Micro-Scale Sulfur and Carbon Isotope Analysis of a Neoarchean Stromatolite: Evidence for a Profound Redox Transition in Shelf Margins prior to the Great Oxidation Event
Abstract
Neoarchean shelf margin environments such as the Campbellrand-Malmani platform are believed to have been sites of substantial O2 accumulation and nutrient cycling prior to the Great Oxidation Event (GOE). Stromatolites in particular serve as biogeochemical "hotspots" where evidence of various metabolic pathways and bacterial lineages can be traced through geochemical fingerprints. We identified morphologically-unique, organic-rimmed pyrite grains embedded in the dolomitic lamina of a Campbellrand Subgroup stromatolite (2.6 Ga). Carbon and sulfur isotopes measured in situ revealed a multi-layered microbial community employing photoautotrophic carbon fixation, organic matter respiration, sulfate reduction, and potentially assimilation of methane. In particular, unusually high kerogen δ13Corg and pyrite δ34S compositions are consistent with a semi-aerobic ecosystem recycling photosynthetic biomass and sulfate reduction in sulfate-limited porewaters, respectively. In addition, an array of positive Δ33S values suggests incorporation of atmospherically-derived sulfur formed from volcanic SO2 photochemistry and isolated in particulate form. We argue the Δ33S-δ34S trend is best explained by mixing between a δ34S-enriched coastal marine sulfate reservoir and stratospheric Δ33S-positive sulfate or elemental sulfur aerosols. The hypothesized buildup of sulfur gases at higher altitudes agrees with prior arguments for increased subaerial felsic volcanism and intense plume activity coinciding with oxidation of the upper mantle. We suggest explosive subaerial eruptions sustained a stratospheric SO2 reservoir that underwent photochemistry via long-wavelength (250-330 nm) UV radiation to produce positive MIF-carrying aerosol particles (sulfate or sulfur) in the Neoarchean. This contrasts with Paleoarchean sulfur chemistry dominated by SO2 photolysis in the 190-220 nm excitation band and points to an evolving Archean atmosphere, culminating in a coupled biogeochemical-tectonic redox transformation that fundamentally changed the atmospheric sulfur cycle and ultimately prompted the GOE.
- Publication:
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AGU Fall Meeting Abstracts
- Pub Date:
- December 2016
- Bibcode:
- 2016AGUFM.V21B..07I
- Keywords:
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- 1030 Geochemical cycles;
- GEOCHEMISTRYDE: 1031 Subduction zone processes;
- GEOCHEMISTRYDE: 1032 Mid-oceanic ridge processes;
- GEOCHEMISTRYDE: 1033 Intra-plate processes;
- GEOCHEMISTRY