Ocean freshening near the end of the Mesozoic

Wiesława Radmacher; Igor Niezgodzki; Vicente Gilabert; Gregor Knorr; David M. Buchs; José A. Arz; Ignacio Arenillas; Martin A. Pearce; Jarosław Tyszka; Mateusz Mikołajczak; Osmín J. Vásquez; Sarit Ashckenazi-Polivoda; Sigal Abramovich; Mariusz Niechwedowicz; Gunn Mangerud

doi:10.1038/s41467-025-62189-9

Ocean freshening near the end of the Mesozoic

Wiesława Radmacher
, Igor Niezgodzki
, Vicente Gilabert
, Gregor Knorr
, David M. Buchs
, José A. Arz
, Ignacio Arenillas
, Martin A. Pearce
, Jarosław Tyszka
, Mateusz Mikołajczak
, Osmín J. Vásquez
, Sarit Ashckenazi-Polivoda
, Sigal Abramovich
, Mariusz Niechwedowicz
, Gunn Mangerud

Department of Earth and Environmental sciences

Research output: Contribution to journal › Article › peer-review

Abstract

Paleogeographic changes have significantly shaped ocean circulation and climate dynamics throughout Earth’s history. This study integrates geological proxies with climate simulations to assess how ocean gateway evolution influenced ocean salinity near the end of the Mesozoic (~66 Ma). Our modeling results demonstrate that 1) Central American Seaway shoaling reorganizes ocean currents, and 2) Arctic marine gateway restrictions, confining Arctic–Global Ocean exchange exclusively to the Greenland–Norwegian Seaway, drive Arctic Ocean surface freshening and southward outflow of buoyant, low-salinity waters. However, only the combined effect of these two factors leads to both Arctic freshening and increased water mass stratification in the Greenland–Norwegian Seaway, proto-North Atlantic, and the Western Tethys. This scenario aligns with Maastrichtian palynological, micropaleontological, and geochemical records from high- and low-latitude sites. Our findings highlight the profound impact of these latest Cretaceous paleogeographic reconfigurations in altering global salinity patterns, underscoring their role as key drivers of global climate dynamics.

Original language	English
Article number	7238
Journal	Nature Communications
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-62189-9
State	Published - 6 Aug 2025

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General
General Physics and Astronomy

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Cite this

Radmacher, W., Niezgodzki, I., Gilabert, V., Knorr, G., Buchs, D. M., Arz, J. A., Arenillas, I., Pearce, M. A., Tyszka, J., Mikołajczak, M., Vásquez, O. J., Ashckenazi-Polivoda, S., Abramovich, S., Niechwedowicz, M., & Mangerud, G. (2025). Ocean freshening near the end of the Mesozoic. Nature Communications, 16(1), Article 7238. https://doi.org/10.1038/s41467-025-62189-9

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abstract = "Paleogeographic changes have significantly shaped ocean circulation and climate dynamics throughout Earth{\textquoteright}s history. This study integrates geological proxies with climate simulations to assess how ocean gateway evolution influenced ocean salinity near the end of the Mesozoic (\textasciitilde{}66 Ma). Our modeling results demonstrate that 1) Central American Seaway shoaling reorganizes ocean currents, and 2) Arctic marine gateway restrictions, confining Arctic–Global Ocean exchange exclusively to the Greenland–Norwegian Seaway, drive Arctic Ocean surface freshening and southward outflow of buoyant, low-salinity waters. However, only the combined effect of these two factors leads to both Arctic freshening and increased water mass stratification in the Greenland–Norwegian Seaway, proto-North Atlantic, and the Western Tethys. This scenario aligns with Maastrichtian palynological, micropaleontological, and geochemical records from high- and low-latitude sites. Our findings highlight the profound impact of these latest Cretaceous paleogeographic reconfigurations in altering global salinity patterns, underscoring their role as key drivers of global climate dynamics.",

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AU - Buchs, David M.

AU - Arz, José A.

AU - Arenillas, Ignacio

AU - Pearce, Martin A.

AU - Tyszka, Jarosław

AU - Mikołajczak, Mateusz

AU - Vásquez, Osmín J.

AU - Ashckenazi-Polivoda, Sarit

AU - Abramovich, Sigal

AU - Niechwedowicz, Mariusz

AU - Mangerud, Gunn

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N2 - Paleogeographic changes have significantly shaped ocean circulation and climate dynamics throughout Earth’s history. This study integrates geological proxies with climate simulations to assess how ocean gateway evolution influenced ocean salinity near the end of the Mesozoic (~66 Ma). Our modeling results demonstrate that 1) Central American Seaway shoaling reorganizes ocean currents, and 2) Arctic marine gateway restrictions, confining Arctic–Global Ocean exchange exclusively to the Greenland–Norwegian Seaway, drive Arctic Ocean surface freshening and southward outflow of buoyant, low-salinity waters. However, only the combined effect of these two factors leads to both Arctic freshening and increased water mass stratification in the Greenland–Norwegian Seaway, proto-North Atlantic, and the Western Tethys. This scenario aligns with Maastrichtian palynological, micropaleontological, and geochemical records from high- and low-latitude sites. Our findings highlight the profound impact of these latest Cretaceous paleogeographic reconfigurations in altering global salinity patterns, underscoring their role as key drivers of global climate dynamics.

AB - Paleogeographic changes have significantly shaped ocean circulation and climate dynamics throughout Earth’s history. This study integrates geological proxies with climate simulations to assess how ocean gateway evolution influenced ocean salinity near the end of the Mesozoic (~66 Ma). Our modeling results demonstrate that 1) Central American Seaway shoaling reorganizes ocean currents, and 2) Arctic marine gateway restrictions, confining Arctic–Global Ocean exchange exclusively to the Greenland–Norwegian Seaway, drive Arctic Ocean surface freshening and southward outflow of buoyant, low-salinity waters. However, only the combined effect of these two factors leads to both Arctic freshening and increased water mass stratification in the Greenland–Norwegian Seaway, proto-North Atlantic, and the Western Tethys. This scenario aligns with Maastrichtian palynological, micropaleontological, and geochemical records from high- and low-latitude sites. Our findings highlight the profound impact of these latest Cretaceous paleogeographic reconfigurations in altering global salinity patterns, underscoring their role as key drivers of global climate dynamics.

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Ocean freshening near the end of the Mesozoic

Abstract

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