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A 15-million-year surface- and subsurface-integrated TEX86 temperature record from the eastern equatorial Atlantic
van der Weijst, C.M.H.; van der Laan, K.J.; Peterse, F.; Reichart, G.-J.; Sangiorgi, F.; Schouten, S.; Veenstra, T.J.T.; Sluijs, A. (2022). A 15-million-year surface- and subsurface-integrated TEX86 temperature record from the eastern equatorial Atlantic. Clim. Past 18(8): 1947-1962. https://dx.doi.org/10.5194/cp-18-1947-2022
In: Climate of the Past. Copernicus: Göttingen. ISSN 1814-9324; e-ISSN 1814-9332, more
Peer reviewed article  

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  • van der Weijst, C.M.H.
  • van der Laan, K.J.
  • Peterse, F.
  • Reichart, G.-J., more
  • Sangiorgi, F.
  • Schouten, S., more
  • Veenstra, T.J.T.
  • Sluijs, A.

Abstract

    TEX86 is a paleothermometer based on Thaumarcheotal glycerol dialkyl glycerol tetraether (GDGT) lipids and is one of the most frequently used proxies for sea-surface temperature (SST) in warmer-than-present climates. However, GDGTs are not exclusively produced in and exported from the mixed layer, so sedimentary GDGTs may contain a depth-integrated signal that is also sensitive to local subsurface temperature variability. In addition, the correlation between TEX86 and SST is not significantly stronger than that to depth-integrated mixed-layer to subsurface temperatures. The calibration of TEX86 to SST is therefore controversial. Here we assess the influence of subsurface temperature variability on TEX86 using a downcore approach. We present a 15 Myr TEX86 record from Ocean Drilling Program Site 959 in the Gulf of Guinea and use additional proxies to elucidate the source of the recorded TEX86 variability. Relatively high GDGT ratio values from 13.6 Ma indicate that sedimentary GDGTs were partlysourced from deeper (>200 m) waters. Moreover, late Pliocene TEX 86 variability is highly sensitive to glacial–interglacial cyclicity, as is also recorded by benthic δ18O, while the variability within dinoflagellate assemblages and surface/thermocline temperature records (U and ) is not primarily explained by glacial–interglacial cyclicity. Combined, these observations are best explained by TEX86 sensitivity to sub-thermocline temperature variability. We conclude that TEX86 represents a depth-integrated signal that incorporates a SST and a deeper component, which is compatible with the present-day depth distribution of Thaumarchaeota and with the GDGT distribution in core tops. The depth-integrated TEX86 record can potentially be used to infer SST variability, because subsurface temperature variability is generally tightly linked to SST variability. Using a subsurface calibration with peak calibration weight between 100 and 350 m, we estimate that east equatorial Atlantic SST cooled by ∼5 C between the Late Miocene and Pleistocene. On shorter timescales, we use the TEX86 record as a proxy for South Atlantic Central Water (SACW), which originates from surface waters in the South Atlantic Gyre and mixes at depth with Antarctic Intermediate Water (AAIW). Leads and lags around the Pliocene M2 glacial (∼3.3 Ma) in our record, combined with published information, suggest that the M2 glacial was marked by SACW cooling during an austral summer insolation minimum and that decreasing CO2 levels were a feedback, not the initiator, of glacial expansion.


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