Smit, J., additional, and Tikoo, S. M., additional

Published
2020
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28. PREDATION ON SCARLET MACAW (ARA MACAO CYANOPTERA) CHICKS BY COLLARED FOREST FALCONS (MICRASTUR SEMITORQUATUS) IN THE MAYA BIOSPHERE RESERVE, GUATEMALA

Author

Rony Garcia-Anleu, Ponce-Santizo, G., Gulick, S., Boyd, J., Brightsmith, D. J., and Mcnab, R. B.

Abstract

∙ Through efforts of the Wildlife Conservation Society, poaching in an important Scarlet Macaw (Ara macao cyanoptera) nesting area in the Maya Biosphere Reserve in Guatemala had been reduced to zero by 2004. However, during long‐term monitoring of the nesting success of Scarlet Macaws in the Maya Biosphere Reserve, unexplained or unknown disappearance of chicks from nests was common despite the aforementioned reduction in poaching. To determine the cause of these disappearances, we installed five video camera surveillance systems in the nest cavities during the 2008 nesting season. Fatal attacks on chicks by Collared Forest Falcons (Micrastur semitorquatus) were recorded at three of these nests. This result highlights natural predation as a limiting factor for the recruitment of new individuals into the Scarlet Macaw population in the Maya Biosphere Reserve even when poaching is suppressed.Resumen ∙ Depredación de pichones de Guacamayas Rojas (Ara macao cyanoptera) por Halcones Selváticos de Collar (Micrastur semitorquatus) en la Reserva de la Biosfera Maya, Guatemala A través de los esfuerzos de la Wildlife Conservation Society, el robo de pichones de Guacamayas Rojas (Ara macao cyanoptera) en una importante zona de anidación de la Reserva de la Biosfera Maya en Guatemala ha sido reducido a cero desde el año 2004. Sin embargo, durante el monitoreo a largo plazo del éxito de anidación de las guacamayas rojas en la Reserva de la Biosfera Maya, la desaparición por razones desconocidas de pichones de los nidos fue común a pesar de la reducción de robos anteriormente mencionada. Para determinar la causa de estas desapariciones, instalamos cinco sistemas de vigilancia de cámaras de video en los nidos durante la temporada de anidación de 2008. En tres de estos cinco nidos se registraron ataques fatales contra pichones por parte del Halcón Selvático de Collar (Micrastur semitorquatus). Este resultado destaca la depredación natural como un factor limitante para el reclutamiento de nuevos individuos en la población de Guacamayas Rojas en la Reserva de la Biosfera Maya, incluso cuando se suprime el robo de pichones.

Published
2017

31. Stress‐Strain Evolution During Peak‐Ring Formation: A Case Study of the Chicxulub Impact Structure

Author

Rae, Auriol, Collins, Gareth, Poelchau, Michael, Riller, Ulrich, Davison, Thomas, Grieve, Richard, Osinski, Gordon, Morgan, Joanna, Gulick, S. P. S., Chenot, Elise, Christeson, G. L., Claeys, P., Cockell, C. S., Coolen, M. J. L., Ferrière, L., Gebhardt, C., Goto, K., Green, S., Jones, H., Kring, D. A., Lofi, Johanna, Lowery, C. M., Ocampo‐Torres, R., Perez‐Cruz, L., Pickersgill, A. E., Rasmussen, C., Rae, A.S.P., Rebolledo‐Vieyra, M., Sato, H., Smit, J., Tikoo, S. M., Tomioka, N., Urrutia‐Fucugauchi, J., Whalen, M. T., Wittmann, A., Xiao, L., Yamaguchi, K. E., Department of Earth Science and Engineering [Imperial College London], Imperial College London, University of Freiburg [Freiburg], Universität Hamburg (UHH), Centre for Planetary Science and Exploration [London, ON] (CPSX), University of Western Ontario (UWO), 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), Science and Technology Facilities Council (STFC), and Natural Environment Research Council (NERC)

Subjects
Geochemistry & Geophysics, 010504 meteorology & atmospheric sciences, [SDU.STU.GP]Sciences of the Universe [physics]/Earth Sciences/Geophysics [physics.geo-ph], 01 natural sciences, stress, strain, Impact crater, DEFORMATION, FLUIDIZATION, Geochemistry and Petrology, impact cratering, CRATER, Earth and Planetary Sciences (miscellaneous), Fluidization, Impact structure, Petrology, 0105 earth and related environmental sciences, Science & Technology, ORIGIN, Scientific drilling, Stress–strain curve, deformation, Drilling, International Ocean Discovery Program, peak ring, Geophysics, Chicxulub, Shear (geology), 13. Climate action, Space and Planetary Science, Physical Sciences, ASYMMETRY, MOON, Geology, HYDROCODE SIMULATIONS
Abstract

Deformation is a ubiquitous process that occurs to rocks during impact cratering; thus, quantifying the deformation of those rocks can provide first-order constraints on the process of impact cratering. Until now, specific quantification of the conditions of stress and strain within models of impact cratering has not been compared to structural observations. This paper describes a methodology to analyze stress and strain within numerical impact models. This method is then used to predict deformation and its cause during peak-ring formation: a complex process that is not fully understood, requiring remarkable transient weakening and causing a significant redistribution of crustal rocks. The presented results are timely due to the recent Joint International Ocean Discovery Program and International Continental Scientific Drilling Program drilling of the peak ring within the Chicxulub crater, permitting direct comparison between the deformation history within numerical models and the structural history of rocks from a peak ring. The modeled results are remarkably consistent with observed deformation within the Chicxulub peak ring, constraining the following: (1) the orientation of rocks relative to their preimpact orientation; (2) total strain, strain rates, and the type of shear during each stage of cratering; and (3) the orientation and magnitude of principal stresses during each stage of cratering. The methodology and analysis used to generate these predictions is general and, therefore, allows numerical impact models to be constrained by structural observations of impact craters and for those models to produce quantitative predictions.Plain Language Summary During impact cratering events, extreme forces act on rocks beneath the crater to produce deformation. Computer simulations of large impact cratering events are particularly important because the conditions of those events can never be simultaneously produced by laboratory experiments. In this study, we describe a method by which the forces and deformations that occur during cratering can be measured in computer simulations of impact cratering events. Combining this analysis with geological observations from impact structures allows us to improve our understanding of impact crater formation. Here, we use this method to study the Chicxulub impact structure, Mexico, to understand the formation of peak rings, rings of hills found internal to the rim of large impact craters. Our analysis provides estimates of the sequence of forces and deformation during peak-ring formation. As deformation produces fractures, our analysis has important implications for how fluids flow through rocks in craters.

Published
2019

34. The Canadian Penning Trap mass spectrometer

Author

Wang, J.C., Savard, G., Sharma, K.S., Clark, J.A., Zhou, Z., Levand, A.F., Boudreau, C., Buchinger, F., Crawford, J.E., Greene, J.P., Gulick, S., Lee, J.K.P., Sprouse, G.D., Trimble, W., Vaz, J., and Zabransky, B.Z.

Published
2004
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35. Ocean resurge-induced impact melt dynamics on the peak-ring of the Chicxulub impact structure, Mexico.

Author

Schulte, Felix M., Wittmann, Axel, Jung, Stefan, Morgan, Joanna V., Gulick, Sean P. S., Kring, David A., Grieve, Richard A. F., Osinski, Gordon R., Riller, Ulrich, IODP-ICDP Expedition 364 Science Party, Gulick, S. P. S., Morgan, J. V., Bralower, T. J., Chenot, E., Christeson, G. L., Claeys, P., Cockell, C. S., Coolen, M. J. L., Ferrière, L., and Gebhardt, C.

Subjects
KELVIN-Helmholtz instability, RAYLEIGH-Taylor instability, CLAY minerals, OCEAN, MELTING, BRECCIA, MARINE debris
Abstract

Core from Hole M0077 from IODP/ICDP Expedition 364 provides unprecedented evidence for the physical processes in effect during the interaction of impact melt with rock-debris-laden seawater, following a large meteorite impact into waters of the Yucatán shelf. Evidence for this interaction is based on petrographic, microstructural and chemical examination of the 46.37-m-thick impact melt rock sequence, which overlies shocked granitoid target rock of the peak ring of the Chicxulub impact structure. The melt rock sequence consists of two visually distinct phases, one is black and the other is green in colour. The black phase is aphanitic and trachyandesitic in composition and similar to melt rock from other sites within the impact structure. The green phase consists chiefly of clay minerals and sparitic calcite, which likely formed from a solidified water–rock debris mixture under hydrothermal conditions. We suggest that the layering and internal structure of the melt rock sequence resulted from a single process, i.e., violent contact of initially superheated silicate impact melt with the ocean resurge-induced water–rock mixture overriding the impact melt. Differences in density, temperature, viscosity, and velocity of this mixture and impact melt triggered Kelvin–Helmholtz and Rayleigh–Taylor instabilities at their phase boundary. As a consequence, shearing at the boundary perturbed and, thus, mingled both immiscible phases, and was accompanied by phreatomagmatic processes. These processes led to the brecciation at the top of the impact melt rock sequence. Quenching of this breccia by the seawater prevented reworking of the solidified breccia layers upon subsequent deposition of suevite. Solid-state deformation, notably in the uppermost brecciated impact melt rock layers, attests to long-term gravitational settling of the peak ring. [ABSTRACT FROM AUTHOR]

Published
2021
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39. Microbial Mayhem in the Nascent Chicxulub Crater

Author

Schaefer, B., primary, Grice, K., additional, Coolen, M.J.L., additional, Summons, R.E., additional, Cui, X., additional, Bauersachs, T., additional, Schwark, L., additional, Böttcher, M. E., additional, Bralower, T. J., additional, Lyons, S. L., additional, Freeman, K. H., additional, Cockell, C. S., additional, Gulick, S. S., additional, Morgan, J. V., additional, Whalen, M. T., additional, Lowery, C. M., additional, and Vajda, V., additional

Published
2019
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41. Extraordinary rocks from the peak ring of the Chicxulub impact crater: P-wave velocity, density, and porosity measurements from IODP/ICDP Expedition 364

Author

Christeson, G. L., Gulick, S. P.S., Morgan, J. V., Gebhardt, C., Kring, D. A., Le Ber, E., Lofi, J., Nixon, C., Poelchau, M., Rae, A. S.P., Rebolledo-Vieyra, M., Riller, U., Schmitt, D. R., Wittmann, A., Bralower, T. J., Chenot, E., Claeys, P., Cockell, C. S., Coolen, M. J.L., Ferrière, L., Green, S., Goto, K., Jones, H., Lowery, C. M., Mellett, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A. E., Rasmussen, C., Sato, H., Smit, J., Tikoo, S. M., Tomioka, N., Urrutia-Fucugauchi, J., Whalen, M. T., Xiao, L., Yamaguchi, K. E., Christeson, G. L., Gulick, S. P.S., Morgan, J. V., Gebhardt, C., Kring, D. A., Le Ber, E., Lofi, J., Nixon, C., Poelchau, M., Rae, A. S.P., Rebolledo-Vieyra, M., Riller, U., Schmitt, D. R., Wittmann, A., Bralower, T. J., Chenot, E., Claeys, P., Cockell, C. S., Coolen, M. J.L., Ferrière, L., Green, S., Goto, K., Jones, H., Lowery, C. M., Mellett, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A. E., Rasmussen, C., Sato, H., Smit, J., Tikoo, S. M., Tomioka, N., Urrutia-Fucugauchi, J., Whalen, M. T., Xiao, L., and Yamaguchi, K. E.

Abstract

Joint International Ocean Discovery Program and International Continental Scientific Drilling Program Expedition 364 drilled into the peak ring of the Chicxulub impact crater. We present P-wave velocity, density, and porosity measurements from Hole M0077A that reveal unusual physical properties of the peak-ring rocks. Across the boundary between post-impact sedimentary rock and suevite (impact melt-bearing breccia) we measure a sharp decrease in velocity and density, and an increase in porosity. Velocity, density, and porosity values for the suevite are 2900–3700 m/s, 2.06–2.37 g/cm3, and 20–35%, respectively. The thin (25 m) impact melt rock unit below the suevite has velocity measurements of 3650–4350 m/s, density measurements of 2.26–2.37 g/cm3, and porosity measurements of 19–22%. We associate the low velocity, low density, and high porosity of suevite and impact melt rock with rapid emplacement, hydrothermal alteration products, and observations of pore space, vugs, and vesicles. The uplifted granitic peak ring materials have values of 4000–4200 m/s, 2.39–2.44 g/cm3, and 8–13% for velocity, density, and porosity, respectively; these values differ significantly from typical unaltered granite which has higher velocity and density, and lower porosity. The majority of Hole M0077A peak-ring velocity, density, and porosity measurements indicate considerable rock damage, and are consistent with numerical model predictions for peak-ring formation where the lithologies present within the peak ring represent some of the most shocked and damaged rocks in an impact basin. We integrate our results with previous seismic datasets to map the suevite near the borehole. We map suevite below the Paleogene sedimentary rock in the annular trough, on the peak ring, and in the central basin, implying that, post impact, suevite covered the entire floor of the impact basin. Suevite thickness is 100–165 m on the top of the peak ring but 200 m in the c

Published
2018
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42. Erratum to: Rock fluidization during peak-ring formation of large impact structures (Nature, (2018), 562, 7728, (511-518), 10.1038/s41586-018-0607-z)

Author

Riller, U., Poelchau, M., Rae, A., Schulte, F., Collins, G., Melosh, H., Grieve, R., Morgan, J., Gulick, S., Lofi, J., Diaw, A., McCall, N., Kring, D., Green, S., Chenot, E., Christeson, G., Claeys, P., Cockell, C., Coolen, Marco, Ferrière, L., Gebhardt, C., Goto, K., Jones, H., Xiao, L., Lowery, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A., Rasmussen, C., Rebolledo-Vieyra, M., Sato, H., Jan, S., Tikoo-Schantz, S., Tomioka, N., Whalen, M., Wittmann, A., Yamaguchi, K., Fucugauchi, J., Bralower, T., Riller, U., Poelchau, M., Rae, A., Schulte, F., Collins, G., Melosh, H., Grieve, R., Morgan, J., Gulick, S., Lofi, J., Diaw, A., McCall, N., Kring, D., Green, S., Chenot, E., Christeson, G., Claeys, P., Cockell, C., Coolen, Marco, Ferrière, L., Gebhardt, C., Goto, K., Jones, H., Xiao, L., Lowery, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A., Rasmussen, C., Rebolledo-Vieyra, M., Sato, H., Jan, S., Tikoo-Schantz, S., Tomioka, N., Whalen, M., Wittmann, A., Yamaguchi, K., Fucugauchi, J., and Bralower, T.

Abstract

In this Article, the middle initial of author Kosei E. Yamaguchi (of the IODP–ICDP Expedition 364 Science Party) was missing and his affiliation is to Toho University (not Tohu University). These errors have been corrected online.

Published
2018

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

Author

Riller, U., Poelchau, M., Rae, A., Schulte, F., Collins, G., Melosh, H., Grieve, R., Morgan, J., Gulick, S., Lofi, J., Diaw, A., McCall, N., Kring, D., Green, S., Chenot, E., Christeson, G., Claeys, P., Cockell, C., Coolen, Marco, Ferrière, L., Gebhardt, C., Goto, K., Jones, H., Xiao, L., Lowery, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A., Rasmussen, C., Rebolledo-Vieyra, M., Sato, H., Smit, J., Tikoo-Schantz, S., Tomioka, N., Whalen, M., Wittmann, A., Yamaguchi, K., Fucugauchi, J., Bralower, T., Riller, U., Poelchau, M., Rae, A., Schulte, F., Collins, G., Melosh, H., Grieve, R., Morgan, J., Gulick, S., Lofi, J., Diaw, A., McCall, N., Kring, D., Green, S., Chenot, E., Christeson, G., Claeys, P., Cockell, C., Coolen, Marco, Ferrière, L., Gebhardt, C., Goto, K., Jones, H., Xiao, L., Lowery, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A., Rasmussen, C., Rebolledo-Vieyra, M., Sato, H., Smit, J., Tikoo-Schantz, S., Tomioka, N., Whalen, M., Wittmann, A., Yamaguchi, K., Fucugauchi, J., and Bralower, T.

Abstract

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

44. Drilling-induced and logging-related features illustrated from IODP-ICDP Expedition 364 downhole logs and borehole imaging tools

Author

Lofi, J., Smith, D., Delahunty, C., Le Ber, E., Brun, L., Henry, G., Paris, J., Tikoo, S., Zylberman, W., Pezard, P., Célérier, B., Schmitt, D., Nixon, C., Gulick, S., Morgan, J., Chenot, E., Christeson, G., Claeys, P., Cockell, C., Coolen, Marco, Ferrière, L., Gebhardt, C., Goto, K., Green, S., Jones, H., Kring, D., Lowery, C., Mellett, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A., Poelchau, M., Rae, A., Rasmussen, C., Rebolledo-Vieyra, M., Riller, U., Sato, H., Smit, J., Tomioka, N., Urrutia-Fucugauchi, J., Whalen, M., Wittmann, A., Xiao, L., Yamaguchi, K., Bralower, T., Lofi, J., Smith, D., Delahunty, C., Le Ber, E., Brun, L., Henry, G., Paris, J., Tikoo, S., Zylberman, W., Pezard, P., Célérier, B., Schmitt, D., Nixon, C., Gulick, S., Morgan, J., Chenot, E., Christeson, G., Claeys, P., Cockell, C., Coolen, Marco, Ferrière, L., Gebhardt, C., Goto, K., Green, S., Jones, H., Kring, D., Lowery, C., Mellett, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A., Poelchau, M., Rae, A., Rasmussen, C., Rebolledo-Vieyra, M., Riller, U., Sato, H., Smit, J., Tomioka, N., Urrutia-Fucugauchi, J., Whalen, M., Wittmann, A., Xiao, L., Yamaguchi, K., and Bralower, T.

Abstract

Expedition 364 was a joint IODP and ICDP mission-specific platform (MSP) expedition to explore the Chicxulub impact crater buried below the surface of the Yucatán continental shelf seafloor. In April and May 2016, this expedition drilled a single borehole at Site M0077 into the crater's peak ring. Excellent quality cores were recovered from ~ 505 to ~1335m below seafloor (m b.s.f.), and high-resolution open hole logs were acquired between the surface and total drill depth. Downhole logs are used to image the borehole wall, measure the physical properties of rocks that surround the borehole, and assess borehole quality during drilling and coring operations. When making geological interpretations of downhole logs, it is essential to be able to distinguish between features that are geological and those that are operation-related. During Expedition 364 some drilling-induced and logging-related features were observed and include the following: effects caused by the presence of casing and metal debris in the hole, logging-tool eccentering, drilling-induced corkscrew shape of the hole, possible re-magnetization of low-coercivity grains within sedimentary rocks, markings on the borehole wall, and drilling-induced changes in the borehole diameter and trajectory.

Published
2018

45. Rapid recovery of life at ground zero of the end-Cretaceous mass extinction

Author

Lowery, C., Bralower, T., Owens, J., Rodríguez-Tovar, F., Jones, H., Smit, J., Whalen, M., Claeys, P., Farley, K., Gulick, S., Morgan, J., Green, S., Chenot, E., Christeson, G., Cockell, C., Coolen, Marco, Ferrière, L., Gebhardt, C., Goto, K., Kring, D., Lofi, J., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A., Poelchau, M., Rae, A., Rasmussen, C., Rebolledo-Vieyra, M., Riller, U., Sato, H., Tikoo, S., Tomioka, N., Urrutia-Fucugauchi, J., Vellekoop, J., Wittmann, A., Xiao, L., Yamaguchi, K., Zylberman, W., Lowery, C., Bralower, T., Owens, J., Rodríguez-Tovar, F., Jones, H., Smit, J., Whalen, M., Claeys, P., Farley, K., Gulick, S., Morgan, J., Green, S., Chenot, E., Christeson, G., Cockell, C., Coolen, Marco, Ferrière, L., Gebhardt, C., Goto, K., Kring, D., Lofi, J., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A., Poelchau, M., Rae, A., Rasmussen, C., Rebolledo-Vieyra, M., Riller, U., Sato, H., Tikoo, S., Tomioka, N., Urrutia-Fucugauchi, J., Vellekoop, J., Wittmann, A., Xiao, L., Yamaguchi, K., and Zylberman, W.

Abstract

The Cretaceous/Palaeogene mass extinction eradicated 76% of species on Earth1,2. It was caused by the impact of an asteroid3,4on the Yucatán carbonate platform in the southern Gulf of Mexico 66 million years ago5, forming the Chicxulub impact crater6,7. After the mass extinction, the recovery of the global marine ecosystem - measured as primary productivity - was geographically heterogeneous8; export production in the Gulf of Mexico and North Atlantic-western Tethys was slower than in most other regions8-11, 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 poisoning12, on recovery times. If no such geographic pattern exists, the best explanation for the observed heterogeneity is a combination of ecological factors - trophic interactions13, species incumbency and competitive exclusion by opportunists14- and 'chance'8,15,16. 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

Published
2018

46. Extraordinary rocks from the peak ring of the Chicxulub impact crater: P-wave velocity, density, and porosity measurements from IODP/ICDP Expedition 364

Author

Christeson, G., Gulick, S., Morgan, J., Gebhardt, C., Kring, D., Le Ber, E., Lofi, J., Nixon, C., Poelchau, M., Rae, A., Rebolledo-Vieyra, M., Riller, U., Schmitt, D., Wittmann, A., Bralower, T., Chenot, E., Claeys, P., Cockell, C., Coolen, Marco, Ferrière, L., Green, S., Goto, K., Jones, H., Lowery, C., Mellett, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A., Rasmussen, C., Sato, H., Smit, J., Tikoo, S., Tomioka, N., Urrutia-Fucugauchi, J., Whalen, M., Xiao, L., Yamaguchi, K., Christeson, G., Gulick, S., Morgan, J., Gebhardt, C., Kring, D., Le Ber, E., Lofi, J., Nixon, C., Poelchau, M., Rae, A., Rebolledo-Vieyra, M., Riller, U., Schmitt, D., Wittmann, A., Bralower, T., Chenot, E., Claeys, P., Cockell, C., Coolen, Marco, Ferrière, L., Green, S., Goto, K., Jones, H., Lowery, C., Mellett, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A., Rasmussen, C., Sato, H., Smit, J., Tikoo, S., Tomioka, N., Urrutia-Fucugauchi, J., Whalen, M., Xiao, L., and Yamaguchi, K.

Abstract

© 2018 Elsevier B.V. Joint International Ocean Discovery Program and International Continental Scientific Drilling Program Expedition 364 drilled into the peak ring of the Chicxulub impact crater. We present P-wave velocity, density, and porosity measurements from Hole M0077A that reveal unusual physical properties of the peak-ring rocks. Across the boundary between post-impact sedimentary rock and suevite (impact melt-bearing breccia) we measure a sharp decrease in velocity and density, and an increase in porosity. Velocity, density, and porosity values for the suevite are 2900–3700 m/s, 2.06–2.37 g/cm3, and 20–35%, respectively. The thin (25 m) impact melt rock unit below the suevite has velocity measurements of 3650–4350 m/s, density measurements of 2.26–2.37 g/cm3, and porosity measurements of 19–22%. We associate the low velocity, low density, and high porosity of suevite and impact melt rock with rapid emplacement, hydrothermal alteration products, and observations of pore space, vugs, and vesicles. The uplifted granitic peak ring materials have values of 4000–4200 m/s, 2.39–2.44 g/cm3, and 8–13% for velocity, density, and porosity, respectively; these values differ significantly from typical unaltered granite which has higher velocity and density, and lower porosity. The majority of Hole M0077A peak-ring velocity, density, and porosity measurements indicate considerable rock damage, and are consistent with numerical model predictions for peak-ring formation where the lithologies present within the peak ring represent some of the most shocked and damaged rocks in an impact basin. We integrate our results with previous seismic datasets to map the suevite near the borehole. We map suevite below the Paleogene sedimentary rock in the annular trough, on the peak ring, and in the central basin, implying that, post impact, suevite covered the entire floor of the impact basin. Suevite thickness is 100–165 m on the top of the peak ring but 200 m in the central basin, s

Published
2018

47. Sedimentology and geomorphology of a large tsunamigenic landslide, Taan Fiord, Alaska

Author

Dufresne, A., Geertsema, M., Shugar, D. H., Koppes, M., Higman, B., Haeussler, P. J., Stark, C., Venditti, J. G., Bonno, D., Larsen, C., Gulick, S. P. S., McCall, N., Walton, M., Loso, M. G., Willis, Michael J., Dufresne, A., Geertsema, M., Shugar, D. H., Koppes, M., Higman, B., Haeussler, P. J., Stark, C., Venditti, J. G., Bonno, D., Larsen, C., Gulick, S. P. S., McCall, N., Walton, M., Loso, M. G., and Willis, Michael J.

Abstract

On 17 October 2015, a landslide of roughly 60 × 106 m3 occurred at the terminus of Tyndall Glacier in Taan Fiord, southeastern Alaska. It caused a tsunami that inundated an area over 20 km2, whereas the landslide debris itself deposited within a much smaller area of approximately 2 km2. It is a unique event in that the landslide debris was deposited into three very different environments: on the glacier surface, on land, and in the marine waters of the fjord. Part of the debris traversed the width of the fjord and re-emerged onto land, depositing coherent hummocks with preserved source stratigraphy on an alluvial fan and adjacent moraines on the far side of the fjord. Imagery from before the landslide shows that the catastrophic slope failure was preceded by deformation and sliding for at least the two decades since the glacier retreated to its current terminus location, exposing steep and extensively faulted slopes. A small volume of the total slide mass remains within the source area and is topped by striated blocks (> 10 m across) and standing trees that were transported down the slope in intact positions during the landslide. Field work was carried out in the summer of 2016, and by the time this paper was written, almost all of the supraglacial debris was advected into the fjord and half the subaerial hummocks were buried by glacial advance; this rapid change illustrates how highly active sedimentary processes in high-altitude glacial settings can skew any landslide-frequency analyses, and emphasizes the need for timely field investigations of these natural hazards.

Published
2018

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