The Effect of Concentration on PES/NMP System on Flat Sheet Membrane Fabrication and its Performance for CO2 Gas Separation

IF 1.2 Q3 MULTIDISCIPLINARY SCIENCES Journal of Physical Science Pub Date : 2023-08-25 DOI:10.21315/jps2023.34.2.8
Mohamad Alif Adnan, Muhd Izzudin Fikry Zainuddin, Abdul Latif Ahmad
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Abstract

Carbon dioxide (CO2) capture utilising membrane technology have become the interest of research due to its low carbon footprint, feasible fabrication process and scalability in its operation. In this study, anisotropic polyethersulfone (PES) membrane was fabricated at various concentration ranging from 20 wt% to 35 wt% without the use of any additives. This study revealed that the finger-like structure disappeared with increased polymer dope concentration which was associated with increased viscosity of the dope solution. Moreover, the surface porosity of the membrane also virtually reduced with increased PES concentration as observed with the SEM images. The pure gas permeation test was also consistent with the observed morphology of the membrane. Membrane made with 20 wt% of PES dope solution exhibits the highest gas permeance which was 154.9 GPU at 2 bar while the CO2/nitrogen (N2) and CO2/methane (CH4) ideal selectivity was close to that of Knudsen’s selectivity value. With increased PES concentration, the CO2 gas permeance reduced drastically accompanied by enhancement on the CO2/N2 and CO2/ CH4 ideal selectivity. The critical concentration of PES dope solution obtained by plotting the PES dope concentration against viscosity was 29.4 wt%. With critical concentration of the dope solution, the CO2 permeance was recorded to be 8.1 GPU while the CO2/N2 and CO2/CH4 ideal selectivity were recorded to be 2.13 and 1.48, respectively at the pressure of 2 bar.
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PES/NMP系统浓度对平板膜制备及其CO2气体分离性能的影响
利用膜技术捕获二氧化碳因其低碳足迹、可行的制造工艺和可扩展性而成为研究的热点。在本研究中,在不使用任何添加剂的情况下,在20 wt%至35 wt%的不同浓度下制备了各向异性聚醚砜(PES)膜。该研究表明,随着聚合物溶液粘度的增加,聚合物溶液浓度的增加,指状结构消失。此外,从SEM图像中可以看出,随着PES浓度的增加,膜的表面孔隙率实际上也降低了。纯气体渗透试验也与观察到的膜形态一致。当PES溶液质量分数为20%时,膜的气体透过率最高,为154.9 GPU, CO2/氮气(N2)和CO2/甲烷(CH4)的理想选择性接近Knudsen选择性值。随着PES浓度的增加,CO2气体透过率急剧降低,CO2/N2和CO2/ CH4理想选择性增强。通过对PES浆液浓度与粘度的关系,得到了PES浆液的临界浓度为29.4 wt%。在临界浓度下,在2 bar的压力下,CO2的渗透率为8.1 GPU, CO2/N2和CO2/CH4的理想选择性分别为2.13和1.48。
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来源期刊
Journal of Physical Science
Journal of Physical Science Physics and Astronomy-Physics and Astronomy (all)
CiteScore
1.70
自引率
0.00%
发文量
19
期刊介绍: The aim of the journal is to disseminate latest scientific ideas and findings in the field of physical sciences among scientists in Malaysia and international regions. This journal is devoted to the publication of articles dealing with research works in Chemistry, Physics and Engineering. Review articles will also be considered. Manuscripts must be of scientific value and will be submitted to independent referees for review. Contributions must be written in English and must not have been published elsewhere.
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