ABSTRACT
An understanding of interfacial barriers underpinning fluid transport in nanoporous membranes is critical for the design of efficient next generation membranes, to harness their potential for industrial scale separations. Such barriers include the contribution of external and internal interfacial barriers, and strongly depend on smoothness of the pore surface, pore size, shape, tortuosity, structural defects such as pore blockage and thermodynamic state of the fluid. We review recent progress in the transport of a fluid through nanoporous membrane materials such as zeolites and carbon nanotubes, which hold promise for industrial significance, but their application is subject to strong interfacial barriers. The contribution of interfacial barriers to the overall transport in these membrane materials is found to be particularly significant when the pore surface is uniform as well as at low temperatures and pressures. Further, such barriers that arise from internal defects such as grain boundaries are found to be remarkable and detrimental to separation kinetics. The internal interfacial barriers are found to be significant, and are enhanced when a dense medium such as a polymer is present at the interface, suggesting that interfacial barriers can play a key role in mixed matrix membranes and is an important area requiring further attention.
Disclosure statement
No potential conflict of interest was reported by the authors.
ORCID
Ravi C. Dutta http://orcid.org/0000-0003-4068-2723
Suresh K. Bhatia http://orcid.org/0000-0001-9716-0112