Abstract
Anaerobic oxidation of methane (AOM) is an important process of methane (CH4) removal in sediments. Various studies suggest that AOM coupled to iron oxide (Fe(OH)3) reduction (Fe-AOM) may complement sulfate-driven AOM in CH4-rich sediments. Here, we apply a transient reaction-transport model to depth profiles of key porewater and sediment constituents for a site in the Bothnian Sea where Fe-AOM has been suggested to occur. At the site, increased eutrophication has led to an upward shift of the sulfate-methane transition zone, submerging Fe(OH)3 in a zone with high CH4 concentrations. Fe-AOM is thought to lead to a strong accumulation of dissolved iron (Fe2+) in the porewater. Results of a sensitivity analysis identify three potential controls on the occurrence of Fe-AOM in coastal surface sediments: (1) bottom-water sulfate ( inline image) concentrations, (2) Fe(OH)3 availability, and (3) organic matter (OM) loading. In-situ CH4 production is particularly sensitive to the OM loading and inline image bottom-water concentration, with higher inline image concentrations significantly inhibiting methanogenesis and decreasing the potential rates of Fe-AOM. We find that only environments with a low salinity and a relatively high Fe(OH)3 loading allow for Fe-AOM to occur in surface sediments. This suggests that Fe-AOM in surface sediments is restricted to areas with relatively high rates of sediment deposition such as estuaries and other nearshore systems. By enhancing porewater Fe2+ concentrations in surface sediments and the flux of Fe2+ from sediments to the overlying water, Fe-AOM may contribute to the lateral transfer of iron (“iron shuttling”) from the coastal zone to deep basins.
Original language | English |
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Pages (from-to) | S267-S282 |
Number of pages | 16 |
Journal | Limnology and Oceanography |
Volume | 61 |
Issue number | 51 |
Early online date | 7 Apr 2016 |
DOIs | |
Publication status | Published - Nov 2016 |