Matrimid®5218/AO-PIM-1 Blend Membranes for Gas Separation

Q2 Materials Science Journal of Membrane Science and Research Pub Date : 2021-11-04 DOI:10.22079/JMSR.2021.540493.1504

Mariagiulia Longo, Bibiana Comesaña-Gándara, Marcello Monteleone, E. Esposito, A. Fuoco, L. Giorno, N. McKeown, J. C. Jansen

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引用次数: 2

Abstract

In the search for more efficient gas separation membranes, blends offer a compromise between costly high-performance polymers and low-cost commercial polymers. Here, blends of the polymer of intrinsic microporosity, AO-PIM-1, and commercial Matrimid®5218 polyimide are used to prepare dense films by solution casting. The morphology of the pure polymers and their blends with 20, 40, 60 and 80 wt.% of AO-PIM-1 in Matrimid® are studied by scanning electron microscopy, and their pure gas permeability is studied as a function of the blend composition with H2, He, O2, N2, CH4 and CO2. The polymers were found only partially miscible and a two-phase structure was formed with large domains of each polymer. When necessary, the films were coated with a thin silicone layer to heal possible pinhole defects. Even small amounts of Matrimid® in AO-PIM-1 resulted in an unexpectedly strong decrease in the permeability of the PIM, whereas a small amount of the PIM led to a modest increase in permeability of Matrimid®. Due to the two-phase structure, the Maxwell model was more suitable to describe the gas permeability as a function of the blend composition than the model for miscible blends. At low Matrimid® concentrations in AO-PIM-1, all models fail to describe the experimental data due to an unexpectedly strong depression of the permeability of the PIM by Matrimid®. Time lag measurements reveal that the changes in permeability as a function of the blend composition are mostly due to changes in the diffusion coefficient.

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Matrmid®5218/AO-PIM-1混合气体分离膜

在寻找更高效的气体分离膜的过程中，共混物在昂贵的高性能聚合物和低成本的商用聚合物之间提供了一个折衷方案。在这里，聚合物的固有微孔隙度，AO-PIM-1，和商用Matrimid®5218聚酰亚胺的共混物被用来制备致密薄膜的溶液铸造。用扫描电镜研究了在Matrimid®中AO-PIM-1含量分别为20%、40%、60%和80%的纯聚合物及其共混物的形貌，并研究了其纯气体渗透性与共混物中H2、He、O2、N2、CH4和CO2组成的关系。发现聚合物仅部分可混溶，形成两相结构，每种聚合物的结构域都很大。必要时，在薄膜上涂上一层薄薄的硅酮层，以修复可能出现的针孔缺陷。即使AO-PIM-1中少量的Matrimid®也会导致PIM的渗透性意外地强烈下降，而少量的PIM则会导致Matrimid®的渗透性适度增加。由于两相结构，麦克斯韦模型比混相共混物模型更适合将渗透率描述为共混物组成的函数。在AO-PIM-1中低浓度的Matrimid®时，由于Matrimid®对PIM渗透率的意外强烈抑制，所有模型都无法描述实验数据。时间滞后测量表明，渗透率的变化作为共混物组成的函数主要是由于扩散系数的变化。

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来源期刊

Journal of Membrane Science and Research Materials Science-Materials Science (miscellaneous)

CiteScore

4.00

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： The Journal of Membrane Science and Research (JMSR) is an Open Access journal with Free of Charge publication policy, which provides a focal point for academic and industrial chemical and polymer engineers, chemists, materials scientists, and membranologists working on both membranes and membrane processes, particularly for four major sectors, including Energy, Water, Environment and Food. The journal publishes original research and reviews on membranes (organic, inorganic, liquid and etc.) and membrane processes (MF, UF, NF, RO, ED, Dialysis, MD, PV, CDI, FO, GP, VP and etc.), membrane formation/structure/performance, fouling, module/process design, and processes/applications in various areas. Primary emphasis is on structure, function, and performance of essentially non-biological membranes.