Slow-spreading submarine ridges in the South Atlantic as a significant oceanic iron source

Copyright: 2013 Nature Publishing Group. This is an ABSTRACT ONLY. The definitive version is published in Nature Geoscience, vol. 6(9), pp 775–779 Low levels of the micronutrient iron limit primary production and nitrogen fixation in large areas of the global ocean. The location and magnitude of oce...

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Bibliographic Details
Main Authors: Saito, MA, Noble, AE, Tagliabue, A, Goepfert, TJ, Lamborg, CH, Jenkins, WJ
Format: Article in Journal/Newspaper
Language:English
Published: Nature Publishing Group 2013
Subjects:
East Pacific rise
Hydrothermal plume
Oxidation-Kinetics
Dissolved Iron
Seawater
Micronutrient iron
Nitrogen fixation
South Atlantic Ocean
Mid-Atlantic Ridge
Pacific
Online Access:http://hdl.handle.net/10204/7442
http://www.nature.com/ngeo/journal/v6/n9/full/ngeo1893.html
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Summary:Copyright: 2013 Nature Publishing Group. This is an ABSTRACT ONLY. The definitive version is published in Nature Geoscience, vol. 6(9), pp 775–779 Low levels of the micronutrient iron limit primary production and nitrogen fixation in large areas of the global ocean. The location and magnitude of oceanic iron sources remain uncertain, however, owing to a scarcity of data, particularly in the deep ocean. Although deep-sea hydrothermal vents along fast-spreading ridges have been identified as important contributors to the oceanic iron inventory, slow-spreading ridges, which contribute more than half of the submarine ridge-crest environment, are assumed to be less significant and remain relatively unexplored(2). Here, we present measurements of dissolved iron and manganese concentrations along a full-depth section in the South Atlantic Ocean, running from offshore of Brazil to Namibia. We detect a large dissolved iron-and manganese-rich plume over the slow-spreading southern Mid-Atlantic Ridge. Using previously collected measurements of helium-3 concentrations-a tracer of hydrothermal activity-we calculate the ratio of dissolved iron to hydrothermal helium in the plume waters and find that it is 80-fold higher than that reported for plume waters emanating from faster-spreading ridges in the southeastern Pacific. Only the application of a higher ratio in global ocean model simulations yields iron fluxes from these slow-spreading submarine ridges that are in line with our observations. We suggest that global iron contributions from hydrothermal vents are significantly higher than previously thought, owing to a greater contribution from slow-spreading regions.

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