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

Lunt, Daniel J.; Bragg, Fran; Chan, Wing‐Le; Hutchinson, David K.; Ladant, Jean‐Baptiste; Niezgodzki, Igor; Steinig, Sebastian; Zhang, Zhongshi; Zhu, Jiang; Abe‐Ouchi, Ayako; Boer, Agatha M. de; Coxall, Helen K.; Donnadieu, Yannick; Knorr, Gregor; Langebroek, Petra; Lohmann, Gerrit; Poulsen, Christopher J.; Sepulchre, Pierre; Tierney, Jessica E.; Valdes, Paul J.; Jones, Tom Dunkley; Hollis, Christopher J.; Huber, Matthew; Otto‐Bliesner, Bette L.

doi:10.5194/cp-2019-149

Cited by 14 publications

(28 citation statements)

References 45 publications

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“…The middle Eocene sporomorph assemblages from the Latrobe-1 borehole are generally similar to those identified in previous studies (Macphail et al, 1994;Greenwood et al, 2003;Hill, 2017), but also include a small proportion of mesothermal-megathermal ("paratropical") components. Although the small number of analyzed samples prohibits a description of pre-, syn-, and post-MECO vegetation, the assemblages from the Latrobe-1 core reveal that this middle Eocene vegetation of coastal southeast Australia consisted of a mosaic of mesothermal rainforest flora.…”

Section: Southeast Australian Vegetation During the Mecosupporting

confidence: 81%

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Surface-circulation change in the southwest Pacific Ocean across the Middle Eocene Climatic Optimum: inferences from dinoflagellate cysts and biomarker paleothermometry

et al. 2020

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Abstract. Global climate cooled from the early Eocene hothouse (∼52–50 Ma) to the latest Eocene (∼34 Ma). At the same time, the tectonic evolution of the Southern Ocean was characterized by the opening and deepening of circum-Antarctic gateways, which affected both surface- and deep-ocean circulation. The Tasmanian Gateway played a key role in regulating ocean throughflow between Australia and Antarctica. Southern Ocean surface currents through and around the Tasmanian Gateway have left recognizable tracers in the spatiotemporal distribution of plankton fossils, including organic-walled dinoflagellate cysts. This spatiotemporal distribution depends on both the physicochemical properties of the water masses and the path of surface-ocean currents. The extent to which climate and tectonics have influenced the distribution and composition of surface currents and thus fossil assemblages has, however, remained unclear. In particular, the contribution of climate change to oceanographic changes, superimposed on long-term and gradual changes induced by tectonics, is still poorly understood. To disentangle the effects of tectonism and climate in the southwest Pacific Ocean, we target a climatic deviation from the long-term Eocene cooling trend: the Middle Eocene Climatic Optimum (MECO; ∼40 Ma). This 500 kyr phase of global warming was unrelated to regional tectonism, and thus provides a test case to investigate the ocean's physicochemical response to climate change alone. We reconstruct changes in surface-water circulation and temperature in and around the Tasmanian Gateway during the MECO through new palynological and organic geochemical records from the central Tasmanian Gateway (Ocean Drilling Program Site 1170), the Otway Basin (southeastern Australia), and the Hampden Beach section (New Zealand). Our results confirm that dinocyst communities track specific surface-ocean currents, yet the variability within the communities can be driven by superimposed temperature change. Together with published results from the east of the Tasmanian Gateway, our new results suggest a shift in surface-ocean circulation during the peak of MECO warmth. Simultaneous with high sea-surface temperatures in the Tasmanian Gateway area, pollen assemblages indicate warm temperate rainforests with paratropical elements along the southeastern margin of Australia. Finally, based on new age constraints, we suggest that a regional southeast Australian transgression might have been coincident with the MECO.

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Section: Southeast Australian Vegetation During the Mecosupporting

confidence: 81%

“…For this group, we follow the suggestion made in Bijl et al (2016) to use the taxonomy of Fensome and Williams (2004) instead of Williams et al ( , 2017a. Sporomorph taxonomy follows Stover and Partridge (1973), Macphail et al (1994), and Raine et al (2011).…”

Section: Processing and Analysismentioning

confidence: 99%

Surface-circulation change in the southwest Pacific Ocean across the Middle Eocene Climatic Optimum: inferences from dinoflagellate cysts and biomarker paleothermometry

et al. 2020

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“…This bias is very classical in warm climate reconstructions with GCMs and could be responsible for a discrepancy between absolute SST from our experiments and proxies (see Huber & Caballero, 2011). Studies carried out with more recent versions of GCM, such as CESM and GFDL, show improvements in the representation of this gradient, in particular thanks to a better consideration of cloud physics and other greenhouse gases (Baatsen et al, 2020;Hutchinson et al, 2020;Lunt et al, 2020;Sagoo et al, 2013;Zhu et al, 2019). With close boundary conditions, they reconstruct flatter gradients thanks to~3°C lower SST in equatorial area and up to 2°C to 3°C higher SST at midlatitudes ( Figure S7; Baatsen et al, 2020;Hutchinson et al, 2018).…”

Section: Changes In Ocean Properties and Dynamics And N/s Thermal DImentioning

confidence: 86%

Quantifying the Effect of the Drake Passage Opening on the Eocene Ocean

Toumoulin

Donnadieu

Ladant

et al. 2020

Paleoceanog and Paleoclimatol

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The opening of the Drake Passage (DP) during the Cenozoic is a tectonic event of paramount importance for the development of modern ocean characteristics. Notably, it has been suggested that it exerts a primary role in the onset of the Antarctic Circumpolar Current (ACC) formation, in the cooling of high‐latitude South Atlantic waters and in the initiation of North Atlantic Deep Water (NADW) formation. Several model studies have aimed to assess the impacts of DP opening on climate, but most of them focused on surface climate, and only few used realistic Eocene boundary conditions. Here, we revisit the impact of the DP opening on ocean circulation with the IPSL‐CM5A2 Earth System Model. Using appropriate middle Eocene (40 Ma) boundary conditions, we perform and analyze simulations with different depths of the DP (0, 100, 1,000, and 2,500 m) and compare results to existing geochemical data. Our experiments show that DP opening has a strong effect on Eocene ocean structure and dynamics even for shallow depths. The DP opening notably allows the formation of a proto‐ACC and induces deep ocean cooling of 1.5°C to 2.5°C in most of the Southern Hemisphere. There is no NADW formation in our simulations regardless of the depth of the DP, suggesting that the DP on its own is not a primary control of deepwater formation in the North Atlantic. This study elucidates how and to what extent the opening of the DP contributed to the establishment of the modern global thermohaline circulation.

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“…Finally, the physiognomic characteristics of fossil, and a subset of modern, sites were compared using a hierarchical cluster analysis to determine similarity. This was achieved by calculating a Euclidean dissimilarity matrix without scaling using the "cluster" package in R (Maechler et al, 2019) and the "Ward D2" method for hierarchical clustering (R Core Team, 2019).…”

Section: Biome and Physiognomic Character Analysismentioning

confidence: 99%

Paleobotanical proxies for early Eocene climates and ecosystems in northern North America from middle to high latitudes

et al. 2020

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Abstract. Early Eocene climates were globally warm, with ice-free conditions at both poles. Early Eocene polar landmasses supported extensive forest ecosystems of a primarily temperate biota but also with abundant thermophilic elements, such as crocodilians, and mesothermic taxodioid conifers and angiosperms. The globally warm early Eocene was punctuated by geologically brief hyperthermals such as the Paleocene–Eocene Thermal Maximum (PETM), culminating in the Early Eocene Climatic Optimum (EECO), during which the range of thermophilic plants such as palms extended into the Arctic. Climate models have struggled to reproduce early Eocene Arctic warm winters and high precipitation, with models invoking a variety of mechanisms, from atmospheric CO2 levels that are unsupported by proxy evidence to the role of an enhanced hydrological cycle, to reproduce winters that experienced no direct solar energy input yet remained wet and above freezing. Here, we provide new estimates of climate and compile existing paleobotanical proxy data for upland and lowland midlatitude sites in British Columbia, Canada, and northern Washington, USA, and from high-latitude lowland sites in Alaska and the Canadian Arctic to compare climatic regimes between the middle and high latitudes of the early Eocene – spanning the PETM to the EECO – in the northern half of North America. In addition, these data are used to reevaluate the latitudinal temperature gradient in North America during the early Eocene and to provide refined biome interpretations of these ancient forests based on climate and physiognomic data.

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

Cited by 14 publications

References 45 publications

Surface-circulation change in the southwest Pacific Ocean across the Middle Eocene Climatic Optimum: inferences from dinoflagellate cysts and biomarker paleothermometry

Surface-circulation change in the southwest Pacific Ocean across the Middle Eocene Climatic Optimum: inferences from dinoflagellate cysts and biomarker paleothermometry

Quantifying the Effect of the Drake Passage Opening on the Eocene Ocean

Paleobotanical proxies for early Eocene climates and ecosystems in northern North America from middle to high latitudes

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