Review on the physical chemistry of iodine transformations in the oceans

The transformation between iodate ( IO 3 − ), the thermodynamically stable form of iodine, and iodide (I - ), the kinetically stable form of iodine, has received much attention because these species are often dependent on the oxygen concentration, which ranges from saturation to non-detectable in th...

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Bibliographic Details
Published in:Frontiers in Marine Science 2023-02, Vol.10
Main Author: Luther, George W.
Format: Article
Language:English
Subjects:
Algae
Carbonate minerals
Carbonates
Chemical reduction
Chemistry
iodate
Iodates
iodide
Iodides
Iodine
iodine intermediates
Kinetics
Manganese
Nitrate reductase
Nitrogen dioxide
Oceans
Organic matter
Oxidants
Oxidation
Oxidizing agents
Oxygen
Reactive oxygen species
reduction
Salinity
Saturation
Sea surface
Seawater
Surface microlayer
Surface microlayers
Thermodynamics
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Summary:The transformation between iodate ( IO 3 − ), the thermodynamically stable form of iodine, and iodide (I - ), the kinetically stable form of iodine, has received much attention because these species are often dependent on the oxygen concentration, which ranges from saturation to non-detectable in the ocean. As suboxic conditions in the ocean’s major oxygen minimum zones indicate that IO 3 − is minimal or non-detectable, the incorporation of IO 3 − into carbonate minerals has been used as a redox proxy to determine the O 2 state of the ocean. Here, I look at the one and two electron transfers between iodine species with a variety of oxidants and reductants to show thermodynamics of these transformations. The IO 3 − to IO 2 − conversion is shown to be the controlling step in the reduction reaction sequence due to thermodynamic considerations. As IO 3 − reduction to IO 2 − is more favorable than NO 3 − reduction to NO 2 − at oceanic pH values, there is no need for nitrate reductase for IO 3 − reduction as other reductants (e.g. Fe 2+ , Mn 2+ ) and dissimilatory IO 3 − reduction by microbes during organic matter decomposition can affect the transformation. Unfortunately, there is a dearth of information on the kinetics of reductants with IO 3 − ; thus, the thermodynamic calculations suggest avenues for research. Conversely, there is significant information on the kinetics of I - oxidation with various oxygen species. In the environment, I - oxidation is the controlling step for oxidation. The oxidants that can lead to IO 3 − are reactive oxygen species with O 3 and •OH being the most potent as well as sedimentary oxidized Mn, which occurs at lower pH than ocean waters. Recent work has shown that iodide oxidizing bacteria can also form IO 3 − . I - oxidation is more facile at the sea surface microlayer and in the atmosphere due to O 3 .
ISSN:2296-7745
2296-7745
DOI:10.3389/fmars.2023.1085618