%T Perylene based novel mixed matrix membranes with enhanced selective pure and mixed gases (CO2, CH4, and N2) separation %I Elsevier B.V. %V 73 %A S. Saqib %A S. Rafiq %A N. Muhammad %A A.L. Khan %A A. Mukhtar %A N.B. Mellon %A Z. Man %A M.H. Nawaz %A F. Jamil %A N.M. Ahmad %D 2020 %R 10.1016/j.jngse.2019.103072 %O cited By 25 %J Journal of Natural Gas Science and Engineering %L scholars14032 %K Carbon dioxide; Filled polymers; Fillers; Gas permeability; Hydrogen bonds; Kinetic energy; Kinetics; Polycyclic aromatic hydrocarbons; Polysulfones; Separation, CO2 separation; Filler-polymers; High thermal stability; Interfacial voids; Mixed matrix membranes; Organic fillers; Perylenes; Solution-casting method, Gas permeable membranes %X A combination of organic filler exhibiting CO2 philic nature with a polymer to develop mixed matrix membranes (MMMs) can capture CO2 efficiently. This work reports the synthesis of perylene filler and polysulfone (PSf)-based MMMs via solution casting method. The successful incorporation of fillers, uniformity/asymmetric, and amorphous nature of MMMs were investigated by FT-IR, FESEM, and PXRD analysis, respectively. MMMs demonstrated high thermal stability with significant weight retention over 750 °C investigated by TGA analysis. The existence of Lewis's basic functionalities, hydrogen bonding, and �-� bonds between the filler-polymer resulted in the formation of highly CO2 philic structure. Results revealed that the perylene is found to be highly porous (1050 m2/g) and compatible with the PSf to form additional channels, enhancement of free PSf volume and tendency to prevent the agglomeration and non-selective interfacial voids. It demonstrated improved permeabilities of CO2 (138), CH4 (59), and N2 (60) without any significant variation in selectivities CO2/CH4 (3) and CO2/CH4 (7). Similarly, mixed gas permeabilities were improved for (CO2�CH4 � 119) and (CO2�N2 � 116) along with enhanced selectivities (CO2�CH4 � 50) and (CO2�N2 � 46). Furthermore, the influence of temperature on gas permeabilities revealed improved kinetic energy and flexibility in the polymer chains. The mechanical strength analysis revealed high filler-polymer compatibility. These results revealed great potential of MMMs for efficient CO2 separation from pre- and post-combustion sources. © 2019 Elsevier B.V.