Directional porous polyimide/polyethylene glycol composite aerogel with enhanced CO 2 uptake performance

Abstract

The cost of CO₂ separation and energy consumption can be decreased through the use of CO₂ adsorption. Due to the electron-rich heteroatoms in its network, polyimide (PI) has a remarkable affinity for CO₂. Polyethylene glycol (PEG) can increase the layer spacing of polymers, so as to change the mass transfer of CO₂ in it. Furthermore, the ether bond (-O-) in PEG has good affinity for CO_2. In this study, PEG-1000 was introduced into PI aerogel by mild sol-gel method at low temperature, and freeze-drying was used to produce PI/PEG composite aerogels with directional pore structure. The effect of PEG-1000 content and directional pore structure of the PI/PEG composite aerogels on CO₂ adsorption performance were further studied. The L-PI/PEG-4 composite aerogel, which contains 4 g PEG and is directionally frozen in liquid nitrogen, has a CO₂ adsorption capacity of 16.76 cm³/g at 25°C and 1 bar. L-PI/PEG-4 aerogel also exhibits high CO₂/N₂ selectivity and adsorption cycle stability.

Keywords

Polyimide aerogel polyethylene glycol directional pore structure

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