The knowledge of iron biogeochemistry is constrained by paucity in the understanding of its
uptake, transport and the partitioning of the element between different phases, redox states and
coordination sites. The work presented in this thesis describes the optimisation and evaluation of a
Flow Injection Chemiluminescence (FICL) method for the shipboard determination of dissolved
Fe(II) species (< 0.2 µm) in seawater. This includes results from two ship-board trials and a study
of the effects of model ligands on iron redox speciation measurements in natural waters. The
method was also used to determine the distribution of dissolved iron species (< 0.2 µm) in two
contrasting study areas in the North East Atlantic Ocean and for a study of aerosol iron dissolution
in seawater.
The FI-CL method was evaluated and was found to be robust and sensitive, to have low limits o f
detection (5-12 pM) and short analysis times 3 min) suitable for the high resolution spatial and
temporal sampling required for shipboard analysis of Fe(II). A study of the effects of model ligands
on Fe(II) determination revealed no conclusive evidence for significant interference from organic
molecules on the method but Fe(III) in the presence of certain organic molecules had the potential
to cause positive and negative interference in aqueous samples.
Field survey results obtained for a transect between the Bay of Biscay to the coast of the
Netherlands, showed enrichment of dissolved iron (0.7 - 2 nM) on the European continental shelf
in March 2002. Near the shelf break, the iron enriched shelf waters were separated from low iron
open ocean surface waters (0.15 - 0.4 nM) by a well-defined mixing gradient. Elevated dissolved
Fe(II) concentrations (> 100 pM) were observed at the shelf break and during a solar radiation
maximum in the coastal waters of the southern North Sea. These features were attributed to the
dissolution of Fe(II) from anoxic sediments and photoreduction of iron from dissolved and
suspended particles, respectively.
hi the surface waters of the Canary Basin in October 2002, low Fe(II) concentrations that varied
from below the limit of detection of the FI-CL method (< 5 pM) to 60 pM were determined. A
horizontal dissolved iron gradient (0.1 - 1.0 nM) inversely related to distance from the North West
African coast was observed. It was hypothesised that the gradient was caused by the advection of
enriched coastal and upwelled water, rather than by spatial variation in aerosol deposition.
Preliminary aerosol iron dissolution experiments demonstrated the significance of the effect of dust
loading and variation in seawater matrix on iron solubility.
In conclusion, continental margins were found to be a highly significant source of dFe in both
study areas and evidence was found that a major portion comes from the reductive dissolution of
iron in sediments. However, the flux of iron from shelf waters to the open ocean is likely to be
dependant on several factors, such as the direction and magnitude of lateral and axial advection and
the efficiency of scavenging and biological uptake in the surface waters.
Date of Award | 2005 |
---|
Original language | English |
---|
Awarding Institution | |
---|
Determination of Dissolved Iron Speciation in the North East Atlantic Ocean by Flow Injection Chemiluminescence
Ussher, S. (Author). 2005
Student thesis: PhD