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Prospects for CO2 carbonation and storage in Upper Miocene sandstone of Sava Depression, Croatia

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Upper Miocene sandstones in the Sava Depression (Northern Croatia) are potential targets for carbon dioxide (CO2)-based enhanced oil recovery (EOR) processes or mineral carbonation with reservoir brine. In general, sandstone lithology, even rich with aluminosilicate minerals, is not the most favourable rock medium for efficient sequestration of CO2 in minerals. However, CO2 is naturally sequestered in minerals when CO2 is injected into sandstone reservoirs and subdued to carbonation. The timescale of such sequestration is on the order of 104–105 years. Upper Miocene sandstones in the Sava Depression could incorporate up to 25% of aluminosilicate minerals (10% K-feldspars) and up to 20% dolomites and often laterally transition between pelitic and psammitic lithofacies, rich in clay minerals (15% micas). Total volumes are approximately 107 and 62 million m3 (approximately 268 and 155 million t of rocks), respectively for the potential injection reservoirs in the Ivanić Field. Oil saturation in the injection intervals is estimated to be approximately 14.8 and 4.1 million m3 respectively. Geochemical analogies and mineralogy can be used to support predictions for the low percentages of injected CO2 that may be stored during carbonation and form secondary minerals
Rocznik
Strony
91--104
Opis fizyczny
Bibliogr. 43 poz., rys., tab., wykr.
Twórcy
  • Veselišće 2c, Zagreb, Croatia
autor
  • INA-Industry of Oil Plc., Av. V. Holjevca 10, Zagreb, Croatia
autor
  • INA-Industry of Oil Plc., Šubićeva 29, Zagreb, Croatia
  • University of Zagreb, Faculty of Mining, Geology and Petroleum Engineering, Pierottijeva 6, Zagreb, Croatia
  • INA-Industry of Oil Plc., Šubićeva 29, Zagreb, Croatia
autor
  • University of Zagreb, Faculty of Mining, Geology and Petroleum Engineering, Pierottijeva 6, Zagreb, Croatia
Bibliografia
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  • 3. Bodor, M., Vlad, M., Balta, S., 2011. Overview of latest mineral carbonation techniques for carbon dioxide sequestration. Tehnomus, 18: 289-296.
  • 4. Carroll, S.A., McNab, W.W., Torres, S.C., 2011. Experimental study of cement - sandstone/shale - brine - CO2 interactions. Geochemical Transactions, 12.
  • 5. Gerdemann, S.J., O'Connor, W.K., Dahlin, D.C., Penner, L.R., Rush, H., 2007. Ex situ aqueous mineral carbonation. Environmental Science and Technology, 41: 2587-2593.
  • 6. Goričnik, B., Domitrovic, D., 2003. Laboratory research of CO2 EOR potential in the mature oilfields in the Republic of Croatia (in Croatian with English summary). Naftaplin, (1): 5-12.
  • 7. Hansen, L.D., Dipple, G.M., Gordon, T.M., Kellett, D.A., 2005. Carbonated serpentinite (listwanite)at Atlin, British Columbia: a geological analogue to carbon dioxide sequestration. Canadian Mineralogist, 43: 225-239.
  • 8. Hangx, S.J.T., Spiers, C.J., 2009. Coastal spreading of olivine to control atmospheric CO2 concentrations: a critical analysis of viability. International Journal of Greenhouse Gas Control, 3: 757-767.
  • 9. Huijgen, W.J.J., Comans, R.N.J., 2005. Mineral CO2 Sequestration by Carbonation of Industrial Residues. ECN publication, www.ecn.nl
  • 10. International Energy Agency. Greenhouse Gas R&D Programme (IEA-GHG), 2000. CO2 storage as carbonate minerals, prepared by CSMA Consultants Ltd, PH3/17, Cheltenham, U.K.
  • 11. Lackner, K.S., Butt, D.P., Wendt, C.H., 1997. Progress on binding CO2 in mineral substrates. Energy Conversion and Management, 38: 259-264.
  • 12. Liu, N., Liu, L., Qu, X., Yang, H., Wang, L., Zhao, S., 2011. Genesis of authigene carbonate minerals in the Upper Cretaceous reservoir, Honggang Anticline, Songliao Basin: a natural analogue for mineral trapping of natural CO2 storage. Sedimentary Geology, 237: 166-178.
  • 13. Koenen, M., Wasch, L.J., Zalinge, M.E. van, Nelskamp, S., 2013.
  • 14. Werkendam, the Dutch natural analogue for CO2 storage long-term mineral reactions. Energy Procedia, 37: 3452-3460.
  • 15. Malvič, T., 2008. Production of porosity map by kriging in sandstone reservoirs, case study from the Sava Depression. Kartografija i Geoinformacije, 9: 12-19.
  • 16. Malvič, T., 2012. Review of Miocene shallow marine and lacustrine depositional environments in Northern Croatia. Geological Quarterly, 56 (3): 493-504.
  • 17. Malvič, T., Velič, J., 2011. Neogene tectonics in Croatian part of the Pannonian Basin and reflectance in hydrocarbon accumulations. In: New Frontiers in Tectonic Research: at the Midst of Plate Convergence (ed. U. Schattner): 215-238. InTech, Rijeka.
  • 18. McKelvy, M.J., Chizmeshya, A.V.G., Soignard, E., Marzke, R., Wolf, G.H., Béarat, H., Doss, B., 2006. Laboratory investigation of Fluid/Solid sequestration reaction processes under in situ sequestration process conditions, 41. Proceedings of the 31 st International Technical Conference on Coal Utilization and Fuel Systems, Clearwater, 21-26 May, 2006: 384-400.
  • 19. Novak, K., Malvic, T., Simon, K., 2012. Increased hydrocarbon recovery and CO2 management, a Croatian example. Environmental Earth Sciences, 68: 1187-1197.
  • 20. Novak, K., Malvič, T., Velič, J., Simon, K., 2013. Increased hydrocarbon recovery and CO2 storage in Neogene sandstones, a Croatian example: part II. Environmental Earth Sciences, doi: 10.1007/s 12665-013-2756-6
  • 21. Novak Zelenika, K., 2012. Deterministic and Stochastic Geological Models of Upper Miocene Sandstones Reservoirs at the Kloštar Oil and Gas Field (in Croatian with English summary). Dissertation, University of Zagreb.
  • 22. Novak Zelenika, K., Velič, J., Malvič, T., 2013. Local sediment sources and palaeoflow directions in Upper Miocene turbidites of the Pannonian Basin System (Croatian part), based on map- ping of reservoir properties. Geological Quarterly, 57 (1): 16-30.
  • 23. Novosel, D., 2009. The Effect of the Carbon Dioxide on the Tertiary Exploration Phase at the Ivanic Oil Field (in Croatian with English summary). Dissertation, University of Zagreb.
  • 24. O'Connor, W.K., Dahlin, D.C., Nilsen, D.N., Rush, G.E., Walters, R.P., Turner, P.C., 2001. Carbon dioxide sequestration by direct mineral carbonation: results from recent studies and current status. DOE/ARC-2001-029. In: Proceedings of the First National Conference on Carbon Sequestration, National Energy Technology Laboratory, U.S. Department of Energy, Washington, 14-17 May, 2001.
  • 25. O'Connor, W.K., Dahlin, D.C., Rush, G.E., Gerdemann, S.J., Penner, L.R., Nilsen, R.P., 2005. Aqueous Mineral Carbonation: Mineral Availability, Pretreatment, Reaction Parametrics, and Process Studies. DOE/ARC-TR-04-002, Albany Research Center, New York.
  • 26. Penner, L.R., O'Connor, W.K., Dahlin, D.C., Rush, G.E., Gerdemann, S.J., 2004. Energy and economic considerations for ex-situ aqueous mineral carbonation, D0E/ARC-2004-028. U.S. Department of Energy, Albany Research Center, Oregon.
  • 27. Perič, M., Kovač, S., 2003. Simulation study of enhanced oil recovery process by C02 injection applying a multi-component COMP II (in Croatian with English summary). Naftaplin, (1): 13-25
  • 28. Sečen, J., 2006. Enhance Oil Recovery Methods (In Croatian), 1st edn. INA-Naftaplin, Zagreb.
  • 29. Seifritz, W., 1990. C02 disposal by means of silicates. Nature, 345: 486.
  • 30. Sipilä, J., Teir, S., Zevenhoven, R., 2008. Carbon Dioxide Sequestration by Mineral Carbonation - Literature Review Update 2005-2007. Cbo Akademi Univ., Heat Engineering Lab. report VT 2008-1.
  • 31. Taber, J.J., Martin, F.D., Seright, R.S., 1997. EOR criteria revisited. Part 2: application and impact of oil prices. SPE Reservoir Engineering, 12: 199-205.
  • 32. Tadej, J., Marič-Durekovič, Ž., Slavkovic, R., 1996. Porosity, cementation, diagenesis and their influence on the productive capibility of sandstone reservoirs in the Sava Depression (Croatia). Geologia Croatica, 49: 311-316.
  • 33. Velič, J., Malvič, T., Cvetkovič, M., 2011. Palinspastic reconstruction of synsedimentary tecton i cs of Neogene and Quaternary sediments in the Kloštar Field (Sava depression, Pannonian Basin, Croatia). Zeitschrift der Deutschen Gesellschaft für Geowissenschaften, 162: 193-201.
  • 34. Vrbanac, B., Velič, J., Malvič, T., 2010. Sedimentation of deep-waterturbidites in the SW part of the Pannonian Basin. Geologica Carpathica, 61: 55-69.
  • 35. Wilkinson, M., Haszeldine, R.S., Fallick, A.E., Odling, N., Stoker, S.J., Gatliff, R.W., 2009. CO2-mineral reaction in a natural analogue for CO2 storage-implications for modeling. Journal of Sedimentary Research, 79: 486-494.
  • 36. Xu, T., Apps, J.A., Pruess, K., 2004. Numerical simulation to study mineral trapping for CO2 disposal in deep aquifers. Applied Geochemistry, 19: 917-936.
  • 37. Xu, T., Apps, J.A., Pruess, K., Yamamoto, H., 2008. Numerical modeling of injection and mineral trapping of CO2 with H2S and SO2 in a Sandstone Formation. Chemical Geology, 242: 319-346.
  • 38. Yajima, T., Okamoto, I., Ohsumi, T., Ninomiya, A., Yukihiro, M., Takayuki, K., 2006. Experimental studies of CO2 fixation by serpentinite. In: Proceedings of the 8th International Conference on Greenhouse Gas Control Technologies, Trondheim, 19-22 June, 2006.
  • 39. Yu, M., Liu, L., Yu, Z., Liu, N., Yang, H., Qu, X., 2014. Dawsonite fixation of mantle CO2 in the cretaceous Songliao Basin, Northeast China: a natural analogue for CO2 mineral trapping in oilfields. International Geology Review, 56: 1792-1812.
  • 40. Zevenhoven, R., Eloneva, S., Teir, S., 2006. Chemical fixation of CO2 in carbonates: routes to valuable products and long-term storage. Catalysis Today, 115: 73-79.
  • 41. Zevenhoven, R., Teir, S., Eloneva, S., Aatos, S., Sorjonen-Ward, P., 2007. CO2 sequestration by carbonation of minerals and industrial by-products in Finland, 72. In: Proceedings of the R'07, Davos, 3-5 September, 2007.
  • 42. Zevenhoven, R., Wiklund, A., Fagerlund, J., Eloneva, S., In't Veen, B., Geerlings, H., Mossel, G. van, Boerrigter, H., 2010. Carbonation of calcium-containing mineral and industrial by-products. Frontiers of Chemical Engineering in China, 4: 110-119.
  • 43. Zevenhoven, R., Fagerlund, J., Björklöf, T., Mäkelä, M., Eklund, O., 2012. Carbon dioxide mineralisation and integration with flue gas desulphurisation applied to a modern coal-fired power plant. Proceedings of EC0S2012, Perugia, Italy, June, 2012 - Paper 179.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-8b8139b4-9872-47eb-a4ad-abf1946ed27c
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