(531g) Vapor Phase Infiltration of Metal Oxides into Nanoporous Polymers for Solvent Stable Nanofiltration Membranes | AIChE

(531g) Vapor Phase Infiltration of Metal Oxides into Nanoporous Polymers for Solvent Stable Nanofiltration Membranes

Authors 

Zhang, F. - Presenter, Georgia Institute of Technology
Ma, Y., Georgia Institute of Technology
Losego, M. D., Georgia Institute of Technology
Lively, R., Georgia Institute of Technology
McGuinness, E., Georgia Institute of Technology
Membrane-based organic solvent separations promise a low-energy alternative to traditional thermal separations but require materials that operate reliably in chemically aggressive environments. While inorganic membranes can withstand demanding conditions, they are costly and difficult to scale. Polymeric membranes, such as polymers of intrinsic microporosity 1 (PIM-1), are easily manufactured into forms consistent with large-scale separations (e.g., hollow fibers), but perform poorly in aggressive solvents. Here, a new post-fabrication membrane modification technique, vapor phase infiltration (VPI) is reported that infuses PIM-1 with inorganic constituents to improve stability while maintaining the polymer’s macroscale form and microporous internal structure. The atomic-scale metal oxide networks within these hybrid membranes protect PIM-1 from swelling or dissolving in solvents. This stability translates to improved separation performance (90 % molecular weight cutoff is 204 Da) in a variety of solvents, including solvents capable of dissolving PIM-1. The infiltrated inorganic phase also appears to give new control over solute sorption in OSN. These hybrid membranes further show promising performance for organic solvent reverse osmosis (OSRO) separations in challenging solvents, even at small molecular weight differentials (14 Da). Because the VPI process can be integrated with state-of-the-art membrane modules, this treatment could be readily adopted into the large-scale manufacturing of advanced membranes.