Iron is an essential micronutrient for the metabolism of marine organisms and
impacts on primary productivity and hence indirectly on climate change. The dominant
source of iron to the sea surface in open ocean regions is from the atmosphere by aeolian
dust transport but the solubility of iron from dust is poorly constrained. In this thesis,
chemical and physical factors impacting on the process of dust dissolution and iron
release in seawater were investigated using FI-CL detection.
A manual FI manifold was automated and optimised for the determination of iron,
at nanomolar concentrations, released from aerosols in seawater. The limit of detection
was 0.04 ± 0.03 nM and the precision (rsd) ranged from 0.2 to 10.8%. Protocols,
maintenance find troubleshooting sections were documented for effective utilisation o f the
technique. A seawater treatment system to produce low DOC (dissolved organic carbon)
and dFe (dissolved iron) seawater was adapted and optimised. This UV photo-oxidation
system was poorly efficient in removing DOC (-40%), complexing ligands (~60%) and
dFe (apparent removal 90%).
An autosampler was designed, validated, and integrated with an incubation system
for sub-sampling during dissolution experiments of aerosol iron in seawater. Fast release
of iron f r om the aerosol particles occurred within the first 2 h, followed by a decrease over
1 day. Preliminary experiments w i t h UV-irradiated seawater exhibited lower solubilities
compared w i t h non UV-irradiated seawater. High dust concentrations gave lower final
solubilities compared with low dust concentrations. A 24 h kinetic study was carried out
using NIST 1648 under contrasting light and dark regimes. Dissolution of the endmember
under dark conditions released 0.36% of the iron whilst the addition of 20 nM to
200 nM Desferrioxamine B (DFOB) stimulated a release of 0.90 to 1.6%. In light, the
release of iron was 0.50% with aerosol, whilst the addition of DFOB (20 nM) induced an
adsorption (-1.18%).
Iron release from aerosol samples from three sites around the Eastern
Mediterranean: Erdemli, Tel-Shikmona and Heraklion was determined in a NATO
funded project. The solubility of contrasting aerosol populations from crustal and
anthropogenic sources was investigated. Crustally derived aerosol samples exhibited a
variable kinetic profile of iron release with an average of maximum solubility of 0.39 ±
0.52%. The anthropogenically influenced aerosol samples exhibited consistent kinetic
profiles (fast release < 2 h) with an average of maximum solubility of 10.6 ± 8.9%. From
these results, an approximation of the atmospheric dry inputs of soluble iron in seawater
to the Levantine Basin was calculated for the first time, ranging from 804 ± 910 t for the
Northern Levantine Basin to 2,670 ± 3,050 t for the Southern Levantine Basin.
Date of Award | 2008 |
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Original language | English |
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Awarding Institution | |
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DISSOLUTION OF AEROSOL IRON IN SEA WATER USING FLOW-INJECTION WITH CHEMILUMINESCENCE DETECTION
SEGURET, M. J. M. (Author). 2008
Student thesis: PhD