T. Graham, On the absorption and dialytic separation of gases by colloid septa, Philosophical Magazine, vol.32, pp.401-420, 1866.

S. Wroblewski, Über die Abhängigkeit der Konstante der Verbreitung der Gase in der Flüssigkeit von der Zähigkeit derselben, Wied. Annln. Phys, vol.8, p.29, 1879.

J. G. Wijmans and R. W. Baker, The solution-diffusion model: a review, J. Membr. Sci, vol.107, pp.1-21, 1995.

K. Cohen, Theory of isotope separation, 1951.

, Separation & purification: critical needs and opportunities, National Academy Press: Board on Chemical Sciences and Technology, 1987.

S. T. Hwang and K. Kammermeyer, Membrane separation of isotopes, Membranes in Separations, 1975.

R. M. Barrer, Diffusion in and through solids, p.1951

S. Weller and W. A. Steiner, Separation of Gases by Fractional Permeation through Membranes, J. Appl. Phys, vol.21, pp.279-283, 1950.

R. W. Baker, ;. , and J. Wiley, Membrane technology and applications, 2004.

W. J. Koros and G. K. Fleming, Membrane-based gas separation, J. Membr. Sci, vol.83, pp.1-80, 1993.

E. Favre, Polymeric membranes for gas separation, Comprehensive Membrane Science and Technology, vol.II, pp.155-212, 2017.
URL : https://hal.archives-ouvertes.fr/hal-01412805

R. W. Baker and B. T. Low, Gas Separation Membrane Materials: A Perspective, Macromolecules, vol.47, pp.6999-7013, 2014.

C. Castel and E. Favre, Membrane separations and energy efficiency, Journal of Membrane Science, vol.548, pp.345-380, 2018.
URL : https://hal.archives-ouvertes.fr/hal-01921399

C. Castel, L. Wang, J. P. Corriou, and E. Favre, Steady vs unsteady membrane gas separation processes, Chemical Engineering Science, vol.183, pp.136-147, 2018.
URL : https://hal.archives-ouvertes.fr/hal-01921396

S. A. Stern and W. P. Walawend, Analysis of membrane separation parameters, Sep. Sci, vol.4, p.129, 1969.

C. T. Blaisdell and K. Kammermeyer, Counter-current and co-current gas separation, Chem. Eng. Sci, vol.28, pp.1249-1255, 1973.

C. Y. Pan and H. W. Habgood, An analysis of the single-stage gaseous permeation process, Ind. Eng. Chem. Fundam, vol.4, pp.323-331, 1974.

C. Pan and H. W. Habgood, Gas separation by permeation part I. Calculation methods and parametric analysis, Can. J. Chem. Eng, vol.56, pp.197-209, 1978.

S. P. Kaldis, G. C. Kapantaidakis, and G. P. Sakellaropoulos, Simulation of multicomponent gas separation in a hollow fiber membrane by orthogonal collocation-hydrogen recovery from refinery gases, J. Membr. Sci, vol.173, pp.61-68, 2000.

M. J. Thundyil and W. J. Koros, Mathematical modeling of gas separation permeatorsfor radial crossflow, countercurrent, and cocurrent hollow fiber membrane modules, J. Membr. Sci, vol.36, pp.114-134, 1997.

M. Scholz, T. Harlacher, T. Melin, and M. Wessling, Modeling Gas Permeation by Linking Nonideal Effects, Ind. Eng. Chem. Res, vol.52, pp.1079-1088, 2013.

D. T. Coker, T. Allen, B. D. Freeman, and G. K. Fleming, Nonisothermal model for gas separation hollow-fiber membranes, AIChE J, vol.45, pp.1451-1468, 1999.

F. Ahmad, K. K. Lau, A. M. Shariff, and Y. Fong-yeong, Temperature and pressure dependence of membrane permeance and its effect on process economics of hollow fiber gas separation system, J. Membr. Sci, vol.430, pp.44-55, 2013.

H. Gorissen, Temperature changes involved in membrane gas separations, Chem. Eng. Process. Process Intensif, vol.22, pp.63-67, 1987.

X. Feng and R. Y. Huang, Concentration polarization in pervaporation separation processes, J. Membr. Sci, vol.92, pp.201-208, 1994.

A. Alpers, B. Keil, O. Lüdtke, and K. Ohlrogge, Organic Vapor Separation: Process Design with Regards to High-Flux Membranes and the Dependence on Real Gas Behavior at High Pressure Applications, Ind. Eng. Chem. Res, vol.38, pp.3754-3760, 1999.

R. Bounaceur, E. Berger, M. Pfister, A. A. Santos, and E. Favre, Rigorous variable permeability modelling and process simulation for the design of polymeric membrane gas separation units: MEMSIC simulation tool, J. Membr. Sci, vol.523, pp.77-91, 2017.
URL : https://hal.archives-ouvertes.fr/hal-01412812

C. Servel, D. Roizard, E. Favre, and D. Horbez, Improved energy efficiency of a hybrid pervaporation/distillation process for acetic acid production: Identification of target membrane performances by simulation, Industrial and Engineering Chemistry Research, vol.53, pp.7768-7779, 2014.
URL : https://hal.archives-ouvertes.fr/hal-01275613

R. Rautenbach and W. Dahm, Gas Permeation -Module Design and Arrangement, Chem. Eng. Process. Process Intensif, vol.21, pp.141-150, 1987.

R. A. Davis, Simple Gas Permeation and Pervaporation Membrane Unit Operation Models for Process Simulators, Chem. Eng. Technol, vol.25, pp.717-722, 2002.

M. H. Chowdhury, X. Feng, P. Douglas, and E. Croiset, A New Numerical Approach for a Detailed Multicomponent Gas Separation Membrane Model and AspenPlus Simulation, Chem. Eng. Technol, vol.28, pp.773-782, 2005.

F. Ahmad, K. K. Lau, A. M. Shariff, and G. Murshid, Process simulation and optimal design of membrane separation system for CO2 capture from natural gas, Comput. Chem. Eng, vol.36, pp.119-128, 2012.

M. M. El-halwagi and V. Manousiouthakis, Synthesis of mass exchange networks, AIChE Journal, vol.35, pp.1233-1244, 1989.

D. F. Rudd, G. J. Powers, and J. J. Siirola, Process Synthesis, 1973.

R. W. Thompson and C. J. King, Systematic synthesis of separation schemes, AIChE J, vol.18, pp.941-948, 1972.

L. Biegler, I. Grossmann, and A. Westerberg, Systematic methods for chemical process design, 1997.

C. A. Floudas, Separation synthesis of multicomponent feed streams into multicomponent product streams, AIChE Journal, vol.33, pp.540-550, 1987.

M. Scholz, M. Alders, T. Lohaus, and M. Wessling, Structural optimization of membrane-based biogas upgrading processes, J. Membr. Sci, vol.474, pp.1-10, 2015.

M. Bozorg, B. Addis, V. Piccialli, A. Ramírez-santos, C. Castel et al., Polymeric membrane materials for nitrogen production from air: A process synthesis study, Chemical Engineering Science, vol.207, pp.1196-1213, 2019.

A. Ramírez-santos, M. Bozorg, B. Addis, V. Piccialli, C. Castel et al., Favre, Optimization of multistage membrane gas separation processes. Example of application to CO2 capture from blast furnace gas, Journal of Membrane Science, vol.566, pp.346-366, 2018.

A. K. Geim, Graphene: Status and prospects, vol.324, pp.1530-1534, 2009.

D. Jiang, V. R. Cooper, and S. Dai, Porous graphene as the ultimate membrane for gas separation, Nano Lett, vol.9, pp.4019-4024, 2009.

A. I. Skoulidas, D. M. Ackerman, J. K. Johnson, and D. S. Sholl, Rapid transport of gases in carbon nanotubes, Phys. Rev. Lett, vol.89, p.185901, 2002.

J. Gascon and F. , Kapteijn Metal-organic framework membranes -high potential, bright future?, Angew. Chem. Int. Ed, vol.49, pp.1530-1532, 2010.

S. Matson, Separation of gases with synthetic membranes, Chemical Engineering Science, vol.38, pp.503-524, 1983.

D. S. Sholl and R. P. Lively, Seven chemical separations to change the world, Nature, vol.532, pp.435-437, 2016.

M. Galizia, W. Chi, Z. P. Smith, T. C. Merkel, R. W. Baker et al., Polymers and Mixed Matrix Membranes for Gas and Vapor Separation: A Review and Prospective Opportunities, Macromolecules, p.50, 2017.

A. F. Ismail, K. C. Kulbe, and T. Matsuura, Gas separation membranes, 2015.

J. G. Wijmans and P. Hao, Influence of the porous support on diffusion in composite membranes, Journal of Membrane Science, vol.474, pp.78-85, 2015.

,

S. P. Lim, X. Tan, and K. Li, Gas/vapour separation using membranes: Effect of pressure drop in lumen of hollow fibers, Chemical Engineering Science, vol.55, pp.2641-2652, 2000.

C. A. Scholes, A. Qader, G. W. Stevens, and S. E. Kentish, Membrane pilot plant trials of CO2 separation from flue gas, Greenh. Gas Sci. Technol, vol.5, pp.229-237, 2015.

L. S. White, X. Wei, S. Pande, T. Wu, and T. C. Merkel, Extended flue gas trials with a membrane-based pilot plant at a one-ton-per-day carbon capture rate, J. Membr. Sci, vol.496, pp.48-57, 2015.

A. Caravella, G. Barbieri, and E. Drioli, Concentration polarization analysis in self supported Pd-based membranes, Sep. Purif. Technol, vol.66, pp.613-624, 2009.

H. Takaba and S. Nakao, Computational fluid dynamics study on concentration polarization in H2/CO separation membranes, J. Membr. Sci, vol.249, pp.83-88, 2005.

H. Lin, S. M. Thompson, A. S. Martin, J. G. Wijmans, K. D. Amo et al., Dehydration of natural gas using membranes. Part II: sweep/ countercurrent design and field test, J. Membr. Sci, vol.432, pp.106-114, 2013.

T. Brinkmann, C. Naderipour, J. Pohlmann, J. Wind, T. Wolff et al., Pilot scale investigations of the removal of carbon dioxide from hydrocarbon gas streams using poly(ethylene oxide) -poly(butylene terephthalate) Polyactive? thin film composite membranes, J. Membr. Sci, vol.489, pp.237-247, 2015.

M. Sandru, T. J. Kim, W. Capala, M. Huijbers, and M. B. Hägg, Pilot scale testing of polymeric membranes for CO2 capture from coal fired power plants, Energy Procedia, vol.37, pp.6473-6480, 2013.

P. Suzana, P. Nunes, G. Z. Culfaz-emecen, T. Ramon, G. Visser et al., Thinking the future of membranes: Perspectives for advanced and new membrane materials and manufacturing processes, Journal of Membrane Science, vol.598, p.117761, 2020.

A. V. Pluijm, N. Miyagishima, E. V. Burg, and Y. Itami, Spiral wound gas separation membrane modules, pp.256827-256828, 2016.