Innovative PEEK membrane structure fabrication using non-solvent induced phase separation

IF 2.6 4区化学 Q3 POLYMER SCIENCE

Journal of Polymer Research Pub Date : 2025-04-15 DOI:10.1007/s10965-025-04386-0

Harish Vishnu Gunjal, Gurminder Singh

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引用次数: 0

Abstract

Research on the fabrication of polymeric membranes for energy conversion, wastewater treatment, filtration, and gas separation applications has attracted attention for high-temperature and chemical-resistant polymeric materials such as poly ether ether ketone (PEEK). In this study, a non-solvent induced phase separation (NIPS) technique was introduced to prepare a porous PEEK membrane. 4-chlorophenol (4 CP) was used as a compatible solvent for the dissolution and precipitation of PEEK, which was achieved through solidification of the membrane by NIPS in three different nonsolvents: ethanol (EtOH), water, and isopropanol (IPA). The processing of PEEK in 4 CP had no effect on its chemical structure, and the achieved thermal properties were similar to virgin PEEK. Process parameters such as polymer concentration and the use of nonsolvents were studied to understand their effects on membrane morphology and performance. Changes in polymer concentration not only alter the casting solution rheology but also restrict the percentage of polymer, which affects the membrane morphology, whereas the use of nonsolvents affects the morphology through diffusion of solvent into nonsolvent. EtOH and IPA as nonsolvents showed sudden changes in the color of the membrane from transparent to white, which resulted in instantaneous de-mixing of solvent and nonsolvent, that formed finger-like structure at 7 wt% and 9 wt% polymer concentrations. Water as a nonsolvent showed a slow color change for phase separation, which resulted in delayed de-mixing, and formed sponge-like structure in the membranes with 7 wt%, 9 wt%, and 11 wt % polymer concentrations. Partial solidification before immersion of the membrane in nonsolvents was observed at 11 wt% polymer concentration owing to reduction in temperature. A dense PEEK membrane was observed after 9 wt% immersion in water, and a porous PEEK membrane was observed after 11 wt% immersion in IPA. Raising the polymer concentration increased the density and reduced membrane shrinkage. The proposed novel approach advances the fabrication of PEEK membranes through the dissolution of PEEK in 4 CP without the use of concentrated acids as well as the synthesis of the PEEK precursor and NIPS process.

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采用非溶剂诱导相分离技术制造新型PEEK膜结构

用于能量转换、废水处理、过滤和气体分离等应用的聚合物膜的制造研究引起了诸如聚醚醚酮（PEEK）等高温耐化学聚合物材料的关注。本研究采用非溶剂诱导相分离（NIPS）技术制备多孔PEEK膜。4-氯苯酚（4cp）作为相容溶剂，通过NIPS在乙醇（EtOH）、水和异丙醇（IPA）三种不同的非溶剂中固化膜，实现PEEK的溶解和沉淀。在4cp中加工PEEK对其化学结构没有影响，得到的热性能与未加工PEEK相似。研究了聚合物浓度和非溶剂用量等工艺参数对膜形态和性能的影响。聚合物浓度的变化不仅改变了铸膜液的流变性，而且限制了聚合物的含量，从而影响了膜的形态，而非溶剂的使用通过溶剂向非溶剂的扩散来影响膜的形态。EtOH和IPA作为非溶剂时，膜的颜色突然从透明变为白色，导致溶剂和非溶剂瞬间脱混，在7 wt%和9 wt%的聚合物浓度下形成指状结构。水作为非溶剂，在相分离时颜色变化缓慢，导致脱混延迟，在聚合物浓度为7 wt%、9 wt%和11 wt%的膜中形成海绵状结构。在聚合物浓度为11wt %时，由于温度降低，在非溶剂中浸泡膜之前观察到部分凝固。在9 wt%的水中浸泡后观察到致密的PEEK膜，在11 wt%的IPA中浸泡后观察到多孔的PEEK膜。提高聚合物浓度可提高膜的密度，降低膜的收缩率。本文提出了一种新的方法，即在不使用浓酸的情况下将PEEK溶解在4cp中制备PEEK膜，以及PEEK前体的合成和NIPS工艺。

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来源期刊

Journal of Polymer Research 化学-高分子科学

CiteScore

4.70

自引率

7.10%

发文量

472

审稿时长

3.6 months

期刊介绍： Journal of Polymer Research provides a forum for the prompt publication of articles concerning the fundamental and applied research of polymers. Its great feature lies in the diversity of content which it encompasses, drawing together results from all aspects of polymer science and technology. As polymer research is rapidly growing around the globe, the aim of this journal is to establish itself as a significant information tool not only for the international polymer researchers in academia but also for those working in industry. The scope of the journal covers a wide range of the highly interdisciplinary field of polymer science and technology, including: polymer synthesis; polymer reactions; polymerization kinetics; polymer physics; morphology; structure-property relationships; polymer analysis and characterization; physical and mechanical properties; electrical and optical properties; polymer processing and rheology; application of polymers; supramolecular science of polymers; polymer composites.