Confinement Effects and CO<sub>2</sub>/CH<sub>4</sub> Competitive Adsorption in Realistic Shale Kerogen Nanopores

Zhou, Wenning; Wang, Haobo; Yang, Xu; Liu, Xunliang; Yan, Yuying

doi:10.1021/acs.iecr.9b06549

Cited by 41 publications

(28 citation statements)

References 74 publications

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“…Fortunately, molecular dynamics (MD) simulations, originating from Newtonian mechanics to define the force and capture the corresponding motion trajectory of all the particles, make it possible to directly characterize and observe the dynamics behaviors of each atom or molecule at the nanoscale. − Typically for shale nanopores flow, the multiple phases (e.g., water and methane) and radical ambient conditions (e.g., high pressure and temperature) can be easily taken account into MD simulations system, − and, hence, a great deal of MD simulation studies have been performed to reveal the transport characteristics of shale gas within nanopores, providing important cognitions and fundamental frameworks for gas transport through shale nanopores. In this work, the authors attempt to present a comprehensive review on current advances of shale gas transport through microporous/nanoporous media from molecular perspectives, including molecular models, flow simulation strategies, and significant results.…”

Section: Introductionmentioning

confidence: 99%

Transport of Shale Gas in Microporous/Nanoporous Media: Molecular to Pore-Scale Simulations

Fan

et al. 2020

Energy Fuels

104

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As the typical unconventional reservoir, shale gas is believed to be the most promising alternative for the conventional resources in future energy patterns, attracting more and more attention throughout the world. Generally, the majority of shale gas is trapped within the tight shale rock with ultralow porosity (<10%) and ultrasmall pore size (as less as several nanometers). Thus, the accurate understanding of gas transport characteristic and its underlying mechanism through these microporous/nanoporous media is critical for the effective exploitation of shale reservoir. In this context, we present a comprehensive review on the current advances of multiscale transport simulations of shale gas in microporous/nanoporous media from molecular to pore-scale. For the gas transport in shale nanopores using molecular dynamics (MD) simulations, the structure and force parameters of various nanopore models, including organic models (graphene, carbon nanotubes, and kerogen) and inorganic models (clays, carbonate, and quartz), and flow simulation strategies (such as nonequilibrium molecular dynamics (NEMD) and Grand Canonical Monte Carlo simulations) are systematically introduced and clarified. The significant MD simulation results about gas transport characteristic in shale nanopores then are elaborated respectively for different factors, including pore size, ambient pressure, nanopore type, atomistic roughness, and pore structure, as well as multicomponent. Besides, the two-phase transport characteristic of gas and water is also discussed, considering the ubiquity of water in shale formation. For the lattice Boltzmann method (LBM) and pore network model (PNM) approaches to conduct pore-scale simulations, we briefly review its origins, modifications, and applications for gas transport simulations in a microporous/nanoporous shale matrix. Particularly, the upscaling methods to incorporate MD simulation into LBM and PNM frameworks are emphatically expounded in the light of recent attempts of MD-based pore-scale simulations. It is hoped that this Review would be helpful for the readers to build a systematical overview on the transport characteristic of shale gas in microporous/nanoporous media and subsequently accelerate the development of the shale industry.

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Section: Introductionmentioning

confidence: 99%

Transport of Shale Gas in Microporous/Nanoporous Media: Molecular to Pore-Scale Simulations

Fan

et al. 2020

Energy Fuels

104

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“…In another study, Ho et al 33 showed that methane release in nanoporous kerogen matrices is characterized by a fast release of pressurized free gas (accounting for less than 50% recovery), followed by a slow release of adsorbed gas as the gas pressure decreases. There are still other related molecular‐level simulation studies on enhanced shale gas recovery by carbon dioxide and CO 2 sequestration in kerogen matrices of different maturity and porosity, see, for example 34‐40 …”

Section: Introductionmentioning

confidence: 99%

“…There are still other related molecular-level simulation studies on enhanced shale gas recovery by carbon dioxide and CO 2 sequestration in kerogen matrices of different maturity and porosity, see, for example. [34][35][36][37][38][39][40] Most molecular models treat the shale OM as a dense porous kerogen matrix. 9,10 Although kerogen is the abundant species in the OM, the OM also contains other compounds such as asphaltenes, resins, and dissolved species (typically hydrocarbons, water and carbon dioxide), where their absence may be mimicked by introducing dummy particles into the kerogen matrix.…”

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confidence: 99%

Methane and carbon dioxide in dual‐porosity organic matter: Molecular simulations of adsorption and diffusion

2020

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Shale gas, which predominantly consists of methane, is an important unconventional energy resource that has had a potential game-changing effect on natural gas supplies worldwide in recent years. Shale is comprised of two distinct components: organic material and clay minerals, the former providing storage for hydrocarbons and the latter minimizing hydrocarbon transport. The injection of carbon dioxide in the exchange of methane within shale formations improves the shale gas recovery, and simultaneously sequesters carbon dioxide to reduce greenhouse gas emissions. Understanding the properties of fluids such as methane and methane/carbon dioxide mixtures in narrow pores found within shale formations is critical for identifying ways to deploy shale gas technology with reduced environmental impact. In this work, we apply molecularlevel simulations to explore adsorption and diffusion behavior of methane, as a proxy of shale gas, and methane/carbon dioxide mixtures in realistic models of organic materials. We first use molecular dynamics simulations to generate the porous structures of mature and overmature type-II organic matter with both micro-and mesoporosity, and systematically characterize the resulting dual-porosity organic-matter structures. We then employ the grand canonical Monte Carlo technique to study the adsorption of methane and the competing adsorption of methane/carbon dioxide mixtures in the organic-matter porous structures. We complement the adsorption studies by simulating the diffusion of adsorbed methane, and adsorbed methane/carbon dioxide mixtures in the organic-matter structures using molecular dynamics.

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“…They attributed this behavior to the fluid curvature which is higher in the cylindrical pore than in slit pores. In the same vein, 141 studied the adsorption selectivity of CH 4 and CO 2 in realistic pore structures considering the surface roughness. They found that inkbottle-shaped pores enhance the selectivity of CO 2 / CH 4 compared to slit pores.…”

Section: ■ Atomistic Simulationmentioning

confidence: 99%

Molecular Modeling of Subsurface Phenomena Related to Petroleum Engineering

et al. 2021

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Experiments are always the go-to approach to reveal mysterious observations and verify new theories. However, scientific research has shifted to areas that are difficult to probe experimentally. Fortunately, computational approaches, such as molecular simulation, became available. With a rigorous theoretical foundation and microscopic insights, molecular simulation could explore unknown territories in physics and validate macroscopic theories. Grand challenges in petroleum engineering require knowledge at the molecular scale more than ever, such as the behavior of confined fluids in shale nanopores. Although it is widely used in materials science, biophysics, and biochemistry, molecular simulation has been underutilized in subsurface modeling. However, the complexity of the subsurface systems and the heterogeneity of reservoir fluids, which currently challenge both our continuum modeling approaches and experimental techniques, could benefit from molecular insights. In this Review, we briefly present the basics of molecular simulation and a few applications addressing current petroleum engineering challenges. These applications include (1) phase equilibria, where molecular simulation handles inaccessible experimental conditions such as high pressure, high temperature, or a toxic environment; (2) asphaltene aggregation, where molecular simulation enables the synthesis and evaluation of the solvent performance; (3) low-salinity water flooding, where molecular simulation reveals the key mechanisms; and (4) shale reservoirs, where molecular simulation derives the new physics controlling the transport phenomena in these reservoirs. Our goal is to demonstrate that the molecular models can shed some light on numerous subsurface applications, moving toward more predictive physics-based models to optimize and control subsurface systems.

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Confinement Effects and CO₂/CH₄ Competitive Adsorption in Realistic Shale Kerogen Nanopores

Cited by 41 publications

References 74 publications

Transport of Shale Gas in Microporous/Nanoporous Media: Molecular to Pore-Scale Simulations

Transport of Shale Gas in Microporous/Nanoporous Media: Molecular to Pore-Scale Simulations

Methane and carbon dioxide in dual‐porosity organic matter: Molecular simulations of adsorption and diffusion

Molecular Modeling of Subsurface Phenomena Related to Petroleum Engineering

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Confinement Effects and CO2/CH4 Competitive Adsorption in Realistic Shale Kerogen Nanopores

Cited by 41 publications

References 74 publications

Transport of Shale Gas in Microporous/Nanoporous Media: Molecular to Pore-Scale Simulations

Transport of Shale Gas in Microporous/Nanoporous Media: Molecular to Pore-Scale Simulations

Methane and carbon dioxide in dual‐porosity organic matter: Molecular simulations of adsorption and diffusion

Molecular Modeling of Subsurface Phenomena Related to Petroleum Engineering

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Product

Resources

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Confinement Effects and CO₂/CH₄ Competitive Adsorption in Realistic Shale Kerogen Nanopores