气体分离
膜
材料科学
基质(化学分析)
化学工程
纳米技术
化学
复合材料
工程类
生物化学
作者
Zhenjie Gu,Xu Zhang,Ran Liang,Fei Wang,Daqiang Wang,Aibing Chen,Zhihua Qiao
标识
DOI:10.1021/acsapm.5c02357
摘要
The integration of metal–organic frameworks into polymer matrices within mixed-matrix membranes (MMMs) presents a promising strategy for fabricating high-performance gas separation membranes. However, nanoparticle aggregation during the scale-up process reduces membrane permselectivity, limiting practical applications. This study presents a facile, solvent-induced vacuum sintering strategy for synthesizing small rigid ZIF-8 (SRZ) enriched with Zn2+ active sites. SRZ exhibited superior hydrophilicity and membrane-forming capability, enabling its homogeneous dispersion within polyvinylamine (PVAm) for the fabrication of large-area PVAm/SRZ/modified poly(ether sulfone) (MPSf) MMMs. These MMMs were uniform, dense, and defect-free, with an effective membrane area of up to 3100 cm2 and ultrathin selective layers of approximately 200 nm. Benefiting from abundant Zn2+ active sites and a rigid framework structure, the developed MMMs demonstrated high CH4 permeance (1933 GPU) and excellent CH4/N2 selectivity (3.5). To further demonstrate their potential, two PVAm/SRZ/MPSf MMMs were employed to construct spiral-wound membrane modules with a packing area of 6200 cm2. The SRZ-based membrane modules exhibited satisfactory CH4 permeance (1261 GPU) while maintaining acceptable CH4/N2 selectivity (3.35). This study presents a feasible approach to facilitate industrial applications of gas separation membranes.
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