Simulation and visualization of the displacement between CO2 and formation fluids at pore-scale levels and its application to the recovery of shale gas

Hou, Peng; Ju, Yang; Gao, Feng; Wang, Jianguo

doi:10.1007/s40789-016-0155-9

Cited by 16 publications

(5 citation statements)

References 130 publications

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“…However, exploring the dynamic properties of methane within such small-scale nanopores presents a considerable challenge. − Molecular dynamics simulation (MD) has emerged as an effective tool, enabling access to the nanometer-scale dynamic behavior of methane in nanopores. ,,,− …”

Section: Introductionmentioning

confidence: 99%

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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: Introductionmentioning

confidence: 99%

“… 41 − 46 Molecular dynamics simulation (MD) has emerged as an effective tool, enabling access to the nanometer-scale dynamic behavior of methane in nanopores. 42 , 43 , 45 , 47 − 58 …”

Section: Introductionmentioning

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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“…Liu et al summarized the CO 2 -ESGR techniques including CO 2 fracturing technology, CO 2 injection-enhanced gas recovery, and CO 2 geological storage in depleted shale gas reservoirs. The CO 2 -ESGR is similar to CO 2 -enhanced coalbed methane recovery in that CO 2 /CH 4 competitive adsorption is an important mechanism for the displacement of CH 4 . , It is recognized that although the CO 2 injection can effectively accelerate the desorption rate of CH 4 , the actual production process depends largely on various geological and engineering factors, such as porosity, permeability, formation thickness, gas injection volume and time, fracture height, fracture half-length, and fracture conductivity. However, few studies have systematically scrutinized the effect of these engineering and operating parameters on the potential of the CO 2 -ESGR and storage in hydraulically fractured shale gas reservoirs.…”

Section: Introductionmentioning

confidence: 99%

Surrogate-Assisted Evolutionary Optimization of CO₂-ESGR and Storage

Wang,

Chen

et al. 2023

Energy Fuels

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CO2-enhanced shale gas recovery (CO2-ESGR) could efficiently recover gas with synchronous carbon sequestration, which is safer and more reliable than that in conventional reservoirs due to adsorption. This study developed an optimization scheme for the CO2-ESGR by integrating stochastic algorithms with an artificial neural network (ANN) surrogate model derived from compositional modeling. First, a shale gas reservoir sector model endowed with characteristics from the Sichuan Basin and hydraulically fractured horizontal wells was built. Then, sensitivity analysis was conducted for five critical parameters, namely, gas injection rate, bottom-hole pressure, fracture spacing, half-length, and conductivity, which are predictors for training surrogate models. Aided by the Latin hypercube sampling (LHS) method, 206 parameter combinations were designed, and CH4 recovery and CO2 storage were obtained by compositional simulation. These data sets with the objectives of CH4 recovery and CO2 storage were then partitioned to train and test the ANN models. A correlation coefficient of 0.99 was achieved for both training and testing, indicating high prediction accuracy and stability. Inputting new parameter sets demonstrated that the ANN surrogate model is comparable with a compositional simulator in terms of prediction accuracy with about 6500 times of speedup. Based on the obtained surrogate model, the five predictors were simultaneously optimized using genetic algorithm and particle swarm optimization, achieving a higher recovery factor than sensitivity analysis and LHS with just around1/220 of the computational time of a single compositional simulation. This study serves as a useful reference for the proactive design and further implementation of CO2-ESGR and concurrent storage.

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“…The adsorption and transport properties of methane in nanopores are profoundly influenced by the characteristics of the pore surface, including π–π stacking structures and the stacking orientation. However, investigating the intricate details of methane behavior at such a small scale remains challenging. − MD simulations have emerged as a valuable tool for exploring the nanoscale behavior of methane molecules in the porous shale matrix. − …”

Section: Introductionmentioning

confidence: 99%

Effects of π–π Stacking on Shale Gas Adsorption and Transport in Nanopores

Chen,

Tang,

Wang

2023

ACS Omega

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The π–π interaction is a prevalent driving force in the formation of various organic porous media, including the shale matrix. The configuration of π–π stacking in the shale matrix significantly influences the properties of shale gas and plays a crucial role in understanding and exploiting gas resources. In this research, we investigate the impact of different π–π stacking configurations on the adsorption and transport of shale gas within the nanopores of the shale matrix. To achieve this, we construct kerogen nanopores using π–π stacked columns with varying stacking configurations, such as offset/parallel stacking types and different orientations of the stacked columns. Through molecular dynamics simulations, we examined the adsorption and transport of methane within these nanopores. Our findings reveal that methane exhibits stronger adsorption in smoother nanopores, with this adsorption remaining unaffected by the nanoflow. We observe a heterogeneous distribution of the 2D adsorption free energy, which correlates with the specific π–π stacking configurations. Additionally, we introduce the concept of “directional roughness” to describe the surface characteristics, finding that the nanoflow flux increases as the roughness decreases. This research contributes to the understanding of shale gas behavior in the shale matrix and provides insights into nanoflow properties in other porous materials containing π–π stackings.

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Simulation and visualization of the displacement between CO2 and formation fluids at pore-scale levels and its application to the recovery of shale gas

Cited by 16 publications

References 130 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

Surrogate-Assisted Evolutionary Optimization of CO₂-ESGR and Storage

Effects of π–π Stacking on Shale Gas Adsorption and Transport in Nanopores

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Simulation and visualization of the displacement between CO2 and formation fluids at pore-scale levels and its application to the recovery of shale gas

Cited by 16 publications

References 130 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

Surrogate-Assisted Evolutionary Optimization of CO2-ESGR and Storage

Effects of π–π Stacking on Shale Gas Adsorption and Transport in Nanopores

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Surrogate-Assisted Evolutionary Optimization of CO₂-ESGR and Storage