Abstract
Enhanced coalbed methane (ECBM) in deep coal seams is being actively investigated around the world. Since the in situ coal seams are always saturated with water, methane sorption behavior on coal in the presence of water can help accurately assess the amount of recoverable methane. Thus, methane sorption isotherms have been measured on a high-rank anthracite, a low-volatile bituminous, a middle-volatile bituminous and a high-volatile bituminous coal with the manometric technology at 30 °C under six different moisture contents. The Dubinin–Astakhov (D–A) equation was used to fit the experimental sorption isotherm data. In all cases, the moisturized coals exhibited lower sorption capacity than the corresponding dry materials and moisture has a significant effect on CH4 sorption capacity. The maximum sorption capacity, V 0, displays a linear decline with the moisture content for the Changcun and Malan samples, but it is nonlinear for the other two coal samples. The net heat of CH4 sorption, βE, is also reduced by the presence of water, but varies only slightly between a relatively small span of about 8.8 and 10.0 kJ mol−1 for the dry samples studied, despite the difference in coal rank. In addition, the maximum sorption capacity of CH4 in dry coals presents the typical “U-shape” trend with coal rank. Moisture has a greater impact on the sorption capacity in low-rank coals than that in high-rank coals. The mechanisms responsible for the effect of moisture on CH4 sorption among various rank coals are also presented. The pore-blocking effect is the main influencing factor for high-rank anthracite, whereas, the competition sorption is dominant for low-rank coals.
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References
Amankwah, K.A.G., Schwarz, J.A.: A modified approach for estimating pseudovapor pressures in the application of the Dubinin–Astakhov equation. Carbon 33, 1313–1319 (1995)
An, F.H., Cheng, Y.P., Wu, D.M., Wang, L.: The effect of small micropores on methane adsorption of coals from Northern China. Adsorption 19, 83–90 (2013)
Billemont, P., Coasne, B., Weireld, G.D.: An experimental and molecular simulation study of the adsorption of carbon dioxide and methane in nanoporous carbons in the presence of water. Langmuir 27, 1015–1024 (2011)
Billemont, P., Coasne, B., De Weireld, G.: Adsorption of carbon dioxide-methane mixtures in porous carbons: effect of surface chemistry. Adsorption 20, 453–463 (2014)
Brennan, J.K., Thomson, K.T., Gubbins, K.E.: Adsorption of water in activated carbons: effects of pore blocking and connectivity. Langmuir 18, 5438–5447 (2002)
Busch, A., Gensterblum, Y.: CBM and CO2-ECBM related sorption processes in coal: a review. Int. J. Coal Geol. 87, 49–71 (2011)
Charrière, D., Behra, P.: Water sorption on coals. J. Colloid Interf. Sci. 344, 460–467 (2010)
Clarkson, C.R., Bustin, R.M.: Binary gas adsorption/desorption isotherms: effect of moisture and coal composition upon carbon dioxide selectivity over methane. Int. J. Coal Geol. 42, 241–271 (2000)
Clarkson, C.R., Bustin, R.M., Levy, J.H.: Application of the mono/multilayer and adsorption potential theories to coal methane adsorption isotherms at elevated temperature and pressure. Carbon 35, 1689–1705 (1997)
Crosdale, P.J., Moore, T.A., Mares, T.E.: Influence of moisture content and temperature on methane adsorption isotherm analysis for coals from a low-rank biogenically-sourced gas reservoir. Int. J. Coal Geol. 76(1), 167 (2008)
Day, S., Fry, R., Sakurovs, R.: Swelling of moist coal in carbon dioxide and methane. Int. J. Coal Geol. 86, 187–203 (2011)
Day, S., Sakurovs, R., Weir, S.: Supercritical gas sorption on moist coals. Int. J. Coal Geol. 74, 203–214 (2008)
Dubinin, M.M.: Porous structure and adsorption properties of active carbons, chemistry and physics of carbon, pp. 51–120. Marcel Dekker Inc., New York (1966)
Fitzgerald, J.E., Pan, Z.J., Sudibandriyo, M., Robinson Jr, R.L., Gasem, K.A.M., Reeves, S.: Adsorption of methane, nitrogen, carbon dioxide and their mixtures on wet Tiffany coal. Fuel 84, 2351–2363 (2005)
Gasparik, M., Ghanizadeh, A., Bertier, P., et al.: High-pressure methane sorption isotherms of black shales from the Netherlands. Energy Fuels 26, 4995–5004 (2012)
Gensterblum, Y., Merkel, A., Bush, A., Krooss, B.M.: High-pressure CH4 and CO2 sorption isotherms as a function of coal maturity and the influence of moisture. Int. J. Coal Geol. 118, 45–57 (2013)
Gensterblum, Y., Busch, A., Krooss, B.M.: Molecular concept and experimental evidence of competitive adsorption of H2O, CO2 and CH4 on organic material. Fuel 115, 581–588 (2014)
Goodman, A.L., Busch, A., Bustin, R.M., et al.: Interlaboratory comparison II: CO2 isotherms measured on moisture-equilibrated Argonne premium coals at 55°C and up to 15MPa. Int. J. Coal Geol. 72, 153–164 (2007)
Goodman, A.L., Busch, A., Duffy, G.J., et al.: An inter-laboratory comparison of CO2 isotherms measured on Argonne premium coal samples. Energy Fuels 18, 1175–1182 (2004)
Goodman, A.L., Campus, L.M., Schroeder, K.T.: Direct evidence of carbon dioxide sorption on Argonne premium coals using attenuated total reflectance-Fourier transform infrared spectroscopy. Energy Fuels 19, 471–476 (2005)
Guo, H.J., Chen, Y.P., Wang, L., et al.: Experimental study on the effect of moisture on low-rank coal adsorption characteristics. J. Nat. Gas Sci. Eng. 24, 245–251 (2015)
Hao, S.X., Chu, W., Jiang, Q.: Yu XP (2014) Methane adsorption characteristics on coal surface above critical temperature through Dubinin–Astakhov model and Langmuir model. Colloids Surf. A 444, 104–113 (2014)
Hao, S.X., Wen, J., Yu, X.P., Chu, W.: Effect of the surface oxygen groups on methane adsorption on coals. Appl. Surf. Sci. 264, 433–442 (2013)
He, J., Shi, Y., Ahn, S., et al.: Adsorption and desorption of CO2 on Korean coal under subcritical to supercritical conditions. J. Phys. Chem. B 114(14), 4854–4861 (2010)
Hodot, B.B.: Outburst of coal and coalbed gas (Chinese Translation), pp. 18–33. China Coal Industry Press, Beijing (1966)
Jin, D.L., Lu, X.Q., Zhang, M.M., et al.: The adsorption behaviour of CH4 on microporous carbons: effects of surface heterogeneity. Phys. Chem. Chem. Phys. 16, 11037–11046 (2014)
Joubert, J.I., Grein, C.T., Bienstock, D.: Sorption of methane in moist coal. Fuel 52, 181–185 (1973)
Joubert, J.I., Grein, T., Bienstock, D.: Effect of moisture on the methane capacity of American coals. Fuel 53, 186–191 (1974)
Kelemen, S.R., Kwaitek, L.M.: Physical properties of selected block Argonne Premium bituminous coal related to CO2, CH4 and N2 adsorption. Int. J. Coal Geol. 77, 2–9 (2009)
Khosrokhavar, R., Wolf, K.H., Bruining, H.: Sorption of CH4 and CO2 on a carboniferous shale from Belgium using a manometric setup. Int. J. Coal Geol. 128–129, 153–161 (2014)
Klier, K., Zettlemoyer, A.C.: Water at interfaces: molecular structure and dynamics. J. Colloid Interface Sci. 58, 216–229 (1977)
Krooss, B.M., van Bergen, F., Gensterblum, Y., Siemons, N., Pagnier, H.J.M., David, P.: High-pressure methane and carbon dioxide adsorption on dry and moisture-equilibrated Pennsylvanian coals. Int. J. Coal Geol. 51, 69–92 (2002)
Lama, R.D., Bodziony, J.: Outburst of gas, coal and rock in underground coal mines. R.D. Lama and Associates, Wollongong (1996)
Laxminarayana, C., Crosdale, P.J.: Role of coal type and rank on methane sorption characteristics of Bowen Basin Australia coals. Int. J. Coal Geol. 40, 309–325 (1999)
Laxminarayana, C., Crosdale, P.J.: Controls on methane sorption capacity of Indian coals. AAPG Bull 86, 201–212 (2002)
Lee, S.-Y., Park, S.-J.: Determination of the optimal pore size for improved CO2 adsorption in activated carbon fibers. J. Colloid Interf. Sci. 389, 230–235 (2013)
Levy, J.H., Day, S.J., Killingley, J.S.: Methane capacities of Bowen Basin coals related to coal properties. Fuel 76, 813–819 (1997)
Li, D.Y., Liu, Q.F., Weniger, P., Gensterblum, Y., Bush, A., Krooss, B.M.: High-pressure sorption isotherms and sorption kinetics of CH4 and CO2 on coals. Fuel 89, 569–580 (2010)
Luo, J.J., Liu, Y.F., Sun, W.J., et al.: Influence of structural parameters on methane adsorption over activated carbon: evaluation by using D–A model. Fuel 123, 241–247 (2014)
Marecka, A., Mianowiski, A.: Kinetics of CO2 and CH4 sorption on high rank coal at ambient temperatures. Fuel 77, 1691–1696 (1998)
Marsh, H., Rand, B.: The characterization of microporous carbons by means of the dubinin-radushkevich equation. J. Colloid Interf. Sci. 33, 101–116 (1970)
Mohammad, S.A., Gasem, K.A.: Modeling the competitive adsorption of CO2 and water at high pressures on wet coals. Energy Fuels 26, 557–568 (2012)
Nie, B.S., Li, X.C., Cui, Y.J., Lu, H.Q.: Theory and application of gas migration in coal seam, pp. 24–40. Science Press, Beijing (2014)
Nie, B.S., Liu, X.F., Yang, L.L., et al.: Pore structure characterization of different rank coals using gas adsorption and scanning electron microscopy. Fuel 158, 908–917 (2015)
Nishino, J.: Adsorption of water vapor and carbon dioxide at carboxylic functional groups on the surface of coal. Fuel 80, 757–764 (2001)
Okolo, G.N., Everson, R.C., Neomagus, H.W.J.P., et al.: Comparing the porosity and surface areas of coal as measured by gas adsorption, mercury intrusion and SAXS techniques. Fuel 141, 293–304 (2015)
Ozdemir, E., Schroeder, K.: Effect of moisture on adsorption isotherms and adsorption capacities of CO2 on coals. Energy Fuels 23, 2821–2831 (2009)
Pan, Z., Connell, L.D., Camilleri, M., Connelly, L.: Effects of matrix moisture on gas diffusion and flow in coal. Fuel 89, 3207–3217 (2010a)
Pan, Z., Connell, L.D., Camilleri, M.: Laboratory characterisation of coal reservoir permeability for primary and enhanced coalbed methane recovery. Int. J. Coal Geol. 82, 252–261 (2010b)
Peng, D.Y., Robinson, D.B.: A new two-constant equation of state. Ind. Eng. Chem. Fundam. 15(1), 59–64 (1976)
Pini, R., Storti, G., Mazzotti, M.: A model for enhanced coal bed methane recovery aimed at carbon dioxide storage. Adsorption 17, 889–900 (2011)
Prinz, D., Littke, R.: Development of the micro- and ultramicroporous structure of coals with rank as deduced from the accessibility to water. Fuel 84, 1645–1652 (2005)
Qiu, N.X., Xue, Y., Guo, Y., et al.: Adsorption of methane on carbon models of coal surface studied by the density functional theory including dispersion correction (DFT-D3). Comput. Theor. Chem. 992, 37–47 (2012)
Radovic, L.R., Menon, V.C., Lenoyleon, C.A., Kyotani, T., Danner, R.P.: On the porous structure of coals: evidence for an interconnected but constricted micropore system and implications for coalbed methane recovery. Adsorption 3, 221–232 (1997)
Rahman, K.A., Loh, W.S., Yanagi, H., Chakraborty, A., Saha, B.B., Chun, W.G., Ng, K.C.: Experimental adsorption isotherm of methane onto activated carbon at suband supercritical temperatures. J. Chem. Eng. Data 55, 4961–4967 (2010)
Romanov, V., Soong, Y.: Long-term CO2 sorption on upper freeport coal powder and lumps. Energy Fuels 22, 1167–1169 (2008)
Sakurovs, R., Day, S., Weir, S., Duffy, G.: Temperature dependence of sorption of gases by coals and charcoals. Int. J. Coal Geol. 73, 250–258 (2008)
Schroeder, K., Ozdemir, E., Morsi, B.I.: Sequestration of carbon dioxide in coal seams. In: First National Carbon Sequestration Conference Proceedings, DOE/NETL, 1–10 (2001)
Siemons, N., Busch, A., Bruining, H., Krooss, B.M., Gensterblum, Y.: Assessing the kinetics and capacity of gas adsorption in coals by a combined adsorption/diffusion method, SPE 84340. In: Annual Technical Conference and Exhibition, Denver 5–8 Oct 203
Stefańska, G.C., Brzóska, K., Winnicki, J.: Sorption of water vapour on exinite concentrates. Adsorption 4, 313–319 (1998)
Sun, W.J., Feng, Y.Y., Jiang, C.F., Chu, W.: Fractal characterization and methane adsorption features of coal particles taken from shallow and deep coalmine layers. Fuel 155, 7–13 (2015)
Švábová, M., Weishauptová, Z., Prˇibyl, O.: The effect of moisture on the sorption process of CO2 on coal. Fuel 92, 187–196 (2012)
Švábová, M., Weishauptová, Z., Prˇibyl, O.: Water vapour adsorption on coal. Fuel 90, 1892–1899 (2011)
Wang, F., Cheng, Y.P., Lu, S.Q., et al.: Influence of coalification on the pore characteristics of middle: high rank coal. Energy Fuels 28, 5729–5736 (2014a)
Wang, G.C., Ju, Y.W., Yuan, B., et al.: Coal-bearing organic shale geological evaluation of Huannan-Huaibei coalfield. China Energy Fuels 28, 5031–5042 (2014b)
Wang, K., Zang, J., Feng, Y.F., Wu, Y.Q.: Effects of moisture on diffusion kinetics in Chinese coals during methane desorption. J. Nat. Gas Sci. Eng. 21, 1005–1014 (2014c)
Weniger, P., Kalkreuth, W., Busch, A., Krooss, B.M.: High-pressure methane and carbon dioxide sorption on coal and shale samples from the Paraná Basin, Brazil. Int. J. Coal Geol. 84, 190–205 (2010)
Wood, G.O.: Affinity coefficients of the Polanyi/Dubinin adsorption isotherm equation, A review with compilations and correlations. Carbon 39, 343–356 (2001)
Zhang, D.F., Cui, Y.J., Liu, B., et al.: Supercritical pure methane and CO2 sorption on various rank coals of China: experiments and modeling. Energy Fuels 25, 1891–1899 (2011)
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Nie, B., Liu, X., Yuan, S. et al. Sorption charateristics of methane among various rank coals: impact of moisture. Adsorption 22, 315–325 (2016). https://doi.org/10.1007/s10450-016-9778-9
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DOI: https://doi.org/10.1007/s10450-016-9778-9