• Development and Application of Micromodel for Visualization of Supercritical CO2 Migration in Pore-scale
  • Park, Bogyeong;Lee, Minhee;Wang, Sookyun;
  • Department of Energy Resources Engineering, Pukyong National University;Department of Earth Environmental Sciences, Pukyong National University;Department of Energy Resources Engineering, Pukyong National University;
  • 공극 규모에서의 초임계상 이산화탄소 거동 가시화를 위한 마이크로모델의 개발과 적용
  • 박보경;이민희;왕수균;
  • 부경대학교 에너지자원공학과;부경대학교 지구환경과학과;부경대학교 에너지자원공학과;
References
  • 1. Arendt, B., Dittmar, D., and Eggers, R., 2004, Interaction of interfacial convection and mass transfer effects in the system CO2-water, Int. J. Heat Mass Transfer, 47, 3649-3657.
  •  
  • 2. Arts, R., Eiken, O., Chadwick, A., Zweigel, P., and van der Meer, L., 2004, Monitoring of CO2 injected at Sleipner using time-lapse seismic data, Energy, 29, 1383-1392.
  •  
  • 3. Bachu, S. and Bennion, B., 2008, Interfacial tension between CO2, freshwater, and brine in the range of pressure from (2 to 27) MPa, temperature from (20 to 125) ℃, and water salinity from (0 to 334000) mg·L−1 , J. Chem. Eng. Data, 54(3), 765-775.
  •  
  • 4. Bachu, S., 2008, CO2 storage in geological media: Role, means, status and barriers to deployment, Prog. Energ. Combust., 34, 254-273.
  •  
  • 5. Bateman, K., Turner, G., Pearce, J.M., Noy, D.J., Birchall, D., and Rochelle, C.A., 2005, Large-scale column experiment: study of CO2, porewater, rock reactions and model test case, Oil Gas Sci. Technol., 60, 161-175.
  •  
  • 6. Chalbaud, C., Robin, M., Lombard, J.-M., Martin, F., Egermann, P., and Bertine, H., 2009, Interfacial tension measurements and wettability evaluation for geological CO2 storage, Adv. Wat. Resour., 32, 98-109.
  •  
  • 7. Chiquet, P., Broseta, D., and Thibeau, S., 2007, Wettability alteration of caprock minerals by carbon dioxide, Geofluids, 7(2), 112-122.
  •  
  • 8. Dullien, F.A.L., 1992, Porous Media-Fluid Transport and Pore Structure, Academic Press, San Diego, California, p. 574.
  •  
  • 9. Er, V., Babadagli, T., and Xu, Z., 2010, Pore-scale investigation of the matrixfracture interaction during CO2 injection in naturally fractured oil reservoirs, Energy Fuel, 24, 1421-1430.
  •  
  • 10. IPCC (Intergovernmental Panel on Climate Change), 2005, Carbon dioxide capture and storage, Cambridge University Press, Cambridge, 431 p.
  •  
  • 11. Juanes, R., Spiteri, E.J., Orr Jr., F.M., and Blunt, M.J., 2006, Impact of relative permeability hysteresis on geological CO2 storage, Water Resour. Res., 42, W12418.
  •  
  • 12. Jung, J.W. and Wan, J., 2012, Supercritical CO2 and ionic strength effects on wettability of silica surfaces: equilibrium contact angle measurements, Energy Fuels, 26(9), 6053-6059.
  •  
  • 13. Kihm, J.H. and Kim, J.M., 2013, Probabilistic preliminary evaluation of geologic carbon dioxide storage capacity of the hasandong formation, Gyeongsang basin, Korea, J. Geol. Soc. Korea, 49, 373-388.
  •  
  • 14. Kim, Y., Wan, J., Kneafsey, T.J., and Tokunaga, T.K., 2012, Dewetting of silica surfaces upon reactions with supercritical CO2 and brine: pore-scale studies in micromodels, Environ. Sci. Technol., 46(7), 4228-4235.
  •  
  • 15. Krevor, S., Pini, R., Li, B., and Benson, S.M., 2011, Capillary heterogeneity trapping of CO2 in a sandstone rock at reservoir conditions, Geophys. Res. Lett., 38(15), L15401, doi:10.1029/ 2011GL048239.
  •  
  • 16. Li, X., Boek, E., Maitland, G.C., and Trusler, J.P.M., 2012, Interfacial tension of (brines+CO2): (0.864 NaCl+0.136 KCl) at temperatures between (298 and 448) K, pressures between (2 and 50) MPa, and total molalities of (1 to 5) molkg-1, J. Chem. Eng. Data, 57, 1078-1088.
  •  
  • 17. Massoudi, R. and King Jr., A.D., 1975, Effect of pressure on the surface tension of aqueous solutions. Adsorption of hydrocarbon gases, carbon dioxide, and nitrous oxide on aqueous solutions of sodium chloride and tetrabutylammonium bromide at 25℃, J. Phys. Chem., 79(16), 1670-1675.
  •  
  • 18. Mills, J., Riazi, M., and Sohrabi, M., 2011, Wettability of common rock-forming minerals in a CO2-brine system at reservoir conditions, Proceedings of the International Symposium of the Society of Core Analysts, Austin, Texas, 1-12.
  •  
  • 19. Riazi, M., Sohrabi, M., Bernstone, C., Jamiolahmady, M., and Ireland, S., 2011, Visualisation of mechanisms involved in CO2 injection and storage in hydrocarbon reservoirs and water-bearing aquifers, Chem. Eng. Res. Des., 89, 1827-1840.
  •  
  • 20. Schaeff, H.T. and McGrail, B.P., 2004, Direct measurements of pH in H2O-CO2 brine mixtures to supercritical conditions, Proceedings of the 7th International Conference on Greenhouse Gas Control Technologies(GHGT-7), Vancouver, Canada.
  •  
  • 21. Wang, Y., Zhang, C.Y., Wei, N., Oostrom, M., Wietsma, T.W., Li, X.C., and Bonneville, A., 2013, Experimental study of crossover from capillary to viscous fingering for supercritical CO2- water displacement in a homogeneous pore network, Environ. Sci. Technol., 47, 212-218.
  •  
  • 22. Yang, D., Gu, Y., and Tontiwachwuthikul, P., 2008, Wettability determination of the reservoir brine-reservoir rock system with dissolution of CO2 at high pressures and elevated temperatures, Energy Fuels, 22, 504-509.
  •  
  • 23. Zhang, C., Oostrom, M., Grate, J.W., Wietsma, T.W., and Warner, M.G., 2011, Liquid CO2 displacement of water in a dual-permeability pore network micromodel, Environ. Sci. Technol., 45(17), 7581-7588.
  •  

This Article

  • 2015; 20(4): 73-82

    Published on Aug 31, 2015

  • 10.7857/JSGE.2015.20.4.073
  • Received on Jun 17, 2015
  • Revised on Jul 1, 2015
  • Accepted on Jul 2, 2015

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