Significant enhancement of mechanical properties for glass fiber fabric-reinforced polyamide 6 composites by improving interfacial bonding

In fiber-reinforced composites, the interfacial bonding between fibers and the matrix is crucial for determining the material's performance. A vacuum-assisted resin transfer molding (VARTM) process was utilized in this work to fabricate glass fiber fabric-reinforced polyamide 6 (GFF/PA6) composites through in-situ polymerization using caprolactam (CL) as the precursor. To enhance the fiber-matrix interfacial bonding, polyethylene glycol (PEG) was incorporated into the polymerization system, improving the hydrogen bonding between the matrix and fibers. Morphological observations and interface layer analysis revealed that the introduction of PEG resulted in improved interfacial bonding and increased interface layer thickness. Molecular dynamics simulations indicated that the amino formate groups formed by the reaction with PEG exhibited more hydrogen bonds with the hydroxyl groups on the glass fiber surface, thereby promoting interfacial bonding between the matrix and fibers. When the PEG content was 10 wt%, the tensile strength and the elongation at break of the corresponding composite increased by 160% and 300% compared to GFF/PA6 composites without PEG. This study presents a promising strategy for enhancing the fiber-matrix interfacial bonding by modifying the matrix, offering a prospective approach for developing high-strength thermoplastic composites.Highlights GFF/PA6 composites were fabricated via the VARTM method. The addition of PEG for matrix modification improved the interfacial bonding. The modification enhances the hydrogen bonding between the matrix and fibers. Good interfacial bonding can greatly promote the crystallization of the matrix. The composites exhibited a significant increase in strength and toughness. Preparation and properties of CFF/PA6-co-PEG composites. image