Transient mobilization of subcrustal carbon coincident with Palaeocene–Eocene Thermal Maximum

Plume magmatism and continental breakup led to the opening of the northeast Atlantic Ocean during the globally warm early Cenozoic. This warmth culminated in a transient (170 thousand year, kyr) hyperthermal event associated with a large, if poorly constrained, emission of carbon called the Palaeoce...

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Bibliographic Details
Published in:Nature geoscience 2022-07, Vol.15 (7), p.573-579
Main Authors: Gernon, Thomas M., Barr, Ryan, Fitton, J. Godfrey, Hincks, Thea K., Keir, Derek, Longman, Jack, Merdith, Andrew S., Mitchell, Ross N., Palmer, Martin R.
Format: Article
Language:English
Subjects:
704/2151/209
704/2151/213
704/2151/598
Atmospheric models
Background levels
Carbon
Carbon dioxide
Carbon dioxide emissions
Carbonates
Cenozoic
Constraints
Decompression
Deep sea
Deep sea sediments
Earth and Environmental Science
Earth Sciences
Earth System Sciences
Emissions
Eocene
Geochemistry
Geology
Geophysics/Geodesy
Hydrothermal springs
Hydrothermal vents
Isotopes
Lava
Magma
Melting
Mid-ocean ridges
Oceans
Outgassing
Palaeocene
Paleocene
Ridges
Rifting
Sediments
Tectonics
Vents
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Summary:Plume magmatism and continental breakup led to the opening of the northeast Atlantic Ocean during the globally warm early Cenozoic. This warmth culminated in a transient (170 thousand year, kyr) hyperthermal event associated with a large, if poorly constrained, emission of carbon called the Palaeocene–Eocene Thermal Maximum (PETM) 56 million years ago (Ma). Methane from hydrothermal vents in the coeval North Atlantic Igneous Province (NAIP) has been proposed as the trigger, though isotopic constraints from deep sea sediments have instead implicated direct volcanic carbon dioxide (CO 2 ) emissions. Here we calculate that background levels of volcanic outgassing from mid-ocean ridges and large igneous provinces yield only one-fifth of the carbon required to trigger the hyperthermal. However, geochemical analyses of volcanic sequences spanning the rift-to-drift phase of the NAIP indicate a sudden ~220 kyr-long intensification of magmatic activity coincident with the PETM. This was likely driven by thinning and enhanced decompression melting of the sub-continental lithospheric mantle, which critically contained a high proportion of carbon-rich metasomatic carbonates. Melting models and coupled tectonic–geochemical simulations indicate that >10 4 gigatons of subcrustal carbon was mobilized into the ocean and atmosphere sufficiently rapidly to explain the scale and pace of the PETM. A change in the style of rifting in the North Atlantic led to carbon fluxes from subcrustal melting that helped trigger the Palaeocene–Eocene Thermal Maximum, according to geochemical analyses of volcanic sequences as well as melting and tectonic modelling.
ISSN:1752-0894
1752-0908
DOI:10.1038/s41561-022-00967-6