Download This PaperConstruction of Multiple Interpenetrating Network Electric Field-Assisted Healing Hydrogel Composite Damage-Resistant Membrane
29 Pages Posted: 9 Apr 2024
Abstract
Inspired by the intrinsic self-healing ability of organisms, this study proposes to incorporate healing properties into separation membranes that have been damaged during cleaning and replacement processes. The polyacrylic acid (PAA) hydrogel-modified layer was first obtained by in situ cross-linking and free radical polymerization in this research. After that, the construction of multiple interpenetrating three-dimensional (3D) network hydrogel-modified layers was realized via inserting amininated carbon nanotubes (CNTs-NH2) and Fe3+. Under the external effect of the electric field, the reversible dynamic linkage bonded in the conductive network constructed by CNTs-NH2 and Fe3+ benefited the rearrangement and diffusion of PAA molecular chains at the fractured interface. The dye separation performance of the composite membrane was restored to ca. 90% of the initial level without affecting the dynamic operation after damage. The hydrogel-modified layer can be structurally stabilized for as long as 100 days. The Fe3+/CNTs-NH2/PAA/PES hydrogel composite membrane maintained a pure water flux of as high as 124.66 L∙m-2∙h-1∙bar-1. This coating also exhibited excellent electrical conductivity (714.33 Ω/sq), mechanical strength (4.31 Mpa), repair, and screening capabilities. It provides a theoretical basis for achieving industrial scale-up and demonstrates good application prospects and empowerment potential.
Keywords: Hydrogel, multiple interpenetrating networks, electric field-assisted healing, Composite membrane
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