鄂尔多斯盆地早侏罗世Toarcian大洋缺氧事件时期湖泊硫循环及其地质意义
- 收稿日期:
2023-08-22
- 网络出版日期:
2023-12-05
摘要: 摘 要 【目的】目前有关鄂尔多斯盆地安崖剖面早侏罗世Toarcian大洋缺氧事件(T-OAE;~183Ma)的研究主要聚焦于古气候条件、沉积环境演化和生物多样性变化等,而对于T-OAE时期湖泊硫循环的机制尚不明确。【方法】为进一步明确其硫循环机制,对安崖剖面泥岩和黑色页岩样品进行岩石学和地球化学分析,利用主、微量元素与黄铁矿硫同位素(δ34Spy)对T-OAE时期硫同位素分馏机制进行探讨。【结果】安崖剖面样品中黄铁矿形态主要为四面体晶型集合形成的草莓状黄铁矿,样品的δ34Spy表现出异常正值(范围为2.7—14.1‰,平均值为8.3‰),根据δ34Spy和TOC的变化并结合地球化学指标(δ13C、TS、Corg/P((La/Th)N)将湖泊沉积环境演化分为四个阶段(富有机质阶段Ⅰ、Ⅱ,贫有机质阶段Ⅰ、Ⅱ)。【结论】鄂尔多斯盆地安崖剖面T-OAE时期δ34Spy值与大气降水和地表径流相吻合,表明湖泊硫的来源主要为水体中的硫酸盐。样品的硫同位素主要由湖泊底水的氧化还原环境以及有机质控制,与沉积速率,硫酸盐浓度无关。当湖泊底水环境富氧和沉积物贫有机质时,溶解氧渗透进沉积物将厌氧氧化剂活化并促进H2S再氧化,通过瑞利分馏模型使δ34Spy正偏。当湖泊环境底水缺氧和沉积物富有机质时,硫酸盐还原细菌活性增强,MSR反应得到促进,优先吸收32S导致δ34Spy负偏。安崖剖面T-OAE时期硫循环主要受到局部/区域环境控制,但硫循环同时还受T-OAE时期全球气候变暖及水文循环加剧等的影响。
Sulfur cycle and its geological significance during T-OAE in Ordos Basin
- Received Date:
2023-08-22
- Available Online:
2023-12-05
Abstract: Abstract: [Objective]Currently, research on the Early Jurassic Toarcian Oceanic Anoxic Event (T-OAE; ~183 Ma) in the Ordos Basin mainly focuses on paleoclimate conditions, sedimentary environment evolution, and biodiversity changes, while the mechanisms of sulfur cycling during the T-OAE period in lakes remain unclear.[Methods]In order to further elucidate the sulfur cycling mechanism, Petrology and Geochemistry analyses were conducted on mudstone and black shale samples from the Anya section. The mechanisms of sulfur isotope fractionation during the T-OAE period were explored using major and trace elements and pyrite sulfur isotopes (δ34Spy).[Results and discussions]The pyrite in the Anya section samples mainly exists in the form of tetrahedral crystals, forming framboidal pyrite. The δ34Spy values of the samples exhibit anomalously positive values (ranging from 2.7 to 14.1‰, with an average of 8.3‰). Based on the variations in δ34Spy and total organic carbon (TOC) in conjunction with geochemical indicators (δ13C, TS, Corg/P, (La/Th)N), the evolution of the lake sedimentary environment during the T-OAE period was divided into four stages (high organic matter stages I and II, low organic matter stages I and II). [Conclusions] The δ34Spy values during the T-OAE period in the Anya section of the Ordos Basin coincide with atmospheric precipitation and surface runoff, indicating that the main source of sulfur in the lake is sulfate in the water mass. The sulfur isotopes of the samples are mainly controlled by the redox conditions of the lake bottom water and organic matter, and are independent of sedimentation rate and sulfate concentration. When the dissolved oxygen in the basin bottom water is low and the organic matter content is high, dissolved oxygen infiltrates into the sediment, activating anaerobic oxidants and promoting the reoxidation of H2S, resulting in positive δ34Spy values through Rayleigh fractionation. When the bottom water environment of the lake is oxygen-rich and the organic matter content is low, dissolved oxygen infiltrates into sediments, activating anaerobic oxidants and promoting H2S reoxidation, leading to a positive δ34Spy shift through the Rayleigh fractionation model. When the bottom water environment of the lake is oxygen-deficient and the organic matter content is high, the activity of sulfate-reducing bacteria is enhanced, promoting the MSR reaction and preferentially incorporating 32S, resulting in a negative δ34Spy shift. The sulfur cycle during the T-OAE period in the Anya section is mainly controlled by local/regional sedimentary environments, but the sulfur cycle is also influenced by global warming and intensified hydrological circulation during the T-OAE period
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