Modelling the Effects of Non-Steady State Transport Dynamics on the Sulfur and Oxygen Isotope Composition of Sulfate in Sedimentary Pore Fluids

Fotherby, Angus; Bradbury, Harold J.; Antler, Gilad; Sun, Xiaole; Druhan, Jennifer L.; Turchyn, Alexandra V.

doi:10.3389/feart.2020.587085

Cited by 8 publications

(11 citation statements)

References 101 publications

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“…It appears that the oxygen isotopic composition of sulfate may increase slightly faster than the sulfur isotopic composition of sulfate at Site 11 (Figure 4A). At one of the sites with piston core data (Site 9; 2,323 mbsl) we note that the cross plot of δ 34 S SO4 vs. δ 18 O SO4 (Figure 4A) comes out of the apparent linear phase, where the sulfur and oxygen isotopic compositions covary, and into the equilibration phase, where δ 18 O SO4 has reset through oxygen isotope equilibrium with water intracellularly and does not change further as the δ 34 S SO4 values continue to increase (Antler et al, 2014;Antler and Pellerin, 2018;Fotherby et al, 2021). The carbon isotope composition of the DIC decreases with depth as expected from the oxidation of organic carbon and the return of 12 C-rich carbon to the DIC pool (Figures 2G,H).…”

Section: Resultsmentioning

confidence: 87%

The Carbon-Sulfur Link in the Remineralization of Organic Carbon in Surface Sediments

et al. 2021

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Here we present the carbon isotopic composition of dissolved inorganic carbon (DIC) and the sulfur isotopic composition of sulfate, along with changes in sulfate concentrations, of the pore fluid collected from a series of sediment cores located along a depth transect on the Iberian Margin. We use these data to explore the coupling of microbial sulfate reduction (MSR) to organic carbon oxidation in the uppermost (up to nine meters) sediment. We argue that the combined use of the carbon and sulfur isotopic composition, of DIC and sulfate respectively, in sedimentary pore fluids, viewed through a δ13CDIC vs. δ34SSO4 cross plot, reveals significant insight into the nature of carbon-sulfur coupling in marine sedimentary pore fluids on continental margins. Our data show systemic changes in the carbon and sulfur isotopic composition of DIC and sulfate (respectively) where, at all sites, the carbon isotopic composition of the DIC decreases before the sulfur isotopic composition of sulfate increases. We compare our results to global data and show that this behavior persists over a range of sediment types, locations and water depths. We use a reactive-transport model to show how changes in the amount of DIC in seawater, the carbon isotopic composition of organic matter, the amount of organic carbon oxidation by early diagenetic reactions, and the presence and source of methane influence the carbon and sulfur isotopic composition of sedimentary pore fluids and the shape of the δ13CDIC vs. δ34SSO4 cross plot. The δ13C of the DIC released during sulfate reduction and sulfate-driven anaerobic oxidation of methane is a major control on the minimum δ13CDIC value in the δ13CDIC vs. δ34SSO4 cross plot, with the δ13C of the organic carbon being important during both MSR and combined sulfate reduction, sulfate-driven AOM and methanogenesis.

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Section: Resultsmentioning

confidence: 87%

The Carbon-Sulfur Link in the Remineralization of Organic Carbon in Surface Sediments

et al. 2021

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“…3). Compared to the range of  34 S SO4 and  18 O values in modern sediment pore waters where microbial sulfate reduction is active (blue area in figure 3) (Fotherby et al, 2021), the range of  34 S SO4 corresponding to Primary Lower Gypsum and Upper Gypsum deposits is limited (Fig. 3).…”

Section: Analytical Resultsmentioning

confidence: 89%

The geochemical riddle of “low-salinity gypsum” deposits

Aloisi

Guibourdenche

Natalicchio

et al. 2022

Geochimica et Cosmochimica Acta

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“…Other processes are known to have an effect on the

{δ^{18} O}_{{italicSO}_{4}}

vs.

{δ^{34} S}_{{italicSO}_{4}}

plot such as the sulfide and pyrite oxidation (Balci et al, 2007) and disproportionation (Böttcher et al, 2001, 2005); however, their effect should only decrease the relative estimated calculated rates of MSR. Additionally, it was shown that when the sulfate reduction rates are high (i.e., the

{δ^{18} O}_{{italicSO}_{4}}

vs.

{δ^{34} S}_{{italicSO}_{4}}

slope is low), the effect of transport such as diffusion and sedimentation is negligible on the measured slope (Fotherby et al, 2020). Such a plot can be adapted to the form of (

{δ^{18} O}_{{italicSO}_{4}}

‐

{δ^{18} O}_{{SO}_{4}, 0}

) vs. (

{δ^{34} S}_{{italicSO}_{4}}

‐

{δ^{34} S}_{{SO}_{4}, 0}

), where

{δ^{18} O}_{{SO}_{4}, 0}

and

{δ^{34} S}_{{SO}_{4}, 0}

are the initial SO 4 2− isotope values, thereby negating the “source effect” and allowing data with a linear relationship from various aquatic and subsurface environments beyond the Dead Sea to be compared (e.g., lakes, seas, estuaries, and salt marshes) (Figure 4).…”

Section: Resultsmentioning

confidence: 99%

“…Other processes are known to have an effect on the δ 18 O SO 4 vs. δ 34 S SO 4 plot such as the sulfide and pyrite oxidation (Balci et al, 2007) and disproportionation (Böttcher et al, 2001(Böttcher et al, , 2005; however, their effect should only decrease the relative estimated calculated rates of MSR. Additionally, it was shown that when the sulfate reduction rates are high (i.e., the δ 18 O SO 4 vs. δ 34 S SO 4 slope is low), the effect of transport such as diffusion and sedimentation is negligible on the measured slope (Fotherby et al, 2020). Such a plot can be adapted to the form of (δ Stable δ 34 S SO 4 and δ 18 O SO 4 from primary gypsum layers found in the Dead Sea sedimentary record were also used to investigate rates of MSR using a similar isotope plot given that the effect of isotope fractionation during gypsum precipitation has a negligible effect on the slope (Torfstein & Turchyn, 2017).…”

Section: Sulfatementioning

confidence: 99%

Intensified microbial sulfate reduction in the deep Dead Sea during the early Holocene Mediterranean sapropel 1 deposition

et al. 2022

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The hypersaline Dead Sea and its sediments are natural laboratories for studying extremophile microorganism habitat response to environmental change. In modern times, increased freshwater runoff to the lake surface waters resulted in stratification and dilution of the upper water column followed by microbial blooms. However, whether these events facilitated a microbial response in the deep lake and sediments is obscure. Here we investigate archived evidence of microbial processes and changing regional hydroclimate conditions by reconstructing deep Dead Sea chemical compositions from pore fluid major ion concentration and stable S, O, and C isotopes, together with lipid biomarkers preserved in the hypersaline deep Dead Sea ICDP-drilled core sediments dating to the early Holocene (ca. 10,000 years BP). Following a significant negative lake water balance resulting in salt layer deposits at the start of the Holocene, there was a general period of positive net water balance at 9500-8300 years BP.The pore fluid isotopic composition of sulfate exhibit evidence of intensified microbial sulfate reduction, where both δ 34 S and δ 18 O of sulfate show a sharp increase from estimated base values of 15.0‰ and 13.9‰ to 40.2‰ and 20.4‰, respectively, and a δ 34 S vs. δ 18 O slope of 0.26. The presence of the n-C 17 alkane biomarker in the sediments suggests an increase of cyanobacteria or phytoplankton contribution to the bulk organic matter that reached the deepest parts of the Dead Sea. Although hydrologically disconnected, both the Mediterranean Sea and the Dead Sea microbial ecosystems responded to increased freshwater runoff during the early Holocene, with the former depositing the organic-rich sapropel 1 layer due to anoxic water column conditions. In the Dead Sea prolonged positive net water balance facilitated primary production and algal blooms in the upper waters and intensified microbial sulfate reduction in the hypolimnion and/or at the sediment-brine interface.

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Modelling the Effects of Non-Steady State Transport Dynamics on the Sulfur and Oxygen Isotope Composition of Sulfate in Sedimentary Pore Fluids

Cited by 8 publications

References 101 publications

The Carbon-Sulfur Link in the Remineralization of Organic Carbon in Surface Sediments

The Carbon-Sulfur Link in the Remineralization of Organic Carbon in Surface Sediments

The geochemical riddle of “low-salinity gypsum” deposits

Intensified microbial sulfate reduction in the deep Dead Sea during the early Holocene Mediterranean sapropel 1 deposition

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