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1. Author Correction: A Tunguska sized airburst destroyed Tall el-Hammam a Middle Bronze Age city in the Jordan Valley near the Dead Sea

Author

Bunch, Ted E., LeCompte, Malcolm A., Adedeji, A. Victor, Wittke, James H., Burleigh, T. David, Hermes, Robert E., Mooney, Charles, Batchelor, Dale, Wolbach, Wendy S., Kathan, Joel, Kletetschka, Gunther, Patterson, Mark C. L., Swindel, Edward C., Witwer, Timothy, Howard, George A., Mitra, Siddhartha, Moore, Christopher R., Langworthy, Kurt, Kennett, James P., West, Allen, and Silvia, Phillip J.

Published
2023
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2. Author Correction: A Tunguska sized airburst destroyed Tall el-Hammam a Middle Bronze Age city in the Jordan Valley near the Dead Sea

Author

Bunch, Ted E., LeCompte, Malcolm A., Adedeji, A. Victor, Wittke, James H., Burleigh, T. David, Hermes, Robert E., Mooney, Charles, Batchelor, Dale, Wolbach, Wendy S., Kathan, Joel, Kletetschka, Gunther, Patterson, Mark C. L., Swindel, Edward C., Witwer, Timothy, Howard, George A., Mitra, Siddhartha, Moore, Christopher R., Langworthy, Kurt, Kennett, James P., West, Allen, and Silvia, Phillip J.

Published
2022
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3. Extraordinary Biomass-Burning Episode and Impact Winter Triggered by the Younger Dryas Cosmic Impact ∼12,800 Years Ago. 1. Ice Cores and Glaciers

Author

Wolbach, Wendy S, Ballard, Joanne P, Mayewski, Paul A, Adedeji, Victor, Bunch, Ted E, Firestone, Richard B, French, Timothy A, Howard, George A, Israde-Alcántara, Isabel, Johnson, John R, Kimbel, David, Kinzie, Charles R, Kurbatov, Andrei, Kletetschka, Gunther, LeCompte, Malcolm A, Mahaney, William C, Melott, Adrian L, Maiorana-Boutilier, Abigail, Mitra, Siddhartha, Moore, Christopher R, Napier, William M, Parlier, Jennifer, Tankersley, Kenneth B, Thomas, Brian C, Wittke, James H, West, Allen, and Kennett, James P

Subjects
Climate Action, Geochemistry, Geology
Abstract

The Younger Dryas boundary (YDB) cosmic-impact hypothesis is based on considerable evidence that Earth collided with fragments of a disintegrating ≥100-km-diameter comet, the remnants of which persist within the inner solar system ∼12,800 y later. Evidence suggests that the YDB cosmic impact triggered an “impact winter” and the subsequent Younger Dryas (YD) climate episode, biomass burning, late Pleistocene megafaunal extinctions, and human cultural shifts and population declines. The cosmic impact deposited anomalously high concentrations of platinum over much of the Northern Hemisphere, as recorded at 26 YDB sites at the YD onset, including the Greenland Ice Sheet Project 2 ice core, in which platinum deposition spans ∼21 y (∼12,836–12,815 cal BP). The YD onset also exhibits increased dust concentrations, synchronous with the onset of a remarkably high peak in ammonium, a biomass-burning aerosol. In four ice-core sequences from Greenland, Antarctica, and Russia, similar anomalous peaks in other combustion aerosols occur, including nitrate, oxalate, acetate, and formate, reflecting one of the largest biomass-burning episodes in more than 120,000 y. In support of widespread wildfires, the perturbations in CO2 records from Taylor Glacier, Antarctica, suggest that biomass burning at the YD onset may have consumed ∼10 million km2, or ∼9% of Earth’s terrestrial biomass. The ice record is consistent with YDB impact theory that extensive impact-related biomass burning triggered the abrupt onset of an impact winter, which led, through climatic feedbacks, to the anomalous YD climate episode.

Published
2018

4. Extraordinary Biomass-Burning Episode and Impact Winter Triggered by the Younger Dryas Cosmic Impact ∼12,800 Years Ago. 2. Lake, Marine, and Terrestrial Sediments

Author

Wolbach, Wendy S, Ballard, Joanne P, Mayewski, Paul A, Parnell, Andrew C, Cahill, Niamh, Adedeji, Victor, Bunch, Ted E, Domínguez-Vázquez, Gabriela, Erlandson, Jon M, Firestone, Richard B, French, Timothy A, Howard, George, Israde-Alcántara, Isabel, Johnson, John R, Kimbel, David, Kinzie, Charles R, Kurbatov, Andrei, Kletetschka, Gunther, LeCompte, Malcolm A, Mahaney, William C, Melott, Adrian L, Mitra, Siddhartha, Maiorana-Boutilier, Abigail, Moore, Christopher R, Napier, William M, Parlier, Jennifer, Tankersley, Kenneth B, Thomas, Brian C, Wittke, James H, West, Allen, and Kennett, James P

Subjects
Geochemistry, Geology
Abstract

Part 1 of this study investigated evidence of biomass burning in global ice records, and here we continue to test the hypothesis that an impact event at the Younger Dryas boundary (YDB) caused an anomalously intense episode of biomass burning at ∼12.8 ka on a multicontinental scale (North and South America, Europe, and Asia). Quantitative analyses of charcoal and soot records from 152 lakes, marine cores, and terrestrial sequences reveal a major peak in biomass burning at the Younger Dryas (YD) onset that appears to be the highest during the latest Quaternary. For the Cretaceous-Tertiary boundary (K-Pg) impact event, concentrations of soot were previously utilized to estimate the global amount of biomass burned, and similar measurements suggest that wildfires at the YD onset rapidly consumed ∼10 million km2 of Earth’s surface, or ∼9% of Earth’s biomass, considerably more than for the K-Pg impact. Bayesian analyses and age regressions demonstrate that ages for YDB peaks in charcoal and soot across four continents are synchronous with the ages of an abundance peak in platinum in the Greenland Ice Sheet Project 2 (GISP2) ice core and of the YDB impact event (12,835–12,735 cal BP). Thus, existing evidence indicates that the YDB impact event caused an anomalously large episode of biomass burning, resulting in extensive atmospheric soot/dust loading that triggered an “impact winter.” This, in turn, triggered abrupt YD cooling and other climate changes, reinforced by climatic feedback mechanisms, including Arctic sea ice expansion, rerouting of North American continental runoff, and subsequent ocean circulation changes.

Published
2018

6. A Tunguska sized airburst destroyed Tall el-Hammam a Middle Bronze Age city in the Jordan Valley near the Dead Sea

Author

Bunch, Ted E., LeCompte, Malcolm A., Adedeji, A. Victor, Wittke, James H., Burleigh, T. David, Hermes, Robert E., Mooney, Charles, Batchelor, Dale, Wolbach, Wendy S., Kathan, Joel, Kletetschka, Gunther, Patterson, Mark C. L., Swindel, Edward C., Witwer, Timothy, Howard, George A., Mitra, Siddhartha, Moore, Christopher R., Langworthy, Kurt, Kennett, James P., West, Allen, and Silvia, Phillip J.

Published
2021
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7. Bayesian chronological analyses consistent with synchronous age of 12,835–12,735 Cal B.P. for Younger Dryas boundary on four continents

Author

Kennett, James P, Kennett, Douglas J, Culleton, Brendan J, Tortosa, J Emili Aura, Bischoff, James L, Bunch, Ted E, Daniel, I Randolph, Erlandson, Jon M, Ferraro, David, Firestone, Richard B, Goodyear, Albert C, Israde-Alcántara, Isabel, Johnson, John R, Pardo, Jesús F Jordá, Kimbel, David R, LeCompte, Malcolm A, Lopinot, Neal H, Mahaney, William C, Moore, Andrew MT, Moore, Christopher R, Ray, Jack H, Stafford, Thomas W, Tankersley, Kenneth Barnett, Wittke, James H, Wolbach, Wendy S, and West, Allen

Subjects
Younger Dryas, comet, Bayesian, radiocarbon, synchroneity
Abstract

The Younger Dryas impact hypothesis posits that a cosmic impact across much of the Northern Hemisphere deposited the Younger Dryas boundary (YDB) layer, containing peak abundances in a variable assemblage of proxies, including magnetic and glassy impact-related spherules, high-temperature minerals and melt glass, nanodiamonds, carbon spherules, aciniform carbon, platinum, and osmium. Bayesian chronological modeling was applied to 354 dates from 23 stratigraphic sections in 12 countries on four continents to establish a modeled YDB age range for this event of 12,835-12,735 Cal B.P. at 95% probability. This range overlaps that of a peak in extraterrestrial platinum in the Greenland Ice Sheet and of the earliest age of the Younger Dryas climate episode in six proxy records, suggesting a causal connection between the YDB impact event and the Younger Dryas. Two statistical tests indicate that both modeled and unmodeled ages in the 30 records are consistent with synchronous deposition of the YDB layer within the limits of dating uncertainty (∼ 100 y). The widespread distribution of the YDB layer suggests that it may serve as a datum layer.

Published
2015

8. Nanodiamond-Rich Layer across Three Continents Consistent with Major Cosmic Impact at 12,800 Cal BP

Author

Kinzie, Charles R, Hee, Shane S Que, Stich, Adrienne, Tague, Kevin A, Mercer, Chris, Razink, Joshua J, Kennett, Douglas J, DeCarli, Paul S, Bunch, Ted E, Wittke, James H, Israde-Alcántara, Isabel, Bischoff, James L, Goodyear, Albert C, Tankersley, Kenneth B, Kimbel, David R, Culleton, Brendan J, Erlandson, Jon M, Stafford, Thomas W, Kloosterman, Johan B, Moore, Andrew MT, Firestone, Richard B, Tortosa, JE Aura, Pardo, JF Jordá, West, Allen, Kennett, James P, and Wolbach, Wendy S

Subjects
Geochemistry, Geology
Abstract

A major cosmic-impact event has been proposed at the onset of the Younger Dryas (YD) cooling episode at ≈12,800 ± 150 years before present, forming the YD Boundary (YDB) layer, distributed over 150 million km2 on four continents. In 24 dated stratigraphic sections in 10 countries of the Northern Hemisphere, the YDB layer contains a clearly defined abundance peak in nanodiamonds (NDs), a major cosmic-impact proxy. Observed ND polytypes include cubic diamonds, lonsdaleite-like crystals, and diamond-like carbon nanoparticles, called n-diamond and i-carbon. The ND abundances in bulk YDB sediments ranged up to ≈500 ppb (mean: 200 ppb) and that in carbon spherules up to ≈3700 ppb (mean: ≈750 ppb); 138 of 205 sediment samples (67%) contained no detectable NDs. Isotopic evidence indicates that YDB NDs were produced from terrestrial carbon, as with other impact diamonds, and were not derived from the impactor itself. The YDB layer is also marked by abundance peaks in other impact-related proxies, including cosmic-impact spherules, carbon spherules (some containing NDs), iridium, osmium, platinum, charcoal, aciniform carbon (soot), and high-temperature melt-glass. This contribution reviews the debate about the presence, abundance, and origin of the concentration peak in YDB NDs.We describe an updated protocol for the extraction and concentration of NDs from sediment, carbon spherules, and ice, and we describe the basis for identification and classification of YDB ND polytypes, using nine analytical approaches. The large body of evidence now obtained about YDB NDs is strongly consistent with an origin by cosmic impact at ≈12,800 cal BP and is inconsistent with formation of YDB NDs by natural terrestrial processes, including wildfires, anthropogenesis, and/or influx of cosmic dust.

Published
2014

9. Extraordinary Biomass-Burning Episode and Impact Winter Triggered by the Younger Dryas Cosmic Impact ̃12,800 Years Ago. 2. Lake, Marine, and Terrestrial Sediments

Author

Wolbach, Wendy S., Ballard, Joanne P., Mayewski, Paul A., Parnell, Andrew C., Cahill, Niamh, Adedeji, Victor, Bunch, Ted E., Domínguez-Vázquez, Gabriela, Erlandson, Jon M., Firestone, Richard B., French, Timothy A., Howard, George, Israde-Alcántara, Isabel, Johnson, John R., Kimbel, David, Kinzie, Charles R., Kurbatov, Andrei, Kletetschka, Gunther, LeCompte, Malcolm A., Mahaney, William C., Melott, Adrian L., Mitra, Siddhartha, Maiorana-Boutilier, Abigail, Moore, Christopher R., Napier, William M., Parlier, Jennifer, Tankersley, Kenneth B., Thomas, Brian C., Wittke, James H., West, Allen, and Kennett, James P.

Published
2018

10. Extraordinary Biomass-Burning Episode and Impact Winter Triggered by the Younger Dryas Cosmic Impact ̃12,800 Years Ago. 1. Ice Cores and Glaciers

Author

Wolbach, Wendy S., Ballard, Joanne P., Mayewski, Paul A., Adedeji, Victor, Bunch, Ted E., Firestone, Richard B., French, Timothy A., Howard, George A., Israde-Alcántara, Isabel, Johnson, John R., Kimbel, David, Kinzie, Charles R., Kurbatov, Andrei, Kletetschka, Gunther, LeCompte, Malcolm A., Mahaney, William C., Melott, Adrian L., Maiorana-Boutilier, Abigail, Mitra, Siddhartha, Moore, Christopher R., Napier, William M., Parlier, Jennifer, Tankersley, Kenneth B., Thomas, Brian C., Wittke, James H., West, Allen, and Kennett, James P.

Published
2018

14. Sediment Cores from White Pond, South Carolina, contain a Platinum Anomaly, Pyrogenic Carbon Peak, and Coprophilous Spore Decline at 12.8 ka

Author

Moore, Christopher R., Brooks, Mark J., Goodyear, Albert C., Ferguson, Terry A., Perrotti, Angelina G., Mitra, Siddhartha, Listecki, Ashlyn M., King, Bailey C., Mallinson, David J., Lane, Chad S., Kapp, Joshua D., West, Allen, Carlson, David L., Wolbach, Wendy S., Them, II, Theodore R., Harris, M. Scott, and Pyne-O’Donnell, Sean

Published
2019
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15. Sedimentary record from Patagonia, southern Chile supports cosmic-impact triggering of biomass burning, climate change, and megafaunal extinctions at 12.8 ka

Author

Pino, Mario, Abarzúa, Ana M., Astorga, Giselle, Martel-Cea, Alejandra, Cossio-Montecinos, Nathalie, Navarro, R. Ximena, Lira, Maria Paz, Labarca, Rafael, LeCompte, Malcolm A., Adedeji, Victor, Moore, Christopher R., Bunch, Ted E., Mooney, Charles, Wolbach, Wendy S., West, Allen, and Kennett, James P.

Published
2019
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16. Abu Hureyra, Syria, Part 1: Shock-fractured quartz grains support 12,800-year-old cosmic airburst at the Younger Dryas onset

Author

Moore, Andrew M.T., primary, Kennett, James P., additional, LeCompte, Malcolm A., additional, Moore, Christopher R., additional, Li, Yong-Qing, additional, Kletetschka, Gunther, additional, Langworthy, Kurt, additional, Razink, Joshua J., additional, Brogden, Valerie, additional, van Devener, Brian, additional, Perez, Jesus Paulo, additional, Polson, Randy, additional, Mitra, Siddhartha, additional, Wolbach, Wendy S., additional, and West, Allen, additional

Published
2023
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17. Abu Hureyra, Syria, Part 2: Additional evidence supporting the catastrophic destruction of this prehistoric village by a cosmic airburst ~12,800 years ago

Author

Moore, Andrew M.T., primary, Kennett, James P., additional, Napier, William M., additional, Bunch, Ted E., additional, Weaver, James C., additional, LeCompte, Malcolm A., additional, Adedeji, A. Victor, additional, Kletetschka, Gunther, additional, Hermes, Robert E., additional, Wittke, James H., additional, Razink, Joshua J., additional, Langworthy, Kurt, additional, Gaultois, Michael W., additional, Moore, Christopher R., additional, Mitra, Siddhartha, additional, Maiorana-Boutilier, Abigail, additional, Wolbach, Wendy S., additional, Witwer, Timothy, additional, and West, Allen, additional

Published
2023
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20. Shock-Synthesized Hexagonal Diamonds in Younger Dryas Boundary Sediments

Author

Kennett, Douglas J., Kennett, James P., West, Allen, West, G. James, Bunch, Ted E., Culleton, Brendan J., Erlandson, Jon M., Hee, Shane S. Que, Johnson, John R., Mercer, Chris, Shen, Feng, Sellers, Marilee, Stafford, Thomas W., Stich, Adrienne, Weaver, James C., Wittke, James H., Wolbach, Wendy S., and Stanley, Steven M.

Published
2009
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24. Extraordinary Biomass-Burning Episode and Impact Winter Triggered by the Younger Dryas Cosmic Impact ∼12,800 Years Ago: A Reply

Author

Wolbach, Wendy S., primary, Ballard, Joanne P., additional, Mayewski, Paul A., additional, Kurbatov, Andrei, additional, Bunch, Ted E., additional, LeCompte, Malcolm A., additional, Adedeji, Victor, additional, Israde-Alcántara, Isabel, additional, Firestone, Richard B., additional, Mahaney, William C., additional, Melott, Adrian L., additional, Moore, Christopher R., additional, Napier, William M., additional, Howard, George A., additional, Tankersley, Kenneth B., additional, Thomas, Brian C., additional, Wittke, James H., additional, Johnson, John R., additional, Mitra, Siddhartha, additional, Kennett, James P., additional, Kletetschka, Gunther, additional, and West, Allen, additional

Published
2020
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27. A Search for Soot from Global Wildfires in Central Pacific Cretaceous-Tertiary Boundary and Other Extinction and Impact Horizon Sediments

Author

Wolbach, Wendy S, Widicus, Susanna, and Kyte, Frank T

Subjects
Geosciences (General)
Abstract

Hypotheses of global wildfires following the Cretaceous-Tertiary (KT) boundary impact are supported by high concentrations of elemental carbon (3.6 mg cm-3) and soot (1.8 mg cm-2) in DSDP Site 465, which was located several thousand kilometers from potential continental sources at 65 Ma. Soot is not preserved at four other central Pacific KT localities, but this is attributed to loss during oxic diagenesis. We find no evidence for wildfires related to major impacts in the late Eocene or to Ir anomalies and extinctions in the late Cenomanian.

Published
2003
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33. Extraordinary Biomass-Burning Episode and Impact Winter Triggered by the Younger Dryas Cosmic Impact ∼12,800 Years Ago. 2. Lake, Marine, and Terrestrial Sediments

Author

Wolbach, Wendy S., Ballard, Joanne P., Mayewski, Paul A., Parnell, Andrew, Cahill, Niamh, Adedeji, Victor, Bunch, Ted. E., Domínguez-Vázquez, Gabriela, Erlandson, Jon M., Firestone, Richard B., French, Timothy A., Howard, George, Israde-Alcántara, Isabel, Johnson, John R., Kimbel, David, Kinzie, Charles R., Kurbatov, Andrei, Kletetschka, Gunther, LeCompte, Malcolm A., Mahaney, William C., Melott, Adrian L., Mitra, Siddhartha, Maiorana-Boutilier, Abigail, Moore, Christopher R., Napier, William M., Parlier, Jennifer, Tankersley, Kenneth B., Thomas, Brian C., Wittke, James H., West, Allen, Kennett, James P., Wolbach, Wendy S., Ballard, Joanne P., Mayewski, Paul A., Parnell, Andrew, Cahill, Niamh, Adedeji, Victor, Bunch, Ted. E., Domínguez-Vázquez, Gabriela, Erlandson, Jon M., Firestone, Richard B., French, Timothy A., Howard, George, Israde-Alcántara, Isabel, Johnson, John R., Kimbel, David, Kinzie, Charles R., Kurbatov, Andrei, Kletetschka, Gunther, LeCompte, Malcolm A., Mahaney, William C., Melott, Adrian L., Mitra, Siddhartha, Maiorana-Boutilier, Abigail, Moore, Christopher R., Napier, William M., Parlier, Jennifer, Tankersley, Kenneth B., Thomas, Brian C., Wittke, James H., West, Allen, and Kennett, James P.

Abstract

Part 1 of this study investigated evidence of biomass burning in global ice records, and here we continue to test the hypothesis that an impact event at the Younger Dryas boundary (YDB) caused an anomalously intense episode of biomass burning at ∼12.8 ka on a multicontinental scale (North and South America, Europe, and Asia). Quantitative analyses of charcoal and soot records from 152 lakes, marine cores, and terrestrial sequences reveal a major peak in biomass burning at the Younger Dryas (YD) onset that appears to be the highest during the latest Quaternary. For the Cretaceous-Tertiary boundary (K-Pg) impact event, concentrations of soot were previously utilized to estimate the global amount of biomass burned, and similar measurements suggest that wildfires at the YD onset rapidly consumed ∼10 million km2 of Earth’s surface, or ∼9% of Earth’s biomass, considerably more than for the K-Pg impact. Bayesian analyses and age regressions demonstrate that ages for YDB peaks in charcoal and soot across four continents are synchronous with the ages of an abundance peak in platinum in the Greenland Ice Sheet Project 2 (GISP2) ice core and of the YDB impact event (12,835–12,735 cal BP). Thus, existing evidence indicates that the YDB impact event caused an anomalously large episode of biomass burning, resulting in extensive atmospheric soot/dust loading that triggered an “impact winter.” This, in turn, triggered abrupt YD cooling and other climate changes, reinforced by climatic feedback mechanisms, including Arctic sea ice expansion, rerouting of North American continental runoff, and subsequent ocean circulation changes.

Published
2018

34. Major wildfires at the Cretaceous-Tertiary boundary

Author

Anders, Edward, Wolbach, Wendy S, and Gilmour, Iain

Subjects
Geophysics
Abstract

The current status of the reconstruction of major biomass fire events at the Cretaceous-Tertiary boundary is discussed. Attention is given to the sources of charcoal and soot, the identification of biomass and fossil carbon, and such ignition-related problems as delated fires, high atmospheric O2 content, ignition mechanisms, and the greenhouse-effect consequences of fire on the scale envisioned. Consequences of these factors for species extinction patterns are noted.

Published
1991

35. Palaeoenvironments and elemental geochemistry across the marine Permo‐Triassic boundary section, Guryul Ravine (Kashmir, India) and a comparison with other North Indian passive margin sections.

Author

Brookfield, Michael E., Stebbins, Alan G., Williams, Jeremy C., Wolbach, Wendy S., Hannigan, Robyn, and Bhat, Ghulam M.

Subjects
GEOCHEMISTRY, PERMIAN-Triassic boundary, ATMOSPHERIC chemistry, CLIMATE change, LOESS, ISOSTASY, CONTINENTAL margins
Abstract

The Guryul Permian–Triassic sediments were deposited on a passive margin in a partially enclosed basin, at a latitude of about 45°S along the southern margin of the Neotethys Ocean. The closest modern analogy is the Japan Sea rotated into a southern hemisphere orientation. Guryul element variations are subdued, mostly lithological, and take place across the change from the dominantly sandy shallow‐water Permian Zewan Formation into the dominantly shaly deeper‐water latest Permian–Triassic Khunamuh Formation, and not at the palaeontological Permian–Triassic boundary. The overall geochemistry of the Guryul sediments is very similar to that of the Ulleung Basin in the Japan Sea, where the sediments are 40%–60% eolian from loess and redeposited loess in the North China Basin. The overall Guryul geochemistry indicates that the sediments were derived from dominantly silica‐rich continental rather than silica‐poor sources although with some more silica‐poor inputs at times. Element ratios suggest increasing aridity and wind abrasion across the Permian–Triassic boundary. Various geochemical redox proxies suggest mainly oxic depositional conditions, with episodes of anoxia, but with little systematic variation across the extinction boundary. Productivity proxies suggest a slight decrease across the Permian–Triassic boundary, and at least one more decreased interval in the Early Triassic. The similar geochemistry of other localities indicate that the Guryul geochemical changes are regional in extent and representative of the North Indian Permian–Triassic passive margin. The lack of consistent element geochemical changes across the boundary accompanied by significant C, S, and other isotopic changes suggests that atmospheric and oceanic chemistry rather than physical changes, such as provenance, climate and sea‐level changes, drove the Permian–Triassic environmental changes and extinctions at least on the mid‐latitude Tethyan shelf of northern India. [ABSTRACT FROM AUTHOR]

Published
2020
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36. Fires at the K/T boundary - Carbon at the Sumbar, Turkmenia, site

Author

Wolbach, Wendy S, Anders, Edward, and Nazarov, Michael A

Subjects
Geophysics
Abstract

Results are reported on carbon analysis and on C and Ir correlations in samples from the marine K-T boundary site SM-4 at the Sumbar River in Turkmenia (USSR), which has the largest known Ir anomaly (580 ng/cq cm). In addition, the boundary clay is thick, and is undisturbed by bioturbation. Kerogen and delta-C-13 elemental carbon in the boundary clay were resolved using a Cr2O7(2-) oxidation method of Wolbach and Anders (1989). It was found that Ir and shocked quartz, both representing impact ejecta, rise sharply at the boundary, peak in the basal layer, and then decline. On the other hand, soot and total elemental C show a similar spike in the basal layer but then rise rather than fall, peking at 7 cm. Results indicate that fires at the SM-4 K-T boundary site started before the basal layer had settled, implying that ignition and spreading of major fires became possible at the time of or very soon after the meteorite impact.

Published
1990
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37. Bayesian chronological analyses consistent with synchronous age of 12,835-12,735 Cal B.P. for Younger Dryas boundary on four continents

Author

Kennett, James P., Kennett, Douglas J., Culleton, Brendan J., Tortosa, J. Emili Aura, Bischoff, James L., Bunch, Ted E., Daniel, I. Randolph, Erlandson, Jon M., Ferraro, David, Firestone, Richard B., Goodyear, Albert C., Israde-Alcántara, Isabel, Johnson, John R., Pardo, Jesús F Jordá, Kimbel, David R., LeCompte, Malcolm A., Lopinot, Neal H., Mahaney, William C., Moore, Andrew M. T., Moore, Christopher R., Ray, Jack H., Stafford jr., Thomas, Tankersley, Kenneth Barnett, Wittke, James H., Wolbach, Wendy S., West, Allen, Kennett, James P., Kennett, Douglas J., Culleton, Brendan J., Tortosa, J. Emili Aura, Bischoff, James L., Bunch, Ted E., Daniel, I. Randolph, Erlandson, Jon M., Ferraro, David, Firestone, Richard B., Goodyear, Albert C., Israde-Alcántara, Isabel, Johnson, John R., Pardo, Jesús F Jordá, Kimbel, David R., LeCompte, Malcolm A., Lopinot, Neal H., Mahaney, William C., Moore, Andrew M. T., Moore, Christopher R., Ray, Jack H., Stafford jr., Thomas, Tankersley, Kenneth Barnett, Wittke, James H., Wolbach, Wendy S., and West, Allen

Abstract

The Younger Dryas impact hypothesis posits that a cosmic impact across much of the Northern Hemisphere deposited the Younger Dryas boundary (YDB) layer, containing peak abundances in a variable assemblage of proxies, including magnetic and glassy impact-related spherules, high-temperature minerals and melt glass, nanodiamonds, carbon spherules, aciniform carbon, platinum, and osmium. Bayesian chronological modeling was applied to 354 dates from 23 stratigraphic sections in 12 countries on four continents to establish a modeled YDB age range for this event of 12,835-12,735 Cal B.P. at 95% probability. This range overlaps that of a peak in extraterrestrial platinum in the Greenland Ice Sheet and of the earliest age of the Younger Dryas climate episode in six proxy records, suggesting a causal connection between the YDB impact event and the Younger Dryas. Two statistical tests indicate that both modeled and unmodeled ages in the 30 records are consistent with synchronous deposition of the YDB layer within the limits of dating uncertainty (100 y). The widespread distribution of the YDB layer suggests that it may serve as a datum layer.

Published
2015

40. Global fire at the Cretaceous-Tertiary boundary

Author

Wolbach, Wendy S., Gilmour, Iain, Orth, Charles J., Brooks, Robert R., and Anders, Edward

Subjects
Geology, Stratigraphic -- Tertiary, Geophysical research -- Analysis, Meteorites -- Research, Fires -- Research, Geology, Stratigraphic -- Cretaceous, Environmental issues, Science and technology, Zoology and wildlife conservation
Published
1988

42. Discovery of a nanodiamond-rich layer in the Greenland ice sheet

Author

Kurbatov, Andrei V., primary, Mayewski, Paul A., additional, Steffensen, Jorgen P., additional, West, Allen, additional, Kennett, Douglas J., additional, Kennett, James P., additional, Bunch, Ted E., additional, Handley, Mike, additional, Introne, Douglas S., additional, Que Hee, Shane S., additional, Mercer, Christopher, additional, Sellers, Marilee, additional, Shen, Feng, additional, Sneed, Sharon B., additional, Weaver, James C., additional, Wittke, James H., additional, Stafford, Thomas W., additional, Donovan, John J., additional, Xie, Sujing, additional, Razink, Joshua J., additional, Stich, Adrienne, additional, Kinzie, Charles R., additional, and Wolbach, Wendy S., additional

Published
2010
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43. Major wildfires at the Cretaceous-Tertiary boundary

Author

Gilmour, Iain, Wolbach, Wendy S, and Anders, Edward

Subjects
Geophysics
Abstract

K-T boundary (KTB) clays from five sites are enriched in soot and charcoal by factors of 100-1000 over Cretaceous levels, apparently due to a global fire. The soot profile nearly coincides with the Ir profile, implying that the fire was triggered by the impact. Much or all of the fuel was biomass, as indicated by the presence of retene and by the C isotopic composition. The amount of elemental C at the KTB (0.012 g/sq cm) is very large, and requires either that most of the Cretaceous biomass burned down or that the soot yield was higher than in small fires. At undisturbed sites, soot correlates tightly with Ir, As, Sb, and Zn. Apparently soot and Ir-bearing ejecta particles coagulated in the stratosphere and then scavenged additional chalcophiles from the hydrosphere. In view of this coagulation, the K-T fire would only slightly prolong the period of darkness and cold caused by impact ejecta.

Published
1989

44. Early environmental effects of the terminal Cretaceous impact

Author

Gilmour, Iain, Wolbach, Wendy S, and Anders, Edward

Subjects
Space Biology
Abstract

The environmental aftereffects of the terminal Cretaceous impact are examined on the basis of the carbon and nitrogen geochemistry in the basal layer of the K-T boundary clay at Woodside Creek, New Zealand. It is shown that organic carbon and nitrogen at this level are enriched by 15 and 20 times Cretaceous values, respectively. Also, it is found that the N abundances and, to a lesser extent, the organic C abundances are closely correlated with the Ir abundances. The changes in carbon and nitrogen content through the basal layer are outlined, focusing on the possible environmental conditions which could have caused enrichment. In addition, consideration is given to the soot and pyrotoxin content. Possible scenarios for the K-T event and the importance of selective extinction are discussed.

Published
1988

45. Darkness after the K-T impact: Effects of soot

Author

Wolbach, Wendy S, Anders, Edward, and Orth, Charles J

Subjects
Environment Pollution
Abstract

Dust from the K-T impact apparently settled from the atmosphere in less than 6 months, restoring sunlight to minimum photosynthesis levels in about 4 months. However, the discovery of a global soot component in the boundary clay makes it necessary to reconsider the problem, as soot particles not only are smaller (0.1 vs. about 0.5 micrometer) and thus settle more slowly, but also are better light absorbers (optical depth of 13 mg soot cm(-2) about 1800; and are more resistant to rainout. Still, the darkness cannot have lasted very much longer than 6 months, else no larger animals would have survived. Perhaps the soot coagulated with the rock dust and fell out with it. Evidence on this point may be sought at a relatively undisturbed K-T boundary site, such as Woodside Creek, N.Z. There the boundary clay and lowermost Tertiary strata are finely laminated and show large chemical and isotopic differences on a millimeter scale, apparently representing a detailed time sequence. Researchers studied a 3 m section across the boundary at this site, analyzing the principal forms of carbon (soot, elemental C, kerogen, and carbonate) as well as 33 elements. Correlations among the elements were sought. Apparently soot came early and coagulated with the ejecta, staying with them for the primary fallout and in the next 5 cm, but then parting company, perhaps due to size sorting.

Published
1988

46. Fullerenes in the Cretaceous-Tertiary Boundary.

Author

Braun, Tibor, Rietmeijer, Frans J. M., Heymann, Dieter, and Wolbach, Wendy S.

Abstract

Fullerenes C60 and C70 were found in the thin clay seams of nine worldwide locations of the geologic boundary between the Cretaceous and Tertiary periods. These clays are also rich in soot. One hypothesis suggests that the fullerenes were synthesized in global wildfires that followed the meteorite impact 65 Ma ago. An alternative hypothesis suggests that the fullerenes predate the formation of the solar system because they contain isotopically anomalous helium in their carbon cages. [ABSTRACT FROM AUTHOR]

Published
2006
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48. Elemental carbon in sediments: Determination and isotopic analysis in the presence of kerogen

Author

Wolbach, Wendy S and Anders, Edward

Abstract

A procedure has been developed for separate measurement and isotopic analysis of kerogen and elemental C (soot, charcoal) in sedimentary rocks. The carbonaceous residue left after HF-HCl dissolution is oxidized with 0.10 MCr2O7=in 2 MH2SO4at 50°C. Kerogen reacts with a half-life of 6–180 hrs, depending on maturity, and thus can be quantitatively removed from elemental C, which reacts more slowly (t12≈ 600–2000 hr). The amount and isotopic composition of kerogen and elemental C are then obtained by measurement of etched and unetched samples, after applying a correction for the loss of elemental C in the etch.

Published
1989
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