Deconvolving microbial and environmental controls on marine sedimentary pyrite sulfur isotope ratios
Bryant, R.N.; Houghton, J.L.; Jones, C.; Pasquier, V.; Halevy, I.; Fike, D.A. (2023). Deconvolving microbial and environmental controls on marine sedimentary pyrite sulfur isotope ratios. Science (Wash.) 382(6673): 912-915. https://dx.doi.org/10.1126/science.adg6103
In: Science (Washington). American Association for the Advancement of Science: New York, N.Y. ISSN 0036-8075; e-ISSN 1095-9203, more
Related to:Halevy, I.; Fike, D.A.; Pasquier, V.; Bryant, R.N.; Wenk, C.B.; Turchyn, A.V.; Johnston, D.T.; Claypool, G.E. (2023). Sedimentary parameters control the sulfur isotope composition of marine pyrite. Science (Wash.) 382(6673): 946-951. https://dx.doi.org/10.1126/science.adh1215, more
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| Authors | | Top |
- Bryant, R.N.
- Houghton, J.L.
- Jones, C.
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- Pasquier, V.
- Halevy, I.
- Fike, D.A.
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| Abstract |
Reconstructions of past environmental conditions and biological activity are often based on bulk stable isotope proxies, which are inherently open to multiple interpretations. This is particularly true of the sulfur isotopic composition of sedimentary pyrite (δ34Spyr), which is used to reconstruct ocean-atmosphere oxidation state and track the evolution of several microbial metabolic pathways. We present a microanalytical approach to deconvolving the multiple signals that influence δ34Spyr, yielding both the unambiguous determination of microbial isotopic fractionation (εmic) and new information about depositional conditions. We applied this approach to recent glacial-interglacial sediments, which feature over 70‰ variations in bulk δ34Spyr across these environmental transitions. Despite profound environmental change, εmic remained essentially invariant throughout this interval and the observed range in δ34Spyr was instead driven by climate-induced variations in sedimentation. |
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