(627e) Diffusion of CO2 and N2 In Zsm-5 Zeolite with Framework Substitutions
AIChE Annual Meeting
2008
2008 Annual Meeting
Separations Division
Adsorbent Materials I
Thursday, November 20, 2008 - 1:10pm to 1:30pm
Zeolites are inorganic aluminosilicates with an ordered atomistic-scale porous topology that have found usage in membrane separations, catalysis, and sequestration. The zeolite ZSM-5 has a well-defined topology with straight channels in the y-direction, zigzag channels in the x-z plane, and with a typical pore diameter of ~5.5 Å. The zeolite lattice has a nominal composition of SiO2, but the Si atoms can be replaced by Al atoms, along with extra framework cations, such as Na+, to maintain charge balance.
One possible application of ZSM-5 is the separation of CO2 from flue gases. The molecules CO2 and N2 have different kinetic diameters and therefore will diffuse through the zeolite pores at different rates, hence separating molecules in a membrane operation.
We have used molecular dynamics (MD) simulations of CO2 and N2 diffusing in ZSM-5 with Na+ and Al present. We performed the simulations with the DL_POLY software package, using the Nose-Hoover thermostat, the Ewald summation for Coulombic forces, a pretabulation of the zeolite potential energy landscape, and for runs over time lengths of 20-26 ns. In the MD runs we collect the trajectories to determine the mean squared displacement over time curve. From this information we calculated the self- and corrected-diffusivities of CO2 and N2 at T=200, 300, and 400 K. The diffusivities provide insight into the mobility of molecules as a function of temperature and concentration.
We consider the cases of 0 and 1 Al substitution of Si in the ZSM-5 unit cell to study the role of heterogeneity. In practice the concentration of the cation (that accompanies the Al) is a property that can be controlled via ion exchange to tune the adsorptive and diffusive properties of molecules in the ZSM-5. The CO2 and N2 molecules have a strong electrostatic interaction to the Na+ cation that is tethered near the Al atom. We find that the diffusivities of CO2 at T=200 and 300 K show a maximum as a function of loading at 1 Al per ZSM-5 unit cell, due to the Na+ strongly attracting the molecules. The Na+ ions also cause pore blockage by occupying space in the pore normally available for transport. The activation barrier for CO2 strongly increases due to the presence of Na+.