EXPERIMENTAL DETERMINATION OF CO2-H2O ACTIVITY-COMPOSITION RELATIONS AT 600-1000°C AND 6-14 KBAR BY REVERSED DECARBONATION AND DEHYDRATION REACTIONS

Abstract

Activity-composition relations in CO 2 -H 2 O solutions were determined at 6, 10, and 14 kbar over broad temperature-fluid composition ranges from 70 reversed determinations of three simple-system decarbonation and dehydration reactions: CaCO 3 + SiO 2 = CaSiO 3 + CO 2 (WQC) calcite quartz wollastonite MgCO 3 + MgSiO 3 = Mg 2 SiO 4 + CO 2 (FEM) magnesite enstatite forsterite Mg 3 Si 4 O 10 (OH) 2 = 3 MgSiO 3 + SiO 2 + H 2 O (TEQ) talc enstatite quartz Brackets of WQC and FEM were achieved by reversing, at constant T and P, the fluid composition coexisting with the assemblages of either reaction, starting with fine-grained mixtures of reactants and products in nearly equimolar amounts and liquid water, oxalic acid, and silver oxalate as fluid sources. Brackets of TEQ were secured by reversing the reaction over narrow temperature intervals at constant P and fluid composition. All experiments were made in the piston-cylinder apparatus with NaCl or NaCl-soft glass pressure media, and all experiments with two-component fluids were buffered at hema-tite-magnetite. Closure intervals of reversed fluid composition averaged less than 2 mol% CO 2 . Activity values of H 2 O (1) and CO 2 (2) were retrieved based on the THERMOCALC 2.3 thermodynamic data set of Holland and Powell (1994), which includes equations of state of H 2 O and CO 2 , supplemented by sev-eral tight reversals of the end-member equilibria. A simple van Laar-type expression reproduces our composition determinations with a standard deviation of only 1.2 mol% CO 2 : RT lnγ 1 = (X 2) 2 W{V 0 1 V 0 2 2 /[(V 0 1 +V 0 2)(X 1 V 0 1 +X 2 V 0 2) 2 ]} RT lnγ 2 = (X 1) 2 W{V 0 2 V 0 1 2 /[(V 0 1 +V 0 2)(X 1 V 0 1 +X 2 V 0 2) 2 ]} where V 0 1 and V 0 2 are, respectively, the specific volumes of pure H 2 O and CO 2 at a given (P,T), the X's are the mole fractions, the γ's the activity coefficients and W is analogous to a regular solution param-eter: W = (A+BT)[1–exp(–20P)] + CPT, with T in K and P in kbar. The best-fit values of the constants are: A = 12893 J, B = –6.501 J/K, C = 1.0112 J/(K⋅kbar). With these formulas, the activity-concentra-tion relations of CO 2 -H 2 O solutions may be reconstructed in a broad P-T-X range using any reason-ably accurate equations of state of pure CO 2 and H 2 O. The activity-concentration relations are closely similar to the modified Redlich-Kwong (MRK) reconstruction of Kerrick and Jacobs (1981) to pres-sures of 6 kbar, but the binary fluids have marginally greater positive non-ideality than the MRK predictions at 10 kbar and significantly greater non-ideality at 14 kbar. The present results can serve as a basis for reliable calculations of mineral-fluid equilibria in metamorphism of the deep crust and upper mantle.