Molecular Investigation of CO2/CH4 Competitive Adsorption and Confinement in Realistic Shale Kerogen

Zhou, Wenning; Zhang, Zhe; Wang, Haobo; Yang, Xu

doi:10.3390/nano9121646

Cited by 31 publications

(21 citation statements)

References 63 publications

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“…The rate at which the ultimate recovery can be reached, however, was determined by the connectivity of reservoir pores and the extent of the induced hydraulic fractures. The adsorption results of CH 4 –CO 2 presented in this study shared a similar trend to some others reported in the literature. ,,,, …”

Section: Resultssupporting

confidence: 91%

“…The results also showed that in the case of the CO 2 /CH 4 binary mixture, increasing the pressure resulted in a slight increase in carbon dioxide adsorption and a slight decrease in methane adsorption. They also examined the impact of thermal maturity on adsorption; the simulation results showed that a mature type II kerogen had a larger adsorption capacity than other type II kerogen molecules …”

Section: Introductionmentioning

confidence: 99%

“…They also examined the impact of thermal maturity on adsorption; the simulation results showed that a mature type II kerogen had a larger adsorption capacity than other type II kerogen molecules. 21 In addition, Gu et al discussed the effect of shale pore structure and composition on the selectivity of carbon dioxide over methane. The authors showed that a higher carbon dioxide adsorption in comparison to that of methane does not necessarily mean more CO 2 −shale interactions.…”

Section: Introductionmentioning

confidence: 99%

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Enhanced Recovery From Organic-Rich Shales through Carbon Dioxide Injection: Molecular-Level Investigation

et al. 2020

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Petroleum engineers are always in a race to maximize the recovery factor out of naturally trapped hydrocarbon resources. Unconventional resources such as organic-rich shales have unlocked significant reserves attributed to the novel production technologies of lateral drilling assisted by hydraulic fracturing. Even though such techniques have enabled the exploitation of shales, the ultimate recovery remained fractional, a challenge to be answered through further improvement. Carbon dioxide injection in unconventional resources, which was initially implemented for coalbed methane, has been recently an active area of investigation for organic-rich shales. In this paper, we present a molecular modeling study of carbon dioxide injection in the organic matter of the shale matrix. We built the molecular model, consistent with the repeated organic matter characterization in the literature. Molecular dynamics (MD) protocol was developed to form a three-dimensional (3-D) configuration of kerogen, followed by Gibbs Monte Carlo simulation for the adsorption/desorption calculations, and self-diffusivity calculations through MD. The aim was to delineate the impact of carbon dioxide injection on the adsorption/desorption behavior coupled with its influence on the transport. Injection of carbon dioxide was found to shift the adsorption isotherm favoring the depletion of methane. The ultimate recovery raised from 54% (no injection of CO 2 ) up to 92% depending on the carbon dioxide concentration and its temperature. Moreover, the injection of carbon dioxide was found to have a minimal impact on the self-diffusivity of methane in kerogen bodies and their associated microcracks.

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Section: Resultssupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Enhanced Recovery From Organic-Rich Shales through Carbon Dioxide Injection: Molecular-Level Investigation

et al. 2020

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“…The in-depth adsorption mechanism and confinement effect in realistic kerogen nanopores are still not fully understood. Based on our previous molecular studies on competitive adsorption of CO 2 /CH 4 in kaolinite clay and graphene slit-like nanopores in shale reservoirs, ,, we focused on the molecular investigation of gas adsorption mechanism and confinement effect in realistic kerogen nanopores in the present work. Type III-A kerogen proposed by Ungerer et al was employed to develop the inkbottle-shaped and slit nanopores with surface roughness.…”

Section: Introductionmentioning

confidence: 99%

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

Zhou

Wang

Yang

et al. 2020

Ind. Eng. Chem. Res.

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The knowledge of adsorption behaviors and mechanism of CO2/CH4 in organic matter is of great importance for CO2 geological sequestration with enhanced gas recovery in shale reservoirs. In this study, the adsorption behaviors and confinement effects of CO2/CH4 in realistic kerogen nanopores have been investigated by using the grand canonical Monte Carlo method. To represent realistic nanopores in the kerogen matrix, the inkbottle-shaped and slit-like nanopores were developed. The effects of temperature, pressure, and pore size on competitive adsorption behaviors and adsorption mechanism of CO2/CH4 were explored. Simulation results indicate that the adsorption capacity of CH4 is lower than that of CO2 in the kerogen matrix with/without kerogen nanopores. A higher pressure and lower temperature are favorable for the adsorption capacities of CO2 and CH4. The gas adsorption capacities have been enhanced in both the inkbottle-shaped and slit-like nanopores. Meanwhile, the existence of inkbottle-shaped micropores is favorable for improving the selectivity of CO2/CH4 in shale organic matter. A higher CO2 injection pressure could improve its adsorption capacity but lower the adsorption selectivity of CO2 over CH4. Furthermore, confinement effects were observed in inkbottle-shaped and slit-like kerogen micropores and small mesopores. Two major factors, including the supercritical state of gas and microscale pores, could enhance the confinement effects. In addition to monolayer adsorption, micropore filling was observed in inkbottle-shaped and slit-like kerogen nanopores because of the confinement effects. It is expected that these results could help in understanding the microscopic adsorption mechanism and provide fundamental information for shale gas exploitation and CO2 sequestration.

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“…Due to its phys i cal prop er ties, CO 2 is a per fect agent for stim u la tion of meth ane (CH 4 ) pro duc tion from ul tra-tight shale res er voirs, as well as from con ven tional res er voirs. Firstly, a higher CO 2 (than CH 4 ) ad sorp tion af fin ity to or ganic mat ter and clay min er als leads to CH 4 re place ment by CO 2 in or ganic matter and other min eral pore sur faces (Heller and Zoback, 2014;Zhou et al, 2019). This mech a nism pro duces an ac tive push of gas off the res er voir and en sures per ma nent bond ing of CO 2 in the shale vol ume.…”

Section: Introductionmentioning

confidence: 99%

The estimation of CO2 storage potential of a gas-bearing shale succession at the early stage of reservoir characterization: a case study from the Baltic Basin (Poland)

Wójcicki¹,

Jarosiński²,

Roman³

2020

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Molecular Investigation of CO2/CH4 Competitive Adsorption and Confinement in Realistic Shale Kerogen

Cited by 31 publications

References 63 publications

Enhanced Recovery From Organic-Rich Shales through Carbon Dioxide Injection: Molecular-Level Investigation

Enhanced Recovery From Organic-Rich Shales through Carbon Dioxide Injection: Molecular-Level Investigation

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

The estimation of CO2 storage potential of a gas-bearing shale succession at the early stage of reservoir characterization: a case study from the Baltic Basin (Poland)

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Molecular Investigation of CO2/CH4 Competitive Adsorption and Confinement in Realistic Shale Kerogen

Cited by 31 publications

References 63 publications

Enhanced Recovery From Organic-Rich Shales through Carbon Dioxide Injection: Molecular-Level Investigation

Enhanced Recovery From Organic-Rich Shales through Carbon Dioxide Injection: Molecular-Level Investigation

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

The estimation of CO2 storage potential of a gas-bearing shale succession at the early stage of reservoir characterization: a case study from the Baltic Basin (Poland)

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