The δ13C in benthic foraminiferal tests of Fontbotia wuellerstorfi (Schwager) Relative to the δ13C of dissolved inorganic carbon in Southern Ocean Deep Water: Implications for glacial ocean circulation models

Abstract

On a transect between 20° and 70°S in the eastern Atlantic Ocean and Weddell Sea, water samples from 19 hydrographic stations and bottom water from 55 surface sediment samples taken with a multiple corer were investigated for the stable carbon isotopic composition of the total dissolved inorganic carbon (δ¹³CΣ_CO2). These measurements were compared to δ¹³C values determined on live specimens of the benthic foraminifer Fontbotia wuellerstorfi and closely related genera from the same stations. In addition, at 16 stations the stable carbon isotope composition of sedimentary organic carbon was measured. General deepwater and bottom‐water mass circulation patterns as inferred from the δ¹³C_ΣCO2 are in close agreement with those known from other nonconservative tracers. Very low δ¹³C values of upper Circumpolar Deep Water (13C_ΣCO2 signal is indicated in the abyssal Weddell Sea. We attribute this to temperature‐dependent fractionation processes during gas exchange of surface waters with the atmosphere at sites of bottom‐water formation. Multiple corer water from the sediment/water interface is slightly δ¹³C depleted relative to deepwater and bottom‐water δ¹³_ΣCO2. The surface sediment organic carbon δ¹³C is 3 to 4‰ lower south of the Polar Front than north of it, and the δ¹³C_org in freshly accumulated phytodetritus is 3 to 4‰ lower than surface sediment organic carbon δ¹³C. Comparison of live F. wuellerstorfi δ¹³C and related genera with bottom‐water δ¹³C_ΣCO2 exhibits at most stations between the Subtropical Front (≈41°S) and the southern boundary of the Antarctic Circumpolar Current (≈55°S) a significant lowering of foraminiferal δ¹³C values. Compilation of a mean last glacial/interglacial δ¹³C amplitude (Δδ¹³C) from six published southern ocean cores results in a shift of −0.99± 0.13‰ PDB; this shift is greater than that in all other regions. However, all of these cores are from positions close to Recent oceanic fronts. Thus, for these peripheral areas of the southern ocean, we suggest about half of the glacial/interglacial shift can be explained by varying frontal zone positions and widths accompanied by a change in mode and height of export production.