Litcius/Paper detail

Inorganic Nanotube Mesophases Enable Strong Self-Healing Fibers

Won Jun Lee, Erwan Paineau, David B. Anthony, Yulin Gao, Hannah S. Leese, Stéphan Rouzière, Pascale Launois, Milo S. P. Shaffer

2020ACS Nano25 citationsDOIOpen Access PDF

Abstract

The assembly of one-dimensional nanomaterials into macroscopic fibers can improve mechanical as well as multifunctional performance. Double-walled aluminogermanate imogolite nanotubes are geo-inspired analogues of carbon nanotubes, synthesized at low temperature, with complementary properties. Here, continuous imogolite-based fibers are wet-spun within a poly(vinyl alcohol) matrix. The lyotropic liquid crystallinity of the system produces highly aligned fibers with tensile stiffness and strength up to 24.1 GPa (14.1 N tex–1) and 0.8 GPa (0.46 N tex–1), respectively. Significant enhancements over the pure polymer control are quantitatively attributed to both matrix refinement and direct nanoscale reinforcement, by fitting an analytical model. Most intriguingly, imogolite-based fibers show a high degree of healability via evaporation-induced self-assembly, recovering up to 44% and 19% of the original fiber tensile stiffness and strength, respectively. This recovery at high absolute strength highlights a general strategy for the development of high-performance healable fibers relevant to composite structures and other applications.

Topics & Concepts

Materials scienceUltimate tensile strengthComposite materialCrystallinityImogoliteCarbon nanotubePolymerNanomaterialsFiberComposite numberNanoscopic scaleVinyl alcoholLyotropicMatrix (chemical analysis)NanotubeAluminosilicateNanotechnologyChemical engineeringLiquid crystallineChemistryEngineeringCatalysisBiochemistryGrouting, Rheology, and Soil MechanicsMicrobial Applications in Construction MaterialsPolymer Nanocomposites and Properties