Influence of sulfate reduction rates on the Phanerozoic sulfur isotope record

Leavitt, William D.; Halevy, Itay; Bradley, Alexander S.; Johnston, David T.

doi:10.1073/pnas.1218874110

Cited by 288 publications

(292 citation statements)

References 69 publications

(121 reference statements)

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“…This yields δ 34 S pyrite value of −18 ‰, which is in agreement with previous estimates (Strauss, 1997;Seal, 2006;Leavitt et al, 2013). This implies the average offset ( pyr ) between δ 34 S seawater and δ 34 S pyrite of −40 ‰ (VCDT) which is similar to the Cenozoic average (Leavitt et al, 2013).…”

Section: Sulfur Cycle Modelsupporting

confidence: 90%

“…This gives pyr of −50 ‰ for the most severe glaciations (lowest shelf extent) and 35 ‰ for the maximum shelf inundation, which is in line with the Leavitt et al (2013) pyr range of estimates for the past 200 Myr. To test the impact of these temporal variations of pyr , we also run our model with "fixed" pyr of −40 ‰ (our steady state value).…”

Section: Model Forcingsupporting

confidence: 85%

“…This implies the average offset ( pyr ) between δ 34 S seawater and δ 34 S pyrite of −40 ‰ (VCDT) which is similar to the Cenozoic average (Leavitt et al, 2013).…”

Section: Sulfur Cycle Modelmentioning

confidence: 81%

“…The sulfur isotope fractionation is negatively correlated with sedimentation rate (e.g., Goldhaber and Kaplan, 1975), and the recent work by Leavitt et al (2013) has identified a negative correlation between δ 34 S pyrite value and shelf area. Since the shelf area has changed dramatically across glacial-interglacial cycles, it is likely that the offset ( pyr ) between δ 34 S seawater and δ 34 S pyrite values has also changed.…”

Section: Model Forcingmentioning

confidence: 98%

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Pleistocene sediment offloading and the global sulfur cycle

2015

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Abstract. Quaternary sea level fluctuations have greatly affected the sediment budgets of the continental shelves. Previous studies suggested that this caused a considerable increase in the net loss of shelf sediments. Since sediment accumulation and erosion are closely tied to the formation and re-oxidation of pyrite, we use a high-resolution record of sulfur isotope ratios ( 34 S / 32 S) of marine sulfate to evaluate the implications of the so-called "shelf sediment offloading" on the global sulfur cycle. Modeling of our δ 34 S record suggests that erosion during sea level lowstands was only partly compensated by increased sedimentation during times of rising sea level and sea level highstands. Furthermore, our data suggests that shelf systems reached a new equilibrium state about 700 ka, which considerably slowed or terminated shelf sediment offloading.

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Section: Sulfur Cycle Modelsupporting

confidence: 90%

Section: Model Forcingsupporting

confidence: 85%

“…This implies the average offset ( pyr ) between δ 34 S seawater and δ 34 S pyrite of −40 ‰ (VCDT) which is similar to the Cenozoic average (Leavitt et al, 2013).…”

Section: Sulfur Cycle Modelmentioning

confidence: 81%

Section: Model Forcingmentioning

confidence: 98%

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Pleistocene sediment offloading and the global sulfur cycle

2015

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“…Polysulfides are in rapid isotopic equilibrium with S 0 and sulfide (Rickard and Luther, 2007;Amrani and Aizenshtat, 2004b), and a primary control on their δ 34 S value is the isotopic fractionation associated with dissimilatory sulfate reduction. The scale of this fractionation varies with sulfate reduction rate and substrate availability, with faster metabolic rates and higher energetic yields generally producing smaller fractionations (e.g., Sim et al, 2011a;Leavitt et al, 2013). Given abundant sulfate in the water column, sulfate reduction rate should be primarily controlled by OM lability, which decreases with water depth.…”

Section: The S-isotope Composition Of Rapidly Sulfurized Ommentioning

confidence: 99%

Rapid organic matter sulfurization in sinking particles from the Cariaco Basin water column

Raven

Sessions

Adkins

et al. 2016

Geochimica et Cosmochimica Acta

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Organic matter (OM) burial in marine sediments is a potentially important control on global climate and the long-term redox state of the earth's surface. Still, we have only a limited understanding of the processes that stabilize OM and facilitate its preservation in the geologic record. Abiotic reactions with (poly)sulfides can enhance the preservation potential of OM, but for this process to be significant it needs to compete with OM remineralization, the majority of which occurs before sinking particles reach the sea floor. Here we investigate whether OM sulfurization occurs within sinking particles in the Cariaco Basin, a modern sulfidic marine environment with high rates of OM burial.Proto-kerogen in sinking particles is frequently more sulfur-rich and 34 S-depleted than expectations for biomass, with a composition that is difficult to explain by mixing with resuspended or terrigenous material. Instead, it appears that sulfur is being incorporated into OM on a timescale of days in sinking particles. The flux of this abiogenic organic S from particles is equivalent to approximately two-thirds of the total amount of protokerogen S at 10 cm depth in underlying sediments (ODP Core 1002B); after 6000 years of more gradual sulfurization reactions, potential water column sources are still equivalent to nearly half of the total proto-kerogen S in Cariaco sediments. Water column sulfurization is most extensive during periods of upwelling and high primary productivity 2 and appears to involve elemental S, possibly via polysulfides. This process has the potential to deliver large amounts of OM to the sediments by making it less available for remineralization, generating OM-rich deposits. It represents a potentially dynamic sink in the global carbon cycle that can respond to changes in environmental conditions, including the size and intensity of O 2 -depleted environments. Water column OM sulfurization could also have played a more significant role in the carbon cycle during ocean anoxic events, for example during the Cretaceous.

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Biogeochemical sulfur cycling during Cretaceous oceanic anoxic events: A comparison of OAE1a and OAE2

2016

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Biogeochemical sulfur cycling has varied widely over geologic time, mainly in response to changes in primary productivity and organic carbon burial, volcanism, weathering, and evaporite deposition. Several of these processes are explicitly linked to discreet (<1.2 Ma) intervals of widespread organic carbon burial, termed oceanic anoxic events (OAEs). During the Cretaceous, there is a highly distinctive ~4‰ negative excursion in the sulfur isotope composition of seawater sulfate (δ34SSO4) that is bracketed by the two most prominent OAEs (OAE1a and OAE2). This excursion lasted for ~25 Ma and has been variously attributed to enhanced volcanism, changes in weathering, evaporite burial, and/or changes in modes of organic carbon remineralization. We present new high‐resolution carbon and sulfur isotope records from carbonate‐associated sulfate and pyrite for OAE1a and OAE2. OAE1a is characterized by a monotonic decrease in δ34SSO4 values. Both negative and positive δ34SSO4 excursions are associated with OAE2. To refine hypotheses for the observed changes in biogeochemical sulfur cycling associated with these events, we use a simple sulfur isotope box model. Both empirical and modeling results indicate that δ34SSO4 variability was dominated by input fluxes during OAE1a, whereas enhanced volcanism, weathering, and pyrite burial controlled δ34SSO4 records during OAE2. Our analysis supports the conclusion that Cretaceous marine sulfate concentrations were much lower than modern concentrations and indicates that increases in marine sulfate occurred at the onset of both events. We conclude that increases in marine sulfate from low background concentrations, in conjunction with other environmental characteristics, contributed to the development of OAEs.

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Influence of sulfate reduction rates on the Phanerozoic sulfur isotope record

Cited by 288 publications

References 69 publications

Pleistocene sediment offloading and the global sulfur cycle

Pleistocene sediment offloading and the global sulfur cycle

Rapid organic matter sulfurization in sinking particles from the Cariaco Basin water column

Biogeochemical sulfur cycling during Cretaceous oceanic anoxic events: A comparison of OAE1a and OAE2

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