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North American continental margin records of the Paleocene-Eocene thermal maximum: implications for global carbon and hydrological cycling

North American continental margin records of the Paleocene-Eocene thermal maximum: implications for global carbon and hydrological cycling
North American continental margin records of the Paleocene-Eocene thermal maximum: implications for global carbon and hydrological cycling
The impacts of the Paleocene-Eocene thermal maximum (PETM) (?55 Ma), one of the most rapid and extreme warming events in Earth history, are well characterized in open marine and terrestrial environments but are less so on continental margins, a major carbon sink. Here, we present stable isotope, carbonate content, organic matter content, and C:N ratio records through the PETM from new outcrop sections in California and from cores previously drilled on the New Jersey margin. Foraminifer ? 18O data suggest that midlatitude shelves warmed by a similar magnitude as the open ocean (5°C–8°C), while the carbon isotope excursion (CIE), recorded both in carbonate and organic matter ? 13C records, is slightly larger (3.3–4.5‰) than documented in open ocean records. Sediment accumulation rates increase dramatically during the CIE in marked contrast to the open ocean sites. In parallel, mass accumulation rates of both organic and inorganic carbon also increased by an order of magnitude. The estimated total mass of accumulated carbon in excess of pre-CIE rates suggests that continental margins, at least along North America, became carbon sinks during the CIE, mainly because of weathering feedbacks and rising sea level. This result is significant because it implies that the negative feedback role of carbon burial on continental margins was greater than previously recognized.
carbon cycle, PETM, continental shelves, Paleocene, Eocene
0883-8305
PA2217
John, Cédric M.
e26a63a2-2d2c-4bb3-9d45-1c20aa44eff9
Bohaty, Steven M.
af9dbe78-8b9f-44f2-ba1d-20795837d2d1
Zachos, James C.
c262d59f-aadc-4e09-b844-098db9a0e3c5
Sluijs, Appy
af623507-b795-4458-8ca5-cce783869a3d
Gibbs, Samantha
82dfbcbc-3a8a-40da-8a80-fe7ad83f3110
Brinkhuis, Henk
2897d110-84de-4cd1-8b90-97a0bc404354
Bralower, Timothy J.
8d16a733-85c8-4837-aa95-f070d61494a7
John, Cédric M.
e26a63a2-2d2c-4bb3-9d45-1c20aa44eff9
Bohaty, Steven M.
af9dbe78-8b9f-44f2-ba1d-20795837d2d1
Zachos, James C.
c262d59f-aadc-4e09-b844-098db9a0e3c5
Sluijs, Appy
af623507-b795-4458-8ca5-cce783869a3d
Gibbs, Samantha
82dfbcbc-3a8a-40da-8a80-fe7ad83f3110
Brinkhuis, Henk
2897d110-84de-4cd1-8b90-97a0bc404354
Bralower, Timothy J.
8d16a733-85c8-4837-aa95-f070d61494a7

John, Cédric M., Bohaty, Steven M., Zachos, James C., Sluijs, Appy, Gibbs, Samantha, Brinkhuis, Henk and Bralower, Timothy J. (2008) North American continental margin records of the Paleocene-Eocene thermal maximum: implications for global carbon and hydrological cycling. Paleoceanography, 23 (2), PA2217. (doi:10.1029/2007PA001465).

Record type: Article

Abstract

The impacts of the Paleocene-Eocene thermal maximum (PETM) (?55 Ma), one of the most rapid and extreme warming events in Earth history, are well characterized in open marine and terrestrial environments but are less so on continental margins, a major carbon sink. Here, we present stable isotope, carbonate content, organic matter content, and C:N ratio records through the PETM from new outcrop sections in California and from cores previously drilled on the New Jersey margin. Foraminifer ? 18O data suggest that midlatitude shelves warmed by a similar magnitude as the open ocean (5°C–8°C), while the carbon isotope excursion (CIE), recorded both in carbonate and organic matter ? 13C records, is slightly larger (3.3–4.5‰) than documented in open ocean records. Sediment accumulation rates increase dramatically during the CIE in marked contrast to the open ocean sites. In parallel, mass accumulation rates of both organic and inorganic carbon also increased by an order of magnitude. The estimated total mass of accumulated carbon in excess of pre-CIE rates suggests that continental margins, at least along North America, became carbon sinks during the CIE, mainly because of weathering feedbacks and rising sea level. This result is significant because it implies that the negative feedback role of carbon burial on continental margins was greater than previously recognized.

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More information

Published date: June 2008
Keywords: carbon cycle, PETM, continental shelves, Paleocene, Eocene
Organisations: Ocean and Earth Science
Learn more about Ocean and Earth Science research

Identifiers

Local EPrints ID: 59173
URI: http://eprints.soton.ac.uk/id/eprint/59173
DOI: doi:10.1029/2007PA001465
ISSN: 0883-8305
PURE UUID: 4d41ba43-a16d-4857-9466-349c6374bb12
ORCID for Steven M. Bohaty: ORCID iD orcid.org/0000-0002-1193-7398

Catalogue record

Date deposited: 26 Aug 2008
Last modified: 16 Mar 2024 03:52

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Contributors

Author: Cédric M. John
Author: Steven M. Bohaty ORCID iD
Author: James C. Zachos
Author: Appy Sluijs
Author: Samantha Gibbs
Author: Henk Brinkhuis
Author: Timothy J. Bralower

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