Iron monosulfide accumulation and pyrite formation in eutrophic estuarine sediments
Publication date
2013
Authors
Kraal, P.
Burton, E.D.
Bush, R.T.
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Advisors
Supervisors
Document Type
Article
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(c) UU Universiteit Utrecht, 2013
Abstract
This study investigates iron (Fe) and sulfur (S) cycling in sediments from the eutrophic Peel–Harvey Estuary in Western
Australia, which is subject to localized accumulation of strongly reducing, organic- and sulfide-rich sediments. Sedimentary
iron was mostly present in highly reactive form (on average 73% of total Fe) and showed extensive sulfidization even in surface
sediments, despite being overlain by a well-mixed oxygenated water column. This indicates that, under eutrophic marine
conditions, Fe sulfidization may be driven by reductive processes in the sediment without requiring oxygen depletion in the
overlying waters. Strong enrichments in iron monosulfide (FeS > 300 lmol g 1) were observed in fine-grained sediment intervals
up to 45 cm depth. This metastable Fe sulfide is commonly restricted to thin subsurface sediment intervals, below which
pyrite (FeS2) dominates. Our findings suggest inhibition of the dissolution–precipitation processes that replace FeS with FeS2
in sediments. Rates of pyrite formation based on the FeS2 profiles were much lower than those predicted by applying commonly
used kinetic equations for pyrite formation. Dissolved H2S was present at millimolar levels throughout the investigated
sediment profiles. This may indicate that (i) pyrite formation via reaction between dissolved Fe (including Fe clusters) and
H2S was limited by low availability of dissolved Fe or (ii) reaction kinetics of pyrite formation via the H2S pathway may
be relatively slow in natural reducing sediments. We propose that rapid burial of the FeS under anoxic conditions in these
organic-rich reducing sediments minimizes the potential for pyrite formation, possibly by preventing dissolution of FeS or
by limiting the availability of oxidized sulfur species that are required for pyrite formation via the polysulfide pathway.