Abstract

KINETICS AND CATALYSIS; REACTION ENGINEERING; AND MATERIALS SCIENCE

Modification of PSf membrane nanostructure using different fabrication parameters and investigation of the CO₂ separation properties of PDMS-coated PSf composite membranes

M. Pakizeh^* * To whom correspondence should be addressed ; S. A. A. Mansoori; M. Pourafshari Chenar; M. Namvar-Mahboub

Department of Chemical Engineering, Faculty of Engineering, Fax: +98 511 8816840, Ferdowsi University of Mashhad, P.O. Box: 91775-1111, Mashhad, Iran. E-mail: pakizeh@um.ac.ir

ABSTRACT

The effects of preparation parameters on the performance and morphology of polydimethylsiloxane/ polysulfone (PDMS/PSf) membranes were investigated. The PDMS layer is mainly used for sealing the defects of the PSf selective layer. The membrane morphologies were characterized by using scanning electron microscopy (SEM). The CO2/CH4 separation performance of membranes was studied by a pure gas permeation experimental set up. According to the SEM results, decreasing the water/N,N-dimethylacetamide (DMAc) ratio as the coagulation medium from pure water to mixture of 90 vol.% DMAc and 10 vol.% water resulted in complete disappearance of macrovoids and also a lowering of the membrane selectivity. Permselectivity results showed that the ideal CO2/CH4 separation factor of the membranes was improved by the presence of the non-solvent additive to the polymer solution. It was also observed that reduction of the coagulation bath temperature (CBT) led to elimination of macrovoids which affect gas separation performance. Using methanol as a coagulant resulted in a less selective membrane compared with ethanol and water as coagulants and the CO2 permeance was about 3 and 9 times greater than with ethanol and water as coagulants, respectively.

Keywords: Preparation parameters; PDMS/PSf membrane; Coagulation medium; CBT; CO2 separation.

INTRODUCTION

High concentrations of greenhouse gases such as CO2 in the atmosphere cause the main environmental problem associated with global warming and acid rain formation. Besides, elimination of carbon dioxide from fuel gases results in a higher caloric value. Thus, separation of CO2 from gas mixtures seems to be essential (Thambimuthu et al., 2005; Herzog et al., 2000; Abu-Zahra et al., 2009).

Polymeric membranes have been the technology of interest for gas separation processes like those mentioned above. These kinds of membranes have been used to remove CO2 in landfill gas recovery processes, biogas purification, natural gas sweetening, etc. (Basu et al., 2010; Brunettia et al., 2010; Ren et al., 2012). Polymer-based membranes have become more competitive in comparison to the traditional separation processes such as amine scrubbing and cryogenic separation (Olajire, 2010; Klara and Srivastava, 2002; Liu and Shi, 2010; Anderson et al., 2006). At present, natural gas is the most important source of energy; it is also produced in large quantity and it often contains excess CO2. The content of CO2 must be diminished to meet the pipeline specification, i.e., 2 mol% or less (Baker, 2004). It was reported that separation processes using asymmetric polymeric membranes assist in the reduction of the CO2 concentration for upgrading low-quality natural gas (Bhide and Stern, 1993a; Bhide and Stern, 1993b).

Gas separation by composite membranes is increasingly fascinating due to their advantages over integrally skinned asymmetric membranes such as: use of highly permeable polymers, high permeation flux, cost-effectiveness when the materials are costly and ease of being made defect free (Chung et al., 1999).

Coated membranes comprised of a sealing layer and separation film meet these requirements. Besides this, coated membranes provide a flexible approach to membrane fabrication. This is due to the fact that the material of the coating layer is often different from the selective film. Traditionally, coated membranes are prepared by dip-coating a suitable selective membrane with a thin layer of polymer functioning as the sealing layer (Chung et al., 1999; Henis and Triboldi, 1981; Feng and Huang, 1997).

Highly permeable polymer can be used to prepare a defect-free selective top-layer. In this way, membrane selectivity increases significantly, with almost no reduction in permeability (Peter and Peinemann, 2009). PDMS is the most commonly used rubbery membrane material for the above purpose. Its glass transition temperature is among the lowest values recorded for polymers (-123 ºC) indicating a very flexible polymer backbone with long-range segmental motion (Brandrup et al., 1999). The PDMS membranes synthesized up to now and evaluated in gas separation applications were in the form of a single layer (Choi et al., 2007; Raharjo, 2007) or of a composite with a macroporous support (Wu, 2006; Yeow, 2002), or a mixed matrix (Kim et al., 2004). As a glassy polymer, PSf has some favorable characteristics such as wide operating temperature limits; maximum and optimum physical properties such as strength and flexibility; good toughness; easy fabrication in a wide variety of configurations and modules and relative low cost, which make it suitable for gas separation processes (Xu and Qusay, 2004; Shi et al., 2007; Rafiq et al., 2012). The fabrication parameters of PSf, significantly affect its morphology and separation performance.

Wang et al. (2002) reported that adding nonsolvent additives into the casting solution can decrease the dissolving power of the solvent and therefore increase the polymer-polymer interaction. Adding a non-solvent additive to the PSf polymer solution augments the tendency of polymer chains to adopt a more tightly coiled conformation. From the other point of view, when non-solvents are added to the polymer solution, polymer solidification can swiftly occur at the membrane surface and, accordingly, membranes with a thin skin layer and a more uniform structure can be formed (Wang et al., 1995).

Wijmans et al. (1983) investigated the effect of coagulation bath composition on the structural characteristics of cellulose acetate (CA) membranes and found that small amounts of solvent in the coagulation bath can promote instantaneous liquidliquid phase separation. The existence of a thick dense skin is also associated with instantaneous liquid-liquid phase separation. A high concentration of solvent in the bath results in the transition from instantaneous to delayed formation which causes the formation of a microporous structure without a dense skin.

The effect of CBT variation on the structural parameters of CA membranes was studied by Smolders et al. (1992). They found that the increase of CBT causes the formation of macrovoids and a more porous structure. The coagulation medium is another important synthesis parameter which can exert drastic effects on the resulting structures of membranes made by phase inversion processes (Banks and Sharples, 1966; Saler et al., 1974; Strathmann, 1985; Mulder et al., 1985; Wijmans et al., 1985; Bottmo et al., 1985).

In this study, the effect of coagulation bath temperature, the solvent/coagulant ratio, the coagulant type and the presence of non-solvent in the casting solution on the morphology of composite PDMS/PSf membranes was studied. Moreover, prepared membranes were subjected to gas separation tests to evaluate the performance of the resultant membranes.

EXPERIMENTAL

Materials and Module

Polysulfone (PSf Ultrason-6010) was supplied by BASF Corporation as the polymer for preparation of the membrane casting solutions. Commercially available DMAc and tetrahydrofuran (THF) were used as solvents for polysulfone, the organic non-solvents used were methanol (MeOH), ethanol (EtOH) and deionized water, which were purchased from Merck. n-Hexane (as solvent) was supplied by Merck. PDMS (viscosity 5000 mPas), tetraethylorthosilicate (TEOS as crosslinker), and dibutyltin dilaurate (DBTDL as catalyst) were purchased from Beijing Chemical Company, China. All liquid solvents were reagent grade and used without further purification. CO2 and CH4 gas cylinders were purchased from Technical Gas Services. The dead-end membrane cells, made from stainless steel (grade 316), were used to carry out the experiments. The schematic view of the manufactured membrane module is shown in Fig. 1. The membranes were placed in the cells that consisted of two detachable parts. Rubber O-rings were used to supply a pressure-tight seal between the membranes and the cells. The membranes had an effective area of approximately 15.7 cm².

Membrane Preparation

Asymmetric PSf flat sheet membranes were prepared by casting. The casting solution generally consisted of polysulfone (polymer), DMAc (less volatile solvent), tetrahydrofuran (THF, more volatile solvent) and ethanol (EtOH, non-solvent). Casting was performed at 298 K in air using a casting blade. Membranes were cast at a designated wet thickness (200µm) onto a polished glass plate. Then, forced-convective evaporation was induced by flowing an inert nitrogen gas stream across the membrane surface for 20s before immersion in a coagulation bath and then it was immediately immersed in the coagulant bath (immersion precipitation method). The water in the membrane was further replaced with ethanol by immersing the membrane for 24 h in aqueous solutions of ethanol with progressively higher ethanol concentrations. Four solutions with different ethanol contents (25, 50, 75 and 100 vol.%) were prepared for this purpose. Then the membrane was immersed in hexane for 24 h in order to extract the ethanol before it was dried with air.

Composite Membrane Preparation

10 g PDMS, 1 g of the crosslinking agent TEOS, and 0.2 g of the catalyst DBTDL were mixed in 40 g of n-hexane for 30 min at 70 ºC under stirring. The coating solution was then cast on the PSf membranes and they were put under a hood overnight in order to eliminate the solvent by evaporation at ambient temperature. As prepared, the membranes were treated for 1 h at 150 ºC in a vacuum oven to complete the crosslinking. A typical cross-sectional SEM image of the PDMS/PSf membrane is shown in Fig. 2. As can be observed, the asymmetric PSf membrane contains a thin selective layer with a thickness of approximately 2µm and a highly permeable coated layer with a thickness of 10µm. The total thickness of the PSf membrane, including the top and porous layers, is about 120 µm.

Membrane Characterizations

Scanning Electron Microscopy (SEM)

The membranes were fractured under liquid nitrogen to give a generally consistent and clean break. The membranes were then sputter-coated with a thin film of gold. The membranes were mounted on brass plates with double-sided adhesive tape in a lateral position. Cross-sectional images of the membranes were obtained with a Cam Scan SEM model LED 1450 VP microscope (LEO, Germany).

Gas Permeation Measurements

A constant pressure system was used for the gas permeation experiments as shown in Fig. 3. Gas permeation tests were performed by using two permeation cells. Circular coated membrane discs with an effective permeation area of 15.7 cm² (membrane area of two cells) were used.

The permeation rates were measured by a bubble flow-meter. The CO2/CH4 separation experiments were conducted at room temperature (25 ºC) and 4 bar pressure. The gas permeates were collected at ambient pressure. Each test was repeated 3 times and the average value is presented.

According to Pesek and Koros (1993), asymmetric membranes are defined to be 'defect-free' if the selectivity of a membrane is greater than 80% of the intrinsic value. The intrinsic permeation properties of dense PSf for CO2 and CH4 are given in Table 1 (Chern et al., 1985).

RESULTS AND DISCUSSION

Effects of the Non-Solvent in the Casting Solution

The optimum non-solvent concentration in the casting solution has to be determined in order to achieve defect-free and ultrathin-skinned asymmetric membranes for gas separation processes. The phase separation is further controlled by the thermodynamic properties of the casting solution and the nonsolvent in the coagulant bath. The addition of a nonsolvent additive to the polymer solution has been found to play a basic role in the development of polymeric membranes for gas separation. Three different casting solutions were prepared by varying of non-solvent (ethanol) content and were used to study the effect of non-solvent on the membrane properties. In the case of a non-solvent free casting solution, a thick skin covers a porous sublayer with a relatively uniform pore size distribution. The sample obtained in this case is formed by a delayed mechanism of liquid-liquid phase separation (Mulder, 1996). The effect of non-solvent additive on the permeance for methane and carbon dioxide and on the CO2/CH4 selectivity at pressure of 4 bar of the composite membranes prepared with different casting solution compositions is depicted in Table 2. As an interesting finding, the selectivity of the synthesized composite membrane surpassed that of the isotropic PSf film reported in Table 1.

As can be seen in Table 2, the ideal CO₂/CH₄ separation factor is enhanced from 25 (without ethanol) to 28.8 (14.4 wt.% ethanol) by introducing the ethanol additive. Recently, Aroon et al. (2010) reported that, by using 10.7 wt.% ethanol as additive, an ideal selectivity of 5.09 was obtained for COsub /CH₄ when NMP was used as solvent. They also obtained a selectivity of 12.45 for CO2/CH4 with 10 wt.% ethanol as additive in the case of a NMP/ THF mixture as solvent. Considering Table 2, the CO2 permeance was slightly enhanced from 14.5 GPU to 17 GPU by increasing the amount of the non-solvent. This can be attributed to instantaneous demixing induced by the presence of the non-solvent additive that caused the formation of a thin skin layer. Among these three cases, a casting solution that contains 14.4 wt% ethanol was less defective than other casting solutions. Hence, as a result, increasing the ethanol can increase the coalescence of the polymer chains in the dense layer and thus the formation of a less defective dense layer.

Effect of the Gelation Bath Solvent Content

According to Table 3, the four samples containing different solvent/water ratios were prepared in order to study the effect of solvent content in the gelation bath on the PSf characteristics. The cross-sections of membranes prepared from a given casting solution (22 wt.% PSf, 31.8% DMAc, 31.8% THF, 14.4% EtOH) and gelation baths with varying solvent/water ratios are shown in Fig. 4. As indicated in Figs. 4 (a) to (c), with increasing amount of solvent in the coagulation bath, one observes a decreasing number of macrovoids in membrane structure. Consequently, the morphology changes from a finger-like to a sponge-like structure. As can be seen at higher magnification, with increasing solvent amount in the coagulation bath, the cell size becomes larger. This can be explained as follows: the cells are formed via a secondary nucleation and growth mechanism in the polymerrich phase and growth takes place because of the diffusional flow of solvent from the surrounding polymer solution. A nucleus can only grow if a stable composition is induced in front of it by diffusion. Growth will cease if a new stable nucleus is formed in front of the first formed nucleus. Stropnik et al. (2002) presented a similar interpretation of cell size variations for several polymeric membranes. The macrovoids are formed via a spinodal demixing mechanism and small cells around the macrovoids are formed via a secondary nucleation and growth mechanism in the polymerrich phase (Aroon et al., 2010). Generally, the macrovoid formation is a result of the liquid-liquid demixing process, where the nuclei of the polymerpoor phase are responsible for macrovoid formation. In this way, growth of the macrovoids occurs and this growth continues until the polymer concentration at the macrovoid/solution interface becomes so high that solidification occurs (Amirilargani et al., 2009). In Fig. 4 (c), it can be observed that the number of finger voids has decreased notably. In Fig. 4 (d), the finger voids have completely disappeared, which means that the primary phase separation mechanism is nucleation and growth of the polymer poor phase (Stropnik et al., 2002). In this case, the solidification rate is very slow so that cells can grow and coalesce with each other, which results in an open and large cellular structure.

Table 3 shows the effect of DMAc concentration in the coagulation bath on the permeance of methane and carbon dioxide and on the pure gas CO2/CH4 separation factor of composite membranes at a pressure of 4 bar. The permeation results showed that the CO2 permeance was increased by increasing the concentration of the solvent in the coagulation bath. This can be attributed to the delayed demixing induced by the presence of the solvent molecules in the coagulation bath. The effect of variation of the solvent content variation in the gelation bath on the CH4 permeance behavior of the synthesized membranes can be seen in Table 3 (Kim et al., 1997; Kim et al., 1999). Wijmans et al. (1983) and Reuvers et al. (1987) similarly observed that, by adding solvent to the coagulation bath, the formation of a skin layer was prevented or some finger-like pores can reach the surface and, consequently, the separation factor diminished. As reported in Table 3, increasing the solvent in the gelation bath, reduced the separation factor for CO2/CH4 from 28.8 to 19.

Effect of Coagulation Bath Temperature (CBT)

The influence of the coagulation bath temperature in the range from 5 ºC to 80 ºC on the flat sheet membrane structures and separation performances was also investigated. The upper and lower limits were selected based on the gelation bath freezing temperature and the PSf softening temperature, respectively. As shown in Figs. 5 (a) to 5 (d), increasing the coagulation bath temperature, increased the cell diameter. Furthermore, the amount of macrovoid and the membrane thickness are also increased dramatically (Han and Nam, 2002). This phenomenon can be explained by the rapid growth of the nuclei of the polymer-poor phase. According to the SEM images, it can be observed that, at the temperature of 5 ºC, the macrovoids have been completely removed. This observation can be justified by the following. Reducing the CBT levels strongly reduces the mutual diffusivities between the nonsolvent (deionized water) and the solvent (DMAc) in the casting solution during the solidification process. In addition, reduction of CBT slows down the growth of the primary nuclei formed after immersion, which results in the formation of numerous nuclei in the cast film (Barzin et al., 2005). The high amount of nuclei results in the suppression of macrovoids and in compactness of the polymer chains, which eventually leads to a restriction in the rotation of PSf segments around the main chain bonds and the formation of denser structures (Fig. 5 (a)). These findings are in agreement with other studies reported in the literature (Smolders et al., 1992). Table 4 shows gas permeances and the separation factors for CO2/CH4 for PDMS/PSf coated membranes fabricated at the different gelation bath temperatures. Comparing the selectivity data obtained for the membranes prepared at the different coagulation temperatures (5-80 ºC) revealed that the CO2 and CH4 gas permeances were increased. Among the CBTs studied here, the membranes prepared at the coagulation bath temperature of 25 ºC exhibited optimum gas separation performance, which means that the amount of pinholes in the selective skin layer was negligible.

Influence of Coagulant Type

The scope of this section is to establish relationships between different organic quench media and water for a given casting system and the resulting morphologies. According to the SEM images taken of the surface (Fig. 6) of the membranes, one can see that when water was used as the coagulation bath, the surface of the membrane was smooth with no clear pores. When ethanol was used as the coagulation bath, pinholes appeared sparsely on the membrane surface, while the use of methanol as coagulant caused the appearance of a large amount of pinholes on the surface. The gas permeances and the selectivities for CO₂/CH₄ of the membranes prepared in the water, ethanol and methanol coagulation baths are shown in Table 5. By comparing the data depicted in this table, we can see that using of methanol as the coagulant resulted in a less selective membrane (23) compared with ethanol (28) and water (28.8), while the CO2 permeance was about 3 and 9 times greater than with ethanol and water as coagulants, respectively. These results are in agreement with Pinnau et al. (1992) observation for N₂/O₂. A question may arise as to why the CO₂ permeance of membranes made with methanol as coagulant is higher than with ethanol and water. We believe that CO2 molecules are adsorbed at a high level on the skin layer surface and can then diffuse through the dense layer; therefore, the CO₂ permeance is governed by the skin layer thickness. Whenever the thickness of the dense skin layer decreases, the permeance of CO2 increases.

CONCLUSIONS

The effect of non-solvent additive (ethanol), different water/solvent ratios as the coagulation medium, CBT and different coagulants on the morphology and gas separation property of PDMS/PSf membranes has been successfully investigated. The results revealed that the CO₂/CH₄ separation factor and the CO2 permeance were increased by the addition of a non-solvent additive. The CO₂/CH₄ separation factor decreased upon increasing the concentration of the solvent in the coagulation bath. With a 20/80 vol. % mixture of water/DMAc as coagulant, pores of varying sizes existed on the membrane surface and, in the case of a 10/90 vol. % mixture of water/DMAc, the finger voids disappeared completely. By increasing the coagulation bath temperature, the cell diameter, the macrovoids and the membrane thickness were increased. By using different coagulants (differing in their boiling points), the CO2/CH4 separation factor and the CO2 permeance were changed notably.

ACKNOWLEDGEMENTS

The authors are grateful for the financial support provided by the Iran National Science Foundation (INSF) and Vice President for Research and Technology of Ferdowsi University of Mashhad under grant number 35462.

REFERENCES

Abu-Zahra, M. R. M., Feron, P. H. M., Jansens, P. J., Goetheer, E. L. V., New process concepts for CO2 post-combustion capture process integrated with co-production of hydrogen. Int. J. Hydrogen Energy, 34, 3392-4004 (2009).

Amirilargani, M., Saljoughi, E., Mohammadi, T., Effects of Tween 80 concentrations as a surfactant additive on morphology and permeability of flat sheet polyethersulfone (PES) membranes. Desalination, 249, 837-842 (2009).

Anderson, L. J., Dixon, J. K., Maginn, E. J., Brennecke, J. F., Measurement of SO2 solubility in ionic liquids. J. Phys. Chem., B, 110, 15059-15062 (2006).

Aroon, M. A., Ismail, A. F., Montazer-Rahmati, M. M., Matsuura, T., Morphology and permeation properties of polysulfone membranes for gas separation: Effects of non-solvent additives and co-solvent. Separation and Purification Technology, 72, 194-202 (2010).

Baker, R. W., Membrane Technology and Application, 2^nd Ed., Wiley, New York, (2004).

Banks, W., Sharples, A., Studies on desalination by reverse osmosis: II. The relation between the fabrication procedure and the structure of cellulose acetate desalination membranes. J. Appl. Chem., 16, 94-99 (1966).

Barzin, J., Madaeni, S. S., Mirzadeh, H., Effect of preparation conditions on morphology and performance of hemodialysis membranes prepared from polyether sulphone and polyvinylpyrrolidone. Iranian Polymer Journal, 14, 353-360 (2005).

Basu, S., Khan, A., Cano-Odena, A., Liu, C., Vankelecom, I. F. J., Membrane based technologies for biogas separations. Chem. Soc. Rev., 39, 750-768 (2010).

Bhide, B. D., Stern, S. A., Membrane processes for the removal of acid gases from natural gas. I. Process configurations and optimization of operating conditions. J. Membr. Sci., 81, 209 (1993a).

Bhide, B. D., Stern, S. A., Membrane processes for the removal of acid gases from natural gas. II. Effects of operating conditions, economic parameters, and membrane properties. J. Membr. Sci., 81, 239 (1993b).

Bottmo, A., Capanelli, G. and Munari, S., Effect of coagulation medium on properties of sulfonated polyvinylidene fluoride membranes. J. Appl. Polym. Sci., 30, 3009-3022 (1985).

Brandrup, J., Immergut, E. H., Grulke, E. A., Polymer Handbook. 4^th Ed., Wiley Interscience, New York (1999).

Brunettia, A., Scuraa, F., Barbieria, G., Drioli, E., Membrane technologies for CO2 separation. J. Membr. Sci., 359, 115-125 (2010).

Chern, R. T., Koros, W. J., Hopfenberg, H. B., Stannett, V. T., Materials selection for membrane- based gas separations. In: D.R. Lloyd (Ed.) Material Science of Synthetic, Royal Society of Chemistry, Washington DC, p. 25 (1985).

Choi, S. H., Kim, J. H., Lee, S. B., Sorption and permeation behaviors of a series of olefins and nitrogen through PDMS membranes. J. Membr. Sci., 209, 54-62 (2007).

Chung, T. S., Shieh, J. J., Lau, W. W. Y., Srinivasan, M. P., Paul, D. R., Fabrication of multi-layer composite hollow fiber membranes for gas separation. J. Membr. Sci., 152, 211-225 (1999).

Feng, X. S., Huang, R. Y. M., Liquid separation by membrane pervaporation: A review. Ind. Eng. Chem. Res., 36, 1048 (1997).

Han, M. J., Nam, S. T., Thermodynamic and rheological variation in polysulfone solution by PVP and its effect in the preparation of phase inversion membrane. J. Membr. Sci., 202, 55-61 (2002).

Henis, L. M. S., Triboldi, M. K., Composite hollow fiber membranes for gas separation: The resistance model approach. J. Membr. Sci., 8, 233 (1981).

Herzog, H., Eliasson, B., Kaarstad, O., Capturing greenhouse gases. Sci. Am., 182, 72-9 (2000).

Kim, J. H., Won, J., Kang, Y. S., Olefin-induced dissolution of silver salts physically dispersed in inert polymers and their application to olefin/ paraffin separation. J. Membr. Sci., 241, 403-407 (2004).

Kim, J. Y., Lee, H. K., Baik, K. J., Kim, S. C., Liquid-liquid phase separation in polysulfone/ solvent/water systems. J. Appl. Polym. Sci., 65, 2643 (1997).

Kim, J. Y., Kim, Y. D., Kanamori, T., Lee, H. K., Baik, K. J., Kim, S. C., Vitrification phenomena in polysulfone/NMP/water system. J. Appl. Polym. Sci., 71, 431 (1999).

Klara, S. M., Srivastava, R. D., US DOE integrated collaborative technology development program for CO2 separation and capture. Environ. Prog., 21, 247-253 (2002).

Liu, J., Shi, F., Research progress of removing hydrogen sulfide technology. Liaoning Chem. Indust., 39, 292-294 (2010).

Mulder, M. H. V., Hendrlkman, J. O., Wijmans, J. G., Smolders, C. A., A rationale for the preparation of asymmetric pervaporation membranes. J. Appl. Polym. Sci., 30, 2805-2820 (1985).

Mulder, M., Basic Principles of Membrane Technologies. 2^nd Ed., Kluwer Academic Publishers, Netherlands (1996).

Olajire, A. A., CO2 capture and separation technologies for end-of-pipe applications. Energy, 35, 2610-2628 (2010).

Peter, J., Peinemann, K.-V., Multilayer composite membranes for gas separation based on crosslinked PTMSP gutter layer and partially cross linked Matrimid 5218 selective layer. J. Membr. Sci., 340, 62-72 (2009).

Pesek, S. C., Koros, W. J., Aqueous quenched asymmetric polysulfone membranes prepared by dry/wet phase separation. J. Membr. Sci., 81, 71 (1993).

Pinnau, I., Koros, W. J., Influence of quench medium on the structures and gas permeation properties of polysulfone membranes made by wet and dry/wet phase inversion. J. Membr. Sci., 71, 81-96 (1992).

Rafiq, S., Mana, Z., Maulud, A., Muhammada, N., Maitra, S., Separation of CO₂ from CH₄ using polysulfone/polyimide silica nanocomposite

M. Pakizeh, S. A. A. Mansoori, M. Pourafshari Chenar and M. Namvar-Mahboub membranes. Separation and Purification, Technology, 90, 162-172 (2012).

Raharjo, R. D., Freeman, B. D., Paul, D. R., Sarti, G. C., Sanders, E. S., Pure and mixed gas CH₄ and n-C₄H₁₀ permeability and diffusivity in poly (dimethylsiloxane). J. Membr. Sci., 306, 75-92 (2007).

Ren, X., Ren, J., Deng, M., Poly(amide-6-b-ethylene oxide) membranes for sour gas separation. Separation and Purification Technology, 89, 1-8 (2012).

Reuvers, A. J. and Smolders, C. A., Formation of membranes by means of immersion precipitation. Part II. The mechanism of formation of membranes prepared from the system cellulose acetateacetone-water. J. Membr. Sci., 34, 67-86 (1987).

Saler, V. H. D., Strathmann, H., Myllus, U. V., Zum bildungsmechanismus asymmetrischer membranen, Die Angewandte Makromolekulare Chemie, 40, (1), 391-404 (1974). (In German).

Shi, Q., Su, Y., Zhu, S., Li, C., Zhao, Y., Jiang, Z., A facile method for synthesis of pegylated polyethersulfone and its application in fabrication of antifouling ultrafiltration membrane. J. Membr. Sci., 303, 204-212 (2007).

Smolders, C. A., Reuvers, A. J., Boom, R. M., Wienk, I. M., Microstructures in phase inversion membranes. Part I. Formation of macrovoids. J. Membr. Sci., 73, 259-275 (1992).

Strathmann, H., Production of microporous media by phase inversion. In: D. R. Lloyd (Ed.), Materials Science of Synthetic Membranes, ACS Symposium Series No. 269, American Chemical Society, Washington, DC, p. 165-195 (1985).

Stropnik, C., Kaiser, V., Polymeric membranes preparation by wet phase separation: Mechanisms and elementary processes. Desalination, 145, 110 (2002).

Thambimuthu, K., Soltanieh, M., Abanades, J. C., Special Report on Carbon Dioxide Capture and Storage. Intergovernmental Panel on Climate Change (IPCC), Cambridge University Press, Cambridge, UK/New York, USA (2005).

Wang, D. L., Teo, W. K., Li, K., Preparation and characterization of high-flux polysulfone hollow fiber gas separation membranes, J. Membr. Sci., 204, 247-256 (2002).

Wang, D. L., Li, K., Teo, W. K., Relationship between mass ratio of nonsolvent-additive to solvent in membrane casting solution and its coagulation value. J. Membr. Sci., 98, 233-240 (1995).

Wijmans, J. G., Baaij, J. P. B., Smolders, C. A., The mechanism of formation of microporous or skinned membranes produced by immersion precipitation. J. Membr. Sci., 14, 263-274 (1983).

Wijmans, J. G., Kant, J., Mulder, M. H. V., Smolders, C. A., Phase separation phenomena in solutions of polysulfone in a mixture of a solvent and a non-solvent: Relationship with membrane formation. Polymer, 26, 1539-1545 (1985).

Wu, F., Li, L., Xu, Z., Tan, S., Zhang, Z., Transport study of pure and mixed gases through PDMS membrane. Chem. Eng. J., 117, 51-59 (2006).

Xu, Z. L., Qusay, F. A., Polyethersulfone, (PES) hollow fiber ultrafiltration membranes prepared by PES/non-solvent/NMP solution. J. Membr. Sci., 233, 101-111 (2004).

Yeow, M. L., Field, R. W., Li, K., Teo, W. K., Preparation of divinyl-PDMS/PVDF composite hollow fibre membranes for BTX removal. J. Membr. Sci., 203, 137-143 (2002).

Submitted: January 17, 2012

Revised: June 11, 2012

Accepted: July 6, 2012

Publication Dates

History