Whereas several well‐established proxies are available for reconstructing past temperatures, salinity remains challenging to assess. Reconstructions based on the combination of (in)organic temperature proxies and foraminiferal stable oxygen isotopes result in relatively large uncertainties, which may be reduced by application of a direct salinity proxy. Cultured benthic and planktonic foraminifera showed that Na incorporation in foraminiferal shell calcite provides a potential independent proxy for salinity. Here we present the first field calibration of such a potential proxy. Living planktonic foraminiferal specimens from the Red Sea surface waters were collected and analyzed for their Na/Ca content using laser ablation quadrupole inductively coupled plasma mass spectrometry. Using the Red Sea as a natural laboratory, the calibration covers a broad range of salinities over a steep gradient within the same water mass. For both Globigerinoides ruber and Globigerinoides sacculifer calcite Na/Ca increases with salinity, albeit with a relatively large intraspecimen and interspecimen variability. The field‐based calibration is similar for both species from a salinity of ~36.8 up to ~39.6, while values for G. sacculifer deviate from this trend in the northernmost transect. It is hypothesized that the foraminifera in the northernmost part of the Red Sea are (partly) expatriated and hence should be excluded from the Na/Ca‐salinity calibration. Incorporation of Na in foraminiferal calcite therefore provides a potential proxy for salinity, although species‐specific calibrations are still required and more research on the effect of temperature is needed.
Abstract. The quantitative reconstruction of past seawater salinity has yet to be
achieved, and the search for a direct and independent salinity proxy is
ongoing. Recent culture and field studies show a significant positive
correlation of Na∕Ca with salinity in benthic and planktonic
foraminiferal calcite. For accurate paleoceanographic reconstructions,
consistent and reliable calibrations are necessary, which are still missing.
In order to assess the reliability of foraminiferal Na∕Ca as a direct
proxy for seawater salinity, this study presents electron microprobe
Na∕Ca data measured on cultured specimens of Trilobatus sacculifer. The culture experiments were conducted over a wide salinity
range of 26 to 45, while temperature was kept constant. To further understand
potential controlling factors of Na incorporation, measurements were also
performed on foraminifera cultured at various temperatures in the range of
19.5 to 29.5 ∘C under constant salinity conditions. Foraminiferal
Na∕Ca values positively correlate with seawater salinity
(Na/CaT. sacculifer=0.97+0.115⋅salinity, R=0.97, p<0.005). Temperature, on the other hand,
exhibits no statistically significant relationship with Na∕Ca values,
indicating salinity to be one of the dominant factors controlling Na
incorporation. The culturing results are corroborated by measurements on
T. sacculifer from Caribbean and Gulf of Guinea surface sediments,
indicating no dissolution effect on Na∕Ca in foraminiferal calcite
with increasing water depth up to >4 km. In conclusion, planktonic
foraminiferal Na∕Ca can be applied as a potential proxy for
reconstructing sea surface salinities, although species-specific calibrations
might be necessary.
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