Abstract
Abstract. Phosphorus (P) concentrations in sediments are frequently used to reconstruct past environmental conditions in freshwater and marine systems, with high values thought to be indicative of a high biological productivity. Recent studies suggest that the post-depositional formation of vivianite, an iron(II)-phosphate mineral, might significantly alter trends in P with sediment depth. To assess its importance, we investigate a sediment record from the Bornholm Basin that was retrieved during the Integrated Ocean Drilling Program (IODP) Baltic Sea Paleoenvironment Expedition 347 in 2013, consisting of lake sediments overlain by brackish–marine deposits. Combining bulk sediment geochemistry with microanalysis using scanning electron microscope energy dispersive spectroscopy (SEM-EDS) and synchrotron-based X-ray absorption spectroscopy (XAS), we demonstrate that vivianite-type minerals rich in manganese and magnesium are present in the lake deposits just below the transition to the brackish–marine sediments (at 11.5 to 12 m sediment depth). In this depth interval, phosphate that diffuses down from the organic-rich, brackish–marine sediments meets porewaters rich in dissolved iron in the lake sediments, resulting in the precipitation of iron(II) phosphate. Results from a reactive transport model suggest that the peak in iron(II) phosphate originally occurred at the lake–marine transition (9 to 10 m) and moved downwards due to changes in the depth of a sulfidization front. However, its current position relative to the lake–marine transition is stable as the vivianite-type minerals and active sulfidization fronts have been spatially separated over time. Experiments in which vivianite was subjected to sulfidic conditions demonstrate that incorporation of manganese or magnesium in vivianite does not affect its susceptibility to sulfide-induced dissolution. Our work highlights that post-depositional formation of iron(II) phosphates such as vivianite has the potential to strongly alter sedimentary P records particularly in systems that are subject to environmental perturbation, such as a change in primary productivity, which can be associated with a lake–marine transition.
Highlights
Phosphorus (P) is a key nutrient for marine organisms as it is essential for intracellular energy, cell growth and metabolism (Tyrrell, 1999)
We investigate the post-depositional formation of vivianite-type minerals in sediments of a hypoxic basin in the Baltic Sea, the Bornholm Basin
Combining various types of geochemical analyses, we demonstrate that vivianite-type minerals began to precipitate below the lake–marine transition in the Bornholm Basin after the seawater intrusion
Summary
Phosphorus (P) is a key nutrient for marine organisms as it is essential for intracellular energy, cell growth and metabolism (Tyrrell, 1999). In marine waters, dissolved phosphate ( denoted as PO4) is converted into particulate organic P by phytoplankton. Part of this particulate P sinks through the water column as dead organic matter and is deposited onto the seafloor (Ruttenberg, 2003). In surface sediments below oxic bottom waters, PO4 that is released by the decomposition of organic matter typically diffuses back into the water column or is bound to iron oxyhydroxides (Feoxide-bound P). Most Fe oxides are dissolved by dissimilatory Fe(III) reduction or by reactions with hydrogen sulfide (HS−) upon burial (Canfield et al, 1992), thereby releasing PO4 to the porewater.
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