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Abstract
MFI zeolite nanosheets membranes are promising candidates for ammonia separation from nitrogen and hydrogen, yet questions remain on the origin of their high selectivity. Silanols, Si-OH, are present in high concentration at the surface of zeolite nanosheets, and force-field-based simulations indicate that surface adsorption at the silanols contributes to selectivity. Silanols can chemically react with ammonia, which may further contribute to the ability of zeolite nanosheet membranes to separate it from other gases. In this work, we use first-principles molecular dynamics techniques to simulate ammonia’s behavior within stacked MFI zeolite nanosheets. We find that at 523 K and a loading corresponding to 35 bar, conditions desired for the ammonia separation, about 30% of ammonia reacts with surface silanols. Our work explores H-bonding and proton transfer within this system.
Supplementary materials
Title
Supporting Information
Description
Calculation details for RDFs and PPDs; supplementary figures showing histograms of tetrahedral order parameter for NH4+ ions, N−H bond length distributions, traces of atomic positions, PPDs for the U0 and U7 trajectories, and evolution of the temperature for the three simulations (PDF).
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