Early diagenesis of sulfur in Bornholm Basin sediments: The role of upward diffusion of isotopically 'heavy' sulfide

Autor:	Alexandra V. Turchyn, Sabine Kasten, Jiarui Liu, Bo Barker Jørgensen, André Pellerin, Hans Røy, Shuhei Ono, Alyssa Findlay, Gareth Izon, Gilad Antler
Rok vydání:	2021
Předmět:	Baltic Sea 010504 meteorology & atmospheric sciences Sulfide chemistry.chemical_element engineering.material 01 natural sciences Marine sediments 03 medical and health sciences chemistry.chemical_compound δ34S Isotope fractionation Geochemistry and Petrology Oxygen isotopes of sulfate 14. Life underwater Multiple sulfur isotopes Sulfate 030304 developmental biology 0105 earth and related environmental sciences chemistry.chemical_classification 0303 health sciences Biogeochemical sulfur cycle Pyrite Sulfur cycle Sulfur Sulfide minerals chemistry 13. Climate action Environmental chemistry engineering
Zdroj:	Liu, J, Pellerin, A, Antler, G, Izon, G, Findlay, A J, Røy, H, Ono, S, Kasten, S, Turchyn, A V & Jørgensen, B B 2021, ' Early diagenesis of sulfur in Bornholm Basin sediments : The role of upward diffusion of isotopically “heavy” sulfide ', Geochimica et Cosmochimica Acta, vol. 313, pp. 359-377 . https://doi.org/10.1016/j.gca.2021.08.018
ISSN:	0016-7037
DOI:	10.1016/j.gca.2021.08.018
Popis:	Sediment-hosted marine sulfur cycling has played a significant role in regulating Earth's surface chemistry over our planet's history. Microbially-mediated reactions involving sulfur are often accompanied by sulfur isotope fractionation that, in turn, is captured by sulfate and sulfide minerals, providing the opportunity to track changes in the microbial utilization of sulfur and thus the marine sulfur cycle. Studying sulfur diagenesis within the Bornholm Basin, Baltic Sea, we explore the interplay between carbon, sulfur and iron, focusing on the fate of sulfur and the dynamics of the sulfur and oxygen isotopic response as a function of the varying thickness of the organic carbon-rich Holocene Mud Layer (HML) across the basin. Using a one-dimensional reaction-transport model, porewater sulfate and sulfide profiles were used to calculate net sulfate reduction rates (SRR) and net sulfide production rates, respectively. These calculations suggest a positive relationship between the thickness of the HML and net rates of sulfate reduction and sulfide production. Given that ascending sulfide is enriched in 34S relative to that produced in-situ, a heightened sulfide flux promotes spatially variable precipitation of 34S-enriched pyrite (δ34S ≈ −10‰) close to the sediment–water interface. Modeling results indicate that this isotopically “heavy” sulfide is formed as a consequence of mixing between ascending sulfide (up to +6.3‰) and that produced in-situ (ca. −40‰). Further, we show that the sulfur and oxygen isotopic composition of porewater sulfate is controlled by the net SRR: when the net SRR is high (i.e., in sulfide-replete settings) the downcore increase in δ18OSO4 is dampened relative to increase in δ34SSO4, whereas when net SRR is low (i.e., in iron-rich parts of the basin) downcore δ18OSO4 values increase while δ34SSO4 values remain invariant. We conclude that sedimentation rates and open system diffusion strongly influence the distribution of sulfur species and their sulfur isotopic composition, as well as the oxygen isotopic composition of sulfate, through the interaction between iron, sulfur and methane. This work highlights the importance of considering diffusion to better understand open system diagenesis and the δ34S signatures of sulfate and sulfide in both modern settings and ancient rocks.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::f7a4b16e50890c422ee4c42ebf50b2ec https://doi.org/10.1016/j.gca.2021.08.018 Zobrazit plný text záznamu Full Text from ScienceDirect