Zhang Mengxi, Jing Xuechun, Zhao Shuang, Shao Pengpeng, Zhang Yuanyuan, Yuan Shuai, Li Yanshuo, Gu Cheng, Wang Xiaoqi, Ye Yanchun, Feng Xiao, Wang Bo
School of Chemistry and Chemical Engineering, Beijing Institute of Technology, Beijing, 100081, P. R. China.
School of Material Science and Chemical Engineering, Ningbo University, Ningbo, 315211, P. R. China.
Angew Chem Int Ed Engl. 2019 Jun 24;58(26):8768-8772. doi: 10.1002/anie.201904385. Epub 2019 May 22.
Membrane technologies that do not rely on heat for industrial gas separation would lower global energy cost. While polymeric, inorganic, and mixed-matrix separation membranes have been rapidly developed, the bottleneck is balancing the processability, selectivity, and permeability. Reported here is a softness adjustment of rigid networks (SARs) strategy to produce flexible, stand-alone, and molecular-sieving membranes by electropolymerization. Here, 14 membranes were rationally designed and synthesized and their gas separation ability and mechanical performance were studied. The separation performance of the membranes for H /CO , H /N , and H /CH can exceed the Robeson upper bound, among which, H /CO separation selectivity reaches 50 with 626 Barrer of H permeability. The long-term and chemical stability tests demonstrate their potential for industrial applications. This simple, scalable, and cost-effective strategy holds promise for the design other polymers for key energy-intensive separations.
不依赖热进行工业气体分离的膜技术将降低全球能源成本。虽然聚合物、无机和混合基质分离膜已得到快速发展,但瓶颈在于平衡可加工性、选择性和渗透性。本文报道了一种刚性网络柔软度调节(SARs)策略,通过电聚合制备柔性、独立的分子筛膜。在此,合理设计并合成了14种膜,并研究了它们的气体分离能力和机械性能。这些膜对H₂/CO₂、H₂/N₂和H₂/CH₄的分离性能可超过罗伯逊上限,其中H₂/CO₂分离选择性达到50,H₂渗透率为626巴耳。长期和化学稳定性测试证明了它们在工业应用中的潜力。这种简单、可扩展且具有成本效益的策略有望用于设计用于关键能源密集型分离的其他聚合物。
