posted on 2020-11-09, 06:05authored byMerilent
T. Kallo, Matthew J. Lennox
The separation of CO2/CH4 gas mixtures is
a key challenge for the energy sector and is essential for the efficient
upgrading of natural gas and biogas. A new emerging field, that of
metal–organic framework nanosheets (MONs), has shown the potential
to outperform conventional separation methods and bulk metal–organic
frameworks (MOFs). In this work, we model the CO2/CH4 separation in both defect-free and defective 2D CuBDC nanosheets
and compare their performance with the bulk CuBDC MOF and experimental
data. We report the results of external force nonequilibrium molecular
dynamics (EF-NEMD) for pure components and binary mixtures. The EF-NEMD
simulations reveal a pore blocking separation mechanism, in which
the CO2 molecules occupy adsorption sites and significantly
restrict the diffusion of CH4. The MON structure achieves
a better selectivity of CO2 over CH4 compared
to the bulk CuBDC MOF which is due to the mass transfer resistance
of the methane molecules on the surface of the nanosheet. Our results
show that it is essential to consider the real mixture in these systems
rather than relying solely on pure component data and ideal selectivity.
Furthermore, the separation is shown to be sensitive to the presence
of missing linker defects in the nanosheets. Only 10% of missing linkers
result in nonselective nanosheets. Hence, the importance of a defect-free
synthetic method for CuBDC nanosheets is underlined.