Abstract
Around the early–middle Eocene boundary, the first occurrence of contourite drift sediments and widespread deep ocean erosion indicate changes in the North Atlantic ocean circulation. Interestingly, these changes coincide with the first steps of Cenozoic cooling from the Paleogene greenhouse climate towards the modern icehouse. The cause for this ocean circulation reorganization is poorly understood since modern water mass tracers may have worked fundamentally different in the past and the paleoceanographic proxy record is limited in both time and space. As a result, it is challenging to reliably reconstruct the climatic and tectonic boundary conditions e.g. atmospheric greenhouse gas concentration and the depth and geometry of developing and closing passages between ocean basins. In this study, we attempt to identify thresholds in tectonic gateway passages and atmospheric CO2 concentration, using the fully coupled Earth System Model COSMOS. Indeed, the simulation of Earth's past climates can unravel the physical processes driving deep-water formation in a greenhouse world. Specifically, we use COSMOS to evaluate the impact of changes in the North Atlantic gateways at the early–middle Eocene boundary on the North Atlantic Deep Western Boundary Currents under low obliquity configuration. We find that Northern Component Waters start to form when the Greenland Scotland Ridge reaches a threshold depth of deeper than 200 m, while the Arctic Ocean is still shut off from the North Atlantic. In this scenario, the relatively deep Greenland Scotland Ridge allows for sufficient inflow of warm, salty Atlantic surface waters into the Nordic Seas to initiate convection during winter cooling. Opening the seaway towards the Arctic leads to a cessation of Northern Component Water formation as it allows for inflow of brackish surface waters into the northern Nordic Seas, hindering Northern Component Water formation.
Highlights
Large-scale climate change over the course of the Cenozoic has been linked to changes in ocean gateway configurations and their respective impact on the global ocean circulation (e.g. Berggren, 1982; Berggren and Hollister, 1977; Kennett, 1977)
We find that Northern Component Waters start to form when the Greenland Scotland Ridge reaches a threshold depth of deeper than 200 m, while the Arctic Ocean is still shut off from the North Atlantic
We find that only simulations with Northern Component Water (NCW) formation are characterized by Deep Western Boundary Currents (DWBC) that would explain the changes in North Atlantic sedimentation at the early– middle Eocene boundary
Summary
Large-scale climate change over the course of the Cenozoic has been linked to changes in ocean gateway configurations and their respective impact on the global ocean circulation (e.g. Berggren, 1982; Berggren and Hollister, 1977; Kennett, 1977). Important uncertainties in Eocene paleobathymetry reside in the depth of important seaways in the North and South Atlantic. During the Eocene, a number of paleogeographic changes could have led to the onset of the meridional deep-water circulation with a deep-water source in the North Atlantic: (i) The Nordic Seas widened considerably during the early Eocene but were still separated from the Atlantic by the Greenland–Scotland Ridge (GSR) Mantle plume activity decreased during the late early Eocene (Parnell-Turner et al, 2014) and a first marine connection between the North Atlantic and the Nordic Seas is indicated by similar planktonic microfauna and microflora on either side of the GSR (Berggren and Schnitker, 1983; Hulsbos et al, 1989).
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