Synthesis and properties of biobased epoxy resins. part 1. Glycidylation of flavonoids by epichlorohydrin

Biobased epoxy resins were synthesized from a catechin molecule, one of the repetitive units in natural flavonoid biopolymers also named condensed tannins. The reactivity of catechin toward epichlorohydrin to form glycidyl ether derivatives was studied using two model compounds, resorcinol and 4‐methylcatechol, which represent the A and B rings of catechin, respectively. These model molecules clearly showed differences in reactivity upon glycidylation, explaining the results found with catechin monomer. The reaction products were characterized by both FTIR and NMR spectroscopy and chemical assay. The glycidyl ether of catechin (GEC) was successfully cured in various epoxy resin formulations. The GECs thermal properties showed that these new synthesized epoxy resins displayed interesting properties compared to the commercial diglycidyl ether of bisphenol A (DGEBA). For instance, when incorporated up to 50% into the DGEBA resin, GEC did not modify the glass‐transition temperature. Epoxy resins formulated with GEC had slightly lower storage moduli but induced a decrease of the swelling percentage, suggesting that GEC‐enhanced crosslinking in the epoxy resin networks. © 2011 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2011 The possibility to partially replace bisphenol A by catechin, a representative of the monomeric unit of condensed tannins, was evaluated. Biobased epoxy resins were formulated from the glycidyl ether of catechin (GEC). Their thermal properties, dynamic mechanical properties, and swelling percentage were investigated and compared to a commercial diglycidyl ether of bisphenol A (DGEBA). For instance, when incorporated into DGEBA resin, GEC did not modify the glass transition temperature but induced a decrease of the swelling percentage, suggesting that GEC enhanced crosslinking in the epoxy resin networks.