Litcius/Paper detail

Tailoring Nanoporous-Engineered Sponge Fiber Molecular Sieves with Ternary-Nested Architecture for Precise Molecular Separation

Feng Zhang, Wenling Jiao, Yang Si, Jianyong Yu, Peng Zhang, Bin Ding

2021ACS Nano52 citationsDOI

Abstract

Polymeric fiber molecular sieves (PFMs) with ultrahigh surface areas, well-defined Murray’s-law hierarchical nanoporous structures, and superior self-standing properties are of great interest for molecular-level separation applications. However, creating such PFMs has been proven extremely challenging. Herein, we report a cross-scale pore-forming strategy to create intriguing sponge fiber molecular sieves with hierarchical, tailorable, and molecularly defined nanoporosity by nanospace-confined chain-packing modulation at the molecular level. Robust secondary ultramicropores (<7 Å) and micropores (<2 nm) are in situ constructed in the macro/mesoporous skeletons of sponge fibers to realize a tunable pore size distribution. The resultant PFMs exhibit the integrated properties of ultrahigh surface area (860 m2 g–1), large pore volume (0.6 cm3 g–1), self-standing properties, and excellent molecular sieving performance and are widely applied in acetophenone/phenyl ethanol separation, hydrogen peroxide purification, ethyl acetate separation, and CO2 adsorption fields. The fabrication of such PFMs provides a feasible way for the design and development of polymeric fibrous sieves for molecular separation in large-scale chemical, energy, and environmental operation processes.

Topics & Concepts

Molecular sieveNanoporousMaterials scienceMesoporous materialTernary operationChemical engineeringNanotechnologyFiberFabricationAdsorptionCatalysisChemistryOrganic chemistryComposite materialPathologyComputer scienceEngineeringAlternative medicineProgramming languageMedicineMembrane Separation and Gas TransportCovalent Organic Framework ApplicationsMembrane Separation Technologies