Pore Structure Characterization of Clay Minerals in the Lower Karamay Formation Conglomerate Reservoir in the Junggar Basin and its Impact on Hydrocarbon Storage and Seepage

Abitkazy, Taskyn; Du, Shanshan; Xu, Feng; Shi, Yongmin

doi:10.1111/1755-6724.13887

Cited by 8 publications

(3 citation statements)

References 44 publications

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“…The pore structure is a key factor that leads to the poor physical properties of tight sandstones (Abitkazy et al, 2021;Muhammad et al, 2021). Therefore, a quantitative method to evaluate the complexity and heterogeneity of pore structures is necessary.…”

Section: Introductionmentioning

confidence: 99%

Influence of Acid Treatment on Pore Structure and Fractal Characterization of a Tight Sandstone: A Case Study from Wudun Sag, Dunhuang Basin

Geng

WANG

ZHANG

et al. 2023

Acta Geologica Sinica (Eng)

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In this study, X‐ray diffraction, N2 adsorption (N2A), and mercury intrusion (MI) experiments were used to investigate the influence of acid treatment on pore structure and fractal characterization of tight sandstones. The results showed that acid treatment generated a certain number of ink‐bottle pores in fine sandstone, aggravated the ink‐bottle effect in the sandy mudstone, and transformed some smaller pores into larger ones. After the acid treatment, both the pore volume in the range of 2–11 nm and 0.271–8 μm for the fine sandstone and the entire pore size range for the sandy mudstone significantly increased. The dissolution of sandstone cement causes the fine sandstone particles to fall off and fill the pores; the porosity increased at first but then decreased with acid treatment time. The fractal dimension obtained using the Frenkel‐Halsey‐Hill model was positively correlated with acid treatment time. However, the total fractal dimensions obtained by MI tests showed different changes with acid treatment time in fine sandstone and sandy mudstone. These results provide good guiding significance for reservoir acidification stimulation.

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Section: Introductionmentioning

confidence: 99%

Influence of Acid Treatment on Pore Structure and Fractal Characterization of a Tight Sandstone: A Case Study from Wudun Sag, Dunhuang Basin

Geng

WANG

ZHANG

et al. 2023

Acta Geologica Sinica (Eng)

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“…Two-dimensional porosity can be quickly determined by means of microscopic evaluation, graph paper projection, image processing, etc., thus sequentially improving accuracy. Two-dimensional porosity is meant to provide a judgment basis regarding the degree of pore development in two-dimensional space so as to quickly evaluate reservoir storage capacity [38][39][40][41][42].…”

Section: The Concept Of "Two-dimensional Permeability"mentioning

confidence: 99%

Characterizing the Microscopic Anisotropic Permeabilities of Tight Oil Reservoirs Impacted by Heterogeneous Minerals

Wang

Wei

et al. 2022

Energies

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This study aimed to reveal the anisotropic permeabilities of tight oil reservoirs impacted by heterogeneous minerals. SEM imaging, image processing, fractal calculation, microscopic reservoir modeling, and visual flow simulation were carried out to investigate the above problems. Results show that the variation coefficient of two-dimensional permeability for the studied tight reservoir samples ranges from 0.09 to 0.95, with an average value of 0.68. The penetration coefficient ranges from 1.16 to 2.64, with an average value of 2.13. The ratio of maximum to minimum permeability is between 1.25 and 7.67, with an average value of 5.62. The fluid flow in tight reservoirs has significant anisotropy comprising dominant flow through conductive channels. Flow in tight oil reservoirs tends to involve minor hydraulic fracturing with no proppant.

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“…The current research is mostly focused on the analysis of a specific block but lacks horizontal comparison between tight reservoirs in different blocks and types. − It is crucial to identify the similarities and differences of the pore–throat structure of cores in different blocks. On the one hand, it can provide a reasonable explanation for the close porosity of rocks but significant differences in permeability, and clarify the main controlling factors of flow, which is necessary to consider in permeability evaluation and flow phenomenon interpretation.…”

Section: Introductionmentioning

confidence: 99%

Investigation of the Microscopic Pore–Throat Structure Difference of Tight Sandstone/Glutenite Based on a Multifractal Method

et al. 2023

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The microscopic pore–throat structure of a tight reservoir is directly related to its seepage capacity. Clarifying the differences in the pore–throat structure of various tight rocks is conducive to reservoir evaluation and flow interpretation. In this study, the microscopic pore–throat structures of tight sandstone (Yanchang Formation, Ordos Basin) and tight glutenite (Upper Wuerhe Formation, Junggar Basin) were characterized by a series of tests, including high-pressure mercury injection, constant-rate mercury injection, and nano-CT. A quantitative analysis was carried out to describe heterogeneity and evaluate permeability based on the multidimensional fractal theory. The correlation coefficient of porosity and permeability of tight sandstone is 0.65, while that of glutenite is only 0.16. The pore–throat size distribution of sandstone is relatively concentrated and well-sorted. The glutenite presents an obvious multipeak pattern, and the proportion of the throat with different sizes is approximate. Multidimensional fractal fitting of sandstone can be divided into two linear segments, whereas glutenite can be divided into four segments. The key factor contributing to this difference is the throat, which controls the flow in the rock. The throat of glutenite exhibits multiscale distribution features, diverse connection modes, and significantly stronger heterogeneity than sandstone, resulting in a poor correlation between porosity and permeability and a complex seepage process. It is essential to consider the influence of microstructure differences, especially heterogeneity and tortuosity when analyzing the flow capacity and clarifying the seepage mechanism of the two types of rock samples.

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Pore Structure Characterization of Clay Minerals in the Lower Karamay Formation Conglomerate Reservoir in the Junggar Basin and its Impact on Hydrocarbon Storage and Seepage

Cited by 8 publications

References 44 publications

Influence of Acid Treatment on Pore Structure and Fractal Characterization of a Tight Sandstone: A Case Study from Wudun Sag, Dunhuang Basin

Influence of Acid Treatment on Pore Structure and Fractal Characterization of a Tight Sandstone: A Case Study from Wudun Sag, Dunhuang Basin

Characterizing the Microscopic Anisotropic Permeabilities of Tight Oil Reservoirs Impacted by Heterogeneous Minerals

Investigation of the Microscopic Pore–Throat Structure Difference of Tight Sandstone/Glutenite Based on a Multifractal Method

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