Abstract
Iron is a scarce but essential micronutrient in the oceans that limits primary productivity in many regions of the surface ocean. The mechanisms and rates of Fe supply to the ocean interior are still poorly understood and quantified. Iron isotope ratios of different Fe pools can potentially be used to trace sources and sinks of the global Fe biogeochemical cycle if these boundary fluxes have distinct signatures. Seafloor hydrothermal vents emit metal rich fluids from mid-ocean ridges into the deep ocean. Iron isotope ratios have the potential to be used to trace the input of hydrothermal dissolved iron to the oceans if the local controls on the fractionation of Fe isotopes during plume dispersal in the deep ocean are understood. In this study we assess the behaviour of Fe isotopes in a Southern Ocean hydrothermal plume using a sampling program of Total Dissolvable Fe (TDFe), and dissolved Fe (dFe). We demonstrate that δ56Fe values of dFe (δ56dFe) within the hydrothermal plume change dramatically during early plume dispersal, ranging from −2.39±0.05‰ to −0.13±0.06‰ (2 SD). The isotopic composition of TDFe (δ56TDFe) was consistently heavier than dFe values, ranging from −0.31±0.03‰ to 0.78±0.05‰, consistent with Fe oxyhydroxide precipitation as the plume samples age. The dFe present in the hydrothermal plume includes stabilised dFe species with potential to be transported to the deep ocean. We estimate that stable dFe exported from the plume will have a δ56Fe of −0.28±0.17‰. Further, we show that the proportion of authigenic iron-sulfide and iron-oxyhydroxide minerals precipitating in the buoyant plume exert opposing controls on the resultant isotope composition of dissolved Fe passed into the neutrally buoyant plume. We show that such controls yield variable dissolved Fe isotope signatures under the authigenic conditions reported from modern vent sites elsewhere, and so ought to be considered during iron isotope reconstructions of past hydrothermalism from ocean sediment records.
Highlights
Iron (Fe) is a key micronutrient that often limits primary productivity in high nutrient low chlorophyll zones of the surface ocean and has an indirect influence on the biological carbon pump (Martin, 1990)
Concentrations of dissolved Fe (dFe), Dissolved Mn (dMn), dCu, dZn and dV in the vent fluids were similar in all samples, with relative standard deviations (RSD) typically
Consistent with experimental work (Bullen et al, 2001; Welch et al, 2003; Butler et al, 2005) and the isotope composition of particulate Fe in hydrothermal plumes (Severmann et al, 2004; Bennett et al, 2009), our results show that Fe oxyhydroxide precipitation produces lighter values for residual d56Fe values of dFe (d56dFe), while the respective d56TDFe is isotopically heavier due to the preferential settling of isotopically light Fe sulphide minerals from the Total Dissolvable Fe (TDFe) pool during plume dispersal (Fig. 6a and b)
Summary
Iron (Fe) is a key micronutrient that often limits primary productivity in high nutrient low chlorophyll zones of the surface ocean and has an indirect influence on the biological carbon pump (Martin, 1990). For this reason it is important to understand the biogeochemical cycle of Fe in the marine environment. A consequence of this is that Fe is a limiting nutrient in areas where other key nutrients are abundant, such as the Southern Ocean (Moore et al, 2013)
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