Abstract
Abstract. Accurate reconstructions of seawater salinity could provide valuable constraints for studying past ocean circulation, the hydrological cycle and sea level change. Controlled growth experiments and field studies have shown the potential of foraminiferal Na ∕ Ca as a direct salinity proxy. Incorporation of minor and trace elements in foraminiferal shell carbonate varies, however, greatly between species and hence extrapolating calibrations to other species needs validation by additional (culturing) studies. Salinity is also known to impact other foraminiferal carbonate-based proxies, such as Mg ∕ Ca for temperature and Sr ∕ Ca for sea water carbonate chemistry. Better constraints on the role of salinity on these proxies will therefore improve their reliability. Using a controlled growth experiment spanning a salinity range of 20 units and analysis of element composition on single chambers using laser ablation-Q-ICP-MS, we show here that Na ∕ Ca correlates positively with salinity in two benthic foraminiferal species (Ammonia tepida and Amphistegina lessonii). The Na ∕ Ca values differ between the two species, with an approximately 2-fold higher Na ∕ Ca in A. lessonii than in A. tepida, coinciding with an offset in their Mg content (∼ 35 mmol mol−2 versus ∼ 2.5 mmol mol−1 for A. lessonii and A. tepida, respectively). Despite the offset in average Na ∕ Ca values, the slopes of the Na ∕ Ca–salinity regressions are similar between these two species (0.077 versus 0.064 mmol mol−1 change per salinity unit). In addition, Mg ∕ Ca and Sr ∕ Ca are positively correlated with salinity in cultured A. tepida but show no correlation with salinity for A. lessonii. Electron microprobe mapping of incorporated Na and Mg of the cultured specimens shows that within chamber walls of A. lessonii, Na ∕ Ca and Mg ∕ Ca occur in elevated bands in close proximity to the primary organic lining. Between species, Mg banding is relatively similar, even though Mg content is 10 times lower and that variation within the chamber wall is much less pronounced in A. tepida. In addition, Na banding is much less prominent in this species than it is in A. lessonii. Inter-species differences in element banding reported here are hypothesized to be caused by differences in biomineralization controls responsible for element uptake.
Highlights
Sea water salinity varies over time and space as a function of continental ice volume, evaporation, precipitation and river runoff
An independent salinity proxy would be useful for constraining past salinity but would improve temperature reconstructions based on Mg / Cacc and reconstructions of past sea water carbonate chemistry based on Sr / common denominator (Ca)
By extending existing calibrations of the Na / Cacc–salinity proxy to the intermediate-Mg calcite precipitating benthic foraminifer Amphistegina lessonii, we show that the Na / Cacc increase as a function of salinity is similar to that in previously studied species
Summary
Sea water salinity varies over time and space as a function of continental ice volume, evaporation, precipitation and river runoff. An effect of salinity on foraminiferal Sr / Cacc has been reported in some studies (Kısakürek et al, 2008; Dissard et al, 2010b; Wit et al, 2013), other studies did not find a relation between salinity and foraminiferal Sr / Ca (Dueñas-Bohórquez et al, 2009; Diz et al, 2012; Allen et al, 2016), which led to the hypothesis that foraminiferal Sr / Ca mainly reflects sea water inorganic carbon chemistry (Keul et al, 2017) in addition to its response to temperature (Lea et al, 1999; Raja et al, 2007). An independent salinity proxy would be useful for constraining past (changes in) salinity but would improve temperature reconstructions based on Mg / Cacc and reconstructions of past sea water carbonate chemistry based on Sr / Ca
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
