Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
8910640 | Geochimica et Cosmochimica Acta | 2018 | 52 Pages |
Abstract
We demonstrate that the potential of pore water δ56Fe as a proxy for benthic Fe fluxes is not straight-forward due to its large variability in marine shelf sediments at small spatial scales (â2.4â° at the site proximal to oxic meltwater discharge vs. â0.9â° at the site proximal to the marine glacier terminus, both at 2â¯cm sediment depth). The controlling factors are multifold and include the amount and reactivity of reducible Fe oxides and organic matter, the isotopic composition of the primary and secondary ferric substrates, sedimentation rates, and physical reworking (bioturbation, ice scraping). The application of δ56Fe geochemistry may prove valuable in investigating biogeochemical weathering and Fe cycling in subglacial environments. This requires, however (similarly to the use of δ56Fe for the quantification of benthic fluxes), that the spatial and temporal variability of the isotopic endmember is known and accounted for. Since geochemical data from subglacial environments are very limited, further studies are needed in order to sufficiently assess Fe cycling and fractionation at glacier beds and the composition of discharges from those areas.
Related Topics
Physical Sciences and Engineering
Earth and Planetary Sciences
Geochemistry and Petrology
Authors
Susann Henkel, Sabine Kasten, Jan F. Hartmann, Adrián Silva-Busso, Michael Staubwasser,