Stratification and mixing of a post-glacial Neoproterozoic ocean: Evidence from carbon and sulfur isotopes in a cap dolostone from northwest China

To improve our knowledge about the geochemical and environmental aftermath of Neoproterozoic global glaciations, we analyzed stable isotopes (δC, δO, δS) and elemental concentrations (Ca, Mg, S, Sr, Fe, andMn) of the∼10-m-thick Zhamoketi cap dolostone atop the Tereeken diamictite in the Quruqtagh area, eastern Chinese Tianshan. Available chemostratigraphic data suggest that the Tereeken diamictite is probably equivalent to the Marinoan glaciation. Our new data indicate that organic and carbonate carbon isotopes of the Zhamoketi cap dolostone show little stratigraphic variations, averaging−28.2‰ and−4.6‰, respectively. In contrast, sulfur isotopes show significant stratigraphic variations. Carbonate associated sulfate (CAS) abundance decreases rapidly in the basal cap dolostone and δSCAS composition varies between +9‰ and +15‰ in the lower 2.5 m. In the overlying interval, CAS abundance remains low while δSCAS rises∼5‰ and variesmore widely between +10‰ and +21‰. The range of δSpy of the cap dolostone overlaps with that of δSCAS, but direct comparison shows that δSpy is typically greater than δ SCAS measured from the same samples. Hypotheses to explain the observations must account for both the remarkable sulfur isotope enrichment of pyrites and the inverse fractionation.We propose that CAS and pyrite were derived from two isotopically distinct reservoirs in a chemically stratified basin or a basin with a sulfate minimum zone. In this model, CAS was derived from shallow, oxic surface waters with moderate sulfate concentration and depleted in S due to the postglacial influx of sulfur from continental weathering. In contrast, pyrite was derived from anoxic bottomwaters (or a sulfate minimum zone) with low sulfate concentration and S enrichment due to long-term syn-glacial sulfate reduction. The rapid shift in CAS abundance and sulfur isotope composition within the cap dolostone is interpreted to reflect the mixing of the two reservoirs after initial deglaciation. Comparison with other post-Marinoan cap carbonates shows significant spatial heterogeneity in δSCAS, which together with strong temporal variation in δSCAS, points to generally low sulfate concentrations in post-Marinoan oceans. © 2007 Elsevier B.V. All rights reserved.