Impact of tuning CO2-philicity in polydimethylsiloxane-based membranes for carbon dioxide separation

• Amidoxime-PDMS membranes with varied amidoxime composition were synthesized.
• The gas separation performance of the membranes exceeded the Robeson upper bound.
• The experimental results showed good consistency with binding energy calculations.

Amidoxime-functionalized polydimethylsiloxane (AO-PDMSPNB) membranes with various amidoxime compositions were synthesized via ring-opening metathesis polymerization followed by post-polymerization modification. Compared to other previously reported PDMS-based membranes, the amidoxime-functionalized membranes show enhanced CO2 permeability and CO2/N2 selectivity. The overall gas separation performance (CO2 permeability 6800 Barrer; CO2/N2 selectivity 19) of the highest performing membrane exceeds the Robeson upper bound line, and the excellent permeability of the copolymer itself provides great potential for real world applications where huge volumes of gases are separated. This paper details how tuning the CO2-philicity within rubbery polymer matrices influences gas transport properties. Key parameters for tuning gas transport properties are discussed, and the experimental results show good consistency with theoretical calculations. This study provides a roadmap to enhancing gas separation performance in rubbery polymers by tuning gas solubility selectivity.

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