Surface Ocean Biogeochemistry Regulates the Impact of Anthropogenic Aerosol Fe Deposition on the Cycling of Iron and Iron Isotopes in the North Pacific

D König; T M Conway; D S Hamilton; A Tagliabue

doi:10.1029/2022GL098016

Surface Ocean Biogeochemistry Regulates the Impact of Anthropogenic Aerosol Fe Deposition on the Cycling of Iron and Iron Isotopes in the North Pacific

Geophys Res Lett. 2022 Jul 16;49(13):e2022GL098016. doi: 10.1029/2022GL098016. Epub 2022 Jul 2.

Authors

D König¹, T M Conway², D S Hamilton³, A Tagliabue¹

Affiliations

¹ School of Environmental Sciences University of Liverpool Liverpool UK.
² College of Marine Science University of South Florida St Petersburg FL USA.
³ Department of Earth and Atmospheric Science Cornell University Ithaca NY USA.

Abstract

Distinctively-light isotopic signatures associated with Fe released from anthropogenic activity have been used to trace basin-scale impacts. However, this approach is complicated by the way Fe cycle processes modulate oceanic dissolved Fe (dFe) signatures (δ⁵⁶Fe_diss) post deposition. Here we include dust, wildfire, and anthropogenic aerosol Fe deposition in a global ocean biogeochemical model with active Fe isotope cycling, to quantify how anthropogenic Fe impacts surface ocean dFe and δ⁵⁶Fe_diss. Using the North Pacific as a natural laboratory, the response of dFe, δ⁵⁶Fe_diss, and primary productivity are spatially and seasonally variable and do not simply follow the footprint of atmospheric deposition. Instead, the effect of anthropogenic Fe is regulated by the biogeochemical regime, specifically the degree of Fe limitation and rates of primary production. Overall, we find that while δ⁵⁶Fe_diss does trace anthropogenic input, the response is muted by fractionation during phytoplankton uptake, but amplified by other isotopically-light Fe sources.

Keywords: anthropogenic iron; biogeochemistry; iron isotopes; model; ocean.