Modeling of Burial History, Source Rock Maturity, and Hydrocarbon Generation of Marine-Continental Transitional Shale of the Permian Shanxi Formation, Southeastern Ordos Basin

Cheng, Ming; Li, Chao; Yin, Jintao; Wang, Peng; Hu, Caizhi; Yu, Yuxi; Lei, Yuhong; Zhang, Likuan

doi:10.1021/acsomega.4c01725

ACS Omega

2024

DOI: 10.1021/acsomega.4c01725

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Modeling of Burial History, Source Rock Maturity, and Hydrocarbon Generation of Marine-Continental Transitional Shale of the Permian Shanxi Formation, Southeastern Ordos Basin

Ming Cheng,

Chao Li,

Jintao Yin

et al.

Abstract: The Ordos Basin is characterized by abundant natural gas resources, and the marine-continental transitional shale gas of the Permian Shanxi Formation has great exploration and development potential. However, few systematic studies have focused on the burial history, thermal maturity, and hydrocarbon generation of the shale, which limits the understanding of shale gas enrichment and resource evaluation. To reveal the shale gas resource potential, we focused on the Shanxi Formation shale in the southeastern Ordo… Show more

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Cited by 3 publications

References 47 publications

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Organic richness and maturity modeling of cretaceous age Chichali shales for enhanced hydrocarbon exploration in Punjab platform, Pakistan

Ahmad,

Hajana,

Akhtar

2024

J Petrol Explor Prod Technol

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Organic richness and maturity modeling of cretaceous age Chichali shales for enhanced hydrocarbon exploration in Punjab platform, Pakistan

Ahmad,

Hajana,

Akhtar

2024

J Petrol Explor Prod Technol

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Lithofacies and Its Reservoir Characteristics of Marine–Continental Transitional Shales: A Case Study of Shanxi Formation in Eastern Ordos Basin

Xue,

Dang,

Zhang

et al. 2024

Energy Fuels

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Marine−continental transitional shale is a significant target for shale gas exploration and development in China. However, current research on the lithofacies and the geological characteristics of these transitional shales is limited, constraining efficient exploration and development in the future. This study examines the S 2 3 submember of the Permian Shanxi Formation in the Daning-Jixian area, which is located on the eastern margin of the Ordos Basin. To identify the various shale lithofacies types, we employed a series of experimental methods, including organic geochemistry, mineral composition analysis, thin-section identification, scanning electron microscopy, and gas adsorption, to systematically analyze the reservoir characteristics of these lithofacies. By integrating sedimentary structures, total organic carbon (TOC) content, and mineral components, we categorized the S 2 3 submember shale into 24 distinct lithofacies, of which 8 types are dominated. They are laminated organic-rich clay shale, laminated organic-rich siltstone, laminated medium organic-rich clay shale, laminated organic-poor clay shale, blocky medium organic-rich clay shale, blocky organic-poor clay shale, blocky organicpoor silty clay shale, and blocky organic-poor siltstone. These lithofacies show considerable variations in reservoir development characteristics, with laminated organic-rich clay shale demonstrating superiority in TOC content, specific surface area, pore diameter, and porosity, thereby emerging as the optimal lithofacies for shale gas exploration and development.

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Source Rock Assessment of the Permian to Jurassic Strata in the Northern Highlands, Northwestern Jordan: Insights from Organic Geochemistry and 1D Basin Modeling

Hamdy,

Farouk,

Qteishat

et al. 2024

Minerals

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The present study focused on the Permian to Jurassic sequence in the Northern Highlands area, NW Jordan. The Permian to Jurassic sequence in this area is thick and deeply buried, consisting mainly of carbonate intercalated with clastic shale. This study integrated various datasets, including total organic carbon (TOC, wt%), Rock-Eval pyrolysis, visual kerogen examination, gross composition, lipid biomarkers, vitrinite reflectance (VRo%), and bottom-hole temperature measurements. The main aim was to investigate the source rock characteristics of these strata regarding organic richness, kerogen type, depositional setting, thermal maturity, and hydrocarbon generation timing. The Permian strata are poor to fair source rocks, primarily containing kerogen type (KT) III. They are immature in the AJ-1 well and over-mature in the NH-2 well. The Upper Triassic strata are poor source rocks in the NH-1 well and fair to marginally good source rocks in the NH-2 well, containing highly mature terrestrial KT III. These strata are immature to early mature in the AJ-1 well and at the peak oil window stage in the NH-2 well. The Jurassic strata are poor source rocks, dominated by KT III and KT II-III. They are immature to early mature in the AJ-1 well and have reached the oil window in the NH-2 well. Biomarker-related ratios indicate that the Upper Triassic oils and Jurassic samples are source rocks that received mainly terrestrial organic input accumulated in shallow marine environments under highly reducing conditions. These strata are composed mostly of clay-rich lithologies with evidence of deposition in hypersaline and/or stratified water columns. 1D basin models revealed that the Upper Triassic strata reached the peak oil window from the Early Cretaceous (~80 Ma) to the present day in the NH-1 well and from ~130 Ma (Early Cretaceous) to ~90 Ma (Late Cretaceous) in the NH-2 well, with the late stage of hydrocarbon generation continuing from ~90 Ma to the present time. The present-day transformation ratio equals 77% in the Upper Triassic source rocks, suggesting that these rocks have expelled substantial volumes of hydrocarbons in the NH-2 well. To achieve future successful hydrocarbon discoveries in NW Jordan, accurate seismic studies and further geochemical analyses are recommended to precisely define the migration pathways.

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Modeling of Burial History, Source Rock Maturity, and Hydrocarbon Generation of Marine-Continental Transitional Shale of the Permian Shanxi Formation, Southeastern Ordos Basin

Cited by 3 publications

References 47 publications

Organic richness and maturity modeling of cretaceous age Chichali shales for enhanced hydrocarbon exploration in Punjab platform, Pakistan

Organic richness and maturity modeling of cretaceous age Chichali shales for enhanced hydrocarbon exploration in Punjab platform, Pakistan

Lithofacies and Its Reservoir Characteristics of Marine–Continental Transitional Shales: A Case Study of Shanxi Formation in Eastern Ordos Basin

Source Rock Assessment of the Permian to Jurassic Strata in the Northern Highlands, Northwestern Jordan: Insights from Organic Geochemistry and 1D Basin Modeling

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