Molecular Dynamics Study on CO<sub>2</sub> Storage in Water-Filled Kerogen Nanopores in Shale Reservoirs: Effects of Kerogen Maturity and Pore Size

Li, Wenhui; Zhang, Mingshan; Nan, Yiling; Pang, Wanying

doi:10.1021/acs.langmuir.0c03232

Cited by 33 publications

(25 citation statements)

References 72 publications

(152 reference statements)

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“…PCFF+ was originally used in the development of kerogen model units by Ungerer et al However, the short-range non-bonded interactions in PCFF+ are described by a repulsive–attractive 9–6 Lennard-Jones (LJ) potential, which is incompatible with many other force fields that include a 12–6 LJ potential, such that it is difficult to simulate kerogens with other compounds. CVFF is one of the most commonly used force fields in kerogen simulations, − ,,, and the 12–6 LJ potential in its functional form is compatible with other force fields. CVFF correctly reproduces the experimental density of the Type II kerogen series and provides a reasonable description of kerogen interactions with its constituents, for example, carbon dioxide, methane (TraPPE-UA), and water .…”

Section: Methodsmentioning

confidence: 99%

“…CVFF is one of the most commonly used force fields in kerogen simulations, − ,,, and the 12–6 LJ potential in its functional form is compatible with other force fields. CVFF correctly reproduces the experimental density of the Type II kerogen series and provides a reasonable description of kerogen interactions with its constituents, for example, carbon dioxide, methane (TraPPE-UA), and water . The partial atomic charges of CVFF atoms were assigned using a bond increment scheme.…”

Section: Methodsmentioning

confidence: 99%

“…Both studies observed that the CH 4 adsorption isotherm in the kerogen follows type I Langmuir adsorption behavior. Li et al . conducted MD simulations to study CO 2 storage in water-filled slit-shaped nanopores of different sizes through a kerogen matrix of the Type II series.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Diffusion Behavior of Methane in 3D Kerogen Models

Bowers

Loganathan

et al. 2021

Energy Fuels

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As global energy demand increases, natural gas recovery from source rocks is attracting considerable attention since recent development in shale extraction techniques has made the recovery process economically viable. Kerogens are thought to play an important role in gas recovery; however, the interactions between trapped shale gas and kerogens remain poorly understood due to the complex, heterogeneous microporous structure of kerogens. This study examines the diffusive behavior of methane molecules in kerogen matrices of different types (Type I, II, and II) and maturity levels (A to D for Type II kerogens) on a molecular scale. Models of each kerogen type were developed using simulated annealing. We employed grand canonical Monte Carlo simulations to predict the methane loadings of the kerogen models and then used equilibrium molecular dynamics simulations to compute the mean square displacement of methane molecules within the kerogen matrices under reservoir-relevant conditions, that is, 365 K and 275 bar. Our results show that methane self-diffusivity exhibits some degree of anisotropy in all kerogen types examined here except for Type I-A kerogens, where diffusion is the fastest and isotropic diffusion is observed. Self-diffusivity appears to correlate positively with pore volume for Type II kerogens, where an increase in diffusivity is observed with increasing maturity. Swelling of the kerogen matrix up to a 3% volume change is also observed upon methane adsorption. The findings contribute to a better understanding of hydrocarbon transport mechanisms in shale and may lead to further development of extraction techniques, fracturing fluids, and recovery predictions.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Diffusion Behavior of Methane in 3D Kerogen Models

Bowers

Loganathan

et al. 2021

Energy Fuels

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“…(a) Fluid transport behaviour in shale nanopores with realistic surfaces: although the elementary compositions and molecular structures of OM and IOM can be obtained with chemical analysis, nanopores with realistic surface properties still cannot be fully structured in MD simulations, including the maturity of OM, surface charge of IOM, surface roughness, and the wettability heterogeneity of pore surfaces, which can have significant influences on gas adsorption and water transport. [265][266][267] (b) The properties of fluids in nanopores: for gas transport, multicomponent gas transport in nanopores should be paid more attention; for water transport, pure water can be extended to a saline solution or non-Newtonian fluid. [35,268,269] (c) Compared with single-phase transport, simulation of multiphase transport in shale nanopores is insufficient: the flow pattern and interfacial interactions of multiple fluids at the nanoscale are still unclear.…”

Section: Nanoconfined Fluid Flow Under a Complex Environmentmentioning

confidence: 99%

A comprehensive review on the flow behaviour in shale gas reservoirs: Multi‐scale, multi‐phase, and multi‐physics

Feng

Chen

et al. 2022

Can J Chem Eng

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An accurate description of fluid flow is critical for the prediction of the productivity of shale gas reservoirs. In this paper, we present the current advances and a systematic summary on the fluid flow in shale gas reservoirs. First, shale pore structures, consisting of organic pores and inorganic pores ranging from nanoscale to micro-scale, and reservoir fluids, including free gas, absorbed gas, and water, are systematically presented. Thereafter, multi-physics flow phenomena motivated by scale effects, such as continuum flow, slip flow, transition flow, free molecular flow, and surface diffusion for gas, as well as the effective viscosity and slip boundary condition for water, are carefully summarized. Meanwhile, these flow mechanisms are discussed with molecular dynamics (MD) simulations and theoretical analysis. Subsequently, on the basis of upscaling approaches, including capillary bundle models, the lattice Boltzmann method (LBM), and pore network models (PNMs), fluid flow through heterogeneous shale matrix is reviewed and the influences of scale effects and pore structures are clarified. Additionally, shale gas well performance is discussed by combining the multiple transport mechanisms and a fracturing-shut-in-flowback-production process. Our review concluded that the fluid flow behaviour in shale gas reservoirs is a complex multi-scale process accompanied by multi-physical phenomena and multi-fluid distributions. Keeping this in mind is helpful for predicting the shale gas production and recoverable gas resources. We expect this study can not only help by providing a better understanding of the fluid flow in shale reservoirs but also provide significant implications to address other multiphase flow processes.

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“…In addition, the scCO 2 flooding in tight reservoirs benefits from the generally excellent miscibility between CO 2 and oils − and promotes oil swelling and viscosity reduction, which are favorable for EOR. On the other hand, as one of the several geological carbon sequestration (GCS) and CO 2 utilization schemes, − CO 2 injection into tight formations can help mitigate carbon emissions. However, CO 2 flooding in tight formations is subject to gas channeling, which can adversely impact the efficacy of EOR .…”

Section: Introductionmentioning

confidence: 99%

Ethanol Blending to Improve Reverse Micelle Dispersity in Supercritical CO₂: A Molecular Dynamics Study

Nan

Zhang

et al. 2021

J. Phys. Chem. B

Self Cite

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Despite a great promise in the enhanced oil recovery in tight formations, CO2 flooding with surfactants is hindered due to the low surfactant solubility in supercritical CO2 (scCO2). Alcohol blending can increase the sodium bis(2-ethylhexyl) sulfosuccinate (AOT) solubility in scCO2. While this finding offers a promising solution to CO2 flooding in tight oil reservoirs, to the best of our knowledge, their working mechanism still remains elusive. Herein, we report a molecular dynamics simulation study to explore the working mechanism of alcohols in reverse micelle (RM) dispersity (“solubility”) increment. The spontaneous aggregation process in two systems (System A consisting of AOT and scCO2; System B consisting of AOT, scCO2, and 10 wt % ethanol) are conducted under a typical tight oil reservoir condition (333 K and 200 bar). After 600 ns runs, the AOT molecules aggregate together and form rod-like RMs in System A, while form several small sphere-like RMs in System B. We observe that the aggregation process in System A occurs when two clusters approach each other end-to-end. More CO2 molecules are around the Na+ ion at the end of the clusters, which can be readily replaced by AOT molecules. On the other hand, the ethanol molecules can better solvate and surround Na+ ions, preventing the further aggregation of AOT clusters in System B. The potential of mean force calculations also reveal that while two small clusters formed by four AOT molecules attract each other in System A, they repel each other in System B. Our work should provide important insights into the design of scCO2-soluble surfactant formulas.

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Molecular Dynamics Study on CO₂ Storage in Water-Filled Kerogen Nanopores in Shale Reservoirs: Effects of Kerogen Maturity and Pore Size

Cited by 33 publications

References 72 publications

Diffusion Behavior of Methane in 3D Kerogen Models

Diffusion Behavior of Methane in 3D Kerogen Models

A comprehensive review on the flow behaviour in shale gas reservoirs: Multi‐scale, multi‐phase, and multi‐physics

Ethanol Blending to Improve Reverse Micelle Dispersity in Supercritical CO₂: A Molecular Dynamics Study

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Molecular Dynamics Study on CO2 Storage in Water-Filled Kerogen Nanopores in Shale Reservoirs: Effects of Kerogen Maturity and Pore Size

Cited by 33 publications

References 72 publications

Diffusion Behavior of Methane in 3D Kerogen Models

Diffusion Behavior of Methane in 3D Kerogen Models

A comprehensive review on the flow behaviour in shale gas reservoirs: Multi‐scale, multi‐phase, and multi‐physics

Ethanol Blending to Improve Reverse Micelle Dispersity in Supercritical CO2: A Molecular Dynamics Study

Contact Info

Product

Resources

About

Molecular Dynamics Study on CO₂ Storage in Water-Filled Kerogen Nanopores in Shale Reservoirs: Effects of Kerogen Maturity and Pore Size

Ethanol Blending to Improve Reverse Micelle Dispersity in Supercritical CO₂: A Molecular Dynamics Study