Impact of coal composition and pore structure on gas adsorption: a study based on a synchrotron radiation facility

Sun, Yingfeng; Zhao, Yixin; Yuan, Liang

doi:10.1002/ghg.1935

Cited by 21 publications

(4 citation statements)

References 43 publications

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“…Understanding the gas adsorption/desorption on coals gives us an insight into the gas migration within coal seams. 118 The sorption isotherm refers to the change of the adsorbed gas amount with different gas pressures at a given temperature, which is usually used to describe the desorption/adsorption process. 26 This section will summarize several classical isothermal adsorption models.…”

Section: Modeling Of Gas Sorption On Coals 311 Sorptionmentioning

confidence: 99%

“…About 95–98% of CH 4 in a coal reservoir is adsorbed in the coal matrix, and the rest of CH 4 is stored in fractures in a free state. Understanding the gas adsorption/desorption on coals gives us an insight into the gas migration within coal seams . The sorption isotherm refers to the change of the adsorbed gas amount with different gas pressures at a given temperature, which is usually used to describe the desorption/adsorption process .…”

Section: Modelings Of General Performances In Co2-ecbmmentioning

confidence: 99%

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Recent Advances and Perspectives of CO₂-Enhanced Coalbed Methane: Experimental, Modeling, and Technological Development

et al. 2023

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Carbon dioxide (CO2)-enhanced coalbed methane recovery (CO2-ECBM) is a critical way to increase methane production and reduce greenhouse gas (CO2 and CH4) emissions. As captured CO2 is continuously injected in the coal seams, a low cost of CO2 sequestration and high efficiency of CH4 recovery can be achieved via the flooding and replacing effects driven by the injected CO2 flow. Scientific insights into the complex process of CO2-ECBM in experiments, modelings, and technological developments need to be made to propose appropriate countermeasures. This review first highlights the progress of CO2-ECBM under laboratory conditions, e.g., the binary gas competitive adsorption and gas displacement experiments in the macroscale and porous structure tests using technologies of nuclear magnetic resonance (NMR), scanning electron microscopy (SEM), and computed tomography (CT) in the microscale. Then, the advances of mathematical models for changing in coal permeability and porosity during CO2-ECBM are reviewed, accompanying with the multi-field and multi-phase coupling responses of competitive sorption, diffusion, gas–water seepage, heat transfer, and solid deformation. Furthermore, the field pilot tests of CO2-ECBM in various countries and regions are also covered to reveal the key technical challenges confronted with the development of CO2-ECBM technology. The perspectives in experiments, models, and field pilots of CO2-ECBM are made, which include but are not limited to the following: conducting a core CH4/CO2 flooding test under in situ conditions, modeling CO2-ECBM with real fractures/faults and coal failure, developing a new method for gas migration and leakage monitoring in the field, and enacting relevant standards, laws, and regulations to promote CO2-ECBM.

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Section: Modeling Of Gas Sorption On Coals 311 Sorptionmentioning

confidence: 99%

Section: Modelings Of General Performances In Co2-ecbmmentioning

confidence: 99%

Recent Advances and Perspectives of CO₂-Enhanced Coalbed Methane: Experimental, Modeling, and Technological Development

et al. 2023

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“…Coal is a kind of heterogeneous microporous material with a high surface area, whose pore size spans from as small as less than 1 nm to as large as several hundred nanometers of plant cell pores [34]. The pore surface of coal has a strong adsorption force on gas, and the amount of gas stored in the coal seam depends on the volume and surface area of pores [35,36].…”

Section: Pore Structurementioning

confidence: 99%

Methane Adsorption Interpreting with Adsorption Potential and Its Controlling Factors in Various Rank Coals

et al. 2020

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Water content, metamorphism (coal rank) particle size, and especially pore structure, strongly influence the adsorption capacity of coal to methane. To understand the mechanism of methane adsorption in different rank coals, and its controlling factors, isothermal adsorption experiments with different coal ranks, moisture contents and particle sizes at the temperature of 303.15 K were conducted. In addition, the pore structures of coals were investigated through N2 adsorption/desorption experiments at the low-temperature of 77 K for selected coals from the Junggar Basin of NW China, Qinshui Basin and Ordos Basin of north China. Moreover, the adsorption potential of methane on the surface of the coal matrix was calculated, the controlling factors of which were discussed. The obtained methane isothermal adsorption result shows that the Langmuir volume (VL) of coal is independent of the particle size, and decreases with the increase of moisture content, which decreases first and then increases when the coal rank increases. Combined with the pore structure by the N2 adsorption at 77 K, VL increases with the increase of pore surface area and pore volume of coal pores. Besides, the adsorption potential of all selected coals decreased with the increase of the methane adsorption volume, showing a negative relationship. The interesting phenomena was found that the surface adsorption potential of the coal matrix decreases with the increase of moisture content, and increases with the decrease of particle size at the same pressure. With the same adsorption amount, the adsorption potential on the surface of coal matrix decreases first, and then increases with the increase of coal rank, reaching a minimum at Ro,m of 1.38%, and enlarging with the increase of pore surface area and the pore volume of coal pores. These findings may have significant implications for discovering CBM accumulation areas and enhancing CBM recovery.

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“…Jia et al revealed that the greater tortuosity of the middle- and low-ranked coal was responsible for a low methane uptake. Oxygen-containing functional groups (OFGs) on the coal surface influenced methane adsorption behavior by interacting with methane molecules. , Sun et al revealed that the gas adsorption capacity was negatively correlated with the ash content and OFGs, while positively correlated with the vitrinite content in a study via synchrotron radiation nanocomputed tomography and small-angle X-ray scattering. Thus, the intricate internal structure of coal hinders the quantitative elucidation of the impact of physicochemical structures on methane adsorption behavior via direct methodologies compared to conventional solid adsorbents. , …”

Section: Introductionmentioning

confidence: 99%

Influence of Tectonically Deformed Coal-Based Activated Carbon and Its Surface Modification on Methane Adsorption

Huan,

Guo,

Chen

et al. 2024

ACS Omega

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A series of coal-based activated carbons (CACs) were synthesized from mylonitized fat coal, a type of tectonically deformed coal (TDC) and symbiotic primary structural coal (PSC), followed by oxidative modification. The pore structure, surface oxygen-containing functional groups, and their influence on methane adsorption by CAC as the simplified coal model were investigated by using low-temperature nitrogen adsorption, Fourier transform infrared spectroscopy, Boehm titration, and X-ray photoelectron spectroscopy. The results showed that tectonic deformation fostered smaller pores, particularly ultramicropores in TDC, dominating methane adsorption. Acid-modified TDC-based activated carbons (ACs) showed higher pore parameters and oxygen-containing functional groups than those of PSC-based ACs. Nitric acid introduced abundant carboxyl groups concurrently increasing the pore volume and specific surface area (SSA), while sulfuric acid−ammonium persulfate treatment resulted in increased lactone groups and a partial collapse/blockage of nanopores. Methane adsorption experiments confirmed the importance of micropores and revealed a significant decrease in capacity owing to increased oxygen-containing functional groups as the primary role, with pore wall corrosion playing a secondary role. Thus, the study highlights the surface effects of TDC on methane adsorption and the potential for producing high-performance methane storage materials from China's tectonic coal resources.

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Impact of coal composition and pore structure on gas adsorption: a study based on a synchrotron radiation facility

Cited by 21 publications

References 43 publications

Recent Advances and Perspectives of CO₂-Enhanced Coalbed Methane: Experimental, Modeling, and Technological Development

Recent Advances and Perspectives of CO₂-Enhanced Coalbed Methane: Experimental, Modeling, and Technological Development

Methane Adsorption Interpreting with Adsorption Potential and Its Controlling Factors in Various Rank Coals

Influence of Tectonically Deformed Coal-Based Activated Carbon and Its Surface Modification on Methane Adsorption

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Impact of coal composition and pore structure on gas adsorption: a study based on a synchrotron radiation facility

Cited by 21 publications

References 43 publications

Recent Advances and Perspectives of CO2-Enhanced Coalbed Methane: Experimental, Modeling, and Technological Development

Recent Advances and Perspectives of CO2-Enhanced Coalbed Methane: Experimental, Modeling, and Technological Development

Methane Adsorption Interpreting with Adsorption Potential and Its Controlling Factors in Various Rank Coals

Influence of Tectonically Deformed Coal-Based Activated Carbon and Its Surface Modification on Methane Adsorption

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Product

Resources

About

Recent Advances and Perspectives of CO₂-Enhanced Coalbed Methane: Experimental, Modeling, and Technological Development

Recent Advances and Perspectives of CO₂-Enhanced Coalbed Methane: Experimental, Modeling, and Technological Development