Issue 1, 2011

Grafting thermally labile molecules on cross-linkable polyimide to design membrane materials for natural gas purification and CO2 capture

Abstract

A novel strategy to design molecularly the cavity size and free volume of flexible polyimide materials via thermal treatment of rigid and cross-linkable polyimides grafted with thermal liable side beta-cyclodextrin (CD) molecules is demonstrated in this study. The spaces occupied by the labile groups may become microvoids after low-temperature thermal degradation while the rigid polyimide backbone prevails. The thermal induced cross-linking reaction among polyimide chains may create ultra-fine micro-pores that integrally connect with microvoids. As a result, the thermally cured membranes fabricated from dense polyimide precursors show gas separation performance surpassing the trade-off lines, with tough and flexible mechanical properties. Thermal annealing at 425 °C produces polyimide membranes with the best CO2 permeability of 4016 Barrer with reasonable gas pair selectivity.

Graphical abstract: Grafting thermally labile molecules on cross-linkable polyimide to design membrane materials for natural gas purification and CO2 capture

Article information

Article type
Paper
Submitted
19 Jul 2010
Accepted
10 Sep 2010
First published
20 Oct 2010

Energy Environ. Sci., 2011,4, 201-208

Grafting thermally labile molecules on cross-linkable polyimide to design membrane materials for natural gas purification and CO2 capture

Y. Xiao and T. Chung, Energy Environ. Sci., 2011, 4, 201 DOI: 10.1039/C0EE00278J

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