Iron is an essential micronutrient for the growth of planktonic species. It is an integral element of
numerous enzymes and proteins with important functions in photosynthesis and respiratory
electron transport. In contrast to iron, hydrogen peroxide (H202 is ubiquitous in seawater.
Phytoplankton are known to generate reactive oxygen species (ROS) such as superoxide and
H202 . This production, in conjunction with membrane bound reductases, may affect an
organism's ability to access nutrients such as iron. The work presented in this thesis describes the
development and optimisation of sensitive flow injection-chemiluminescence techniques to assess
redox processes at the cellular level and their application to investigate marine processes.
Two flow injection methods, one based on direct sample injection and another involving the preconcentration
of iron, were used to determine iron(II) and dissolved iron and assess potential
interference from a number of metals and H202. The results demonstrated the increased
oxidation of Fe(II) in the presence of H202 (half life reduced from 10.4 to 3.5 min at 50 nM
H202 and confirmed the ability of the pre-concentration method to remove this matrix
interference. The accuracy and precision of the pre-concentration method were confirmed
through analysis of samples collected on two international intercomparison studies. The results
demonstrated that the method was precise (- 8 %RSD) and provided a suitably low limit of
detection (17 pM) for the determination of dissolved iron.
Dust deposition is an important source of iron to remote open ocean regions. The solubility of
iron and aluminium in North Atlantic waters was assessed through an on-deck dissolution
experiment. Calculated solubilities of iron released from six differing dust samples were low and
varied from 0.001 to 0.04 %, whereas the release of aluminium ranged from 0.06 - 9.0 %.
Solubility was inversely correlated with particle concentration, where higher solubility was
observed for lower particle concentrations.
A versatile and adaptable FI system was developed, with a low detection limit (0.4 - 1.3 nM),
excellent precision (1.1 - 1.8 %RSD) and the capability of sensitive real-time determination of
H202 over a wide dynamic range. The results from laboratory based assays using a novel in-line
filter approach demonstrated H202 production by the diatom species Thalassiaira ueiss weissflogii with
observed concentrations in the range 30- 100 nM. In addition, through field studies carried out
in two different oceanic regions (English Channel and Ross Sea), a previously unreported
correlation between phytoplankton biomass and surface H20 1 concentrations was observed.
The FI-CL instrumentation for the determination of Fe(II) was successfully adapted and
optimised for the continuous in-line measurements of Fe(II) generated by diatoms. This
technique provided a low detection limit (11 pM) and excellent precision (6.3 ± 3.2 % RSD). In
further laboratory based assays with T. ueissflogii, preliminary results indicated pM changes in
Fe(II) generation following the reduction of organically bound Fe(Ill).
Date of Award | 2007 |
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Original language | English |
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Awarding Institution | |
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Marine Biogeochemistry Studies of Iron and Hydrogen Peroxide using Flow Injection-Chemiluminescence
Milne, A. (Author). 2007
Student thesis: PhD