Contrasts in the marine inorganic carbon chemistry of the Benguela Upwelling System since the Last Glacial Maximum
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2025-03-25
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Journal Article
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Abstract
Upwelling regions are dynamic systems where relatively cold, nutrient-, and CO2-rich waters reach to the surface from the deep. CO2 sink or source properties of these regions are dependent not only on the dissolved inorganic carbon content of the upwelled waters, but also on the efficiency of the biological carbon pump which constrains the drawdown of atmospheric CO2 in the surface waters. The Benguela Upwelling System (BUS) is a major upwelling region with one of the most productive marine ecosystems today. However, contrasting signals reported on the variation in upwelling intensities based on, for instance, foraminiferal and radiolarian indices over the last glacial cycle indicate that a complete understanding of (local) changes is currently lacking. To reconstruct changes in the CO2 history of the northern Benguela upwelling region over the last 27 kyr, we used a box core (64PE450-BC6) and piston core (64PE450-PC8) from the Walvis Ridge. Here, we apply various temperature and pCO(2) proxies, representing both surface (U-37(k') and delta C-13 of alkenones) and subsurface (Mg Ca and delta B-11 in planktonic foraminiferal shells) processes. Reconstructed pCO(2) records suggest enhanced storage of carbon at depth during the Last Glacial Maximum (LGM). The offset between delta C-13 of planktonic (high delta C-13) and benthic foraminifera (low delta C-13) suggests evidence of a more efficient biological carbon pump, potentially fueled by remote and local iron supply through eolian transport and dissolution in the shelf regions, effectively preventing release of the stored glacial CO2.
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21 (3)
Pages / Article No.
679 - 704
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Copernicus
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08619 - Labor für Ionenstrahlphysik (LIP) / Laboratory of Ion Beam Physics (LIP)