中国鄂尔多斯盆地东北部生物成因过程产生的 H2S 驱动沉积黄铁矿多级形成的定量特征研究

IF 2.7 2区 地球科学 Q1 GEOLOGY Sedimentary Geology Pub Date : 2024-11-01 DOI:10.1016/j.sedgeo.2024.106768
Liang Yue, Yangquan Jiao, Liqun Wu, Hui Rong
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引用次数: 0

摘要

与有机物质相关的沉积黄铁矿的 δ34S 负值通常被认为是生物生成过程的结果。然而,人们对细菌介导的同位素值在沉积地层中的分布和演变情况仍然知之甚少。在鄂尔多斯盆地东北部中侏罗世地层中,富黄铁矿结核(PyRNs)大量分布在与煤不整合的砂岩底部,这为定量描述砂岩中受煤中有机质影响的黄铁矿硫同位素和微量元素的分布、形态和组成提供了良好的机会。在距离煤炭 4 米的范围内,共出现了 1007 个 PyRNs。在砂岩中,从下到上,结核的形状在垂直剖面上由椭圆形变为圆形,长度和数量逐渐减少,每增加 1 米,长度和数量分别减少约 45 毫米和约 228 个。显微镜下,黄铁矿呈八面体晶体,微量元素分布图显示黄铁矿呈多级生长(多达十几级),Co、Ni、As、Se 和 Mo 的成分分区明显。钴和镍之间呈正相关,钴/镍比值在 0.06 到 0.45 之间,这表明铁和这些微量元素来自成岩流体。煤中的有机硫作为硫源,被细菌以缓慢的还原速度还原生成 H232S。H232S 向上迁移并与铁反应,在砂岩中形成黄铁矿,导致极低的 δ34S 值(从 -53.9 到 -43.1‰),从核心到边缘,单个颗粒的 δ34S 值逐渐降低,距离煤的距离每增加 1 米,δ34S 值降低 2.2 到 8.8‰。这项研究强调了沉积黄铁矿在矿物学(如数量、大小、形态)和地球化学(微量元素、硫同位素)特征方面的显著变化。研究结果可以将黄铁矿的多级生长与生物分馏联系起来,并为从煤中生物衍生的硫固定在砂岩中提供了新的见解,可用于定量描述全球沉积环境中受有机物控制的沉积矿物的形成过程。
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Quantitative characterization on multistage formation of sedimentary pyrite driven by H2S derived from biogenic process in the northeastern Ordos Basin, China
Negative δ34S values of sedimentary pyrite associated with organic matter are routinely assumed to be the result of biogenic process. However, the distribution and evolution of isotopic values mediated by bacteria across sedimentary strata remains poorly understood. Abundant pyrite-rich nodules (PyRNs) are distributed in the bottom of the sandstone unconformably overlying the coal in middle Jurassic strata in the northeastern Ordos Basin, providing a good opportunity to quantitatively characterize the distribution, morphology and compositions of sulfur isotope and trace element of pyrite in the sandstone influenced by organic matter in the coal. A total of 1007 PyRNs occurs within a range of 4 m from the coal. From bottom to top in the sandstone, the shape of the nodule changes from oval to round on the vertical section, and the length and number gradually decrease at the rate of ~45 mm and ~ 228 for every 1 m increase in distance, respectively. Microscopically, pyrite occurs as euhedral crystals, and trace element mapping reveals multistage growth (up to a dozen times) and a marked compositional zoning with respect to Co, Ni, As, Se and Mo. The positive correlation between Co and Ni, with ratios of Co/Ni ranging from 0.06 to 0.45, indicates that Fe and those trace elements are sourced from diagenetic fluid. The organic sulfur in coal, serving as a sulfur source, is reduced by bacteria to generate H232S at a slow reduction rate. The H232S migrates upwards and reacts with Fe to form pyrite in the sandstone, resulting in extremely low δ34S values (from −53.9 to −43.1 ‰), which gradual decrease both from core to margin in individual grain and at the rate of 2.2 to 8.8 ‰ for every 1 m increase in distance away from the coal. This study highlights the significant variability of mineralogical (e.g., number, size, morphology) and geochemical (trace elements, sulfur isotope) characteristics of sedimentary pyrite. Results allow the relation of multistage growth of pyrite to biogenic fractionation, and provide fresh insights into biogenically derived sulfur from coals to be fixed in sandstones, which can be applied to quantitative characterization of formation processes of sedimentary minerals controlled by organic matter in sedimentary environments worldwide.
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来源期刊
Sedimentary Geology
Sedimentary Geology 地学-地质学
CiteScore
5.10
自引率
7.10%
发文量
133
审稿时长
32 days
期刊介绍: Sedimentary Geology is a journal that rapidly publishes high quality, original research and review papers that cover all aspects of sediments and sedimentary rocks at all spatial and temporal scales. Submitted papers must make a significant contribution to the field of study and must place the research in a broad context, so that it is of interest to the diverse, international readership of the journal. Papers that are largely descriptive in nature, of limited scope or local geographical significance, or based on limited data will not be considered for publication.
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