Molecular Simulation of CH4 Nanoscale Behavior and Enhanced Gas Recovery in Organic-Rich Shale

Li, Yang; Lu, Lize; Zhu, Jingyi; Yang, Zhaozhong; Qu, Junle; Han, Xue; Ouyang, Jingyun

doi:10.1155/2022/2420869

Cited by 3 publications

(3 citation statements)

References 48 publications

(48 reference statements)

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“…After gaining sufficient knowledge about the impact of curvature on methane transportation, we can gradually add more complexities to model the nanochannel. These complexities could include adding functional groups or roughness to the surface of the walls, altering the shape of the cross-section, or even constructing the curved nanochannel by compressing multiple individual kerogen molecules. ,, This progressive approach will allow us to build a more comprehensive and accurate model of the nanochannels in kerogen, enhancing our understanding of methane behavior in these environments.…”

Section: Methodsmentioning

confidence: 99%

Shale Gas Nanofluid in the Curved Carbon Nanotube: A Molecular Dynamics Simulation Study

Wang,

Li,

Zhang

2024

ACS Omega

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Curved nanochannels are prevalent in porous and tortuous materials, with shale matrices being a noteworthy example. The tortuosity of shale matrices significantly influences the behavior of shale gas, holding crucial implications for gas recovery engineering. In this study, we employ molecular dynamics simulation (MD) to investigate the impact of curvature and radius in tortuous nanochannel formed by a curved singlewalled carbon nanotube (SWCNT) on the adsorption and transport properties of methane gas fluid. Our findings reveal that the inner half surface of the SWCNT, characterized by negative curvature, exhibits enhanced methane adsorption. Methane in straighter and narrower channels displays higher flow velocities, while wider channels exhibit higher flow flux. The nonzero flow velocity alters adsorption strength, causing the outer half to surpass the inner half. Tangent and vertical velocities of the flow are heterogeneously distributed in the channel, with the outer half having higher tangent velocities. Additionally, a vertical velocity pulse near the entrance induces turbulent vortex flow, slowing down the tangent flow velocity. This research contributes to a deeper understanding of shale gas properties in matrices with bent and curved channels, offering insights into nanofluids in carbon nanotubes and porous media featuring curved nanochannels.

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Section: Methodsmentioning

confidence: 99%

Shale Gas Nanofluid in the Curved Carbon Nanotube: A Molecular Dynamics Simulation Study

Wang,

Li,

Zhang

2024

ACS Omega

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“…Using a simple model of kerogen in gas shale, in agreement with experimental observations, these authors found that replacing methane by CO 2 is favorable from a thermodynamic viewpoint owing to the strong interactions between CO 2 and kerogen. Since then, by investigating methane/carbon dioxide coadsorption in molecular models of kerogen, many simulation studies have shown that injection of carbon dioxide indeed shifts the adsorption isotherm conditions by favoring the depletion of methane. − While the thermodynamic view derived from these works should be complemented by transport coefficients (to fully grasp the complexity of enhanced gas recovery), they already provide a comprehensive view of the problem. Using similar molecular modeling approaches, other authors also considered simple available thermodynamic models to describe methane/carbon dioxide coadsorption in kerogen. , Finally, as an important development beyond thermodynamic modeling, Xu et al have proposed a kinetic model of enhanced gas recovery.…”

Section: Fluid Thermodynamics and Transport In Kerogenmentioning

confidence: 99%

Development of Atomistic Kerogen Models and Their Applications for Gas Adsorption and Diffusion: A Mini-Review

et al. 2023

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With the emergence of shale gas, numerous atomic-scale models of kerogen have been proposed in the literature. These models, which attempt to capture the structure, chemistry, and porosity of kerogens of various types and maturities, are nowadays commonlyif not routinelyused to gain nanoscale insights into the thermodynamics and dynamics of complex and important processes such as hydrocarbon recovery and carbon sequestration. However, modeling such a complex, disordered, and heterogeneous material is a particularly challenging task. It implies that important underlying assumptions and simplifications, which can significantly affect the predicted properties, have to be made when constructing the kerogen models. In this mini review, we discuss the existing atomistic models of kerogen by categorizing them according to the different approaches and assumptions used during their construction. For each type of model, we also describe how the construction strategy can impact the prediction of certain properties. Important work on kerogen interactions with gas and oil, from both the point of view of equilibrium adsorption (including adsorption-induced deformation) and transport, are described. Possible improvements and upscaling strategiesto better account for kerogen in its geological environmentare also discussed.

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“…With further development of experimental methods, techniques such as elemental analysis, X-ray photoelectron spectroscopy (XPS), and 13 C NMR were used to characterize the elemental composition and functional groups of kerogen to construct a molecular monomer. − A dense matrix can be obtained by several kerogen monomers through a series of annealing procedures. Researchers have modified the matrix according to different research purposes: (1) dummy particles were added in the compression process to build a matrix model with a specific porosity , and (2) cutter atoms were introduced to construct different pore shapes in matrix models. − Numerous kerogen matrices have been used in gas adsorption isotherm simulations and adsorption-induced kerogen swelling effects. − Yu et al used GCMC-MD to compare the volumetric strain caused by the adsorption of CH 4 , C 2 H 6 , and CO 2 . The author suggested that the maximum absolute adsorption capacity of C 2 H 6 was smaller than that of CH 4 and CO 2 , which was attributed to the molecular size.…”

Section: Introductionmentioning

confidence: 99%

Molecular Dynamics Simulation of Adsorption and Absorption Behavior of Shale Oil in Realistic Kerogen Slits

Fei

Wang

et al. 2023

Energy Fuels

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Exploring the occurrence of shale oil is of guiding significance to the exploration and recovery of shale oil. However, most studies focus on adsorption and neglect absorption or study it independently, which weakens the understanding of the coupling relationship between adsorption and absorption and the occurrence mechanism of shale oil in kerogen and its associated pores. Based on molecular dynamics (MD) simulation, the kerogen matrix with a smooth surface is constructed, and the general amber force field is adopted to calculate the adsorption and absorption of shale oil in a type II kerogen slit, and the influences of temperature, pressure, and pore diameter on the occurrence of shale oil are also discussed. Molecules absorbed in the kerogen matrix are mainly retained in the free space formed by the accumulation of aliphatic carbon. The effects of temperature on the distribution of shale oil in adsorption and absorption are opposite. High temperature improves the desorption of molecules from the adsorption sites and causes a lower adsorption and greater absorption. In contrast, pressure and pore diameter only slightly influence the distribution of shale oil. Unexpectedly, the result under aqueous conditions shows that the shale oil was absorbed quickly before the formation of water clusters. Once the water clusters are formed due to the strong hydrogen bonding and adsorbed near the N-, S-, and O-containing groups on the kerogen surface, the matrix gaps are blocked due to the size exclusion, and the absorption is suppressed. Additionally, we established the evolution of the ratio of free-adsorbed−absorbed oil at different temperatures and pressures, which provides a new idea and a new method for detecting the occurrence and mobility evaluation of shale oil under reservoir conditions.

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Molecular Simulation of CH4 Nanoscale Behavior and Enhanced Gas Recovery in Organic-Rich Shale

Cited by 3 publications

References 48 publications

Shale Gas Nanofluid in the Curved Carbon Nanotube: A Molecular Dynamics Simulation Study

Shale Gas Nanofluid in the Curved Carbon Nanotube: A Molecular Dynamics Simulation Study

Development of Atomistic Kerogen Models and Their Applications for Gas Adsorption and Diffusion: A Mini-Review

Molecular Dynamics Simulation of Adsorption and Absorption Behavior of Shale Oil in Realistic Kerogen Slits

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