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2. The DeepMIP contribution to PMIP4: methodologies for selection, compilation and analysis of latest Paleocene and early Eocene climate proxy data, incorporating version 0.1 of the DeepMIP database

Author

Hollis, Christopher J, Jones, Tom Dunkley, Anagnostou, Eleni, Bijl, Peter K, Cramwinckel, Margot J, Cui, Ying, Dickens, Gerald R, Edgar, Kirsty M, Eley, Yvette, Evans, David, Foster, Gavin L, Frieling, Joost, Inglis, Gordon N, Kennedy, Elizabeth M, Kozdon, Reinhard, Lauretano, Vittoria, Lear, Caroline H, Littler, Kate, Lourens, Lucas, Meckler, A Nele, Naafs, B David A, Paelike, Heiko, Pancost, Richard D, Pearson, Paul N, Roehl, Ursula, Royer, Dana L, Salzmann, Ulrich, Schubert, Brian A, Seebeck, Hannu, Sluijs, Appy, Speijer, Robert P, Stassen, Peter, Tierney, Jessica, Tripati, Aradhna, Wade, Bridget, Westerhold, Thomas, Witkowski, Caitlyn, Zachos, James C, Zhang, Yi Ge, Huber, Matthew, and Lunt, Daniel J

Subjects
Earth Sciences
Abstract

Abstract. The early Eocene (56 to 48 million years ago) is inferred to havebeen the most recent time that Earth's atmospheric CO2 concentrationsexceeded 1000 ppm. Global mean temperatures were also substantially warmerthan those of the present day. As such, the study of early Eocene climate provides insightinto how a super-warm Earth system behaves and offers an opportunity toevaluate climate models under conditions of high greenhouse gas forcing. TheDeep Time Model Intercomparison Project (DeepMIP) is a systematicmodel–model and model–data intercomparison of three early Paleogene timeslices: latest Paleocene, Paleocene–Eocene thermal maximum (PETM) and earlyEocene climatic optimum (EECO). A previous article outlined the modelexperimental design for climate model simulations. In this article, weoutline the methodologies to be used for the compilation and analysis ofclimate proxy data, primarily proxies for temperature and CO2. Thispaper establishes the protocols for a concerted and coordinated effort tocompile the climate proxy records across a wide geographic range. Theresulting climate “atlas” will be used to constrain and evaluate climatemodels for the three selected time intervals and provide insights into themechanisms that control these warm climate states. We provide version 0.1 ofthis database, in anticipation that this will be expanded in subsequentpublications.

Published
2019

3. Constraining early to middle Eocene climate evolution of the southwest Pacific and Southern Ocean

Author

Dallanave, Edoardo, Bachtadse, Valerian, Crouch, Erica M, Tauxe, Lisa, Shepherd, Claire L, Morgans, Hugh EG, Hollis, Christopher J, Hines, Benjamin R, and Sugisaki, Saiko

Subjects
early-middle Eocene, Southwest Pacific Ocean, magnetostratigraphy, biochronology, climate evolution, early Eocene climatic optimum, Physical Sciences, Earth Sciences, Geochemistry & Geophysics
Abstract

Studies of early Paleogene climate suffer from the scarcity of well-dated sedimentary records from the southern Pacific Ocean, the largest ocean basin during this time. We present a new magnetostratigraphic record from marine sediments that outcrop along the mid-Waipara River, South Island, New Zealand. Fully oriented samples for paleomagnetic analyses were collected along 45 m of stratigraphic section, which encompasses magnetic polarity Chrons from C23n to C21n (~51.5-47 Ma). These results are integrated with foraminiferal, calcareous nannofossil, and dinoflagellate cyst (dinocyst) biostratigraphy from samples collected in three different expeditions along a total of ~80 m of section. Biostratigraphic data indicates relatively continuous sedimentation from the lower Waipawan to the upper Heretaungan New Zealand stages (i.e., lower Ypresian to lower Lutetian, 55.5 to 46 Ma). We provide the first magnetostratigraphically-calibrated age of 48.88 Ma for the base of the Heretaungan New Zealand stage (latest early Eocene). To improve the correlation of the climate record in this section with other Southern Ocean records, we reviewed the magnetostratigraphy of Ocean Drilling Program (ODP) Site 1172 (East Tasman Plateau) and Integrated Ocean Drilling Program (IODP) Site U1356 (Wilkes Land Margin, Antarctica). A paleomagnetic study of discrete samples could not confirm any reliable magnetic polarity reversals in the early Eocene at Site 1172. We use the robust magneto-biochronology of a succession of dinocyst bioevents that are common to mid-Waipara, Site 1172, and Site U1356 to assist correlation between the three records. A new integrated chronology offers new insights into the nature and completeness of the southern high-latitude climate histories derived from these sites.

Published
2016

4. The Chicxulub Impact Produced a Powerful Global Tsunami

Author

Range, Molly M., primary, Arbic, Brian K., additional, Johnson, Brandon C., additional, Moore, Theodore C., additional, Titov, Vasily, additional, Adcroft, Alistair J., additional, Ansong, Joseph K., additional, Hollis, Christopher J., additional, Ritsema, Jeroen, additional, Scotese, Christopher R., additional, and Wang, He, additional

Published
2022
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9. Late Paleocene CO2 drawdown, climatic cooling, and terrestrial denudation in the southwest Pacific

Author

Hollis, Christopher J., Naeher, Sebastian, Clowes, Christopher D., Naafs, B. David A., Pancost, Richard D., Taylor, Kyle W. R., Dahl, Jenny, Li, Xun, Ventura, G. Todd, and Sykes, Richard

Abstract

​​​​​​​Late Paleocene deposition of an organic-rich sedimentary facies on the continental shelf and slope of New Zealand and eastern Australia has been linked to short-lived climatic cooling and terrestrial denudation following sea level fall. Recent studies confirm that the organic matter in this facies, termed “Waipawa organofacies”, is primarily of terrestrial origin, with a minor marine component. It is also unusually enriched in 13C. In this study we address the cause of this enrichment. For Waipawa organofacies and its bounding facies in the Taylor White section, Hawke's Bay, paired palynofacies and carbon isotope analysis of heavy liquid-separated density fractions indicate that the heaviest δ13C values are associated with degraded phytoclasts (woody plant matter) and that the 13C enrichment may be partly due to lignin degradation. Compound-specific stable carbon isotope analyses of samples from the Taylor White and mid-Waipara (Canterbury) sections display similar trends and further reveal a residual 13C enrichment of ∼ 2.5 ‰ in higher plant biomarkers (long chain n-alkanes and fatty acids) and a ∼ 2 ‰–5 ‰ change in subordinate marine biomarkers. Using the relationship between atmospheric CO2 and C3 plant tissue δ13C values, we determine that the 3 ‰ increase in terrestrial δ13C may represent a ∼ 35 % decrease in atmospheric CO2.Refined age control for Waipawa organofacies indicates that deposition occurred between 59.2 and 58.5 Ma, which coincides with an interval of carbonate dissolution in the deep sea that is associated with a Paleocene oxygen isotope maximum (POIM, 59.7–58.1 Ma) and the onset of the Paleocene carbon isotope maximum (PCIM, 59.3–57.4 Ma). This association suggests that Waipawa deposition occurred during a time of cool climatic conditions and increased carbon burial. This relationship is further supported by published TEX86-based sea surface temperatures that indicate a pronounced regional cooling during deposition. We suggest that reduced greenhouse gas emissions from volcanism and accelerated carbon burial, due to tectonic factors, resulted in short-lived global cooling, growth of ephemeral ice sheets and a global fall in sea level. Accompanying erosion and carbonate dissolution in deep-sea sediment archives may have hidden the evidence of this “hypothermal” event until now.

Published
2021
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11. DeepMIP: Model intercomparison of early Eocene climatic optimum (EECO) large-scale climate features and comparison with proxy data

Author

Lunt, Daniel J, Bragg, Fran, Chan, Wing-Le, Hutchinson, David K, Ladant, Jean-Baptiste, Morozova, Polina, Niezgodzki, Igor, Steinig, Sebastian, Zhang, Zhongshi, Zhu, Jiang, Abe-Ouchi, Ayako, Anagnostou, Eleni, de Boer, Agatha M., Coxall, Helen K., Donnadieu, Yannick, Foster, Gavin, Inglis, Gordon N., Knorr, Gregor, Langebroek, Petra M., Lear, Caroline H., Lohmann, Gerrit, Poulsen, Christopher J., Sepulchre, Pierre, Tierney, Jessica E., Valdes, Paul J., Volodin, Evgeny M., Jones, Tom Dunkley, Hollis, Christopher J., Huber, Matthew, Otto-Bliesner, Bette L., Lunt, Daniel J, Bragg, Fran, Chan, Wing-Le, Hutchinson, David K, Ladant, Jean-Baptiste, Morozova, Polina, Niezgodzki, Igor, Steinig, Sebastian, Zhang, Zhongshi, Zhu, Jiang, Abe-Ouchi, Ayako, Anagnostou, Eleni, de Boer, Agatha M., Coxall, Helen K., Donnadieu, Yannick, Foster, Gavin, Inglis, Gordon N., Knorr, Gregor, Langebroek, Petra M., Lear, Caroline H., Lohmann, Gerrit, Poulsen, Christopher J., Sepulchre, Pierre, Tierney, Jessica E., Valdes, Paul J., Volodin, Evgeny M., Jones, Tom Dunkley, Hollis, Christopher J., Huber, Matthew, and Otto-Bliesner, Bette L.

Published
2021

12. DeepMIP : model intercomparison of early Eocene climatic optimum (EECO) large-scale climate features and comparison with proxy data

Author

Lunt, Daniel J., Bragg, Fran, Chan, Wing-Le, Hutchinson, David K., Ladant, Jean-Baptiste, Morozova, Polina, Niezgodzki, Igor, Steinig, Sebastian, Zhang, Zhongshi, Zhu, Jiang, Abe-Ouchi, Ayako, Anagnostou, Eleni, de Boer, Agatha M., Coxall, Helen K., Donnadieu, Yannick, Foster, Gavin, Inglis, Gordon N., Knorr, Gregor, Langebroek, Petra M., Lear, Caroline H., Lohmann, Gerrit, Poulsen, Christopher J., Sepulchre, Pierre, Tierney, Jessica E., Valdes, Paul J., Volodin, Evgeny M., Dunkley Jones, Tom, Hollis, Christopher J., Huber, Matthew, Otto-Bliesner, Bette L., Lunt, Daniel J., Bragg, Fran, Chan, Wing-Le, Hutchinson, David K., Ladant, Jean-Baptiste, Morozova, Polina, Niezgodzki, Igor, Steinig, Sebastian, Zhang, Zhongshi, Zhu, Jiang, Abe-Ouchi, Ayako, Anagnostou, Eleni, de Boer, Agatha M., Coxall, Helen K., Donnadieu, Yannick, Foster, Gavin, Inglis, Gordon N., Knorr, Gregor, Langebroek, Petra M., Lear, Caroline H., Lohmann, Gerrit, Poulsen, Christopher J., Sepulchre, Pierre, Tierney, Jessica E., Valdes, Paul J., Volodin, Evgeny M., Dunkley Jones, Tom, Hollis, Christopher J., Huber, Matthew, and Otto-Bliesner, Bette L.

Abstract

We present results from an ensemble of eight climate models, each of which has carried out simulations of the early Eocene climate optimum (EECO, similar to 50 million years ago). These simulations have been carried out in the framework of the Deep-Time Model Intercomparison Project (DeepMIP; http://www.deepmip.org , last access: 10 January 2021); thus, all models have been configured with the same paleogeographic and vegetation boundary conditions. The results indicate that these non-CO2 boundary conditions contribute between 3 and 5 degrees C to Eocene warmth. Compared with results from previous studies, the DeepMIP simulations generally show a reduced spread of the global mean surface temperature response across the ensemble for a given atmospheric CO2 concentration as well as an increased climate sensitivity on average. An energy balance analysis of the model ensemble indicates that global mean warming in the Eocene compared with the preindustrial period mostly arises from decreases in emissivity due to the elevated CO2 concentration (and associated water vapour and long-wave cloud feedbacks), whereas the reduction in the Eocene in terms of the meridional temperature gradient is primarily due to emissivity and albedo changes owing to the non-CO2 boundary conditions (i.e. the removal of the Antarctic ice sheet and changes in vegetation). Three of the models (the Community Earth System Model, CESM; the Geophysical Fluid Dynamics Laboratory, GFDL, model; and the Norwegian Earth System Model, NorESM) show results that are consistent with the proxies in terms of the global mean temperature, meridional SST gradient, and CO2, without prescribing changes to model parameters. In addition, many of the models agree well with the first-order spatial patterns in the SST proxies. However, at a more regional scale, the models lack skill. In particular, the modelled anomalies are substantially lower than those indicated by the proxies in the southwest Pacific; here, modelled co

Published
2021
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13. Tropical sea temperatures in the high-latitude South Pacific during the Eocene

Author

Hollis, Christopher J., Handley, Luke, Crouch, Erica M., Morgans, Hugh E.G., Baker, Joel A., Creech, John, Collins, Katie S., Gibbs, Samantha J., Huber, Matthew, Schouten, Stefan, Zachos, James C., and Pancost, Richard D.

Subjects
Tropics -- Natural history, South Pacific Ocean -- Natural history, Ocean temperature -- Measurement, Geological research, Earth sciences
Abstract

Sea-surface temperature (SST) estimates of ~30[degrees]C from planktic foraminifera and archaeal membrane lipids in bathyal sediments in the Canterbury Basin, New Zealand, support paleontological evidence for a warm subtropical to tropical climate in the early Eocene high-latitude (55[degrees]S) southwest Pacific. Such warm SSTs call into question previous estimates based on oxygen isotopes and present a major challenge to climate modelers. Even under hypergreenhouse conditions (2240 ppm C[O.sub.2]), modeled summer SSTs for the New Zealand region do not exceed 20[degrees]C.

Published
2009

15. Multiple early Eocene hyperthermals: their sedimentary expression on the New Zealand continental margin and in the deep sea

Author

Nicolo, Micah J., Dickens, Gerald R., Hollis, Christopher J., and Zachos, James C.

Subjects
New Zealand -- Natural history, Climatic changes -- Observations, Carbon -- Isotopes, Carbon -- Chemical properties, Geological research, Earth sciences
Abstract

The Paleocene-Eocene thermal maximum (PETM) ca. 55.5 Ma was a geologically brief interval characterized by massive influx of isotopically light carbon, extreme changes in global climate, and profound variations in Earth system processes. An outstanding issue is whether it was an isolated event, or the most prominent example of a recurring phenomenon. Recent studies of condensed deep-sea sections support the latter, but this finding remains uncertain. Here we present and discuss lithologic and carbon isotope records across two lower Eocene outcrops on South Island, New Zealand. The PETM manifests as a marl-rich horizon with a significant negative carbon isotope excursion (CIE). Above, in sediment deposited between 54 and 53 Ma, are four horizons with similar though less pronounced expressions. Marl beds of all five horizons represent increased terrigenous sedimentation, presumably linked to an accelerated hydrological cycle. Five corresponding clay-rich horizons and CIEs are found in deep-sea records, although the lithologic variations represent carbonate dissolution rather than siliciclastic dilution. The presence of five intervals with similar systemic responses in different environments suggests a mechanism that repeatedly injected large masses of [sup.13]C-depleted carbon during the early Eocene. Keywords: Paleocene-Eocene thermal maximum, PETM, carbon isotope excursion, CIE.

Published
2007

16. Global mean surface temperature and climate sensitivity of the early Eocene Climatic Optimum (EECO), Paleocene-Eocene Thermal Maximum (PETM), and latest Paleocene

Author

Inglis, Gordon N., Bragg, Fran, Burls, Natalie J., Cramwinckel, Margot J., Evans, David, Foster, Gavin L., Huber, Matthew, Lunt, Daniel J., Siler, Nicholas, Steinig, Sebastian, Tierney, Jessica E., Wilkinson, Richard, Anagnostou, Eleni, M. De Boer, Agatha, Dunkley Jones, Tom, Edgar, Kirsty M., Hollis, Christopher J., Hutchinson, David K., Pancost, Richard D., Inglis, Gordon N., Bragg, Fran, Burls, Natalie J., Cramwinckel, Margot J., Evans, David, Foster, Gavin L., Huber, Matthew, Lunt, Daniel J., Siler, Nicholas, Steinig, Sebastian, Tierney, Jessica E., Wilkinson, Richard, Anagnostou, Eleni, M. De Boer, Agatha, Dunkley Jones, Tom, Edgar, Kirsty M., Hollis, Christopher J., Hutchinson, David K., and Pancost, Richard D.

Abstract

Accurate estimates of past global mean surface temperature (GMST) help to contextualise future climate change and are required to estimate the sensitivity of the climate system to CO2 forcing through Earth s history. Previous GMST estimates for the latest Paleocene and early Eocene (57 to 48 million years ago) span a wide range (9 to 23 C higher than pre-industrial) and prevent an accurate assessment of climate sensitivity during this extreme greenhouse climate interval. Using the most recent data compilations, we employ a multi-method experimental framework to calculate GMST during the three DeepMIP target intervals: (1) the latest Paleocene (57 Ma), (2) the Paleocene Eocene Thermal Maximum (PETM; 56 Ma), and (3) the early Eocene Climatic Optimum (EECO; 53.3 to 49.1 Ma). Using six different methodologies, we find that the average GMST estimate (66% confidence) during the latest Paleocene, PETM, and EECO was 26.3 C (22.3 to 28.3 C), 31.6 C (27.2 to 34.5 C), and 27.0 C (23.2 to 29.7 C), respectively. GMST estimates from the EECO are 10 to 16 C warmer than pre-industrial, higher than the estimate given by the Intergovernmental Panel on Climate Change (IPCC) 5th Assessment Report (9 to 14 C higher than pre-industrial). Leveraging the large "signal" associated with these extreme warm climates, we combine estimates of GMST and CO2 from the latest Paleocene, PETM, and EECO to calculate gross estimates of the average climate sensitivity between the early Paleogene and today. We demonstrate that "bulk" equilibrium climate sensitivity (ECS; 66% confidence) during the latest Paleocene, PETM, and EECO is 4.5 C (2.4 to 6.8 C), 3.6 C (2.3 to 4.7 C), and 3.1 C (1.8 to 4.4 C) per doubling of CO2. These values are generally similar to those assessed by the IPCC (1.5 to 4.5 C per doubling CO2) but appear incompatible with low ECS values (1:5 per doubling CO2).

Published
2020

18. DeepMIP: model intercomparison of early Eocene climatic optimum (EECO) large-scale climate features and comparison with proxy data

Author

Lunt, Daniel J., primary, Bragg, Fran, additional, Chan, Wing-Le, additional, Hutchinson, David K., additional, Ladant, Jean-Baptiste, additional, Morozova, Polina, additional, Niezgodzki, Igor, additional, Steinig, Sebastian, additional, Zhang, Zhongshi, additional, Zhu, Jiang, additional, Abe-Ouchi, Ayako, additional, Anagnostou, Eleni, additional, de Boer, Agatha M., additional, Coxall, Helen K., additional, Donnadieu, Yannick, additional, Foster, Gavin, additional, Inglis, Gordon N., additional, Knorr, Gregor, additional, Langebroek, Petra M., additional, Lear, Caroline H., additional, Lohmann, Gerrit, additional, Poulsen, Christopher J., additional, Sepulchre, Pierre, additional, Tierney, Jessica E., additional, Valdes, Paul J., additional, Volodin, Evgeny M., additional, Dunkley Jones, Tom, additional, Hollis, Christopher J., additional, Huber, Matthew, additional, and Otto-Bliesner, Bette L., additional

Published
2021
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19. Global mean surface temperature and climate sensitivity of the early Eocene Climatic Optimum (EECO), Paleocene–Eocene Thermal Maximum (PETM), and latest Paleocene

Author

Inglis, Gordon N., primary, Bragg, Fran, additional, Burls, Natalie J., additional, Cramwinckel, Margot J., additional, Evans, David, additional, Foster, Gavin L., additional, Huber, Matthew, additional, Lunt, Daniel J., additional, Siler, Nicholas, additional, Steinig, Sebastian, additional, Tierney, Jessica E., additional, Wilkinson, Richard, additional, Anagnostou, Eleni, additional, de Boer, Agatha M., additional, Dunkley Jones, Tom, additional, Edgar, Kirsty M., additional, Hollis, Christopher J., additional, Hutchinson, David K., additional, and Pancost, Richard D., additional

Published
2020
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20. Temperature-dependent frictional properties of heterogeneous Hikurangi Subduction Zone input sediments, ODP Site 1124

Author

Boulton, Carolyn, Niemeijer, André R., Hollis, Christopher J., Townend, John, Raven, Mark D., Kulhanek, Denise K., Shepherd, Claire L., Experimental rock deformation, and Experimental rock deformation

Subjects
Décollement, 010504 meteorology & atmospheric sciences, Subduction, Friction, Pacific Plate, Seismicity, Geology, FOS: Earth and related environmental sciences, Induced seismicity, Creep, 010502 geochemistry & geophysics, Mineralogy, 01 natural sciences, Subduction zone, Geochemistry, Geophysics, 14. Life underwater, Petrology, Stability, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

The Hikurangi Subduction Zone (HSZ), New Zealand, accommodates westward subduction of the Pacific Plate. Where imaged seismically, the shallow HSZ d��collement (

Published
2019

21. The DeepMIP contribution to PMIP4: Methodologies for selection, compilation and analysis of latest Paleocene and early Eocene climate proxy data, incorporating version 0.1 of the DeepMIP database

Author

Hollis, Christopher J., Dunkley Jones, Tom, Anagnostou, Eleni, Bijl, Peter K., Cramwinckel, Margot J., Cui, Ying, Dickens, Gerald R., Edgar, Kirsty M., Eley, Yvette, Evans, David, Foster, Gavin L., Frieling, Joost, Inglis, Gordon N., Kennedy, Elizabeth M., Kozdon, Reinhard, Lauretano, Vittoria, Lear, Caroline H., Littler, Kate, Lourens, Lucas, Nele Meckler, A., Naafs, B. David A., Pälike, Heiko, Pancost, Richard D., Pearson, Paul N., Röhl, Ursula, Royer, Dana L., Salzmann, Ulrich, Schubert, Brian A., Seebeck, Hannu, Sluijs, Appy, Speijer, Robert P., Stassen, Peter, Tierney, Jessica, Tripati, Aradhna, Wade, Bridget, Westerhold, Thomas, Witkowski, Caitlyn, Zachos, James C., Ge Zhang, Yi, Huber, Matthew, Lunt, Daniel J., Hollis, Christopher J., Dunkley Jones, Tom, Anagnostou, Eleni, Bijl, Peter K., Cramwinckel, Margot J., Cui, Ying, Dickens, Gerald R., Edgar, Kirsty M., Eley, Yvette, Evans, David, Foster, Gavin L., Frieling, Joost, Inglis, Gordon N., Kennedy, Elizabeth M., Kozdon, Reinhard, Lauretano, Vittoria, Lear, Caroline H., Littler, Kate, Lourens, Lucas, Nele Meckler, A., Naafs, B. David A., Pälike, Heiko, Pancost, Richard D., Pearson, Paul N., Röhl, Ursula, Royer, Dana L., Salzmann, Ulrich, Schubert, Brian A., Seebeck, Hannu, Sluijs, Appy, Speijer, Robert P., Stassen, Peter, Tierney, Jessica, Tripati, Aradhna, Wade, Bridget, Westerhold, Thomas, Witkowski, Caitlyn, Zachos, James C., Ge Zhang, Yi, Huber, Matthew, and Lunt, Daniel J.

Abstract

The early Eocene (56 to 48 million years ago) is inferred to have been the most recent time that Earth's atmospheric CO2 concentrations exceeded 1000 ppm. Global mean temperatures were also substantially warmer than those of the present day. As such, the study of early Eocene climate provides insight into how a super-warm Earth system behaves and offers an opportunity to evaluate climate models under conditions of high greenhouse gas forcing. The Deep Time Model Intercomparison Project (DeepMIP) is a systematic model-model and model-data intercomparison of three early Paleogene time slices: latest Paleocene, Paleocene-Eocene thermal maximum (PETM) and early Eocene climatic optimum (EECO). A previous article outlined the model experimental design for climate model simulations. In this article, we outline the methodologies to be used for the compilation and analysis of climate proxy data, primarily proxies for temperature and CO2. This paper establishes the protocols for a concerted and coordinated effort to compile the climate proxy records across a wide geographic range. The resulting climate "atlas" will be used to constrain and evaluate climate models for the three selected time intervals and provide insights into the mechanisms that control these warm climate states. We provide version 0.1 of this database, in anticipation that this will be expanded in subsequent publications.

Published
2019

22. The DeepMIP contribution to PMIP4: Methodologies for selection, compilation and analysis of latest Paleocene and early Eocene climate proxy data, incorporating version 0.1 of the DeepMIP database

Author

Marine Palynology, Stratigraphy & paleontology, Marine palynology and palaeoceanography, Stratigraphy and paleontology, Hollis, Christopher J., Dunkley Jones, Tom, Anagnostou, Eleni, Bijl, Peter K., Cramwinckel, Margot J., Cui, Ying, Dickens, Gerald R., Edgar, Kirsty M., Eley, Yvette, Evans, David, Foster, Gavin L., Frieling, Joost, Inglis, Gordon N., Kennedy, Elizabeth M., Kozdon, Reinhard, Lauretano, Vittoria, Lear, Caroline H., Littler, Kate, Lourens, Lucas, Nele Meckler, A., Naafs, B. David A., Pälike, Heiko, Pancost, Richard D., Pearson, Paul N., Röhl, Ursula, Royer, Dana L., Salzmann, Ulrich, Schubert, Brian A., Seebeck, Hannu, Sluijs, Appy, Speijer, Robert P., Stassen, Peter, Tierney, Jessica, Tripati, Aradhna, Wade, Bridget, Westerhold, Thomas, Witkowski, Caitlyn, Zachos, James C., Ge Zhang, Yi, Huber, Matthew, Lunt, Daniel J., Marine Palynology, Stratigraphy & paleontology, Marine palynology and palaeoceanography, Stratigraphy and paleontology, Hollis, Christopher J., Dunkley Jones, Tom, Anagnostou, Eleni, Bijl, Peter K., Cramwinckel, Margot J., Cui, Ying, Dickens, Gerald R., Edgar, Kirsty M., Eley, Yvette, Evans, David, Foster, Gavin L., Frieling, Joost, Inglis, Gordon N., Kennedy, Elizabeth M., Kozdon, Reinhard, Lauretano, Vittoria, Lear, Caroline H., Littler, Kate, Lourens, Lucas, Nele Meckler, A., Naafs, B. David A., Pälike, Heiko, Pancost, Richard D., Pearson, Paul N., Röhl, Ursula, Royer, Dana L., Salzmann, Ulrich, Schubert, Brian A., Seebeck, Hannu, Sluijs, Appy, Speijer, Robert P., Stassen, Peter, Tierney, Jessica, Tripati, Aradhna, Wade, Bridget, Westerhold, Thomas, Witkowski, Caitlyn, Zachos, James C., Ge Zhang, Yi, Huber, Matthew, and Lunt, Daniel J.

Published
2019

24. Late Paleocene CO2 drawdown, climatic cooling, and terrestrial denudation in the southwest Pacific.

Author

Hollis, Christopher J., Naeher, Sebastian, Clowes, Christopher D., Dahl, Jenny, Li, Xun, Naafs, B. David A., Pancost, Richard D., Taylor, Kyle W. R., Ventura, G. Todd, and Sykes, Richard

Abstract

Late Paleocene deposition of an organic-rich sedimentary facies on the continental shelf and slope of New Zealand and eastern Australia has been linked to short-lived climatic cooling and terrestrial denudation following sea-level fall. Recent studies have confirmed that the organic matter in this facies, termed Waipawa organofacies, is primarily of terrestrial origin, with a minor marine component. It is also unusually enriched in δ13C. In this study we aim to determine the cause or causes of this enrichment. For Waipawa organofacies and its bounding facies in the Taylor White section, Hawkes Bay, paired palynofacies and δ13C analysis of density fractions indicate that the heaviest δ13C values are associated with degraded phytoclasts (woody plant matter) and that the 13C enrichment is partly due to lignin degradation. Compound specific δ13C analyses of samples from the Taylor White and mid-Waipara (Canterbury) sections confirms this relationship but also reveal a residual 13C enrichment of ~ 2.5 ‰ in higher plant biomarkers (n-alkanes and n-alkanoic acids) and 3-4 ‰ in the subordinate marine component, which we interpret as indicating a significant drawdown of atmospheric CO2. Refined age control for Waipawa organofacies indicates that deposition occurred between 59.2 and 58.4 Ma, which coincides with a Paleocene oxygen isotope maximum (POIM) and the onset of the Paleocene carbon isotope maximum (PCIM). This timing suggests that this depositional event was related to global cooling and carbon burial. This relationship is further supported by published TEX86-based sea surface temperatures that indicate a pronounced regional cooling during deposition. We suggest that reduced greenhouse gas emissions from volcanism and accelerated carbon burial related to several tectonic factors and positive feedbacks resulted in short-lived global cooling, growth of ephemeral ice sheets, and a global fall in sea level. Accompanying erosion and carbonate dissolution in deep sea sediment archives may have hidden the evidence of this "hypothermal" event until now. [ABSTRACT FROM AUTHOR]

Published
2021
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26. The DeepMIP contribution to PMIP4:experimental design for model simulations of the EECO, PETM, and pre-PETM

Author

Lunt, Dan, Huber, Matthew, Anagnostou, Eleni, Baatsen, Michiel, Caballero, Rodrigo, DeConto, Rob, Dijkstra, Henk, Donnadieu, Yannick, Evans, David, Feng, Ran, Foster, Gavin, Gasson, Ed, von der Heydt, Anna, Hollis, Christopher J., Inglis, Gordon, Jones, Stephen, Kiehl, Jeff, Kirtland Turner, Sandy, Korty, Robert, Kozdon, Reinhardt, Krishnan, Srinath, Ladant, Jean-Baptiste, Langebroek, Petra, Lear, Caroline, LeGrande, Allegra, Littler, Kate, Markwick, Paul, Otto-Bliesner, Bette, Pearson, Paul, Poulsen, Christopher, Salzmann, Ulrich, Shields, Christine, Snell, Kathryn, Starz, Michael, Super, James, Tabor, Clay, Tierney, Jess, Tourte, Gregory J. L., Tripati, Aradhna, Upchurch, Gary, Wade, Bridget, Wing, Scott, Winguth, Arne, Wright, Nicky, Zachos, James, and Zeebe, Richard

Abstract

Past warm periods provide an opportunity to evaluate climate models under extreme forcing scenarios, in particular high (>800 ppmv) atmospheric CO2 concentrations. Although a post-hoc intercomparison of Eocene (∼50 million years ago, Ma) climate model simulations and geological data has been carried out previously, models of past high-CO2 periods have never been evaluated in a consistent framework. Here, we present an experimental design for climate model simulations of three warm periods within the early Eocene and the latest Paleocene (the EECO, PETM, and pre-PETM). Together with the CMIP6 preindustrial control and abrupt 4CO2 simulations, and additional sensitivity studies, these form the first phase of DeepMIP – the Deep-time Model Intercomparison Project, itself a group within the wider Paleoclimate Modelling Intercomparison Project (PMIP). The experimental design specifies and provides guidance on boundary conditions associated with palaeogeography, greenhouse gases, astronomical configuration, solar constant, land surface processes, and aerosols. Initial conditions, simulation length, and output variables are also specified. Finally, we explain how the geological datasets, which will be used to evaluate the simulations, will be developed.

Published
2017
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27. Global mean surface temperature and climate sensitivity of the EECO, PETM and latest Paleocene.

Author

Inglis, Gordon N., Bragg, Fran, Burls, Natalie, Evans, David, Foster, Gavin L., Huber, Matthew, Lunt, Daniel J., Siler, Nicholas, Steinig, Sebastian, Wilkinson, Richard, Anagnostou, Eleni, Cramwinckel, Margot, Hollis, Christopher J., Pancost, Richard D., and Tierney, Jessica E.

Abstract

Accurate estimates of past global mean surface temperature (GMST) help to contextualise future climate change and are required to estimate the sensitivity of the climate system to CO2 forcing during the geological record. GMST estimates from the latest Paleocene and early Eocene (~ 57 to 48 million years ago) span a wide range (~ 9 to 23 °C higher than pre-industrial) and prevent an accurate assessment of climate sensitivity during this extreme greenhouse climate interval. Here, we develop a multi-method experimental framework to calculate GMST during three target intervals: 1) the latest Paleocene (~ 57 Ma), 2) the Paleocene-Eocene Thermal Maximum (56 Ma) and 3) the early Eocene Climatic Optimum (EECO; 49.4 to 53.3 Ma). Using six independent methodologies, we find that average GMST estimates during the latest Paleocene and PETM are 11.7 °C (±0.6 °C) and 18.7 °C (±0.8 °C) higher than pre-industrial, respectively. GMST estimates from the EECO are 13.3 °C (±0.5 °C) warmer than pre-industrial and comparable to previous IPCC AR5 estimates (12.7 °C higher than pre-industrial). Leveraging the extremely large "signal" associated with these extreme warm climates, we combine estimates of GMST and CO2 from the latest Paleocene, PETM and EECO to calculate a gross estimate of the average climate sensitivity between the early Paleogene and today. This yields gross climate sensitivity estimates for the latest Paleocene, PETM and EECO which range between 2.8 to 4.8 °C (66 % confidence). These largely fall within the range predicted by the IPCC (1.5 to 4.5 °C per doubling CO2), but appear incompatible with low values (between 1.5 and 2.8 °C per doubling CO2). [ABSTRACT FROM AUTHOR]

Published
2020
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28. The age of the Takatika Grit, Chatham Islands, New Zealand

Author

Hollis, Christopher J., Stickley, Catherine E., Bijl, Peter K., Schiøler, Poul, Clowes, Christopher D., Li, Xun, Campbell, Hamish, Hollis, Christopher J., Stickley, Catherine E., Bijl, Peter K., Schiøler, Poul, Clowes, Christopher D., Li, Xun, and Campbell, Hamish

Abstract

The oldest Paleogene strata on Chatham Islands, east of New Zealand, are the phosphatized conglomerates and sandstones of the Takatika Grit that crops out on the northeastern coast at Tioriori and unconformably overlies the Chatham Schist. An intact Cretaceous–Paleogene boundary transition is not preserved at this locality. New biostratigraphic analysis of dinoflagellate, diatom and radiolarian microfossil assemblages confirms that the Takatika Grit is of late early–middle Paleocene (New Zealand Teurian stage) age but contains reworked microfossils of early Campanian (Early Haumurian) age. Vertebrate fossils found in this unit are inferred to be a mixture of reworked Cretaceous and in situ Paleocene bones and teeth. The overlying Tutuiri Greensand is of middle–late Paleocene age in its lower part and also contains reworked Cretaceous microfossils.

Published
2017

29. The age of the Takatika Grit, Chatham Islands, New Zealand

Author

Marine palynology and palaeoceanography, Marine Palynology, Hollis, Christopher J., Stickley, Catherine E., Bijl, Peter K., Schiøler, Poul, Clowes, Christopher D., Li, Xun, Campbell, Hamish, Marine palynology and palaeoceanography, Marine Palynology, Hollis, Christopher J., Stickley, Catherine E., Bijl, Peter K., Schiøler, Poul, Clowes, Christopher D., Li, Xun, and Campbell, Hamish

Published
2017

30. The age of the Takatika Grit, Chatham Islands, New Zealand

Author

Marine Palynology, Marine palynology and palaeoceanography, Hollis, Christopher J., Stickley, Catherine E., Bijl, Peter K., Schiøler, Poul, Clowes, Christopher D., Li, Xun, Campbell, Hamish, Marine Palynology, Marine palynology and palaeoceanography, Hollis, Christopher J., Stickley, Catherine E., Bijl, Peter K., Schiøler, Poul, Clowes, Christopher D., Li, Xun, and Campbell, Hamish

Published
2017

31. Descent towards the Icehouse:Eocene sea surface cooling inferred from GDGT distributions

Author

Inglis, Gordon, Farnsworth, Alexander, Lunt, Dan, Foster, Gavin, Hollis, Christopher J., Pagani, Mark, Jardine, Phillip E., Pearson, Paul, Markwick, Paul, Galsworthy, Amanda, Raynham, Lauren, Taylor, Kyle, and Pancost, Rich

Abstract

The TEX86 proxy, based on the distribution of marine isoprenoidal glycerol dialkyl glycerol tetraether lipids (GDGTs), is increasingly used to reconstruct sea surface temperature (SST) during the Eocene epoch (56.0-33.9 Ma). Here we compile published TEX86 records, critically re-evaluate them in light of new understandings in TEX86 palaeothermometry and supplement them with new data in order to evaluate long term temperature trends in the Eocene. We investigate the effect of archaea other than marine Thaumarchaeota upon TEX86 values using the branched-to-isoprenoid tetraether index (BIT), the abundance of GDGT-0 relative to crenarchaeol (%GDGT-0) and the Methane Index (MI). We also introduce a new ratio, %GDGTRS, which may help identify Red Sea-type GDGT distributions in the geological record. Using the offset between TEX86H and TEX86L (ΔH-L) and the ratio between GDGT-2 and GDGT-3 ([2]/[3]), we evaluate different TEX86 calibrations and present the first integrated SST compilation for the Eocene (55 to 34 Ma). Although the available data are still sparse some geographic trends can now be resolved. In the high-latitudes (>55 °), there was substantial cooling during the Eocene (~6 °C). Our compiled record also indicates tropical cooling of ~2.5°C during the same interval. Using an ensemble of climate model simulations that span the Eocene, our results indicate that only a small percentage (~10%) of the reconstructed temperature change can be ascribed to ocean gateway reorganisation or paleogeographic change. Collectively, this indicates that atmospheric carbon dioxide (pCO2) was the likely driver of surface water cooling during the descent towards the icehouse.

Published
2015
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32. Descent toward the Icehouse: Eocene sea surface cooling inferred from GDGT distributions

Author

Inglis, Gordon N., Farnsworth, Alexander, Lunt, Daniel, Foster, Gavin L., Hollis, Christopher J., Pagani, Mark, Jardine, Phillip E., Pearson, Paul N., Markwick, Paul, Galsworthy, Amanda M. J., Raynham, Lauren, Taylor, Kyle W. R., and Pancost, Richard D.

Subjects
QE
Abstract

The TEX86 proxy, based on the distribution of marine isoprenoidal glycerol dialkyl glycerol tetraether lipids (GDGTs), is increasingly used to reconstruct sea surface temperature (SST) during the Eocene epoch (56.0–33.9 Ma). Here we compile published TEX86 records, critically reevaluate them in light of new understandings in TEX86 palaeothermometry, and supplement them with new data in order to evaluate long-term temperature trends in the Eocene. We investigate the effect of archaea other than marine Thaumarchaeota upon TEX86 values using the branched-to-isoprenoid tetraether index (BIT), the abundance of GDGT-0 relative to crenarchaeol (%GDGT-0), and the Methane Index (MI). We also introduce a new ratio, % GDGTRS, which may help identify Red Sea-type GDGT distributions in the geological record. Using the offset between TEX86H and TEX86L(ΔH-L) and the ratio between GDGT-2 and GDGT-3 ([2]/[3]), we evaluate different TEX86 calibrations and present the first integrated SST compilation for the Eocene (55 to 34 Ma). Although the available data are still sparse some geographic trends can now be resolved. In the high latitudes (>55°), there was substantial cooling during the Eocene (~6°C). Our compiled record also indicates tropical cooling of ~2.5°C during the same interval. Using an ensemble of climate model simulations that span the Eocene, our results indicate that only a small percentage (~10%) of the reconstructed temperature change can be ascribed to ocean gateway reorganization or paleogeographic change. Collectively, this indicates that atmospheric carbon dioxide (pCO2) was the likely driver of surface water cooling during the descent toward the icehouse.

Published
2015

34. Descent toward the icehouse: Eocene sea surface cooling inferred from GDGT distributions

Author

Inglis, Gordon N., Farnsworth, Alexander, Lunt, Daniel, Foster, Gavin L., Hollis, Christopher J., Pagani, Mark, Jardine, Phillip E., Pearson, Paul N., Markwick, Paul, Galsworthy, Amanda M.J., Raynham, Lauren, Taylor, Kyle W.R., Pancost, Richard D., Inglis, Gordon N., Farnsworth, Alexander, Lunt, Daniel, Foster, Gavin L., Hollis, Christopher J., Pagani, Mark, Jardine, Phillip E., Pearson, Paul N., Markwick, Paul, Galsworthy, Amanda M.J., Raynham, Lauren, Taylor, Kyle W.R., and Pancost, Richard D.

Abstract

The TEX86 proxy, based on the distribution of marine isoprenoidal glycerol dialkyl glycerol tetraether lipids (GDGTs), is increasingly used to reconstruct sea surface temperature (SST) during the Eocene epoch (56.0–33.9 Ma). Here we compile published TEX86 records, critically reevaluate them in light of new understandings in TEX86 palaeothermometry, and supplement them with new data in order to evaluate long-term temperature trends in the Eocene. We investigate the effect of archaea other than marine Thaumarchaeota upon TEX86 values using the branched-to-isoprenoid tetraether index (BIT), the abundance of GDGT-0 relative to crenarchaeol (%GDGT-0), and the Methane Index (MI). We also introduce a new ratio, % GDGTRS, which may help identify Red Sea-type GDGT distributions in the geological record. Using the offset between TEX86H and TEX86L(ΔH-L) and the ratio between GDGT-2 and GDGT-3 ([2]/[3]), we evaluate different TEX86 calibrations and present the first integrated SST compilation for the Eocene (55 to 34 Ma). Although the available data are still sparse some geographic trends can now be resolved. In the high latitudes (>55°), there was substantial cooling during the Eocene (~6°C). Our compiled record also indicates tropical cooling of ~2.5°C during the same interval. Using an ensemble of climate model simulations that span the Eocene, our results indicate that only a small percentage (~10%) of the reconstructed temperature change can be ascribed to ocean gateway reorganization or paleogeographic change. Collectively, this indicates that atmospheric carbon dioxide (pCO2) was the likely driver of surface water cooling during the descent toward the icehouse.

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