Development of an experimental data base and theories for prediction of thermodynamic properties of aqueous electrolytes and nonelectrolytes of geochemical significance at supercritical temperatures and pressures. Annual performance report

This project is divided into method experimental measurements, theoretical development, and geochemical applications. We have completed experimental volumetric measurements on aqueous solutions of CO{sub 2} H{sub 2}S, CH{sub 4}, NH{sub 3} and B(OH){sub 3} at 25 to 432{degree}C and 280 and 350 bar. A...

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Bibliographic Details
Main Authors: Wood, R. H., Hnedkovsky, L., Lin, Ching Lung, Shock, E. L.
Other Authors: United States. Department of Energy.
Format: Report
Language:English
Published: Delaware Univ., Newark, DE (United States). Dept. of Chemistry and Biochemistry 1992
Subjects:
Progress Report
Solubility
Volume
Bubbles
Thermodynamic Properties
Chemical And Physicochemical Properties
580000
58 Geosciences
Methane
Carbonic Acid
Geosciences
Hydrogen Sulfides
Rock-Fluid Interactions 400201
Free Energy
Boric Acid
Aqueous Solutions
Ammonia
High Pressure
Hydrothermal Systems
Temperature Range 0400-1000 K
Carbon Dioxide
37 Inorganic
Organic
Physical And Analytical Chemistry
Density
Geochemistry
Very High Pressure
Carbonic acid
Online Access:https://doi.org/10.2172/10182216
https://digital.library.unt.edu/ark:/67531/metadc1400347/
Description
Summary:This project is divided into method experimental measurements, theoretical development, and geochemical applications. We have completed experimental volumetric measurements on aqueous solutions of CO{sub 2} H{sub 2}S, CH{sub 4}, NH{sub 3} and B(OH){sub 3} at 25 to 432{degree}C and 280 and 350 bar. A vibrating tube densitometer that allows density measurements near bubble point and also measures the bubble pressure was developed and used to measure densities and bubble pressures of aqueous Co{sub 2}. Heat capacity measurements should be completed by the end of the grant period. Simulations of models for methane in water at temperatures to 1000{degrees}C are in progress. In order to facilitate these free energy calculations the possible errors associated with the calculations have been explored in two papers (Wood, 1991; Wood et al., 1991) and methods of controlling and estimating these errors have been developed. Applications of the new data to geochemical processes is now possible. Efforts have focussed on extracting equilibrium constants for carbonic acid dissociation at supercritical condition from published experiments on mineral equilibria in H{sub 2}0-CO{sub 2} fluids (Boehlke and Shock, 1990; and in prep.). As a result, estimates of pKa for carbonic acid are now available at temperatures from 300 to 750{degrees}C and pressures from 1 to 7 kilobars. They will be combined with {bar V}{sup {degree}} and {bar C}p{sup {degree}} data for CO{sup 2}(aq) to improve geochemical calculations.

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