Iron-binding ligand production and copper speciation in an incubation experiment of Antarctic Peninsula shelf waters from the Bransfield Strait, Southern Ocean

The evolution of dissolved iron (Fe) and copper (Cu) speciation was followed through a simulated spring bloom event in a 15-day incubation experiment of natural seawater collected during austral winter from high macronutrient high Fe waters of Bransfield Strait in the Southern Ocean. The incubation...

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Bibliographic Details
Published in:Marine chemistry 2010-10, Vol.122 (1), p.148-159
Main Authors: Buck, Kristen N., Selph, Karen E., Barbeau, Katherine A.
Format: Article
Language:English
Subjects:
Bottles
Chemical speciation
Control equipment
Copper
Dissolution
Earth sciences
Earth, ocean, space
Exact sciences and technology
External geophysics
Geochemistry
Incubation
Iron
Ligands
Marine
Mineralogy
Physical and chemical properties of sea water
Physics of the oceans
Seawater
Silicates
Southern Ocean
Speciation
Straits
Water geochemistry
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Summary:The evolution of dissolved iron (Fe) and copper (Cu) speciation was followed through a simulated spring bloom event in a 15-day incubation experiment of natural seawater collected during austral winter from high macronutrient high Fe waters of Bransfield Strait in the Southern Ocean. The incubation experiment included unamended bottles as well as Fe additions using the stable isotope of Fe, 57Fe, as inorganic ( 57FeCl 3) and organic ( 57Fe-aerobactin, 57Fe-desferrioxamine B) amendments. Exposure to summer light conditions resulted in substantial growth for all treatments, mimicking the initiation of a spring bloom. The addition of Fe resulted in a 30% increase in phytoplankton biomass over unamended controls by day 15, indicating that the unamended waters became Fe limited despite initially elevated dissolved Fe concentrations. Dissolved Cu and Cu speciation remained largely unchanged for all treatments of the incubation, with Cu speciation dominated by exceedingly strong Cu-binding ligands (log K CuL 1, Cu 2+ cond ~ 16) and low resultant Cu 2+ concentrations (10 − 16.3 ± 0.3 mol L − 1 ). In only the unamended light bottles, strong Fe-binding ligands were produced over the course of the experiment. The observed production of strong Fe-binding ligands in the control bottles that became Fe-limited supports the important role of biologically produced siderophore-type natural ligands in the marine Fe cycle.
ISSN:0304-4203
1872-7581
DOI:10.1016/j.marchem.2010.06.002