CO2 separation performance and thermo-mechanical characteristics of mixed matrix membranes composed of polyvinylidene fluoride/hyperbranched polyethylenimine embedded with zinc oxide/graphene oxide filler

IF 2.4 3区化学 Q3 POLYMER SCIENCE

Iranian Polymer Journal Pub Date : 2024-05-08 DOI:10.1007/s13726-024-01321-w

Muhammad Waqas Ahmad, Sana Sahar Shiekh, Aneela Sabir, Rafi Ullah Khan

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Abstract

Herein, polyvinylidene fluoride (PVDF)/hyperbranched polyethylenimine (HPEI) blend matrix was infused with graphene oxide–zinc oxide (GO–ZnO) filler to fabricate mixed matrix membranes (MMMs). These membranes were investigated by dynamic mechanical–thermal analysis (DMTA), single and binary gas (CO₂/N₂ and CO₂/CH₄) experiments and for anti-plasticization performance. Varying loading fractions [0.1%, 0.3%, 0.5% and 0.7% (by weight)] of as-synthesised GO–ZnO filler were incorporated into the blend matrix (PVDF/HPEI). Utmost consideration was provided to understand the microstructure of MMMs through DMTA and its influence on gas separation performance. Single gas testing revealed that MMMs exhibited ~ 82% improved CO₂ permeability as compared to the control membrane, at 0.5% (by weight) GO–ZnO filler loading. During binary gas experiments, CO₂ permeability increased by 79%, whereas CO₂/N₂ and CO₂/CH₄ selectivity was enhanced by 136% and 142%, respectively. The highly CO₂-phillic amine moieties of HPEI and the polar oxygen-containing moieties on GO sheets augmented the CO₂ diffusivity and sorption. Amongst various membranes, MMMs loaded with 0.5% (by weight) GO–ZnO tested at various pressures (4, 6, 8 and 10 bars) demonstrated the highest inhibitory effect on the CO₂-induced plasticization. DMTA suggested that GO–ZnO created a robust interfacial adhesion with PVDF/HPEI, forming a rigid microstructure that was propitious in resisting pressure-induced plasticization. With a significant boost in thermo-mechanical attributes and CO₂ separation efficiency, GO–ZnO-loaded MMMs suggest intriguing prospects in CO₂ separation applications.

Graphical abstract

Abstract Image

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由嵌入氧化锌/氧化石墨烯填料的聚偏氟乙烯/超支化聚乙烯亚胺组成的混合基质膜的二氧化碳分离性能和热机械特性

在本文中，聚偏二氟乙烯（PVDF）/超支化聚乙烯亚胺（HPEI）共混基质注入了氧化石墨烯-氧化锌（GO-ZnO）填料，以制造混合基质膜（MMMs）。这些膜通过动态机械热分析（DMTA）、单一和二元气体（CO2/N2 和 CO2/CH4）实验以及抗塑化性能进行了研究。在混合基质（PVDF/HPEI）中加入了不同负载分数[0.1%、0.3%、0.5%和 0.7%（重量比）]的合成 GO-ZnO 填料。研究人员通过 DMTA 对 MMM 的微观结构及其对气体分离性能的影响进行了深入研究。单气体测试表明，与对照膜相比，当 GO-ZnO 填料含量为 0.5%（重量百分比）时，MMM 的二氧化碳渗透率提高了约 82%。在二元气体实验中，二氧化碳渗透性提高了 79%，而 CO2/N2 和 CO2/CH4 选择性分别提高了 136% 和 142%。HPEI 的高二氧化碳illic胺分子和 GO 片上的极性含氧分子提高了二氧化碳的扩散性和吸附性。在各种膜中，在不同压力（4、6、8 和 10 巴）下测试的负载了 0.5%（按重量计）GO-ZnO 的 MMM 对二氧化碳诱导的塑化具有最高的抑制作用。DMTA 表明，GO-ZnO 与 PVDF/HPEI 形成了强大的界面粘附力，形成了刚性微结构，有利于抵抗压力引起的塑化。随着热机械属性和二氧化碳分离效率的显著提高，GO-ZnO负载的MMMs在二氧化碳分离应用中展现出了引人入胜的前景。图文摘要

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来源期刊

Iranian Polymer Journal 化学-高分子科学

CiteScore

4.90

自引率

9.70%

发文量

107

审稿时长

2.8 months

期刊介绍： Iranian Polymer Journal, a monthly peer-reviewed international journal, provides a continuous forum for the dissemination of the original research and latest advances made in science and technology of polymers, covering diverse areas of polymer synthesis, characterization, polymer physics, rubber, plastics and composites, processing and engineering, biopolymers, drug delivery systems and natural polymers to meet specific applications. Also contributions from nano-related fields are regarded especially important for its versatility in modern scientific development.