Evolution of Earth’s tectonic carbon conveyor belt
Evolution of Earth’s tectonic carbon conveyor belt
Concealed deep beneath the oceans is a carbon conveyor belt, propelled by plate tectonics. Our understanding of its modern functioning is underpinned by direct observations, but its variability through time has been poorly quantified. Here we reconstruct oceanic plate carbon reservoirs and track the fate of subducted carbon using thermodynamic modelling. In the Mesozoic era, 250 to 66 million years ago, plate tectonic processes had a pivotal role in driving climate change. Triassic–Jurassic period cooling correlates with a reduction in solid Earth outgassing, whereas Cretaceous period greenhouse conditions can be linked to a doubling in outgassing, driven by high-speed plate tectonics. The associated ‘carbon subduction superflux’ into the subcontinental mantle may have sparked North American diamond formation. In the Cenozoic era, continental collisions slowed seafloor spreading, reducing tectonically driven outgassing, while deep-sea carbonate sediments emerged as the Earth’s largest carbon sink. Subduction and devolatilization of this reservoir beneath volcanic arcs led to a Cenozoic increase in carbon outgassing, surpassing mid-ocean ridges as the dominant source of carbon emissions 20 million years ago. An increase in solid Earth carbon emissions during Cenozoic cooling requires an increase in continental silicate weathering flux to draw down atmospheric carbon dioxide, challenging previous views and providing boundary conditions for future carbon cycle models.
629-639
Müller, R. Dietmar
e3aad460-457d-483a-b226-71621f378631
Mather, Ben
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Dutkiewicz, Adriana
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Keller, Tobias
d8dfcfa5-89d1-4203-aa2d-8c142c00a169
Merdith, Andrew
6e6e4af3-ae97-42eb-9b81-36e3c1d6783b
Gonzalez, Christopher M.
c7c54350-8dcc-4229-9120-9189d48fce9b
Gorczyk, Weronika
e9b4088f-70f5-4402-8131-900cf186a883
Zahirovic, Sabin
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26 May 2022
Müller, R. Dietmar
e3aad460-457d-483a-b226-71621f378631
Mather, Ben
c99c0545-fbe5-43f0-a0c9-89cfd0d68b68
Dutkiewicz, Adriana
4e98b73a-d904-4a7e-bd19-741bab6ce8ad
Keller, Tobias
d8dfcfa5-89d1-4203-aa2d-8c142c00a169
Merdith, Andrew
6e6e4af3-ae97-42eb-9b81-36e3c1d6783b
Gonzalez, Christopher M.
c7c54350-8dcc-4229-9120-9189d48fce9b
Gorczyk, Weronika
e9b4088f-70f5-4402-8131-900cf186a883
Zahirovic, Sabin
9fa711da-7223-4f31-a8cb-554940642ff2
Müller, R. Dietmar, Mather, Ben and Dutkiewicz, Adriana
,
et al.
(2022)
Evolution of Earth’s tectonic carbon conveyor belt.
Nature, 605, .
(doi:10.1038/s41586-022-04420-x).
Abstract
Concealed deep beneath the oceans is a carbon conveyor belt, propelled by plate tectonics. Our understanding of its modern functioning is underpinned by direct observations, but its variability through time has been poorly quantified. Here we reconstruct oceanic plate carbon reservoirs and track the fate of subducted carbon using thermodynamic modelling. In the Mesozoic era, 250 to 66 million years ago, plate tectonic processes had a pivotal role in driving climate change. Triassic–Jurassic period cooling correlates with a reduction in solid Earth outgassing, whereas Cretaceous period greenhouse conditions can be linked to a doubling in outgassing, driven by high-speed plate tectonics. The associated ‘carbon subduction superflux’ into the subcontinental mantle may have sparked North American diamond formation. In the Cenozoic era, continental collisions slowed seafloor spreading, reducing tectonically driven outgassing, while deep-sea carbonate sediments emerged as the Earth’s largest carbon sink. Subduction and devolatilization of this reservoir beneath volcanic arcs led to a Cenozoic increase in carbon outgassing, surpassing mid-ocean ridges as the dominant source of carbon emissions 20 million years ago. An increase in solid Earth carbon emissions during Cenozoic cooling requires an increase in continental silicate weathering flux to draw down atmospheric carbon dioxide, challenging previous views and providing boundary conditions for future carbon cycle models.
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Accepted/In Press date: 13 January 2022
e-pub ahead of print date: 25 May 2022
Published date: 26 May 2022
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Local EPrints ID: 488370
URI: http://eprints.soton.ac.uk/id/eprint/488370
ISSN: 0028-0836
PURE UUID: adfc97cc-5f0f-476d-a808-062fb52c8ef3
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Date deposited: 21 Mar 2024 17:32
Last modified: 23 Mar 2024 03:13
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Contributors
Author:
R. Dietmar Müller
Author:
Ben Mather
Author:
Adriana Dutkiewicz
Author:
Tobias Keller
Author:
Andrew Merdith
Author:
Christopher M. Gonzalez
Author:
Weronika Gorczyk
Author:
Sabin Zahirovic
Corporate Author: et al.
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