Molecular modeling on Gulong shale oil and wettability of reservoir matrix

Cui, FengLu; Jin, Xu; Liu, He; Wu, HengAn; Wang, Fengchao

doi:10.46690/capi.2022.04.01

Cited by 10 publications

(5 citation statements)

References 35 publications

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“…Inorganic pores and fractures are dominantly significant in the shale oil generation window, and organic pores are significant in the shale gas generation window. Several investigations have been performed on the role of the mineral-hosted pore-fracture network and microscopic mechanism of the liquid hydrocarbon storage in these in lower-thermal-maturity, lacustrine shale. ,,− Recently, it has been shown that inorganic minerals can host abundant pore-fracture networks during deposition to burial as overburden stress and diagenesis increase . Loucks et al suggested that rigid mineral particle skeleton support, mechanical compaction, and later dissolution strongly control the inorganic pore-fracture formation and development.…”

Section: Shale Oil Storage Within Lower-thermal-maturity Lacustrine S...mentioning

confidence: 99%

Multi-Scale and Multi-Dimensional Imaging of Mineral Matrix Pore-Fracture Networks in Lower-Thermal-Maturity Lacustrine Shale: Examples from the Paleogene Shahejie Formation, Bohai Bay Basin

Zhao²,

Wen

et al. 2023

Energy Fuels

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The pore-fracture network within shale significantly controls the microscopic storage of hydrocarbons. The Paleogene lacustrine Shahejie Formation of Bohai Bay Basin represents an outstanding lower-thermal-maturity example of a mineral matrix pore-fracture system. Recent studies have shown that most pores in Shahejie shale detectable by high-resolution electron microscopy are associated with an inorganic mineral matrix instead of organics. However, because of the lack of both qualitative and quantitative data on nanometer to micrometer scales, such microstructures have limited the ability to predict hydrocarbon storage feature. Representative Shahejie shale samples come from the Well F39X1 to investigate the pore-fracture network using a synergistic multiscale multi-dimensional workflow by field emission scanning electron microscopy, multi-scale CT, and FIBSEM. Investigations in both 2D and 3D and across cm−mm−μm−nm length scales indicate heterogeneity at every scale and dimensions. From 2D SEM images, clay flake-hosted interparticle pores, rigid grain-hosted interparticle pores, intraparticle dissolution pores, grain-rim microfractures, intragranular microfractures, and matrix microfractures are identified with varying numbers, sizes, and geometries. Large field-of-view 2D scanning electron microscopy images were also used to quantitatively and statistically study the abundance and size of pores and fractures. Using multi-scale CT techniques, pores and fractures from centimeter to nanometer scales were observed with preferential propagation along the mineral aggregate-rich laminations, resulting in an interconnected pore-fracture network. Using FIBSEM, the mineral/organic particles and their related pore phases were visualized, quantitatively computing the pore size and abundance. The visual results suggest that the mineral matrix pore-fracture network in lacustrine Shahejie Formation plays a key role as the liquid hydrocarbon storage space. The application of these techniques to the lower-thermal-maturity shale reservoirs provides important insights into estimating and visualizing rock microstructural heterogeneity and preliminarily establishing a liquid hydrocarbon microscopic storage model.

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Section: Shale Oil Storage Within Lower-thermal-maturity Lacustrine S...mentioning

confidence: 99%

Multi-Scale and Multi-Dimensional Imaging of Mineral Matrix Pore-Fracture Networks in Lower-Thermal-Maturity Lacustrine Shale: Examples from the Paleogene Shahejie Formation, Bohai Bay Basin

Zhao²,

Wen

et al. 2023

Energy Fuels

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“…To bridge our understanding of the intricacies of wetting phenomena with the molecular-level nuances, molecular dynamics (MD) simulations have emerged as an indispensable tool. − Most MD simulations, nevertheless, have primarily focused on homogeneous and smooth surfaces such as graphene and graphite, , but these do not properly represent kerogen’s heterogeneous and rough nature. , To gain deeper insights into wettability, recent studies have started to employ more realistic models of kerogen in which wettability is described by the wetting contact angle of the fluid on the kerogen surface (Table ).…”

Section: Introductionmentioning

confidence: 99%

Wetting Behavior of Kerogen Surfaces: Insights from Molecular Dynamics

Sanchouli,

Babaei,

Kanduč

et al. 2024

Langmuir

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In this study, the wettability of a kerogen surface, a key component of shale reservoirs, is investigated by using molecular dynamics simulations. Specifically, we examined the impact of droplet size and morphology as well as surface roughness on the water contact angles. The findings highlighted that the contact angle dependency on the droplet size intensifies with increased rigidity of the surface. Conversely, as the surface becomes more flexible and rougher, it gains hydrophilicity. The higher hydrophilicity stems from the ability of water molecules to penetrate the kerogen corrugations and form more hydrogen bonds with heteroatoms, particularly oxygen. Notably, the contact angle of kerogen hovers between 65 and 75°, thereby crossing the transition from an underoil hydrophilic to an underoil hydrophobic state. Consequently, minor alterations in the kerogen nanostructure can dramatically alter the wetting preference between water and oil. This insight is of paramount significance for refining strategies in managing fluid interactions in shale reservoirs such as geological carbon storage or oil extraction.

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“…The increase in demand and consumption of light crude oil has led to a decline in global oil reserves and supply. Therefore, short-term and long-term demand needs to be supplemented by unconventional oil resources [1][2][3][4][5][6][7][8]. Heavy oil resources are widely spread around the world.…”

Section: Introductionmentioning

confidence: 99%

Current Status and Future Trends of In Situ Catalytic Upgrading of Extra Heavy Oil

Chen

Cai

et al. 2023

Energies

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In situ catalytic upgrading of heavy oil decomposes viscous heavy oil underground through a series of complex chemical and physical reactions with the aid of an injected catalyst, and permits the resulting lighter components to flow to the producer under a normal pressure drive. By eliminating or substantially reducing the use of steam, which is prevalently used in current heavy oil productions worldwide and is a potent source of contamination concerns if not treated properly, in situ catalytic upgrading is intrinsically environmental-friendly and widely regarded as one of the promising techniques routes to decarbonize the oil industry. The present review provides a state-of-the-art summarization of the technologies of in situ catalytic upgrading and viscosity reduction in heavy oil from the aspects of catalyst selections, catalytic mechanisms, catalytic methods, and applications. The various types of widely used catalysts are compared and discussed in detail. Factors that impact the efficacy of the in situ upgrading of heavy oil are presented. The challenges and recommendations for future development are also furnished. This in-depth review is intended to give a well-rounded introduction to critical aspects on which the in situ catalytic application can shed light in the development of the world’s extra heavy oil reservoirs.

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Molecular modeling on Gulong shale oil and wettability of reservoir matrix

Cited by 10 publications

References 35 publications

Multi-Scale and Multi-Dimensional Imaging of Mineral Matrix Pore-Fracture Networks in Lower-Thermal-Maturity Lacustrine Shale: Examples from the Paleogene Shahejie Formation, Bohai Bay Basin

Multi-Scale and Multi-Dimensional Imaging of Mineral Matrix Pore-Fracture Networks in Lower-Thermal-Maturity Lacustrine Shale: Examples from the Paleogene Shahejie Formation, Bohai Bay Basin

Wetting Behavior of Kerogen Surfaces: Insights from Molecular Dynamics

Current Status and Future Trends of In Situ Catalytic Upgrading of Extra Heavy Oil

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