Pore Structure and Migration Ability of Deep Shale Reservoirs in the Southern Sichuan Basin

The migration phenomenon of deep shale gas is a subject that has yet to be fully comprehended, specifically regarding the migration ability of deep shale gas. This study focuses on the Longmaxi Formation in the southern Sichuan Basin, utilizing it as an example. Various experimental techniques, such...

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Published inMinerals (Basel) Vol. 14; no. 1; p. 100
Main Authors Wu, Jianfa, Wu, Qiuzi, Xu, Liang, Yang, Yuran, Liu, Jia, Yin, Yingzi, Jiang, Zhenxue, Tang, Xianglu, Miao, Huan
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.01.2024
Subjects
Adsorption
Calcite
Calcite crystals
Carbon dioxide
Carbonates
Clay minerals
Correlation
Experiments
Fractal analysis
Fractal geometry
Fractals
Heterogeneity
Mathematical analysis
Mercury
Organic matter
Parameters
Permeability
Pore size
Sedimentary rocks
Shale
Shale gas
Shale oils
Shales
Surface area
Temperature gradients
Total organic carbon
China
Sichuan Basin
Tibetan Plateau
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Summary:The migration phenomenon of deep shale gas is a subject that has yet to be fully comprehended, specifically regarding the migration ability of deep shale gas. This study focuses on the Longmaxi Formation in the southern Sichuan Basin, utilizing it as an example. Various experimental techniques, such as temperature-driven nitrogen and carbon dioxide adsorption, high-pressure mercury intrusion, XRD, and TOC analysis, are employed. The goal is to analyze the pore structure and fractal characteristics of the Longmaxi Formation shale. Additionally, the study aims to calculate its Knudsen number based on parameters like temperature gradient and pressure coefficient. The migration ability of the Longmaxi Formation shale in southern Sichuan Basin is also discussed. The results show the following: (1) The pore volume distribution of the Longmaxi Formation shale in the study area ranges from 0.0131 to 0.0364 cm3/g. Mesopores contribute approximately 56% of the pore volume, followed by micropores with a contribution rate of about 26%, and macropores contributing approximately 18%. Additionally, the Longmaxi Formation shale exhibits strong heterogeneity, with the fractal dimension (D1) of mesopores ranging from 2.452 to 2.8548, with an average of 2.6833, and the fractal dimension (D2) of macropores ranging from 2.9626 to 2.9786, averaging 2.9707. (2) The fractal dimensions of shale were significantly influenced by organic matter, inorganic minerals, and pore structure parameters. D1 and D2 were positively correlated with TOC, clay mineral content, and specific surface area, while exhibiting negative correlation with quartz. However, the correlations with calcite content, pore volume, and average pore size were not significant. (3) The proportion of pores satisfying Darcy flow in the Longmaxi Formation shale was approximately 3.7%–11.8%, with an average of 6.6%. Consequently, the migration capability of shale gas can be calculated using Darcy’s law. Furthermore, the migration capability of shale gas is controlled by D2, specifically the surface area, and the connectivity of macropores.
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content type line 14
ISSN:2075-163X
2075-163X
DOI:10.3390/min14010100