Characterizing nanoscale pores and its structure in coal: Experimental investigation

Zhao, Difei; Guo, Yinghai; Wang, Geoff; Mao, Xiaoxiao

doi:10.1177/0144598719831397

Cited by 24 publications

(7 citation statements)

References 55 publications

(99 reference statements)

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“…The coal pores differ widely in pore size and pore shape and can be categorized into the matrix pore and cleat pore. − The cylindrical matrix pores with a diameter of 1–100 nm account for more than 97% of coal pore space, meaning that coal-bed methane (CBM) is primarily adsorbed in the matrix pores. , The slit-shaped cleat pores, however, are 0.1–10 μm in width and 1–3 cm in length. The cleats are well connected to one another and thus offer the major contribution to fluid mobility. , While the matrix pore contribution to fluid mobility is small, the desorption of methane (CH 4 ) therein results in significant matrix shrinkage and cleat permeability increase. , …”

Section: Introductionmentioning

confidence: 99%

Adsorption Mechanisms of High-Pressure Methane and Carbon Dioxide on Coals

et al. 2021

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Carbon dioxide (CO 2 ) geological sequestration and coal-bed methane (CBM) recovery in deep coal seams are usually operated with a pressure higher than 10 MPa. The adsorption mechanisms of methane (CH 4 ) and CO 2 on coals in such a situation, however, are not yet revealed. With the help of a high-pressure gas adsorption system, CH 4 and CO 2 adsorption isotherms were first conducted on two coal samples. Simplified local density (SLD) theory was then tailored and applied to describe the adsorption characteristics of specific CH 4 and CO 2 on coals. Next, the adsorption mechanisms of high-pressure CH 4 and CO 2 on coal samples were revealed on the basis of adsorbed and bulk density distributions within the matrix pores. The results show that the high-pressure gas adsorption on coals is different from that at low pressure. The excess adsorption capacity first increases and then decreases with pressure, and the maximum value occurs at a specific pressure referring to reverse pressure. The maximum excess adsorption capacity of CH 4 is less than that of CO 2 , while its reverse pressure is greater than that of CO 2 . The reversal of excess adsorption with pressure depends on the relative increase in adsorption and bulk phases. However, the mechanisms of adsorption reversal vary with gas types. The reversal of CH 4 excess adsorption is due to the saturation near the pore wall, while the CO 2 excess adsorption reversal is due to the dramatic bulk density changes near the critical point. Advances in the mechanism of high-pressure gas adsorption on coals suggests that coal seams deeper than 1000 m have more recovery potential, and CO 2 -enhanced coal-bed methane recovery success depends on the optimal management of its injection pressure and the associated coal swelling.

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Section: Introductionmentioning

confidence: 99%

Adsorption Mechanisms of High-Pressure Methane and Carbon Dioxide on Coals

et al. 2021

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“…27 and Zhao et al . 28 , the contact angle between mercury and pore surface was set to 130 degrees, and the surface tension of mercury was set to 0.485 J/m 2 .…”

Section: Methodsmentioning

confidence: 99%

Investigation on the pore characteristics of coal specimens with bursting proneness

Jiang

Zhang

et al. 2019

Sci Rep

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To achieve further insight into the pore characteristics, the coal specimens with different bursting proneness before and after uniaxial compression failure are tested and compared in this paper. The data of mercury intrusion test is corrected by that of low-temperature nitrogen adsorption and desorption test (LTNAD). The pore size distribution and pore volume of specimens are obtained. The pore compressibility coefficient is determined based on the fractal dimension of pore. Scanning electron microscope (SEM) and computed tomography (CT) are combined to evaluated the pore connectivity. The value of pore compressibility coefficient of specimens with high bursting proneness is larger than that of medium bursting proneness. It means more compressibility and abrupt failure under stress. The researches of both SEM and CT indicate that the pore connectivity of specimens with medium bursting proneness is better. The results show that great differences exist in the pore characteristics of specimens with high and medium bursting proneness, and uniaxial compression failure exacerbates the complexity of pore characteristics.

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“…Before MIP, the sample was dried at 373 k for 12 h, and then evacuated at 50 umHg for 8 min to discharge the residual gas and moisture. According to the suggestions of Gan et al [22] and Zhao et al [23], the contact angle between mercury and pore surface was set as 130 • and the mercury surface tension was set as 0.485 J/m 2 .…”

Section: Mipmentioning

confidence: 99%

Characteristics of Pore and Fracture of Coal with Bursting Proneness Based on DIC and Fractal Theory

Zhao

Jiang

et al. 2020

Energies

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Coal is a complex heterogeneous and anisotropic material conformed with fractal characteristics. The pore and fracture characteristics have important influence on the dynamic disasters including rock burst and gas outburst, however, the relationship between them is not accurately investigated due to inadequate research method. The pore and fracture distribution of coal with different bursting proneness were obtained by comprehensive application of MIP, LTNAD, SEM, and X-ray CT, and then fractal theory and DIC were used to research the pore and fracture characteristics. The result indicated that the modification of MIP result by LTNAD result could effectively eliminate the adverse effect of coal matrix compressibility, exactly reflect the distribution of pore and fracture in coal, and the pore distribution of coal with different bursting proneness were quite different. Gray scale image from SEM and 3D reconstruction technology based on X-ray CT could show the geological structure, fracture structure, and pore structure characteristics of coal. The study of LTNAD, SEM, and X-ray CT showed that these methods complemented each other, the coal had fractal properties, and the fractal dimension value had a positive correlation with the bursting proneness of coal sample.

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Characterizing nanoscale pores and its structure in coal: Experimental investigation

Cited by 24 publications

References 55 publications

Adsorption Mechanisms of High-Pressure Methane and Carbon Dioxide on Coals

Adsorption Mechanisms of High-Pressure Methane and Carbon Dioxide on Coals

Investigation on the pore characteristics of coal specimens with bursting proneness

Characteristics of Pore and Fracture of Coal with Bursting Proneness Based on DIC and Fractal Theory

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