Tag Archive for: GEOTRACES

The unaccounted dissolved iron (II) sink: Insights from dFe(II) concentrations in the deep Atlantic Ocean

Abstract

Hydrothermal vent sites found along mid-ocean ridges are sources of numerous reduced chemical species and trace elements. To establish dissolved iron (II) (dFe(II)) variability along the Mid Atlantic Ridge (between 39.5°N and 26°N), dFe(II) concentrations were measured above six hydrothermal vent sites, as well as at stations with no active hydrothermal activity. The dFe(II) concentrations ranged from 0.00 to 0.12 nmol L−1 (detection limit = 0.02 ± 0.02 nmol L−1) in non-hydrothermally affected regions to values as high as 12.8 nmol L−1 within hydrothermal plumes. Iron (II) in seawater is oxidised over a period of minutes to hours, which is on average two times faster than the time required to collect the sample from the deep ocean and its analysis in the onboard laboratory. A multiparametric equation was used to estimate the original dFe(II) concentration in the deep ocean. The in-situ temperature, pH, salinity and delay between sample collection and its analysis were considered. The results showed that dFe(II) plays a more significant role in the iron pool than previously accounted for, constituting a fraction >20 % of the dissolved iron pool, in contrast to <10 % of the iron pool formerly reported. This discrepancy is caused by Fe(II) loss during sampling when between 35 and 90 % of the dFe(II) gets oxidised. In-situ dFe(II) concentrations are therefore significantly higher than values reported in sedimentary and hydrothermal settings where Fe is added to the ocean in its reduced form. Consequently, the high dynamism of dFe(II) in hydrothermal environments masks the magnitude of dFe(II) sourced within the deep ocean.

Highlights

  • Considering oxidation, open ocean iron (II) concentrations are below 0.2 nmol L−1.
  • The highest measured iron (II) concentration was 69.6 nmol L−1 at the Rainbow vent.
  • In the open ocean iron (II) account for 20 % of the dissolved iron pool.
  • Oxygen variations within OMZ account for 60 % of iron(II) oxidation variability.

Reference

Gonzalez-Santana, D.; Lough, A. J. M.; Planquette, H.; Sarthou, G.; Tagliabue, A.; Lohan, M. C. The Unaccounted Dissolved Iron (II) Sink: Insights from DFe(II) Concentrations in the Deep Atlantic Ocean. Sci. Total Environ. 2023, 862, 161179.

https://doi.org/10.1016/j.scitotenv.2022.161179.

Links between biogeochemical cycles of metals and living organisms

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Improving our knowledge of the metal cycle in contrasting environments of the world ocean is absolutely necessary for a better understanding of the oceanic biogeochemical cycles of major elements (C, Si, N, S) and the biological carbon pump. LEMAR is internationally recognised in this field, in particular through our strong involvement in the GEOTRACES programme. We combine observations, field or laboratory experiments and modelling. Our originality lies in the combined study of the dissolved and particulate phases, as well as their speciation (redox and organic), in order to better understand the interactions between these two reservoirs, which are fundamental in the metal cycle and yet are still little studied. Our expertise also includes the study of interactions between the metal cycle and plankton, by linking metal speciation to the bioavailability of micronutrients for marine plankton (phytoplankton and bacteria). The integration of omics tools (functional genomics, transcriptomics, etc.) into this theme is currently essential to further investigate the link between biogeochemical cycles of metals and interactions with living organisms. These explorations will continue to be carried out, both during oceanographic missions and in laboratory studies, notably thanks to our numerous international collaborations and our involvement in the future international programme BioGeoSCAPES (‘Ocean metabolism and nutrient cycles on a changing planet’). The strong international momentum of the GEOTRACES programme and the forthcoming BioGeoSCAPES programme now allows us to build and meet the challenge of integrated microbial biogeochemistry projects that require international coordination with a multidisciplinary approach.

Tag Archive for: GEOTRACES

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