@article{scholars8670, doi = {10.1002/app.44761}, year = {2017}, title = {Prediction of CO2 gas permeability behavior of ionic liquid{\^a}??polymer membranes (ILPM)}, note = {cited By 12}, publisher = {John Wiley and Sons Inc.}, number = {17}, journal = {Journal of Applied Polymer Science}, volume = {134}, keywords = {Carbon dioxide; Forecasting; Gas permeability; Gases; Ionic liquids; Liquids; Mechanical permeability; Membranes; Models; Polymeric membranes; Polymers, Accurate prediction; Dispersed phase; Gas separation membrane; Liquid polymers; Literature data; Maxwell models; Model parameters, Gas permeable membranes}, url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85010377906&doi=10.1002\%2fapp.44761&partnerID=40&md5=19a82e7c3aa135b93692ac4e50d5e94c}, author = {Mannan, H. A. and Mukhtar, H. and Murugesan, T. and Man, Z. and Bustam, M. A. and Shaharun, M. S. and Abu Bakar, M. Z.}, abstract = {Predicting the gas permeability of ionic liquid-polymeric membranes (ILPM) is of great importance for the design of efficient gas separation membrane materials. The available models for the prediction of CO2 gas permeability through ionic liquid-polymeric membranes were analyzed using the literature data. Maxwell model was selected for modification due to relatively accurate prediction capability. The Maxwell model was modified for ionic liquid-polymeric membranes by incorporating model parameter k for the effectiveness of volume fraction of dispersed phase. The established methodology was tested for different ionic liquid-polymeric membrane systems for validation. A satisfactory agreement was observed for predicted and experimental permeability by using the current approach. This method can be used for the prediction of CO2 gas permeability through ionic liquid-polymeric membranes. {\^A}{\copyright} 2017 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2017, 134, 44761. {\^A}{\copyright} 2017 Wiley Periodicals, Inc.}, issn = {00218995} }