The purpose of this study is to examine the mechanism
of photo-oxidation of natural dissolved organic matter
(DOM)
in the presence of iron. This process is of interest
in
natural waters for several reasons: as a significant
sink
of DOM in sunlit surface waters; as a source and sink
of reactive oxygen species
(HO2/O2
•-, hydrogen
peroxide,
and HO•) and as a factor controlling iron
speciation.
Studies were conducted in laboratory model systems
containing fulvic acid and lepidocrocite (γ-FeOOH)
particles at pH 3 and pH 5, irradiated with simulated
sunlight.
Measured concentrations of dissolved Fe(II), total
dissolved
Fe, and hydrogen peroxide were interpreted as the net
effects of competing reactions reducing and oxidizing Fe
and
producing and destroying hydrogen peroxide. A kinetic
model constructed using information gained from separate
experiments in simpler systems was used to assess the
relative importance of individual reactions. Comparison
of
photoreductive dissolution rates in aerated and de-aerated
systems at pH 3 and pH 5 indicated that the decrease in
rate
with increasing pH is mostly due to a decrease in the
concentration of surface Fe(III)−fulvate complexes and
that,
in the presence of oxygen, some of the surface Fe(II) is
re-oxidized (not necessarily by oxygen) before detachment
can take place. Kinetic modeling indicated that fast
redox
cycling of Fe occurs at both pH values. The dark
reduction
of Fe(III) by fulvic acid and photochemical
ligand-to-metal
charge transfer reactions of dissolved
Fe(III)−fulvate
complexes play almost equally significant roles in the
reduction
of dissolved Fe(III). The main oxidants of dissolved
Fe(II)
are HO2/O2
•-
(produced via reduction of O2 by
photo-excited fulvic acid) and hydrogen peroxide [the
product of Fe(II) reaction with
HO2/O2
•-].
Iron redox cycling can catalyze the oxidation of humic substances and increase the rate of oxygen consumption in surface waters rich in iron and organic carbon. This study examines the role of Fenton's reaction [oxidation of Fe(II) by hydrogen peroxide] in this catalytic cycle. A number of competing processes were observed in model systems containing dissolved Fe, hydrogen peroxide, and Suwannee River fulvic acid. First, the effective rate constant of Fenton's reaction increased with increasing fulvic acid concentration, indicating the formation of Fe(II)-fulvate complexes that react more rapidly with hydrogen peroxide than Fe(II)-aquo complexes. This effect was significant at pH 5 but negligible at pH 3. A second effect was scavenging of the HO • radical produced in Fenton's reaction by fulvic acid, forming an organic radical. The organic radical reduced oxygen to HO 2 • /O 2 •-, which then regenerated hydrogen peroxide by reaction with Fe(II). Finally, Fe(III) was reduced by a dark reaction with fulvic acid, characterized by an initially fast reduction followed by slower processes. The behavior of Fe(II) and hydrogen peroxide over time in the presence of fulvic acid and oxygen could be described by a kinetic model taking all of these reactions into account. The net result was an iron redox cycle in which hydrogen peroxide as well as oxygen were consumed (even though direct oxidation of Fe(II) by oxygen was not significant), and the oxidation of fulvic acid was accelerated.
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