Large-Scale Computational Screening of Metal Organic Framework (MOF) Membranes and MOF-Based Polymer Membranes for H 2 /N 2 Separations

Several thousands of metal organic frameworks (MOFs) have been reported to date, but the information on H /N separation performances of MOF membranes is currently very limited in the literature. We report the first large-scale computational screening study that combines state-of-the-art molecular simulations, grand canonical Monte Carlo (GCMC) and molecular dynamics (MD), to predict H permeability and H /N selectivity of 3765 different types of MOF membranes. Results showed that MOF membranes offer very high H permeabilities, 2.5 × 10 to 1.7 × 10 Barrer, and moderate H /N membrane selectivities up to 7. The top 20 MOF membranes that exceed the polymeric membranes' upper bound for H /N separation were identified based on the results of initial screening performed at infinite dilution condition. Molecular simulations were then carried out considering binary H /N and quaternary H /N /CO /CO mixtures to evaluate the separation performance of MOF membranes under industrial operating conditions. Lower H permeabilities and higher N permeabilities were obtained at binary mixture conditions compared to the ones obtained at infinite dilution due to the absence of multicomponent mixture effects in the latter. Structure-performance relations of MOFs were also explored to provide molecular-level insights into the development of new MOF membranes that can offer both high H permeability and high H /N selectivity. Results showed that the most promising MOF membranes generally have large pore sizes (>6 Å) as well as high surface areas (>3500 m /g) and high pore volumes (>1 cm /g). We finally examined H /N separation potentials of the mixed matrix membranes (MMMs) in which the best MOF materials identified from our high-throughput screening were used as fillers in various polymers. Results showed that incorporation of MOFs into polymers almost doubles H permeabilities and slightly enhances H /N selectivities of polymer membranes, which can advance the current membrane technology for efficient H purification.