A Ternary Mixing Model Approach Using Benthic Foraminifer δ13C‐δ18O Data to Reconstruct Late Pliocene Deep Atlantic Water Mass Mixing

Late Pliocene deep Atlantic δ13C data have been interpreted as evidence for enhanced Atlantic Meridional Overturning Circulation (AMOC) compared to the present, but this hypothesis is not supported by the Pliocene Model Intercomparison Project (PlioMIP). Here, we adopt a new approach to assess varia...

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Published in:Paleoceanography and paleoclimatology 2020-12, Vol.35 (12), p.n/a
Main Authors: Weijst, Carolien M. H., Winkelhorst, Josse, Lourens, Lucas, Raymo, Maureen E., Sangiorgi, Francesca, Sluijs, Appy
Format: Article
Language:English
Subjects:
Atlantic Meridional Overturning Circulation
Atlantic Meridional Overturning Circulation (AMOC)
benthic δ13C‐δ18O
Benthos
Data
Drilling
eastern equatorial Atlantic
Foraminifera
Intercomparison
Isotopes
M2 glacial
Mass
Ocean circulation
Ocean currents
Oceans
Oxygen
Oxygen isotopes
Pliocene
ternary mixing model
Tracers
Variability
Water
Water circulation
Water mass mixing
Water masses
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Summary:Late Pliocene deep Atlantic δ13C data have been interpreted as evidence for enhanced Atlantic Meridional Overturning Circulation (AMOC) compared to the present, but this hypothesis is not supported by the Pliocene Model Intercomparison Project (PlioMIP). Here, we adopt a new approach to assess variability in deep ocean circulation based on paired stable carbon (δ13C) and oxygen isotopes (δ18O) of benthic foraminifera, both (semi)conservative water mass tracers. Assuming that deep Atlantic benthic δ13C‐δ18O variability is predominantly driven by mixing, we extrapolate the δ13C‐δ18O data outside the sampled range to identify the end‐members. At least three end‐members are needed to explain the spatial δ13C‐δ18O variability in the deep North Atlantic Ocean: two Northern Component Water (NCW) and one Southern Component Water (SCW) water masses. We use a ternary mixing model to quantify the mixing proportions between SCW and NCW in the deep Atlantic Ocean. Our analysis includes new data from Ocean Drilling Program Sites 959 and 662 in the eastern equatorial Atlantic and suggests that the AMOC cell was deeper during the M2 glacial than during late Pliocene interglacials. Moreover, we identify a new cold and well‐ventilated water mass that was geographically restricted to the southeast Atlantic Ocean between 3.6 and 2.7 Ma and did not contribute significantly to the δ13C‐δ18O variability of the rest of the basin. This high‐δ13C high‐δ18O water mass has led to the misconception of a reduced latitudinal δ13C gradient. Our analyses show that the late Pliocene δ13C gradient between NCW and SCW was similar to the present‐day value of 1.1‰. Key Points Paired δ13C‐δ18O data are used to identify water mass end‐members outside the sampled range In past oceans, a ternary mixing model using δ13C‐δ18O may outperform a binary δ13C mixing model AMOC was relatively deep during the M2 glacial compared to the late Pliocene interglacials
ISSN:2572-4517
2572-4525
DOI:10.1029/2019PA003804