GSA Annual Meeting, November 5-8, 2001

Paper No. 0
Presentation Time: 9:15 AM

RELATIVE BOUYANCIES OF CO2-H2O MIXTURES AT 300-400°C AND PRESSURES TO 100 MEGAPASCALS*


BLENCOE, James G.1, ANOVITZ, Lawrence M.1, SINGH, Jagmohan2 and SEITZ, Jeffery C.3, (1)Oak Ridge National Lab, P.O. Box 2008, Bldg. 4500-S, Oak Ridge, TN 37831-6110, (2)Oak Ridge National Laboratory, P.O. Box 2008, Bldg. 4500-S, Oak Ridge, TN 37831-6110, (3)Department of Geological Sciences, California State University, Hayward, Hayward, CA 94542-3088, blencoejg@ornl.gov

Numerical models for hydrothermal fluid flow commonly include the premise that the migrating fluid is pure water. This simplifying assumption implies that small amounts of dissolved gases (e.g., CO2) and solids (e.g., NaCl and SiO2) have negligible effects on the thermophysical properties and phase relations of H2O-rich hydrothermal solutions. Thus, it is significant that recently acquired density and phase equilibrium data for CO2-H2O mixtures (Seitz and Blencoe, 1997; Seitz et al., 1999; Blencoe et al., 2001; Seitz et al., in prep.) can be used to calculate highly accurate relative bouyancies for the fluids at 300-400°C, P £ 100 MPa, using pure H2O as the reference fluid. The relative bouyancy (RB) of a CO2-H2O mixture at a given P and T is defined by the relation RB = rH2O/r, where rH2O is the density of pure water, and r is the density of the CO2-H2O mixture. Peak values for RB at 300, 350 and 400°C, calculated from the density data for CO2-H2O mixtures—with densities for pure H2O given by a highly accurate equation of state (Wagner and Pruß, 1995)—are, respectively: 11.8 (P = 9.94 MPa, XCO2  = 0.10); 5.4 (P = 17.44 MPa, XCO2 =  0.20); and 2.2 (P = 34.94 MPa, XCO2 =  0.30). Therefore, at 300-400°C, P £ 100 MPa: (1) the most bouyant CO2-H2O mixtures are H2O-rich, and (2) the bouyancy contrast between the most bouyant CO2-H2O fluid and pure H2O increases sharply with decreasing temperature and pressure. These results strongly suggest that small amounts of CO2 can have profound effects on the rates and patterns of hydrothermal fluid flow in sedimentary basins, geothermal fields and shallow contact metamorphic aureoles.

*Research sponsored by the Division of Chemical Sciences, Geosciences, and Biosciences, Office of Basic Energy Sciences, U.S. Department of Energy under contract DE-AC05-00OR22725, Oak Ridge National Laboratory, managed and operated by UT-Battelle, LLC.