Gas-sieving zeolitic membranes fabricated by condensation of precursor nanosheets.
Mostapha DakhchouneLuis Francisco VillalobosRocio SeminoLingmei LiuMojtaba RezaeiPascal SchouwinkClaudia Esther AvalosPaul BaadeVanessa WoodYu HanMichele CeriottiKumar Varoon AgrawalPublished in: Nature materials (2020)
The synthesis of molecular-sieving zeolitic membranes by the assembly of building blocks, avoiding the hydrothermal treatment, is highly desired to improve reproducibility and scalability. Here we report exfoliation of the sodalite precursor RUB-15 into crystalline 0.8-nm-thick nanosheets, that host hydrogen-sieving six-membered rings (6-MRs) of SiO4 tetrahedra. Thin films, fabricated by the filtration of a suspension of exfoliated nanosheets, possess two transport pathways: 6-MR apertures and intersheet gaps. The latter were found to dominate the gas transport and yielded a molecular cutoff of 3.6 Å with a H2/N2 selectivity above 20. The gaps were successfully removed by the condensation of the terminal silanol groups of RUB-15 to yield H2/CO2 selectivities up to 100. The high selectivity was exclusively from the transport across 6-MR, which was confirmed by a good agreement between the experimentally determined apparent activation energy of H2 and that computed by ab initio calculations. The scalable fabrication and the attractive sieving performance at 250-300 °C make these membranes promising for precombustion carbon capture.
Keyphrases
- reduced graphene oxide
- room temperature
- quantum dots
- visible light
- metal organic framework
- highly efficient
- contrast enhanced
- diffusion weighted imaging
- magnetic resonance
- photodynamic therapy
- single molecule
- molecular dynamics simulations
- density functional theory
- computed tomography
- gold nanoparticles
- magnetic resonance imaging
- carbon dioxide
- replacement therapy
- combination therapy
- structural basis
- ionic liquid
- risk assessment