Litcius/Paper detail

High glass transition catalyst-free polybenzoxazine vitrimer through one-pot solventless method

Festus Ifeanyi Anagwu, Eleftheria Dossi, Alexandros A. Skordos

2025Reactive and Functional Polymers12 citationsDOIOpen Access PDF

Abstract

A high glass transition polybenzoxazine has been synthesised by a one-pot solventless method via the Mannich condensation of a phenolic disulphide, paraformaldehyde and aniline. The solventless process reduces synthesis time, material costs, and the need for post-synthesis purification. The polybenzoxazine exhibits a glass transition temperature ( T g ) of 155 °C and thermosetting behaviour below this temperature. Dynamic disulphide bond metathesis associated with a topological freezing temperature of 78 °C and an activation energy of 127 kJ/mol delivers vitrimeric functionality with fast, catalyst-free stress relaxation above T g . This material fully relaxes stress within 5 s at 190 °C, with thermal degradation beginning above 250 °C. It exhibits a glassy modulus of 3.6 GPa, high char yield (57.4 %) translating to a high limiting oxygen index ( LOI ) of 40.5 % and excellent environmental resistance, as evidenced by low water uptake (1.4 %) after immersion at 75 °C for 31 days. The combination of environmental resistance, due to thermosetting character, high glass transition, facile synthesis, high char yield, good processability, and fast stress relaxation position this polybenzoxazine as a promising candidate matrix system for repairable aerospace thermosetting continuous fibre composites. • Aero-grade benzoxazine vitrimer can be synthesised via one-pot solventless strategy. • High temperature benzoxazine vitrimer heals under manufacturing conditions. • Benzoxazine vitrimer exhibits high limiting oxygen index due to high char yield. • Benzoxazine vitrimer exhibits low water absorption at elevated temperature.

Topics & Concepts

Glass transitionCatalysisMaterials sciencePolymer scienceComposite materialPolymerOrganic chemistryChemistryLiquid Crystal Research AdvancementsPhotopolymerization techniques and applications