From energy storage to separation applications, performances of nanoporous membranes are typically limited by an inherent trade-off between transport rate and selectivity. For example, conventional protective garments sacrifice breathability to prevent exposure to harmful agents, and this trade-off severely hinders the duration of their active use. The discovery of enhanced fluid flow in single-walled carbon nanotubes (SWCNT) has provided a path toward combining the diametric properties of high selectivity and permeability into a single SWCNT-based material, yet successful demonstration of this promise remains elusive.
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