Dual-phase microporous polymer nanofilms by interfacial polymerization for ultrafast molecular separation

Author(s)

Lee, Tae Hoon; Balcik, Marcel; Wu, Wan-Ni; Pinnau, Ingo; Smith, Zachary P

Abstract

Fine-tuning microporosity in polymers with a scalable method has great potential for energy-efficient molecular separations. Here, we report a dual-phase molecular engineering approach to prepare microporous polymer nanofilms through interfacial polymerization. By integrating two micropore-generating units such as a water-soluble Tröger’s base diamine (TBD) and a contorted spirobifluorene (SBF) motif, the resultant TBD-SBF polyamide shows an unprecedentedly high surface area. An ultrathin TBD-SBF membrane (~20 nm) exhibits up to 220 times improved solvent permeance with a moderate molecular weight cutoff (~640 g mol−1) compared to the control membrane prepared by conventional chemistry, which outperforms currently reported polymeric membranes. We also highlight the great potential of the SBF-based microporous polyamides for hydrocarbon separations by exploring the isomeric effects of aqueous phase monomers to manipulate microporosity.

Date issued

2024-08-16

URI

https://hdl.handle.net/1721.1/157679

Department

Massachusetts Institute of Technology. Department of Chemical Engineering

Journal

Science Advances

Publisher

American Association for the Advancement of Science

Citation

Tae Hoon Lee et al. ,Dual-phase microporous polymer nanofilms by interfacial polymerization for ultrafast molecular separation.Sci. Adv.10,eadp6666(2024).

Version: Final published version