Current Trends and Future Developments on (Bio-) Membranes

Part 1 New, promising to be commercialized, membrane<br>materials and units<br>1. Review on polymeric membrane materials for gas separations which are<br>stated above the Robeson’s trade-off upper bound<br> <br>2. New inorganic membranes for gas separations which are stated above the<br>Robeson’s trade-off upper bound<br> <br>3. New nonporous fillers-based hybrid membranes for gas separations and water<br>treatment process<br> <br>4. New commercial membranes for gas separations and water desalination<br>processes<br> <br>Part 2 New membrane manufacturing materials<br>5. New metal-organic frameworks and other porous filler-based hybrid<br>membranes for gas separation and wastewater treatment<br> <br>6. Polymers of intrinsic microporosity and their applicability in pilot-scale<br>membrane units<br> <br>7. SiC porous membranes. How possible could be the production of<br>high selective porous SiC membranes?<br> <br>8. Carbon and graphene oxide materials and their potential applications in<br>membrane separation technology<br> <br>9. Solvent and material selection for greener membrane manufacturing<br> <br>10. New polymeric and inorganic membrane materials for water separation<br> <br>Part 3 The next decade’s ideas about the future<br>membrane technology<br>11. Hybrid membranes, liquid/solid, for the enhancement of membrane gas<br>selectivity. The example of ionic liquid membrane<br> <br>12. Cryogenic-membrane gas separation hybrid processes<br> <br>13. New perspectives in gas separations (CO2/CH4, H2/CH4) using membranes<br> <br>14. New perspectives in O2/N2 gas separation<br> <br>15. Recent advances in the application of magnetic/electromagnetic<br>field for water desalination<br> <br>16. Applications of graphene oxide in reverse osmosis membranes<br> <br>17. Membrane water processes and nanobubble technology