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W4282033587 endingPage "124659" @default.
W4282033587 startingPage "124659" @default.
W4282033587 abstract "It is essential to understand the law by which coal adsorbs water to prevent coal and rock disasters in the mining process. However, the hydration of coal containing inorganic minerals is seldom studied. In this study, X-ray diffraction (XRD), low-pressure nitrogen adsorption (LPNA), and low-temperature carbon dioxide adsorption (TCA) experiments were performed on coal samples to obtain inorganic mineral compositions and pore structure characteristics. Then, vacuum vapor sorption analyzer (VVS) experiments were carried out on coal samples. GAB and Freundlich models were used to classify the strong adsorption region, weak adsorption region, and critical humidity for monolayer adsorption. The relationship between the amount of adsorbed water and the coal's pore structure and surface chemical properties was discussed. Then, the reason for the difference in specific surface area between N2 and H2O adsorbents was elucidated. Finally, we discuss the significance of coal-water adsorption by pyrite and clay minerals in preventing coal and dynamic rock disasters." @default.
W4282033587 created "2022-06-13" @default.
W4282033587 creator A5010383136 @default.
W4282033587 creator A5013652689 @default.
W4282033587 creator A5038023769 @default.
W4282033587 creator A5038086413 @default.
W4282033587 date "2022-09-01" @default.
W4282033587 modified "2023-10-15" @default.
W4282033587 title "Water vapor sorption properties on coals affected by hydrophilic inorganic minerals and pore fissures" @default.
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W4282033587 doi "https://doi.org/10.1016/j.fuel.2022.124659" @default.
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