Highly permeable reverse osmosis membranes incorporated with hydrophilic polymers of intrinsic microporosity via interfacial polymerization

doi:10.1016/j.cjche.2021.05.002

Abstract

Abstract: Enhancing the water permeation while maintaining high salt rejection of existing reverse osmosis (RO) membranes remains a considerable challenge. Herein, we proposed to introduce polymer of intrinsic microporosity, PIM-1, into the selective layer of reverse osmosis membranes to break the trade-off effect between permeability and selectivity. A water-soluble a-LPIM-1 of low-molecular-weight and hydroxyl terminals was synthesized. These designed characteristics endowed it with high solubility and reactivity. Then it was mixed with m-phenylenediamine and together served as aqueous monomer to react with organic monomer of trimesoyl chloride via interfacial polymerization. The characterization results exhibited that more “nodule” rather than “leaf” structure formed on RO membrane surface, which indicated that the introduction of the high free-volume of a-LPIM-1 with three dimensional twisted and folded structure into the selective layer effectively caused the frustrated packing between polymer chains. In virtue of this effect, even with reduced surface roughness and unchanged layer thickness, the water permeability of prepared reverse osmosis membranes increased 2.1 times to 62.8 L·m^-2·h^-1 with acceptable NaCl rejection of 97.6%. This attempt developed a new strategy to break the trade-off effect faced by traditional polyamide reverse osmosis membranes.

Key words: PIM-1, Intrinsic microporosity, Reverse osmosis, Interfacial polymerization, Trade-off

摘要： Enhancing the water permeation while maintaining high salt rejection of existing reverse osmosis (RO) membranes remains a considerable challenge. Herein, we proposed to introduce polymer of intrinsic microporosity, PIM-1, into the selective layer of reverse osmosis membranes to break the trade-off effect between permeability and selectivity. A water-soluble a-LPIM-1 of low-molecular-weight and hydroxyl terminals was synthesized. These designed characteristics endowed it with high solubility and reactivity. Then it was mixed with m-phenylenediamine and together served as aqueous monomer to react with organic monomer of trimesoyl chloride via interfacial polymerization. The characterization results exhibited that more “nodule” rather than “leaf” structure formed on RO membrane surface, which indicated that the introduction of the high free-volume of a-LPIM-1 with three dimensional twisted and folded structure into the selective layer effectively caused the frustrated packing between polymer chains. In virtue of this effect, even with reduced surface roughness and unchanged layer thickness, the water permeability of prepared reverse osmosis membranes increased 2.1 times to 62.8 L·m^-2·h^-1 with acceptable NaCl rejection of 97.6%. This attempt developed a new strategy to break the trade-off effect faced by traditional polyamide reverse osmosis membranes.

关键词: PIM-1, Intrinsic microporosity, Reverse osmosis, Interfacial polymerization, Trade-off

Jing Dou, Shuo Han, Saisai Lin, Zhikan Yao, Lian Hou, Lin Zhang. Highly permeable reverse osmosis membranes incorporated with hydrophilic polymers of intrinsic microporosity via interfacial polymerization[J]. Chinese Journal of Chemical Engineering, 2022, 45(5): 194-202.

References

[1] V.G. Gude, Desalination and sustainability——An appraisal and current perspective, Water Res. 89 (2016) 87-106
[2] J.X. Sun, Y. Wang, S.C. Xu, S.C. Wang, Energy recovery device with a fluid switcher for seawater reverse osmosis system, Chin. J. Chem. Eng. 16 (2) (2008) 329-332
[3] A. Subramani, J.G. Jacangelo, Emerging desalination technologies for water treatment:Acritical review, Water Res. 75 (2015) 164-187
[4] W.J. Lau, S. Gray, T. Matsuura, D. Emadzadeh, J.P. Chen, A.F. Ismail, A review on polyamide thin film nanocomposite (TFN) membranes:History, applications, challenges and approaches, Water Res. 80 (2015) 306-324
[5] J.N. Zheng, F.B. Cheng, Y.P. Li, X. Lü, M.J. Yang, Progress and trends in hydrate based desalination (HBD) technology:A review, Chin. J. Chem. Eng. 27 (9) (2019) 2037-2043
[6] J.G. Wijmans, R.W. Baker, The solution-diffusion model:A review, J. Membr. Sci. 107 (1-2) (1995) 1-21
[7] D.R. Paul, Reformulation of the solution-diffusion theory of reverse osmosis, J. Membr. Sci. 241 (2) (2004) 371-386
[8] G.M. Geise, D.R. Paul, B.D. Freeman, Fundamental water and salt transport properties of polymeric materials, Prog. Polym. Sci. 39 (1) (2014) 1-42
[9] M.H. Cohen, D. Turnbull, Molecular transport in liquids and glasses, J. Chem. Phys. 31 (5) (1959) 1164-1169
[10] Z.X. Low, P.M. Budd, N.B. McKeown, D.A. Patterson, Gas permeation properties, physical aging, and its mitigation in high free volume glassy polymers, Chem. Rev. 118 (12) (2018) 5871-5911
[11] Y.C. Xiao, B.T. Low, S.S. Hosseini, T.S. Chung, D.R. Paul, The strategies of molecular architecture and modification of polyimide-based membranes for CO₂ removal from natural gas-A review, Prog. Polym. Sci. 34 (6) (2009) 561-580
[12] W. Xie, H. Ju, G.M. Geise, B.D. Freeman, J.I. Mardel, A.J. Hill, J.E. McGrath, Effect of free volume on water and salt transport properties in directly copolymerized disulfonated poly(arylene ether sulfone) random copolymers, Macromolecules 44 (11) (2011) 4428-4438
[13] C.H. Lee, D. Vanhouten, O. Lane, J.E. McGrath, J.B. Hou, L.A. Madsen, J. Spano, S. Wi, J. Cook, W. Xie, H.J. Oh, G.M. Geise, B.D. Freeman, Disulfonated poly(arylene ether sulfone) random copolymer blends tuned for rapid water permeation via cation complexation with poly(ethylene glycol) oligomers, Chem. Mater. 23 (4) (2011) 1039-1049
[14] Y. Li, J.Y. Zhu, S. Li, Z. Guo, B. van der Bruggen, Flexible aliphatic-aromatic polyamide thin film composite membrane for highly efficient organic solvent nanofiltration, ACS Appl. Mater. Interfaces 12 (28) (2020) 31962-31974
[15] Y. Zhang, L.M. Yang, K.P. Pramoda, W.X. Gai, S. Zhang, Highly permeable and fouling-resistant hollow fiber membranes for reverse osmosis, Chem. Eng. Sci. 207 (2019) 903-910
[16] N. Petzetakis, C.M. Doherty, A.W. Thornton, X.C. Chen, P. Cotanda, A.J. Hill, N.P. Balsara, Membranes with artificial free-volume for biofuel production, Nat. Commun. 6 (2015) 7529
[17] B.F. Li, S. Japip, T.S. Chung, Molecularly tunable thin-film nanocomposite membranes with enhanced molecular sieving for organic solvent forward osmosis, Nat. Commun. 11 (1) (2020) 1198
[18] Q.L. Song, S.K. Nataraj, M.V. Roussenova, J.C. Tan, D.J. Hughes, W. Li, P. Bourgoin, M.A. Alam, A.K. Cheetham, S.A. Al-Muhtaseb, E. Sivaniah, Zeolitic imidazolate framework (ZIF-8) based polymer nanocomposite membranes for gas separation, Energy Environ. Sci. 5 (8) (2012) 8359-8369
[19] G.M. Shi, H.M. Chen, Y.C. Jean, T.S. Chung, Sorption, swelling, and free volume of polybenzimidazole (PBI) and PBI/zeolitic imidazolate framework (ZIF-8) nano-composite membranes for pervaporation, Polymer 54 (2) (2013) 774-783
[20] L.W. Xu, L. Xiang, C.Q. Wang, J. Yu, L.X. Zhang, Y.C. Pan, Enhanced permeation performance of polyether-polyamide block copolymer membranes through incorporating ZIF-8 nanocrystals, Chin. J. Chem. Eng. 25 (7) (2017) 882-891
[21] D.L. Zhao, W.S. Yeung, Q.P. Zhao, T.-S. Chung, Thin-film nanocomposite membranes incorporated with UIO-66-NH₂ nanoparticles for brackish water and seawater desalination, J. Membr. Sci. 604 (2020) 118039
[22] B.S. Ghanem, K.J. Msayib, N.B. McKeown, K.D. Harris, Z.G. Pan, P.M. Budd, A. Butler, J. Selbie, D. Book, A. Walton, A triptycene-based polymer of intrinsic microposity that displays enhanced surface area and hydrogen adsorption, Chem. Commun.(Camb) (1) (2007) 67-69
[23] N. Chaoui, M. Trunk, R. Dawson, J. Schmidt, A. Thomas, Trends and challenges for microporous polymers, Chem. Soc. Rev. 46 (11) (2017) 3302-3321
[24] S. Das, P. Heasman, T. Ben, S.L. Qiu, Porous organic materials:strategic design and structure-function correlation, Chem. Rev. 117 (3) (2017) 1515-1563
[25] N.B. McKeown, P.M. Budd, Polymers of intrinsic microporosity (PIMs):Organic materials for membrane separations, heterogeneous catalysis and hydrogen storage, Chem. Soc. Rev. 35 (8) (2006) 675-683
[26] Y. Han, W.S.W. Ho, Recent advances in polymeric membranes for CO₂ capture, Chin. J. Chem. Eng. 26 (11) (2018) 2238-2254
[27] B.S. Ghanem, N.B. McKeown, P.M. Budd, J.D. Selbie, D. Fritsch, High-performance membranes from polyimides with intrinsic microporosity, Adv. Mater. 20 (14) (2008) 2766-2771
[28] B.S. Ghanem, N.B. McKeown, P.M. Budd, N.M. Al-Harbi, D. Fritsch, K. Heinrich, L. Starannikova, A. Tokarev, Y. Yampolskii, Synthesis, characterization, and gas permeation properties of a novel group of polymers with intrinsic microporosity:PIM-polyimides, Macromolecules 42 (20) (2009) 7881-7888
[29] P.M. Budd, B.S. Ghanem, S. Makhseed, N.B. McKeown, K.J. Msayib, C.E. Tattershall, Polymers of intrinsic microporosity (PIMs):Robust, solution-processable, organic nanoporous materials, Chem. Commun. (2) (2004) 230-231
[30] N.B. McKeown, P.M. Budd, K.J. Msayib, B.S. Ghanem, H.J. Kingston, C.E. Tattershall, S. Makhseed, K.J. Reynolds, D. Fritsch, Polymers of intrinsic microporosity (PIMs):Bridging the void between microporous and polymeric materials, Chem.-Eur. J. 11 (9) (2005) 2610-2620
[31] A.F. Bushell, M.P. Attfiled, C.R. Mason, P.M. Budd, Y. Yampolskii, L. Starannikova, A. Rebrov, F. Bazzarelli, P. Bernardo, J.C. Jansen, M. Lanc, K. Friess, V. Shantarovich, V. Gustov, V. Isaeva, Gas permeation parameters of mixed matrix membranes based on the polymer of intrinsic microporosity PIM-1 and the zeolitic imidazolate framework ZIF-8, J. Membr. Sci. 427 (2013) 48-62
[32] D. Chang, M. Yu, C. Zhang, Y. Zhao, R. Kong, F.Y. Xie, J.X. Jiang, Indolo[3, 2-b]carbazole-containing hypercrosslinked microporous polymer networks for gas storage and separation, Microporous Mesoporous Mater. 228 (2016) 231-236
[33] N.Y. Du, H.B. Park, G.P. Robertson, M.M. Dal-Cin, T. Visser, L. Scoles, M.D. Guiver, Polymer nanosieve membranes for CO₂-capture applications, Nat. Mater. 10 (5) (2011) 372-375
[34] P.M. Budd, N.B. McKeown, B.S. Ghanem, K.J. Msayib, D. Fritsch, L. Starannikova, N. Belov, O. Sanfirova, Y. Yampolskii, V. Shantarovich, Gas permeation parameters and other physicochemical properties of a polymer of intrinsic microporosity:Polybenzodioxane PIM-1, J. Membr. Sci. 325 (2) (2008) 851-860
[35] P. Gorgojo, S. Karan, H.C. Wong, M.F. Jimenez-Solomon, J.T. Cabral, A.G. Livingston, Ultrathin polymer films with intrinsic microporosity:Anomalous solvent permeation and high flux membranes, Adv. Funct. Mater. 24 (30) (2014) 4728-4737
[36] X.M. Wu, Q.G. Zhang, F. Soyekwo, Q.L. Liu, A.M. Zhu, Pervaporation removal of volatile organic compounds from aqueous solutions using the highly permeable PIM-1 membrane, AIChE J. 62 (3) (2016) 842-851
[37] S. Thomas, I. Pinnau, N.Y. Du, M.D. Guiver, Pure- and mixed-gas permeation properties of a microporous spirobisindane-based ladder polymer (PIM-1), J. Membr. Sci. 333 (1-2) (2009) 125-131
[38] M.F. Jimenez-Solomon, Q.L. Song, K.E. Jelfs, M. Munoz-Ibanez, A.G. Livingston, Polymer nanofilms with enhanced microporosity by interfacial polymerization, Nat. Mater. 15 (7) (2016) 760-767
[39] Z.H. Wang, S. Guo, B. Zhang, L.P. Zhu, Hydrophilic polymers of intrinsic microporosity as water transport nanochannels of highly permeable thin-film nanocomposite membranes used for antibiotic desalination, J. Membr. Sci. 592 (2019) 117375
[40] Q. Shi, K. Zhang, R.F. Lu, J.W. Jiang, Water desalination and biofuel dehydration through a thin membrane of polymer of intrinsic microporosity:Atomistic simulation study, J. Membr. Sci. 545 (2018) 49-56
[41] J.S. Song, N.Y. Du, Y. Dai, G.P. Robertson, M.D. Guiver, S. Thomas, I. Pinnau, Linear high molecular weight ladder polymers by optimized polycondensation of tetrahydroxytetramethylspirobisindane and 1, 4-dicyanotetrafluorobenzene, Macromolecules 41 (20) (2008) 7411-7417
[42] P. Yanaranop, B. Santoso, R. Etzion, J.Y. Jin, Facile conversion of nitrile to amide on polymers of intrinsic microporosity (PIM-1), Polymer 98 (2016) 244-251
[43] K.K. Yan, L. Jiao, S.S. Lin, X.S. Ji, Y. Lu, L. Zhang, Superhydrophobic electrospun nanofiber membrane coated by carbon nanotubes network for membrane distillation, Desalination 437 (2018) 26-33
[44] C.Y. Zhu, H.N. Li, J. Yang, J.J. Li, J.R. Ye, Z.K. Xu, Vacuum-assisted diamine monomer distribution for synthesizing polyamide composite membranes by interfacial polymerization, J. Membr. Sci. 616 (2020) 118557
[45] J. Wang, Y.T. Zhang, J.Y. Zhu, J.W. Hou, J.D. Liu, B. van der Bruggen, Zwitterionic functionalized layered double hydroxides nanosheets for a novel charged mosaic membrane with high salt permeability, J. Membr. Sci. 510 (2016) 27-37
[46] F. Topuz, B. Satilmis, T. Uyar, Electrospinning of uniform nanofibers of polymers of intrinsic microporosity (PIM-1):The influence of solution conductivity and relative humidity, Polymer 178 (2019) 121610
[47] Y. Pan, L.J. Zhang, Z.J. Li, L.J. Ma, Y.F. Zhang, J. Wang, J.Q. Meng, Hierarchical porous membrane via electrospinning PIM-1 for micropollutants removal, Appl. Surf. Sci. 443 (2018) 441-451
[48] C.L. Zhang, P. Li, B. Cao, Electrospun microfibrous membranes based on PIM-1/POSS with high oil wettability for separation of oil-water mixtures and cleanup of oil soluble contaminants, Ind. Eng. Chem. Res. 54 (35) (2015) 8772-8781
[49] L.F. Liu, X. Xie, S.R. Qi, R.H. Li, X. Zhang, X.X. Song, C.J. Gao, Thin film nanocomposite reverse osmosis membrane incorporated with UIO-66 nanoparticles for enhanced boron removal, J. Membr. Sci. 580 (2019) 101-109
[50] O. Akin, F. Temelli, Probing the hydrophobicity of commercial reverse osmosis membranes produced by interfacial polymerization using contact angle, XPS, FTIR, FE-SEM and AFM, Desalination 278 (1-3) (2011) 387-396
[51] C.Y. Tang, Y.N. Kwon, J.O. Leckie, Effect of membrane chemistry and coating layer on physiochemical properties of thin film composite polyamide RO and NF membranes:I. FTIR and XPS characterization of polyamide and coating layer chemistry, Desalination 242 (1-3) (2009) 149-167
[52] Z. Zhang, Y.T. Qin, G.D. Kang, H.J. Yu, Y. Jin, Y.M. Cao, Tailoring the internal void structure of polyamide films to achieve highly permeable reverse osmosis membranes for water desalination, J. Membr. Sci. 595 (2020) 117518
[53] H. Dong, L. Zhao, L. Zhang, H.L. Chen, C.J. Gao, W.S. Winston Ho, High-flux reverse osmosis membranes incorporated with NaY zeolite nanoparticles for brackish water desalination, J. Membr. Sci. 476 (2015) 373-383
[54] S.S. Bing, J.Q. Wang, H. Xu, Y.Y. Zhao, Y. Zhou, L. Zhang, C.J. Gao, L.A. Hou, Polyamide thin-film composite membrane modified with persulfate for improvement of perm-selectivity and chlorine-resistance, J. Membr. Sci. 555 (2018) 318-326
[55] Z. Tan, S.F. Chen, X.S. Peng, L. Zhang, C.J. Gao, Polyamide membranes with nanoscale turing structures for water purification, Science 360 (6388) (2018) 518-521
[56] S.Y. Kwak, S.G. Jung, Y.S. Yoon, D.W. Ihm, Details of surface features in aromatic polyamide reverse osmosis membranes characterized by scanning electron and atomic force microscopy, J. Polym. Sci. B Polym. Phys. 37 (13) (1999) 1429-1440
[57] J.X. Qin, S.S. Lin, S.Q. Song, L. Zhang, H.L. Chen, 4-dimethylaminopyridine promoted interfacial polymerization between hyperbranched polyesteramide and trimesoyl chloride for preparing ultralow-pressure reverse osmosis composite membrane, ACS Appl. Mater. Interfaces 5 (14) (2013) 6649-6656
[58] H.J. Kim, K. Choi, Y. Baek, D.G. Kim, J. Shim, J. Yoon, J.C. Lee, High-performance reverse osmosis CNT/polyamide nanocomposite membrane by controlled interfacial interactions, ACS Appl Mater Interfaces 6 (4) (2014) 2819-2829
[59] J.T. Duan, Y.C. Pan, F. Pacheco, E. Litwiller, Z.P. Lai, I. Pinnau, High-performance polyamide thin-film-nanocomposite reverse osmosis membranes containing hydrophobic zeolitic imidazolate framework-8, J. Membr. Sci. 476 (2015) 303-310
[60] D.H.N. Perera, Q. Song, H. Qiblawey, E. Sivaniah, Regulating the aqueous phase monomer balance for flux improvement in polyamide thin film composite membranes, J. Membr. Sci. 487 (2015) 74-82