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Nanosheet-based MFI membranes, known to be highly selective for hydrocarbon isomer separations, exhibit an NH 3 /N 2 mixture separation factor of 2236 with NH 3 permeance of 1.1 × 10 −6 mol m −2 s −1 Pa −1 , and NH 3 /H 2 separation factor of 307 with NH 3 permeance of 2.3 × 10 −6 mol m −2 s −1 Pa −1 at room temperature. Consistent with a competitive sorption-based separation, lower operating temperatures and higher pressures result in increased separation factor. At 323 K, with an equimolar mixed feed of NH 3 /N 2 , the fluxes and separation factors at 3 and 7 bar are 0.13 mol m −2 s −1 and 191, and 0.26 mol m −2 s −1 and 220, respectively. This performance compares favorably with that of other membranes and suggests that MFI membranes can be used in separation and purification processes involving mixtures of NH 3 /N 2 /H 2 encountered in ammonia synthesis and utilization. The membranes also exhibit high performance for the separation of ethane, n -propane and n -butane from H 2 . 

Zeolite nanosheets with improved thickness and orientation uniformity yield effective separation membranes for xylene isomers. 

Abstract Synthesis of a pentasil‐type zeolite with ultra‐small few‐unit‐cell crystalline domains, which we call FDP (few‐unit‐cell crystalline domain pentasil), is reported. FDP is made using bis‐1,5(tributyl ammonium) pentamethylene cations as structure directing agent (SDA). This di‐quaternary ammonium SDA combines butyl ammonium, in place of the one commonly used for MFI synthesis, propyl ammonium, and a five‐carbon nitrogen‐connecting chain, in place of the six‐carbon connecting chain SDAs that are known to fit well within the MFI pores. X‐ray diffraction analysis and electron microscopy imaging of FDP indicate ca. 10 nm crystalline domains organized in hierarchical micro‐/meso‐porous aggregates exhibiting mesoscopic order with an aggregate particle size up to ca. 5 μm. Al and Sn can be incorporated into the FDP zeolite framework to produce active and selective methanol‐to‐hydrocarbon and glucose isomerization catalysts, respectively.