Geochemistry and P and Fe fractionation in anoxic sediments

We investigated the phosphorus (P) and iron (Fe) fractionation in four cores with anoxic sediments, deposited during the mid-Cretaceous oceanic anoxic event 2 (~94 Ma) and the Paleocene-Eocene thermal maximum (?55 Ma), that were exposed to oxygen after core recovery. Surprisingly, P associated with...

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Bibliographic Details
Main Authors: Kraal, Peter, Slomp, Caroline P, Forster, Astrid, Kuypers, Marcel MM, Sluijs, Appy
Format: Dataset
Language:English
Published: PANGAEA 2009
Subjects:
207-1260
302-M0004A
41-367
93-603B
ACEX-M4A
Arctic Coring Expedition
ACEX
Arctic Ocean
Calcium carbonate
COMPCORE
Composite Core
Deep Sea Drilling Project
DEPTH
sediment/rock
DRILL
Drilling/drill rig
DSDP
Event label
Exp302
Glomar Challenger
Integrated Ocean Drilling Program / International Ocean Discovery Program
IODP
Iron
Iron/Sulfur ratio
Joides Resolution
Leg207
Leg41
Leg93
North Atlantic/BASIN
North Atlantic Ocean
Ocean Drilling Program
ODP
Phosphorus
authigenic
exchangeable
iron-bound
total
Pyrite
FeS2
Ratio
Vidar Viking
Arctic
North Atlantic
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.783338
https://doi.org/10.1594/PANGAEA.783338
Description
Summary:We investigated the phosphorus (P) and iron (Fe) fractionation in four cores with anoxic sediments, deposited during the mid-Cretaceous oceanic anoxic event 2 (~94 Ma) and the Paleocene-Eocene thermal maximum (?55 Ma), that were exposed to oxygen after core recovery. Surprisingly, P associated with iron oxyhydroxides (Fe-bound P) was a major P phase in these laminated sediments deposited under euxinic conditions. A significant fraction of total Fe was present as (poorly) crystalline ferric Fe. This fraction increased with increasing storage time of the investigated cores. In carbonate-poor samples, Fe-bound P accounted for up to 99% of total P and its abundance correlated with pyrite contents. In samples with higher CaCO3 contents (>5 wt% in the investigated samples), P was mostly present in authigenic Ca-P minerals, irrespective of pyrite contents. We conclude that the P fractionation in anoxic, carbonate-poor, sediments is strongly affected by pyrite oxidation that occurs when these sediments are exposed to oxygen. Pyrite oxidation produces sulfuric acid and iron oxyhydroxides. The abundance of poorly crystalline Fe oxyhydroxides provides further evidence that these were indeed formed through recent (post-recovery) oxidation rather than in situ tens of millions of years ago. The acid dissolves apatite and the released phosphate is subsequently bound in the freshly formed iron oxyhydroxides. Pyrite oxidation thus leads to a conversion of authigenic Ca-P to Fe-bound P. In more calcareous samples, CaCO3 can act as an effective buffer against acidic dissolution of Ca-P minerals. The results indicate that shielding of sediments from atmospheric oxygen is vital to preserve the in situ P fractionation and to enable a valid reconstruction of marine phosphorus cycling based on sediment records.

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