Causes and consequences of the Messinian salinity crisis
Causes and consequences of the Messinian salinity crisis
Salt giants are massive salt deposits (hundreds of metres thick) that form during the evaporation of semi-enclosed seas. The drivers of salt giant formation and their feedbacks on global and regional environmental change remain debated. In this Review, we summarize the boundary conditions, causes and consequences of the Mediterranean Messinian salinity crisis (MSC; 5.97–5.33 million years ago). Salt giant formation is more complex than the simple evaporation of an enclosed sea. Instead, the tectonic setting of an evaporative basin largely determines the timing and mode of salt formation, with superimposed impacts of orbital-scale climate and sea-level fluctuations. These drivers triggered precipitation of carbonates, gypsum, halite and bittern salts, with well-defined orbital cyclicities in carbonate and gypsum phases. Removal of Ca2+ during salt giant deposition decouples the oceanic Ca2+ and HCO3− sinks, causing reduced CaCO3 burial and, consequently, increased ocean pH, lower atmospheric partial pressure of CO2, and global cooling. Salt giants, which reflect a net evaporite-ion extraction of ~7–10% from oceans and persist over million-year timescales, could therefore be an important climate driver but are currently underconsidered in long-term carbon cycle models. Future research should use advanced hydrogeochemical models of water–ocean exchange to further explore interactions between salt giants and environmental change.
335-350
Krijgsman, Wout
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Rohling, Eelco J.
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Palcu, Dan V.
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Raad, Fadl
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Amarathunga, Udara
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Flecker, Rachel
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Florindo, Fabio
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Roberts, Andrew P.
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Sierro, Francisco J.
23ddf779-d2ff-4648-a531-d11e7ba12aa5
Aloisi, Giovanni
156cfad8-c235-4825-bd6d-ae5a6c3be031
May 2024
Krijgsman, Wout
53323502-3f97-44b9-a2df-e1790ce3370f
Rohling, Eelco J.
a2a27ef2-fcce-4c71-907b-e692b5ecc685
Palcu, Dan V.
f243d856-a9ea-410d-b8d2-8efee1f28677
Raad, Fadl
f0451056-abe8-4723-bc13-c5aafea5c2f1
Amarathunga, Udara
5029978e-bdd2-478f-90b4-2428bad9b1c0
Flecker, Rachel
1832f807-66eb-4cd5-b8ab-3b505e04b1e1
Florindo, Fabio
5953170b-79f7-431e-9e08-824a47e0fbd5
Roberts, Andrew P.
bfc571f6-9c7a-4cc5-8df9-2c41ef5ac2a1
Sierro, Francisco J.
23ddf779-d2ff-4648-a531-d11e7ba12aa5
Aloisi, Giovanni
156cfad8-c235-4825-bd6d-ae5a6c3be031
Krijgsman, Wout, Rohling, Eelco J., Palcu, Dan V., Raad, Fadl, Amarathunga, Udara, Flecker, Rachel, Florindo, Fabio, Roberts, Andrew P., Sierro, Francisco J. and Aloisi, Giovanni
(2024)
Causes and consequences of the Messinian salinity crisis.
Nature Reviews Earth & Environment, 5 (5), .
(doi:10.1038/s43017-024-00533-1).
Abstract
Salt giants are massive salt deposits (hundreds of metres thick) that form during the evaporation of semi-enclosed seas. The drivers of salt giant formation and their feedbacks on global and regional environmental change remain debated. In this Review, we summarize the boundary conditions, causes and consequences of the Mediterranean Messinian salinity crisis (MSC; 5.97–5.33 million years ago). Salt giant formation is more complex than the simple evaporation of an enclosed sea. Instead, the tectonic setting of an evaporative basin largely determines the timing and mode of salt formation, with superimposed impacts of orbital-scale climate and sea-level fluctuations. These drivers triggered precipitation of carbonates, gypsum, halite and bittern salts, with well-defined orbital cyclicities in carbonate and gypsum phases. Removal of Ca2+ during salt giant deposition decouples the oceanic Ca2+ and HCO3− sinks, causing reduced CaCO3 burial and, consequently, increased ocean pH, lower atmospheric partial pressure of CO2, and global cooling. Salt giants, which reflect a net evaporite-ion extraction of ~7–10% from oceans and persist over million-year timescales, could therefore be an important climate driver but are currently underconsidered in long-term carbon cycle models. Future research should use advanced hydrogeochemical models of water–ocean exchange to further explore interactions between salt giants and environmental change.
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MSC_NREE_Revision_accepted
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Submitted date: 21 February 2024
Accepted/In Press date: 21 February 2024
e-pub ahead of print date: 16 April 2024
Published date: May 2024
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Local EPrints ID: 490349
URI: http://eprints.soton.ac.uk/id/eprint/490349
PURE UUID: 8afcc526-4fbe-408c-a28e-843e19f944c3
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Date deposited: 23 May 2024 17:04
Last modified: 16 Oct 2024 04:01
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Contributors
Author:
Wout Krijgsman
Author:
Dan V. Palcu
Author:
Fadl Raad
Author:
Udara Amarathunga
Author:
Rachel Flecker
Author:
Fabio Florindo
Author:
Andrew P. Roberts
Author:
Francisco J. Sierro
Author:
Giovanni Aloisi
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