(758e) Theory and Experiment for Thermodynamics of the CO2/H2O System
AIChE Annual Meeting
2011
2011 Annual Meeting
Engineering Sciences and Fundamentals
Thermodynamics of Energy Systems
Thursday, October 20, 2011 - 4:35pm to 4:55pm
Mixtures containing CO2 and H2O are important in many applications. In the electric power industry, they are two of the primary components of combustion gases. In advanced power cycles that facilitate CO2 sequestration, these components may appear in synthesis gas, and they will certainly appear in CO2-rich streams being compressed and transported for sequestration. Of key importance in many of these applications is the vapor-phase thermodynamic properties, which determine, for example, the dew point where liquid water will condense out of a CO2 stream being compressed for sequestration.
We have undertaken a comprehensive program to study the gas-phase thermodynamics of this mixture, particularly at high temperatures where experimental data are scarce and scattered. We have used ab initio quantum mechanics to develop an intermolecular potential-energy surface of low uncertainty for the CO2/H2O pair; this surface has been used to calculate the cross second virial coefficient B12 as a function of temperature. In addition, we have constructed a high-temperature, single-sinker magnetic suspension densimeter and used it to make density measurements on CO2/H2O mixtures at temperatures from 500 K to 620 K and pressures up to 17 MPa. Values of B12 derived from the mixture density measurements agree within mutual uncertainties with those derived from theory. Similar agreement between theory and experiment has been obtained for the N2/H2O system, which is also of interest in energy applications.