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由叔丁基-三联苯聚酰胺和多孔聚合物网络制成的混合基质膜的自由体积和渗透性

Free Volume and Permeability of Mixed Matrix Membranes Made from a Terbutil--terphenyl Polyamide and a Porous Polymer Network.

作者信息

Soto Cenit, Carmona Javier, Freeman Benny D, Palacio Laura, González-Ortega Alfonso, Prádanos Pedro, Lozano Ángel E, Hernandez Antonio

机构信息

Surfaces and Porous Materials (SMAP), Associated Research Unit to CSIC, University of Valladolid, Facultad de Ciencias, Paseo Belén 7, E-47011 Valladolid, Spain.

Institute of Sustainable Processes (ISP), Dr. Mergelina s/n, 47011 Valladolid, Spain.

出版信息

Polymers (Basel). 2022 Aug 3;14(15):3176. doi: 10.3390/polym14153176.

DOI:10.3390/polym14153176
PMID:35956689
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9371232/
Abstract

A set of thermally rearranged mixed matrix membranes (TR-MMMs) was manufactured and tested for gas separation. These membranes were obtained through the thermal treatment of a precursor MMM with a microporous polymer network and an o-hydroxypolyamide,(HPA) created through a reaction of 2,2-bis(3-amino-4-hydroxyphenyl)-hexafluoropropane (APAF) and 5'-terbutil--terfenilo-3,3″-dicarboxylic acid dichloride (tBTmCl). This HPA was blended with different percentages of a porous polymer network (PPN) filler, which produced gas separation MMMs with enhanced gas permeability but with decreased selectivity. The thermal treatment of these MMMs gave membranes with excellent gas separation properties that did not show the selectivity decreasing trend. It was observed that the use of the PPN load brought about a small decrease in the initial mass losses, which were lower for increasing PPN loads. Regarding the glass transition temperature, it was observed that the use of the filler translated to a slightly lower Tg value. When these MMMs and TR-MMMs were compared with the analogous materials created from the isomeric 5'-terbutil--terfenilo-4,4″-dicarboxylic acid dichloride (tBTpCl), the permeability was lower for that of tBTmCl, compared with the one from tBTpCl, although selectivity was quite similar. This fact could be attributed to a lower rigidity as roughly confirmed by the segmental length of the polymer chain as studied by WAXS. A model for FFV calculation was proposed and its predictions compared with those evaluated from density measurements assuming a matrix-filler interaction or ideal independence. It turns out that permeability as a function of FFV for TR-MMMs follows an interaction trend, while those not thermally treated follow the non-interaction trend until relatively high PPN loads were reached.

摘要

制备了一组热重排混合基质膜(TR-MMMs)并进行了气体分离测试。这些膜是通过对一种前驱体MMM进行热处理得到的,该前驱体MMM具有微孔聚合物网络和通过2,2-双(3-氨基-4-羟基苯基)-六氟丙烷(APAF)与5'-叔丁基-1,1'-联苯-3,3''-二羧酸二氯(tBTmCl)反应生成的邻羟基聚酰胺(HPA)。将这种HPA与不同百分比的多孔聚合物网络(PPN)填料混合,得到了气体渗透性增强但选择性降低的气体分离MMMs。对这些MMMs进行热处理后得到的膜具有优异的气体分离性能,且没有显示出选择性下降的趋势。观察到使用PPN负载会导致初始质量损失略有降低,随着PPN负载增加,质量损失更低。关于玻璃化转变温度,观察到使用填料会使Tg值略低。当将这些MMMs和TR-MMMs与由异构体5'-叔丁基-1,1'-联苯-4,4''-二羧酸二氯(tBTpCl)制备的类似材料进行比较时,与tBTpCl相比,tBTmCl的渗透率较低,尽管选择性相当相似。这一事实可归因于聚合物链段长度所大致证实的较低刚性,如广角X射线散射(WAXS)研究所示。提出了一种自由体积分数(FFV)计算模型,并将其预测结果与假设基质-填料相互作用或理想独立情况下从密度测量评估得到的结果进行比较。结果表明,TR-MMMs的渗透率作为FFV的函数遵循相互作用趋势,而未经热处理的MMMs在达到相对较高的PPN负载之前遵循非相互作用趋势。

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