Hydrogen isotope separation with nanoporous materials is a very challenging yet promising approach. To overcome the limitation of the conventional isotope separation strategy, quantum sieving-based separation using nanoporous materials has been investigated recently. In this study, to see the thermodynamic deuterium separation phenomena attributed to the chemical affinity quantum sieving effect, we examine Hofmann-type metal-organic frameworks (MOFs), Co(pyz)[M(CN)4] (pyz = pyrazine, M = Pd2+, Pt2+, and Ni2+), which have microporosity (4.0 × 3.9 Å2) and an extraordinarily high density of open metal sites (∼9 mmol/cm3). Owing to the preferential adsorption of D2 over H2 at strongly binding open metal sites, the Hofmann-type MOF, Co(pyz)[Pd(CN)4] exhibited a high selectivity (SD2/H2) of 21.7 as well as a large D2 uptake of 10 mmol/g at 25 K. This is the first study of Hofmann-type MOFs to report high selectivity and capacity, both of which are important parameters for the practical application of porous materials toward isotope separation.
Keywords: MOFs; deuterium; gas separation; hydrogen isotopes; isotope separation; metal−organic frameworks; open metal sites; quantum sieving.