Your search keyword '"Salzmann U"' showing total 12 results

1. Pliocene Model Intercomparison Project Phase 3 (PlioMIP3) – Science plan and experimental design

Author

Haywood, A.M., Tindall, J.C., Burton, L.E., Chandler, M.A., Dolan, A.M., Dowsett, H.J., Feng, R., Fletcher, T.L., Foley, K.M., Hill, D.J., Hunter, S.J., Otto-Bliesner, B.L., Lunt, D.J., Robinson, M.M., and Salzmann, U.

Published

2024

2. Ice sheet–free West Antarctica during peak early Oligocene glaciation

Author

Smith, H Jesse, Klages, Johann Philipp, Hillenbrand, C-D, 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, Gohl, K, Smith, H Jesse, Klages, Johann Philipp, Hillenbrand, C-D, 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 Ma ago – initiated Antarctic ice-sheet build-up, influencing global climate until today. However, the extent of the ice sheet during the Early Oligocene Glacial Maximum (~33.7–33.2 Ma) that immediately followed this transition, a critical knowledge gap for assessing feedbacks between permanently glaciated areas and early Cenozoic global climate reorganization, is uncertain. Here, 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 preventing 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

3. Ice sheet–free West Antarctica during peak early Oligocene glaciation

Author

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

Abstract

One of Earth’s most fundamental climate shifts – the greenhouse-icehouse transition 34 Ma ago – initiated Antarctic ice-sheet build-up, influencing global climate until today. However, the extent of the ice sheet during the Early Oligocene Glacial Maximum (~33.7–33.2 Ma) that immediately followed this transition, a critical knowledge gap for assessing feedbacks between permanently glaciated areas and early Cenozoic global climate reorganization, is uncertain. Here, 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 preventing 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

4. Ice sheet–free West Antarctica during peak early Oligocene glaciation

Author

Klages, J. P., Hillenbrand, C.-D., Bohaty, S. M., Salzmann, U., Bickert, T., Lohmann, G., Knahl, H. S., Gierz, P., Niu, L., Titschack, J., Kuhn, G., Frederichs, T., Müller, J., Bauersachs, T., Larter, R. D., Hochmuth, K., Ehrmann, W., Nehrke, G., Rodríguez-Tovar, F. J., Schmiedl, G., Spezzaferri, S., Läufer, A., Lisker, F., van de Flierdt, T., Eisenhauer, Anton, Uenzelmann-Neben, G., Esper, O., Smith, J. A., Pälike, H., Spiegel, C., Dziadek, R., Ronge, T. A., Freudenthal, T., Gohl, K., Klages, J. P., Hillenbrand, C.-D., Bohaty, S. M., Salzmann, U., Bickert, T., Lohmann, G., Knahl, H. S., Gierz, P., Niu, L., Titschack, J., Kuhn, G., Frederichs, T., Müller, J., Bauersachs, T., Larter, R. D., Hochmuth, K., Ehrmann, W., Nehrke, G., Rodríguez-Tovar, F. J., Schmiedl, G., Spezzaferri, S., Läufer, A., Lisker, F., van de Flierdt, T., Eisenhauer, Anton, Uenzelmann-Neben, G., Esper, O., Smith, J. A., Pälike, H., Spiegel, C., Dziadek, R., Ronge, T. A., 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. Editor’s summary Earth’s climate underwent a dramatic transition around 34 million years ago, when the Antarctic Ice Sheet first began to form, but the regional evolution of that ice sheet remains poorly defined. Klages et al . present data from marine sediments near West Antarctica showing that conditions there during the beginning of the Oligocene were mild and unfavorable to the growth of a permanent ice sheet. Model results based on those data suggest that the ice sheet in West Antarctica did not begin to form until 7 or 8 million years after the process began in East Antarctica.

Published

2024

5. A large-scale transcontinental river system crossed West Antarctica during the Eocene

Author

Zundel, M., Spiegel, C., Mark, C., Millar, I.L., Chew, D., Klages, J.P., Gohl, K., Hillenbrand, C.-D., Najman, Y., Salzmann, U., Ehrmann, W., Titschack, J., Bauersachs, T., Uenzelmann-Neben, G., Bickert, T., Müller, J., Larter, R., Lisker, F., Bohaty, S.M., Kuhn, G., Zundel, M., Spiegel, C., Mark, C., Millar, I.L., Chew, D., Klages, J.P., Gohl, K., Hillenbrand, C.-D., Najman, Y., Salzmann, U., Ehrmann, W., Titschack, J., Bauersachs, T., Uenzelmann-Neben, G., Bickert, T., Müller, J., Larter, R., Lisker, F., Bohaty, S.M., and Kuhn, G.

Abstract

Extensive ice coverage largely prevents investigations of Antarctica’s unglaciated past. Knowledge about environmental and tectonic development before large-scale glaciation, however, is important for understanding the transition into the modern icehouse world. We report geochronological and sedimentological data from a drill core from the Amundsen Sea shelf, providing insights into tectonic and topographic conditions during the Eocene (~44 to 34 million years ago), shortly before major ice sheet buildup. Our findings reveal the Eocene as a transition period from >40 million years of relative tectonic quiescence toward reactivation of the West Antarctic Rift System, coinciding with incipient volcanism, rise of the Transantarctic Mountains, and renewed sedimentation under temperate climate conditions. The recovered sediments were deposited in a coastal-estuarine swamp environment at the outlet of a >1500-km-long transcontinental river system, draining from the rising Transantarctic Mountains into the Amundsen Sea. Much of West Antarctica hence lied above sea level, but low topographic relief combined with low elevation inhibited widespread ice sheet formation.

Published

2024

6. Pliocene model intercomparison project Phase 3 (PlioMIP3) – Science plan and experimental design

Author

Haywood, A.M., primary, Tindall, J.C., additional, Burton, L.E., additional, Chandler, M.A., additional, Dolan, A.M., additional, Dowsett, H.J., additional, Feng, R., additional, Fletcher, T.L., additional, Foley, K.M., additional, Hill, D.J., additional, Hunter, S.J., additional, Otto-Bliesner, B.L., additional, Lunt, D.J., additional, Robinson, M.M., additional, and Salzmann, U., additional

Published

2023

7. A large-scale transcontinental river system crossed West Antarctica during the Eocene.

Author

Zundel M, Spiegel C, Mark C, Millar I, Chew D, Klages J, Gohl K, Hillenbrand CD, Najman Y, Salzmann U, Ehrmann W, Titschack J, Bauersachs T, Uenzelmann-Neben G, Bickert T, Müller J, Larter R, Lisker F, Bohaty S, and Kuhn G

Abstract

Extensive ice coverage largely prevents investigations of Antarctica's unglaciated past. Knowledge about environmental and tectonic development before large-scale glaciation, however, is important for understanding the transition into the modern icehouse world. We report geochronological and sedimentological data from a drill core from the Amundsen Sea shelf, providing insights into tectonic and topographic conditions during the Eocene (~44 to 34 million years ago), shortly before major ice sheet buildup. Our findings reveal the Eocene as a transition period from >40 million years of relative tectonic quiescence toward reactivation of the West Antarctic Rift System, coinciding with incipient volcanism, rise of the Transantarctic Mountains, and renewed sedimentation under temperate climate conditions. The recovered sediments were deposited in a coastal-estuarine swamp environment at the outlet of a >1500-km-long transcontinental river system, draining from the rising Transantarctic Mountains into the Amundsen Sea. Much of West Antarctica hence lied above sea level, but low topographic relief combined with low elevation inhibited widespread ice sheet formation.

Published

2024

8. Deciphering local and regional hydroclimate resolves contradicting evidence on the Asian monsoon evolution.

Author

Wolf A, Ersek V, Braun T, French AD, McGee D, Bernasconi SM, Skiba V, Griffiths ML, Johnson KR, Fohlmeister J, Breitenbach SFM, Pausata FSR, Tabor CR, Longman J, Roberts WHG, Chandan D, Peltier WR, Salzmann U, Limbert D, Trinh HQ, and Trinh AD

Abstract

The winter and summer monsoons in Southeast Asia are important but highly variable sources of rainfall. Current understanding of the winter monsoon is limited by conflicting proxy observations, resulting from the decoupling of regional atmospheric circulation patterns and local rainfall dynamics. These signals are difficult to decipher in paleoclimate reconstructions. Here, we present a winter monsoon speleothem record from Southeast Asia covering the Holocene and find that winter and summer rainfall changed synchronously, forced by changes in the Pacific and Indian Oceans. In contrast, regional atmospheric circulation shows an inverse relation between winter and summer controlled by seasonal insolation over the Northern Hemisphere. We show that disentangling the local and regional signal in paleoclimate reconstructions is crucial in understanding and projecting winter and summer monsoon variability in Southeast Asia., (© 2023. Springer Nature Limited.)

Published

2023

9. Highly restricted near-surface permafrost extent during the mid-Pliocene warm period.

Author

Guo D, Wang H, Romanovsky VE, Haywood AM, Pepin N, Salzmann U, Sun J, Yan Q, Zhang Z, Li X, Otto-Bliesner BL, Feng R, Lohmann G, Stepanek C, Abe-Ouchi A, Chan WL, Peltier WR, Chandan D, von der Heydt AS, Contoux C, Chandler MA, Tan N, Zhang Q, Hunter SJ, and Kamae Y

Abstract

Accurate understanding of permafrost dynamics is critical for evaluating and mitigating impacts that may arise as permafrost degrades in the future; however, existing projections have large uncertainties. Studies of how permafrost responded historically during Earth's past warm periods are helpful in exploring potential future permafrost behavior and to evaluate the uncertainty of future permafrost change projections. Here, we combine a surface frost index model with outputs from the second phase of the Pliocene Model Intercomparison Project to simulate the near-surface (~3 to 4 m depth) permafrost state in the Northern Hemisphere during the mid-Pliocene warm period (mPWP, ~3.264 to 3.025 Ma). This period shares similarities with the projected future climate. Constrained by proxy-based surface air temperature records, our simulations demonstrate that near-surface permafrost was highly spatially restricted during the mPWP and was 93 ± 3% smaller than the preindustrial extent. Near-surface permafrost was present only in the eastern Siberian uplands, Canadian high Arctic Archipelago, and northernmost Greenland. The simulations are similar to near-surface permafrost changes projected for the end of this century under the SSP5-8.5 scenario and provide a perspective on the potential permafrost behavior that may be expected in a warmer world.

Published

2023

10. Safeguarding Imperiled Biodiversity and Evolutionary Processes in the Wallacea Center of Endemism.

Author

Struebig MJ, Aninta SG, Beger M, Bani A, Barus H, Brace S, Davies ZG, Brauwer M, Diele K, Djakiman C, Djamaluddin R, Drinkwater R, Dumbrell A, Evans D, Fusi M, Herrera-Alsina L, Iskandar DT, Jompa J, Juliandi B, Lancaster LT, Limmon G, Lindawati, Lo MGY, Lupiyaningdyah P, McCannon M, Meijaard E, Mitchell SL, Mumbunan S, O'Connell D, Osborne OG, Papadopulos AST, Rahajoe JS, Rosaria, Rossiter SJ, Rugayah, Rustiami H, Salzmann U, Sheherazade, Sudiana IM, Sukara E, Tasirin JS, Tjoa A, Travis JMJ, Trethowan L, Trianto A, Utteridge T, Voigt M, Winarni N, Zakaria Z, Edwards DP, Frantz L, and Supriatna J

Abstract

Wallacea-the meeting point between the Asian and Australian fauna-is one of the world's largest centers of endemism. Twenty-three million years of complex geological history have given rise to a living laboratory for the study of evolution and biodiversity, highly vulnerable to anthropogenic pressures. In the present article, we review the historic and contemporary processes shaping Wallacea's biodiversity and explore ways to conserve its unique ecosystems. Although remoteness has spared many Wallacean islands from the severe overexploitation that characterizes many tropical regions, industrial-scale expansion of agriculture, mining, aquaculture and fisheries is damaging terrestrial and aquatic ecosystems, denuding endemics from communities, and threatening a long-term legacy of impoverished human populations. An impending biodiversity catastrophe demands collaborative actions to improve community-based management, minimize environmental impacts, monitor threatened species, and reduce wildlife trade. Securing a positive future for Wallacea's imperiled ecosystems requires a fundamental shift away from managing marine and terrestrial realms independently., (© The Author(s) 2022. Published by Oxford University Press on behalf of the American Institute of Biological Sciences.)

Published

2022

11. African Hydroclimate During the Early Eocene From the DeepMIP Simulations.

Author

Williams CJR, Lunt DJ, Salzmann U, Reichgelt T, Inglis GN, Greenwood DR, Chan WL, Abe-Ouchi A, Donnadieu Y, Hutchinson DK, de Boer AM, Ladant JB, Morozova PA, Niezgodzki I, Knorr G, Steinig S, Zhang Z, Zhu J, Huber M, and Otto-Bliesner BL

Abstract

The early Eocene (∼56-48 Myr ago) is characterized by high CO 2 estimates (1,200-2,500 ppmv) and elevated global temperatures (∼10°C-16°C higher than modern). However, the response of the hydrological cycle during the early Eocene is poorly constrained, especially in regions with sparse data coverage (e.g., Africa). Here, we present a study of African hydroclimate during the early Eocene, as simulated by an ensemble of state-of-the-art climate models in the Deep-time Model Intercomparison Project (DeepMIP). A comparison between the DeepMIP pre-industrial simulations and modern observations suggests that model biases are model- and geographically dependent, however, these biases are reduced in the model ensemble mean. A comparison between the Eocene simulations and the pre-industrial suggests that there is no obvious wetting or drying trend as the CO 2 increases. The results suggest that changes to the land sea mask (relative to modern) in the models may be responsible for the simulated increases in precipitation to the north of Eocene Africa. There is an increase in precipitation over equatorial and West Africa and associated drying over northern Africa as CO 2 rises. There are also important dynamical changes, with evidence that anticyclonic low-level circulation is replaced by increased south-westerly flow at high CO 2 levels. Lastly, a model-data comparison using newly compiled quantitative climate estimates from paleobotanical proxy data suggests a marginally better fit with the reconstructions at lower levels of CO 2 ., Competing Interests: The authors declare no conflicts of interest relevant to this study., (© 2022. The Authors.)

Published

2022

12. Alpine permafrost could account for a quarter of thawed carbon based on Plio-Pleistocene paleoclimate analogue.

Author

Cheng F, Garzione C, Li X, Salzmann U, Schwarz F, Haywood AM, Tindall J, Nie J, Li L, Wang L, Abbott BW, Elliott B, Liu W, Upadhyay D, Arnold A, and Tripati A

Subjects

Carbon analysis, Climate, European Alpine Region, Temperature, Permafrost

Abstract

Estimates of the permafrost-climate feedback vary in magnitude and sign, partly because permafrost carbon stability in warmer-than-present conditions is not well constrained. Here we use a Plio-Pleistocene lacustrine reconstruction of mean annual air temperature (MAAT) from the Tibetan Plateau, the largest alpine permafrost region on the Earth, to constrain past and future changes in permafrost carbon storage. Clumped isotope-temperatures (Δ 47 -T) indicate warmer MAAT (~1.2 °C) prior to 2.7 Ma, and support a permafrost-free environment on the northern Tibetan Plateau in a warmer-than-present climate. Δ 47 -T indicate ~8.1 °C cooling from 2.7 Ma, coincident with Northern Hemisphere glacial intensification. Combined with climate models and global permafrost distribution, these results indicate, under conditions similar to mid-Pliocene Warm period (3.3-3.0 Ma), ~60% of alpine permafrost containing ~85 petagrams of carbon may be vulnerable to thawing compared to ~20% of circumarctic permafrost. This estimate highlights ~25% of permafrost carbon and the permafrost-climate feedback could originate in alpine areas., (© 2022. The Author(s).)

Published

2022