Your search keyword '"Bohaty SM"' showing total 6 results

1. Ice sheet-free West Antarctica during peak early Oligocene glaciation.

Author

Klages JP, Hillenbrand CD, Bohaty SM, Salzmann U, Bickert T, Lohmann G, Knahl HS, Gierz P, Niu L, Titschack J, Kuhn G, Frederichs T, Müller J, Bauersachs T, Larter RD, Hochmuth K, Ehrmann W, Nehrke G, Rodríguez-Tovar FJ, Schmiedl G, Spezzaferri S, Läufer A, Lisker F, van de Flierdt T, Eisenhauer A, Uenzelmann-Neben G, Esper O, Smith JA, Pälike H, Spiegel C, Dziadek R, Ronge TA, Freudenthal T, and Gohl K

Abstract

One of Earth's most fundamental climate shifts, the greenhouse-icehouse transition 34 million years ago, initiated Antarctic ice sheet buildup, influencing global climate until today. However, the extent of the ice sheet during the Early Oligocene Glacial Maximum (~33.7 to 33.2 million years ago) that immediately followed this transition-a critical knowledge gap for assessing feedbacks between permanently glaciated areas and early Cenozoic global climate reorganization-is uncertain. In this work, we present shallow-marine drilling data constraining earliest Oligocene environmental conditions on West Antarctica's Pacific margin-a key region for understanding Antarctic ice sheet evolution. These data indicate a cool-temperate environment with mild ocean and air temperatures that prevented West Antarctic Ice Sheet formation. Climate-ice sheet modeling corroborates a highly asymmetric Antarctic ice sheet, thereby revealing its differential regional response to past and future climatic change.

Published

2024

2. An astronomically dated record of Earth's climate and its predictability over the last 66 million years.

Author

Westerhold T, Marwan N, Drury AJ, Liebrand D, Agnini C, Anagnostou E, Barnet JSK, Bohaty SM, De Vleeschouwer D, Florindo F, Frederichs T, Hodell DA, Holbourn AE, Kroon D, Lauretano V, Littler K, Lourens LJ, Lyle M, Pälike H, Röhl U, Tian J, Wilkens RH, Wilson PA, and Zachos JC

Abstract

Much of our understanding of Earth's past climate comes from the measurement of oxygen and carbon isotope variations in deep-sea benthic foraminifera. Yet, long intervals in existing records lack the temporal resolution and age control needed to thoroughly categorize climate states of the Cenozoic era and to study their dynamics. Here, we present a new, highly resolved, astronomically dated, continuous composite of benthic foraminifer isotope records developed in our laboratories. Four climate states-Hothouse, Warmhouse, Coolhouse, Icehouse-are identified on the basis of their distinctive response to astronomical forcing depending on greenhouse gas concentrations and polar ice sheet volume. Statistical analysis of the nonlinear behavior encoded in our record reveals the key role that polar ice volume plays in the predictability of Cenozoic climate dynamics., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2020

3. Antarctic Ice Sheet variability across the Eocene-Oligocene boundary climate transition.

Author

Galeotti S, DeConto R, Naish T, Stocchi P, Florindo F, Pagani M, Barrett P, Bohaty SM, Lanci L, Pollard D, Sandroni S, Talarico FM, and Zachos JC

Abstract

About 34 million years ago, Earth's climate cooled and an ice sheet formed on Antarctica as atmospheric carbon dioxide (CO2) fell below ~750 parts per million (ppm). Sedimentary cycles from a drill core in the western Ross Sea provide direct evidence of orbitally controlled glacial cycles between 34 million and 31 million years ago. Initially, under atmospheric CO2 levels of ≥600 ppm, a smaller Antarctic Ice Sheet (AIS), restricted to the terrestrial continent, was highly responsive to local insolation forcing. A more stable, continental-scale ice sheet calving at the coastline did not form until ~32.8 million years ago, coincident with the earliest time that atmospheric CO2 levels fell below ~600 ppm. Our results provide insight into the potential of the AIS for threshold behavior and have implications for its sensitivity to atmospheric CO2 concentrations above present-day levels., (Copyright © 2016, American Association for the Advancement of Science.)

Published

2016

4. Reorganization of Southern Ocean plankton ecosystem at the onset of Antarctic glaciation.

Author

Houben AJ, Bijl PK, Pross J, Bohaty SM, Passchier S, Stickley CE, Röhl U, Sugisaki S, Tauxe L, van de Flierdt T, Olney M, Sangiorgi F, Sluijs A, Escutia C, Brinkhuis H, Dotti CE, Klaus A, Fehr A, Williams T, Bendle JA, Carr SA, Dunbar RB, Flores JA, Gonzàlez JJ, Hayden TG, Iwai M, Jimenez-Espejo FJ, Katsuki K, Kong GS, McKay RM, Nakai M, Pekar SF, Riesselman C, Sakai T, Salzmann U, Shrivastava PK, Tuo S, Welsh K, and Yamane M

Subjects

Animals, Antarctic Regions, Cold Temperature, Fossils, Adaptation, Physiological, Dinoflagellida physiology, Ecosystem, Ice Cover, Oceans and Seas, Phytoplankton physiology, Zooplankton physiology

Abstract

The circum-Antarctic Southern Ocean is an important region for global marine food webs and carbon cycling because of sea-ice formation and its unique plankton ecosystem. However, the mechanisms underlying the installation of this distinct ecosystem and the geological timing of its development remain unknown. Here, we show, on the basis of fossil marine dinoflagellate cyst records, that a major restructuring of the Southern Ocean plankton ecosystem occurred abruptly and concomitant with the first major Antarctic glaciation in the earliest Oligocene (~33.6 million years ago). This turnover marks a regime shift in zooplankton-phytoplankton interactions and community structure, which indicates the appearance of eutrophic and seasonally productive environments on the Antarctic margin. We conclude that earliest Oligocene cooling, ice-sheet expansion, and subsequent sea-ice formation were important drivers of biotic evolution in the Southern Ocean.

Published

2013

5. The role of carbon dioxide during the onset of Antarctic glaciation.

Author

Pagani M, Huber M, Liu Z, Bohaty SM, Henderiks J, Sijp W, Krishnan S, and DeConto RM

Abstract

Earth's modern climate, characterized by polar ice sheets and large equator-to-pole temperature gradients, is rooted in environmental changes that promoted Antarctic glaciation ~33.7 million years ago. Onset of Antarctic glaciation reflects a critical tipping point for Earth's climate and provides a framework for investigating the role of atmospheric carbon dioxide (CO(2)) during major climatic change. Previously published records of alkenone-based CO(2) from high- and low-latitude ocean localities suggested that CO(2) increased during glaciation, in contradiction to theory. Here, we further investigate alkenone records and demonstrate that Antarctic and subantarctic data overestimate atmospheric CO(2) levels, biasing long-term trends. Our results show that CO(2) declined before and during Antarctic glaciation and support a substantial CO(2) decrease as the primary agent forcing Antarctic glaciation, consistent with model-derived CO(2) thresholds.

Published

2011

6. Transient Middle Eocene atmospheric CO₂ and temperature variations.

Author

Bijl PK, Houben AJ, Schouten S, Bohaty SM, Sluijs A, Reichart GJ, Sinninghe Damsté JS, and Brinkhuis H

Abstract

The long-term warmth of the Eocene (~56 to 34 million years ago) is commonly associated with elevated partial pressure of atmospheric carbon dioxide (pCO(2)). However, a direct relationship between the two has not been established for short-term climate perturbations. We reconstructed changes in both pCO(2) and temperature over an episode of transient global warming called the Middle Eocene Climatic Optimum (MECO; ~40 million years ago). Organic molecular paleothermometry indicates a warming of southwest Pacific sea surface temperatures (SSTs) by 3° to 6°C. Reconstructions of pCO(2) indicate a concomitant increase by a factor of 2 to 3. The marked consistency between SST and pCO(2) trends during the MECO suggests that elevated pCO(2) played a major role in global warming during the MECO.

Published

2010