The mechanisms involved in pressure-driven gas permeation through a micropore on vitreous SiO2 membranes were examined by molecular dynamics simulation. Virtual amorphous SiO2 membranes were prepared by the melt-quench method utilizing modified Born–Mayer–Huggins pair potential and Stillinger–Weber 3-body interactions. A dual-control plane non-equilibrium molecular dynamics technique was employed to simulate gas permeation phenomena under a constant upstream
pressure, in which the permeating molecules were modelled as Lennard–Jones particles. The dependencies of the permeance of He and CO2 molecules on temperature and pore size were examined. For cylindrical pores about 8 and 6Å in diameter, the calculated temperature dependencies for the permeance of helium molecules were similar to the tendencies predicted by the normal Knudsen permeation mechanism, while in the case of CO2 permeation, a temperature dependency larger than He and a significant deviation from the Knudsen mechanism were observed. The deviation was more obvious for the smaller Å pore model. A simple gas permeation model that takes the effect of the pore wall potential field into consideration satisfactorily explained the permeation properties of CO2 in the high temperature region. The permeation mechanism was also examined from the viewpoint of the lateral potential and density distribution in a micropore. The values for the potential within micropores, predicted from the observed temperature dependencies of the gas permeation rate and using the simple gas permeation model, were in good agreement with the depth of the potential field resulting from the given potential parameters. The findings also indicate that the density (pressure) difference in a micropore between the pore entrance and exit, which could be enhanced by an attractive pore wall potential, might be the true driving force for permeation, particularly in the high temperature region.
A Molecular Dynamics Simulation of Pressure-Driven Gas Permeation in a Micropore Potential Field on Silica Membranes. T.Yoshioka, M.Asaeda, T.Tsuru: Journal of Membrane Science, 2007, 293[1-2], 81-93