The effect of carbonate chemistry on trace element incorporation in high-Mg calcitic foraminifera
The effect of carbonate chemistry on trace element incorporation in high-Mg calcitic foraminifera
The sodium-to-calcium ratio (Na/Ca) of biogenic CaCO3 has recently been introduced as a proxy for past seawater Ca2+ concentrations ([Ca2+sw]) as demonstrated by a positive correlation between seawater and shell Na/Ca with a minor influence of salinity. In the present study, we investigate the effect of carbonate chemistry on the Na/Ca proxy by conducting a set of experiments in which pH and the concentration of dissolved inorganic carbon (DIC) were independently varied. In addition to Na+, the incorporation of Li+, Mg2+, and Sr2+ into the shells of the large benthic high-Mg calcitic foraminifer Operculina ammonoides was assessed by culturing under constant DIC (∼2170 µmol kg−1) with varying pH (7.5–8.4 NBS scale), and under varying DIC (830–2470 µmol kg−1) with constant pH (∼7.9). Foraminiferal growth rate correlates linearly with calcite saturation state (Ω) of the experimental seawater (SW). The lowest pH and DIC experiments were characterized by low population growth rates, and some of these specimens died and their shells partially dissolved. Na/Cashell and Li/Cashell in O. ammonoides are positively correlated with SW [CO32–] and Ω, whereas Sr/Cashell and Mg/Cashell are much less sensitive to these parameters. The relative sensitivity of Na/Cashell to Ω in O. ammonoides is ∼ 4 % per Ω unit. However, given that past changes in surface water Ω were probably small relative to changes in [Ca2+sw] the correction for this secondary effect over the Cenozoic is likely to be small. Therefore, we conclude that the sensitivity of O. ammonoides Na/Ca to the carbonate system is unlikely to compromise the use of this proxy to reconstruct past [Ca2+sw]. In the case of the low-Mg planktic and benthic foraminifera, a data compilation exercise indicates that no resolvable carbonate chemistry effect exists on Na/Ca. Thus, the Na/Ca proxy in benthic nummulitid and planktic foraminifera can be utilized for past [Ca2+sw] reconstructions. Furthermore, coupling this information with the distribution coefficients of other elemental and isotopic systems (e.g., Li+, Sr2+, Mg2+, K+, B, δ11B) may allow the reconstruction of wider aspects of past ocean chemistry. Finally, comparison of trace and minor element incorporation into low and high-Mg foraminiferal species, coccolithophores, inorganic calcite, and amorphous CaCO3 (ACC), we propose a modified biomineralization model for hyaline foraminifera centered on SW vacuolization. Foraminiferal data can be explained by a biomineralization process in which high-Mg species utilize a precursor phase (ACC) to produce high-Mg calcite whereas low-Mg species actively remove Mg2+ from the site of calcification.
Biomineralization, Carbonate chemistry, Foraminifera, Proxies, Trace elements
105-116
Hauzer, Hagar
68d86aec-9d2c-4c71-9b63-0fedac4ed501
Evans, David
878c65c7-eab9-4362-896b-166e165eb94b
Müller, Wolfgang
360a71f7-0b47-4ff3-8c32-1912d70401aa
Rosenthal, Yair
0130f66f-7653-490b-b323-76956e66c9e1
Erez, Jonathan
ed56a557-377e-4b63-8ba8-3d23e506e5c0
1 February 2025
Hauzer, Hagar
68d86aec-9d2c-4c71-9b63-0fedac4ed501
Evans, David
878c65c7-eab9-4362-896b-166e165eb94b
Müller, Wolfgang
360a71f7-0b47-4ff3-8c32-1912d70401aa
Rosenthal, Yair
0130f66f-7653-490b-b323-76956e66c9e1
Erez, Jonathan
ed56a557-377e-4b63-8ba8-3d23e506e5c0
Hauzer, Hagar, Evans, David, Müller, Wolfgang, Rosenthal, Yair and Erez, Jonathan
(2025)
The effect of carbonate chemistry on trace element incorporation in high-Mg calcitic foraminifera.
Geochimica et Cosmochimica Acta, 390, .
(doi:10.1016/j.gca.2024.11.022).
Abstract
The sodium-to-calcium ratio (Na/Ca) of biogenic CaCO3 has recently been introduced as a proxy for past seawater Ca2+ concentrations ([Ca2+sw]) as demonstrated by a positive correlation between seawater and shell Na/Ca with a minor influence of salinity. In the present study, we investigate the effect of carbonate chemistry on the Na/Ca proxy by conducting a set of experiments in which pH and the concentration of dissolved inorganic carbon (DIC) were independently varied. In addition to Na+, the incorporation of Li+, Mg2+, and Sr2+ into the shells of the large benthic high-Mg calcitic foraminifer Operculina ammonoides was assessed by culturing under constant DIC (∼2170 µmol kg−1) with varying pH (7.5–8.4 NBS scale), and under varying DIC (830–2470 µmol kg−1) with constant pH (∼7.9). Foraminiferal growth rate correlates linearly with calcite saturation state (Ω) of the experimental seawater (SW). The lowest pH and DIC experiments were characterized by low population growth rates, and some of these specimens died and their shells partially dissolved. Na/Cashell and Li/Cashell in O. ammonoides are positively correlated with SW [CO32–] and Ω, whereas Sr/Cashell and Mg/Cashell are much less sensitive to these parameters. The relative sensitivity of Na/Cashell to Ω in O. ammonoides is ∼ 4 % per Ω unit. However, given that past changes in surface water Ω were probably small relative to changes in [Ca2+sw] the correction for this secondary effect over the Cenozoic is likely to be small. Therefore, we conclude that the sensitivity of O. ammonoides Na/Ca to the carbonate system is unlikely to compromise the use of this proxy to reconstruct past [Ca2+sw]. In the case of the low-Mg planktic and benthic foraminifera, a data compilation exercise indicates that no resolvable carbonate chemistry effect exists on Na/Ca. Thus, the Na/Ca proxy in benthic nummulitid and planktic foraminifera can be utilized for past [Ca2+sw] reconstructions. Furthermore, coupling this information with the distribution coefficients of other elemental and isotopic systems (e.g., Li+, Sr2+, Mg2+, K+, B, δ11B) may allow the reconstruction of wider aspects of past ocean chemistry. Finally, comparison of trace and minor element incorporation into low and high-Mg foraminiferal species, coccolithophores, inorganic calcite, and amorphous CaCO3 (ACC), we propose a modified biomineralization model for hyaline foraminifera centered on SW vacuolization. Foraminiferal data can be explained by a biomineralization process in which high-Mg species utilize a precursor phase (ACC) to produce high-Mg calcite whereas low-Mg species actively remove Mg2+ from the site of calcification.
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Hauzer et al 2025 FINAL
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Accepted/In Press date: 21 November 2024
e-pub ahead of print date: 26 November 2024
Published date: 1 February 2025
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© 2024 Elsevier Ltd
Keywords:
Biomineralization, Carbonate chemistry, Foraminifera, Proxies, Trace elements
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Local EPrints ID: 503003
URI: http://eprints.soton.ac.uk/id/eprint/503003
ISSN: 0016-7037
PURE UUID: c4eba7eb-7f48-4c85-8941-c4420e004899
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Date deposited: 15 Jul 2025 16:57
Last modified: 17 Jul 2025 02:23
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Author:
Hagar Hauzer
Author:
David Evans
Author:
Wolfgang Müller
Author:
Yair Rosenthal
Author:
Jonathan Erez
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