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Benthic iron flux influenced by climate-sensitive interplay between organic carbon availability and sedimentation rate in Arctic fjords

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  • Lisa C. Herbert, Stony Brook University, Rutgers University
  • ,
  • Qingzhi Zhu, Stony Brook University
  • ,
  • Alexander B. Michaud, Bigelow Laboratory for Ocean Sciences
  • ,
  • Katja Laufer-Meiser, Aarhus Universitet, Helmholtz Centre for Ocean Research Kiel
  • ,
  • Christopher K. Jones, Oklahoma State University, University of California at Riverside
  • ,
  • Natascha Riedinger, Oklahoma State University
  • ,
  • Zachery S. Stooksbury, University of Tennessee, Knoxville
  • ,
  • Robert C. Aller, Stony Brook University
  • ,
  • Bo Barker Jørgensen
  • Laura M. Wehrmann, Stony Brook University

Benthic iron (Fe) fluxes from continental shelf sediments are an important source of Fe to the global ocean, yet the magnitude of these fluxes is not well constrained. Processing of Fe in sediments is of particular importance in the Arctic Ocean, which has a large shelf area and Fe limitation of primary productivity. In the Arctic fjords of Svalbard, glacial weathering delivers high volumes of Fe-rich sediment to the fjord benthos. Benthic redox cycling of Fe proceeds through multiple pathways of reduction (i.e., dissimilatory iron reduction and reduction by hydrogen sulfide) and re-oxidation. There are few estimates of the magnitude and controlling factors of the benthic Fe flux in Arctic fjords. We collected cores from two Svalbard fjords (Kongsfjorden and Lilliehöökfjorden), measured dissolved Fe2+ concentrations using a two-dimensional sensor, and analyzed iron, manganese, carbon, and sulfur species to study benthic Fe fluxes. Benthic fluxes of Fe2+ vary throughout the fjords, with a “sweet spot” mid-fjord controlled by the availability of organic carbon linked to sedimentation rates. The flux is also impacted by fjord circulation and sea ice cover, which influence overall mineralization rates in the sediment. Due to ongoing Arctic warming, we predict an increase in the benthic Fe2+ flux with reduced sea ice cover in some fjords and a decrease in the Fe2+ flux with the retreat of tidewater glaciers in other regions. Decreasing benthic Fe2+ fluxes in fjords may exacerbate Fe limitation of primary productivity in the Arctic Ocean.

TidsskriftLimnology and Oceanography
Sider (fra-til)3374-3392
Antal sider19
StatusUdgivet - sep. 2021

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