High-performance spiro-branched polymeric membranes for sustainability applications

IF 25.7 1区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Nature Sustainability Pub Date : 2024-05-29 DOI:10.1038/s41893-024-01364-0
Huaqing Zhang, Wei Xu, Wanjie Song, Kang Peng, Lixuan Sun, Cui Yang, Xin Zhang, Hongjun Zhang, Bangjiao Ye, Xian Liang, Zhengjin Yang, Liang Wu, Xiaolin Ge, Tongwen Xu
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Abstract

Ion exchange membranes are semi-permeable thin films allowing for selective transport of either anions or cations and have wide applications in desalination, wastewater treatment and energy conversion and storage. Poly(aryl piperidinium) polymers are promising materials for a new generation of anion exchange membranes with high chemical stability, although their ionic conductivity remains to be further improved. Here we report a design of branched microporous poly(aryl piperidinium) membranes that combine ultra-high Cl− conductivity (120 mS cm−1 at 80 °C), excellent mechanical and chemical stability and solution processability. At the heart of our rational design is the use of stereo-contorted spirobifluorene monomers to control the topology and orientations of branched chains, achieving balanced rigidity and flexibility. The loose chain packing structure reduces the energy barrier for ion dissociation and diffusion within the polymer networks, which can be processed into large-area membranes aided by a colloidal method. When applied to redox flow batteries, our microporous membranes deliver record-breaking performance at a high current density of 400 mA cm−2. Our work suggests a feasible strategy for the development of high-performance membranes that will find more applications critical to sustainability. Ion exchange membranes play an essential role in a range of technologies critical to sustainability. Here the authors show a membrane design that features a favourable combination of good stability, high ionic conductivity and processability with demonstrated application in flow batteries.

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用于可持续性应用的高性能螺枝聚合物膜
离子交换膜是一种半透薄膜,可以选择性地传输阴离子或阳离子,在海水淡化、废水处理、能量转换和储存等领域有着广泛的应用。聚(芳基哌啶)聚合物是具有高化学稳定性的新一代阴离子交换膜的理想材料,但其离子传导性仍有待进一步提高。在此,我们报告了一种支化微孔聚(芳基哌啶)膜的设计,这种膜兼具超高 Cl- 导电性(80 °C 时为 120 mS cm-1)、优异的机械和化学稳定性以及溶液加工性。我们合理设计的核心是使用立体配位螺二芴单体来控制支链的拓扑结构和取向,从而实现刚性和柔性的平衡。松散的链包装结构降低了离子在聚合物网络中解离和扩散的能量障碍,在胶体方法的帮助下,可将其加工成大面积薄膜。当应用于氧化还原液流电池时,我们的微孔膜能以 400 mA cm-2 的高电流密度提供破纪录的性能。我们的工作为高性能膜的开发提出了一种可行的策略,这种膜将在更多对可持续发展至关重要的应用领域中找到用武之地。离子交换膜在一系列对可持续发展至关重要的技术中发挥着重要作用。作者在此展示了一种膜设计,它将良好的稳定性、高离子传导性和可加工性很好地结合在一起,并在液流电池中得到了应用。
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来源期刊
Nature Sustainability
Nature Sustainability Energy-Renewable Energy, Sustainability and the Environment
CiteScore
41.90
自引率
1.10%
发文量
159
期刊介绍: Nature Sustainability aims to facilitate cross-disciplinary dialogues and bring together research fields that contribute to understanding how we organize our lives in a finite world and the impacts of our actions. Nature Sustainability will not only publish fundamental research but also significant investigations into policies and solutions for ensuring human well-being now and in the future.Its ultimate goal is to address the greatest challenges of our time.
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