Abstract
Membrane-based gas separation has attracted a great deal of attention recently due to the requirement for high purity gasses in industrial applications like fuel cells, and because of environment concerns, such as global warming. The current methods of cryogenic distillation and pressure swing adsorption are energy intensive and costly. Therefore, polymer membranes have emerged as a less energy intensive and cost effective candidate to separate gas mixtures. However, the use of polymeric membranes has a drawback known as the permeability-selectivity tradeoff. Many approaches have been used to overcome this limitation including the use of polymer blends. Polymer blending technology synergistically combines the favorable properties of different polymers like high gas permeability and high selectivity, which are difficult to attain with a single polymer. During polymer mixing, polymers tend to uncontrollably phase separate due to unfavorable thermodynamics, which limits the number of completely miscible polymer combinations for gas separations. Therefore, compatibilizers are used to control the phase separation and to obtain stable membrane morphologies, while improving the mechanical properties. In this review, we focus on immiscible polymer blends and the use of compatibilizers for gas separation applications.
Highlights
The global oil and gas separation market is expected to be worth ~11 billion USD by
Khan et al [39] studied the gas separation properties of polymer blend membranes comprised of Matrimid® 9725 and sulfonated aromatic polyether ether ketone (SPEEK), which formed completely miscible polymer blends over the entire composition range they tested as characterized by DSC studies
In this review we focus on the use of the compatibilizers compatibilizers for gas separation applications
Summary
The global oil and gas separation market is expected to be worth ~11 billion USD by. 2020 [1]. They were, unable to achieve improvements membranes They obtained mechanically stable miscible polymer blend membranes for the above gas pair selectivities [62]. Khan et al [39] studied the gas separation properties of polymer blend membranes comprised of Matrimid® 9725 and sulfonated aromatic polyether ether ketone (SPEEK), which formed completely miscible polymer blends over the entire composition range they tested as characterized by DSC studies. Both pure and mixed gas experiments were carried out for several gases including CO2 , CH4 and N2.
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