Rheological and foaming behaviors of long-chain branched polyamide 6 with controlled branch length

A series of long-chain branched polyamide 6 samples (LCB PA6s) with well-defined branch length were successfully fabricated via reactive extrusion by tuning various linear PA6s as reactive materials. Their structureproperty relationships were systematically investigated. The GPC-rheology method was performed to demonstrate the existence of LCB topological structure and quantitatively determine the relative branch length for three LCB PA6s. Rheological characterization showed that an increase in branch length resulted in the increased zeroshear viscosity and storage modulus at low frequency, reduced loss factor and high strain hardening coefficient under elongational flow, i.e., the enhanced elastic response and melt strength of PA6s. Finally, the melt foamability of the LCB PA6s were verified by batch foaming experiments with supercritical CO2 as the blowing agent. The LCB-Mb 4.5 with the longest branch length and highest melt strength appeared the biggest expansion ratio of 18.2 and broadest foaming window of 70 ?C, which was expected to be in production on a large scale through continuous extrusion foaming process.

Automated summary

In this study, a series of long-chain branched polyamide 6 samples (LCB PA6s) with well-defined branch length were successfully fabricated via reactive extrusion using various linear PA6s as reactive materials. The GPC-rheology method was used to demonstrate the existence of LCB topological structure and quantitatively determine the relative branch length for three LCB PA6s. Rheological characterization showed that increasing branch length resulted in enhanced elastic response and melt strength of PA6s. Additionally, the melt foamability of these LCB PA6s was verified through batch foaming experiments with supercritical CO2 as the blowing agent, showing potential for large-scale production via continuous extrusion foaming process.