(579b) Sorption-Enhanced Mixed-Gas Transport in Amine Functionalized Polymers of Intrinsic Microporosity (PIMs) | AIChE

(579b) Sorption-Enhanced Mixed-Gas Transport in Amine Functionalized Polymers of Intrinsic Microporosity (PIMs)

Authors 

Benedetti, F. M., Massachusetts Institute of Technology
Wu, A. X., MIT
Smith, Z., MIT
Roy, N., MIT
Polymers of intrinsic microporosity (PIMs) have shown excellent pure-gas separation performance due to their rigid backbones, inefficient packing, and high free volume. Their out-of-equilibrium packing structures, however, make PIMs susceptible to physical aging and their intrachain rigidity alone has proven insufficient to mitigate plasticization. Moreover, pure-gas transport performance for PIMs rarely matches mixed-gas performance for industrially relevant conditions. For instance, several studies on the mixed-gas transport in PIMs have demonstrated the beneficial effects of competitive sorption on separation performance, where gases with high polymer affinity (e.g., CO2) can reduce the sorption of co-penetrants in a mixture (e.g., CH4 and N2) and increase selectivity. However, due to CO2-induced plasticization at high pressures, decreases in diffusion selectivity can outweigh beneficial competition effects. This trade-off in performance is especially detrimental for PIMs with little CO2 affinity and poor plasticization resistance, as they rely primarily on diffusion-selective transport that may be significantly reduced at high pressure.

Here, we report on mixed-gas transport properties of polymers of intrinsic microporosity (PIMs) with identical benzodioxane backbones, but a diverse set of backbone functionalities. Low-pressure mixed-gas tests indicate a relationship between CO2 sorption affinity and enhancements in CO2/CH4 and CO2/N2 mixed-gas selectivity compared to pure-gas scenarios. The amine-functionalized PIM-1 (PIM-NH2), showed an unprecedented 140% and 250% increase in mixed-gas CO2/CH4 and CO2/N2 mixed-gas selectivity, respectively, compared to pure-gas. Moreover, PIM-NH2 films retained a CO2/CH4 mixed-gas selectivity over 20 up to a total mixed-gas pressure of 26 bar, demonstrating strong plasticization resistance compared to pristine PIM-1. Pure-gas sorption and mixed-gas permeation performance for six PIMs were­ compared across a range of reported microporous polymers, elucidating structure/property relationships that can enable rational design of high-performance chemistries for industrially relevant scenarios. Results demonstrate the promise of primary amine functionalization for developing highly sorption-selective and plasticization-resistant membranes for gas separations.

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