M. Alkattan, E. H. Oelkers, J. L. Dandurand, and J. Schott,

, 25 to 80°C, Chem. Geol, vol.151, pp.199-214

S. Bachu, W. D. Gunter, and E. H. Perkins, Aquifer Disposal of CO 2 : Hydrodynamic and Mineral Trapping, Energy Convers. Mgmt, vol.35, pp.269-279, 1994.

J. Baumann, D. Buhmann, W. Dreybrodt, and H. D. Schulz, Calcite Dissolution Kinetics in Porous Media, Chem. Geol, vol.53, pp.219-228, 1985.

R. A. Berner, Rate Control of Mineral Dissolution under Earth Surface Conditions, Am. Jour. Sci, vol.278, pp.1235-1252, 1978.

S. Brunauer, P. H. Emmett, and E. Teller, Adsorption of Gases in Multimolecular Layers, Jour. Am. Chem. Soc, vol.60, pp.309-319, 1938.

D. Buhmann and W. Dreybrodt, The Kinetics of Calcite Dissolution and Precipitation in Geologically Relevant Situations of Karst Areas. 1. Open System, Chem. Geol, vol.48, pp.189-211, 1985.

D. Buhmann and W. Dreybrodt, The Kinetics of Calcite Dissolution and Precipitation in Geologically Relevant Situations of Karst Areas. 2. Closed System, Chem. Geol, vol.53, pp.109-124, 1985.

D. Buhmann and W. Dreybrodt, Calcite Dissolution in the System H 2 O-CO 2-CaCO 3 with Participation of Foreign Ions, Chem. Geol, vol.64, pp.89-102, 1987.

T. E. Burch, K. L. Nagy, and A. C. Lasaga, Free Energy Dependence of Albite Dissolution Kinetics at 80°C and pH 8.8, Chem. Geol, vol.105, pp.137-162, 1993.

E. Busenberg and L. N. Plummer, A Comparative Study of the Dissolution and Crystal Growth Kinetics of Calcite and Aragonite, Studies in, vol.1578, pp.139-168, 1986.

W. H. Casey, Heterogeneous Kinetics and Diffusion Boundary Layers: the Example of Reaction in Fracture, Jour. Geophys. Res, vol.92, pp.8007-8013, 1987.

C. Cassou, Modélisation numérique des interactions eauroche, 2000.

L. Chou and R. Wollast, Steady State Kinetics and Dissolution Mechanisms of Albite, Amer. Jour. Sci, vol.285, pp.963-993, 1985.

F. T. Chung, R. A. Jones, and T. H. Nguyen, Measurements and Correlations of the Physical Properties of CO 2Heavy Crude Oil Mixtures, SPE Reservoir Engineering, vol.3, pp.822-828, 1988.

A. Coudrain-ribstein, P. Gouze, and G. De-marsily, Temperature-Carbon Dioxide Partial Pressure Trends in Confined Aquifers, Chem. Geol, vol.145, pp.73-89, 1998.

J. L. Devidal, J. Schott, and J. L. Dandurand, An Experimental Study of Kaolinite Dissolution and Precipitation Kinetics as a Function of Chemical Affinity and Solution Composition at 150°C, 40 bar, and pH 2, 6.8 and 7.8, Geoch. Cosmoch. Acta, vol.61, pp.5165-5186, 1997.

P. M. Dove and D. A. Crerar, Kinetics of Quartz Dissolution in Electrolyte Solutions Using a Hydrothermal Mixed-Flow Reactor, Geoch. Cosmoch. Acta, vol.54, pp.955-969, 1990.

J. I. Drever, Kinetics of the Dissolution of Calcite and its Application to Karstification, New Jersey. Dreybrodt, W, vol.31, pp.245-269, 1981.

E. L. Dromgoole and L. M. Walter, Inhibition of Calcite Growth Rates by Mn 2+ in CaCl 2 Solutions at 10, 25 and 50°C, Geoch. Cosmoch. Acta, vol.54, pp.2991-3000, 1990.

Z. Duan, R. Sun, L. Eisenlohr, K. Meteva, F. Gabrovs-v-ek et al., An Improved Model Calculating CO 2 Solubility in Pure Water and Aqueous NaCl Solutions from 273 to 533 K and from 0 to 2000 bar, Chem. Geol, vol.193, pp.257-271, 2003.

, The Inhibiting Action of Intrinsic Impurities in Natural É Brosse et al. / Modelling Fluid-Rock Interaction Induced by the Percolation of CO 2-Enriched Solutions in Core Samples Calcium Carbonate Minerals to their Dissolution Kinetics in

, Aqueous H 2 O-CO 2 Solutions, Geoch. Cosmoch., Acta, vol.63, pp.989-1002

R. M. Enick and S. M. Klara, CO 2 Solubility in Water and Brine under Reservoir Conditions, Chem. Eng. Comm, vol.90, pp.23-33, 1990.

J. M. Gautier, E. H. Oelkers, and J. Schott, Are Quartz Dissolution Rates Proportional to BET Surface Areas?, Geoch. Cosmoch. Acta, vol.65, pp.1059-1070, 2001.

W. D. Gunter, E. H. Perkins, and T. J. Mccann, Aquifer Disposal of CO 2-Rich Gases: Reaction Design for Added Capacity, Energy Convers. Mgmt, vol.34, pp.941-948, 1993.

W. D. Gunter, B. Wiwchar, and E. H. Perkins, Aquifer Disposal of CO 2-Rich Greenhouse Gases: Extension of the Time Scale of Experiment for CO 2-Sequestering Reactions by, Geochemical Modelling. Mineral. and Petrol, vol.59, pp.121-140, 1997.

C. Guy and J. Schott, Multisite Surface Reaction versus Transport Control During the Hydrolysis of a Complex Oxide, Chem. Geol, vol.78, pp.181-204, 1989.

H. C. Helgeson, Thermodynamics of Hydrothermal Systems at Elevated Temperatures and Pressures, Amer. Jour. Science, vol.267, pp.729-804, 1969.

H. C. Helgeson, D. H. Kirkham, and G. C. Flowers, Theoretical Prediction of the Thermodynamic Behavior of Aqueous Electrolytes by High Pressures and Temperatures. IV. Calculation of Activity Coefficients, Osmotic Coefficients, and Apparent Molal and Standard and Relative Partial Molal Properties to 600°C and 5 kb, Am. Jour. of Science, vol.281, pp.1249-1516, 1981.

H. C. Helgeson, W. M. Murphy, and P. Aagaard, Thermodynamic and Kinetic Constraints on Reaction Rates Among Minerals and Aqueous Solutions. II. Rate Constants, Effective Surface Area, and the Hydrolysis of Feldspar, Geoch. Cosmoch. Acta, vol.48, pp.2405-2432, 1984.

I. Hutcheon and H. Abercrombie, Carbon Dioxide in Clastic Rocks and Silicate Hydrolysis, Geology, vol.18, pp.541-544, 1990.

A. A. Jeschke and W. Dreybrodt, Dissolution Rates of Minerals and their Relation to Surface Morphology, Geoch. Cosmoch. Acta, vol.66, pp.3055-3062, 2002.

J. W. Johnson, K. G. Knauss, W. E. Glassley, L. D. Deloach, and A. F. Tompson, Reactive Transport Modeling of PlugFlow Reactor Experiments: Quartz and Tuff Dissolution at 240°C, Jour. of Hydrol, vol.209, pp.81-111, 1998.

J. W. Johnson, J. K. Nitao, and K. G. Knaus, Reactive Transport Modelling of CO 2 Storages in Saline Aquifers to Elucidate Fundamental Processes, Trapping Mechanisms, and Sequestration Partitioning, Geol. Soc. Spec. Publ, vol.233, pp.805-817, 2004.

C. Kervévan, M. Azaroual, and P. Durst, Improvement of the Calculation Accuracy of Acid Gas Solubility in Deep Reservoir Brines: Application to the Geological Storage of CO 2, 2005.

B. Kieffer, C. F. Jové-colón, E. H. Oelkers, and J. Schott, of Porosity, Permeability, and Fluid Flow Rate, vol.63, pp.3525-3534, 1999.

R. B. Knapp, Spatial and Temporal Scales of Local Equilibrium in Dynamic Fluid-Rock systems, Geoch. Cosmoch. Acta, vol.53, pp.1955-1964, 1989.

A. C. Lasaga, Kinetic Theory in the Earth Sciences, 1998.

L. Gallo, Y. Bildstein, O. Brosse, and E. , Coupled Reaction-Flow Modeling of Diagenetic Changes in Reservoir Permeability, Porosity and Mineral Compositions, Jour. of Hydrology, vol.209, pp.366-388, 1998.

P. C. Lichtner, Continuum Formulation of MulticomponentMultiphase Reactive Transport, Reactive Transport in Porous Media, vol.34, pp.1-81, 1996.

A. Lüttge, U. Winkler, and A. C. Lasaga, Interferometric Study of the Dolomite Dissolution: A New Conceptual Model for Mineral Dissolution, Geoch. Cosmoch. Acta, vol.67, pp.1099-1116, 2003.

M. A. Mast and J. I. Drever, The Effect of Oxalate on the Dissolution Rates of Oligoclase and Tremolite, Geoch. Cosmoch. Acta, vol.51, pp.2559-2568, 1987.

R. L. Mathis and S. O. Sears, Effect of CO 2 Flooding on Dolomite Reservoir Rock, vol.13132, 1984.

W. M. Murphy and H. C. Helgeson, Thermodynamic and Kinetic Constraints on Reaction Rates Among Minerals and Aqueous Solutions. IV. Retrieval of Rate Constants and Activation Parameters for the Hydrolysis of Pyroxene, Wollastonite, Olivine, Andalusite, Quartz and Nepheline, Am. Jour. of Science, vol.289, pp.17-101, 1989.

K. L. Nagy and A. C. Lasaga, Dissolution and Precipitation Kinetics of Gibbsite at 80°C and pH 3: The Dependence on Solution Saturation State, Geoch. Cosmoch. Acta, vol.56, pp.3093-3111, 1992.

K. L. Nagy, C. I. Steefel, A. E. Blum, and A. C. Lasaga, Dissolution and Precipitation Kinetics of Kaolinite: Initial Results at 80°C with Application to Porosity Evolution in a Sandstone, Prediction of Reservoir Quality Through Reservoir Modeling, vol.49, pp.85-101, 1990.

K. L. Nagy, A. E. Blum, and A. C. Lasaga, Dissolution and Precipitation Kinetics of Kaolinite at 80°C and pH 3: The Dependence on Solution Saturation State, Am. Jour. of Science, vol.291, pp.649-686, 1991.

C. Noiriel, D. Bernard, P. Gouze, and X. Thibault, Hydraulic Properties and Microgeometry Evolution Accompanying Limestone Dissolution by Acidic Water. This Issue. Oelkers, E.H. (1996) Physical and Chemical Properties of Rocks and Fluids for Chemical Mass Transport Calculations, Reactive Transport in Porous Media, vol.34, pp.131-191, 2005.
URL : https://hal.archives-ouvertes.fr/hal-02017191

L. N. Plummer, T. M. Wigley, and D. L. Parkhurst, The Kinetics of Calcite Dissolution in CO 2-Water Systems at 5° to 60°C and 0.0 to 1.0 atm CO 2, Am. Jour. Sci, vol.278, pp.179-216, 1978.

O. S. Pokrovsky and J. Schott, Surface Chemistry and Dissolution Kinetics of Divalent Metal Carbonates, Environ. Sci. Technol, vol.36, pp.426-432, 2002.

S. Portier, S. Portier, and C. Rochelle, Modelling CO 2 Solubility in Pure Water and NaCl-Type Waters from 0 to 300 Degrees Celcius and from 1 to 300 bar. Application to the Utsira Formation at Sleipner, Geochemical Aspects of CO, 2005.

;. Sequestering, M. Whitaker, and S. , Dissolution of an Immobile Phase During Flow in Porous media, press. Quintard, vol.38, pp.833-844, 1999.

D. T. Rickard and E. L. Sjöberg, Mixed Kinetic Control of Calcite Dissolution Rates, Amer. Jour. Science, vol.283, pp.815-830, 1983.

G. D. Ross, A. C. Todd, J. A. Tweedie, and A. G. Will, The Dissolution Effects of CO 2-Brine Systems on the Permeability of UK and North Sea Calcareous Sandstones, p.10685, 1982.

, Oil & Gas Science and Technology-Rev. IFP, vol.60, issue.2, 2005.

J. L. Schnoor, Kinetics of Chemical Weathering: a Comparison of Laboratory and Field Weathering Rates, Aquatic Chemical Kinetics, pp.475-504, 1990.

R. Simon and D. Graue, Generalized Correlations for Predicting Solubility, Swelling and Viscosity Behavior of CO 2Crude Oil System, J. Petrol. Tech, pp.102-106, 1965.

E. L. Sjöberg and D. T. Rickard, , 1984.

, Aqueous Solutions. Geoch. Cosmoch. Acta, vol.48, pp.485-493

J. T. Smith and S. N. Ehrenberg, Correlation of Carbon Dioxide Abundance with Temperature in Clastic Hydrocarbon Reservoirs: Relationship to Inorganic Chemical Equilibrium, Mar. & Petrol. Geol, vol.6, pp.129-135, 1989.

C. I. Steefel and K. T. Macquarrie, Approaches to, 1996.
URL : https://hal.archives-ouvertes.fr/hal-00564123

, Modeling Reactive Transport in Porous Media, vol.34, pp.83-129

W. Stumm, J. J. Morgan, . Sidney, . Toronto, W. Stumm et al., Dissolution of Oxide and Silicate Minerals: Rates Depend on Surface Speciation, Aquatic Mineral Kinetics, Reaction Rates of Processes in Natural Waters, pp.367-400, 1970.

R. K. Svec and R. B. Grigg, Physical Effects of WAG Fluids on Carbonate Core Plugs, 2001.

J. W. Tester, W. G. Worley, B. A. Robinson, C. O. Grigsby, and J. L. Feerer, Correlating Quartz Dissolution Kinetics in Pure Water from 25 to 625°C, Geoch. Cosmoch. Acta, vol.58, pp.2407-2420, 1994.

M. Thiry, Diversity of Continental Silicification Features: Examples from the Cenozoic Deposits in the Paris Basin and Neighbouring Basement, Int. Ass. Sediment. Spec. Publ, vol.27, pp.87-127, 1999.
URL : https://hal.archives-ouvertes.fr/hal-00648058

E. Usdowski, P. Van-cappellen, L. Charlet, W. Stumm, and P. Wersin, Reactions and Equilibria in the Systems CO 2-H 2 O and CaCO 3-CO 2-H 2 O (0-50°C), A Review. N. Jb. Miner. Abh, vol.144, pp.3505-3518, 1982.

T. Vengu, Propriétés thermodynamiques d'un pétrole brut en présence de gaz carbonique. Application à la récupération assistée. Thèse, univ, 1983.

A. F. White and S. L. Brantley, The Effect of Time on the Weathering of Silicate Minerals: Why Do Weathering Rates Differ in the Laboratory and Field?, Chem. Geol, vol.202, pp.479-506, 2003.

A. F. Withe and M. Peterson, The Role of Reactive Surface Areas in Chemical Weathering, Geochemistry of the Earth's Surface and of Mineral Formation, 2nd Int. Symp, pp.334-338, 1990.

T. Xu, J. A. Apps, and K. Pruess, Reactive Geochemical Transport Simulation to Study Mineral Trapping for CO 2 Disposal in Deep Arenaceous Formations, Jour. Geophys. Res, vol.108, 2003.