Sulfur isotopes in rivers: Insights into global weathering budgets, pyrite oxidation, and the modern sulfur cycle

Burke, Andrea; Present, Theodore M.; Paris, Guillaume; Rae, Emily C.M.; Sandilands, Brodie H.; Gaillardet, Jérôme; Peucker‐Ehrenbrink, Bernhard; Fischer, Woodward W.; McClelland, J. W.; Spencer, Robert G. M.; Voß, Britta; Adkins, Jess F.

doi:10.1016/j.epsl.2018.05.022

Cited by 156 publications

(110 citation statements)

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“…The majority of this isotope variability occurs within a single lithologic unit, the TSS, despite all evidence to suggest sulfate is quantitatively derived from pyrite oxidation. This observation implies that riverine sulfate δ 34 S compositions are an insufficient conservative tracer to estimate pyrite vs. evaporite weathering contributions to global fluvial sulfate export (20,56,57). In the TSS alone, MSR appears to increase δ 34 S by ∼ 30‰ within consistently pyrite-dominated lithology; this would traditionally be interpreted as a shift from pyritedominated to evaporite-dominated weathering (57).…”

Section: Resultsmentioning

confidence: 98%

“…This observation implies that riverine sulfate δ 34 S compositions are an insufficient conservative tracer to estimate pyrite vs. evaporite weathering contributions to global fluvial sulfate export (20,56,57). In the TSS alone, MSR appears to increase δ 34 S by ∼ 30‰ within consistently pyrite-dominated lithology; this would traditionally be interpreted as a shift from pyritedominated to evaporite-dominated weathering (57). Furthermore, downstream Marsyandi River tributary isotope compositions approach median values for global datasets, suggesting that global δ 34 S and δ 18 O distributions may more strongly reflect MSR intensity and secondary sulfur storage in floodplains than weathering lithology.…”

Section: Resultsmentioning

confidence: 99%

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Triple oxygen isotope insight into terrestrial pyrite oxidation

Hemingway

Olson

Turchyn

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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The mass-independent minor oxygen isotope compositions (Δ′17O) of atmospheric O2andCO2are primarily regulated by their relative partial pressures,pO2/pCO2. Pyrite oxidation during chemical weathering on land consumesO2and generates sulfate that is carried to the ocean by rivers. The Δ′17O values of marine sulfate deposits have thus been proposed to quantitatively track ancient atmospheric conditions. This proxy assumes directO2incorporation into terrestrial pyrite oxidation-derived sulfate, but a mechanistic understanding of pyrite oxidation—including oxygen sources—in weathering environments remains elusive. To address this issue, we present sulfate source estimates and Δ′17O measurements from modern rivers transecting the Annapurna Himalaya, Nepal. Sulfate in high-elevation headwaters is quantitatively sourced by pyrite oxidation, but resulting Δ′17O values imply no direct troposphericO2incorporation. Rather, our results necessitate incorporation of oxygen atoms from alternative,17O-enriched sources such as reactive oxygen species. Sulfate Δ′17O decreases significantly when moving into warm, low-elevation tributaries draining the same bedrock lithology. We interpret this to reflect overprinting of the pyrite oxidation-derived Δ′17O anomaly by microbial sulfate reduction and reoxidation, consistent with previously described major sulfur and oxygen isotope relationships. The geologic application of sulfate Δ′17O as a proxy for pastpO2/pCO2should consider both 1) alternative oxygen sources during pyrite oxidation and 2) secondary overprinting by microbial recycling.

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Section: Resultsmentioning

confidence: 98%

Section: Resultsmentioning

confidence: 99%

Triple oxygen isotope insight into terrestrial pyrite oxidation

Hemingway

Olson

Turchyn

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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“…The presence of sulfides in permafrost may therefore alter the balance between H 2 CO 3 -and H 2 SO 4 -driven weathering, with fundamental implications for climate feedbacks (Burke et al, 2018;Torres et al, 2017). Along with carbonate lithologies, shale-which often contains sulfides (Clarke, 1924)-occurs across the Arctic and within Pleistocene glacial limits (Hartmann & Moosdorf, 2012;Kokelj, Lantz, et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Mineral Weathering and the Permafrost Carbon‐Climate Feedback

Zolkos

Tank

Kokelj

2018

Geophysical Research Letters

109

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Permafrost thaw in the Arctic enables the biogeochemical transformation of vast stores of organic carbon into carbon dioxide (CO 2 ). This CO 2 release has significant implications for climate feedbacks, yet the potential counterbalance from CO 2 fixation via chemical weathering of minerals exposed by thawing permafrost is entirely unstudied. We show that thermokarst in the western Canadian Arctic can enable rapid weathering of carbonate tills, driven by sulfuric acid from sulfide oxidation. Unlike carbonic acid-driven weathering, this caused significant and previously undocumented CO 2 production and outgassing in headwater streams. Increasing riverine solute fluxes correspond with long-term intensification of thermokarst and reflect the regional predominance of sulfuric acid-driven carbonate weathering. We conclude that thermokarst-enhanced mineral weathering has potential to profoundly disrupt Arctic freshwater carbon cycling. While thermokarst and sulfuric acid-driven carbonate weathering in the western Canadian Arctic amplify CO 2 release, regional variation in sulfide oxidation will moderate the effects on the permafrost carbon-climate feedback.Plain Language Summary In the Arctic, perennially frozen ground (permafrost) in previously glaciated regions stores abundant minerals and is often ice-rich. Therefore, this permafrost can rapidly thaw and collapse, resulting in thermokarst and exposing minerals to breakdown by chemical weathering. Mineral weathering by carbonic acid fixes CO 2 , making it less likely to enter the atmosphere. However, the effect of thermokarst on mineral weathering, carbon cycling, and rising atmospheric CO 2 levels is unknown. We show thermokarst enhances weathering in streams in the western Canadian Arctic can rapidly produce significant and previously undocumented CO 2 because carbonate weathering in this region is driven by sulfuric acid (from weathering of sulfide minerals) instead of carbonic acid. Long-term river chemistry reveals that this weathering is intensifying as thermokarst accelerates. Across the Arctic, increasing thermokarst will profoundly impact freshwater carbon cycling, yet the influence of weathering on climate feedbacks will depend on regional variation in the mineral composition of permafrost soils. À

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“…Microbial sulfate reduction (MSR), reoxidation of sulfide, and the burial and oxidation of pyrite govern sedimentary inorganic carbon and alkalinity fluxes (Ben-Yaakov, 1973;Froelich et al, 1979). Pyrite in sedimentary rocks may be exposed and oxidized during uplift, erosion, and weathering-impacting Earth's dioxygen and carbon dioxide budgets on tectonic timescales (Burke et al, 2018;Kump & Garrels, 1986;M. A. Torres et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Variability in sulfur isotope records of Phanerozoic seawater sulfate

Present

Adkins

Fischer

2020

Preprint

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Key Points  6710 measurements of δ 34 S of sulfate in Phanerozoic sedimentary rocks were compiled and systematically updated to a consistent time scale  Records derived from evaporites, barite, and carbonate-associated sulfate are similar, but also contain dramatic short-term discrepancies  Variation created by diagenetic and depositional processes increases with age in all records, obscuring temporal trends in marine sulfate Plain Language Summary Sedimentary rocks deposited in ancient marine basins preserve a record of seawater composition. We compare the sulfur isotopic composition of three sedimentary materials that contain sulfatea major ion in seawater important for carbon and oxygen cycling. Evaporite salts, the mineral barite, and trace sulfate in limestone each reveal the same first-order trends over the last 541 million years, but also display substantial shorter order discrepancies that reflect how the materials capture and store paleooceanographic information. These discrepancies partially obscure understanding of the relationship between life, ocean chemistry, and climate.

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Sulfur isotopes in rivers: Insights into global weathering budgets, pyrite oxidation, and the modern sulfur cycle

Cited by 156 publications

References 50 publications

Triple oxygen isotope insight into terrestrial pyrite oxidation

Triple oxygen isotope insight into terrestrial pyrite oxidation

Mineral Weathering and the Permafrost Carbon‐Climate Feedback

Variability in sulfur isotope records of Phanerozoic seawater sulfate

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