Surface engineering of intrinsically microporous poly(ether-ether-ketone) membranes: From flat to honeycomb structures.

Surface engineering of polymeric membranes can induce subtle changes in membrane properties and enhance their performance. Numerous membrane surface modification methods have been developed to improve the material performance. However, these methods can be complex, thus limiting their practical applications. Herein, we present a simple method for fabricating membranes with honeycomb surfaces by controlling the polymer molecular weight (M w). Spirobisindane-based intrinsically microporous poly(ether-ether-ketone) (iPEEK-SBI) homopolymers with low and high M w s were synthesized and used to prepare organic solvent nanofiltration (OSN) membranes. The significant effects of polymer M w on its physical properties, membrane morphology, and OSN performance were systematically investigated. iPEEK showed excellent solution processability, high Brunauer–Emmett–Teller surface area, and remarkable thermal stability. Three mechanically flexible OSN membranes exhibiting honeycomb surfaces with different honeycomb cell sizes were prepared using iPEEK-SBI homopolymers with low M w s at concentrations of 27–39 wt% in N -methyl-2-pyrrolidone. By contrast, the use of iPEEK-SBI homopolymers with high M w s yielded membranes with flat surfaces. The M w cutoffs of the membranes were fine-tuned in the range of 408–772 g mol−1 by adjusting the dope solution concentration. Although the M w cutoffs were unaffected by polymer M w , the membranes derived from the polymer with low M w exhibited substantially higher solvent permeance (18%–26%) than that of the high M w membrane prepared at the same dope solution concentration. Stable performance was demonstrated over seven days of continuous cross-flow filtration and a six-month aging of the membranes. This work shows the importance of surface engineering for OSN membranes by adjusting polymer M w. These findings open a new avenue for fine-tuning the properties of OSN membranes. Image 1 • Membranes prepared using intrinsically microporous poly(ether-ether-ketone). • Polymer molecular weight affects physical properties and membrane morphology. • Flat vs. honeycomb membrane surfaces studied via computational fluid dynamics. • Dope solution concentration affects honeycomb structure and Feret diameter. • Honeycomb surface demonstrate high thermal stability and stable performance. [ABSTRACT FROM AUTHOR]