Confining Water Nanotubes in a Cu10O13-Based Metal-Organic Framework for Propylene/Propane Separation with Record-High Selectivity

Energy-efficient separation of propylene (C3H6)/ propane (C3H8) is in high demand for the chemical industry. However, this process is challenging due to the imperceptible difference in molecular sizes of these gases. Here, we report a continuous water nanotube dedicatedly confined in a Cu(10)O(13)(-)based metal-organic framework (MOF) that can exclusively adsorb C3H6 over C3H8 with a record-high selectivity of 1570 (at 1 bar and 298 K) among all the porous materials. Such a high selectivity originates from a new mechanism of initial expansion and subsequent contraction of confined water nanotubes (similar to 4.5 angstrom) caused by C3H6 adsorption rather than C3H8. Such unique response was further confirmed by breakthrough measurements, in which one adsorption/desorption cycle yields each component of the binary mixture high purity (C3H6: 98.8%; C3H8: >99.5%) and good C3H6 productivity (1.6 mL mL(-1)). Additionally, benefiting from the high robustness of the framework, the water nanotubes can be facilely recovered by soaking the MOF in water, ensuring long-term use. The molecular insight here demonstrates that the confining strategy opens a new route for expanding the function of MOFs, particularly for the sole recognition from challenging mixtures.

Automated summary

Researchers reported a continuous water nanotube confined in a Cu(10)O(13)(-) based metal-organic framework (MOF) that can selectively adsorb C3H6 over C3H8 with a record-high selectivity of 1570 among all the porous materials. The high selectivity is attributed to the initial expansion and subsequent contraction of the confined water nanotubes caused by C3H6 adsorption rather than C3H8. The water nanotubes can be easily recovered by soaking the MOF in water, ensuring long-term use.