Correlating gas permeability and morphology of bio-based polyether-block-amide copolymer membranes by IR nanospectroscopy

Oana David*, Miren Etxeberria Benavides, Iban Amenabar Altuna, Francisco Jose Fernandez Carretero, Maria del Mar Diaz De Guereñu Zabarte, Jean Jaques Flat, Quentin Pineau, Monika Goikoetxea Larruskain, Rainer Hillenbrand*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

The gas permeability of polymer membranes is determined by their nanoscale morphology, which strongly depends on the membrane fabrication. Here, we demonstrate how the correlation between gas permeability and fabrication-dependent nanoscale morphology of polymer membranes can be elucidated by infrared (IR) nanospectroscopy based on elastic IR scattering at an atomic force microscope tip. Specifically, we fabricated membranes of PEBAX® RNEW – a bio-based polyether-block-amide copolymer – by solvent casting and extrusion, achieving unprecedented CO2 permeability and CO2/N2 selectivity for the solvent-cast membranes. For the extruded membranes, however, we found an about 50 % reduced CO2 permeability, which could not be explained by differential scanning calorimetry and conventional IR spectroscopy. In contrast, IR nanospectroscopy revealed a highly crystalline polyether oxide (PEO) surface layer on the extruded membranes, not observed for the solvent-cast membranes. Annealing of the extruded membranes at 110 °C transformed the crystalline into amorphous PEO layers, as confirmed by IR nanospectroscopy, yielding a gas permeability close to that of the solvent-cast membranes. We thus attribute the dramatic gas reduction of the extruded membranes to their highly crystalline surface layers. Generally, studying polymer morphology by IR nanospectroscopy provides valuable information for better understanding the local gas permeability properties of polymer membranes.

Original languageEnglish
Article number123001
JournalJournal of Membrane Science
Volume708
DOIs
Publication statusPublished - Aug 2024

Keywords

  • Gas separation
  • IR nanospectroscopy
  • Membrane
  • Polyether-block-amides
  • Polymer segregation

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