Distribution Prediction of Shale Deformation Structures in Tectonically Complex Area Based on Relationship Between Geological Structures and Shale Deformation

Cheng, Guofeng; Jiang, Bo; Li, Fengli; Li, Ming; Song, Yu

doi:10.3389/feart.2022.813074

Cited by 3 publications

(1 citation statement)

References 40 publications

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“…In addition, artificial uniaxial, multi-axial, hightemperature, and high-pressure deformation tests were utilized to simulate the deformation process and elucidate the dynamic deformation mechanism (Cheng et al, 2021(Cheng et al, , 2022. Cheng et al (2023) used the high-temperature and high-pressure triaxial experimental technique to simulate the structural modification process of shale during the period of tectonic deformation, and at the same time, obtained some rock mechanical parameters, such as compressive strength, Poisson's ratio, Young's modulus, shear strength, and brittle-ductile conversion.…”

Section: Tectonic Activity and Shale Deformationmentioning

confidence: 99%

Structural evolution and characterization of organic-rich shale from macroscopic to microscopic resolution: The significance of tectonic activity

Gao,

Li,

Cheng

et al. 2023

Adv. Geo-Energy Res.

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Shale gas exploration and development have taken significant strides in the relatively straightforward intra-basin stability zone and intra-basin weak deformation zone of marine shale in the Sichuan Basin, South China. In addition, the extra-basin strong tectonic modification zones have been actively explored. However, the results have been limited, which reveals the complexity of shale gas formation and preservation conditions in the context of multi-scale geological processes. These tectonic geological conditions have a significant impact on the shale gas content, while it has been difficult to figure out how tectonic deformation modifies reservoir structure and what specific mechanism causes shale gas content anomalies. Based on subjecting geologic samples to combined hightemperature and high-pressure experiments, this study summarizes the tectonic constraint mechanism of shale petrophysical structure evolution and its impact on shale gas storage, reveals the intrinsic connection and mechanism of shale pore-fracture and organic matter, inorganic mineral particle structure evolution and tectonic stress, and identifies the remodeling mechanism of the shale reservoir physical property change. The findings contribute to the theory of shale deformation and gas accumulation, as well as offer a scientific foundation for the exploration of marine shale gas in the complex tectonic zones outside the Sichuan Basin.

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Section: Tectonic Activity and Shale Deformationmentioning

confidence: 99%

Structural evolution and characterization of organic-rich shale from macroscopic to microscopic resolution: The significance of tectonic activity

Gao,

Li,

Cheng

et al. 2023

Adv. Geo-Energy Res.

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Evolution Mechanism of Pore Structures of Organic-Rich Shale Under Tectonic Deformation: A Comparative Study Between Whole Rock and Kerogen Samples

Cheng,

Jiang,

et al. 2023

Nat Resour Res

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Microstructures of Cleavage and Fault Mirror and Their Effects on Maturity and Pore Structure of Tectonically Deformed Shales

Xiang,

Wang,

Zhu

et al. 2024

Energy Fuels

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Cleavage and fault mirror (FM) are commonly observed in tectonically deformed shales (TDSs), but their microstructures and effects on reservoir properties are rarely reported. In this study, ten TDS samples collected from the detachment folds of the Wufeng–Longmaxi Formation in the Nanchuan area were investigated using optical microscopy, field emission scanning electron microscopy, Raman spectroscopy, and low-temperature gas adsorption. The results show that dense fracture cleavages perpendicular to the bedding direction are developed in the fracture-crumpled and scaly shales. In contrast, S–C and S–CC′ fabrics are developed in the crumpled shales, while crenulation cleavages are developed in crumpled-scaly and crumpled-mylonitized shales, and the mineral particles in the cleavage domain are crushed into smaller sizes and exhibit enhanced orientation. The FMs in TDSs are primarily developed on the cleavage plane. The flat and smooth surfaces of FMs are predominantly composed of organic matter (OM), followed by clay minerals. The FM is formed through a plastic flow of OM-clay covering or filling between crushed mineral particles. Raman spectra reveal that the average OM maturity of the samples without FMs developed is 3.49%. In contrast, the average maturity of OM on FMs is 3.64%, showing an average increment of up to 0.15%. OM pores are the predominant pores in brittle and brittle-ductile deformed shales. As the degree of deformation increases, the pore volume and specific surface area of fracture-crumpled and scaly shales slightly increase, while those of crumpled shales decrease significantly. The absence of fracture cleavages without FMs has a limited effect on the pore morphology and structure. However, under the control of densely developed FMs, the OM pores are either compacted into micropores or disappear, whereas abundant interparticle pores and intraparticle pores are generated on both sides, leading to a significant change in pore structure parameters.

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Distribution Prediction of Shale Deformation Structures in Tectonically Complex Area Based on Relationship Between Geological Structures and Shale Deformation

Cited by 3 publications

References 40 publications

Structural evolution and characterization of organic-rich shale from macroscopic to microscopic resolution: The significance of tectonic activity

Structural evolution and characterization of organic-rich shale from macroscopic to microscopic resolution: The significance of tectonic activity

Evolution Mechanism of Pore Structures of Organic-Rich Shale Under Tectonic Deformation: A Comparative Study Between Whole Rock and Kerogen Samples

Microstructures of Cleavage and Fault Mirror and Their Effects on Maturity and Pore Structure of Tectonically Deformed Shales

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