Phase Behavior of Carbon Dioxide Confined in Silica Aerogel in the Vicinity of the Bulk Critical Point

Abstract

The small angle neutron scattering intensities from silica aerogel filled with carbon dioxide at different loading densities of the bulk fluid (0.3–0.65 g/cm3) were measured at fixed volume condition as a function of decreasing temperature, from 35 to 25 °C, to characterize the phase behavior of the confined CO2 about the critical point of the bulk CO2. The data present no evidence of a bulklike phase transition of the confined CO2 in the explored parameter region. They show that the confined CO2 may be approximated as a two phase system. The first phase (liquid film) is formed by CO2 molecules at the silica surface, and the second phase (confined fluid) fills up the rest of the pore volume. The thickness δ of the liquid film as well as the scattering-length densities of the two phases were obtained by analyzing the Porod invariants and the oscillations observed in the Porod plots at each loading density and temperature. The resulting δ values vary in the range 25–45 Å depending on the temperature and loading density. The density of the liquid film is 1.5–2 times larger than that of the confined fluid, which in its turn exceeds the density of bulk CO2 at similar temperature and pressure. At the lowest temperature (25 °C), the densities of the liquid film and confined fluid respectively approach 1.25 g/cm3 and 0.8 g/cm3 independently of the loading conditions.