Paleoenvironmental Transition during the Rhuddanian–Aeronian and Its Implications for Lithofacies Evolution and Shale Gas Exploration: Insights from the Changning Area, Southern Sichuan Basin, South-West China

IF 2.2 4区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS
Minerals Pub Date : 2024-09-18 DOI:10.3390/min14090949
Hangyi Zhu
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引用次数: 0

Abstract

During the Rhuddanian–Aeronian interglacial period, global geological events such as glacial melting, synsedimentary volcanic activity, biological resurgence, and large-scale marine transgressions caused frequent fluctuations in paleoproductivity, climate changes, and sea level variations. These paleoenvironmental transitions directly influenced the development characteristics of shale lithofacies. This study investigates the Longmaxi Formation shale in the Changning area in the Southern Sichuan basin, focusing on 28 core samples from Well N1. Using scanning electron microscopy, QEMSCAN, TOC, XRD, and major and trace element analyses, we reconstructed the paleoenvironmental transitions of this period and explored their control over shale lithofacies types and mineral compositions. Four shale lithofacies were identified: carbonate rich lithofacies (CRF), biogenic quartz-rich lithofacies (BQRF), detrital clay-rich lithofacies (CRDF), and detrital quartz-rich lithofacies (DQRF). During the Rhuddanian period, rising global temperatures caused glacial melting and rapid marine transgressions. The low oxygen levels in bottom waters, combined with upwelling and abundant volcanic material, led to high paleoproductivity. This period primarily developed BQRF and CRF. Rich nutrients and abundant siliceous organisms, along with anoxic to anaerobic conditions, provided the material basis and preservation conditions for high biogenic quartz and organic matter content. High paleoproductivity and anoxic conditions also facilitated the precipitation of synsedimentary calcite and supplied Mg2⁺ and SO₄2⁻ for the formation of iron-poor dolomite via sulfate reduction. From the Late Rhuddanian to the Mid-Aeronian, the Guangxi orogeny caused sea levels to fall, increasing water oxidation and reducing upwelling and volcanic activity, which lowered paleoproductivity. Rapid sedimentation rates, stepwise global temperature increases, and the intermittent intensification of weathering affected terrigenous clastic input, resulting in the alternating deposition of CRF, CRDF, and DQRF. Two favorable shale gas reservoirs were identified from the Rhuddanian–Aeronian period: Type I (BQRF) in the L1–L3 Layers, characterized by high TOC and brittleness, and Type II (DQRF) in the L4 Layer, with significant detrital quartz content. The Type I-favorable reservoir supports ongoing gas production, and the Type II-favorable reservoir offers potential as a future exploration target.
白垩纪-新生代古环境转变及其对岩相演化和页岩气勘探的影响:中国西南四川盆地南部长宁地区的启示
在 Rhuddanian-Aeronian 间冰期,冰川融化、合成火山活动、生物复苏和大规模海侵等全球地质事件导致古生产率频繁波动、气候变化和海平面变化。这些古环境的转变直接影响了页岩岩相的发育特征。本研究以四川盆地南部长宁地区龙马溪地层页岩为研究对象,重点研究了N1井的28个岩心样品。利用扫描电子显微镜、QEMSCAN、TOC、XRD以及主要和微量元素分析,我们重建了这一时期的古环境转换,并探讨了它们对页岩岩相类型和矿物组成的控制。我们确定了四种页岩岩相:富含碳酸盐的岩相(CRF)、富含生物石英的岩相(BQRF)、富含碎屑粘土的岩相(CRDF)和富含碎屑石英的岩相(DQRF)。在 Rhuddanian 时期,全球气温升高导致冰川融化和快速的海洋断裂。底层水的含氧量很低,再加上上升流和丰富的火山物质,导致了很高的古生产率。这一时期主要发育了BQRF和CRF。丰富的营养物质和大量的硅质生物,以及缺氧到厌氧条件,为高生物石英和有机质含量提供了物质基础和保存条件。高古生产力和缺氧条件还促进了合成方解石的沉淀,并为通过硫酸盐还原形成贫铁白云岩提供了 Mg2⁺和 SO₄2-。从晚古宙到中新世,广西造山运动导致海平面下降,增加了水的氧化作用,减少了上升流和火山活动,从而降低了古生产率。快速的沉积速率、全球气温的逐步上升以及风化作用的间歇性加剧影响了土著碎屑岩的输入,导致了CRF、CRDF和DQRF的交替沉积。在 Rhuddanian-Aeronian 时期发现了两个有利的页岩气藏:第一类(BQRF)位于 L1 至 L3 层,具有高总有机碳和脆性的特点;第二类(DQRF)位于 L4 层,含有大量的碎屑石英。I 型有利储层支持目前的天然气生产,而 II 型有利储层则有可能成为未来的勘探目标。
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来源期刊
Minerals
Minerals MINERALOGY-MINING & MINERAL PROCESSING
CiteScore
4.10
自引率
20.00%
发文量
1351
审稿时长
19.04 days
期刊介绍: Minerals (ISSN 2075-163X) is an international open access journal that covers the broad field of mineralogy, economic mineral resources, mineral exploration, innovative mining techniques and advances in mineral processing. It publishes reviews, regular research papers and short notes. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced.
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