Carbon capture and storage in deep geological formations is a method to reduce greenhouse gas emissions. Supercritical CO2 is injected into a reservoir and dissolves in the brine. Under the impact of pressure and temperature (P-T) the aqueous species of the CO2-acidified brine diffuse through the cap rock where they trigger CO2-water-rock interactions. These geochemical reactions result in mineral dissolution and precipitation along the CO2 migration path and are responsible for a change in porosity and therefore for the sealing capacity of the cap rock. This study focuses on the diffusive mass transport of CO2 along a gradient of decreasing P-T conditions. The process is retraced with a one-dimensional hydrogeochemical reactive mass transport model. The semi-generic hydrogeochemical model is based on chemical equilibrium thermodynamics. Based on a broad variety of scenarios, including different initial mineralogical, chemical and physical parameters, the hydrogeochemical parameters that are most sensitive for safe long-term CO2 storage are identified. The results demonstrate that P-T conditions have the strongest effect on the change in porosity and the effect of both is stronger at high P-T conditions because the solubility of the mineral phases involved depends on P-T conditions. Furthermore, modeling results indicate that the change in porosity depends strongly on the initial mineralogical composition of the reservoir and cap rock as well as on the brine compositions. Nevertheless, a wide range of conditions for safe CO2 storage is identified.
Acknowledgments
We would like to thank the anonymous reviewers for their constructive reviews that considerably improved the manuscript.
| [1] |
S. Holloway, An overview of the underground disposal of carbon dioxide, Energy Convers. Manag. 38 (1997) 193-198.
|
| [2] |
IPCC, Special Report on Carbon Dioxide Capture and Storage. Prepared by Working Group III of the International Panel of Climate Change, Cambridge University Press, Cambridge, United Kingdom/New York, NY, USA, 2005.
|
| [3] |
I. Gaus, P. Audigane, L. André, J. Lions, N. Jacquemet, P. Durst, I. Czernichowski-Lauriol, M. Azaroual, Geochemical and solute transport modelling for CO2 storage, what to expect from it? Int. J. Greenh. Gas Control 2 (4) (2008) 605-625.
|
| [4] |
J.R. Black, S.A. Carroll, R.R. Haese, Rates of mineral dissolution under CO2 storage conditions, Chem. Geol. 399 (2015) 134-144.
|
| [5] |
I. Gaus, M. Azaroual, I. Czernichowski-Lauriol, Reactive transport modelling of the impact of CO2 injection on the clayey cap rock at Sleipner (North Sea), Chem. Geol. 217 (3-4) (2005) 319-337.
|
| [6] |
A. Credoz, O. Bildstein, M. Jullien, J. Raynal, J.-C. Pétronin, M. Lillo, C. Pozo, G. Geniaut, Experimental and modeling study of geochemical reactivity between clayey caprocks and CO2 in geological storage conditions, Energy Procedia 1 (1) (2009) 3445-3452.
|
| [7] |
M. Fleury, J. Pironon, Y.M. Le Nindre, O. Bildstein, P. Berne, V. Lagneau, D. Broseta, T. Pichery, S. Fillacier, M. Lescanne, O. Vidal, Evaluating sealing efficiency of caprocks for CO2 storage: an overview of the Geocarbone Integrity Program and results, Energy Procedia 4 (2011) 5227-5234.
|
| [8] |
F. Gherardi, T. Xu, K. Pruess, Numerical modeling of self-limiting and selfenhancing caprock alteration induced by CO2 storage in a depleted gas reservoir, Chem. Geol. 244 (1-2) (2007) 103-129.
|
| [9] |
H. Tian, F. Pan, T. Xu, B.J. McPherson, G. Yue, P. Mandalaparty, Impacts of hydrological heterogeneities on caprock mineral alteration and containment of CO2 in geological storage sites, Int. J. Greenh. Gas Control 24 (2014) 30-42.
|
| [10] |
O. Bildstein, C. Kervévan, V. Lagneau, P. Delaplace, A. Crédoz, P. Audigane, E. Perfetti, N. Jacquemet, M. Jullien, Integrative modeling of caprock integrity in the context of CO2 storage: evolution of transport and geochemical properties and impact on performance and safety assessment, Oil Gas. Sci. Technol. e Rev. IFP 65 (3) (2010) 485-502.
|
| [11] |
B.L. Alemu, P. Aagaard, I.A. Munz, E. Skurtveit, Caprock interaction with CO2: a laboratory study of reactivity of shale with supercritical CO2 and brine, Appl. Geochem. 26 (12) (2011) 1975-1989.
|
| [12] |
J. Wollenweber, S. Alles, A. Busch, B.M. Krooss, H. Stanjek, R. Littke, Experimental investigation of the CO2 sealing efficiency of caprocks, Int. J. Greenh. Gas Control 4 (2) (2010) 231-241.
|
| [13] |
Z. Szabó, H. Hellevang, C. Király, E. Sendula, P. Kónya, G. Falus, S. Török, C. Szabó, Experimental-modelling geochemical study of potential CCS caprocks in brine and CO2-saturated brine, Int. J. Greenh. Gas Control 44 (2016) 262-275.
|
| [14] |
P. Bolourinejad, R. Herber, Chemical effects of sulfur dioxide co-injection with carbon dioxide on the reservoir and caprock mineralogy and permeability in depleted gas fields, Appl. Geochem. 59 (2015) 11-22.
|
| [15] |
H. Tian, T. Xu, Y. Li, Z. Yang, F. Wang, Evolution of sealing efficiency for CO2 geological storage due to mineral alteration within a hydrogeologically heterogeneous caprock, Appl. Geochem. 63 (2015) 380-397.
|
| [16] |
S. Mohd Amin, D.J. Weiss, M.J. Blunt, Reactive transport modelling of geologic CO2 sequestration in saline aquifers: the influence of pure CO2 and of mixtures of CO2 with CH4 on the sealing capacity of cap rock at 37°C and 100bar, Chem. Geol. 367 (2014) 39-50.
|
| [17] |
H. Liu, Z. Hou, P. Were, Y. Gou, L. Xiong, X. Sun, Modelling CO2-brine-rock interactions in the upper paleozoic formations of ordos basin used for CO2 sequestration, Environ. Earth Sci. 73 (5) (2015) 2205-2222.
|
| [18] |
W. van Berk, Y. Fu, H.-M. Schulz, Creation of pre-oil-charging porosity by migration of source-rock-derived corrosive fluids through carbonate reservoirs: one-dimensional reactive mass transport modelling, Pet. Geosci. 21 (2014) 35-42.
|
| [19] |
T.H. Van Pham, P. Aagaard, H. Hellevang, On the potential for CO2 mineral storage in continental flood basalts -PHREEQC batch-and 1D diffusionreaction simulations, Geochem. Trans. 13 (5) (2012).
|
| [20] |
J.L. Palandri, Y.K. Kharaka, A Compilation of Rate Parameters of Watermineral Interaction Kinetics for Application to Geochemical Modeling, California, Menlo Park, 2004.
|
| [21] |
L. Marini, Geological Sequestration of Carbon Dioxide:Thermodynamics, Kinetics, and Reaction Path Modeling, Elsevier, Amsterdam, 2007.
|
| [22] |
W. Stumm, J.J. Morgan, Aquatic Chemistry:an Introduction Emphasizing Chemical Equilibria in Natural Waters, second ed.ed., John Wiley & Sons, Inc., United States of America, 1981.
|
| [23] |
H.C. Helgeson, Solution chemistry and metamorphism, Res. Geochem. 2 (1967) 362-404.
|
| [24] |
H.C. Helgeson, PII: 0016-7037(68) 90100-2: evaluation of irreversible reactions in geochemical processes involving minerals and aqueous solutionsdI. Thermodynamic relations, Geochim. Cosmochim. Acta 32 (8) (1968) 853-877.
|
| [25] |
H.C. Helgeson (Ed.), Mass Transfer Among Minerals and Hydrothermal Solutions, second ed., Wiley, New York, 1979.
|
| [26] |
H.C. Helgeson, R.M. Garrels, F.T. Mackenzie, Evaluation of irreversible reactions in geochemical processes involving minerals and aqueous solutions: II. Applications, Geochim. Cosmochim. Acta 33 (1969) 455-481.
|
| [27] |
H.C. Helgeson, T.H. Brown, A. Nigrini, T.A. Jones, Calculation of mass transfer in geochemical processes involving aqueous solutions, Geochim. Cosmochim. Acta 34 (1970) 569-592.
|
| [28] |
A.R. Bowden, A. Rigg, Assessing reservoir performance risks in CO2 storage projects, Greenh. Gas. Control Technol. 1 (2005) 683-691.
|
| [29] |
S. Angus, B. Armstrong, K.M. De Reuck, International thermodynamic tables of the fluid state, Carbon Dioxide, Union pure Appl. Chem. 3 (1976).
|
| [30] |
H. Salimi, K.-H. Wolf, J. Bruining, The influence of capillary pressure on the phase equilibrium of the CO2-water system: application to carbon sequestration combined with geothermal energy, Int. J. Greenh. Gas Control 11 (2012) S47-S66.
|
| [31] |
E. Lindenberg, D. Wessel-Berg, Vertical convection in an aquifer column under a gas cap of CO2, Energy Convers. Manag. 38 (1997) 229-234.
|
| [32] |
C.A. Rochelle, Y.A. Moore, The Solubility of Supercritical CO2 into Pure Water and Synthetic Utsira Pore Water: British Geological Survey Report CR/02/052N, 2002.
|
| [33] |
E.T. Arning, Y. Fu, W. van Berk, H.-M. Schulz, Organic carbon remineralisation and complex, early diagenetic solideaqueous solutionegas interactions: case study ODP Leg 204, Site 1246 (Hydrate Ridge), Mar. Chem. 126 (1-4) (2011) 120-131.
|
| [34] |
E.L. Cussler, Diffusion:Mass Transfer in Fluid Systems, third ed.ed., Cambridge Univ. Press, Cambridge, 2009.
|
| [35] |
S.J. Kemp, J. Bouch, H.A. Murphy, Mineralogical Characterisation of the Nordland Shale, UK Quadrant 16, Northern North Sea, British Geological Survey, Commissioned Report, CR/01/136, 2001.
|
| [36] |
D.L. Parkhurst, C. Appelo,Description of Input for PHREEQC Version 3dA Computer Program for Speciation, Batch-reaction, One-dimensional Transport, and Inverse Geochemical Calculations: U.S. Geological Survey Techniques and Methods, 2013.
|
| [37] |
L. De Windt, A. Burnol, P. Montarnal, J. van der Lee, Intercomparison of reactive transport models applied to UO2 oxidative dissolution and uranium migration, J. Contam. Hydrol. 61 (2003) 303-312.
|
| [38] |
O. Gundogan, E. Mackay, A. Todd, Comparison of numerical codes for geochemical modelling of CO2 storage in target sandstone reservoirs, Chem. Eng. Res. Des. 89 (2011) 1805-1816.
|
| [39] |
B. Nowack, K.U. Mayer, S.E. Oswald, W. van Beinum, C.A.J. Appelo, D. Jacques, P. Seuntjens, F. Gérard, B. Jaillard, A. Schnepf, T. Roose, Verification and intercomparison of reactive transport codes to describe rootuptake, Plant Soil 285 (2006) 305-321.
|
| [40] |
C. Haase, F. Dethlefsen, M. Ebert, A. Dahmke, Uncertainty in geochemical modelling of CO2 and calcite dissolution in NaCl solutions due to different modelling codes and thermodynamic databases, Appl. Geochem. 33 (2013) 306-317.
|
| [41] |
D.L. Parkhurst, C. Appelo, Users Guide to PHREEQC (Version 2) d a Computer Program for Speciation, Batch-reaction, One-dimensional Transport and Inverse Geochemical Calculations, U.S. Geological Survey, Denver, Colorado, 1999.
|
| [42] |
D. Schäfer, Numerische Modellierung Reaktiver Prozesse Organischer Kontaminanten in Grundwasserleitern: Habilitationsschrift, 2004.
|
| [43] |
H. Hellevang, P. Aagaard, E.H. Oelkers, B. Kvamme, Can dawsonite permanently trap CO2? Environ. Sci. Technol. 39 (21) (2005) 8281-8287.
|
| [44] |
J. Rutqvist, J. Birkholzer, F. Cappa, C.-F. Tsang, Estimating maximum sustainable injection pressure during geological sequestration of CO2 using coupled fluid flow and geomechanical fault-slip analysis, Energy Convers. Manag. 48 (6) (2007) 1798-1807.
|
| [45] |
L.F. Konikow, J.D. Bredehoeft, Ground-water models cannot be validated, Adv. Water Resour. 15 (1) (1992) 75-83.
|
| [46] |
A. Verma, K. Pruess, Thermohydrological conditions and silica redistribution near high-level nuclear wastes emplaced in saturated geological formations, J. Geophys. Res. 93 (1988) 1159-1173.
|
| [47] |
P.J. Vaughan, Analysis of permeability reduction during flow of heated, aqueous fluid through westerly granite,in: C. -F. Tsang (Ed.), Coupled Processes Associated with Nuclear Waste Repositories, Acad. Pr, Orlando, Fla, 1987, pp. 529-539.
|
| [48] |
H. Pape, C. Clauser, J. Iffland, Variation of permeability with porosity in sandstone diagenesis interpreted with a fractal pore space model, Pure Appl. Geophys. 157 (4) (2000) 603-619.
|
| [49] |
M. Fleury, P. Berne, P. Bachaud, Diffusion of dissolved CO2 in caprock, Energy Procedia 1 (1) (2009) 3461-3468.
|
PDF
