Pore structure and fractal characteristics of transitional shales with different lithofacies from the eastern margin of the Ordos Basin

Wang, Tao; Deng, Ze; Hu, Haiyan; Tian, Fenghua; Ding, Rong; Zhang, Tao; Ma, Zhanrong; Hou, Songyi; Li, Xiaogang; Dai, Ruirui; Hong, Xing

doi:10.1002/ese3.1580

Cited by 2 publications

(4 citation statements)

References 56 publications

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“…Vitrinite is the main carrier of primary pores, metamorphic pores, and endogenous microfissures followed by fibrous bodies, which mainly develop plant tissue pores, while exinite does not develop pores, resulting in the PV usually increasing with increasing vitrinite content. Studies have shown that the stronger the hydrocarbon generation ability, the more favorable the development of metamorphic pores. ,, The high vitrinite content in coal, combined with its strong thermoplasticity, brittleness, and gas generation, results in the development of metamorphic pores in vitrinite. , Considering that metamorphic pores are micropores according to pore size compared with inertinite-rich coal, vitrinite-rich coal features a greater proportion of micropores, thus exhibiting greater homogeneity and better pore connectivity.…”

Section: Discussionmentioning

confidence: 99%

“…The coal sample pretreatment procedure used in the LP-CO 2 GA experiment was similar to that used in the LT-N 2 GA experiment. The coal sample was degassed for 16 h, and the adsorption test was carried out at 273 K with high-purity CO 2 (more than 99.999%) as the adsorbent . The pore structure parameters, including the PV, SSA, APD, and PSD, were obtained based on nonlocal density functional theory (NLDFT). , This testing was strictly implemented according to the standards of ISO 15901-2:2022.…”

Section: Methodsmentioning

confidence: 99%

“…The coal samples were crushed to 60−80 mesh (0.250−0.180 mm) and then pretreated before being subjected to the CH 4 adsorption test. Wang et al 48 described the equilibrium water process in detail. The adsorption temperature was 70 °C, and the maximum pressure was approximately 25 MPa.…”

Section: Experiments and Methodsmentioning

confidence: 99%

“…16,27,58 The high vitrinite content in coal, combined with its strong thermoplasticity, brittleness, and gas generation, results in the development of metamorphic pores in vitrinite. 27,48 Considering that metamorphic pores are micropores according to pore size compared with inertinite-rich coal, vitrinite-rich coal features a greater proportion of micropores, thus exhibiting greater homogeneity and better pore connectivity.…”

Section: Influence Of Proximate Analysis and Maceralmentioning

confidence: 99%

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Study on the Pore Structure and Multifractal Characteristics of Medium- and High-Rank Coals Based on the Gas Adsorption Method: A Case Study of the Benxi Formation in the Eastern Margin of the Ordos Basin

Wang,

Deng,

et al. 2024

Energy Fuels

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Nanopore heterogeneity significantly affects the adsorption, desorption, and diffusion processes of coalbed methane.Here, the medium-and high-rank coals of the Benxi Formation in the eastern margin of the Ordos Basin were taken as the research object, and low-pressure CO 2 adsorption and low-temperature N 2 adsorption experiments were used to study the pore characteristics; combined with multifractal theory, the multifractal characteristics of micropores (0.3−2.0 nm) and meso-/macropores (2−300 nm) in MRC and HRC are characterized and explored, and the evolutionary trends and influential factors during metamorphism are explored. The results show that the pore distribution of micropores and meso-/macropores in MRC to HRC coal has multifractal characteristics. Compared with meso-/macropores, micropores exhibit smaller Δα values and larger H values; that is, micropores have weaker heterogeneity and better pore connectivity. As the coal rank increases, the percentage of the micropore volume in the coal increases, and the pore size distribution of micropores and meso-/macropores tends to be more homogeneous, which leads to a decrease in the pore structure uniformity and improvement in the pore connectivity in coal reservoirs. An increase in the vitrinite content leads to better connectivity and a more uniform pore structure of micropores and meso-/macropores. An increase in the mineral content and A d leads to a decrease in the connectivity of micropores and meso-/macropores and tends to increase the complexity of pore structures. With increasing micropore volume and specific surface area, the degree of pore aggregation and heterogeneity decreases, and the pore connectivity increases. However, there is no significant correlation between the pore structure and the multifractal parameters of the meso-/macropore structure. The HRC samples have more micropores than the MRC samples and thus exhibit greater pore structure homogeneity and better pore connectivity. A uniform distribution and good connectivity of the pores help to improve the methane adsorption capacity.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Experiments and Methodsmentioning

confidence: 99%

Section: Influence Of Proximate Analysis and Maceralmentioning

confidence: 99%

See 2 more Smart Citations

Study on the Pore Structure and Multifractal Characteristics of Medium- and High-Rank Coals Based on the Gas Adsorption Method: A Case Study of the Benxi Formation in the Eastern Margin of the Ordos Basin

Wang,

Deng,

et al. 2024

Energy Fuels

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Full-Scale Pore and Microfracture Characterization of Deep Coal Reservoirs: A Case Study of the Benxi Formation Coal in the Daning–Jixian Block, China

Wang,

Zhou,

Fan

et al. 2024

International Journal of Energy Research

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The pore-fracture structure of deep coal reservoirs is highly important for evaluating, exploring, and developing coalbed methane (CBM) resources. This study considers three coal samples from the DJ57 well in the Benxi Formation in the Daning–Jixian block on the eastern margin of the Ordos Basin as the research object. Based on the coal quality parameters of the coal samples, field emission scanning electron microscopy (FE-SEM), gas adsorption experiments, high-pressure mercury intrusion porosimetry (MIP), and microcomputed tomography (micro-CT) scanning were used to quantitatively characterize the nanoscale pores and microscale fractures in deep coal reservoirs and to evaluate the pore-fracture structure at different scales. The results reveal that the pore types in the Benxi Formation coal samples are diverse and include mainly organic matter (OM) pores, inorganic pores (intraparticle and interparticle pores), and microfractures. The organic pores are diverse in shape and mainly exhibit round, oval, and wedge shapes, while the microfractures exhibit slender stripes or serrated curves. The multiscale quantitative characterization of deep coal reservoir pores and fractures is based on a variety of pore characterization methods, and the pore and fracture volume distributions are mainly U-shaped, revealing the coexistence of micropores and microfractures. The volumes of micropores (0.3–2 nm), mesopores (2–50 nm), macropores (50 nm to 10 μm), and microfractures (>10 μm) account for 78.00%, 6.78%, 2.08%, and 13.14%, respectively, of the total pore volume (PV). Based on a full-scale pore-fracture splicing calculation, the total permeability of the Benxi Formation coal samples ranges from 5.77 to 28.22 mD. The observation results indicate that the microfractures are connected to each other, forming a network structure with strong connectivity. The microfractures are mainly associated with pore diameters>100 μm, accounting for approximately 95% of the total permeability. Moreover, micropores in deep coal reservoirs provide a large space for CBM adsorption, and microfractures enhance the seepage capacity of CBM.

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Pore structure and fractal characteristics of transitional shales with different lithofacies from the eastern margin of the Ordos Basin

Cited by 2 publications

References 56 publications

Study on the Pore Structure and Multifractal Characteristics of Medium- and High-Rank Coals Based on the Gas Adsorption Method: A Case Study of the Benxi Formation in the Eastern Margin of the Ordos Basin

Study on the Pore Structure and Multifractal Characteristics of Medium- and High-Rank Coals Based on the Gas Adsorption Method: A Case Study of the Benxi Formation in the Eastern Margin of the Ordos Basin

Full-Scale Pore and Microfracture Characterization of Deep Coal Reservoirs: A Case Study of the Benxi Formation Coal in the Daning–Jixian Block, China

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