Testing the Cenozoic multisite composite δ18O and δ13C curves: New monospecific Eocene records from a single locality, Demerara Rise (Ocean Drilling Program Leg 207)
Testing the Cenozoic multisite composite δ18O and δ13C curves: New monospecific Eocene records from a single locality, Demerara Rise (Ocean Drilling Program Leg 207)
Until recently, very few high-quality deep ocean sedimentary sections of Eocene age have been available. Consequently, our understanding of Eocene paleoceanography has become heavily reliant on “composite” records patched together from multiple sites in different ocean basins and generated using multiple taxa (potential sources of “local” noise in the global signal). Here we test the reliability of the early to middle Eocene composite δ18O and δ13C stratigraphies (Zachos et al., 2001) by generating new monospecific records in benthic foraminiferal calcite from a single locality, Demerara Rise, in the tropical western Atlantic (Ocean Drilling Program Leg 207). We present new stable isotope correction factors for commonly used Eocene benthic foraminiferal species. We find that interspecies isotopic offsets are constant across the isotopic range, supporting the notion that the inconstant intertaxa offsets reported elsewhere result from mixing species within genera. In general, the δ18O stratigraphy from Demerara Rise supports the validity of the Eocene δ18O composite, while revealing a temporary warming punctuating middle Eocene cooling. This warming may correspond to the so-called “Middle Eocene Climatic Optimum” previously documented in the Southern Ocean. The composite and Demerara Rise records for δ13C differ substantially. By removing the intersite and intertaxa sources of uncertainty in δ13C, we obtain a clearer picture of carbon cycling during the Eocene. Secular change in interocean δ13C gradients through the Eocene reveals that intervals of climatic warmth (especially the early Eocene) are associated with very small water mass ageing gradients.
benthic foraminifera, Eocene, stable isotopes, warm climates, Ocean Drilling Program, Demerara Rise
PA2019
Sexton, Philip F.
8f381c3d-6181-4027-bc35-258780a1f383
Wilson, Paul
f940a9f0-fa5a-4a64-9061-f0794bfbf7c6
Norris, Richard D.
9e0dfa1e-0c69-4666-bbf9-a5a14909d8f9
16 June 2006
Sexton, Philip F.
8f381c3d-6181-4027-bc35-258780a1f383
Wilson, Paul
f940a9f0-fa5a-4a64-9061-f0794bfbf7c6
Norris, Richard D.
9e0dfa1e-0c69-4666-bbf9-a5a14909d8f9
Sexton, Philip F., Wilson, Paul and Norris, Richard D.
(2006)
Testing the Cenozoic multisite composite δ18O and δ13C curves: New monospecific Eocene records from a single locality, Demerara Rise (Ocean Drilling Program Leg 207).
Paleoceanography and Paleoclimatology, 21 (2), .
(doi:10.1029/2005PA001253).
Abstract
Until recently, very few high-quality deep ocean sedimentary sections of Eocene age have been available. Consequently, our understanding of Eocene paleoceanography has become heavily reliant on “composite” records patched together from multiple sites in different ocean basins and generated using multiple taxa (potential sources of “local” noise in the global signal). Here we test the reliability of the early to middle Eocene composite δ18O and δ13C stratigraphies (Zachos et al., 2001) by generating new monospecific records in benthic foraminiferal calcite from a single locality, Demerara Rise, in the tropical western Atlantic (Ocean Drilling Program Leg 207). We present new stable isotope correction factors for commonly used Eocene benthic foraminiferal species. We find that interspecies isotopic offsets are constant across the isotopic range, supporting the notion that the inconstant intertaxa offsets reported elsewhere result from mixing species within genera. In general, the δ18O stratigraphy from Demerara Rise supports the validity of the Eocene δ18O composite, while revealing a temporary warming punctuating middle Eocene cooling. This warming may correspond to the so-called “Middle Eocene Climatic Optimum” previously documented in the Southern Ocean. The composite and Demerara Rise records for δ13C differ substantially. By removing the intersite and intertaxa sources of uncertainty in δ13C, we obtain a clearer picture of carbon cycling during the Eocene. Secular change in interocean δ13C gradients through the Eocene reveals that intervals of climatic warmth (especially the early Eocene) are associated with very small water mass ageing gradients.
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Published date: 16 June 2006
Keywords:
benthic foraminifera, Eocene, stable isotopes, warm climates, Ocean Drilling Program, Demerara Rise
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Local EPrints ID: 37748
URI: http://eprints.soton.ac.uk/id/eprint/37748
ISSN: 2572-4525
PURE UUID: d4d17bc6-31e5-41f4-9d4e-4b645e0e5c0e
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Date deposited: 26 May 2006
Last modified: 16 Mar 2024 03:13
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Author:
Philip F. Sexton
Author:
Richard D. Norris
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