Mechanism of imidazole catalysis in the curing of epoxy resins

Abstract

AbstractThe mechanism of imidazole catalysis in the curing of epoxy resins was studied using the PGE/1‐methylimidazole, 2‐methylimidazole, and 1,2‐dimethylimidazole model systems and another model system based on trichloromethylethylene oxide. It was demonstrated that imidazolium systems, generated in the curing reaction, show an inherent instability leading to cleavage of an NC bond or the 2‐CH bond (2‐unsubstituted imidazoles). Fourier‐transform infrared spectroscopy was used to follow specific changes in the IR spectrum of the curing mixture during polymerization. The identification of carbonyl absorptions occurring during the polymerization led to the conclusion that ketone formation is a general occurrence in the cure of epoxides with nitrogen compounds. We have also shown that imidazoles are regenerated during the curing process by at least two routes. One pathway for the regeneration of the catalyst involves N‐dealkylation of the imidazole via a substitution process. Another route, β‐elimination, afforded carbonyl compounds, which account for the previously unexplained appearence of infrared bands in the 1650–1770 cm−1 region during the curing process. These investigations demonstrated the true catalytic function of the imidazole. Possible mechanisms for the regeneration of the catalyst are also suggested.