Organic complexation of iron in
The chemical speciation of iron was determined in the Southern Ocean along a transect from 48 to 703S at 203E. Dissolved iron concentrations were low at 0.1}0.6 nM, with average concentrations of 0.25$0.13 nM. Organic iron complexing ligands were found to occur in excess of the dissolved iron concen...
| Main Authors: | , |
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| Format: | Text |
| Language: | English |
| Published: |
2001
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| Online Access: | http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.567.426 http://www.liv.ac.uk/~sn35/Documents/Papers/Boye et al DSR 2001.pdf |
| Summary: | The chemical speciation of iron was determined in the Southern Ocean along a transect from 48 to 703S at 203E. Dissolved iron concentrations were low at 0.1}0.6 nM, with average concentrations of 0.25$0.13 nM. Organic iron complexing ligands were found to occur in excess of the dissolved iron concentration at 0.72$0.23 nM (equivalent to an excess of 0.5 nM), with a complex stability of logK "22.1$0.5 (on the basis of Fe and L). Ligand concentrations were higher in the upper water column (top 200m) suggesting in situ production by microorganisms, and less at the surface consistent with photochemical breakdown. Our data are consistent with the presence of stable organic iron-complexing ligands in deep global ocean waters at a background level of&0.7 nM. It has been suggested that this might help stabilise iron at levels of &0.7 nM in deep ocean waters. However, much lower iron concentrations in the waters of the Southern Ocean suggest that these ligands do not prevent the removal of iron (by scavenging or biological uptake) to well below the concentration of these ligands. Scavenging reactions are probably inhibited by such ligand competition, so it is likely that biological uptake is the chief cause for the further removal of iron to these low levels in waters that su!er from very low iron inputs. 2001 Elsevier Science Ltd. All rights reserved. |
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