Isotopically light Mo in sediments of methane seepage controlled by the benthic Fe–Mn redox shuttle process

Isotopically light Mo in sediments of methane seepage controlled by the benthic Fe–Mn redox shuttle process

Methane seepage has been extensively observed in various continental margin settings. It has profound effects on the marine redox environment and the molybdenum (Mo) cycles in marine sediments. Therefore, there has been much recent attention on the redox-sensitive behavior of Mo in methane seepage e...

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Bibliographic Details
Published in:Global and planetary change Vol. 239; p. 104512
Main Authors: Miao, Xiaoming, Wei, Jiangong, Li, Jingrui, Liu, Xiting, Wang, Dong, Li, Jie, Feng, Xiuli
Format: Journal Article
Language:English
Published: Elsevier B.V 01-08-2024
Subjects:
Fe-Mn shuttle
Iron isotope
Methane seepage
Molybdenum isotope
Redox
Sediment
Molybdenum isotope
Redox
Methane seepage
Sediment
Fe-Mn shuttle
Iron isotope
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Summary:Methane seepage has been extensively observed in various continental margin settings. It has profound effects on the marine redox environment and the molybdenum (Mo) cycles in marine sediments. Therefore, there has been much recent attention on the redox-sensitive behavior of Mo in methane seepage environments. However, the characteristics of the Mo isotope composition in the cold-seep system remain poorly understood. In this study, we performed geochemical analyses, including Mo content and isotope composition, on sediment samples (core QDN-MS6) from the “Haima” cold-seep deposit area in the South China Sea. The analysis reveals a significant concentration of authigenic pyrite in the mid-section of QDN-MS6 core (373–403 cm). Moreover, the δ34S value in this interval is notably elevated with high total sulfur/total organic carbon ratio. Additionally, the sediments in the mid-section exhibits substantial enrichment in Mo (enrichment factors of Mo ranging from 5.29 to 39.32). This implies that the sediments in the mid-section are influenced by sulfate-driven anaerobic oxidation of methane. Most notably, the sediments in the mid-section displayed distinct low δ98Mo values (with an average of −0.7‰). After careful consideration, we ruled out the influence of organic matter, an oxic environment, a weakly sulfidic environment, and incomplete removal of thiopolybdate as contributing factors. Based on δ56Fe-Fe/Al ratios, (Mo–U) enrichment factors, and As enrichment factors, we propose that the “benthic Fe-Mn redox shuttle process” is the primary cause of the observed light δ98Mo signatures in sediments. This newly identified mechanism sheds light on Mo isotope cycling in methane seepage environments and enhances our understanding of the Mo isotope cycling process. •δ34S and enrichment of Mo and U indicated sulfate-driven anaerobic oxidation of methane in the 373–403 cm section.•Clear low δ98Mo and δ56Fe characteristics were evident in the sediments of methane seepage.•The reductive dissolution of Fe and Mn (oxy)hydroxides was the main driver of low δ98Mo.•The benthic Fe–Mn redox shuttle process is an important contributor to the Mo source in methane seepage environments.
ISSN:0921-8181
1872-6364
DOI:10.1016/j.gloplacha.2024.104512